Engine Ingestion Standards and Certifications
By Behzad Mhp 27621760 Nirmal Raju 26734227 Nishant Jogadia 27272588 Siddharth Salkar 27169787
ENGR 6421- Standards Regulations and Certifications
WHAT EXACTLY IS ENGINE INGESTION TEST ?
Bird Ingestion Test
Issued by :
Federal Aviation Administration(FAA) under AC No. 33.76-1A
Purpose-Title 14 of the Code of Federal Regulations (14 CFR) 33.76
Applicability – Engine Manufacturer or Modifier
• Bird Strike
Usually occur during take-off , climb and landing of airplanes
Rare cause of accidents – only 0.3% of total aircraft Fatal Accident Frequency Rate from all causes
Force or momentum exchangePart Struck No. of
Strikes% of Strikes causing damage
Nose/Fuselage 6393 9.5Windshield 2546 6.6Wing/Rotor 3006 25Landing Gear 1595 9.5Lights 183 71Tail 381 30
No. of birds struck
No. of strikers
% of Strikes causing damage
1 7704 11.92-10 2726 18.9>10 320 23.8Total 10750
• Classification of Bird Strike
Single birdBetween 2 and 10 birdsMore than 10 birds
• Engine must be structurally and operationally tolerant to:
Large Single Bird Ingestion
Small and Medium Flocking Bird Ingestion
Large Flocking Bird Ingestion
BASIC DEFINITIONS
• Front of the Engine:
• Minimum Engine
• Critical Impact Parameter (CIP):stress , strain , deflection , twist etc
Large Single Bird Ingestion• Complete loss of thrust• Determine critical location on first stage of rotating blades• Evaluation of engine dynamic response• Selection of optimum ingestion speed (200 knot)
SMALL AND MEDIUM FLOCKING BIRD INGESTION
• MethodFirst Bird is targeted for the core primary flow path
Second bird – most critical exposed location
Remaining birds- fan face area
• Engine must produce at least 75% of takeoff power or thrust after ingestion.
• Momentary power drop should not exceed 3 seconds.
• Rig Tests.
• Sustained high vibration after 2 minutes - vary power
• Exceeding Engine Operating Limits
• Total run-on test time – 20 minutes
LARGE FLOCKING BIRD INGESTION
• Selection of target : not less than 50% of airfoil height
• Multiple Stages
• Test Duration : Exceed 20 minutes
• Segment 1= Duration 1 minute
• Power > or = 50% of maximum rated takeoff
• Segment 2 = Duration 13 minutes
• Engine should maintain power not less than 50%
• Sustained Power Loss : more than 3 seconds
Hailstone Ingestion test
Issued by :Federal Aviation Administration(FAA) under 14 CFR Parts 23, 25 and 33
BACKGROUND• There have been a number of multiple turbine engine power-loss and instability events, forced
landings, and accidents attributed to operating airplanes in extreme rain or hail.
• If an airplane encounters severe rain or hail with installed engines that are susceptible to flameout, the airplane will be susceptible to an all engine out, forced landing.
• Rain or hail related in-flight engine shutdowns are rare occurrences. This is due, in large part, to the high quality of meteorological data available to ground controllers and pilots, and to well established weather avoidance procedures.
• However, while such events are infrequent, they pose a serious hazard because they typically occur during a critical phase of flight where recovery is difficult or impossible.
CERTIFICATION TESTING• The rain and hail ingestion threats have been
defined for purposes of certification testing as 30 seconds duration for hail and 3 minutes duration for rain.
• Once flameout occurs under these conditions, it is unlikely that the engine will be capable of recovery until the ingestion of rain or hail ceases, with or without an automatic re-ignition system.
ILLUSTRATION OF RAIN AND HAIL TREATS
CERTIFICATION STANDARD ATMOSPHERIC RAIN AND HAIL CONCENTRATIONS
Altitude (feet) Rain water content (RWC)(grams water/meter 3 air)
0 20.020,000 20.026,300 15.232,700 10.839,300 7.746,000 5.2
Altitude (feet) Hail water content (HWC)(grams water/meter 3 air)
0 6.07,300 8.98,500 9.410,000 9.912,000 10.015,000 10.016,000 8.917,700 7.819,300 6.621,500 5.624,300 4.429,000 3.346,000 0.2
Volcanic Ash Ingestion
Background
Effects
Important Factors
Safety measures and Recommendations
Certification standards
Challenges
Avoid Visible Ash
BACKGROUND• Galunggung, June 4th, 1982 – Airbus
747 (BA)• Failure of all 4 engines• Molten ash in Comubstor• Contaminated fuel tanks
• Mount Redoubt, Dec 1989 – Airbus 747 (KLM)• Flame out of all 4 engines in 80s• 5 mins & from 28000 ft – 13300 ft • $80 million in repairs
• Mount Pinatubo, Phillippines June 1991• 8000 Kms reaching East Coast of Africa• 20 aircrafts damaged• Significant effects over 1000 kms.
EYJAFJALLAJÖKULL, ICELAND, APRIL 2010
• Contamination of European Airspace• Loss of aircraft separation due to ash avoidance• Air traffic flows reduced; disrupted flight operations; economic
impact• Ash avoidance principle compromised (SRAs, Threshold limits)• ICAO set-up International Volcanic Ash Task Force (IVATF) in response,
to understand aviation hazards and impact of flight operations in ash environment.• A-NPA by EASA embracing the IVATF approach
EFFECTS• Erosion of blades and linings• Melting and clogging the
combustor or other parts• Damage to filters and seals• Corrosion • Negative impact on restarting
ability of engine• Contamination of bleed air,
sensor data and electronics
IMPORTANT FACTORS• Eruption type (determines particle size
distribution)• Energy level (impacts height and distance of
spread)• Ash constitution• Weather pattern• Agglomeration, rate of descent • Engine characteristics:
• Combustor and peak cycle temperature• Pressure ratio• Turbine blade technology• Cooling and bleed system
• Flight profile (climb, cruise, flight idle)
SAFETY MEASURES AND RECOMMENDATIONS• Avoidance of Visible Ash• Volcanic Ash Advisory Centres (VAAC) and Meteorological
Watch Offices (MWO) to forecast location and concentration• Safety Risk Assessment (SRA) by the operator• Establish Upper and Lower limits to differentiate immediate
safety hazards and long term effects• Flight crew awareness
CERTIFICATION STANDARDSObjectives:• Establish upper limit possessing immediate safety hazard• Ensure built-in safety margin from TC holders • Establish guidelines for future operations
Challenges:• The probability of ash encounter is very low.• Reduce efficiency and performance, environmental and economic impacts• Limited accuracy of forecast models or direct measurement devices• Delay in implementation• Inadequate testing methods (sand testing)
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