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Quyết định 1045/QĐ-CHK năm 2024 hướng dẫn thực hiện quy định, khuyến cáo thực hành của ICAO (Doc 9157 - Part 2) về Đường lăn, sân đỗ tàu bay và sân chờ tại sân bay do Cục trưởng Cục Hàng không Việt Nam ban hành

Số hiệu: 1045/QĐ-CHK Loại văn bản: Quyết định
Nơi ban hành: Cục Hàng không Việt Nam Người ký: Phạm Văn Hảo
Ngày ban hành: 10/05/2024 Ngày hiệu lực: Đã biết
Ngày công báo: Đang cập nhật Số công báo: Đang cập nhật
Tình trạng: Đã biết

BỘ GIAO THÔNG VẬN TẢI
CỤC HÀNG KHÔNG VIỆT NAM
-------

CỘNG HÒA XÃ HỘI CHỦ NGHĨA VIỆT NAM
Độc lập - Tự do - Hạnh phúc
---------------

Số: 1045/QĐ-CHK

Hà Nội, ngày 10 tháng 5 năm 2024

QUYẾT ĐỊNH

VỀ VIỆC BAN HÀNH HƯỚNG DẪN VIỆC THỰC HIỆN QUY ĐỊNH, KHUYẾN CÁO THỰC HÀNH CỦA ICAO (DOC 9157 - PART 2) VỀ ĐƯỜNG LĂN, SÂN ĐỖ TÀU BAY VÀ SÂN CHỜ TẠI SÂN BAY

CỤC TRƯỞNG CỤC HÀNG KHÔNG VIỆT NAM

Căn cứ Luật Hàng không dân dụng Việt Nam ngày 29/6/2006 và Luật sửa đổi, bổ sung một số điều của Luật Hàng không dân dụng Việt Nam ngày 21/11/2014;

Căn cứ Nghị định số 66/2015/NĐ-CP ngày 12/8/2015 của Chính phủ quy định về Nhà chức trách hàng không;

Căn cứ Nghị định số 05/2021/NĐ-CP ngày 25/01/2021 của Chính phủ về quản lý, khai thác cảng hàng không, sân bay, Nghị định số 20/2024/NĐ-CP ngày 23/02/2024 sửa đổi Nghị định số 05/2021/NĐ-CP;

Căn cứ Nghị định số 64/2022/NĐ-CP ngày 15/9/2022 của Chính phủ về sửa đổi, bổ sung một số điều của các Nghị định liên quan đến hoạt động kinh doanh trong lĩnh vực hàng không dân dụng;

Căn cứ Thông tư số 29/2021/TT-BGTVT ngày 30/11/2021 của Bộ Giao thông vận tải quy định chi tiết về quản lý, khai thác cảng hàng không, sân bay;

Căn cứ Thông tư số 19/2017/TT-BGTVT ngày 06/6/2017 của Bộ Giao thông vận tải về quản lý, bảo đảm hoạt động bay, Thông tư số 32/2021/TT- BGTVT ngày 14/12/2021 của Bộ Giao thông vận tải sửa đổi Thông tư số 19/2017/TT-BGTVT;

Căn cứ Quyết định số 651/QĐ-BGTVT ngày 29/5/2023 của Bộ trưởng Bộ Giao thông vận tải quy định chức năng, nhiệm vụ, quyền hạn và cơ cấu tổ chức của Cục Hàng không Việt Nam; Quyết định số 371/QĐ-BGTVT ngày 02/4/2024 của Bộ trưởng Bộ Giao thông vận tải về việc sửa đổi Điều 3 Quyết định số 651/QĐ-BGTVT;

Xét đề nghị của Trưởng phòng Quản lý cảng hàng không, sân bay.

QUYẾT ĐỊNH:

Điều 1. Ban hành kèm theo Quyết định này Hướng dẫn việc thực hiện quy định, khuyến cáo thực hành của ICAO (Doc 9157 - Part 2) về Đường lăn, sân đỗ tàu bay và sân chờ tại sân bay (Số tham chiếu: GM 2.2).

Điều 2. Quyết định này có hiệu lực kể từ ngày ký.

Điều 3. Các ông/bà Tổng giám đốc Tổng công ty Cảng hàng không Việt Nam - CTCP, Tổng giám đốc Tổng công ty Quản lý bay Việt Nam, Tổng giám đốc Cảng hàng không quốc tế Vân Đồn, Giám đốc các Cảng vụ hàng không miền Bắc, miền Trung, miền Nam, Trưởng phòng Quản lý cảng hàng không, sân bay và Thủ trưởng các cơ quan, đơn vị liên quan chịu trách nhiệm thi hành Quyết định này./.


Nơi nhận:
- Như Điều 3;
- Cục trưởng (để b/c);
- Các Phó Cục trưởng;
- Các phòng: QLC, QLHĐB, TCATB, ANHK, KHCNMT, PC-HTQT, TTHK;
- Lưu: VT, QLC (TD 10bn).

KT. CỤC TRƯỞNG
PHÓ CỤC TRƯỞNG




Phạm Văn Hảo

AERODROME DESIGN MANUAL

Taxiways, Aprons and Holding Bays

Hướng dẫn việc thực hiện quy định, khuyến cáo thực hành của ICAO (Doc 9157 - Part 2) về Đường lăn, sân đỗ tàu bay và sân chờ tại sân bay

(GM 2.2)

Issued herewith Decision No. 1045/QD-CHK dated 10th May 2024

VERSION RECORDS

Date of issue

Subject(s)/ Amendment

Source

Effective date

Note

10th May 2024

First Edition

ICAO Doc 9157 - Part 2 (2020)

10th May 2024

TABLE OF CONTENTS

FOREWORD

1. BACKGROUND

2. SCOPE AND PURPOSE

CHAPTER 1

TAXIWAYS

1.1 TAXIWAY SYSTEMS

1.2 PHYSICAL CHARACTERISTICS DESIGN CRITERIA

1.3 RAPID EXIT TAXIWAYS (RETS)

1.4 TAXIWAYS ON BRIDGES

1.5 FILLETS

1.6 TAXIWAY SHOULDERS AND STRIPS

1.7 FUTURE AIRCRAFT DEVELOPMENTS

CHAPTER 2

HOLDING BAYS AND OTHER BYPASSES

2.1 NEED FOR HOLDING BAYS AND OTHER BYPASSES

2.2 TYPES OF BYPASSES

2.3 COMMON DESIGN REQUIREMENTS AND CHARACTERISTICS

2.4 SIZE AND LOCATION OF HOLDING BAYS

2.5 HOLDING BAY MARKING AND LIGHTING

CHAPTER 3

APRONS

3.1 TYPES OF APRONS

3.2 DESIGN REQUIREMENTS

3.3 BASIC TERMINAL APRON LAYOUTS

3.4 SIZE OF APRONS

3.5 APRON GUIDANCE

3.6 DE-ICING/ANTI-ICING FACILITIES

CHAPTER 4

SEGREGATION OF TRAFFIC ON THE MOVEMENT AREA

4.1 NEED FOR TRAFFIC SEGREGATION

4.2 ACTIVITIES CAUSING A MIX OF AIRCRAFT AND GROUND VEHICLES

4.3 METHODS TO ACHIEVE SEGREGATION

APPENDIX 1

FILLET DESIGN

APPENDIX 2

JET BLAST AND BLAST FENCE CONSIDERATIONS

APPENDIX 3

AEROPLANE CLASSIFICATION BY CODE NUMBER AND LETTER

APPENDIX 4

TAXIWAY DEVIATION STUDIES

APPENDIX 5

DESIGN, LOCATION AND NUMBER OF RAPID EXIT TAXIWAYS

FOREWORD

1. BACKGROUND

1.1 Pursuant to Article 11, Clause 2 of the Decree No. 66/2015/ND-CP dated 12th August 2015 on the Civil Aviation Authority stipulating the function and responsibility of the Civil Aviation Authority of Viet Nam (CAAV) in guiding the implementation of Standards and Recommended Practices of ICAO.

1.2 Pursuant to Article 8, Clause 10 of the Decree No. 05/2021/ND-CP dated 25th January 2021 on the management and operation of airport and aerodrome stipulating the function and responsibility in providing guidance on and issue professional instructions related to management and operation of airports/aerodromes in line with regulations of law and regulations of ICAO (including: documents providing guidelines for airport/aerodrome design; documents providing guidelines for operation and assurance of security and safety at airports/aerodromes).

1.3 Pursuant to Article 4, Clause 6 of the Decree No. 0/5/2021/ND-CP dated 25th January 2021 stipulating details of airport/aerodrome infrastructure shall be designed and operated according to the standards of International Civil Aviation Organization (ICAO).

1.4 This Manual is issued by CAAV specifying the details of provisions to be met by the AO organizations, originators related. The details in this Manual are based on those stipulated in ICAO Doc 9157 - Part 2 [as in force and amended from time to time by the Council of the International Civil Aviation Organization (ICAO)] and with such modifications as may be determined by CAAV to be applicable in Viet Nam.

1.5 Amendments to this document are the responsibility of the Airport Management Department - CAAV. Readers should forward advice of errors, inconsistencies or suggestions for improvement to this Manual to the addressee stipulated below.

Airport Management Department - CAAV

No. 119, Nguyen Son Street, Gia Thuy ward, Long Bien district, Ha Noi. Email Address: and@caa.gov.vn.

2. SCOPE AND PURPOSE

2.1 This Manual includes guidance on the general layout and description of updated design criteria for taxiway physical characteristics, including the shoulder and strips. The guidance is based on well-equipped modern aircraft which have increased capabilities offered by advanced technologies, often providing very precise guidance on landing, take-off and taxiing.

In accordance with the provisions in Annex 14 - Aerodromes, Volume I - Aerodrome Design and Operations, it is recommended to provide holding bays when the traffic volume is high and the provision of aprons where necessary, to permit the on- and off- loading of passengers, cargo or mail as well as the servicing of aircraft without interfering with the aerodrome traffic. The guidance for holding bays and dual or multiple taxiways, which describes the advantages and disadvantages of the different configurations, is aimed at providing aerodrome controllers with greater flexibility in adjusting the take-off sequence to overcome undue delays. The guidance concerning aprons describes, inter alia, basic apron layouts, design requirements and the area required for a particular apron layout.

This manual also includes guidance for the segregation of traffic on the movement area and considerations for designing aerodrome facilities in order to achieve the maximum practical segregation of aircraft and ground vehicular traffic.

2.2 The purpose of this manual is to assist in the implementation of the specifications described above and help ensure their uniform application.

CHAPTER 1

TAXIWAYS

1.1 TAXIWAY SYSTEMS

Functional requirements

1.1.1 Maximum capacity and efficiency of an aerodrome are realized only by obtaining the proper balance between the need for runways, passenger and cargo terminals, and aircraft storage and servicing areas. These separate and distinct aerodrome functional elements are linked by the taxiway system. The components of the taxiway system therefore serve to link the aerodrome functions and are necessary to develop optimum aerodrome utilization.

1.1.2 The taxiway system should be designed to minimize the restriction of aircraft movement to and from the runways and apron areas. A properly designed system should be capable of maintaining a smooth, continuous flow of aircraft ground traffic at the maximum practical speed with a minimum of acceleration or deceleration. This requirement ensures that the taxiway system will operate at the highest levels of both safety and efficiency.

1.1.3 For any given aerodrome, the taxiway system should be able to accommodate (without significant delay) the demands of aircraft arrivals and departures on the runway system. At low levels of runway utilization the taxiway system can accomplish this with a minimum number of components. However, as the runway acceptance rate increases, the taxiway system capacity must be sufficiently expanded to avoid becoming a factor which limits aerodrome capacity. In the extreme case of runway capacity saturation, when aircraft are arriving and departing at the minimum separation distances, the taxiway system should allow aircraft to exit the runway as soon as practical after landing and to enter the runway just before take-off. This enables aircraft movements on the runway to be maintained at the minimum separation distance.

Planning principles

1.1.4 Runways and taxiways are the least flexible of the aerodrome elements and must therefore be considered first when planning aerodrome development. Forecasts of future activity should identify changes in the rate of aircraft movements, the nature of the traffic, type of aircraft and any other factors affecting the layout and dimensioning of the runway and taxiway systems. Care should be taken not to place so much attention on the present needs of the system that later phases of development that have equal or greater importance are neglected. For example, if an aerodrome is forecast to serve a higher category of aircraft type in the future, the current taxiway system should be designed to accommodate the greatest separation distances that ultimately will be required (see Table 1-1).

1.1.5 In planning the general layout of the taxiway system, the following principles should be considered:

a) taxiway routes should connect the various aerodrome elements by the shortest distances, thus minimizing both taxiing time and cost;

b) taxiway routes should be as simple as possible in order to avoid pilot confusion and the need for complicated instructions;

c) straight runs of pavement should be used wherever possible. Where changes in direction are necessary, curves of adequate radii, as well as fillets or extra taxiway width, should be provided to permit taxiing at the maximum practical speed (see Section 1.4 and Appendix 1);

d) taxiway crossings of runways and other taxiways should be avoided whenever possible in the interests of safety and to reduce the potential for significant taxiing delays;

e) taxiway routings should have as many one-way segments as possible to minimize aircraft conflicts and delay. Taxiway segment flows should be analysed for each configuration under which runway(s) will be used;

f) the taxiway system should be planned to maximize the useful life of each component so that future phases of development incorporate sections from the current system; and

g) ultimately, a taxiway system will perform only as well as its least adequate component. Therefore, potential bottlenecks should be identified and eliminated in the planning phase.

1.1.6 Other important considerations when planning a taxiway system include the following:

a) taxiway routes should avoid areas where the public could have easy access to the aircraft. Security of taxiing aircraft from sabotage or armed aggression should be of primary importance in areas where this is of particular concern;

b) taxiway layouts should be planned to avoid interference with navigation aids by taxiing aircraft or ground vehicles using the taxiway;

c) all sections of the taxiway system should be visible from the aerodrome control tower. Remote cameras can be used to monitor sections of taxiways shadowed by terminal buildings or other aerodrome structures if such obstructions cannot be practically avoided;

d) the effects of jet blast on areas adjacent to the taxiways should be mitigated by stabilizing loose soils and erecting blast fences where necessary to protect people or structures (see Appendix 2); and

e) the location of taxiways may also be influenced by ILS installations due to interferences to ILS signals by a taxiing or stopped aircraft. Information on critical and sensitive areas surrounding ILS installations is contained in Annex 10, Volume I, Attachment C.

Table 1-1. Design criteria for a taxiway

Outer main gear wheel span

Physical characteristics

Up to but not including 4.5 m

4.5 m up to but not including 6 m

6 m up to but not including 9 m

9 m up to but not including 15 m

9 m up to but not including 15 m

9 m up to but not including 15 m

Minimum width of:

taxiway pavement

7.5 m

10.5 m

17 ma

15 mb,c

23 mc

23 m

23 m

graded portion of taxiway strip

20.5 m

22 m

25 m

37 m

38 m

44 m

Minimum clearance distance of outer main wheel to taxiway edge

1.5 m

2.25 m

4.0 ma

3 mb

4.0 m

4.0 m

4.0 m

Code letter

Physical characteristics

A

B

C

D

E

F

Minimum width of

taxiway pavement and shoulder

-

-

25 m

34 m

38 m

44 m

taxiway strip

31 m

40 m

52 m

74 m

87 m

102 m

Minimum separation distance between taxiway centre line and: centre line of instrument runway code

number 1

number 2

number 3

number 4

77.5 m

77.5 m

-

-

82 m

82 m

152 m

-

88 m

88 m

158 m

158 m

-

-

166 m

166 m

-

-

172.5 m

172.5 m

-

-

180 m

180 m

centre line of non-instrument runway code

number 1

37.5 m

42 m

48 m

-

-

-

number 2

47.5 m

52 m

58 m

-

-

-

number 3

-

87 m

93 m

101 m

107.5 m

115 m

number 4

-

-

93 m

101 m

107.5 m

115 m

taxiway centre line object

23 m

32 m

44 m

63 m

76 m

91 m

taxiwayd

15.5 m

20 m

26 m

37 m

43.5 m

51 m

aircraft stand taxilane

12 m

16.5 m

22.5 m

33.5 m

40 m

47.5 m

Maximum longitudinal slope of taxiway:

pavement

3%

3%

1.5%

1.5%

1.5%

1.5%

change in slope

1% per 25 m

1% per 25 m

1% per 30 m

1% per 30 m

1% per 30 m

1% per 30 m

Maximum transverse slope of:

taxiway pavement

2%

2%

1.5%

1.5%

1.5%

1.5%

graded portion of taxiway strip upwards

3%

3%

2.5%

2.5%

2.5%

2.5%

graded portion of taxiway strip downwards

5%

5%

5%

5%

5%

5%

ungraded portion of strip upwards or downwards

5%

5%

5%

5%

5%

5%

Code letter

Physical characteristics

A

B

C

D

E

F

Minimum radius of longitudinal vertical curve

2 500 m

2 500 m

3 000 m

3 000 m

3 000 m

3 000 m

Minimum taxiway sight distance

150 m from

200 m from

300 m from

300 m from

300 m from

300 m from

1.5 m above

2 m above

3 m above

3 m above

3 m above

3 m above

a. Taxiway intended to be used by aeroplanes with a wheel base equal to or greater than 18 m.

b. Taxiway intended to be used by aeroplanes with a wheel base less than 18 m.

c. On straight portions.

d. Taxiway other than an aircraft stand taxilane.

1.1.7 There should be a sufficient number of entrance and exit taxiways serving a specific runway to accommodate the current demand peaks for take-offs and landings. Additional entrances and exits should be designed and developed ahead of expected growth in runway utilization. The following principles apply to the planning of these taxiway system components:

a) the function of exit taxiways is to minimize the runway occupancy time of landing aircraft. In theory, exit taxiways can be located to best serve each type of aircraft expected to use the runway. In practice, the optimum number and spacing are determined by grouping the aircraft into a limited number of classes based upon landing speed and deceleration after touchdown;

b) the exit taxiway should allow an aircraft to move off the runway without restriction to a point clear of the runway, thus allowing another operation to take place on the runway as soon as possible;

c) an exit taxiway can be either at a right angle to the runway or at an acute angle.

The former type requires an aircraft to decelerate to a very low speed before turning off the runway, whereas the latter type allows aircraft to exit the runway at higher speeds, thus reducing the time required on the runway and increasing the runway capacity (details about the location and geometry of the acute angle type [called rapid exit taxiway] are presented in Section 1.3 and Appendix 5); and

d) a single runway entrance at each end of the runway is generally sufficient to accommodate the demand for take-offs. However if the traffic volume warrants, the use of bypasses, holding bays or multiple runway entrances can be considered (see Chapter 2).

1.1.8 Taxiways located on aprons are divided into two types as follows (see Figure 1-1):

a) apron taxiway is a taxiway located on an apron and intended either to provide a through taxi route across the apron or to gain access to an aircraft stand taxilane; and

b) aircraft stand taxilane is a portion of an apron designated as a taxiway and intended to provide access to aircraft stands only.

1.1.9 The requirements for apron taxiways regarding strip width, separation distances, etc., are the same as for any other type of taxiway. The requirements for aircraft stand taxilanes are also the same except for the following modifications:

a) the transverse slope of the taxilane is governed by the apron slope requirement;

b) the aircraft stand taxilane does not need to be included in a taxiway strip; and

c) the requirements for the separation distances from the centre line of the taxilane to an object are less stringent than those for other types of taxiways.

1.1.10 Aircraft stand lead-in lines, which branch off to the parking positions, are not considered to be a part of the aircraft stand taxilane and, therefore, are not subject to the requirements for taxiways.

1.1.11 Figure 1-2 provides a reference to the minimum separate distances as provided in Table 3-1 of Annex 14, Volume I, for each of the taxiways and taxilanes mentioned in Figure

Stages in taxiway system development

1.1.12 To minimize current construction costs, an aerodrome’s taxiway system should be only as complex as needed to support the near-term capacity needs of the runway. With careful planning, additional taxiway components can be added to the system in stages to keep pace with the growth in aerodrome demand. Different stages in taxiway system development are described in the following paragraphs (see Figure 1-3):

a) a minimum aerodrome taxiway system, supporting a low level of runway utilization, can consist of only turnaround pads or taxiway turnarounds at both ends of the runway and a stub taxiway from the runway to the apron;

b) traffic growth which results in a low to moderate level of runway utilization may be accommodated by building a partial parallel taxiway to connect one or both turnarounds (parallel taxiways provide safety benefits as well as greater efficiency);

c) as runway utilization increases, a full parallel taxiway can be provided by completing the missing sections of the partial parallel taxiway;

d) exit taxiways, in addition to the ones at each runway end, can be constructed as runway utilization increases toward saturation;

e) holding bays and bypass taxiways can be added to further enhance runway capacity. These facilities seldom restrict the attainment of full aerodrome capacity within the existing aerodrome property because land is usually available to permit their construction; and

f) a dual-parallel taxiway, located outboard of the first parallel taxiway, should be considere`d when movement in both directions along the taxiway is desirable. With this second taxiway, a one-way flow network can be established for each direction of runway use. The need for the dual-parallel system increases in proportion to the amount of development alongside the taxiway.

For additional information, see the Airport Planning Manual (Doc 9184), Part 1 - Master Planning.

Figure 1-1. Taxiways on aprons

Figure 1-2. Taxiway minimum separation distances

a) Angular turnaround

b) Circular turnaround

Figure 1-3. Turnarounds

Figure 1-3. Turnarounds (cont.)

Evaluating taxiway layout alternatives

1.1.13 An evaluation of alternative taxiway systems must take into account the operating efficiency of each system in combination with the runway and apron layouts it is designed to serve. The greater the complexity of the runway, taxiway and apron layouts, the greater the possibility for reducing operating costs through a comparison of alternative taxiway systems. Several computerized aircraft traffic flow simulation models have been developed for this purpose by consultants, aircraft operators and airport authorities.

1.1.14 For example, the United States Federal Aviation Administration has the Airfield Delay Model which simulates all significant aircraft movements performed on an aerodrome and its runway approach paths during an extended period of time. Such models are able to consider a variety of input variables such as:

- aircraft mix;

- traffic volume;

- traffic peaking;

- aerodrome layouts (taxiway and runway);

- terminal destinations of aircraft;

- runway configurations;

- taxiway configurations;

- rapid exit taxiways; and

- use of particular runways by categories of aircraft.

From these inputs, these models produce outputs for evaluation and comparison which include:

- taxiing fuel costs;

- taxiing distances;

- taxiing travel times;

- taxiing delays; and

- runway arrival anddeparture delays.

Aircraft taxi distances

1.1.15 The main reason to minimize aircraft taxi distances is to reduce taxi time and thus save fuel and enhance aircraft utilization and safety. Of particular importance are the taxi distances for the heavily loaded aircraft taxiing for take-off. Even small airports should have layouts which recognize this need.

1.1.16 At larger airports the issue of aircraft safety has greater significance. Detailed investigations have shown that when a fully laden aircraft is taxied over a distance varying from 3 to 7 km (depending upon the aircraft type, its tire size and type, and the ambient temperature), the tire carcass temperature during take-off can exceed a critical value of 120°C (250°F). Exceeding this critical temperature affects the nylon cord strength and rubber adhesion of the tire and significantly increases the risk of tire failure. The 120°C limit used in the industry applies to taxiing for take-off as well as the take-off run. At 120°C the nylon tensile strength is reduced by 30 per cent. Higher temperatures cause permanent deterioration of rubber adhesive properties. Tire failures during take-off are serious because they can result in an aborted take-off with braking being ineffective on those wheels having blown tires.

1.1.17 Taxi distances should therefore be kept to the minimum practicable. In the case of large wide-bodied aircraft, a distance of 5 km is considered to be the acceptable upper limit, and where unfavourable factors exist, such as those which require frequent use of brakes, this limit may have to be reduced.

1.1.18 Every airport master plan, irrespective of the size of the airport development, should recognize the need to minimize taxi distances, especially for departing aircraft, for both economy and safety. The suitable location of rapid exit taxiways can do much to reduce taxi distances for landing aircraft. Further, take-offs from taxiway intersections and the use of rapid exit taxiways not only reduce taxi distances and runway occupancy time but also increase runway capacity.

1.2 PHYSICAL CHARACTERISTICS DESIGN CRITERIA

General

1.2.1 Design criteria for taxiways are less stringent than those for runways since aircraft speeds on taxiways are much slower than those on runways. Table 1-1 shows the main physical characteristics design criteria recommended for a taxiway in accordance with the specifications in Annex 14, Volume I. It should be emphasized that with respect to the clearance distance between the outer main wheel of the aircraft and the edge of the taxiway, it is assumed that the cockpit of the aircraft remains over the taxiway centre line markings.

Aerodrome reference code

1.2.2 The reference code is intended to provide a simple method for interrelating the numerous specifications concerning the characteristics of aerodromes to ensure that the aerodrome facilities are suitable for the aeroplanes that are intended to operate at the aerodrome. The code is composed of two elements which are related to the aeroplane performance characteristics and dimensions. Element 1 is a number based on the aeroplane reference field length, and Element 2 is a letter based on the aeroplane wingspan.

1.2.3 A particular specification is related to the more appropriate of the two elements of the code or to an appropriate combination of the two code elements. The code letter or number within an element selected for design purposes is related to the critical aeroplane characteristics for which the facility is provided. When applying the relevant specifications in Annex 14, Volume I, the aeroplanes which the aerodrome is intended to serve are identified first followed by the two elements of the code.

1.2.4 An aerodrome reference code - a code number and a letter - selected for aerodrome planning purposes shall be determined in accordance with the characteristics of the aeroplane for which an aerodrome facility is intended. Further, the aerodrome reference code numbers and letters shall have the meanings assigned to them in Table 1 - 2. A classification of representative aeroplanes by code number and code letter is included in Appendix 3.

1.2.5 The code number for Element 1 shall be determined from Table 1-2, selecting the code number corresponding to the highest value of the aeroplane reference field lengths of the aeroplanes for which the runway is intended. The aeroplane reference field length is defined as the minimum field length required for take-off at maximum certificated take-off mass, sea level, standard atmospheric conditions, still air and zero runway slope, as shown in the appropriate aeroplane flight manual prescribed by the certificating authority or equivalent data from the aeroplane manufacturer. Accordingly, if 1 650 m corresponds to the highest value of the aeroplane reference field lengths, the code number selected would be “3”.

1.2.6 The code letter for Element 2 shall be determined from Table 1-2, selecting the code letter which corresponds to the greatest wing span of the aeroplanes for which the facility is intended.

1.2.7 The wingspan component is relevant for aerodrome characteristics related to separation distances (e.g. obstacles, strips), while outer main gear wheel span (OMGWS) components impact ground-based manoeuvring characteristics (e.g. runway and taxiway widths). The two determining components should be used separately, since using the most demanding component may cause overdesign, either for separations or runway/taxiway width for some aeroplane types. As the OMGWS is the relevant parameter for determining runway width, taxiway width and graded portion of taxiway strips, it is referenced directly in the relevant provisions to avoid the complexity of a third code element.

Table 1-2. Aerodrome reference code

Code element 1

Code number

Aeroplane reference field length

1

Less than 800 m

2

800 m up to but not including 1 200 m

3

1 200 m up to but not including 1 800 m

4

1 800 m and over

Code element 2

Code letter

Wingspan

A

Up to but not including 15 m

B

15 m up to but not including 24 m

C

24 m up to but not including 36 m

D

36 m up to but not including 52 m

E

52 m up to but not including 65 m

F

65 m up to but not including 80 m

Table 1-3. Aircraft speeds versus radius of curve

Speed

(km/h)

Radius of curve

(m)

16

15

32

60

48

135

64

240

80

375

96

540

Taxiway width

1.2.8 Minimum taxiway widths are shown in Table 1-1. The values selected for the minimum taxiway widths are based on adding clearance distance from wheel to pavement edge to the maximum OMGWS within its category.

Taxiway curves

1.2.9 Changes in direction of taxiways should be as few and small as possible. The design of the curve should be such that when the cockpit of the aeroplane remains over the taxiway centre line markings, the clearance distance between the outer main wheels of the aeroplane and the edge of the taxiway should not be less than those specified in Table 1-1.

1.2.10 If curves are unavoidable, the radii should be compatible with the manoeuvring capability and normal taxiing speeds of the aircraft for which the taxiway is intended. Table 1-3 shows values of allowable aircraft speeds for given radii of curvature based on a lateral load factor of 0.133 g (see 1.2.23). Where sharp curves are planned and their radii will not suffice to prevent wheels of taxiing aircraft from leaving the pavement, it may be necessary to widen the taxiway so as to achieve the wheel clearance specified in Table 1-1. It is to be noted that compound curves may reduce or eliminate the need for extra taxiway width.

Junctions and intersections

1.2.11 To ensure that the minimum wheel clearance distances specified in Table 1-1 are maintained, fillets should be provided at junctions and intersections of taxiways with runways, aprons and other taxiways. Information on the design of fillets is given in 1.5.

Taxiway minimum separation distances

General

1.2.12 The separation distance between the centre line of a taxiway and the centre line of a runway, another taxiway or an object should not be less than the appropriate dimension specified in Table 1-1. It may, however, be permissible to operate with lower separation distances at an existing aerodrome if an aeronautical study indicates that such lower separation distances would not adversely affect the safety or significantly affect the regularity of operations of aeroplanes. Guidance on factors which may be considered in the aeronautical study is given in 1.2.29 through 1.2.67.

1.2.13 The distances are based on the maximum wing span of a group and on the deviation of one aircraft from the taxiway centre line a distance equal to the wheel-to-edge clearance and the increment (Z) for that group. It should be noted that, even in instances where a particular aircraft design (as a result of an unusual combination of large wing span and narrow gear span) might result in the wing tip extending farther from the centre line distance, the resulting clearance distance would still be considerably more than that required for aircraft to pass.

Separation distances between taxiways, and between taxiways and objects

1.2.14 Formulas and separation distances are shown in Table 1-4 and illustrated in Figure 1-4. The separation distances related to taxiways and apron taxiways are based on the aircraft wing span (Y) and the maximum lateral deviation (X) (the wheel-to-edge clearance specified in Table 1-1).

Table 1-4. Minimum separation distances between taxiways and between taxiways and objects (dimensions in metres)

Code letter

Separation distances

A

B

C

D

E

F

Between apron taxiway/taxiway centre line and apron taxiway/taxiway centre line:

wing span (Y)

15.0

24.0

36.0

52.0

65.0

80.0

+ maximum lateral deviation (X)

1.5

2.25

3.0

4.0

4.0

4.0

+ increment (Z)

6.5

5.75

5.0

7.0

7.0

7.0

Total separation distance (V)

23.0

32.0

44.0

63.0

76.0

91.0

Between apron taxiway/taxiway centre line and object:

1/2 wing span (Y)

7.5

12.0

18.0

26.0

32.5

40.0

+ maximum lateral deviation (X)

1.5

2.25

3.0

4.0

4.0

4.0

+ increment (Z)

6.5

5.75

5.0

7.0

7.0

7.0

Total separation distance (V)

15.5

20.0

26.0

37.0

43.5

51.0

Between aircraft stand taxilane centre line and aircraft stand taxilane centre line

wing span (Y)

15.0

24.0

36.0

52.0

65.0

80.0

+ gear deviation

1.5

1.5

1.5

2.5

2.5

2.5

+ increment (Z)

3.0

3.0

3.0

5.0

5.0

5.0

Total separation distance (V)

19.5

28.5

40.5

59.5

72.5

87.5

Between aircraft stand taxilane centre line and object:

1/2 wing span (Y)

7.5

12.0

18.0

26.0

32.5

40.0

+ gear deviation

1.5

1.5

1.5

2.5

2.5

2.5

+ increment (Z)

3.0

3.0

3.0

5.0

5.0

5.0

Total separation distance (V)

12.0

16.5

22.5

33.5

40.0

47.5

1.2.15 Lesser distances on aircraft stand taxilanes are considered appropriate because taxiing speeds are normally lower when taxiing on these taxiways, and the increased attention of pilots results in less deviation from the centre line. Accordingly, instead of assuming an aircraft is off the centre line as far as the maximum lateral deviation (X) would allow, a lesser distance is assumed which is referred to as “gear deviation”.

1.2.16 It may be noted that two factors have been used in the development of the formulas: the maximum lateral deviation/gear deviation and the wing tip clearance increment. These factors have different functions. The deviation factor represents a distance that aircraft might travel in normal operation. On the other hand, the increment (Z in Figure 1-4) is a safety buffer intended to avoid accidents when aircraft go beyond the taxiway, to facilitate taxiing by providing extra space, and to account for other factors influencing taxiing speeds.

1.2.17 A graduated increment scale rather than a constant increment for all code letters has been selected because:

a) pilot judgement of clearance distance is more difficult in aircraft with larger wing spans, particularly when the aircraft has swept wings; and

b) the momentum of larger aircraft may be higher and could result in such aircraft running farther off the edge of a taxiway.

1.2.18 The increments for the determination of the separation distances between an apron taxiway and an object are the same as those proposed between a taxiway and an object, the reason being that although apron taxiways are associated with aprons, it is thought that their location should not imply a reduction in taxiing speed. Aircraft will normally be moving at slow speeds on an aircraft stand taxilane and can therefore be expected to remain close to the centre line. A deviation of 1.5 m has been selected for code letters A to C. A deviation of 2.5 m has been adopted for code letters D to F. The use of a graduated scale for lateral deviation in a stand taxilane is considered appropriate since the ability of a pilot to follow the centre line is decreased in larger aircraft because of the cockpit height.

U = Main gear span

X = Maximum lateral deviation

V = Separation distance

Y = Wing span

W = Taxiway width

Z = Increment

Figure 1-4. Separation distance to an object

1.2.19 Larger increments have been selected for the separation distances between taxiway/object and apron taxiway/object than for other separation distances. These larger increments are considered necessary because normally objects along such taxiways are fixed objects, thus making the probability of a collision with one of them greater than that of one aircraft running off the taxiway just as another aircraft is passing that point on the parallel taxiway. Also, the fixed object may be a fence or wall which runs parallel to the taxiway for some distance. Even in the case of a road running parallel to a taxiway, vehicles may unknowingly reduce the clearance distance by parking off the road.

Separation distances between taxiways and runways

1.2.20 The separation distances are based on the concept of the wing of an aircraft centred on a parallel taxiway remaining clear of the associated runway strip. The formulas and separation distances are shown in Table 1 -5. The separation distance between the centre lines of a runway and a parallel taxiway is based on the accepted principle that the wing tip of an aeroplane taxiing on the parallel taxiway should not penetrate the associated runway strip. However this minimum separation distance may not provide adequate length for the link taxiway connecting the parallel taxiway and the runway to permit safe taxiing of another aircraft behind an aircraft holding short of the runway at the holding position. To permit such operations, the parallel taxiway should be so located as to comply with the requirements of Annex 14, Volume I, Tables 3-1 and 3-2, considering the dimensions of the most demanding aeroplane in a given aerodrome code. For example, at a code E aerodrome, this separation would be equal to the sum of the distance of the runway holding position from the runway centre line, plus the overall length of the most demanding aeroplane, and the taxiway-to-object distance specified in column E of Table 1-1.

Table 1-5. Minimum separation distances between taxiway/apron taxiway centre line and runway centre line (dimensions in metres)

Code number

1

2

3

4

A

B

A

B

A

B

C

D

C

D

E

F

1/2 wing span (Y)

+ 1/2 strip width

7.5

12

7.5

12

7.5

12

18

26

18

26

32.5

40

(non-instrument approach runway)

30

30

40

40

75

75

75

75

75

75

75

75

Total

37.5

42

47.5

52

82.5

87

93

101

93

101

107.5

115

or 1/2 wing span (Y)

7.5

12

7.5

12

7.5

12

18

26

18

26

32.5

40

+ 1/2 strip width

(instrument approach runway)

70

70

70

70

140

140

140

140

140

140

140

140

Total

77.5

82

77.5

82

147.5

152

158

166

158

166

172.5

180

Parallel taxiway geometry

1.2.21 The separation distances between parallel taxiways shown in Table 1-1 have been selected on the basis of desired wing tip clearances. There are other factors which should also be taken into account when evaluating the capability of making a normal 180-degree turn from one taxiway to another parallel taxiway. These include:

a) maintaining a reasonable taxi speed to achieve high taxiway system utilization;

b) maintaining specified clearance distances between the outer main wheel and the taxiway edge when the cockpit remains over the taxiway centre marking; and

c) manoeuvring at a steering angle that is within the capability of the aircraft and which will not subject the tires to unacceptable wear.

1.2.22 To evaluate the taxi speed when making the 180-degree turn, it is assumed that the radii of curvature are equal to one-half of the separation distance indicated in Table 1-1, and as shown below:

Code letter

Radius (m)

A

11.5

B

16.0

C

22.0

D

31.5

E

38.0

F

45.5

1.2.23 The velocity in the turn is a function of the radius of the curve (R) and the lateral load factor (f). Thus, if it is assumed that the lateral load factor is limited to 0.133 g:

V = (127.133 x (f) x R)1/2

= (127.133 x 0.133 R) 1/2

= 4.1120( R1/2),

where R is in metres.

The resulting allowable velocities are shown in Table 1-6.

1.2.24 Examination of Table 1-6 shows that a velocity of 25.4 km/h is achieved for code letter E. In the case of code letter F, the velocity would be 27.7 km/h. To achieve the same speed on taxiways associated with the other code letters, a separation distance of 80 m would be required. The separation distances for code letters A and B, however, may be unreasonably large when compared with those required by the desired wing tip clearance. In this connection, experience shows that small aircraft require a slower speed than larger aircraft because of their sensitivity to nose gear swivelling.

1.2.25 To evaluate the factors mentioned in 1.2.21 b) and c), a computer programme was developed by an aircraft manufacturer to show the motion of an aircraft during a 180-degree turn. A representative aircraft from each code letter was used (see Table 1-6). These aircraft were chosen for illustrative purposes because they have the greatest distance between the main gear and the cockpit of the aircraft within each code. The radius of the curve for each case is based on one-half of the minimum separation distance.

1.2.26 The ability to make a smooth turn depends, in part, on the allowable steering angle. Table 1-7 provides data for the representative aircraft. (The data shown in the last column are based on the data of Table 1 -6 and assume 3-degree nose tire slip for Lear 55, F28 and MD80, and 5-degree nose tire slip for MD11 and B747.) The study revealed that the maximum angle required during the turn is within the limits given in Table 1-7 for all aircraft.

1.2.27 The solution for a 180-degree turn, which was arrived at by use of a computer programme, can also be determined by graphical means. The procedure requires a step-by- step movement of the cockpit along the centre line of the curve. The main gear is assumed to travel along a line that is formed by the original position of the mid-point between the main gear and the new position of the cockpit. This is illustrated in Figure 1-5.

1.2.28 It is significant to note that the computer programme results were based on increments of movement of 0.5 degrees. This is much too tedious for a graphical solution, and a comparison was made of the computer programme solution with a graphical solution in which the increments were 10 degrees. It was concluded that an error of approximately 2.4 m is introduced by the coarser increments of the graphical method. Increments of 5 degrees will reduce the error to approximately 1.5 m.

Table 1-6. Assumed data for calculation of 180-degree turn

Radius of curvature

(m)

Main gear to cockpit

(m)

Velocity
V = 4.1120 (R
1/2)
(km/h)

Code letter

Critical aircraft mode

A

11.5

Lear 55

5.7

14.0

B

16.0

F28

11.9

16.5

C

22.0

MD80

20.3

19.3

D

31.5

MD11

31.0

23.1

E

38.0

A340-600

37.4

25.4

E

38.0

B747

27.8

25.4

E

38.0

B777-300

34.2

25.4

F

45.5

A380

31.9

27.7

Table 1-7. Aircraft steering angles

Maximum steering angle

Approx. steering angle during 180-degree turn

Aircraft model

Lear 55

55°

40°

F28

76°

45°

MD80

82°

65°

MD11

A340-600

72°

75°

70°

70°

B747

70°

50°

B777-300

70°

65°

A380

70°

45°

Figure 1-5. Graphical solution of a 180-degree turn

Radius of curvature
and path of cockpit

Aeronautical study relating to minimum separation distances

Introduction

1.2.29 The aim of the specifications in Annex 14, Volume I, is to give aerodrome planners a tool to design efficient aerodromes for safe aircraft operations. It is not intended, however, that the Annex be used to regulate aircraft operations. It may be permissible to operate at existing aerodromes with lower taxiway separation distances than those specified in the Annex if an aeronautical study indicates that such lower separation distances would not adversely affect the safety or significantly affect the regularity of operations of aircraft. The purpose of this material is to assist States in undertaking an aeronautical study by defining the criteria considered pertinent for the assessment of whether lesser dimensions than those specified in Annex 14, Volume I, Table 3-1 (reproduced in Table 1-1) are adequate for the operation of new larger aeroplanes in the specific operational environment at an existing aerodrome. This may also result in operational restrictions or limitations. Where alternative measures, operational procedures and operating restrictions have been developed, their details are reproduced in the aerodrome manual and reviewed periodically to assess their continued validity. It is expected that infrastructure on an existing aerodrome or a new aerodrome will fully comply with Annex 14, Volume I, specifications at the earliest opportunity. Further guidance to assess the compatibility of the operation of a new aeroplane with an existing aerodrome can be found in the Procedures for Air Navigation Services (PANS) - Aerodromes (Doc 9981).

Objectives and scope

1.2.30 The prime objective of an aeronautical study is to assess the adequacy of the protection provided by the existing layout for the operation of the critical aircraft with respect to:

a) collision with another aircraft, vehicle or object;

b) run-off from paved surfaces; and

c) engine damage from ingestion.

1.2.31 The areas of concern which this assessment will address relate to specific functional requirements in terms of:

a) Distance between centre line of runway and centre line of taxiway;

b) Distance between centre line of taxiway and centre line of parallel taxiway;

c) distance between centre line of taxiway and object;

d) distance between centre line of aircraft stand taxilane and object;

e) runway and taxiway dimensions, surface and shoulders; and

f) protection of engines against damage from foreign objects.

It should be noted that every operational factor listed above need not be considered in all instances. Therefore, the appropriate authority should determine which factors are relevant to a risk analysis for a specific site. Additionally, the appropriate authority should define the parameters for each of the operational factors selected and assign a hierarchy of values to each of them, based upon subjective operational and engineering judgements.

Basic considerations

1.2.32 Operational experience with large aircraft at aerodromes not designed to the specifications dictated by that aircraft type has shown that a safe and regular operation is feasible, though subject to specific measures being implemented (the use of selected taxi routings, designated aircraft stand taxilanes, etc.). This may be due to the fact that a variety of adverse factors do not necessarily affect the operational environment at a certain aerodrome. Furthermore, analyses of accidents and incidents do not indicate that they are caused by inadequate margins that do not meet the specifications in Annex 14, Volume I. It may thus be assumed that the above considerations similarly apply to the operation of new larger aeroplanes, subject to the conditions resulting from the aeronautical study.

Assessment aspects

1.2.33 An aeronautical study will consist essentially of a risk analysis based on pertinent criteria to assess:

a) probability of collision;

b) probability of run-off; and

c) risk of engine ingestion.

The majority of criteria being qualitative in nature, the assessment of risk levels cannot be expressed in absolute or quantitative terms. For the outcome of the study to be meaningful, it should be complemented by operational and engineering judgements. This suggests that the appropriate authority should consult with the aircraft operator when carrying out the assessment.

1.2.34 Referring to collision risk assessment, which addresses the separation/clearance distances provided, the relative risk level on the movement area (expressed in terms of probability of a collision to occur) is generally considered to increase in the following order of priority:

runway → taxiway → apron taxiway → aircraft stand taxilane

The increase in risk is attributed to:

a) decreasing accounting for aircraft deviations from the centre line/guideline and associated incremental margins;

b) increasing density of vehicles and objects; and

c) increasing complexity of layouts giving rise to pilot distraction, confusion, misinterpretation, etc.

1.2.35 A crucial criterion for assessing the adequacy of existing separation/clearance distances for safe and regular operation of new larger aeroplanes is the accuracy with which aircraft taxi relative to the centre line/guideline on runways and taxiways:

a) on straight portions; and

b) on taxiway curves.

1.2.36 The following factors can impact on the accuracy or safety achieved in day-to- day operational environments and require, therefore, a detailed examination as applicable:

a) quality of aircraft nose wheel guidelines (marking and lighting);

b) quality of signs;

c) visibility conditions;

d) day or night;

e) surface state (dry, wet, contaminated by snow/ice);

f) taxi speed;

g) pilots’ attention;

h) pilots’ technique of negotiating turns;

i) wind effects (cross-wind); and

j) aircraft handling characteristics.

1.2.37 The provision of taxiing guidance, i.e. marking, lighting and signs which are adequately conspicuous in all operational conditions, together with good surface friction conditions, is considered paramount for achieving a high degree of taxiing accuracy. This is substantiated by the fact that the pilot of a large aeroplane, being unable to see the wing tips, will have to rely primarily on taxiing guidance, the accurate tracking of which will guarantee proper wing tip clearance.

1.2.38 Good surface friction characteristics are required because nose wheel steering effectiveness can become significantly degraded with large aeroplanes whenever the surface is other than dry, thereby challenging the execution of controlled turns. This is particularly true in the presence of a strong cross-wind.

1.2.39 The rationale used for determining separation distances for code letters E and F assumes a lateral deviation value of 4.0 m from the centre line for taxiways/apron taxiways on either straight or curved portions. For aircraft stand taxilanes the respective value is 2.5 m and is referred to as gear deviation.

1.2.40 Taxiway deviation studies, using a representative mix of aircraft types including large aeroplanes, were conducted at London/Heathrow and Amsterdam/Schiphol airports (see Appendix 4). Results suggest that in favourable operating conditions (i.e. positive guidance provided by centre line lighting and marking and good surface friction characteristics), the mean deviation of main gears of aircraft from the centre line on straight taxiway portions is less than 4.5 m. It should be noted here, however, that the value of maximum deviation of main gears of most aircraft reached the 8 to 10 m range depending on aircraft type. With these provisions, a reduction of the deviation value accounted for in an aeronautical study may be acceptable relative to straight portions of taxiways, whereas the specified value should be retained if the above conditions are not met.

1.2.41 For taxiway curves, however, the situation is somewhat different. A fixed deviation of 4.0 m seen as adequate for defining separation/clearance distances does not account for the natural main gear track-in which results from the cockpit following the centre line. For new larger aeroplanes, the track-in allowance may be inadequate for the smaller turn radii of taxiways. Therefore, a detailed evaluation will be required to determine the path followed by the wing tip on the inside of the turn. For a detailed study involving other new larger aeroplanes, it may be necessary to consult the aircraft manufacturers.

1.2.42 Design specifications are based on the assumption that, in taxiway curves, the cockpit is following the centre line of the taxiway. In day-to-day operations, however, pilots frequently use the straight-through or oversteering technique. This alternative practice may be taken into account when contemplating operations with reduced separation/clearance distances. This may apply, for example, in the case of curved parallel taxiways with the aircraft on the outer taxiway using the cockpit over the centre line technique while the aircraft on the inner taxiway applies the oversteering technique (e.g. main gear centre over centre line). Other measures of importance are taxiway turn fillet size and wing tip clearance in the terminal areas.

1.2.43 Apart from assessing the adequacy of separation/clearance distances given the relatively small deviations anticipated in normal operation, the aeronautical study may further require an assessment of the probability of collision due to large inadvertent excursions including run-offs from the paved surface.

1.2.44 Inadvertent excursions are guarded against by using an appropriate safety buffer (increment Z) which, however, does not make a differentiation with regard to the degree of risk involved. Accordingly, it may be assumed that the specified margins will provide adequate protection against a large variety of unfavourable operational factors.

1.2.45 When contemplating lesser margins, the study will have to determine the relative probability of collision for the particular operational environment at the aerodrome concerned. This entails an assessment of the total risk, composed of:

a) the risk of run-offs; and

b) exposure to collision risks;

and for which separate criteria will apply:

for a):

- surface friction conditions

- taxi speed

- straight or curvedtaxiway

- taxi-in or taxi-out;

for b):

- type of object (fixed/mobile)

- extent or density of objects

- affected part of the movement area.

1.2.46 Expressed in practical terms, the run-off risk is considered to increase with poor surface friction characteristics (snow/ice) where taxi speeds are relatively high, especially in taxiway curves. The exposure to collision risks increases with the aircraft moving from the runway to the apron due to the increase in object density (fixed and mobile) and the smaller margins provided. In a favourable operational environment, however, it may be determined that the probability of collision is extremely remote or improbable and therefore lesser separation/clearance distances are acceptable. This may apply for an isolated object located along a straight taxiway, low taxi speeds and good surface friction characteristics being prevalent.

Considerations related to specific functional requirements

Runway/taxiway separation distances

1.2.47 The main principle governing runway/taxiway separation distances is that the wing tip of a taxiing aeroplane should not penetrate the strip of the associated runway. Other major aspects requiring consideration concern the protection of an aircraft that has inadvertently run off a runway against collision with another aircraft taxiing on a parallel taxiway and the protection of the ILS critical and sensitive areas against interference from radio navaids. The risk of a collision occurring is essentially governed by:

a) the probability of a run-off, and

b) the exposure to collision risks,

and would have to be assessed in a study for the particular operational environment existing at the aerodrome concerned.

1.2.48 There is statistical evidence that run-offs occur for a variety of causal factors and with different degrees of lateral deviation from the runway centre line. The risk of runway run-offs is significantly due to:

a) environmental factors:

- poor runway surface characteristics

- strong cross-wind/gusts/wind shear;

b) aircraft operation factors:

- human

- technical failures/malfunctions (steering/tire/brake/reverse thrust failures).

1.2.49 While factors related to aircraft operation are in general unpredictable, the environmental factors are subject to control or monitoring by the appropriate authority so that overall risks can be minimized. Furthermore, the exposure to collision risks is largely affected by the magnitude of lateral deviation from the runway centre line and the traffic density.

1.2.50 Guidance on grading of strips for precision approach runways, taking into account lateral deviations, is provided in Annex 14, Volume I, Attachment A, 9.3 and Figure A-4. Relating the lateral dimensions to the existing separation distance may assist in assessing the relative exposure to collision risks. For lesser separation distances than those specified in Annex 14, Volume I, however, it would appear advisable to make efforts to minimize run-off risks through effective control and reporting of runway surface friction characteristics and reliable reporting of wind conditions. Accordingly, aircraft operators can contribute to minimizing run-off risks by applying operational restrictions commensurate with reported conditions.

Taxiway/taxiway separation distances

1.2.51 The separation distances specified for parallel taxiways are intended to provide a safe wing tip clearance by accounting for the anticipated deviation of a manoeuvring aircraft from the taxiway centre line, in terms of:

a) taxiing accuracy achieved in day-to-day operation; and

b) inadvertent excursions/run-offs.

A study on whether lesser distances provide adequate safety margins in the operational environment of an existing aerodrome layout will require an assessment of the risk of collision which, owing to different levels involved, should be related to:

a) straight parallel taxiways; and

b) taxiway curves.

In either case, the risk of collision between two aircraft on parallel taxiways is determined primarily by the probability of an inadvertent major excursion by an aircraft from the taxiway centre line.

2.2.52 In contrast, taxiing accuracy per se is not considered to affect the collision risk to a critical extent in the case of straight parallel taxiways.

2.2.53 On taxiway curves, however, taxiing accuracy becomes a critical element in terms of collision risks for the various reasons outlined in 1.2.33 through 1.2.46. Accordingly, the trajectories of the wing tips of two large aircraft must be established.

2.2.54 When contemplating lesser separation distances, careful consideration must be given to the various factors affecting taxiing accuracy (1.2.33 through 1.2.46), in particular taxiway curves. In this regard, the maintenance of good surface friction characteristics under all environmental circumstances is considered a dominant prerequisite for minimizing:

a) lateral deviations through proper nose-wheel steering and wheel-braking effectiveness; and

b) risks of run-off.

Accordingly, the overall risk would be reduced essentially to the possibility of inadvertent major excursions resulting from unpredictable technical failures affecting the steering capability of an aircraft (e.g. nose-wheel steering). The assessment of the overall risk would thus consist of:

a) the probability of occurrence of a technical failure leading to a major excursion; and

b) the exposure to collision risks subject to traffic density.

In the case of a) above, however, there is no indication that the probability rate of mechanical failures would be significant.

Taxiway/object separation distances

2.2.55 The risk considerations and the prerequisites related to reduced separation distances as outlined in 1.2.51 through 1.2.54 will similarly apply when assessing the adequacy of actual separation distances between the taxiway centre line and objects at an existing aerodrome. As far as the exposure to risks of collision is concerned, particular attention appears warranted with respect to:

a) the nature of objects (fixed or mobile);

b) their size (isolated or extended); and

c) their location relative to straight portions of taxiways or taxiway curves.

2.2.56 It is reiterated that obstacles situated close to taxiway curves and adjacent areas will require particular examination. This includes not only consideration of wing tip clearances but also the possibility of impingement of jet wake on the object as a result of aircraft changing direction at an intersection.

Apron taxiway/object separation distances

2.2.57 In general, the apron is considered an area of high activity involving a changing pattern of obstacles of fixed/mobile and permanent or temporary nature in a variable operating environment. Accordingly, aircraft operating along an apron taxiway may be exposed to incomparably higher risks of collision as compared to aircraft taxiing on a standard taxiway, margins accounted for by the formula in terms of deviation and increment being the same. This is actually evidenced by the comparatively high rate of reported incidents occurring on aprons, which is a matter of continuing concern. There is, however, no indication of the incidents being related to basic inadequacies of the specified minimum separation distances.

2.2.58 Nevertheless, it may be reasonably assumed that at an aerodrome where lesser separation is provided, there is increased potential for incidents to occur unless a set of specific requirements relating to all critical elements involved in apron activities is fulfilled.

2.2.59 Risks of collision relate predominantly to mobile objects which may infringe upon clearance distances relative to taxiing aircraft. Accordingly, a basic requirement would be to segregate the operating area of an aircraft from the respective area intended to be used by mobile objects (e.g. servicing vehicles and equipment facilities). Specifically this would include:

a) for the aircraft:

- taxi guidelines (marking and lighting);

b) for mobile objects:

- apron safety lines (see Annex 14, Volume I, Chapter 5)

- service road boundary lines

- procedures and regulations to ensure discipline.

1.2.60 Concerning taxi guidance on aprons, it is of paramount importance, in order to minimize the risk of major excursions, that the pilot be provided with a conspicuous and unambiguous guideline which is visible continuously in all prevailing operating conditions. This guideline is crucial for pilots of large aircraft who, being unable to routinely observe the wing tip and having difficulty judging small clearances, must follow the designated guidelines as closely as practicable. While doing so, pilots will have to rely on safe taxiing at normal taxi speed.

1.2.61 To ensure accurate manoeuvring and prevent large deviations, when nose-wheel steering or braking effectiveness is marginal, the provision of good surface friction characteristics is important, especially when high cross-winds are encountered.

Aircraft stand taxilane/object separation distances

1.2.62 The preceding apron-oriented risk aspects and functional requirements are equally valid for separation distances between aircraft stand taxilane centre lines and objects.

1.2.63 From an operational point of view, the separation distance as specified by the formula in terms of a reduced gear deviation allowance and safety buffer is rated as rather marginal relative to an operating environment where the exposure to collision risks is normally greatest and the accuracy of aircraft manoeuvring is most demanding. Reducing the specified values, therefore, should be considered as a last resort only, conditional to a study scrutinizing all risk aspects discussed in this section as applicable to the most unfavourable operating conditions representative of the aerodrome concerned. In conducting the study, consultation with the aircraft operator is essential to ascertain whether the operational aircraft parameters assumed in the study are realistic.

Taxiway dimensions, surface and shoulders

1.2.64 An aeronautical study should further examine the level of protection provided by existing physical layouts against run-offs from taxiway pavements. This relates primarily to the width of taxiways and associated wheel-to-edge clearances.

Width of taxiways. The specified wheel-to-edge clearance of 4.0 m for code letters E and F is considered a minimum. Accordingly, the width of taxiways should provide this clearance, in particular on curves and at intersections. As a minimum, the width of taxiways should be equal to the sum of the wheel-to-pavement edge clearance on both sides plus the maximum outer main gear span for the code letter.

Protection of engines against foreign object damage

1.2.65 The degree of damage caused to engines from ingesting foreign objects is substantial and, therefore, a matter of continuing concern. As new larger aeroplanes are equipped with more powerful engines, the problem is likely to be aggravated. Protection of the taxiway shoulders extending laterally at least to the inner engine is therefore needed. Similarly, it should be ascertained whether the type of surface of the shoulder is adequate to resist erosion from engine blast.

1.2.66 At airports subjected to snow and ice conditions, the problem caused by foreign object damage is particularly critical on the entire movement area. The extent to which snow/ice clearance is carried out will determine the risk level not only for foreign object damage but likewise for run-offs.

Notification

1.2.67 When recommended clearance distances are not provided at certain locations of the movement area at a particular airport, this should be appropriately identified in the Aerodrome/Heliport Chart - ICAO (Annex 4, Chapter 13 refers) for operational evaluation by aircraft operators and pilots.

The effect of new larger aeroplanes on existing airports

1.2.68 To meet the needs of an ever-changing aviation industry, succeeding generations of larger aeroplanes have been introduced. Experience gained through the introduction of these aeroplanes has taught airport planners that adequate planning in the initial design of an airport is vital. However, in spite of the best efforts of airport planners, a facility developed for the current generation of aeroplanes may not be adequate for succeeding generations. In order to minimize any impact on capacity, airports would need to be expanded and developed to accommodate such new larger aeroplanes.

1.2.69 With a view to complying with applicable specifications, airport planners and engineers have to explore all avenues while undertaking the rehabilitation of existing facilities. Often, after due consideration of all options, the physical limitations of the existing facilities may leave the airport operator with no choice but to implement operational restrictions stemming from a compatibility study conducted in accordance with the provisions in Annex 14, Volume I. Further procedures outlining the compatibility between aeroplane operations and aerodrome infrastructure and operations when an aerodrome accommodates an aeroplane that exceeds the certificated characteristics of the aerodrome are available in the Procedures for Air Navigation Services (PANS) - Aerodromes (Doc 9981).

Taxiway minimum separation distances

1.2.70 As stated in 1.2.47, the main principle governing runway/taxiway separation distances is that the wing tip of a taxiing aeroplane should not penetrate the strip of the associated runway. Care must be taken to ensure that the increased wingspan of a new larger aircraft does not increase the risk of collision with another aircraft taxiing on a parallel taxiway if the larger aircraft inadvertently runs off a runway, and that ILS critical and sensitive areas are protected. Where the wingspan of an aeroplane on a taxiway penetrates the associated runway strip of a parallel runway, appropriate operational restrictions, such as the taxiway not being used by an aeroplane of such large wingspan when the runway is occupied, will have to be considered. In most cases, to maintain aerodrome capacity, simultaneous operations of smaller aeroplanes that would not infringe upon the separations of the more demanding aeroplanes may be considered. For instance, at existing aerodromes with runway and taxiway separation distances complying with code letter E specifications, it may be permissible to operate a code letter E or smaller aeroplane on the existing parallel taxiway while a code letter F aeroplane is using the runway.

1.2.71 However, the minimum separation distance between a runway and a parallel taxiway may not provide adequate length for a link taxiway, connecting the parallel taxiway and the runway, to permit safe taxiing of an aircraft behind an aircraft holding short of the runway at the holding position due to either the larger wingspan of the taxiing aeroplane or the fuselage length of the holding aeroplane or both. To permit such operations, the parallel taxiway should be so located as to comply with the requirements of Annex 14, Volume I, Tables 3-1 and 3-2, considering the dimensions of the most demanding aeroplane in a given aerodrome code. For example, this separation would be equal to the sum of the distance of the runway holding position from the runway centre line, plus the overall length of the most demanding aeroplane, and the taxiway-to-object distance specified in column E of Table 1-1.

1.2.72 At issue is the need to provide adequate clearances on an existing airport in order to operate a new larger aircraft with the minimum risk possible. If the clearance distances given Annex 14, Volume I, cannot be met, then an aeronautical study should be conducted to ensure operational safety and to ascertain what, if any, operational restrictions must be implemented to maintain safety (see Figure 1-6).

1.2.73 In order to minimize such restrictions, when a new facility is planned for addition to the existing airport infrastructure, it would be prudent to apply the basic clearance distance concept adopted in the development of the specifications found in Annex 14, Volume I. An example of the application of this concept would be:

An airport with an aerodrome reference code E is planning to develop a new link taxiway for code F operations, adjacent to an existing code E taxiway. What should be the separation between them?

If both taxiways are to be used for simultaneous code F aeroplane operations (provided all other relevant requirements are satisfactorily met) then the minimum separation distance should be that specified for code F in Annex 14, Volume I, Table 3-1, column 10.

If the existing taxiway is to be used by code E aircraft only, then the new code F taxiway may be located as follows:

Minimum separation distance: (1/2 WSe + 1/2 WSf) + C + Zf where ws is the wing span, C is the applicable wheel-to-pavement edge clearance (4.0 m in this case) and Zf is the safety margin (7.0 m) for the most demanding code.

In this example, airport capacity may be slightly reduced should there be a need for two code F aeroplanes to use these taxiways simultaneously since the existing taxiway is not in accordance with code F specifications. Where such a philosophy is implemented with respect to other facilities, a similar approach may be adopted, provided the values of the wheel-to- taxiway edge clearance and wing tip clearance used are those for the higher code letter.

Apron size and capacity, stand clearances and taxiing on aprons

1.2.74 Larger wingspan and the potential for greater fuselage length of code F aeroplanes will have a direct bearing on how many of these aeroplanes can be accommodated on existing aprons and where they can be accommodated. For codes D, E and F aeroplanes, existing stands should provide clearances of 7.5 m as specified in Annex 14, Volume I. Existing stands that are unable to provide such clearances will need to be modified. Where physical constraints preclude such modifications, operational restrictions may have to be developed to ensure safe operations.

1.2.75 Adequate clearances behind parked or holding aeroplanes should also be provided. This issue is impacted not only by the wingspan of the taxiing aeroplanes but also the fuselage length of the parked aeroplanes. While the wingspan is a defining criterion, the fuselage length of these aeroplanes will also have a direct bearing on their effect on other taxiing aeroplanes. Therefore, while aeroplanes with a larger wingspan may be faced with operational restrictions due to their wingspans, it may be also necessary to implement operational restrictions in those cases where the increased fuselage length of an aircraft may cause reduced clearances with other taxiing aircraft.

Figure 1-6. Taxiway to taxiway separation distances

1.3 RAPID EXIT TAXIWAYS (RETS)

General

1.3.1 A rapid exit taxiway is a taxiway connected to a runway at an acute angle and designed to allow landing aeroplanes to turn off at higher speeds than those achieved on other exit taxiways, thereby minimizing runway occupancy time.

1.3.2 A decision to design and construct a rapid exit taxiway is based upon analyses of existing and contemplated traffic. The main purpose of these taxiways is to minimize aircraft runway occupancy and thus increase aerodrome capacity. When the design peak-hour traffic density is approximately less than 25 operations (landings and take-offs), the right angle exit taxiway may suffice. The construction of this right angle exit taxiway is less expensive, and when properly located along the runway, achieves an efficient flow of traffic.

1.3.3 The establishment of a single worldwide standard for the design of rapid exit taxiways has many obvious advantages. Pilots become familiar with the configuration and can expect the same results when landing at any aerodrome with these facilities. Accordingly, design parameters have been established in Annex 14, Volume I, for a grouping of exit taxiways associated with a runway whose code number is 1 or 2 and another grouping for code number 3 or 4. Since the introduction of rapid exit taxiways, additional field tests and studies have been conducted to determine taxiway utilization, exit taxiway location and design, and runway occupancy time. Evaluation of such material has led to the development of exit taxiway location and design criteria based on specified aircraft populations moving at relatively high speeds.

1.3.4 There is some difference of opinion with respect to the speed at which pilots negotiate rapid exit taxiways. While it has been inferred from some studies that these taxiways are normally used at a speed not higher than 46 km/h (25 kt) and even in some cases at lower speeds when poor braking action or strong cross-winds are encountered, measurements at other aerodromes have shown that they are being used at speeds of over 92 km/h (49 kt) under dry conditions. For safety reasons 93 km/h (50 kt) has been taken as the reference for determining curve radii and adjacent straight portions for rapid exit taxiways where the code number is 3 or 4. For computing the optimum exit locations along the runway, however, the planner will choose a lower speed. In any case, the optimum utilization of rapid exits requires pilot cooperation. Instruction on the design of, and benefits to be obtained from use of, these taxiways may increase their use.

Location and number of exit taxiways

Planning criteria

1.3.5 The following basic planning criteria should be considered when planning rapid exit taxiways to ensure that, wherever possible, standard design methods and configurations are used:

a) for runways exclusively intended for landings, a rapid exit taxiway should be provided only if dictated by the need for reduced runway occupancy times consistent with minimum inter-arrival spacings;

b) for runways where alternating landings and departures are conducted, time separation between the landing aircraft and the following departing aircraft is the main factor limiting runway capacity;

c) as different types of aircraft require different locations for rapid exit taxiways, the expected aircraft fleet mix will be an essential criterion; and

d) the threshold speed, braking ability and operational turn-off speed (Vex) of the aircraft will determine the location of the exits.

1.3.6 The location of exit taxiways in relation to aircraft operational characteristics is determined by the deceleration rate of the aircraft after crossing the threshold. To determine the distance from the threshold, the following basic conditions should be taken into account:

a) threshold speed; and

b) initial exit speed or turn-off speed at the point of tangency of the central (exit) curve (point A, Figures 1-7 and 1-8).

Figure 1-7. Design for rapid exit taxiways (code number 1 or 2)

Figure 1-8. Design for rapid exit taxiways (code number 3 or 4)

Design, location and number of rapid exit taxiways

1.3.7 Determining the optimum location and required number of rapid exit taxiways to suit a particular group of aeroplanes is recognized as a comparatively complex task owing to the many criteria involved. Although most of the operational parameters are specific to the type of aircraft with respect to the landing manoeuvre and subsequent braked deceleration, there are some criteria which are reasonably independent of the type of aircraft.

1.3.8 Accordingly, a methodology, known as the Three Segment Method, was developed which permits the determination of the typical segmental distance requirements from the landing threshold to the turn-off point based on the operating practices of individual aircraft and the effect of the specific parameters involved. The methodology is based on analytical considerations supplemented by empirical assumptions, as described below.

1.3.9 For the purpose of exit taxiway design, the aircraft are assumed to cross the threshold at an average of times the stall speed in the landing configuration at maximum certificated landing mass with an average gross landing mass of about 85 per cent of the maximum. Further, aircraft can be grouped on the basis of their threshold speed at sea level as follows:

Group A - less than 169 km/h (91 kt)

Group B - between 169 km/h (91 kt) and 222 km/h (120 kt)

Group C - between 224 km/h (121 kt) and 259 km/h (140 kt)

Group D - between 261 km/h (141 kt) and 306 km/h (165 kt), although the maximum threshold crossing speed of aircraft currently in production is 282 km/h (152 kt).

1.3.10 An analysis of some aircraft indicates that they may be placed in the groups as follows:

Group A

Group B

DC3

DHC6

DHC7

Avro RJ 100

DC6

DC7

Fokker F27

Fokker F28

HS146

HS748

IL76

Group C

Group D

A300, A310, A320, A330, A359, A388

A340

B707-320

A351

B727

B747

B737

B777

B747-SP

B779

B757

B789

B767

DC10-30/40

B788

MD-11

DC9

IL62

MD80

IL86

MD90

IL96

DC10-10

L1011-500

L1011-200

TU154

1.3.11 The number of exit taxiways will depend on the types of aircraft and number of each type that operate during the peak period. For example, at a very large aerodrome, most aircraft will likely be in groups C or D. If so, only two exits may be required. On the other hand, an aerodrome having a balanced mixture of all four groups of aircraft may require four exits.

1.3.12 Using the Three Segment Method, the total distance required from the landing threshold to the point of turn-off from the runway centre line can be determined according to the method illustrated in Figure 1-9.

The total distance S is the sum of three distinct segments which are computed separately.

Segment 1: Distance required from landing threshold to maingear touchdown (S1).

Segment 2: Distance required for transition from maingear touchdown to establish stabilized braking configuration (S2).

Segment 3: Distance required for deceleration in a normal braking mode to a nominal turn-off speed (S3).

Speed profile:

Vth

Threshold speed based on 1.3 times the stall speed of assumed landing mass equal to 85 per cent of maximum landing mass. Speed is corrected for elevation and airport reference temperature.

Vtd

Assumed as Vth - 5 kt (conservative). Speed decay considered representative for most types of aircraft.

Vba

Assumed brake application speed.

Vth

- 15 kt (wheel brakes and/or reverse thrust application).

Vex

Nominal turn-off speed:

Code number 3 or 4: 30 kt

Code number 1 or 2: 15 kt

for standard rapid exit taxiways according to Figures 1-7 and 1-8.

Figure 1-9. Three Segment Method

For other types of exit taxiways see Table 1-8 and Figure 1-10 for turn-off speed.

Distances [in m]:

S1

Empirically derived firm distance to mean touchdown point, corrected for downhill slope and tailwind component where applicable.

Aircraft category C and D:

S1 = 450 m

Correction for slope:

+ 50 m / - 0.25%

Correction for tailwind:

+ 50 m / + 5 kt

Aircraft category A and B:

S1 = 250 m

Correction for slope:

+ 30 m / - 0.25%

Correction for tailwind:

+ 30 m / + 5 kt

S2

The transition distance is calculated for an assumed transition time (empirical) Dt = 10 seconds at an average ground speed of:

s2 = 10 x Vav [ Vav in m/s], or

s2 = 5 x (Vth -10) [ Vth in kt]

S3

The braking distance is determined based on an assumed deceleration rate ‘a’ according to the following equation:

A deceleration rate of a = 1.5 m/s2 is considered a realistic operational value for braking on wet runway surfaces.

1.3.13 The final selection of the most practical rapid exit taxiway location(s) must be considered in the overall planning requirements, taking into account other factors such as:

- location of the terminal/apron area;

- location of other runways and their exits;

- optimization of traffic flow within the taxiway system with respect to traffic control procedures;

- avoidance of unnecessary taxi detours, etc.

Furthermore, there may be a need to provide additional exit taxiways - especially at long runways - after the main rapid exit(s) depending upon local conditions and requirements. These additional taxiways may or may not be rapid exit taxiways. Intervals of approximately 450 m are recommended up to within 600 m of the end of the runway.

Table 1-8. Aircraft speed versus the radius of a rapid exit taxiway

Radii R [m]:

Vdes [kt]:

Vop [kt]:

40

14

3

60

17

16

120

24

22

160

28

24

240

34

27

375

43

30

550

52

33

Based on the design exit speed Vdes complying with a lateral acceleration of 0.133 g, the operational turn- off speed Vop is determined empirically to serve as the criterion for the optimal location of the exit.

Figure 1-10. Aircraft speed versus the radius of a rapid exit taxiway

1.3.14 Some aerodromes have heavy activity of aircraft in code number 1 or 2. When possible, it may be desirable to accommodate these aircraft on an exclusive runway with a rapid exit taxiway. At those aerodromes where these aircraft use the same runway as commercial air transport operations, it may be advisable to include a rapid exit taxiway to expedite ground movement of the small aircraft. In either case, it is recommended that this exit taxiway be located at 450 m to 600 m from the threshold.

1.3.15 As a result of Recommendation 3/5 framed by the Aerodromes, Air Routes and Ground Aids Divisional Meeting (1981), ICAO in 1982 compiled data on actual rapid exit taxiway usage. The data, which were collected from 72 airports and represented operations on 229 runway headings, provided information on the type of exit taxiway, distances from threshold to exits, exit angle and taxiway usage for each runway heading. During the analysis it was assumed that the sample size of the surveyed data was equal for each runway heading. Another assumption was that whenever an aircraft exited through an exit taxiway located at an angle larger than 45°, the aircraft could have exited through a rapid exit taxiway, had there been a rapid exit taxiway on that location (except the runway end). The accumulated rapid exit usage versus distance from thresholds is tabulated in Table 1-9. This means that had there been a rapid exit taxiway located at a distance of 2200 m from thresholds, 95 per cent of aircraft in group A could have exited through that exit taxiway. Similarly, rapid exit taxiways located at 2300 m, 2670 m and 2950 m from thresholds could have been utilized by 95 per cent of aircraft in groups B, C and D, respectively. The table shows the distances as corrected by using the correction factors suggested in the study carried out by the Secretariat and presented to the AGA/81 Meeting, namely, 3 per cent were 300 m of altitude and 1 per cent per 5.6°C above 15°C.

Table 1-9. Accumulated rapid exit usage by distance from threshold (metres)

Aircraft category

50%

60%

70%

80%

90%

95%

100%

A

1 170

1 320

1 440

1 600

1 950

2 200

2 900

B

1 370

1 480

1 590

1 770

2 070

2 300

3 000

C

1 740

1 850

1 970

2 150

2 340

2 670

3 100

D

2 040

2 190

2 290

2 480

2 750

2 950

4 000

Geometric design

1.3.16 Figures 1-7 and 1-8 present some typical designs for rapid exit taxiways in accordance with the specifications given in Annex 14, Volume I. For runways of code number 3 or 4, the taxiway centre line marking begins at least 60 m from the point of tangency of the central (exit) curve and is offset 0.9 m to facilitate pilot recognition of the beginning of the curve. For runways of code number 1 or 2, the taxiway centre line marking begins at least 30 m from the point of tangency of the central (exit) curve.

1.3.17 A rapid exit taxiway should be designed with a radius of turn-off curve of at least:

550 m where the code number is 3 or 4, and

275 m where the code number is 1 or 2;

to enable exit speeds under wet conditions of:

93 km/h (50 kt) where the code number is 3 or 4, and

65 km/h (35 kt) where the code number is 1 or 2.

1.3.18 The radius of the fillet on the inside of the curve at a rapid exit taxiway should be sufficient to provide a widened taxiway throat in order to facilitate recognition of the entrance and turn-off onto the taxiway.

1.3.19 A rapid exit taxiway should include a straight distance after the turn-off curve sufficient for an exiting aircraft to come to a full stop clear of any intersecting taxiway and should not be less than the following when the intersection angle is 30°:

Code number

Code number

1 or 2

3 or 4

35 m

75 m

The above distances are based on deceleration rates of 0.76 m/s2 along the turn-off curve and 1.52 m/s2 along the straight section.

1.3.20 The intersection angle of a rapid exit taxiway with the runway should not be greater than 45° nor less than 25° and preferably should be 30°.

1.4 TAXIWAYS ON BRIDGES

General

1.4.1 The layout of an aerodrome, its dimensions and/or the extension of its runway/taxiway system may require taxiways to bridge over surface transport modes (roads, railways, canals) or open water (rivers, sea bays). Taxiway bridges should be designed so as not to impose any difficulties for taxiing aircraft and to permit easy access to emergency vehicles responding to an emergency involving an aircraft on the bridge. Strength, dimensions, grades and clearances should allow unconstrained aircraft operations day and night as well as under varying seasonal conditions, i.e. heavy rain, periods of snow and ice coverage, low visibility or gusty winds. The requirements of taxiway maintenance, cleaning and snow removal, as well as emergency evacuation of the aircraft occupants, should be taken into account when bridges are being designed.

Siting

1.4.2 For operational and economic reasons the number of bridging structures required and problems related therewith can be minimized by applying the following guidelines:

a) if possible, the surface modes should be routed so that the least number of runways or taxiways will be affected;

b) the surface modes should be concentrated so that preferably all can be bridged with a single structure;

c) a bridge should be located on a straight portion of a taxiway with a straight portion provided on both ends of the bridge to facilitate the alignment of the aeroplanes approaching the bridge;

d) rapid exit taxiways should not be located on a bridge; and

e) bridge locations that could have an adverse effect upon the instrument landing system, the approach lighting or runway/taxiway lighting systems should be avoided.

Dimensions

1.4.3 The design of the bridge structure is determined by its purpose and the specifications relevant to the transport mode that it will serve. Aeronautical requirements should be met with respect to width, shoulders and gradings, etc., of the taxiway.

1.4.4 The bridge width measured perpendicularly to the taxiway centre line shall not be less than the width of the graded portion of the strip provided for that taxiway, unless a proven method of lateral restraint is provided which shall not be hazardous for aeroplanes for which the taxiway is intended. Therefore, minimum width requirements will normally be:

20.5 m

where the code letter is

A

22m

wherethecodeletter is

B

25m

wherethecodeletter is

C

37m

wherethecodeletter is

D

38m

wherethecodeletter is

E

44m

wherethecodeletter is

F

with the taxiway in the centre of the strip. In the exceptional cases when a curved taxiway has to be located on the bridge, extra width should be provided to compensate for the unsymmetrical movement of the aircraft by track-in of the main gear.

1.4.5 If the type of aircraft using the aerodrome is not clearly defined or if the aerodrome is limited by other physical characteristics, the width of the bridge to be designed should be related to a higher code letter from the very beginning. This will prevent the aerodrome operator from taking very costly corrective action once a larger aircraft starts to operate on that aerodrome and has to use the taxiway bridge.

1.4.6 The taxiway width on the bridge should be at least as wide as off the bridge. Unlike the construction of other parts of the taxiway system, the strip on the bridge will normally have a paved surface and serve as a fully bearing shoulder. Additionally, the paved strip on the bridge facilitates maintenance and, where necessary, snow clearing work. Furthermore, the paved surface strip provides access to the bridge for rescue and fire fighting vehicles as well as other emergency vehicles.

1.4.7 The efficiency of ground movement operations will be enhanced if aircraft are able to approach and depart from bridges on straight portions of the taxiway. These will enable aircraft to align themselves with the main undercarriage astride the taxiway centre line before crossing the taxiway bridge. The length of the straight section should be at least twice the wheel base (distance from the nose gear to the geometric centre of the main gear) of the most demanding aircraft and not less than

15m for codeletter A

20m for codeletter B

50m for codeletter C, D or E

70m for codeletter F.

It should be noted that possible future aircraft may have a wheel base of 35 m or more indicating a requirement for a straight distance of at least 70 m.

Gradients

1.1.8 For drainage purposes, taxiway bridges are generally designed with normal taxiway transverse slopes. If, for other reasons, a slope less than 1.5 per cent has been selected, consideration should be given to the provision of sufficient drainage capability on the taxiway bridge.

1.1.9 Ideally, the bridge should be level with the adjacent aerodrome terrain. If, for other technical reasons, the top of the bridge must be higher than the surrounding aerodrome terrain, the adjoining taxiway sections should be designed with slopes which do not exceed the longitudinal gradients specified in Table 1-1.

Bearing strength

1.1.10 A taxiway bridge should be designed to support the static and dynamic loads imposed by the most demanding aircraft expected to use the aerodrome. Future trends of aircraft mass development should be taken into account in specifying the “most demanding aircraft”. Information on future trends is regularly issued by the manufacturers’ associations. Incorporation of future requirements may help to avoid costly redesign of bridges due to progress in technology and/or increasing transport demand.

1.1.11 The strength of the bridge should normally be sufficient over the entire width of the graded area of taxiway strip to withstand the traffic of the aeroplanes the taxiway is intended to serve. Minimum width requirements are specified in 1.4.4. Parts of the same bridge that have been added to serve vehicular traffic only may have lesser strength than those intended for aircraft traffic.

Lateral restraint

1.1.12 When the full load-bearing width provided is less than that of the graded area of the taxiway strip, a proven method of lateral restraint should be provided that shall not be hazardous to aeroplanes for which the taxiway is intended. The lateral restraint system should be provided at the edges of the full load-bearing portion of the strip to prevent the aircraft from falling off the bridge or entering areas of reduced bearing strength. Lateral restraint devices should generally be considered as additional safety measures rather than a means of reducing the full load-bearing width of the taxiway bridge.

1.1.13 Information collected from States indicates that lateral restraint devices are normally provided on a taxiway bridge, irrespective of the width of the full load-bearing area. The lateral restraint device generally consists of a concrete curb which may serve as a barrier. Two examples of concrete curbs commonly used are shown in Figure 1-11. The recommended minimum distance for the location of the lateral restraint device varies among States, but a range between 9 and 27 m from the taxiway centre line was reported. However, factors mentioned in 1.4.6 should be kept in view when considering the location of lateral restraints. The curb is generally from 20 to 60 cm high, the lowest type of curb being used when the width of the graded area is significantly greater than the width of the taxiway strip. Taxiway bridges have been in service for varying periods of time, some of them for over 20 years, and no occurrences of aircraft running off taxiway bridges have been reported.

1.1.14 It may be desirable to provide a second lateral restraint device. This device may consist of a concrete curb or a safety guard rail which is not designed to prevent aircraft running off the taxiway but rather as a safety measure for maintenance personnel and vehicles using the bridge.

Figure 1-11. Examples of concrete curbs

Blast protection

1.1.15 Where the taxiway passes over another transport mode, some kind of protection against aircraft engine blast may need to be provided. This can be accomplished by light cover construction of perforated material (bars or grid-type elements) capable of braking the initial jet blast to uncritical velocities of the order of 56 km/h. Contrary to closed covers, an open construction does not cause any drainage and loading capacity problems.

1.1.16 The overall width of the bridge and protected area should be equal to or exceed the blast pattern of the aircraft using the taxiway. This may be determined by reference to the manufacturers’ literature on the aircraft concerned.

1.5 FILLETS

General

1.5.1 Annex 14, Volume I, recommends minimum clearance distances between the outer main wheels of the aircraft which the taxiway is intended to serve and the edge of the taxiway when the cockpit of the aircraft remains over the taxiway centre line markings. These clearance distances are shown in Table 1-1. To meet these requirements when an aircraft is negotiating a turn, it may be necessary to provide additional pavement on taxiway curves and at taxiway junctions and intersections. It is to be noted that in the case of a taxiway curve the extra taxiway area provided to meet the recommended clearance distance requirement is part of the taxiway and therefore the term “extra taxiway width” is used rather than “fillet”. In the case of a junction or intersection of a taxiway with a runway, apron or another taxiway, however, the term “fillet” is considered to be the appropriate term. In both cases (the extra taxiway width as well as the fillet), the strength of the extra paved surface to be provided should be the same as that of the taxiway. The following material presents concise information on fillet design.

Methods for manoeuvring aircraft on taxiway intersections

1.5.2 Specifications in Annex 14, Volume I concerning taxiway design as well as relevant visual aids specifications are based upon the concept that the cockpit of the aircraft remains over the taxiway centre line. Offsetting the guidelines outwards should be avoided because it implies having a separate guideline for each aircraft type and for use in both directions. Such a multiplicity of lines is impractical particularly when the taxiway is intended to be used at night or during poor visibility conditions, and it would thus be necessary to provide a compromise offset guideline that could be used by all aircraft.

1.6 TAXIWAY SHOULDERS AND STRIPS

General

1.6.1 A shoulder is an area adjacent to the edge of a full strength paved surface so prepared as to provide a transition between the full strength pavement and the adjacent surface. The main purpose of the provision of a taxiway shoulder is: to prevent jet engines that overhang the edge of a taxiway from ingesting stones or other objects that might damage the engine; to prevent erosion of the area adjacent to the taxiway; and to provide a surface for the occasional passage of aircraft wheels. A shoulder should be capable of withstanding the wheel loading of the heaviest airport emergency vehicle. A taxiway strip is an area, including a taxiway, intended to protect an aircraft operating on the taxiway and to reduce the risk of damage to an aircraft accidentally running off the taxiway.

1.6.2 The widths to be provided for taxiway shoulders and strips are given in Table 1-1. It may be noted that shoulders 5.5 m wide for code letter D, 7.5 m wide for code letter E and 10.5 m wide for code letter F on both sides of the taxiway are considered to be suitable. These taxiway shoulder width requirements are based on the most critical aircraft operating in these categories, at this time. On existing airports, it is desirable to protect a wider area should operations by new larger aircraft be intended, as the possibility of potential foreign object damage and the effect of exhaust blast on the taxiway shoulder during break away will be higher. The taxiway shoulder width is considered suitable when it protects the inboard engines of the critical aircraft which are much closer to the ground than the outboard engines.

1.6.3 The graded portions to be provided for taxiways are based on the maximum OMGWS of a group and on the deviation of one aircraft from the taxiway centre line (wheel- to-edge clearance) and the increment (Z), but in any case not lower than the required shoulder width as shown in Table 1-1.

1.6.4 The surface of the shoulder that abuts the taxiway should be flush with the surface of the taxiway while the surface of the strip should be flush with the edge of the taxiway or shoulder, if provided. For code letter C, D, E or F, the graded portion of the taxiway strip should not rise more than 2.5 per cent or slope down at a gradient exceeding 5 per cent. The respective slopes for code letter A or B are 3 per cent and 5 per cent. The upward slope is measured with reference to the transverse slope of the adjacent taxiway surface and the downward slope is measured with reference to the horizontal. There should, furthermore, be no holes or ditches tolerated within the graded portion of the taxiway strip. The taxiway strip should provide an area clear of objects which may endanger taxiing aeroplanes. Consideration will have to be given to the location and design of drains on a taxiway strip to prevent damage to an aircraft accidentally running off a taxiway. Suitably designed drain covers may be required.

1.6.5 No obstacles should be allowed on either side of a taxiway within the distance shown in Table 1 -1. However, signs and any other objects which, because of their functions, must be maintained within the taxiway strip in order to meet air navigation requirements may remain but they should be frangible and sited in such a manner as to reduce to a minimum the hazard to an aircraft striking them. Such objects should be sited so that they cannot be struck by propellers, engine pods and wings of aircraft using the taxiway. As a guide they should be so sited that there is nothing higher than 30 cm above taxiway edge level within the taxiway strip.

Treatment

1.6.6 Taxiway shoulders and graded portions of strips provide an obstacle-free area intended to minimize the probability of damage to an aircraft using these areas accidentally or in an emergency. These areas should thus be prepared or constructed so as to reduce the risk of damage to an aircraft running off the taxiway and be capable of supporting access by rescue and fire fighting vehicles and other ground vehicles, as appropriate, over its entire area. When a taxiway is intended to be used by turbine-engined aircraft, the jet engines may overhang the edge of the taxiway while the aircraft is taxiing and may then ingest stones or foreign objects from the shoulders. Further, blast from the engines may impinge on the surface adjacent to the taxiway and may dislodge material with consequent hazard to personnel, aircraft and facilities. Certain precautions must therefore be taken to reduce these possibilities. The type of surface of the taxiway shoulder will depend on local conditions and contemplated methods and cost of maintenance. While a natural surface (e.g. turf) may suffice in certain cases, in others, an artificial surface may be required. In any event, the type of surface selected should be such as to avoid the blowing up of debris as well as dust while also meeting the minimum load bearing capability mentioned above.

1.6.7 Under most taxiing conditions, blast velocities are not critical except at intersections where thrusts approach those on breakaway. With the present criteria of up to 23 m wide taxiways, the outboard engines of the larger jets extend beyond the edge of the pavement. For this reason, treatment of taxiway shoulders is recommended to prevent their erosion and to prevent the ingestion of foreign material into jet engines or the blowing of such material into the engines of following aircraft. The material below presents concise information on methods of protection of marginal areas subject to blast erosion and of those areas which must be kept free from debris to prevent ingestion by overhanging turbine engines. Additional information can be found in Appendix 2, 15 to 18.

1.6.8 Studies of engine blast and blast effects have included profile development and velocity contour as related to engine type, aircraft mass and configuration; variation in thrust; and effect of cross-wind. It has been found that the effects of heat associated with the jet wake are negligible. Heat dissipates more rapidly with distance than blast force. Furthermore, personnel, equipment and structures normally do not occupy the upper limits of those areas where heat is generated during jet operations. Studies indicate that objects in the path of a jet blast are acted upon by several forces including the dynamic pressure associated with the impact of gases as they strike the surface, drag forces set up when viscous gases move past an object, and uplift forces caused by either differential pressures or turbulence.

1.6.9 Cohesive soils, when loosened, are susceptible to erosion by jet blast. For these soils, protection that is adequate against the natural erosive forces of wind and rain will normally be satisfactory. The protection must be a kind that adheres to the clay surfacing so that the jet blast does not strip it off. Oiling or chemical treatment of a cohesive soil surface are possible solutions. The cohesion required to protect a surface from blast erosion is small; normally, a plasticity index (PI) of two or greater will suffice. However, if the area is periodically used by ground vehicles with their equipment, a PI of six or more will be necessary. There should be good surface drainage for these areas if equipment moves over them since this type of surface will be softened by ponding. Special consideration must be given to highly plastic cohesive soils subject to more than about a 5 per cent shrinkage. For these soils, good drainage is very important since they become extremely soft when wet. When dry, these soils crack and become subject to greater lift forces. Fine, cohesionless soils, which are the most susceptible to erosion by blast, are considered to be those which do not have the cohesive properties defined above.

Shoulder and blast pad design thickness

1.6.10 The thickness of taxiway shoulders and blast pads should be able to accommodate an occasional passage of the critical aircraft considered in pavement design and the critical axle load of emergency or maintenance vehicles which may pass over the area. In addition, the following factors should be taken into account:

a) The minimum design thickness required for shoulder and blast pads to accommodate the critical aircraft can be taken as one half of the total thickness required for the adjacent paved area;

b) the critical axle load of the heaviest emergency or maintenance vehicle likely to traverse the area should be considered in the determination of the pavement thickness. If this thickness is greater than that based on a) above, then this design thickness should be used for shoulder and blast pads;

c) for wide-body aircraft such as the A330, A340, A350, B767, B777, B787, MD11, L1011 or smaller, the recommended minimum surface thickness, if bituminous concrete on an aggregate base is used, is 5 cm on shoulders and 7.5 cm on blast pads. For aircraft such as the B747 or larger, an increase of 2.5 cm in this thickness is recommended;

d) the use of a stabilized base for shoulders and blast pads is also recommended. A 5 cm bituminous concrete surface is the recommended minimum on a stabilized base;

e) the use of Portland cement concrete and a granular sub-base for shoulder and blast pads (or cement- stabilized sand) is advantageous. A minimum thickness of 15 cm of cement concrete is recommended; and

f) the same compaction and construction criteria for sub-grade and pavement courses in shoulder and blast areas should be used as for full strength pavement areas. It is recommended that a drop-off of approximately 2.5 cm be used at the edge of the full strength pavement, shoulders and blast pads to provide a definite line of demarcation.

1.7 FUTURE AIRCRAFT DEVELOPMENTS

General

1.7.1 Annex 14, Volume I sets forth the minimum aerodrome specifications for aircraft that have the characteristics of those which are currently operating or for similar aircraft that are planned for introduction in the immediate future. The current specifications are therefore intended to accommodate aeroplanes with wing spans of up to 80 m, e.g. Airbus A380-800. Accordingly, any additional safeguards that might be considered appropriate to provide for more demanding aircraft are not taken into account in the Annex. Such matters are left to appropriate authorities to evaluate and take into account as necessary for each particular aerodrome.

1.7.2 The following information may assist these authorities and airport planners to be aware of the way in which the introduction of larger aircraft may alter some of the specifications. In this respect, it is worth noting that it is probable that some increase in current maximum aircraft size may be acceptable without major modifications to existing aerodromes. However, the upper limit of aircraft size which is examined below is, in all probability, beyond this consideration unless aerodrome procedures are altered, with resulting reduction in aerodrome capacity.

Future aircraft trends

1.7.3 The trends for future aircraft designs may be obtained from various sources, including the aircraft manufacturers and the International Coordinating Council of Aerospace Industries Associations. For the purpose of planning future airport development, the following aircraft dimensions may be used:

Code F

Larger than code F

wing span

up to 80 m

up to 90 m

outer main gear wheel span

up to 15 m

up to 15 m

overall length

up to 80 m

80 m or more

tail height

up to 24 m

up to 24 m

maximum gross mass

575 000 kg or more

650 000 kg or more

Aerodrome data

1.7.4 Using the rationale developed for implementation of certain specifications related to the aerodrome reference code, it is possible that aircraft with the dimensions shown in the previous paragraph could have the effects on the taxiway system described below.

Taxiway width

1.7.5 It is expected that taxiing characteristics of future large aircraft will be similar to those of the largest current aircraft when considering the straight portion of the taxiway. The taxiway width, WT, for these aircraft is represented by the relationship:

WT = TM + 2C

where:

TM = maximum outer main gear wheel span

C = clearance between the outer main gear wheel and the taxiway edge (maximum allowable lateral deviation). This geometry is shown in Figure 1-12.

1.7.6 Assuming the expected growth of outer main gear wheel span to 15 m and a wheel- to-edge clearance of 4.0 m, the taxiway width for planning purposes comes to 23 m.

Figure 1-12. Taxiway width geometry

Runway-parallel taxiway separation distance

1.7.7 The separation distance between a runway and a parallel taxiway is currently based on the premise that any part of the aircraft on the taxiway centre line must not protrude into the associated runway strip area. This distance, S, is represented by the relationship:

where:

SW = strip width

WS = wing span

This geometry is illustrated in Figure 1-13.

1.7.8 The separation distance for planning purposes for the largest aircraft predicted by future trends data is m. This value is based on the assumption that this aircraft, having a wing span of 90 m, can safely operate in the current 280 m runway strip width required for a non-precision or precision approach runway.

Figure 1-13. Parallel runway-taxiway separation geometry

Separation between parallel taxiways

1.7.9 The rationale for determining the separation distance between parallel taxiways, one of which may be an apron taxiway, is based on providing a suitable wing tip clearance when an aircraft has deviated from the taxiway centre line. Primary factors influencing this issue are: wing span (WS), main gear wheel clearance (C) and wing tip clearance (Z). This results in an expression for the separation distance, S, of:

S = WS + C + Z

where:

WS = wing span

C = clearance between the outer main gear wheel and the taxiway edge (maximum allowable lateral deviation)

Z = wing tip clearance (increment) that accounts for aircraft steering performance, pavement surface conditions, and an assured safety buffer to account for unforeseen problems, and to minimize potential adverse impacts on airport capacity.

The geometry of this relationship is shown in Figure 1-14.

1.7.10 The separation distances between parallel taxiways and between parallel taxiways and apron taxiways are considered to be the same since it is assumed that the speed that the aircraft will taxi in both systems is the same. The separation distance, for planning purposes, for a future aircraft span of 90 m, a lateral deviation, C, of 4.0 m and a current code F wing tip clearance (increment) of 7.0 m, is 101 m.

Figure 1-14. Parallel taxiway separation geometry

Separation distance between taxiway and object

1.7.11 Taxiing speeds on a taxiway and on an apron taxiway are assumed to be the same. Therefore, the separation distances to an object are assumed to be the same in both cases. A rationale has been developed which bases the taxiway-to-object separation distance on a clearance between the wing tip of the aircraft and the object when the aircraft has deviated from the taxiway centre line. This taxiway-to-object separation distance, S, is:

where:

WS = wing span

C = clearance between the outer main gear wheel and the taxiway edge (maximum allowable lateral deviation)

Z = wing tip clearance to an object (increment); (see explanation above in 1.7.9).

Figure 1-15 illustrates this geometry.

1.7.12 Application of the above relationship results in a taxiway centre line or apron taxiway centre line-to-object distance of 53 m when using a 4.0 m deviation and a current code F wing tip clearance (increment) of 7.0 m. The assumed wing span is 84 m.

Aircraft stand taxilane-to-object

1.7.13 The lower taxiing speed of an aircraft in a stand taxilane permits a smaller lateral deviation to be considered than with other taxiways. The geometry of Figure 1-16 illustrates the relationship of aircraft clearance to an object in a stand taxilane. Thus the separation distance, S, is found using the following formula:

where:

WS = wing span

d = lateral deviation

Z = wing tip clearance to an object (increment); (see explanation in 1.7.9 above).

1.7.14 Application of the above rationale results in an object separation distance, for planning purposes, for future large aircraft in a stand taxilane of 52.5 m. This value is based on a wing span of 90 m, a gear deviation of 3.5 m and a wing tip clearance (increment) of 5.0 m.

Figure 1-16. Aircraft stand taxilane-to-object geometry

Other considerations

1.7.15 In addition to the guidance in the preceding paragraphs, preliminary criteria to accommodate future aircraft development are described below:

Runway width: 45 m

Runway sight distance: Same as current requirement for code letter F

Runway transverse slope: Same as current requirement for code letter F

Runway shoulders: Overall width of runway and shoulder - 75 m, paved to a minimum overall width of runway and shoulder of not less than 60 m. A widened area may need to be prepared to prevent erosion of the adjacent area and foreign object damage.

Slope and strength of runway shoulders: Same as current requirement for code letter F

Minimum separation distances between taxiway centre line and runway centre line:

1/2 wing span (Y)

45 m

+

1/2 strip width

(non-instrument approach runway)

75 m

Total

120 m

or

1/2 wing span (Y)

45 m

+

1/2 strip width

(instrument approach runway)

140 m

Total

185 m

Taxiway pavement and shoulder (overall width): Adequate space should be prepared to prevent erosion of the adjacent area and foreign object damage. The width of that portion of a taxiway bridge capable of supporting aeroplanes shall not be less than the width of the graded area of the strip provided for that taxiway.

Graded portion of taxiway strip (overall width): Adequate space should be prepared to prevent erosion of the adjacent area and foreign object damage. The width of that portion of a taxiway bridge capable of supporting aeroplanes shall not be less than the width of the graded area of the strip provided for that taxiway

CHAPTER 2

HOLDING BAYS AND OTHER BYPASSES

2.1 NEED FOR HOLDING BAYS AND OTHER BYPASSES

2.1.1 Procedures for Air Navigation Services - Air Traffic Management (Doc 4444), Chapter 7, 7.9.1, Departure sequence, states that “departures shall normally be cleared in the order in which they are ready for take-off, except that deviations may be made from this order of priority to facilitate the maximum number of departures with the least average delay”. At low levels of aerodrome activity (less than approximately 50 000 annual operations), there is normally little need to make deviations in the departure sequence. However, for higher activity levels, aerodromes with single taxiways and no holding bays or other bypasses provide aerodrome control units with no opportunity to change the sequence of departures once the aircraft have left the apron. In particular, at aerodromes with large apron areas, it is often difficult to arrange for aircraft to leave the apron in such a way that they will arrive at the end of the runway in the sequence required by air traffic services units.

2.1.2 The provision of an adequate number of holding bay spaces or other bypasses, based upon an analysis of the current and near-term hourly aircraft departure demand, will allow a large degree of flexibility in generating the departure sequence. This provides air traffic services units with greater flexibility in adjusting the take-off sequence to overcome undue delays, thus increasing the capacity of an aerodrome. In addition, holding bays or other bypasses allow:

a) departure of certain aircraft to be delayed owing to unforeseen circumstances without delaying the following aircraft (for instance, a last minute addition to the payload or a replacement of defective equipment);

b) aircraft to carry out pre-flight altimeter checks and alignment and programming of airborne inertial navigation systems when this is not possible on the apron;

c) engine runups for piston aircraft; and

d) establishment of a VOR aerodrome check-point.

2.2 TYPES OF BYPASSES

2.2.1 In general, taxiway features that allow an aircraft to bypass a preceding aircraft can be divided into three types:

a) Holding bays. A defined area where aircraft can be held or bypassed. Figure 2-

1 shows some examples of holding bay configurations and Figure 2-2 gives a detailed example of a holding bay, located at the taxi-holding position.

b) Dual taxiways. A second taxiway or a taxiway bypass to the normal parallel taxiway. Figure 2-3 shows some examples.

c) Dual runway entrances. A duplication of the taxiway entrance to the runway. Some examples are shown in Figure 2-4.

 

Figure 2-1. Examples of holding bay configurations

Figure 2-2. Detailed example of holding bay

Figure 2-3. Examples of dual taxiways

Figure 2-4. Examples of dual runway entrances

2.2.2 If a holding bay is used, aircraft can, on the basis of their priority, take off in the order as cleared by ATC. The availability of a holding bay allows aircraft to leave and independently re-enter the departure stream. A detailed example of the pavement area for a holding bay located at the taxi-holding position is shown in Figure 2-2. This design is for a non-precision or a precision approach runway where the code number is 3 or 4 and incorporates an aircraft wing- tip-to-wing-tip clearance of 15 m when both aircraft are centred on the centre line. Holding bay design for other runway types or locations along the taxiway will have proportional dimensional requirements.

2.2.3 Dual taxiways or taxiway bypasses can only achieve relative departure priority by separating the departure stream into two parts. Taxi bypasses can be constructed at a relatively low cost, but provide only a small amount of flexibility to alter the departure sequence. A full length dual taxiway is the most expensive alternative and can only be justified at very high activity aerodromes where there is a clear need for two-directional movement parallel to the runway. This need arises when passenger terminal aprons or other facilities are located in such a manner that they generate aircraft movements opposite to the departure flow.

2.2.4 The dual runway entrance reduces the take-off run available for aircraft using the entrance not located at the extremity of the runway. This is not a serious disadvantage if this entrance can be used by aircraft for which the remaining take-off run is adequate. A dual runway entrance also makes it possible to bypass an aircraft delayed on another entrance taxiway or even at the extremity of the runway. The use of dual entrances in combination with dual taxiways will give a degree of flexibility comparable to that obtained with a well- designed holding bay. Oblique entrances permit entry at some speed, but they make it more difficult for the crew to see aircraft approaching to land and, because of the larger paved area required, they are more expensive to provide. Though operational and traffic control groups have advocated designs for runway entry which would permit acceleration while turning onto the runway, further studies, simulations and experience will be necessary prior to establishing a recommended design of this type.

2.2.5 For a given aerodrome, the best choice between these methods depends upon the geometry of the existing runway/taxiway system and the volume of aircraft traffic. Experience shows that local technical and economic considerations will often be decisive when choosing between the three types (or combinations of types). These three types can also be used in various combinations to optimize surface movements of aircraft to the threshold.

2.3 COMMON DESIGN REQUIREMENTS AND CHARACTERISTICS

2.3.1 Regardless of the type of bypass used, minimum centre line to centre line separations between taxiways and runways must be maintained as required for the type of runway served (see Table 1-1).

2.3.2 The cost of constructing any bypass is directly related to the area of new pavement required. In addition, indirect costs may result from disruptions to air traffic during the construction period.

2.3.3 The design selected should always provide at least one entrance to the beginning of the runway usable for take-off so that aircraft requiring the entire take-off run may easily align themselves for take-off without significant loss of runway length.

2.3.4 Propeller wash and jet blast from holding aircraft should be directed away from other aircraft and away from the runway. The preparation and the maintenance of the shoulders should be as described for taxiway shoulders (see 1.6.6 to 1.6.10).

2.4 SIZE AND LOCATION OF HOLDING BAYS

2.4.1 The space required for a holding bay depends on the number of aircraft positions to be provided, the size of the aircraft to be accommodated and the frequency of their utilization. The dimensions must allow for sufficient space between aircraft to enable them to manoeuvre independently. In general, the wing tip clearance (increment) between a parked aircraft and one moving along the taxiway or apron taxiway should not be less than that given by the following tabulation:

Code letter

Wing tip clearance (increment) (m)

A

6.5

B

5.75

C

5

D

7

E

7

F

7

2.4.2 When used to allow flexible departure sequencing, the most advantageous location for a holding bay is adjacent to the taxiway serving the runway end. Other locations along the taxiway are satisfactory for aircraft performing pre-flight checks or engine runups or as a holding point for aircraft awaiting departure clearance. Criteria for the location of holding bays with respect to the runway are given below.

2.4.3 The distance between a holding bay and the centre line of a runway should be in accordance with Table 2-1 and, in the case of a precision approach runway, should be such that a holding aircraft will not interfere with the operation of radio aids. Therefore, the aircraft should be clear of the ILS sensitive and critical areas, and it should not penetrate the obstacle free zone.

2.4.4 At elevations greater than 700 m, the distance of 90 m specified in Table 2-1 for a precision approach runway code number 4 should be increased as follows:

a) up to an elevation of 2 000 m - 1 m for every 100 m in excess of 700 m;

b) elevation in excess of 2 000 m and up to 4 000 m - 13 m plus 1.5 m for every 100 m in excess of 2 000 m; and

c) elevation in excess of 4 000 m and up to 5 000 m - 43 m plus 2 m for every 100 m in excess of 4 000 m.

2.4.5 If a holding bay for a precision approach runway code number 4 is at a higher elevation compared to the threshold, the distance of 90 m specified in Table 2-1 should be further increased 5 m for every metre the bay is higher than the threshold.

2.4.6 The distance of 107.5 m for code number 4 where the code letter is F is based on an aircraft with a tail height of 24 m, a distance from the nose to the highest part of the tail of 62.2 m, a nose height of 10 m, holding at an angle of 45 degrees or more with respect to the runway centre line and being clear of the obstacle free zone.

2.4.7 The distance of 90 m for code number 3 or 4 is based on an aircraft with a tail height of 20 m, a distance from the nose to the highest part of the tail of 52.7 m and a nose height of 10 m, holding at an angle of 45 degrees or more with respect to the runway centre line, being clear of the obstacle free zone and not accountable for the calculation of obstacle clearance altitude/height.

2.4.8 The distance of 60 m for code number 1 or 2 is based on an aircraft with a tail height of 8 m, a distance from the nose to the highest part of the tail of 24.6 m and a nose height of 5.2 m, holding at an angle of 45 degrees or more with respect to the runway centre line, being clear of the obstacle free zone.

2.5 HOLDING BAY MARKING AND LIGHTING

To facilitate accurate manoeuvring of aircraft on the holding bays, it is desirable to provide suitable marking and lighting. These will also prevent parked aircraft from interfering with the passage of other aircraft moving along the adjacent taxiway. A solid line to be followed by the pilot of the aircraft appears to be a suitable method. Taxiway edge lighting should be provided on a holding bay intended for night use. Location and characteristics of the lights should be in accordance with the specifications for taxiway lighting set out in Annex 14, Volume I, Chapter 5.

Table 2-1. Minimum distance from the runway centre line to a holding bay

Code number

Type of runway operation 

1

2

3

4

Non-instrument and take-off 

30 m

40 m

75 m

75 m

Non-precision approach

40 m

40 m

75 m

75 m

Precision approach
Category I

60 mb

60 mb

90 ma,b

90 ma,b

Precision approach
Category II or III

-

-

90 ma,b

90 ma,b,c

a. If a holding bay is at a lower elevation compared to the threshold, the distance may be decreased 5 m for every metre the bay is lower than the threshold, contingent upon not infringing on the inner transitional surface.

b. This distance may need to be increased to avoid interference with radio aids; for a precision approach runway category III the increase may be of the order of 50 m.

c. Where the code letter is F, this distance should be 107.5 m.

CHAPTER 3

APRONS

An apron is a defined area intended to accommodate aircraft for purposes of loading and unloading passengers, mail or cargo, fuelling and parking or maintenance. The apron is generally paved but may occasionally be unpaved; for example, in some instances, a turf parking apron may be adequate for small aircraft.

3.1 TYPES OF APRONS

Passenger terminal apron

3.1.1 The passenger terminal apron is an area designed for aircraft manoeuvring and parking that is adjacent or readily accessible to passenger terminal facilities. This area is where passengers board the aircraft from the passenger terminal. In addition to facilitating passenger movement, the passenger terminal apron is used for aircraft fuelling and maintenance as well as loading and unloading cargo, mail and baggage. Individual aircraft parking positions on the passenger terminal apron are referred to as aircraft stands.

Cargo terminal apron

3.1.2 Aircraft that carry only freight and mail may be provided a separate cargo terminal apron adjacent to a cargo terminal building. The separation of cargo and passenger aircraft is desirable because of the different types of facilities each requires both on the apron and at the terminal.

Remote parking apron

3.1.3 In addition to the terminal apron, airports may require a separate parking apron where aircraft can park for extended periods. These aprons can be used during crew layovers or for light periodic servicing and maintenance of temporarily grounded aircraft. While parking aprons are removed from the terminal aprons, they should be located as close to them as is practical to minimize the time for passenger loading/unloading as well as from a security point of view.

Service and hangar aprons

3.1.4 A service apron is an uncovered area adjacent to an aircraft hangar on which aircraft maintenance can be performed, while a hangar apron is an area on which aircraft move into and out of a storage hangar.

General aviation aprons

3.1.5 General aviation aircraft, used for business or personal flying, require several categories of aprons to support different general aviation activities.

Itinerant apron

3.1.5.1 Itinerant (transient) general aviation aircraft use the itinerant apron as temporary aircraft parking facilities and to access fuelling, servicing and ground transportation. At aerodromes servicing only general aviation aircraft, the itinerant apron is usually adjacent to, or an integral part of, a fixed-based operator’s area. The terminal apron will generally also set aside some area for itinerant general aviation aircraft.

Base aircraft aprons or tiedowns

3.1.5.2 General aviation aircraft based at an aerodrome require either hangar storage or a tiedown space in the open. Hangared aircraft also need an apron in front of the building for manoeuvring. Open areas used for base aircraft tiedown may be paved, unpaved or turf, depending on the size of aircraft and local weather and soil conditions. It is desirable that they be in a separate location from the itinerant aircraft aprons.

Other ground servicing aprons

3.1.5.3 Areas for servicing, fuelling or loading and unloading should also be provided as needed.

3.2 DESIGN REQUIREMENTS

3.2.1 The design of any of the various apron types requires the evaluation of many interrelated and often contradictory characteristics. Despite the distinct purposes of the different apron types, there are many general design characteristics relating to safety, efficiency, geometry, flexibility and engineering that are common to all types. The following paragraphs give a brief description of these general design requirements.

Safety

3.2.2 Apron design should take into account safety procedures for aircraft manoeuvring on the apron. Safety in this context implies that aircraft maintain specified clearances and follow the established procedures to enter, move within and depart from apron areas. Services provided to aircraft parked on the apron should incorporate safety procedures, especially regarding aircraft fuelling. Pavements should slope away from terminal buildings and other structures to prevent the spread of fuel fires on the apron. Water outlets should be located at each stand position for routine hosing of the apron surface. Aircraft security should also be considered in locating the apron area where the aircraft can be protected from unauthorized personnel. This is accomplished by physically separating public access areas from the apron areas.

Efficiency

3.2.3 Apron design should contribute to a high degree of efficiency for aircraft movements and dispensing apron services. Freedom of movement, minimum taxi distances and a minimum of delay for aircraft initiating movements on the apron are all measures of efficiency for any of the apron types. If the ultimate aircraft stand arrangement can be determined during the initial planning phase of the aerodrome, utilities and services should be installed in fixed installations. Fuel lines and hydrants, compressed air hookups and electrical power systems must be carefully preplanned because these systems are often placed under the apron pavement. The high initial cost of these systems will be offset by the increased efficiency of the stand, which allows greater utilization of the apron. Achieving these measures of efficiency will ensure the maximum economic value of the apron.

Geometry

3.2.4 The planning and design of any apron type are dependent upon a number of geometric considerations. For example, the length and width of a land parcel available for apron development may preclude the choice of certain apron layout concepts. For a new aerodrome it may be possible to develop the most efficient arrangement, based upon the nature of the demand, and then to set aside an area of land ideally suited to the plan. However, expansion or addition of aprons at existing aerodromes will usually be less than ideal due to the limitations imposed by the shape and size of available parcels. The overall area needed per aircraft stand includes the area required for aircraft stand taxilanes as well as apron taxiways used in common with other aircraft stands. Therefore, the overall area needed for apron development is a function not only of aircraft size, clearances and parking method, but also of the geometric arrangement of aircraft stand taxilanes, other taxiways, blast fences, areas used for the stationing of service vehicles and roads for the movement of ground vehicles.

Flexibility

3.2.5 Planning for aprons should include an evaluation of the following flexibility characteristics.

Range of aircraft sizes

3.2.5.1 The number and size of aircraft stands should be matched to the number and size of aircraft types expected to use the apron. A compromise must be developed between the extremes of:

a) using one size of aircraft stand large enough for the largest aircraft type; and b) using as many different sized stands as there are aircraft types.

The first method is a highly inefficient use of area, while the second provides a low level of operating flexibility. For passenger terminal aprons, a compromise solution that achieves adequate flexibility is to group the aircraft into two to four size classes and provide stands for a mix of these general sizes in proportion to the demand forecast. A greater number of general aviation parking space sizes can be used because the space may be leased and occupied by a single aircraft of known dimensions.

Expansion capability

3.2.5.2 Another key element of a flexible apron system is allowance for expansion to meet future needs. To avoid undue restriction of the growth potential of a particular apron area, the apron should be designed in modular stages so that successive stages become integral additions to the existing apron with a minimum of disruption to ongoing activities.

Common design characteristics

3.2.6 Many technical design requirements for the construction of apron surfaces are common to all apron types. Several of these factors are described in the following paragraphs.

Pavement

3.2.6.1 The choice of pavement surface is determined by evaluating aircraft mass, load distribution, soil conditions and the relative cost of alternative materials. Reinforced concrete is routinely used at aerodromes serving the largest commercial aircraft where greater strength and durability are needed. As a minimum, most aerodromes require an asphalt (tarmac) surface to satisfy strength, drainage and stabilization criteria, though turf and cement-stabilized sand aprons have been satisfactorily used in some locations. Reinforced concrete is usually more expensive to install than asphalt but is less expensive to maintain and usually lasts longer. In addition, concrete is relatively unaffected by spilled jet fuel, whereas asphalt surfaces are damaged if fuel remains on the surface for even short periods of time. This problem can be partially overcome by coating the asphalt with special sealants and by frequently washing off the pavement.

Pavement slope

3.2.6.2 Slopes on an apron should be sufficient to prevent accumulation of water on the surface of the apron but should be kept as level as drainage requirements permit. Efficient storm drainage of large, paved apron areas is normally achieved by providing a steep pavement slope and numerous area drains. On aprons, however, too great a slope will create manoeuvrability problems for aircraft and service vehicles operating on the apron. Additionally, fuelling of aircraft requires nearly a level surface to achieve the proper fuel mass balance in the assorted aircraft storage tanks. The design of slopes and drains should direct spilled fuel away from building and apron service areas. In order to accommodate the needs for drainage, manoeuvrability and fuelling, apron slopes should be 0.5 to 1.0 per cent in the aircraft stand areas and no more than 1.5 per cent in the other apron areas.

Jet blast and propeller wash

3.2.6.3 The effects of extreme heat and air velocities from jet and propeller engines must be considered when planning apron areas and adjacent service roads and buildings. For some aerodromes, it may be necessary to provide greater aircraft-to-aircraft separations or erect blast fences between parking spaces to counteract these effects. Appendix 2 gives greater detail on this design consideration.

3.3 BASIC TERMINAL APRON LAYOUTS

General considerations

3.3.1 The type of terminal apron parking layout best suited to a particular aerodrome is a function of many interrelated criteria. Design of the terminal apron must, of course, be completely consistent with the choice of terminal design and vice versa. An iterative procedure for selecting the best combination of apron and terminal design should be used to compare the advantages and disadvantages of each system analysed separately. The volume of aircraft traffic using the terminal is an important factor in determining the apron layout that is most efficient in serving a particular terminal design. In addition, an aerodrome with a disproportionate percentage of international transfer (direct connection with another flight) or locally originating passengers may need a specialized terminal and apron system design to accommodate the skewed characteristic of the passenger traffic.

Passenger loading

3.3.2 The passenger loading method to be used must be taken into account when planning the apron layout. Some methods can be used with only one or two of the basic parking layouts.

3.3.2.1 Direct upper level loading is made possible by the development of the loading bridge, permitting the passenger to board the aircraft from the upper level of the terminal building. Two types of aircraft loading bridges are illustrated in Figure 3-1:

a) The stationary loading bridge. A short loading bridge which extends from a projection in the building. The aircraft parks nose-in alongside the projection and stops with the aircraft front door opposite the bridge. The bridge extends a very short distance to the aircraft, allowing very little variation between the height of the aircraft main deck and the terminal floor.

b) The apron drive loading bridge. A bridge which has one end of a telescoping gangway hinged to the terminal building and the other end supported by a steerable, powered dual-wheel. The bridge pivots towards the aircraft and lengthens until it reaches the aircraft door. The end mating with the aircraft can be raised or lowered significantly, permitting aircraft of varying deck heights to be served from the loading bridge.

3.3.2.2 There are other basic passenger loading methods used in addition to aircraft loading bridges:

a) Movable steps. Movable steps are pushed or driven to the aircraft and set at door level. Passengers walk in the open on the apron or are driven by bus between the terminal and the aircraft and use the steps to board the aircraft.

b) Passenger transporters. Passengers board a bus or specially designed passenger transporter at the terminal building and are driven to a remote aircraft stand. Passengers then may use steps to board the aircraft or board the aircraft from the same level as the aircraft floor, i.e. by elevation of the vehicle.

c) Aircraft-contained steps. This procedure is similar to the movable steps and can be used with any aircraft equipped with self-contained steps. After stopping, the crew releases the self-contained steps and passengers walk on the apron or are driven by bus between the aircraft and the terminal building.

Passenger terminal apron concepts

3.3.3 The design of passenger terminal aprons is directly interrelated with the passenger terminal concept. Determination of passenger terminal concepts is described in the Airport Planning Manual (Doc 9184), Part 1 - Master Planning. Various apron/terminal concepts are illustrated in Figure 3-2, and the characteristics of each concept from the viewpoint of the apron are briefly described below.

Simple concept

3.3.4 This concept is to be applied at low-traffic-volume airports. Aircraft are normally parked angled either nose in or nose-out for self-taxi in and taxi out. Consideration should be given to providing adequate clearance between apron edge and airside terminal frontage to reduce the adverse effects of jet engine blast. Where this is not done, jet engine blast fences should be provided. Apron expansion can be done incrementally in accordance with demands, causing little disruption to airport operation.

Figure 3-1. Passenger loading bridges

Figure 3-2. Passenger terminal apron concepts

Linear concept

3.3.5 The linear concept may be regarded as an advanced stage of the simple concept. Aircraft can be parked in an angled or parallel parking configuration. However, the nose- in/push-out parking configuration with minimum clearance between apron edge and terminal is more common in this concept because of more efficient utilization of apron space and handling of aircraft and passengers. Nose-in parking affords relatively easy and simple manoeuvring for aircraft taxiing into gate position. Push-out operations cause little disruption of apron activities in neighbouring gate positions. However, towing tractors and skilled operators are required. At busy traffic airports, it may become necessary to provide double apron taxiways to lessen the blocking of the taxiway by push-out operations. The corridor between the apron edge and terminal frontage can be used for circulation of apron traffic, and the area around the nose of the parked aircraft can be used for ground service equipment parking slots. When apron depth is planned from the outset to cater to the longest fuselage length, the linear concept has as much flexibility and expansibility as the simple concept and almost as much as the open apron concept.

Pier (finger) concept

3.3.6 As seen in Figure 3-2, there are several variations on this concept, according to the shape of the pier. Aircraft can be parked at gate positions on both sides of the piers, either angled, parallel or perpendicular (nose-in). Where there is only a single pier, most advantages of the linear concept would apply for airside activities with the exception that the pier concept has a limited incremental expansion capability. When there are two or more piers, care must be taken to provide proper space between them. If each pier serves a large number of gates, it may be necessary to provide double taxiways between piers to avoid conflicts between aircraft entering and leaving the gate positions. It is important to provide sufficient space between two or more piers to cater to future larger aircraft.

Satellite concept

3.3.7 The satellite concept consists of a satellite unit, surrounded by aircraft gate positions, separated from the terminal. The passenger access to a satellite from the terminal is normally via an underground or elevated corridor to best utilize the apron space, but it could also be on the surface. Depending on the shape of the satellite, the aircraft are parked in radial, parallel or some other configuration around the satellite. When aircraft are parked radially, push-back operation is easy but requires larger apron space. If a wedge-shaped aircraft parking configuration is adopted, it not only requires unfavourable sharp turns taxiing to some of the gate positions but also creates traffic congestion of ground service equipment around the satellite. A disadvantage of this concept is the difficulty of incremental expansion which means that an entire new unit would need to be constructed when additional gate positions are required.

Transporter (open) apron concept

3.3.8 This concept may be referred to as an open or remote apron or transporter concept. As aprons may be ideally located for aircraft, i.e. close to the runway and remote from other structures, this concept would provide advantages for aircraft handling, such as shorter overall taxiing distance, simple self-manoeuvring, ample flexibility and expansibility of aprons. However, as it requires transporting passengers, baggage and cargo for relatively longer distances by transporters (mobile lounges/buses) and carts to and from the terminal, it can create traffic congestion problems on the airside.

Hybrid concept

3.3.9 The hybrid concept means the combining of more than one of the above-mentioned concepts. It is fairly common to combine the transporter concept with one of the other concepts to cater to peak traffic. Aircraft stands located at remote areas from the terminal are often referred to as remote aprons or remote stands.

3.4 SIZE OF APRONS

General

3.4.1 The amount of area required for a particular apron layout depends upon the following factors:

a) the size and manoeuvrability characteristics of the aircraft using the apron;

b) the volume of traffic using the apron;

c) clearance requirements;

d) type of ingress and egress to the aircraft stand;

e) basic terminal layout or other airport use (see 3.3);

f) aircraft ground activity requirements; and

g) taxiways and service roads.

Aircraft size

3.4.2 The size and manoeuvrability of the mix of aircraft expected to use a given apron must be known before a detailed apron design can be undertaken. Figure 3-3 shows the dimensions needed for sizing an aircraft stand space, and Table 3-1 lists dimensions for some typical aircraft. The overall aircraft size dimensions - total length (L) and wing span (S) - can be used as the starting point in establishing the overall apron area requirement for an aerodrome. All other areas needed for clearances, taxiing, servicing, etc., must be determined with regard to this basic aircraft “footprint”. The manoeuvrability characteristics of an aircraft are a function of the turning radius (R) which is in turn related to the location of the aircraft turning centre. The turning centre is the point about which the aircraft pivots when turning. This point is located along the centre line of the main undercarriage at a variable distance from the fuselage centre line depending upon the amount of nosewheel angle used in the turning manoeuvre. The values listed in Table 3-1 for the turning radii are derived from the nosewheel angles as listed. In most cases, these radii values are measured from the turning centre to the wing tip; however, on some aircraft, the turning radii are measured from the turning centre to the aircraft nose or to the horizontal stabilizers.

Traffic volumes

3.4.3 The number and size of aircraft stand positions needed for any type of apron can be determined from forecasts of aircraft movements at a given aerodrome. The forecast of apron activity must be broken down into an appropriate demand planning period for the type of apron involved. The apron need not be designed for extraordinary peak periods of activity, but should be able to accommodate a reasonable peak activity period with a minimum amount of delay. For example, the number of passenger terminal aircraft stands should be adequate to handle the peak hour traffic of the average day of the peak month. The peak period for accumulation of cargo aircraft is longer than an hour and less than a day; therefore, the cargo apron should handle the average day’s activity of the peak month. Other apron types should have enough parking spaces to handle their appropriate peak period of activity. In addition, planning for aprons should be broken into several phases to minimize the capital cost outlays needed. Apron areas should then be added as needed to accommodate the growth in demand.

* Determined by nose tip or tail tip on some aircraft

Figure 3-3. Dimensions for sizing aircraft stand spacing

Table 3-1. Selected aircraft dimensions

Aircraft type

Length
(m)

Wing span (m)

Nose wheel angle

Turning radius (m)

A300BB2

46.70

44.80

50°

38.80a

A320-200

37.57

33.91

70°

21.91c

A330/A340-200

59.42

60.30

65°

45.00a

A330/A340-300

63.69

60.30

65°

45.60a

B727200

46.68

32.92

75°

25.00c

B737200

30.58

28.35

70°

18.70a

B737-400

36.40

28.89

70°

21.50c

B737-900

41.91

34.32

70°

24.70c

B747

70.40

59.64

60°

50.90a

B747400

70.67

64.90

60°

53.10a

B757-200

47.32

37.95

60°

30.00a

B767-200

48.51

47.63

60°

36.00a

B767-400 ER

51.92

61.37

60°

42.06a

B777-200

63.73

60.93

64°

44.20a

B777-300

73.86

73.08

64°

46.80a

BAC 111400

28.50

27.00

65°

21.30a

DC861/63

57.12

43.41/45.2

70°

32.70c

DC930

36.36

28.44

75°

20.40c

DC940

38.28

28.44

75°

21.40c

DC950

40.72

28.45

75°

22.50c

MD82

45.02

32.85

75°

25.10b

MD90-30

46.50

32.87

75°

26.60b

DC1010

55.55

47.35

65°

35.60a

DC1030

55.35

50.39

65°

37.30a

DC1040

55.54

50.39

65°

36.00a

MD11

61.60

52.50

65°

39.40a

L1011

54.15

47.34

60°

35.59a

a. Towing tip

b. Tonose

c. Totail

Clearance requirements

3.4.4 An aircraft stand should provide the following minimum clearances between aircraft using the stand as well as between aircraft and adjacent buildings or other fixed objects.

Code letter

Clearance (m)

A

3.0

B

3.0

C

4.5

D

7.5

E

7.5

F

7.5

The clearances for code letters D, E and F can be reduced in the following locations (for aircraft using a taxi-in, push-out procedure only):

a) between the terminal (including passenger loading bridges) and the nose of an aircraft; and

b) over a portion of the stand provided with azimuth guidance by a visual docking guidance system.

These clearances may, at the discretion of the airport planners, be increased as needed to ensure safe operation on the apron. Location of aircraft stand taxilanes and apron taxiways should provide the following minimum separation distance between the centre line of these

taxiways and an aircraft at the stand:

Minimum separation distances

Code letter

Aircraft stand taxilane centre line to object

(m)

Apron taxiway centre line to object

(m)

A

12.0

15.5

B

16.5

20.0

C

22.5

26.0

D

33.5

37.0

E

40.0

43.5

F

47.5

51.0

Types of aircraft stand ingress and egress

1.1.5 There are several methods used by an aircraft to enter and leave an aircraft stand: it may enter and leave under its own power; it may be towed in and towed out; it may enter a position under its own power and be towed or pushed out. However, in considering apron size requirements, the various methods can be categorized as either selfmanoeuvring or tractor- assisted.

1.1.5.1 Self-manoeuvring. This term denotes the procedure whereby an aircraft enters and leaves the aircraft stand under its own power, that is, without recourse to a tractor for any part of the manoeuvre. Figure 3-4 a), b) and c) shows the area required for aircraft manoeuvring into and out of an aircraft stand position for angled nose-in, angled nose-out and parallel parking configuration, respectively. The normal manoeuvre of taxiing into and out of an aircraft stand adjoining the terminal building or pier by nose-in or nose-out parking configuration involves a 180 degree turn as shown in Figure 3-4 a) and b). The radius of this turn and the geometry of the aircraft are among the factors which determine the aircraft stand spacing. Although this method of parking requires more pavement area than tractor-assisted methods, this is offset by a saving of the equipment and personnel required for the tractor operation. Thus these methods are common at airports with a relatively small volume of traffic. Figure 3-4 c) illustrates the stand spacing for self-manoeuvring aircraft, which is contingent upon the angle at which the aircraft can comfortably manoeuvre into a stand position with other aircraft parked in the adjacent positions. While this parking configuration affords easiest manoeuvring for aircraft to taxi-in/out, it requires the largest apron area. In addition, due consideration should be given to the adverse effect of jet blast on servicing crew and equipment in neighbouring aircraft stands.

1.1.5.2 Tractor-assisted. This term applies to any method of ingress and egress that requires the use of a tractor and tow bar. Most of the world’s busiest aerodromes use some variation of tractor-assisted methods. The most common procedure is the taxi-in, push-out method, but aircraft can also be towed in and out in other combinations. Use of tractors allows a much closer spacing of aircraft stands, reducing both the apron and terminal space required to accommodate a high volume of terminal aircraft parking. Figure 3-4 d) shows the area required for aircraft that taxi in and push out perpendicular to the terminal building. Clearly this procedure results in a more efficient use of apron space than the selfmanoeuvring procedure. This is a simple manoeuvre which can be done without creating excessive engine blast problems for apron personnel and equipment or the terminal building. The requirement for jet blast fences is also reduced or eliminated by adopting this procedure. Generally, some type of guidance system is provided for pilots to position aircraft accurately in the gate position. The departure manoeuvre is more complicated and usually involves the aircraft being pushed backward by a tractor onto the taxiway while at the same time being turned up to 90 degrees. Normally the push-back operation is carried out without the engines started. It takes an average of 3 to 4 minutes from the beginning of the push-back until the tractor is disconnected and the aircraft is moving under its own power. The push-out operation requires skill and practice on the part of the driver to avoid over-castoring the nose wheel and, on slippery pavement, to keep the aircraft moving while simultaneously maintaining directional control because of the reduced traction.

1.1.5.3 Stand spacing. General formulas have been developed in a number of cases to calculate the required distance between aircraft stands. The simplest case is for aircraft that taxi in perpendicular to the terminal building and push out straight back. As shown in Figure 3-4 d), the minimum stand spacing (D) equals the wing span (S) plus the required clearance (C).

1.1.5.4 For other ingress and egress procedures, or for other parking angles, the geometry is more complex and a detailed analysis needs to be undertaken to determine stand spacings. Manufacturers’ technical data should be consulted to determine the wing tip radii and operating characteristics for those aircraft likely to use these more complex manoeuvring techniques.

Aircraft ground servicing

1.1.6 Passenger aircraft services that are carried out during the time an aircraft is parked in a stand position include: galley, toilet and potable water service; baggage handling; fuelling; provision of air conditioning, oxygen, electrical power supply and starting air; and aircraft towing. Most of these functions have a vehicle and/or equipment associated with them or have some type of fixed installation established to conduct these services. Figures 3-5 and 3-6 show a typical ground equipment service layout for a medium-sized aircraft. The area to the right of the aircraft nose forward of the wing is often used as a pre-positioned service area to store vehicles and equipment when the nose- in/push-out parking configuration is adopted.

Figure 3-4. Clearance area required for terminal stand ingress and egress

Figure 3-5. Typical ground equipment service layout (Boeing 737 - MAX)

Figure 3-6. Typical ground equipment service layout (Airbus A350-900)

Taxiways and service roads

General

1.1.7 The total area needed for an apron includes not only the individual aircraft stands, but also the area required for apron taxiways, aircraft stand taxilanes and service roads needed to access the aircraft stands and provide necessary support services. Locations for these facilities will depend upon the terminal arrangement, runway locations and locations of off- apron services such as flight kitchens, fuel farms, etc.

Apron taxiways

1.1.8 Chapter 1 of this manual defines apron taxiways and aircraft stand taxilanes and their interaction with the aircraft stands. Aircraft stand taxilanes branch off of apron taxiways, which in turn are generally located on the edge of the apron pavement.

Service roads

1.1.9 Chapter 4 of this manual discusses the need for and location of service roads. The space needed for service roads must be considered during the overall apron planning. They are usually located either adjacent and parallel to the terminal building or on the airside of the aircraft stand parallel to the aircraft stand taxilane. The width required will depend upon the anticipated level of traffic and whether a one-way road system can be developed. If the service road is located adjacent to the terminal building, adequate clearance must be available under the loading bridges for the largest vehicles expected to use the road. If the service road is not adjacent to the terminal building, the difficulty of providing the necessary headroom under bridges is eliminated, but it introduces the problem of vehicle/aircraft conflict. Overall apron planning should also take into account manoeuvring and storage areas for ground equipment.

3.5 APRON GUIDANCE

In the Aerodrome Design Manual (Doc 9157), Part 4 - Visual Aids, the benefits of apron marking and lighting, as well as guidance on aircraft stands, are discussed. The objective of guidance on aircraft stands is to provide safe manoeuvring of aircraft on the aircraft stand and precise positioning of aircraft. Generally, during good visibility periods, the use of painted lines and, if necessary, marshallers will ensure safe, accurate movements. Floodlighting on the apron area should be added for night operations and when visibility is poor, pavement centre line lighting should be provided. Visual docking guidance systems provide accurate guidance for an aircraft parking under its own power.

3.6 DE-ICING/ANTI-ICING FACILITIES

Location

3.6.1 Centralized de-icing/anti-icing facilities at or adjacent to terminals can be used if the demand for gate positions would not cause excessive delays, congestion and long waiting periods, and if the taxiing time from the terminal to the take-off runway would be less than the hold-over time of the fluid being used. An off-gate facility or a remote facility would permit better utilization of aircraft stands, compensate for changing weather conditions due to a shorter taxiing time and, consequently, ensure availability of a greater portion of the hold- over time.

3.6.2 An off-gate facility along a taxiway may lead to queuing of aeroplanes and thus should have bypass taxiing capability as shown in Figure 3-7. An off-gate facility better permits collection of de-icing/anti-icing fluid run-off for its safe disposal than do aircraft stands. Where holding bays of adequate size and capacity are provided, these could be used for de-icing/anti-icing of aeroplanes provided all the above requirements are fulfilled. The taxiing routes for access to the de-icing/anti-icing pads should have minimum turns and intersections for expediting the movement of aeroplanes, while not affecting operational safety.

3.6.3 In order that de-icing/anti-icing facilities may operate efficiently, and to prevent the likelihood of runway incursions by service vehicles, vehicle service roads or staging areas may be required. Consideration should be given to ensure that the emergency response times of aerodrome rescue and fire fighting vehicles are not compromised. These service roads should take into account operational and safety factors (prevention of runway/taxiway incursions) as well as environmental factors (management of de-icing/anti-icing fluid run-off, etc.). Appropriate surface movement guidance and control (SMGC) signs, such as vehicle stop signs or road-holding position signs, may need to be installed.

Figure 3-7. Minimum separation distance on a de-icing/anti-icing facility

Factors affecting the size of the de-icing/anti-icing facility

3.6.4 The size of a de-icing/anti-icing facility is dependent on the size of the aircraft, the number of aircraft requiring the treatment, the meteorological conditions, the type and capacity of the dispensing equipment used and the method of treatment. An indication of the total size of the facility could be estimated from the number of aircraft requiring treatment at a given time. The transit time of de-icing/anti-icing vehicles between the refilling/storage area and the de-icing/anti-icing facilities should also be taken into account.

Factors affecting the number of de-icing/anti-icing pads

3.6.5 The number of pads required is dependent on:

a) the meteorological conditions - at airports where wet snow or freezing rain conditions are more prevalent, a greater number of de-icing/anti-icing pads are recommended to be provided to prevent unacceptable delays;

b) the type of aeroplanes to be treated - narrow-body aeroplanes require less processing time than do wide-body aeroplanes. Aeroplanes with fuselage- mounted engines require more processing time than those with wing-mounted engines;

c) the method of application of de-icing/anti-icing fluid - the method may be either the one-step or two- step de-icing/anti-icing procedure. As the latter procedure results in longer occupancy times, the number of de-icing/anti-icing pads required should be based on the two-step procedure for flexibility and also to ensure that the maximum aeroplane departure flow rates are not adversely affected;

d) the type and capacity of the dispensing equipment used - mobile de-icing/anti- icing equipment with small tank capacities and requiring extended fluid heating times can increase application times and adversely affect the aeroplane departure flow rates; and

e) the departure flow rates - the number of aeroplanes to be treated should match the number of takeoff operations that can be cleared to minimize possible delays and airport congestion.

Environmental considerations

3.6.6 The size of a de-icing/anti-icing pad should be equal to the parking area required for the most demanding aeroplane and should also provide a 3.8 m vehicle movement area all round. Where more than one de-icing/anti-icing pad is provided, there should be no overlap of the vehicle movement area required exclusively for each pad. Furthermore, while planning the total size of a de-icing/anti-icing facility, the minimum clearances specified in Chapter 3 of Annex 14, Volume I should be taken into account.

3.6.7 Excess de-icing/anti-icing fluid running off an aeroplane poses the risk of contamination of ground water if allowed to mix with other surface run-off. Furthermore, the fluids also have an adverse effect on the pavement surface friction characteristics. Therefore, it is imperative that an optimum quantity be used. Nevertheless, all excess fluids must be properly collected to prevent ground water contamination. All surface run-off from such areas must be adequately treated before discharging into storm water drains.

3.6.8 One approach would be to collect all apron surface run-off at a collection point where the contaminated run-off could be suitably treated before discharging it to the storm water drains. Grooving of the pavement would facilitate in the collection of all excess de- icing/anti-icing fluids. In case of remote de-icing/anti-icing pads, the collection and handling of the excess fluid is relatively easier than at aircraft stands.

CHAPTER 4

SEGREGATION OF TRAFFIC ON THE MOVEMENT AREA

4.1 NEED FOR TRAFFIC SEGREGATION

4.1.1 The potential for aircraft and ground vehicle interactions exists on the runways, taxiways and aprons that make up the aircraft movement area. The number of interactions can be minimized, however, in the planning phase of the aerodrome facility by segregating the air and ground traffic. Properly segregated traffic will minimize the possibility of aircraft and ground vehicle collisions and maximize the efficiency of aircraft movements. Those interactions that are necessary should be planned for predesignated areas using established procedures.

4.1.2 There is a need for some ground vehicles to operate on the movement area for the purposes of aircraft servicing, aerodrome maintenance and construction work, and emergency operations. However, because of the different physical characteristics of aerodromes, no specific design criteria can be established to promote segregation of traffic. There are, however, a number of measures that may be taken to lessen the amount of mixing of aircraft and ground vehicles.

4.2 ACTIVITIES CAUSING A MIX OF AIRCRAFT AND GROUND VEHICLES

4.2.1 The majority of interactions that can occur between aircraft and ground vehicles take place on apron areas. The following are some aircraft servicing operations performed on aprons that may involve attendance of ground vehicles and that should be taken into account when planning segregation of traffic on aprons:

a) passenger unloading/loading;

b) baggage unloading/loading;

c) cargo and/or mail unloading/loading;

d) galley service;

e) sanitation service;

f) fuelling service;

g) provision of compressed air forengine starting;

h) aircraft maintenance; and

i) electric power and air conditioning (if not provided by aircraft auxiliary power units).

In addition, provision should be made for emergency and security vehicles on the apron areas.

4.2.2 Ground vehicle activities that occur on movement areas outside of the aprons include the following:

a) Emergency operations. Rescue and firefighting equipment, which may be required at any point on the aerodrome or runway approach areas;

b) Security operations. Small vehicles used for the patrol of fence lines and restricted areas;

c) Aerodrome maintenance and construction. Repair of pavements, navigation aids and lighting, grass mowing, snow/ice removal operations, etc.

4.3 METHODS TO ACHIEVE SEGREGATION

4.3.1 Several general concepts for achieving segregation of traffic are presented in the following paragraphs. For apron areas in particular, the degree of segregation which can be achieved depends largely on the available space. The greater the amount of space available for a given number of aircraft stands, the easier it is to segregate types of traffic. Normally, the need for economy is such that aprons are rarely designed with excess area and, in any case, air traffic growth generally absorbs any designed spare apron area. The degree of segregation necessary is dependent on the dimensions and other characteristics of aircraft (e.g. wing span, manoeuvrability and jet blast) and the nature of the ground vehicles. In addition, when planning an aerodrome, aircraft operators should be consulted to determine their anticipated ground vehicle movement requirements.

Exclusion

4.3.2 Although the design of aerodrome facilities can ease considerably the problem of mixing of aircraft with ground vehicles, it is nevertheless most important that aircraft operators be conscious of the need to keep the volume of their ground traffic to a minimum. All ground vehicles whose function does not require them to be on the movement area should be excluded. This practice is also in accord with basic aerodrome security measures. Landside road systems should be designed so that public vehicles have access to all public areas of an aerodrome without travelling on the movement area. Measures should also be taken to prevent unauthorized access of public vehicles to the movement area. This requires the provision of fences, gates and other security systems needed to strictly control access.

Service roads for ground vehicles

4.3.3 Airside service roads for ground vehicles can eliminate or lessen to a great extent the necessity for the use of runways and taxiways by ground vehicles. Such roads should be planned so that at least the critical sections of the movement area for traffic congestion can be bypassed by ground vehicular traffic. For example, these roads may be used as aerodrome perimeter service roads providing access to navigation aids, as temporary roads for construction vehicles or as airside roads between terminal buildings and aprons for the passage of airline vehicles, baggage trains, etc. For terminals with passenger loading bridges, airside roads may (for some designs) pass beneath the immovable part of the loading bridge. Figure 4-1 shows examples of airside service roads used on aprons.

4.3.4 Some general considerations in the planning of roads are described as follows:

a) Every effort should be made to plan airside service roads so that they do not cross runways and taxiways. At high-traffic aerodromes, road tunnels beneath runways and taxiways should be considered at major intersections in order to avoid such crossings;

Figure 4-1. Examples of airside service roads

b) The planning of the aerodrome road layout should take into account the need to provide emergency access roads for use by rescue and fire fighting vehicles to various areas on the aerodrome and in particular to the approach areas up to 1 000 m from the threshold, or at least within the aerodrome boundary;

c) Service roads to navigation aids should be planned in such a manner as to present minimal interference to the function of the aids. If it is necessary for an access road to cross an approach area, the road should be located so that vehicles travelling on it are not obstacles to aircraft operations; and

d) The airside service road system must be designed to account for local security measures. Access points to the system will thus need to be restricted. Should ground vehicle movements affect surface movement of aircraft on runways and taxiways, it will be required that the ground vehicle movements be coordinated by the appropriate aerodrome control. Control is normally exercised by means of twoway radio communication, although visual signals, such as signal lamps, are adequate when traffic at the aerodrome is light. Signs or signals may also be employed to aid control at intersections.

Fixed servicing installations

4.3.5 Many apron service vehicles can be eliminated with the provision of fixed servicing installations set either within the apron or within the terminal buildings adjacent to the aircraft stands. For example, the provision of hydrant fuelling systems, compressed air outlets, static power supplies, drainage outlets, drinking water hydrants, air conditioning outlets and telephone outlets close to aircraft stands would considerably reduce the equipment and vehicles required for aircraft servicing. Loading bridges for passenger loading and unloading can also be thought of as a form of fixed servicing installation as they eliminate the need for passenger loading equipment and the need for passengers to travel over the apron (either by walking or in a passenger transport vehicle). Furthermore, loading bridges generally lend themselves to the provision of fixtures for aircraft servicing operations. Some of the disadvantages of fixed servicing installations are high initial costs and limited flexibility for different aircraft types. However, if in the planning stage careful consideration is given to the location and number of these facilities, the required flexibility can be achieved. In addition, the different power supply requirements of present-day aircraft complicate the provision of static power supplies; however, the trend in aircraft design is towards greater standardization of electrical requirements. See the Airport Planning Manual (Doc 9184), Part 1 - Master Planning, for planning considerations regarding fixed servicing installations.

Markings

4.3.6 Paint markings should be used to facilitate the segregation of traffic on aprons.

Markings can be used to provide guidance to pilots in manoeuvring their aircraft safely and expeditiously on aprons. Other markings are used to designate safety limits for placement of equipment on aprons, e.g. wing tip clearance lines and other markings used to delineate access routes for ground vehicles, passengers or personnel across the apron. There should be a colour change between lines to distinguish one from another.

APPENDIX 1

FILLET DESIGN

1. TERMINOLOGY AND SYMBOLS

1.1 General

A description of the terms and symbols used in this appendix is given below. Throughout this appendix it is assumed that the aircraft is taxiing on a horizontal pavement.

1.2 Terms related to the aircraft

(see Figure A1-1)

Centre line through main undercarriage. Line from the turning centre perpendicular to the aircraft longitudinal axis.

Datum length (d). Distance between aircraft datum point and centre line through undercarriage.

Datum point of aircraft (S). Point on longitudinal axis of aircraft which follows the guideline on the ground. The datum point is located vertically beneath the cockpit of the aircraft.

Main undercarriage centre (U). Point of intersection of longitudinal aircraft axis and centre line through main undercarriage.

Nose wheel steering angle. Angle formed by the longitudinal axis of aircraft and the direction of the nose wheel.

Steering angle (fi). Angle formed by the tangent to the guideline and the longitudinal axis of aircraft.

Track of the main undercarriage (T). Distance between the outer main wheels of aircraft including the width of the wheels.

Turning centre (P). Centre of turn of aircraft at any time.

1.3 Terms related to taxiway and fillet design

(see Figure A1-2)

Deviation of main undercarriage (Ả). Distance between main undercarriage centre (U) and the guideline measured at right angles to the latter.

Guideline. Line applied to the pavement by means of markings and/or lights which the aircraft datum point must follow while taxiing.

Guideline centre (O). Centre of curvature of guideline at point S.

1.4 Glossary of symbols

The following symbols are used when describing the path of the main undercarriage centre and the design of the fillets (see Figures A1-1 and A1-2).

d = aircraft datum length

M = minimum clearance distance between outer wheels of main undercarriage leg and edge of pavement

O = centre of curvature of guideline at point S

P = turning centre

r = radius of fillet arc

R = radius of curvature of guidelineat point S S = datum point of aircraft

T = track of the main undercarriage

U = main undercarriage centre

α = angle between the radial line OU and the tangent to the path of the main undercarriage centre at U

β = steering angle

ƛ = main undercarriage deviation

p and 3 = polar coordinates of a point [(s) or (U), as applicable]

2. DETERMINATION OF THE PATH FOLLOWED BY THE MAIN UNDERCARRIAGE OF A TAXIING AIRCRAFT

2.1 Determination of the path by calculation

General

2.1.1 In general, the junction or intersection of taxiways with runways, aprons and other taxiways is achieved by means of an arc of a circle (Figure A1-2B). The calculations below are therefore restricted to the solutions based on this assumption. Nevertheless, the following calculation is more general than the one strictly necessary for the study of fillets. It also applies to movement of an aircraft leaving its parking position on an apron or manoeuvring on a holding bay.

Figure A1-1.Terms and symbols related to aircraft

Note: Figure shows:

a) the location of the taxiway centre line;

b) two fillets, each comprising an arc of a circle and two tangents;

c) the aeroplane cockpit follows the taxiway centre line.

B. Terms

Figure A1-2. Terms and symbols related to taxiway and fillet design

Datum point (S) follows an arc of a circle

Locus of main undercarriage centre (U)

2.1.2 Because of the simplifying assumption above, the datum point of the aircraft (S) follows an arc of a circle with centre O and radius R during the turn. In order to describe the movement of a taxiing aircraft, it is necessary to have a reference coordinate system. Let OX be the datum line, ρ and θu be the polar coordinates of U (see Figure A1-3). During movement, the straight line US remains a tangent to the path of the point U at U. This condition produces the differential equation for the locus of U:

Figure A1-3. Study of the path of the main under carriage

2.1.3 Special case: R = d. Integration is only easy in the particular case when R = d (see Figure A1-3B). Indeed, if R, the radius of curvature of the guideline, is equal to d, then the datum length of the aircraft would be:

2.1.4 General case: R ≠ d. If R is not equal to d, equation (4) can only be evaluated by solving an elliptical integral. Such an evaluation requires appreciable calculations which cannot be justified for the purpose of fillet design. The alternative method using an approximation described in 2.1.2 equation (4) avoids excessively laborious calculation and still provides a fillet design of adequate accuracy.

2.1.5 Knowledge of the steering angle (β) at any point of the path of the aircraft datum point (s) easily enables the locus of the main undercarriage centre (U) to be found and hence the path of the undercarriage during the turn to be derived. Let now O be the guideline centre and R its radius. Assuming that the steering angle (β) remains unchanged, the instantaneous centre of rotation of the aircraft at a given time is P and not O. Consequently, during the short taxi run, the datum point would have departed from the guideline and covered an arc subtending a small angle equal to:


Figure A1-4. Steering angle and deviations of the undercarriage when R=d


This condition produces the following biunivocal relationship between θS and β under the given initial conditions:

2.1.6 Integration of this equation prompts the assumption that R/d = X and consideration of the one case when R > d, . Solving the equation with respect to β/2 and applying the initial conditions, it can be found that:

Deviation of main undercarriage centre (λ)

2.1.7 On an apron, depending on the initial conditions, the deviation of U can be inside or outside the guideline followed by S (see Figure A1-5). On a runway or a taxiway when the aircraft datum point (S) enters the turn, the initial deviation of the main undercarriage centre is outside the arc of circle and during the turn it gradually tracks in. At any time therefore (see Figure A1-3):

The solutions of this equation produce the following deviation values:

where the positive sign must be used in case of deviation outside the arc of circle and the negative sign in case of deviation inside the arc of circle.

Figure A1-5. Deviation of main undercarriage centre when the datum point follows an arc of circle

Datum point (S) follows a straight line

Locus of main undercarriage centre (U)

2.1.8 Having completed the curve, the datum point (S) follows a straight path along the taxiway centre line. The steering angle is progressively reduced and the main undercarriage centre describes a tractrix (see Figure A1-6). As a result,

enables the steering angle to be calculated when the datum point (S) has travelled through a distance F along the straight taxiway centre line.

Deviation of main undercarriage centre (λ)

2.1.9 When the datum point (S) has covered the distance F along a straight segment of the guideline (see Figure A1-6) the steering angle (β) has assumed the value calculated in the first equation of 2.1.3 and the deviation of the main undercarriage centre (U) is given by:

Figure A1-6. Deviation of the main undercarriage centre when the datum point follows a straight line

Results of the above calculations

2.1.10 The calculations described above can be used to find the locus of the main undercarriage centre of an aircraft during a turn. Moreover, they permit plotting of graphs similar to those shown in Figures A1-7, A1-9, A1-11, A1-14, A1-15, A1-16 and A1-17. The use of these graphs as an aid for fillet design is described in 3.

2.2 Determination of the path with the aid of graphs

General

2.2.1 This method[I] involves determining several successive positions of the aircraft using the following parameters:

β = steering angle; and

λ = deviation of main undercarriage

and plotting the locus of the main undercarriage centre point by point during the manoeuvre of the aircraft. The graph obtained must be checked to verify that the steering angle during the turn remains within the permissible limits for the nose wheel of the aircraft in question.

Datum point (S) follows a straight line

Locus of the main undercarriage centre (U)

2.2.2 Figure A1-7 gives the deviation of the main undercarriage centre from a straight line knowing the initial deviation from that line and the distance travelled along it by the datum point.

Example

An aircraft of datum length 18 m follows a straight line for a distance of 40 m, as shown in Figure A1-8.

Step 1. Scale the initial deviation as shown. Initial deviation = 12 m = 66.7% of the datum length.

Step 2. The distance of 40 m travelled by the datum point is 216.7% of the datum length.

Step 3. The deviation of the undercarriage centre after the datum point has travelled along the straight line is 8.75% of the datum length as shown on Figure A1-7. The deviation in this position is 1.60 m.

Figure A1-7. Steering angle (β) and deviations (λ) of the main undercarriage centre when the datum point (S) follows a straight line

Figure A1-8. Example of the deviation of the main undercarriage centre (U) when the datum point follows a straight line

Datum point (S) follows an arc of a circle

Locus of the main undercarriage centre (U)

2.2.3 The graphs on Figure A1-9 have been drawn for selected values of the ratio:

The graphs have been prepared for R/d values ranging between 0.5 and 10.0. These values are marked above every graph which shows:

a) the deviation of the main undercarriage centre;

b) the steering angle (dashed curve)

as a function of the values assumed by the polar angle of the aircraft datum point.

Example

An aircraft of datum length 18 m follows an arc of circle of radius 27 m, as shown in Figure

A1-10.

Note: In the graphs, a dotted line for the steering angle corresponds to a solid line representing the deviation of the main undercarriage. When the deviation of the main undercarriage is indicated by a dot-dash line, the steering angle should be read on the corresponding dot-dash line.

Nose wheel deflection angles (β)

2.2.4 Knowing the ratio X of the datum length to the aircraft wheel base (distance between the nose wheel and the centre line through the main undercarriage), the nose wheel deflection angles can be read from Table A1 -1 for any given steering angle.

Example

An aircraft of datum length of 55 m and wheel base of 36.6 m develops a steering angle of 77.778° after negotiating an arc of a circle.


Figure A1-9. steering angle (β) and deviations (λ) of the main undercarriage centre when the aircraft datum point follows an arc of circle

Figure A1-9. steering angle (β) and deviations (λ) of the main undercarriage centre when the aircraft datum point follows an arc of circle (cont)

Figure A1-9. steering angle (β) and deviations (λ) of the main undercarriage centre when the aircraft datum point follows an arc of circle (cont)

Figure A1-9. steering angle (β) and deviations (λ) of the main undercarriage centre when the aircraft datum point follows an arc of circle (cont)

Figure A1-9. steering angle (β) and deviations (λ) of the main undercarriage centre when the aircraft datum point follows an arc of circle (cont.)

Figure A1-9. Steering angle (β) and deviations (λ) of the main undercarriage centre when the aircraft datum point follows an arc of circle (cont.)

Figure A1-9. Steering angle (β) and deviations (λ) of the main undercarriage centre when the aircraft datum point follows an arc of circle (cont.)


Figure A1-10. Example of locus of main undercarriage centre when datum point follows an arc of circle

Figure A1-11. Polar angle of aircraft datum point (S)

3. DESIGN OF FILLETS[2]

3.1 Graphic method

3.1.1 The graphic method consists in determining the fillet by drawing a plan to scale. The scale should be sufficiently large to ensure an adequate accuracy of the drawing. The plan can be drawn in selective stages as described below:

a) draw the centre lines of the taxiways (or runways) to be connected;

b) draw the edges of the taxiways and/or runways to be laid on the plan;

c) draw the path of the main undercarriage centre for the most exacting type of aircraft point by point; and

d) design the fillet.

3.1.2 The path of the undercarriage centre can be drawn by using the graphs on Figures A1-7 and A1-9 as described in 2.2. Various designs are acceptable for the fillet provided that the minimum clearance distances shown in Table A1-1 are complied with. To ensure that these clearance distance requirements are met, a practical method involves drawing a curve parallel to the path of the main undercarriage centre, which is located at a distance equal to (T/2 + M), and then drawing the fillet accordingly.

Example: Design of a fillet by the graphic method (see Figure A1-12)

Data
(m)

Taxiway change of direction

90°

Taxiway centre line radius (R)

36.6

Taxiway width (X)

23.0

Aircraft datum length (d)

18.3

Aircraft undercarriage track (T)

8.0

Safety margin (M)

4.0

Step 1. From Figure A1-9M for R/d = 2, extract:

a) the value of the polar angle for the datum point (S) at the beginning of the turn, the corresponding steering angle (β) being O;

b) the associated value or the main undercarriage centre deviation expressed as a decimal part of the datum length which is 0.235. Now list some values of λ/d and p for a sequence of θs (e.g. in increments of 20°). Next, draw the datum line and then plot the points as described in step 3 below.

Step 3. The curves can be drawn as follows:

a) draw the datum line as shown in Figure A1-12;

b) for each value of θs selected in step 1, plot the corresponding point U. For this, locate point S on the guideline, draw the longitudinal axis of aircraft with corresponding steering angle p and mark U at a distance d = 18.3 m from S. Using the values of λ/d in step 1, check the accuracy of the plotting;

c) where the datum point S again follows a straight line after coming out of the turn, using the values of λ/d and F/d from step 2, plot the locus of the undercarriage centre as shown in Figure A1-12;

d) on a perpendicular dropped from U onto the aircraft longitudinal axis, plot a distance inwards equal to (T/2 + M) = 4 + 4.0 = 8.0 m for each selected position of U. The line through these points is the curve parallel to the path of the main undercarriage centre. This is a theoretical minimum limit for the fillet.

Note: If the taxiway could be used by aircraft in both directions, draw the relevant curve as well.

e) select a design of fillet which can easily be staked out. As a rule it is preferable to choose an outline made up of straight sections and an arc of a circle. In the case in question an arc with a radius of 31.7 m is the easiest outline (Figure A1-12).

Step 4. Check the validity of the design, Figure A1-12:

a) the clearance distance is 4.0 m in compliance with the minimum recommended in Annex 14, Chapter 3 (see Table A1-1);

b) the maximum value (28°) of the steering angle is compatible with the operational limits of the nose wheel deflection for all the types of aircraft likely to use the aerodrome.

Figure A1-12. Graphic method for designing fillet

3.2 Arc-and-tangent method

3.2.1 The path of the main undercarriage centre of an aircraft during a turn is a complex curve, but it approximates an arc of a circle and its tangents. A design for a fillet which closely follows the main undercarriage path and allows for the safety margin required can be obtained by using:

a) an arc concentric with the taxiway centre line in order to provide the necessary additional width of pavement inside the turn; and

b) a tangent at each end of the arc providing a wedge-shaped end of the fillet to cater for residual deviation of the main undercarriage.

For drawing the fillet, it is sufficient to know the radius (r) of the arc and the length (l) of the wedge-shaped ends of the fillet (see Figure A1-13).

Determination of the radius of the fillet (r)

3.2.2 The fillet radius is equal to:

in which

R = radius of taxiway centre linetaken as guideline

λ max = maximum value of the deviation of the main undercarriage

M = minimum safety margin

T = track of main undercarriage

3.2.3 The maximum value of the main undercarriage deviation k max depends on the datum length (d), the radius of curvature of the taxiway centre line (R) and the rate of change in direction. This maximum value is obtained from Figure A1-14 as a percentage of the aircraft datum length for any value of ratio R/d included between 1 and 5.

3.2.4 When the aircraft datum length (d) is greater than the centre line radius (R), a construction line should be used with a value for the radius equal to the datum length, assuming R/d = 1. The points at which this construction line joins the straight section of the taxiway centre line should be marked for drawing in the wedge-shaped ends (see 3.2.8).

Figure A1-13. Design of a fillet by the arc-and-tangent method showing required clearance distances and calculated fillet

Figure A1-14. Maximum deviation (k max) of main undercarriage centre

Determination of the length of the wedge-shaped ends

3.2.5 Filleting is no longer required at the point where the main undercarriage deviation becomes less than the maximum deviation permissible without filleting:

where

X

=

taxiway width

M

=

minimum safety margin

T

=

track of main undercarriage

The residual deviation is reached at the end of the turn, when the datum point (S) has covered along the straight taxiway centre line a distance F given by the equation (17) in 2.1.8. The length of each wedge-shaped end of the fillet is therefore:

l = F - d

3.2.6 Equation (17) enables F to be expressed as a function of:

a) β, residual steering angle corresponding to λ, as obtained in 3.2.5 above; and

b) β max, maximum value of the steering angle during a turn. This value is reached when λ is equal to λ max, as given by Figure A1-14.

Use of prepared graphs avoids all calculation. The residual steering angle reached when the deviation is equal to the maximum permissible deviation without filleting is obtainable from Figure A1-15. (Figures are given to cover a datum length range between 12 and 60 m.) The maximum value of the steering angle during a turn is obtained from Figure A1-16 by reading from the taxiway change of direction to the ratio R/d and across to obtain the steering angle. Finally, Figure A1-17 enables the values of the steering angle to be converted into displacements along the straight guideline.

3.2.7 Care should be taken to ensure that the steering angle does not exceed the maximum nose wheel angle of the aircraft which are expected to use the aerodrome. If that were the case, the radius of curvature of the guideline and the size of fillet would have to be increased.

Note: Because the datum point does not generally coincide with the nose wheel, this introduces a slight error. This error, however, is on the safe side.

Drawing the fillet

3.2.8 The required fillet is obtained as follows:

a) Draw an arc concentric with the taxiway centre line using radius (r) (or, if necessary, an arc concentric with the construction line mentioned in 3.2.4).

b) Along the inside edge of the taxiway, mark Q1 and Q2 at distance l from the curved section of the guideline, as shown in Figure A1-13.

c) From the points obtained in b) above, draw tangents to the arc with radius (r).

3.2.9 The arc-and-tangent method is illustrated in Example 1.

Variant of arc-and-tangent method

3.2.10 A closer approximation to the required fillet can be obtained by the use of two fairing lines. The second point is obtained by recalculating the maximum permissible deviation without fillet but using a smaller safety margin. The practical method and the result obtained are illustrated in Example 2.

3.3 Quick reference graph method

3.3.1 The quick reference graphs enable the fillets of taxiways to be designed in a relatively simple manner, provided that constant values are given to certain variables:

- the width of the taxiways and the minimum clearance distance: corresponding to the code letter of longest runway served;

- datum length and undercarriage track: corresponding to most demanding type of aircraft involved.

3.3.2 Figure A1-20 has been prepared for a particular type of aircraft, namely the Boeing 747, and has been plotted on the basis of the following constant values, as recommended by Annex 14:

X - width of taxiways = 23 m

M - minimum clearance distance = 4.0 m

and taking as a guideline the taxiway centre line. In accordance with the provisions of Annex

14, the datum point selected is located vertically beneath the cockpit. The following constant values relate to this type of aircraft:

B747

Parameter

(m)

Datum length of aircraft

(d)

27.7

Undercarriage track

(T)

12.8

3.3.3 The edge of the fillet (Figure A1-21) is determined as follows:

Step 1. First the radius of the fillet arc (r) is determined by plotting the point corresponding to the change in direction of the taxiway and of the centre line curve radius on graph A in Figure A1-20. The value obtained by interpolation between the curves drawn for round values of r is used to draw an arc concentric to that of the guideline.

Step 2. The distance travelled (F) from the point when the fillet becomes unnecessary is obtained in the same manner by means of graph B on Figure A1-20. This gives the distance from the point where the inside edge of the taxiway becomes straight again.

Step 3. The arc tangents are drawn so that they intersect the edge of the taxiway at the end of the distance travelled (F). The line obtained is the required fillet as shown in the diagram (Figure A1-21).

Figure A1-15. Steering angle (β) and main undercarriage centre deviation (λ) (Figures and sloping lines show steering angles)

Figure A1-16. Increase of steering angle during a turn

Figure A1-17. Decrease of steering angle on completion of turn

Example 1: Fillet design using arc-and-tangent method (see Figure A1-18)

Figure A1-18. Typical fillet design, arc-and-tangent method (see Example 1)

Example 2: Compound fillet for longdatum, widetrack aircraft (see Figure A1-19)

Figure A1-19. Compound fillet for long-datum, wide-track aircraft (see Example 2)

Figure A1-20. Quick reference graph for Boeing 747 (cockpit over taxiway centre line)

Figure A1-21. Taxiway fillet diagram

Table A1-1. Relationship between steering angle and nose wheel deflection angle

Nose wheel deflection angle (°)

X = 1.0

X = 1.1

X = 1.2

X = 1.3

X = 1.4

X = 1.5

X = 1.6

X = 1.7

X = 1.8

X = 1.9

X = 2.0

0.5

0.500

0.550

0.600

0.650

0.700

0.750

0.800

0.850

0.900

0.950

1.000

1.0

1.000

1.100

1.200

1.300

1.400

1.500

1.600

1.700

1.800

1.899

1.999

1.5

1.500

1.650

1.800

1.950

2.100

2.249

2.399

2.549

2.699

2.848

2.998

2.0

2.000

2.200

2.400

2.599

2.799

2.998

3.198

3.397

3.597

3.796

3.995

2.5

2.500

2.750

2.999

3.249

3.498

3.747

3.996

4.245

4.494

4.742

4.991

3.0

3.000

3.299

3.599

3.898

4.196

4.495

4.793

5.091

5.389

5.686

5.984

3.5

3.500

3.849

4.198

4.546

4.894

5.242

5.589

5.936

6.283

6.629

6.974

4.0

4.000

4.399

4.797

5.194

5.591

5.988

6.384

6.779

7.174

7.568

7.961

4.5

4.500

4.948

5.395

5.842

6.288

6.733

7.177

7.621

8.063

8.505

8.945

5.0

5.000

5.497

5.993

6.489

6.983

7.476

7.969

8.460

8.949

9.438

9.925

5.5

5.500

6.046

6.591

7.135

7.677

8.219

8.758

9.296

9.833

10.368

10.900

6.0

6.000

6.595

7.188

7.780

8.371

8.959

9.546

10.131

10.713

11.293

11.871

6.5

6.500

7.144

7.785

8.425

9.063

9.698

10.331

10.962

11.590

12.215

12.837

7.0

7.000

7.692

8.382

9.069

9.754

10.436

11.115

11.790

12.463

12.132

13.797

7.5

7.500

8.240

8.978

9.712

10.443

11.171

11.895

12.615

13.332

14.044

14.751

8.0

8.000

8.788

9.573

10.354

11.131

11.904

12.673

13.437

14.196

14.951

15.700

8.5

8.500

9.336

10.167

10.995

11.818

12.635

13.448

14.255

15.057

15.852

16.642

9.0

9.000

9.883

10.761

11.635

12.502

13.364

14.220

15.070

15.912

16.748

17.577

9.5

9.500

10.430

11.355

12.273

13.185

14.091

14.989

15.880

16.763

17.638

18.505

10.0

10.000

10.977

11.947

12.911

13.867

14.815

15.755

16.686

17.609

18.522

19.425

10.5

10.500

11.523

12.539

13.547

14.546

15.536

16.517

17.488

18.449

19.399

20.339

11.0

11.000

12.069

13.130

14.181

15.223

16.255

17.276

18.286

19.284

20.270

21.244

11.5

11.500

12.612

13.720

14.815

15.899

16.971

18.031

19.079

20.113

21.134

22.142

12.0

12.000

13.160

14.309

15.447

16.572

17.684

18.583

19.867

20.937

21.992

23.031

12.5

12.500

13.705

14.898

16.077

17.243

18.394

19.530

20.650

21.754

22.842

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13.0

13.000

14.249

15.485

16.706

17.912

19.101

20.274

21.429

22.566

23.685

24.784

13.5

13.500

14.793

16.071

17.333

18.578

19.805

21.013

22.202

23.371

24.520

25.648

14.0

14.000

15.337

16.657

17.959

19.242

20.505

21.748

22.970

24.170

25.348

26.503

14.5

14.500

15.880

17.241

18.583

19.904

21.203

22.479

23.733

24.963

26.168

27.350

15.0

15.000

16.423

17.825

19.205

20.563

21.896

23.206

24.490

25.748

26.981

28.187

15.5

15.500

16.965

18.407

19.825

21.219

22.587

23.928

25.242

26.528

27.785

29.015

16.0

16.000

17.506

18.988

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21.873

23.273

24.645

25.988

27.300

28.582

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16.5

16.500

18.047

19.568

21.061

22.524

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25.358

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28.066

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30.644

17.0

17.000

18.588

20.147

21.675

23.172

24.636

26.066

27.463

28.825

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31.444

17.5

17.500

19.128

20.725

22.288

23.818

25.312

26.770

28.192

29.577

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32.235

18.0

18.000

19.667

21.301

22.899

24.460

25.984

27.469

28.915

30.321

31.689

33.017

18.5

18.500

20.206

21.876

23.508

25.100

26.652

28.162

29.632

31.059

32.445

33.790

19.0

19.000

20.745

22.450

24.115

25.737

27.316

28.851

30.343

31.790

33.194

34.553

19.5

19.500

21.282

23.023

24.719

26.371

27.976

29.535

31.048

32.514

33.934

35.308

20.0

20.000

21.820

23.594

25.322

27.001

28.633

30.214

31.747

33.231

34.666

36.052

20.5

20.500

22.356

24.164

25.922

27.629

29.285

30.889

32.440

33.940

35.389

36.788

21.0

21.000

22.892

24.733

26.520

28.254

29.933

31.558

33.127

34.643

36.105

37.514

21.5

21.500

23.427

25.300

27.116

28.876

30.577

32.221

33.808

35.338

36.812

38.232

22.0

22.000

23.962

25.866

27.710

29.494

31.218

32.880

34.483

36.026

37.512

38.940

22.5

22.500

24.496

26.430

28.301

30.109

31.854

33.534

35.152

36.708

38.203

39.639

23.0

23.000

25.029

26.993

28.891

30.722

32.485

34.183

35.814

37.283

38.886

40.330

23.5

23.500

25.561

27.554

29.478

31.330

33.113

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36.471

38.049

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41.011

24.0

24.000

26.093

28.114

30.062

31.936

33.737

35.465

37.122

38.709

40.229

41.684

24.5

24.500

26.625

28.673

30.644

32.539

34.356

36.098

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39.362

40.889

42.348

25.0

25.000

25.155

29.230

31.224

33.128

34.971

36.726

38.405

40.009

41.540

43.003

25.5

25.500

27.685

29.786

31.802

33.734

35.582

37.349

39.037

40.648

42.185

43.650

26.0

26.000

28.214

30.340

32.377

34.326

36.189

37.967

39.664

41.281

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44.288

26.5

26.500

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30.892

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36.792

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43.450

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27.0

27.000

29.270

31.443

33.520

35.502

37.390

39.188

40.899

42.525

33.071

45.541

27.5

27.500

29.796

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34.088

36.084

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39.791

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43.138

44.685

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28.0

28.000

30.323

32.540

34.653

36.664

38.575

40.389

42.111

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45.292

46.760

28.5

28.500

30.848

33.086

35.216

37.240

39.161

40.982

42.708

44.343

45.892

47.358

29.0

29.000

21.372

22.631

35.777

37.813

39.742

41.570

43.299

44.936

46.484

47.949

29.5

29.500

31.896

34.174

36.335

38.382

40.320

42.153

43.885

45.522

47.069

48.531

30.0

30.000

32.419

34.715

36.890

38.948

40.893

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44.465

46.102

47.648

49.107

30.5

30.500

32.941

35.255

37.443

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41.463

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45.039

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48.219

49.674

31.0

31.000

33.463

35.793

37.994

40.071

42.028

43.872

45.608

47.244

48.784

50.235

31.5

31.500

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36.329

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44.435

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49.342

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32.0

32.000

34.503

36.864

39.088

41.180

43.146

44.994

46.730

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49.893

51.334

32.5

32.500

35.022

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41.730

43.700

45.548

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48.910

50.438

51.874

33.0

33.000

35.540

37.929

40.172

42.276

44.249

46.097

47.810

49.454

50.077

52.406

33.5

33.500

36.057

38.459

40.170

42.819

44.794

46.642

48.372

49.991

51.509

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34.0

34.000

36.574

38.987

41.246

43.359

45.335

47.182

48.908

50.524

52.035

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34.5

34.500

37.090

39.514

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45.872

47.717

49.440

51.050

52.555

53.964

35.0

35.000

37.604

40.039

42.311

44.430

46.406

48.248

49.967

51.571

53.069

54.470

35.5

35.500

38.119

40.562

42.839

44.960

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48.775

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54.971

36.0

36.000

38.632

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45.467

47.461

49.297

51.005

52.596

54.080

55.465

36.5

36.500

39.144

41.604

43.889

46.011

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49.184

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53.101

54.577

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37.0

37.000

39.656

42.122

44.410

46.532

48.501

50.328

52.024

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55.068

56.435

37.5

37.500

40.166

42.639

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47.050

49.015

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38.0

38.000

40.676

43.154

45.445

47.565

49.526

51.341

53.024

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56.034

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38.5

38.500

41.185

43.667

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55.068

56.509

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39.0

39.000

41.693

44.179

46.471

48.585

50.537

52.339

54.005

55.548

56.978

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39.5

39.500

42.201

44.689

46.981

49.091

51.036

52.831

54.489

56.022

57.443

58.761

40.0

40.000

42.707

45.198

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49.594

51.533

53.320

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56.492

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59.210

40.5

40.500

43.213

45.704

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50.094

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55.443

56.957

58.357

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41.0

41.000

43.719

46.210

48.494

50.590

52.515

54.285

55.914

57.418

58.807

60.093

41.5

41.500

44.222

46.713

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42.0

42.000

44.725

47.215

49.492

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53.483

55.234

56.843

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59.692

60.956

42.5

42.500

45.227

47.716

49.988

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58.772

60.128

61.381

43.0

43.000

45.729

48.215

50.481

52.549

54.439

56.169

57.756

59.215

60.559

61.800

43.5

43.500

46.229

48.712

50.972

53.031

54.911

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58.206

59.654

60.986

62.216

44.0

44.000

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49.208

51.461

53.511

55.381

57.089

58.653

60.088

61.409

62.626

44.5

44.500

47.228

49.702

51.947

53.988

55.847

57.543

59.096

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63.033

45.0

45.000

47.726

50.194

52.431

54.462

56.310

57.995

59.534

60.945

62.241

63.435

45.5

45.500

48.224

50.685

52.914

54.934

56.770

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62.652

63.833

46.0

46.000

48.720

51.175

53.394

55.403

57.227

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60.401

61.878

63.058

64.227

46.5

46.500

49.216

51.663

53.872

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57.681

59.328

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62.202

63.460

64.616

47.0

47.000

49.711

52.149

54.347

56.333

58.132

59.765

61.254

62.613

63.858

65.002

47.5

47.500

50.205

52.634

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56.794

58.850

60.200

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63.021

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65.384

48.0

48.000

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53.118

55.293

57.253

59.025

60.631

62.092

63.425

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48.5

48.500

51.190

53.600

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65.031

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49.0

49.000

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56.230

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59.907

61.485

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64.222

65.415

66.508

49.5

49.500

51.173

54.559

56.696

58.614

60.343

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63.325

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66.876

50.0

50.000

52.663

55.037

57.159

59.063

60.777

62.326

63.730

65.007

66.172

67.240

50.5

50.500

53.152

55.513

57.621

59.510

61.209

62.742

64.131

65.394

66.546

67.600

51.0

51.000

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63.155

64.530

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67.957

51.5

51.500

54.128

56.461

58.539

60.396

62.063

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64.925

66.159

67.283

68.311

52.0

52.000

54.615

56.933

58.995

60.836

62.487

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65.317

66.537

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68.662

52.5

52.500

55.102

57.404

59.449

61.273

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68.008

69.010

53.0

53.000

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63.326

64.781

66.094

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68.366

69.355

53.5

53.500

56.072

58.341

60.351

62.142

63.743

65.181

66.478

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68.721

69.697

54.0

54.000

56.556

58.807

60.800

62.573

64.156

65.578

66.859

68.019

69.074

70.035

54.5

54.500

57.039

59.272

61.247

63.001

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65.972

67.238

68.383

69.423

70.371

55.0

55.000

57.521

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61.692

63.428

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66.364

67.614

68.744

69.770

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55.5

55.500

58.003

60.199

62.136

63.358

65.383

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70.114

71.035

56.0

56.000

58.484

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64.276

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67.141

68.358

69.458

70.455

71.363

56.5

56.500

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61.120

63.017

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66.190

67.526

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70.794

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57.0

57.000

59.444

61.579

63.456

65.115

66.590

67.909

69.093

70.161

71.130

72.011

57.5

57.500

59.923

62.037

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65.532

66.988

68.289

69.457

70.510

71.464

72.331

58.0

58.000

60.401

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67.384

68.667

69.818

70.856

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72.649

58.5

58.500

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64.762

66.360

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59.0

59.000

61.355

63.402

65.194

66.772

68.170

69.417

70.534

71.540

72.451

73.278

59.5

59.500

61.831

63.855

65.624

67.181

68.360

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70,889

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60.0

60.000

62.307

64.307

66.053

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70.158

71.242

72.216

73.098

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60.5

60.500

62.781

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64.481

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69.334

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74.205

61.0

61.000

63.256

65.207

66.907

68.400

69.719

70.892

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72.884

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74.509

61.5

61.500

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65.655

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68.802

70.101

71.255

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73.214

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74.812

62.0

62.000

64.202

66.102

67.775

69.204

70.482

71.617

72.632

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74.366

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62.5

62.500

64.674

66.549

68.177

69.603

70.861

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73.870

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75.411

63.0

63.000

65.146

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72.336

73.315

74.195

74.988

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63.5

63.500

65.617

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64.0

64.000

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75.603

76.295

64.5

64.500

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72.360

73.400

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65.0

65.000

67.027

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70.267

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76.211

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65.5

65.500

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77.164

66.0

66.000

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69.644

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73.468

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75.324

76.107

76.812

77.450

66.5

66.500

68.432

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73.834

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76.420

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67.0

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73.133

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78.017

67.5

67.500

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68.0

68.000

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76.631

77.349

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78.579

68.5

68.500

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73.143

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69.0

69.000

70.763

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73.549

74.667

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77.276

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78.587

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69.5

69.500

71.227

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76.847

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79.411

70.0

70.000

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75.427

76.361

77.184

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78.569

79.156

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70.5

70.500

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73.559

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77.520

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71.0

71.000

72.619

73.900

75.165

76.182

77.072

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78.550

79.171

79.728

80.232

71.5

71.500

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74.420

75.566

76.559

77.425

78.188

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79.470

80.012

80.503

72.0

72.000

73.544

74.850

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77.778

78.521

79.180

79.768

80.296

80.772

72.5

72.500

74.006

75.278

76.367

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78.129

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81.041

73.0

73.000

74.467

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77.681

78.480

79.182

79.805

80.360

80.859

81.309

73.5

73.500

74.929

76.134

77.164

78.053

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79.511

80.116

80.655

81.139

81.575

74.0

74.000

75.389

76.561

77.561

78.425

79.178

79.840

80.426

80.949

81.418

81.841

74.5

74.500

75.850

76.987

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79.525

80.167

80.735

81.241

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82.106

75.0

75.000

76.310

77.413

78.354

79.165

79.872

80.493

81.043

81.533

81.973

82.369

75.5

75.500

76.770

77.838

78.749

79.534

80.218

80.818

81.350

81.824

82.249

82.632

76.0

76.000

77.229

78.262

79.143

79.902

80.563

81.143

81.656

82.114

82.524

82.894

76.5

76.500

77.688

78.686

79.537

80.269

80.907

81.466

81.962

82.403

82.798

83.155

77.0

77.000

78.147

79.110

79.930

80.636

81.250

81.789

82.266

82.691

83.072

83.415

77.5

77.500

78.605

79.533

80.322

81.002

81.593

82.111

82.570

82.979

83.345

83.675

78.0

78.000

79.063

79.955

80.714

81.367

81.935

82.433

82.873

83.265

83.617

83.933

78.5

78.500

79.521

80.377

81.105

81.731

82.276

82.753

83.175

83.551

82.888

84.192

79.0

79.000

79.979

80.799

81.496

82.095

82.616

83.073

83.477

83.837

84.159

84.449

79.5

79.500

80.436

81.220

81.886

82.459

82.956

83.392

83.778

84.121

84.429

84.706

80.0

80.000

80.893

81.641

82.276

82.822

83.296

83.711

84.078

84.405

84.698

84.962

80.5

80.500

81.350

82.061

82.665

83.184

83.634

84.029

84.378

84.689

84.967

85.217

81.0

81.000

81.807

82.481

83.054

83.545

83.972

84.347

84.677

84.971

85.235

85.472

81.5

81.500

82.263

82.901

83.442

83.907

84.310

84.664

84.976

85.254

85.502

85.726

82.0

82.000

82.719

83.320

83.830

84.287

84.647

84.980

85.274

85.536

85.770

85.980

82.5

82.500

83.175

83.739

84.217

84.628

84.984

85.296

85.572

85.817

86.036

86.234

83.0

83.000

83.631

84.156

84.604

84.988

85.320

85.612

85.869

86.098

86.302

86.487

83.5

83.500

84.087

84.576

84.991

85.347

85.656

85.927

86.166

86.378

86.568

86.740

84.0

84.000

84.542

84.994

85.378

85.707

85.992

86.242

86.462

86.658

86.834

86.992

84.0

84.000

84.542

84.994

85.378

85.707

85.992

86.242

86.462

86.658

86.834

86.992

84.5

84.500

84.997

85.412

85.764

86.066

86.327

86.556

86.758

86.938

87.099

87.244

85.0

85.000

85.453

85.830

86.150

86.424

86.662

86.870

87.054

87.217

87.364

87.495

85.5

85.500

85.908

86.248

86.536

86.782

86.997

87.184

87.349

87.496

87.628

87.747

86.0

86.000

86.363

86.665

86.921

87.141

87.331

87.498

87.645

87.775

87.892

87.998

86.5

86.500

86.817

87.082

87.306

87.498

87.665

87.811

87.940

88.054

88.156

88.248

87.0

87.000

87.272

87.499

87.691

87.856

87.999

88.124

88.234

88.332

88.420

88.499

87.5

87.500

87.727

87.916

88.076

88.214

88.333

88.437

88.529

88.611

88.684

88.749

88.0

88.000

88.182

88.333

88.461

88.571

88.666

88.750

88.823

88.889

88.947

89.000

88.5

88.500

88.636

88.750

88.846

88.928

89.000

89.062

89.118

89.167

89.210

89.250

89.0

89.000

89.091

89.167

89.231

89.286

89.333

89.375

89.412

89.444

89.474

89.500

89.5

89.500

89.545

89.583

89.615

89.643

89.667

89.687

89.706

89.722

89.737

89.750

90.0

90.000

90.000

90.000

90.000

90.000

90.000

90.000

90.000

90.000

90.000

90.000

APPENDIX 2

JET BLAST AND BLAST FENCE CONSIDERATIONS

Introduction

1. “Jet blast” and “prop wash” are terms used to describe the air currents that emanate from the operation of jet and propeller engines, respectively. The design of ground facilities, buildings and pavements must take into account the impact of the forces that result from these air movements. Prior to the introduction of jet turbine engines, very little attention was focused, when planning facilities and pavements, on the detrimental effects of propeller wash. Service and maintenance areas were sometimes equipped with fences to deflect winds because of the close aircraft spacings used in these areas, but the design of aprons and terminal buildings was generally not influenced by propeller wash considerations. The introduction of the jet engine and the technological improvements that have been made towards increasing the power and efficiency of these engines have brought about a significant increase in blast velocities and, therefore, the need to design facilities to accommodate the wind forces associated with these velocities. This appendix describes the nature of these forces in terms of their magnitude and location and presents concepts in the location and design of blast fences and pavements which may be required at aerodromes to mitigate these wind forces.

Related effects

2. In addition to high wind velocities, the noise, heat and fumes from jet engine exhaust should also be anticipated when planning aerodrome facilities. However, the areas where the effects of jet engine exhaust are detrimental to personnel or buildings are usually unoccupied because of the high blast air velocities. The potential for sand, gravel or other loose objects to become projectiles and be thrown for great distances or drawn into engines must be mitigated. Such flying objects can injure personnel and damage equipment, facilities and other aircraft.

Design thrust levels

3. Three levels of engine thrust are commonly used to determine the critical velocities for use in building and pavement design: idle thrust, breakaway thrust and maximum continuous thrust (take-off thrust). Nearly all facilities adjacent to aircraft movement areas will be subjected to at least idle thrust from the engines on the critical design aircraft. Breakaway thrust is the level of thrust needed to initiate aircraft taxi movement and is generally 50 to 60 per cent of maximum continuous thrust. Areas typically designed for breakaway thrust may include terminal buildings, apron and taxiway shoulders, holding bays and all pavements except for the runways. Aircraft use maximum continuous thrust during take-off, and thus the runway pavement, shoulders and ends (blast pads) would be designed for this thrust level.

Threshold velocities

4. Jet blast velocities above 56 km/h are considered to be undesirable for personal comfort or for the operation of vehicles or other equipment on the movement area. Buildings can be designed to withstand much higher velocities, but the extra cost of construction needed to handle wind pressures above those normally used in building design may become prohibitive. Buildings are normally designed to handle winds of 130 to 200 km/h, depending upon locality. If design velocities are increased above this level because of blast, then the building structural frame and architectural facades will need to be strengthened accordingly. The tradeoff between increasing the cost of the building and other solutions to lower the blast velocities striking the building (such as erecting blast fences or increasing the apron size) must be examined for any given aerodrome.

BLAST VELOCITIES AND PRESSURES Velocity contours

5. Information on specific jet engine exhaust velocities, including lateral and vertical contours, for a given aircraft model is given in the Airplane Characteristics For Airport Planning document prepared for most aircraft models by the aircraft manufacturer. These documents are generally available from the manufacturers upon written request. Lateral and vertical contours for the B737-8, B747-8, MD-11 and B777-300ER at idle, breakaway and take-off power are shown in Figures A2-1 through A2-4. Table A2-1 shows the distance from the rear of an aircraft at which the blast velocity has been reduced to 56 km/h, the threshold for personal comfort, operation of vehicles or other equipment, for each of the four commercial aircraft types and thrust levels.

Blast pressure

6. The forces generated by jet blast can be calculated using formulas of the general wind pressure form P = C X V, where P is the pressure, C is a shape factor and V is the square of the wind velocity normal to the surface. Figure A2-5 presents a graph of pressure versus blast velocity and includes the general formula in terms of the units given for velocity and pressure. The upper curve gives the pressure on a flat surface oriented perpendicular to the direction of the blast which yields the greatest possible pressure. The lower curve is for a more aerodynamically shaped surface with a shape factor coefficient 70 per cent as great as the flat surface coefficient. The total force on a curved surface is found by multiplying the pressure by the area of the surface projected onto a plane perpendicular to the direction of the blast. Because pressure is a function of the square of the velocity, a doubling of velocity causes a quadrupling of pressure. On the other hand, a relatively small increase in the distance between the rear of an aircraft and buildings, equipment or personnel will yield a significant reduction in the pressure exerted by the blast on the object. Also shown on Figure A2-5 are representative blast velocities from Table A2-2 to show the relationship with the personal comfort level and the typical building design wind pressure.

Other considerations

7. Several additional factors which further define the nature of blast are as follows:

a) jet blast is irregular and turbulent in nature. When designing windows and elements of buildings less than 1.4 m, the vibrations caused by the cyclicality of blast velocities should be taken into account;

b) the height of the centre line of blast depends uponthe height and angle of the engines on the aircraft;

c) except for long-bodied aircraft, the lateral spreadof blast winds is generally confined within the wing tips of the aircraft for a significant distance behind the aircraft (see notes on Figures A2-1 through A2-4); and

d) ambient winds can increase, decrease or shift the engine blast, depending upon the direction of the wind. Allowance can be made for this factor by adding an ambient wind velocity (appropriate for a given locality) to the blast velocity.

BLAST FENCES

Application

8. Blast fences are used at aerodromes to reduce or eliminate the detrimental effects of blast by deflecting the high air velocities, heat, fumes and noise associated with blast. The application of either fences or screens becomes necessary when it is impractical to provide a safe, reasonable separation between aircraft engines and people, buildings or other objects on the aerodrome. Aerodrome locations requiring blast fences are indicated in Figure A2-6.

Planning criteria

9. The aircraft types and their possible movement patterns must be established when planning a system of blast fences for a new or existing aerodrome. Each segment of the aircraft movement area, including the aprons, taxiways, holding bays and runways, must be analysed to determine the magnitude and all possible orientations for blast in that particular location. For a new aerodrome, this information can be used as one of the many criteria needed to determine appropriate building restriction lines for the location of future facilities. For an existing aerodrome, this information can be used to determine where new blast fences should be located or modified because of the introduction of larger jets, the addition of new runways or taxiways, or a change in aircraft ground movement patterns.

Blast fences in apron areas

10. The type of apron movement pattern used by aircraft entering or exiting aircraft stands is a critical factor in determining the need for and location of blast fences. Figure A2-7 illustrates an example of the fence requirements for a self-manoeuvring aircraft stand and for the same stand using a taxi-in, push-out procedure. Because the aircraft on this self- manoeuvring stand must make a full 180° turn within the apron area under breakaway blast conditions, all areas along the public access road, service road and between aircraft parking positions can be subjected to excessive blast. As a result, fences will be required in all of these locations unless sufficient separation can be provided between the aircraft positions and the affected area. The situation becomes more complicated if passengers must walk on the apron to board the aircraft. Additional precautions may be required to protect them from the blast of aircraft entering or leaving adjacent stands. Had the apron been designed so as to use a nose- in, push-out procedure and nose-loading devices, only a blast fence along the public access road would be needed. This type of apron system has become more common at larger aerodromes serving the latest generation of jets because of the increasing problem with blast in the newer jets and the need to reduce the cost and complexity of accommodating blast on self-manoeuvring stands.

Blast fences in off-apron areas

11. Blast fences should also be used anywhere on an aerodrome where blast could cause a danger to personnel or inflict damage to buildings, equipment or other aircraft. They are often used along taxiways and near taxiway crossovers to protect hangars or terminal facilities where the aircraft can turn through 90 or 180 degrees. Another critical location is the area off the end of the runway, centred about the runway centre line, which should be examined closely because this area is subjected to the aircraft’s maximum continuous thrust on take-off. Roads or railways intersecting these areas may need the protection of blast fences. Of course the use of blast fences in any location should not cause a hazard to the movement of aircraft or ground vehicles (see Figure A2-7).

Other types of blast protection

12. Although the use of manufactured blast fences is effective, blast protection may be gained using other methods and materials. Any obstruction, either natural or constructed, will afford some level of protection. Hedges, bushes and trees can also help attenuate sound. Tall hedges may be used with great advantage in some cases such as around engine run-up areas.

DESIGN OF BLAST FENCES

13. Though often vital to the safe operation of an aerodrome, blast fences are rarely the starting point in the design of apron or aerodrome facilities. Instead, they are located only after the basic aerodrome layout has been determined and where it is most convenient with regard to aircraft or ground vehicle movements. In addition, the appearance of the fences will often be dictated by overall architectural considerations. For these reasons, the design of blast fences is difficult to standardize and often requires custom design.

Types of fencing

14. Fencing material can be either concrete or metal. Most premanufactured fences are metal. Concrete deflectors generally require much less maintenance. Louvred fences deflect the blast through their full height and therefore are subjected to lower wind forces than a solid fence for the same blast conditions. Baffles, perforations, louvres and corrugations can be used singly or in combination to most effectively reduce or eliminate blast effects behind the fence. Several types of blast fences are illustrated in Figure A2-8.

Structural design of blast fences

15. Both custom-designed and premanufactured blast fences require a thorough structural analysis to ensure that the fence used has adequate strength to carry the wind forces. The procedures which would be used in a typical design are summarized in the following paragraphs.

a) Gross wind pressure. For a given fence location, the worst possible blast velocity and pressure from the aircraft to be served at the aerodrome can be obtained from the aircraft manufacturers.

b) Height of fence. The blast fence should, at a minimum, be high enough to deflect the centre portion of the blast. This height is an aircraft-dependent variable and should be used in conjunction with the calculation of pressure to establish the critical fence section.

c) Shape and type of fence. The shape of the fence, whether curved, straight, angled or vertical, and the type of fence, such as solid or louvred, will determine the net wind pressure on the wall. Aerodynamically designed shapes and the use of openings in the fences will reduce the gross pressure requirements.

d) Analysis of forces. Given the net pressure on the wall, its height, the location of other supports such as braces or struts, and the type of materials used, the sizes and strengths of the members required for the wall can be determined. This procedure applies to premanufactured fence sections as well as custom- designed sections.

e) Foundations. The size and shape of the supporting foundation will depend on the factors listed in d) as well as the type of soils present in the area. Therefore, foundations, by necessity, are custom-designed.

BLAST PADS AND SHOULDERS

16. Shoulders adjacent to taxiways and runways and particularly the areas off the ends of the runways may be subjected to large blast forces. In fact, drag and uplift forces, caused by high-energy jet exhaust from turbine-engined aircraft, at 10.5 m behind the exhaust nozzle of an engine operating at maximum thrust, can raise boulders 0.6 m in diameter completely off the ground. The forces causing such erosion decrease rapidly with distance; beyond about 360 m from the engine of a long-bodied aircraft, they affect only sand and finer cohesionless soils. Blast pads and shoulder paving should be used as needed to mitigate the detrimental effects of these factors. Guidance on treatment of shoulders and blast pads is given in Chapter 1, 1.6.10.

Dimensions

17. Blast pads should have a width equal to the width of the runway plus shoulders. The length of blast pads may be determined as follows:

- For aircraft such as Boeing 747 and A380, a blast pad length of at least 120 m is recommended;

- For smaller aircraft, a blast pad length of 60 m is recommended.

Drainage

18. Drainage capability should be maintained or improved in the affected areas. Where pavement edge drop-off and five per cent transverse slope are present in existing turf areas, they may be retained in the new paved surface. It is recommended that courses of sufficient depth be provided to maintain the positive drainage of granular base or sub-base courses under the runway pavement. An alternative is the provision of subdrains at the pavement edge. A sufficient number of manholes should be provided in the subdrains to permit observation and flushing of the subdrain system. Manhole covers should be capable of withstanding the superimposed loads.

Special conditions

19. It is recognized that local conditions at some aerodrome sites may require additional surface protection from erosion. In those circumstances, it is recommended that additional pavement be provided. The pavement section and surface material to be used should be governed by past satisfactory local experience. In approving low-cost materials and procedures, maintenance time should be considered, particularly for areas adjacent to critical- use “operational areas” or “taxiways.”

Table A2-1. Distance at which blast velocity has been reduced to 56 km/h

Aircraft type

Idle thrust

(m)

Breakaway thrust

(m)

Take-off thrust

(m)

DC8

6

B727

29

49

130

B747

76

250

410

DC10

64

180

460

A320

17.5

48

380

B737-8

19

56

334

B777-300ER

43

99

689

B747-8

22

98

789

MD-11

65

160

564

A380

45

88

429

Table A2-2. Blast velocity levels

Blast velocity at 15 m from the tail

Blast velocity at 30 m from the tail

Aircraft type

Idle
(km/h)

Breakaway
(km/h)

Take-off
(km/h)

Idle
(km/h)

Breakaway
(km/h)

Take-off
(km/h)

Commercial jets

DC8

29

122

210

14

96

161

B727

106

193

530

53

96

290

B747

74

164

320

67

143

260

DC10

116

260

610

85

177

420

A320

60

120

224*

45

79

215*

B737-8

56

80

241

N/A

56

241

B777-300ER

56

80

161

56

80

161

B747-8

56

80

322

N/A

80

241

MD-11

72

120

322

56

120

322

A380

78

132

262*

67

111

254*

(*) extrapolated values

Business jets

Lear-Commander

47

95

215

21

43

98

Falcon

72

137

305

43

64

146

Sabreliner

79

162

370

35

74

169

Gulfstream-II

145

297

675

80

141

320

Figure A2-6. Aerodrome locations requiring blast fences

Figure A2-7.Blast fences in apron areas

Figure A2-8. Types of blast fences

APPENDIX 3

AEROPLANE CLASSIFICATION BY CODE NUMBER AND LETTER

Aeroplane reference field length

Wing span

Outer main gear wheel span

Aircraft Make

Model

Code

(m)

(m)

(m)

DeHavilland Canada

DHC2

1A

381

14.6

3.3

DHC2T

1A

427

14.6

3.3

Britten Norman

BN2A

1A

353

14.9

4.0

Cessna

152

1A

408

10.0

-

172 S

1A

381

11.0

2.7

180

1A

367

10.9

-

182 S

1A

462

11.0

2.9

Stationair 6

1A

543

11.0

2.9

Turbo 6

1A

500

11.0

2.9

Stationair 7

1A

600

10.9

-

Turbo 7

1A

567

10.9

-

Skylane

1A

479

10.9

-

Turbo Skylane

1A

470

10.9

-

310

1A

518

11.3

-

310 Turbo

1A

507

11.3

-

Golden Eagle 421 C

1A

708

12.5

-

Titan 404

1A

721

14.1

-

Piper

PA28-161

1A

4941

10.7

3.2

PA28-181

1A

4901

10.8

3.2

PA28R-201

1A

4871

10.8

3.4

PA32R-301

1A

5391

11.0

3.5

PA32R-301T

1A

7561

11.0

3.5

PA34-220T

1A

5201

11.9

3.5

PA44-180

1A

6711

11.8

3.2

PA46-350P

1A

6371

13.1

3.9

Raytheon/Beechcraft

A24R

1A

603

10.0

3.9

A36

1A

670

10.2

2.9

76

1A

430

11.6

3.3

B55

1A

457

11.5

2.9

B60

1A

793

12.0

3.4

B100

1A

579

14.0

4.3

Cessna

525

1B

939

14.3

4.1

DeHavilland Canada

DHC3

1B

497

17.7

3.7

DHC6

1B

695

19.8

4.1

LET

L410 UPV

1B

740

19.5

4.0

Raytheon/Beechcraft

E18S

1B

753

15.0

3.9

B80

1B

427

15.3

4.3

C90

1B

488

15.3

4.3

200

1B

579

16.6

5.6

Short

SC7-3/SC7-3A

1B

616

19.8

4.6

DeHavilland Canada

DHC7

1C

689

28.4

7.8

Lear Jet

24F

2A

1 005

10.9

2.5

28/29

2A

912

13.4

2.5

Pilatus

PC-12

2B

810

16.3

4.5

PC-24

2B

830

17.0

3.3

LET

L410 UPV-E

2B

920

20.02

4.0

L410 UPV-E9

2B

952

20.02

4.0

L410 UPV-E20

2B

1 050

20.02

4.0

L420

2B

920

20.02

4.0

Shorts

SD3-30

2B

1 106

22.8

4.6

Dassault Aviation

Falcon 10

3A

1 615

13.1

3.0

Hawker Siddley

HS 125-400

3A

1 646

14.3

3.3

HS 125-600

3A

1 646

14.3

3.3

HS 125-700

3A

1 768

14.3

3.3

Lear Jet

24D

3A

1 200

10.9

2.5

35A/36A

3A

1 287/1 458

12.0

2.5

54

3A

1 217

13.4

2.5

55

3A

1 292

13.4

2.5

Bombardier Aero.

CRJ 100

3B

1 470

21.2

4.0

CRJ 100ER

3B

1 720

21.2

4.0

CRJ 200

3B

1 440

21.2

4.0

CRJ 200ER

3B

1 700

21.2

4.0

Dassault Aviation

Falcon 20

3B

1 463

16.3

3.7

Falcon 200

3B

1 700

16.3

3.5

F50/F50EX

3B

1 586

18.9

4.5

Falcon 900

3B

1 504

19.3

4.6

Falcon 900EX

3B

1 590

19.3

4.6

F2000

3B

1 658

19.3

5.0

Embraer

EMB-135 LR

3B

1 745

20.0

4.1

Fokker

F28-1000

3B

1 646

23.6

5.8

F28-2000

3B

1 646

23.6

5.8

I.A.I.

SPX

3B

1 644

16.6

-

Galaxy

3B

1 798

17.7

-

Gulfstream Aero.

G IV-SP

3B

1 661

23.7

4.8

Nord

262

3B

1 260

21.9

3.4

Antonov

AN24

3C

1 600

29.2

8.8

Airbus

A220-100

3C

1 423

35.1

6.7

A220-300

3C

1 797

35.1

6.7

A318-100

3C

1 779

34.1

8.9

A319-100 w/o sharklets

3C

1 799

34.1

8.9

A319-100 with sharklets

3C

1 799

35.8

8.9

A319neo

3C

1 735

35.8

8.9

A320-200 w/o sharklets3

3C

1 797

34.1

8.9

A320-200 with sharklets3

3C

1 797

35.8

8.9

A320neo

3C

1 775

35.8

8.9

Boeing

B717-200

3C

1 670

28.4

5.4

B737-600

3C

1 690

34.3

7.0

B737-700

3C

1 598

34.3

7.0

B737-8003

3C

1 799

34.3

7.0

B737-9003

3C

1 799

34.3

7.0

B737-73

3C

1 799

35.9

7.0

B737-83

3C

1 799

35.9

7.0

B737-93

3C

1 799

35.9

7.0

Convair

240

3C

1 301

28.0

8.4

440

3C

1 564

32.1

8.6

580

3C

1 341

32.1

8.6

600

3C

1 378

28.0

8.4

640

3C

1 570

32.1

8.6

Douglas

DC3

3C

1 204

28.8

5.8

DC4

3C

1 542

35.8

8.5

DC6A/6B

3C

1 375

35.8

8.5

DC9-20

3C

1 551

28.5

6.0

Embraer

EMB-120 ER

3C

1 481

19.8

6.6

EMB-170-100 STD

3C

1 431

26.0

6.3

EMB-170-100 LR

3C

1 524

26.0

6.3

EMB-170-200 LR/SU

3C

1 715

26.0

6.3

EMB-190-100 STD

3C

1 614

28.7

7.2

EMB-190-200 STD

3C

1 779

28.7

7.2

Fokker

F27-500

3C

1 670

29.0

7.9

F27-600

3C

1 670

29.0

7.9

F28-3000

3C

1 640

25.1

5.8

F28-4000

3C

1 640

25.1

5.8

F28-6000

3C

1 400

25.1

5.8

F50

3C

1 355

29.0

8.0

McDonnell Douglas

MD90

3C

1 798

32.9

6.2

SAAB

340A

3C

1 220

21.4

7.3

340B

3C

1 220

22.84

7.3

SAAB 2000

3C

1 340

24.8

8.9

Airbus

A300 B2

3D

1 676

44.8

10.9

Bae

ATP

3D

1 540

30.6

9.3

DeHavilland Canada

DHC5D

3D

1 471

29.3

10.2

Bombardier Aero.

CRJ100LR

4B

1 880

21.2

4.0

CRJ200LR

4B

1 850

21.2

4.0

Dassault Aviation

Falcon 20-5 (Retrofit)

4B

1 859

16.3

3.7

Embraer

EMB-145 LR

4B

2 269

20.0

4.1

Airbus

A320-200 w/o sharklets

4C

2 111

34.1

8.9

A320-200 with sharklets

4C

2 108

35.8

8.9

A321-200 w/o sharklets

4C

2 513

34.1

8.9

A321-200 with sharklets

4C

2 513

35.8

8.9

A321neo

4C

2 366

35.8

8.9

BAC

1-11-200

4C

1 884

27.0

5.2

1-11-300

4C

2 484

27.0

5.2

1-11-400

4C

2 420

27.0

5.2

1-11-475

4C

2 286

28.5

5.4

1-11-500

4C

2 408

28.5

5.2

Boeing

B727-100

4C

2 502

32.9

6.9

B727-200

4C

3 176

32.9

6.9

B737-100

4C

2 499

28.4

6.4

B737-200

4C

2 295

28.4

6.4

B737-300

4C

2 160

28.9

6.4

B737-400

4C

2 550

28.9

6.4

B737-500

4C

2 470

28.9

6.4

B737-800

4C

2 090

34.3

7.0

B737-900

4C

2 240

34.3

7.0

B737-7

4C

2 375

35.9

7.0

B737-8

4C

2 600

35.9

7.0

B737-9

4C

3 100

35.9

7.0

Embraer

EMB-170-200 STD

4C

2 221

26.0

6.3

EMB-170-200 LR

4C

2 221

28.7

6.3

EMB-170-200 AR

4C

2 221

26.0

6.3

EMB-190-100 LR

4C

2 064

28.7

7.2

EMB-190-100 IGW

4C

2 220

28.7

7.2

EMB-190-200 LR

4C

2 179

28.7

7.2

EMB-190-200 AR

4C

2 383

28.7

7.2

Fokker

F100

4C

1 840

28.1

6.0

Gulfstream Aero

G V

4C

1 863

28.5

5.1

Douglas

DC9-10

4C

1 975

27.2

5.9

DC9-15

4C

1 990

27.3

6.0

DC9-20

4C

1 560

28.4

6.0

DC9-30

4C

2 134

28.5

5.9

DC9-40

4C

2 091

28.5

5.9

DC9-50

4C

2 451

28.5

5.9

McDonnell Douglas

MD81

4C

2 290

32.9

6.2

MD82

4C

2 280

32.9

6.2

MD83

4C

2 470

32.9

6.2

MD87

4C

2 260

32.9

6.2

MD88

4C

2 470

32.9

6.2

Airbus

A300B4-200

4D

2 727

44.8

11.1

A300-600R

4D

2 279

44.8

11.1

A310-300

4D

2 350

43.9

11.0

Boeing

B707-300

4D

3 088

44.4

7.9

B707-400

4D

3 277

44.4

7.9

B720

4D

1 981

39.9

7.5

B757-200

4D

1 980

38.1

8.6

B757-300

4D

2 400

38.1

8.6

B767-200

4D

1 981

47.6

10.8

B767-300ER

4D

2 540

47.6

10.9

B767-400ER

4D

3 130

51.9

10.8

Canadair

CL44D-4

4D

2 240

43.4

10.5

Ilyushin

18V

4D

1 980

37.4

9.9

62M

4D

3 280

43.2

8.0

Lockheed

L100-20

4D

1 829

40.8

4.9

L100-30

4D

1 829

40.4

4.9

L188

4D

2 066

30.2

10.5

L1011-1

4D

2 426

47.3

12.8

L1011-100/200

4D

2 469

47.3

12.8

L1011-500

4D

2 844

47.3

12.8

Douglas

DC8-61

4D

3 048

43.4

7.5

DC8-62

4D

3 100

45.2

7.6

DC8-63

4D

3 179

45.2

7.6

DC8-71

4D

2 770

43.4

7.5

DC8-72

4D

2 980

45.2

7.6

DC8-73

4D

3 050

45.2

7.6

McDonnell Douglas

DC10-10

4D

3 200

47.4

12.6

DC10-30

4D

3 170

50.4

12.6

DC10-40

4D

3 124

50.4

12.6

Tupolev

TU134A

4D

2 400

29.0

10.3

TU154

4D

2 160

37.6

12.4

Airbus

A330-200

4E

2 820

60.3

12.6

A330-300

4E

2 776

60.3

12.6

A340-200

4E

2 891

60.3

12.6

A340-300

4E

2 989

60.3

12.6

A340-500

4E

3 023

63.4

12.6

A340-600

4E

3 189

63.4

12.6

A350-900

4E

2 631

64.7

12.9

A350-1000

4E

2 754

64.7

12.8

Boeing

B747-100

4E

3 060

59.6

12.4

B747-200

4E

3 150

59.6

12.4

B747-300

4E

3 292

59.6

12.4

B747-400

4E

2 890

64.95

12.6

B747-SR

4E

1 860

59.6

12.4

B747-SP

4E

2 710

59.6

12.4

B777-200

4E

2 390

61.0

12.9

B777-200ER

4E

3 110

61.0

12.9

B777-300

4E

3 140

60.9

12.9

B777-300ER

4E

3 120

64.8

12.9

B787-8

4E

2 600

60.1

9.8

B787-9

4E

2 800

60.1

9.8

B787-10

4E

2 800

60.1

9.8

McDonnell Douglas

MD11

4E

3 130

52.05

12.6

Airbus

A380

4F

2 865

79.8

14.3

Boeing

B747-8

4F

2 956

68.4

12.7

B777-9

4F

2 9006

71.8

12.8

1. Over a 15 m obstacle.

2. With wing tip tanks installed.

3. Alternate maximum take-off weight consult manufacture airport planning manual or airline operator.

4. With extended wing tips.

5. Winglets.

6. Preliminary data.

APPENDIX 4

TAXIWAY DEVIATION STUDIES

Introduction

Note: There have been several studies to measure aircraft deviations from taxiway centre lines. This appendix contains examples of studies conducted in London and Amsterdam. The results are specific or particular to each airport, pavement surfaces and weather conditions. While these studies may be of guidance to those intending to carry out similar studies, it may not be appropriate to use the results directly where any or some of the local factors are different from those used in these studies. Safety of operations must be the overriding concern whenever studies aimed at operating with separation distances less than the minimum safety clearances specified in Table 3-1 of Annex 14, Volume I are contemplated.

London/Heathrow study

1. A taxiway deviation study was carried out by British Airports Public Ltd. at London Heathrow Airport. Over 77 000 aircraft taxiing movements in all weather conditions were recorded. The purpose of the study was to show that pilots do not deviate significantly from the centre line when taxiing. The analysis of the data had two objectives. The primary objective was to estimate the probability of two Boeing 747-400 aircraft colliding wing tips when passing each other on parallel taxiways. The secondary objective was to estimate the expected number of years that would elapse before this collision occurred. The study also attempted to assess the adequacy of the separation distances between parallel taxiway runways and between taxiways and objects, as recommended in Annex 14, Volume I, Table 3-1.

Straight sections of taxiways

2. Based on some 2 000 observations of B747 deviations on the straight sections of taxiways, the study concluded that the probability of two B747-400 aircraft colliding when passing each other on parallel taxiways is around 10-8, i.e. 1 in 100 million. This assumes that the taxiway centre lines are 76.5 m apart and that the aircraft have a wing span of 65 m. Upon analysing the data in the large data base which had been established, there was ample evidence to indicate that taxiing aircraft do not deviate from taxiway centre lines to any great degree. The data also provided an estimate of the number of occasions per year that two standard B747s pass each other on Heathrow’s parallel taxiways. This would be about 80 occasions per year out of around 34 000 B747 air transport movements. This low figure occurredbecause, in the majority of cases, theaircraft would be moving in the same direction through the taxiway system. Departing aircraft use one runway and arriving aircraft use another; their paths rarely overlap.

Figure A4-1 shows the distribution of deviations upon which the analysis is based.

Curved sections of taxiways

3. It was considered that the probability of collision on curved sections on taxiways is of the same order of magnitude as in straight sections, i.e. 10-8. There were not enough observations of B747 deviations on the curved sections of taxiway to repeat the analysis detailed for straight sections. Data were collected at two locations. Data from the inner curve proved not to be useful because there was a large paved area to the inside of it which pilots tended to cut across. The number of observations on the outer curve was low because several months of maintenance work had closed that part of the taxiway. Figure A4-2 shows the distribution of the 185 B747 deviations observed on the outer curve. The negative numbers are deviations from the centre line towards the inside of the curve. This is in a different form to Figure A4-1 which shows only absolute deviations. Figure A4-2 shows that almost all aircraft main wheels cut across the corner. For a collision to occur at a curved part of the parallel taxiway, the outer aircraft must deviate to the inside and the inner aircraft must deviate to the outside. Figure A4-2 shows that the latter is very unlikely to happen. The overall distribution suggests that the collision probability would be similar to that of straight sections, i.e. 10-8 Curved sections of taxiways were regarded as less of a problem than straight sections of taxiways since there will always be fewer curved elements in a given taxiway layout. Thus, the chance that two aircraft pass on a curved section is much less than on a straight section.

Speed effect

4. The analysis showed that an aircraft’s speed does not affect its lateral deviation.

Bad weather effect

5. No link could be established between bad weather and large taxiway deviations. During the data collection period, most weather conditions were encountered including snow fall, heavy rain, strong winds and visibility reduced to 1 000 m.

Statistics for all aircraft

6. Tables A4-1 and A4-2 show summary statistics for all aircraft on the straight and the outer curved sections of taxiways, respectively.

Amsterdam Schiphol study

7. A taxiway centre line deviation test was conducted at Amsterdam’s Schiphol Airport from October 1988 to September 1991. Over 9 000 ICAO Category E aircraft (mostly B747) taxiing movements were recorded over the three- year span. Using infra-red beams, data were collected for a straight and a curved section of the taxiway. The taxiway width was 22.9 m. The curved section had a centre line radius of 55 m and a turn of 120 degrees. Centre line lighting was provided on both sections of taxiway.

8. The data were used by the Boeing Company to accomplish a statistical analysis of aircraft landing gear deviations. The purpose of the study was to estimate the extreme probabilities of gear deviations (those well outside the range of observed deviations), as well as to obtain estimates of the probability of wing tip contact between two aircraft on parallel taxiways.

9. A summary of statistics for the taxiway data is provided in Table A4-3. The data from the curved section indicates that pilots of large aircraft use a judgmental oversteer technique to insure that the main landing gear remains on the pavement.

Deviation probability estimates

10. The fact that data do not exist for gear deviations greater than 3.54 m on straight taxiways necessitates extrapolation for probabilities for greater deviations.

Wing tip contact probability

11. Using the extrapolated probabilities of extreme main gear deviations, the probabilities of wing tip-to-wing tip contact between two aircraft on parallel taxiways were calculated. These probabilities depend on the probability distribution of the sum of the two taxiway deviations, noting that two simultaneous deviations on parallel taxiways are statistically independent.

12. Table A4-4 summarizes estimates of required taxiway separations and estimated 90 per cent upper bounds for various wingspan probabilities.

Estimates of required taxiway separations

13. As an example, the mean estimate of taxiway separation required for a probability of a 109 wing tip contact between two aircraft with 73.2 m wingspans is 80.5 m.

Conditions affecting deviation

14. Some conditions that were recorded with the deviation were the year, month, day, time, taxi speed and direction. The variability of deviations was not affected by these factors. For example, the standard deviation on the straight section is 68.8 cm. The standard deviation is 67.1 cm after removing any systematic deviation due to taxi direction, season and time of day. Thus, the practical significance (in contrast to the statistical significance) of these effects may be minimal.

Figure A4-1. B747 main wheel deviations for straight sections of taxiway

Figure A4-2. B747 main wheel deviations for curved sections of taxiway

Table A4-1. Summary statistics (straight sections of taxiway)

Main wheel deviation (m)

Nose wheel deviation (m)

Speed (kt)

Aircraft

Mean

95%

Max

Mean

95%

Max

Mean

95%

Max

Observations

A310

0.60

1.42

9.0

0.56

1.37

9.1

18.8

25

35

1 213

B727

0.65

1.85

8.1

0.56

1.36

9.0

18.9

27

49

1 997

B737

0.81

1.90

9.1

0.68

1.62

8.5

17.2

25

35

9 035

B747

0.59

1.90

4.1

0.47

1.21

7.8

17.3

25

34

1 988

B757

0.72

1.74

7.9

0.63

1.43

6.1

16.1

24

35

6 089

BAC1-11

0.65

1.53

9.5

0.63

1.49

8.2

15.8

23

33

3 749

DC9S

0.68

1.62

9.5

0.63

1.50

8.7

17.2

25

39

2 941

DC9

0.59

1.44

8.4

0.57

1.42

8.2

16.2

24

33

2 885

F27

0.95

2.39

9.6

0.62

1.47

9.6

17.9

26

32

1 075

F28

1.26

5.73

10.0

1.00

4.63

9.2

17.2

24

33

745

S360

0.80

2.00

7.4

0.63

1.43

9.2

17.1

23

27

1 528

L1011

0.50

1.22

8.9

0.46

1.13

5.2

17.1

25

31

722

Table A4-2. Summary statistics (outer taxiway curve)

Main wheel deviation (m)

Nose wheel deviation (m)

Speed (kt)

Aircraft

Mean

Min

5%

95%

Max

Mean

Min

5%

95%

Max

Mean

95%

Max

Observations

A310

-2.2

-6.4

-3.9

-0.5

+0.6

+0.54

-6.0

-1.3

+2.4

+4.6

16.0

21

27

848

B727

-1.92

-7.5

-3.7

+0.2

+2.5

+0.37

-5.2

-1.5

+2.2

+6.1

17.0

23

33

1 044

B737

-0.75

-5.0

-2.5

+0.9

+5.8

+0.32

-5.4

-1.4

+2.1

+5.4

16.6

22

30

3 152

B747

-3.31

-7.6

-5.7

-0.5

+0.1

-0.04

-4.1

-2.4

+2.6

+5.3

15.3

22

25

185

B757

-1.50

-7.7

-3.2

0.0

+2.5

+0.08

-3.7

-1.5

+2.0

+4.7

16.3

21

27

2 425

BAC1-11

-1.10

-9.7

-3.0

+0.7

+4.2

+0.47

-5.8

-1.4

+2.4

+6.1

16.4

22

27

962

DC9S

-1.09

-9.0

-3.2

+1.0

+3.6

-0.29

-8.3

-2.6

+1.9

+5.7

16.2

22

29

1 510

DC9

-1.11

-7.2

-3.0

-0.8

+2.0

+0.28

-3.0

-1.7

+2.3

+6.7

15.9

22

26

557

F27

-1.69

-7.4

-4.0

+0.4

+8.0

+0.39

-4.2

-1.4

+2.4

+9.2

17.1

23

27

465

F28

-1.33

-8.2

-3.8

+0.7

+9.2

+0.52

-8.9

-1.4

+2.5

+6.0

17.2

22

26

467

S360

-0.71

-9.6

-2.8

+1.1

+8.7

+0.47

-3.7

-1.3

+2.4

+4.2

17.0

22

25

534

L1011

-2.8

-5.9

-4.5

-0.8

+1.4

+0.18

 -4.4

-2.2

+2.3

+3.4

14.5

20

26

255

Table A4-3. Summary of taxiway data

ICAO

Code E Aircraft

B747 (All models)

Schiphol Report Code E Aircraft

Nose

Main

Nose

Main

Nose

Main

Straight section

Sample size

7 958

7 958

7 855

7 855

8 191

8 191

Mean (cm)

-14.8

-12.5

-15.2

-13.2

-8.0

-26.0

Std. dev. (cm)

68.5

76.4

67.4

68.8

68.0

70.0

Curved section

Sample size

1 382

1 382

1 351

1 351

1 380

1 380

Mean (cm)[3]

393.5

-202.2

400.3

-199.8

389

-199

Std. dev. (cm)

244.1

236.8

237.6

236.0

227

216

Table A4-4. Estimates of taxiway separations and 90 per cent upper bounds

Estimates

90% bounds

Wingspan

10e-6

10e-7

10e-8

10e-9

10e-6

10e-7

10e-8

10e-9

67

72.8

73.4

73.9

74.4

73.3

73.9

74.6

75.2

70

75.8

76.4

76.9

77.4

76.4

76.7

77.6

78.2

73

78.9

79.5

80.0

80.5

79.4

80.0

80.7

81.3

76

81.9

82.5

83.0

83.5

82.4

83.1

83.7

84.3

79

85.0

85.6

86.1

86.6

85.5

86.1

86.7

87.4

82

88.0

88.6

89.1

89.6

88.5

89.2

89.8

90.4

85

91.1

91.7

92.2

92.7

91.6

92.2

92.8

93.5

APPENDIX 5

DESIGN, LOCATION AND NUMBER OF RAPID EXIT TAXIWAYS

5.1 Process of determination of the optimal location of the turn-off point

5.2 Example for the use of the method described in Chapter 1, 1.3

The following example is provided to illustrate the use of the method described in Chapter 1, 1.3. The calculations are based on the following assumptions:

Aerodrome Reference Code number 4

In order to enhance runway capacity under specified conditions, a new exit should be located between 1 800 m and 2 500 m from threshold on a non- instrument runway with a length of 2 500 m. In the touch down area the runway slope is -0.75 per cent.

The exit should be commissioned by 2020.

The runway should provide its full capacity in strong headwind conditions (headwind > 15 kt). In this situation it is the only runway available for landing as well as for take-off at this airport, and it has to serve all types of aircraft.

In light wind conditions the runway is used exclusively for landing by commuter aircraft; for take-off, however, it is used by all types of aircraft, subject to the performance capabilities of the aircraft.

5.3 Example for the design of a non-standard rapid exit taxiway

Chapter 1, 1.3.19 and Figure 1-6 specify that the construction of a standard RET would normally require a distance between the centre lines of the runway and a parallel taxiway of at least

(where dR is the additional distance required for turns onto the taxiway centre line).

An alternate method for the construction of a parallel taxiway spaced at 120 m, which would accommodate a higher turn-off speed, as compared to a right-angled exit taxiway, is described below and shown in Figure A5-3.

The exit was designed as follows:

Centre line: The first part of the turn-off curve approximates the shape of a spiral, with an initial turnoff radius of 160 m changing to 100 m in the second part. When an angle of 60° between the taxiway centre line and the runway axis is reached, the radius changes to 40 m. The third part of the turn shows a constant radius of 40 m until the 180° turn is completed.

Turn-off speed: According to Chapter 1, Table 1-8, the turn-off speed is 24 kt for a radius of 160 m. The turn-off speed for a 40 m radius is 13 kt. The distance required for the aircraft to decelerate from 24 to 13 kt is approximately 140 m. This leads to a deceleration rate of a = 0.4 m/s2 along the turn-off curve, which is a safe value for all types of aircraft.

Inside fillet curve: The inside fillet curve was designed to allow access to all types of aircraft using this airport. The critical aircraft is the B777-300 which at the present time has the longest datum length.

Outer edge: In order to allow intersection take-offs from this exit, the outer edge is designed with a simple right angle. The distance from the centre line to the outer edge is 20 m at the closest point, providing adequate safety for all turning manoeuvres.

5.4 Calculation of the turn-off curve

The coordinates of the basic points of the turn-off curve were determined as shown in Figure A5-4 and in the following calculations (all values in metres).

With

R1 = 160 m

R2 = 100 m

R3 = 40 m

the calculations are valid for 112 m < s < 127 m where S is the distance from centre line RWY to centre line TWY.

Table A5-1. Anticipated fleetmix, 2020-2030

Aircraft

Share:

B747

1.2%

B777

1.2%

A340

6.7%

A3xx

0.2%

B757

1.4%

B767

1.7%

B737*

22.3%

A330

6.4%

A320*

35.9%

RJ*

18.1%

Misc.

4.9%

Total

100.0%

Table A5-2. Optimal turn-off points and segments

Turn-off point [m]:

Turn-off segment [m]:

A/C served at Vwind [kt]:

Sum of share [%]:

B737

A320

RJ

1 530

1 430 - 1 730

25

20, 25

59

1 620

1 520 - 1 820

20, 25

25

15, 20, 25

135

1 660

1 560 - 1 860

20, 25

25

15, 20

117

1 760

1 660 - 1 960

15, 20, 25

20, 25

15

157

1 800

1 700 - 2 000

15, 20

15, 20, 25

15

170

1 870

1 770 - 2 070

15

15, 20

0, 15

130

1 980

1 880 - 2 180

15

0

54

2 040

1 940 - 2 240

0

15

0

76

2 210

2 110 - 2 410

0

0

58

2 330

2 230 - 2 530

0

36

Figure A5-1. Optimal turn-off segment - A320

Figure A5-2. Optimal turn-off point

Figure A5-3. An alternative exit taxiway design

Figure A5-4. Calculation of the turn-off curve



[I] The graphs on Figures A1-7, A1-9 and Table A1-1 were prepared by Australia. The graphs can also be used for an aircraft manoeuvring on a holding bay or leaving an aircraft stand.

[2] The graphs in this section were prepared by the United Kingdom.

[3] Positive number indicates value outside of curved centre line. Negative number indicates value inside of curved centre line.

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