Post on 16-Dec-2015
CH-53K Heavy Lift Helicopter
A Survivability Focused Design
Presented at the American Helicopter Society 67th Annual Forum Virginia Beach, VA
May 3-5, 2011
This is a work of the U.S. Government and is not subject to copyright protection in the U.S.
Kathy Russellkathy.russell@navy.milVulnerability Analyst
NAVAIRChina Lake, California
Martin Krammermartin.krammer@navy.milVulnerability Test Engineer
NAVAIRChina Lake, California
Richard Gardnerrichard.gardner@navy.mil
Survivability LeadNAVAIR
Patuxent River, Maryland
Nicholas Gerstnernick.gerstner@survice.com
Survivability AnalystSURVICE Engineering
Dayton, Ohio
Introduction
Next Generation
Heavy Lift Helicopter for the US Marine Corps
• Operational
Requirements
More Survivable Design
CH-53ECH-53K
• Survivability
Key Performance
Parameters
• Air Vehicle
Specification
Background
Balanced Survivability Approach
•Susceptibility - the inability of an aircraft to avoid being hitSusceptibility Reduction - missile warning and missile jamming or decoying further enhance the survivability capabilities of the platform
•Vulnerability - the inability of an aircraft to sustain damage once hitVulnerability Reduction – threat tolerant design
Susceptibility and Vulnerability Reduction Verification• Analysis • Flight Test • Live Fire Test
Susceptibility Reduction
Threat Avoidance
Susceptibility reduction for the CH-53K consists of an integrated Aircraft Survivability Equipment (ASE) suite
Radar Warning Receiver AN/APR-39B(V)2 (RWR)/Electronic Warfare Management System Directional Infrared Countermeasures System (DIRCM) AN/AAQ-24(V)
Missile Warning System (MWS) *update – Laser Detection incorporated with MWS Countermeasure Dispenser System (CMDS) AN/ALE-47
Analysis and Flight Test will assess the ASE system effectiveness against AVS threats
SusceptibilityVerification
Susceptibility Analysis•Incorporates threat systems•Aircraft performance data•Various models and simulations
– Moderate Transmittance (MODTRAN)– Modeling System for Advanced Investigation of
Countermeasures (MOSAIC)– Future Operational Combat Unified Simulation
(FOCUS)– Multi-Service Electro-Optics Signature
(MuSES)
Survivability Requirements
CH-53K Key Performance Parameters
Two of the seven system KPP’s are Survivability Requirements
•Fly Away Capability – Ballistic Tolerant Design•Force Protection – Cockpit and Cabin Armor
Meeting the KPP requirements
•Challenging yet achievable Air Vehicle Specification (AVS)•Continuous Survivability Analyses•Early Ballistic Tests•Early involvement and a coordinated survivability team
Vulnerability Reduction
VulnerabilityVerification
Analysis and Test
MODEL TEST
VulnerabilityVerification
Vulnerability Analysis – Critical Data Sets
Geometry Conversion Techniques• SAC CATIA to BRL-CAD format• Streamlines the modeling effort • Ensures precise and accurate component representation
Traditional Data Sets• DMEA• Pd/h and Pk/d• FALT
VulnerabilityVerification
Vulnerability Analysis – Critical Data Sets
Low and Slow(L&S)
High and Fast(H&F)
0 40 80 Vmax
Helicopter Speed (kts)
0
100
Amax
Alt
itu
de
AG
L (
ft)
Low and Slow(L&S)
High and Fast(H&F)
0 40 80 Vmax
Helicopter Speed (kts)
0
100
Amax
Alt
itu
de
AG
L (
ft)
Traditional Flight RegimesDiscrete Mission Points• Define specific flight conditions
• Correlate to susceptibility analyses
Mission Points
Design ImpactInitial Assessment – Not compliant
Assessment Updates• Updated preliminary designs
• Integrated CH-53E JLF results
Design Enhancements• MGB redundant lube system
• Supplemental fuel feed system
• Main rotor actuator redesign
• Tail rotor drive shaft growth
Risk Reduction Testing• Identified components for testing to refine design and analysis
• Tail rotor drive shaft and Flexbeam successfully tested
• Additional items identified for testing
VulnerabilityVerification
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36
Analysis Update Reference No.
Status Spec
Initial assessment
RR testing
CDR
Risks From CDR Design Challenges
PDR
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36
Analysis Update Reference No.
Status Spec
Initial assessment
RR testing
CDR
Risks From CDR Design Challenges
PDR
VulnerabilityVerification
Assessment ProgressionMilestone Assessments – Compliant
Force Protection Verification
Design ImpactInitial and Milestone Assessments – Compliant
Assessment Progression• KPP requirements addressed cockpit and cabin occupant protection
• Weight optimization studies conducted to minimizeineffective armor and maximize protection
• Design changes assessed for impact on protection levels
Initial PDR Design Current CDR DesignInitial PDR Design Current CDR DesignCDR Cockpit Armor
CDR Cabin Armor
CH-53K Survivability
• Risk Reduction Tests─Tail Rotor Flex Beam
─Tail Rotor Drive Shaft
─ Sponson Material - Fuel Cell Interaction
─ Fuel Line Leak Containment
• Live Fire Tests
Risk Reduction Test
Tail Rotor Flex Beam Test
Test Damage
Ballistic Impact
Test ConclusionTest articles were able to maintain
the loads after damage
Test ConclusionTest articles were able to maintain
the loads after damage
Risk Reduction Test
Tail Rotor Drive Shaft Test
Ballistic Impact
Test Damage
Test ConclusionTail Rotor Drive Shaft is tolerant to the AVS
ballistic threat
Test ConclusionTail Rotor Drive Shaft is tolerant to the AVS
ballistic threat
Test Set-up
Demonstrates structural capability to respond to hydrodynamic ram
• Sponson composite wall construction• Self sealing performance of candidate fuel bladder
Risk Reduction Test
Sponson Material – Fuel Cell Interaction
Proposed solutions tested for leak mitigation / fire suppression initiated by ballistic impacts on fuel feed lines
Fuel Line Leak Containment
• CH-53K is designated as a covered LFT&E system– U.S. Code Title 10, Section 2366 (10USC2366)
• Alternative LFT&E (ALFT&E) strategy uses analysis to aid in
identification of critical components and viable test shots
• Key Focus Areas– Collateral and cascading effects
– Assess potential crew and passenger casualty
– Assess CH-53K Battle Damage Assessment and Repair procedures
– Provide survivability comparison of CH-53K with legacy CH-53E
– What modifications can be made to reduce the vulnerability of the CH-53K?
LFT&E
• MRGB• IGB & TGB• TR Drive Shaft• TR Flex Couplings• TR Disconnect Couplings
Main and Tail Rotor Servos
Stationary and Rotating Scissors
TR Pitch Beam Pitch Control Link
• TR Blade, Flex Beam• TR Pitch Link• TR Pitch Change Shaft• TR Shaft• TR Pitch Beam• Armor – Crew, Cabin• Propulsion – GE 38
Component Level Ballistic Tests
• TR Hangar Bearings & Mounts• Stationary Scissors• Swash Plate• MR & TR Servos• Sponson structure & cell
•Drive System Tests– MRGB Rear Module– TR Gearbox– Intermediate Gearbox– TR Drive Shaft – TR Flex Coupling– TR Disconnect Coupling– TR Hanger Bearing and
Bracket– NGB-MRGB Shaft, Coupling
Hanger Bearing– Rotor Brake– NGB & Mounts
•Armor Tests– Cabin floor / wall– Cockpit seat & wing
•Structure Tests– Transition and Tail
•Fire Tests– Engine Nacelle
• Fire detection / ext. system
– Fuel System• Sponson / SEFS• Feed (Engine)• Dump & Refuel • Fuel line Sleeves
– Hydraulic System
•Flight Control Tests– Control boxes & wiring– MR Servo Actuator– TR Servo Actuator– TR Blade
– TR Hub
– TR Pitch Beam
– TR Control Link– TR Pitch Change Shaft– Swashplate
GTV System Level Tests
CH-53E(mounted on a hover stand at WSL during JLF Tests)
Model - Test - Model
MODEL TEST
Initial A
ssessment/
Model
PDR Update
CDR Update
MS - C / OTRR
Trade Studies
Trade Studies
Lessons learned
from previous
programs
e.g. CH-53E
Risk Reduction Test results
Data from formal live fire
test program
ENSURES SURVIVABLE DESIGN
Questions ?