5 airport-geometric design-1
TRANSCRIPT
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CVLE 535AIRPORT ENGINEERING
Dr. Youssef Attallah
GEOMTRIC DESIGNOF AIRPORTS
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Review of geometric design standards Runway-runway separation standards Runway-taxiway separations Taxiway and taxilanes Runway exit types and kinematic
model application Runway exit locations Very large capacity aircraft ADG VI
(Airbus A380)
Outlines of this Presentation
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Source: FAA AC 5300-13 (Chapter 2) Dictated by safety analyses Provide sufficient space for expansion
and good movement of aircraft For regular aircraft (those than can be
classified according to the FAA design standard) use Tables
Study carefully Appendix 9 in FAA AC 5300-13 to understand the general geometric design rationale of the methods explained in Chapter 2
Taxiway and Runway Design Distances
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What is Included in FAA AC 150/5300-13?
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Size of Aircraft Design Group VI (Airbus A380 types)
ADG VI aircraft have total lengths ranging from 76 to 82 meters representing a modest increment from current Boeing 747-400 transports
Geometric Design Challenges
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ADG VI aircraft have total lengths of 230 feet today
ADG VI aircraft have wingspans around 15% larger than current transports (262 feet for Airbus A380)
Structural weight penalties of folding wings are unacceptable to most airlines
Large Wingspan Challenges
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Federal Aviation Administration (FAA)
Geometric Design Classification
FAA Approach Speed Classification
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Taxiway dimensional standards for aircraft design group VI have increased to avoid possible foreign object damage
200 foot wide runways and 100 foot wide taxiways
Impacts on Taxiway Design Standards
ADG VI Runway(200 feet wide – 61
meters)
ADG VI Taxiway(100 feet wide – 31
meters)
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Sample Airport to Learn Design Standards
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Taxiway and Runway Distances (TERP Groups A and B)
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Taxiway and Runway Distances(TERP Groups A and B)
Important Footnotes to Table 2-1 for Design
Source: FAA AC 5300-13 – Table 2-1
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Example Runway to Taxiway Dimensions
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Taxiway and Runway Distances(TERP Groups C and D)
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Taxiway and Runway Distances(TERP Groups C and D)
Important Footnotes to Table 2-2 for Design
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Taxiway/Taxilane Separation Standards
Source: FAA AC 5300-13 – Table 2-3
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Example (IAD Airport)
Image Source: U.S. Geological Survey
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Taxiway centerline to parallel taxiway/taxilane centerline require 1.2 times airplane wingspan plus 10 feet (3 m);
Taxiway centerline to fixed or movable object require 0.7 times airplane wingspan plus 10 feet (3 m);
Taxilane centerline to parallel taxilane centerline required 1.1 times airplane wingspan plus 10 feet (3 m.);
Taxilane centerline to fixed or movable object require 0.6 times airplane wingspan plus 10 feet (3 m.) and
Rules Used in Derivation of Taxiway/Taxilane
Separation Standards
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Dual taxilanes 2.3 times airplane wingspan plus 30 feet (10 m)
Aircraft parked at gates require wingtip to wingtip separations at gates or tie-down areas for safety: 10 ft. (3 m.) for aircraft in groups I and II 15 ft. (5 m.) for group III 20 ft. (6 m.) for group IV 25 ft. (8 m.) for group V 30 ft. (10 m.) for group VI
Source: FAA AC 150/5300-13
Aircraft Rights-of-Way Near Gate Areas
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Example: Dual Taxilane Between Two Terminal Buildings (Concourses)
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Example Dual Taxilane (IAD)
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Review of Runway Design (Table 3.1)
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Taxiway Safety Areas
Source: FAA AC 5300-13 – Table 4-1
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Many airports were designed and constructed before new standards were developed
Consequently many times we find that current geometric design standards are not met
These airports require Modification of Standards (MOS)
MOS are approved by FAA on a one-to-one basis
For example, the Airbus A380 requires a 200 foot wide runway (see ADG VI standards)
The FAA and ICAO have provided an MOS procedure whereby the A380 can operate from 150 foot runways with 50 foot stabilized shoulders
Design Standards and Old Airports
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Delta Airlines operates Boeing 767-300 into LGA
The critical aircraft wingspan is 156.08 feet (ADG IV)
Example of a Legacy Airport (LGA)
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Current Situation
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Recapitulation of FAA Standards
Required runway to taxiway centerline = 400 feet Available runway to taxiway centerline = ~350 feet A Modification of Standard (MOS) waiver is needed from FAA
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Taxiway centerline to parallel taxiway/taxilane centerline require 1.2 times airplane wingspan plus 10 feet (3 m)
Required for limiting ADG IV aircraft (171 foot wingspan) = 215 feet
Rule for Modification of Standards (MOS) = 1.2 * critical wingspan + 10 feet
Distance = 1.2 (156.08) + 10 feet = 197 feet Airport has 200 feet between parallel taxiways Boeing 767-300 operates from LGA
Sample Modification of Standards (MOS)
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Taxiway to Taxiway Standards
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Taxiway centerline to parallel taxiway/taxilane centerline require 1.2 times airplane wingspan plus 10 feet (3 m);
Taxiway centerline to fixed or movable object require 0.7 times airplane wingspan plus 10 feet (3 m);
Taxilane centerline to parallel taxilane centerline require 1.1 times airplane wingspan plus 10 feet (3 m.);
Taxilane centerline to fixed or movable object require 0.6 times airplane wingspan plus 10 feet (3 m.) and
Rules Used in Derivation of Taxiway/Taxilane
Separation Standards
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Located in FAA AC 150/5300-13, Chapter 5 (paragraphs 500-504)
Includes vertical profile limits for runways and taxiways Important to maintain line-of-sight in the operations Pilot to pilot ATC controller to aircraft
Runway and Surface Gradients
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Surface Gradient StandardsChapter 5 in AC 150/5300-13
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1.5 % maximum for runways serving transport aircraft. Up to 2% for general utility runways (Groups A and B) 1.5 % transverse from crest (groups C, D. and E) Maximum gradient change 1.5 % for groups C,D,
and E. Use 2% for groups A and B Vertical curve length (1000 x grade change in feet
for groups C, D, and E). Use 300 x grade change for groups A and B.
Minimum distance between points of intersection (1000 ft. for each 1% grade change for groups C,D, and E)
0.8 % grade in first quarter of runway (both ends)
Longitudinal Runway Grades
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Longitudinal GradesApproach Speed Groups A and B
Source: FAA AC 5300-13 – Figure 5-1
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Transverse Grades for Approach Speed Groups A and B
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Longitudinal GradesApproach Speed Groups C and D
Source: FAA AC 5300-13 – Figure 5-3
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Transverse Grades forApproach Speed Groups C and D
Source: FAA AC 5300-13 – Figure 5-4
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Longitudinal and Transverse Grades
Of Runway Safety Areas
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You are conducting a study for an existing airport. The airport wants to handle air carrier operations with airlines flying the Canadair CRJ-700 aircraft (regional jet)
Determine the suitability of the runway to conduct air carrier operations. If the runway is not suitable for carrier operations suggest modifications to do it
Example Problem
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The Bombardier CRJ-700 is an interesting aircraft because is a boundary case between Approach speeds B and C. The aircraft has the following geometric characteristics:
Table 1. Bombardier CRJ-700 Information (source: Bombardier Aircraft).
Example Problem: Solution (1)
The aircraft approach speed is not published, we use a conservative speed of 121 knots which puts the aircraft in category C-II (less than 79 feet of wingspan)
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The maximum grade allowed is 1.5%. The runway satisfies this criteria.
The maximum grade change is 1.5%. This criterion is violated at point A.
The required 0.8% grade for the first ¼ of the runway is not met by the runway.
The transitional curve lengths are 1,985 feet for point A and 1,400 for point B
Example Problem: Solution (2)
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Design the two transition curves at points A and B in the vertical profile shown in the figure. Find the curve length and the elevation of the points on the transition curve at points A and B.
Example Problem
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G1 = grade of first tangent (%)
G2 = grade of second tangent (%)
L = length of transition curve (feet)
x = station along the horizontal axis defining the transition curve
Ep = Elevation of the points on transition curve (feet) at station x
Epvc = Elevation of the initial point on transition curve (feet) (called point of the vertical curve)
A = G2 - G1; % algebraic change in grade (%) of the transition curve
Elevation of points on the transition curve (ft)
The equation of a symmetric parabola used as transition curve is given by the following equations:
𝐸𝑝=𝐸𝑝𝑣𝑐+𝐺1
100×𝑥2+ 𝐴×𝑥2
200× 𝐿
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The transition curve with point of intersection at A (1985 feet long) is shown below
The Point of Intersection (PVC) is located 2189.5 feet from the runway threshold
This is obtained as 970 meters (3182 feet) minus half of the curve length (1985 feet)
The elevation of the curve is 2050 feet minus the drop in runway elevation between the runway threshold and the point of the curve (0.85/100 * 2189.5 feet)
The elevation of the Point of the Vertical Curve is 2031.4 feet.
Vertical Curve Solution for Point A
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Vertical Curve Solution
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Along runways
Two points 5 feet above the runway should be mutually visible for the entire runway
Between intersecting runways
Two points 5 feet above the runway should be mutually visible inside the runway visibility zone (polygon)
Three distance rules are used in the creation of the visibility zone: 1) < 750 feet, 2) 750-1500 feet and 3) >1500 feet
See diagram (next slide or Figure 5-5 of the FAA AC 5300-13)
Line of Sight Standards
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Runway Visibility Zone
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The purpose of runway exists is to improve service times of airport runways
The number of runway exists varies from airport to airport and within runways at the same airport
Several types of runway exits can be implemented
90 degree (right-angle) 45 degree exit (for GA applications) 30 degree high speed runway exit (for high density operations) New 30 degree angle high-speed runway exit with 1,400 foot
spiral design (for high-density operations)
Runway Exits
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Good for low volume applications < 30 operations/hr Typically 8 m/s exit speed
90 Degree Runway Exit
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Good for high-volume general aviation airport applications (> 30 operations /hr)
Typically 13-15 m/s exit speed
45 Degree Angle Runway Exit
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Good for high-volume applications (> 30 operations/hr) Typically 21-22 m/s exit speed
30 Degree Angle Runway Exit
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Factors that affect the runway exit locations:
Fleet mix Operations/hr Environmental conditions (wet vs. dry pavement) Terminal or gate locations Type and number of runway exits
Manual tables developed by ICAO and FAA
Use computer models like REDIM - Runway Exit Design Interactive Model (Developed at Virginia Tech for the FAA and NASA)
Procedures to Locate Runway Exits
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Typical Aircraft/Pilot Runway Behavior(Landing Case)
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Flare phase Free roll phase (ICAO calls it transition) Braking phase
Three Segment Method to EstimateRunway Exit Locations
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Aircraft cross the runway threshold at approach speed (1.3 Vstall) (called Vapp)
Refer to approach speeds in FAA AC 5300-13 Appendix 13 Touchdown is empirically Vapp * 0.95
Touchdown point location varies from 1500 feet for aircraft in groups C and D to 850 feet for aircraft in groups A and B
Calculate distance S1 using known touchdown distance
Flare Segment
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Touchdown speed at 0.95 * Vapp
Aircraft roll freely for 1-3 seconds before brakes are applied In modern aircraft spoilers deploy automatically as soon as the
main landing gear “squat” switch detects strut deflection Aircraft decelerates at ~0.03*g (0.3 m/s-s) Calculate the final speed using a simple constant deceleration
profile (a = 0.03 * g) Calculate distance S2 using the known initial speed and free roll
time
Free Roll or Transition Segment
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Aircraft starts braking at the end of the free roll or transition phase Average deceleration rates measures in the field vary from 1.3 to 1.8
m/s-s (use average 1.5 m/s-s)
Aircraft decelerates until reaching a comfortable exit speed (Vexit)
Use the exit speeds defined for typical runway exit types defined in slide “Operational Values of Runway Exit Speeds”
Calculate distance S3 using initial speed, final speed and deceleration rate
Braking Segment
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Applicable Formulas(Uniformly Accelerated Motion)
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Estimate the runway exit location for an Embraer 170 aircraft with the following parameters:
Touchdown location = 400 meters Deceleration rate = -1.5 m/s-s Exit type = 90 degree angle (8 m/s) Approach speed at MALW ~ 125 knots
Example Calculation
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Flare distance = 400 meters
Transition distance = 120 meters
Braking distance = 1100 meters
Validate using your calculator
𝑽 𝒂𝒑𝒑=𝟏𝟐𝟓×𝟏 .𝟖𝟓𝟐=𝟔𝟒 .𝟑𝒎/𝒔𝑽 𝒇=𝟔𝟒 .𝟑×𝟎 .𝟗𝟓−𝟏.𝟓×𝟐=𝟓𝟖 .𝟎𝟗𝒎/𝒔
𝟓𝟖 .𝟎𝟗𝟐=𝟔𝟏 .𝟎𝟗𝟐−𝟐×𝟏 .𝟓×𝑺𝑺≅𝟏𝟐𝟎𝒎
𝟖𝟐=𝟓𝟖 .𝟎𝟗𝟐+𝟐×−𝟏 .𝟓×𝑺𝑺≅𝟏𝟏𝟎𝟎𝒎
Total Distance to Runway Exit = 1620 meters (5,315 ft)
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Real World Runway Speed Profiles(CLT Runway 23 operations – watch randomness)
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ROT Distributions (2 airports)
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Sample 90 and 45 deg. Angle Exits (DCA)
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High-Speed Speed Exits (IAD)(Standard 30 degree angle)