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Overview of fatigue/spalling tests. HCAT Program Review Long Beach April 2001. Wear - better than equal to Cr (mostly considerably better) Fatigue - better than Cr Hydrogen embrittlement - HVOF causes no embrittlement environmental embrittlement under test Impact
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Overview of fatigue/spalling tests HCAT Program Review Long Beach April 2001
Wear - better than equal to Cr (mostly considerably better) Fatigue - better than Cr Hydrogen embrittlement - HVOF causes no embrittlement environmental embrittlement under test Impact Both Gravelometry and Whackometry show HVOF better than or equal to Cr Rig tests F-18 pins “passed” Boeing test F-18 E/F fatigue and endurance doing well at Messier-Dowty Issues remaining Corrosion C-HCAT data look good HCAT data had problems new samples being run (Bruce Sartwell will report) Spalling WC-Co looked good (not perfect) WC-CoCr spalled, especially thick coatings considerable progress made in understanding and improving performance Findings so far
Overview of spalling/fatigue issues • Summary of spalling issues • User requirements • Progress in meeting requirements - tests run • Results of Tuesday evening meeting • What can now be coated
Summary of spalling issues • C-HCAT findings • WC-CoCr, 0.003” spalled above 180 ksi • WC-CoCr, 0.010” spalled above 125 ksi • Evidence of less severe spalling on WC-Co runouts • Apparent mechanism • cracks start at surface of coating, presumably growing in tensile cycles • bifurcate or deflect at, or just above, interface • when cracks join up spall occurs on compressive cycle • Data suggests WC-CoCr is generally more brittle than WC-Co, but Jerry Schell optimization suggests WC-CoCr can be made similar to WC-Co
Crack propagation in WC-Co (NRC/Orenda) Initiation Surface Interface Bifurcation
Commercial Typically 100 ksi, R=0.1, thousands of cycles Maximum 170 ksi, R=0.1 Land-based military 180 ksi, R=-1, a thousand or so cycles (Air Force) 240 ksi, R=-1, occasional hard landings, (Air Force) Carrier-based military Pins 235 ksi, R=-0.5, launch loads, 2,250 cycles, (OEMs) Pistons 240 ksi, R=-1, occasional hard landings, (NAVAIR) OEMs 0.003” typical Airlines 0.010” or thicker for MRO Repair Depots 0.010” or thicker for O&R User requirements Yield stresses: 4340M = 220 ksi 300M = 230 ksi A100 = 235 ksi
Thousands of landing gear cylinders, axles, pins currently chrome plated Only a few pins see anything near yield stress, and do not see full stress reversal loads are largely shear, not bending Only a few inner cylinders see anything near yield stress, but do see full stress reversal large bending loads Carrier-launched aircraft have very small safety factor How many parts see maximum loads? Retract actuator pins
Major concerns • Depots are concerned that HVOF may be accepted by OEMs and then be required in place of Cr, but that if thick HVOF does not work, they will be in trouble • must be able to use thick coatings for repair • repair must meet same performance criteria as thin OEM coatings • If dispense with Cr, want to dispense with all of it • do not want a little left that requires we keep Cr tanks running
Carrier launch drag brace pins Commercial pins, cylinders, axles Hard carrier landing inner cylinders Normal 5,000 times 2,250 times Max 100 times 10 times Hard landing inner cylinders 1 time Land-based military 1,000 times Landing gear loads and R values
Additional tests and detailed materials evaluations - Orenda/NRC Famous forty - smooth bar fatigue samples coated with WC-Co tested at high load levels (John Sauer, Phil Bretz) interrupted testing to track cracking and spalling Prop hub specimens high residual stress coatings (Engelhard), fatigue testing (Hamilton-Standard); high load testing (John Sauer) A-10 Nose Landing Gear cylinders (Hill AFB) using newly-optimized JP-5000 WC-Co (Jerry Schell) bending stress spalling tests (Craig Edwards, Doug Wiser) fatigue specimen spalling tests (Jerry Schell) F-18 E/F Drag Brace spectrum loads, including launch loads in-progress HVOF WC-CoCr so far withstands spectrum loads on brace and pins Tests run since August 2000
New JP-5000 WC-Co April 2001 High-resid stress 0.015”WC-Co Jan 2001 WC-Co 0.003”, 0.010” July 2000 WC-CoCr 0.003” September 2000 Commercial (last century) We have made a lot of progress in the past few months Carrier-based Drag brace pins OEM and rebuild Where we are now OEM and rebuild 0.010” WC-CoCr September 2000 OEM and rebuild
Commercial thin and thick WC-Co or WC-CoCr Land-based military thin and thick WC-Co, most parts, pins, etc. except inner cylinders prone to hard landings (A-10) Carrier-based military thin and thick WC-Co for most components thin and thick WC-Co on launch train components (pins, R=-0.5) except inner cylinders Issues remaining Do results on small samples equate to real parts? Inner cylinders (R=-1) not yet demonstrated may require coating process refinement Optimization Are there issues with stress corrosion cracking if we use coatings with high compressive residual stress? Can WC-CoCr be made as good as WC-Co? Summary - what now looks doable