mms&tf piston engine seminar by chad menne / malibu aerospace
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MMS&TF Piston Engine Seminar By Chad Menne / Malibu Aerospace. Teledyne Continental Motors “Gold Motor”. Textron Lycoming “Grey Motor”. Who am I and why are we here?. Chad Menne Malibu Aerospace Over 7,000 hours of PA46 time Corporate flight experience Aircraft management - PowerPoint PPT PresentationTRANSCRIPT
MMS&TF Piston Engine SeminarBy Chad Menne / Malibu Aerospace
Teledyne Continental Motors“Gold Motor”
Textron Lycoming“Grey Motor”
• Chad Menne• Malibu Aerospace• Over 7,000 hours of PA46 time• Corporate flight experience• Aircraft management• Flight test experience• Engineering – Research & Development• FAA Certification Tests• Maintenance / Production Flight Tests
Who am I and why are we here?
Both Lycoming & Continental Engines How do we operate these engines? Why do we operate them that way? What are we missing? What is my mechanic missing? What are common problems?
Today’s Topics
Reliability◦ “Piston engines are comprised of a thousand parts
flying in all different directions, looking for a way out.”
Let’s talk engines
Reliability◦ “Piston engines are comprised of a thousand parts flying in
all different directions, looking for a way out.”
98 out of 1385 total accidents were due to powerplant failures (7%), representing 21.4Million flight hours (Nall report 2007). That is one accident every 218,367 flight hours caused by engine failures,(turbine & piston). 11 of them resulted in fatalities (0.8%), which equals ONE fatal accident every 1.95Million flight hours due to engine failure. The TOTAL fatal accident rate is 1 per 84,920 flight hours for ALL types of accidents in ALL types of planes.
Let’s talk engines
Reliability◦ “Piston engines are comprised of a thousand parts flying in all different
directions, looking for a way out.”
98 out of 1385 total accidents were due to powerplant failures (7%), representing 21.4Million flight hours (Nall report 2007). That is one accident every 218,367 flight hours caused by engine failures,(turbine & piston). 11 of them resulted in fatalities (0.8%), which equals ONE fatal accident every 1.95Million flight hours due to engine failure. The TOTAL fatal accident rate is 1 per 84,920 flight hours for ALL types of accidents in ALL types of planes.
The piston PA46 fleet averages about 150,000 hours/year That means we should see one accident every 1.5 years and one
fatal accident every 13 years due to engine failure (piston & turbine) Some sources claim a piston engine fails every 3,200 flight hours.
Pratt & Whitney claims a PT6 failure every 333,000 flight hours by comparison
Let’s talk engines
Both Malibu & Mirage◦ Exhaust!
Turbo transitions, slip joints, gaskets, clamps◦ Magnetos
Cam wear, moisture/corrosion, points, dist. block◦ Turbochargers
Don’t expect them to go to TBO◦ Cam & lifter corrosion and wear
Excess moisture, fuel dilution, shearing & thermal breakdown of the oil
Common Problems
Exhaust valves◦ Most common cause from high power & high CHT & exhaust temps
Starter drive adapters◦ Lightweight Iskra starters can cause premature wear◦ Air conditioner driveshaft seals can leak
Cylinder & ring wear◦ First to be blamed & rarely the cause
Bearing end play◦ Check for proper end play during pre-flight and DO NOT fly without
end play! Borescope for detailed inspection before condemning a
cylinder Be sure to use TCM master orifice tool for daily calibration
during a compression check
Malibu specific problems
Exhaust valve guide wear (high oil consumption and rough running)
Broken oil control rings Poor break-in results (high oil consumption)
◦ Lycoming does not allow mineral oil Cracked oil sump at turbo support studs Cracked internal oil baffle
◦ Be sure to check suction screen for rivets Fuel servo problems
◦ Unable to get proper ground mixture or full power fuel flow◦ Can cause surging in cruise
Fuel line AD 2008-14-07 every 100 hours (cracking due to improper securing of lines)
Mirage specific problems
Believe it, or not!
Lifter Main bearing
Crankcase bearing journal
Crankshaft Bearing Wear
Oil Sample - Good
Oil Sample - Bad
Iron Cylinders, rotating shafts, valve train and any steel part sharing the oil. Copper Brass or bronze parts, bushings, bearings, oil coolers, sacrificial coatings. Nickel Valve guides, trace element in steel, some cylinder types. Chromium Rings, cylinders, a trace element in steel. Silver Sacrificial coatings, a trace element in some types of bearings, bearing cage plating Magnesium Engine casings, additives Aluminum Pistons, piston pin plugs, bearing overlay, casings. Lead Primarily leaded gas blow-by, traces from bearings Silicon Abrasive dirt from intake air, silicone sealers and gaskets, sample contamination. Tin Bearings, bronze parts (with copper), anti-wear coatings. Molybdenum Traces of anti-wear coatings, some cylinder types, and bearings.
Most Common Sources of Wear Metal Elements in Oil
Exhaust Woes
Leaky Gasket Colorful clues
Mirage Turbo Transition
Heavy, Cast Inconel Erosion & Blistering
Malibu Turbo Transition
.065” Stainless Steel Check at EVERY Oil Change!
Tailpipe Trouble
Corrosion has its way Heat Muff - Uncovered
V-Band Clamps
Exhaust Clamps
Malibu & Old-Style Mirage Clamps Crack from over-tightening
Exhaust Clamp Engagement
The right way The WRONG way
Sump Cracks (Turbo Mounts)
Turbochargers
Compressor damage Bearing failure Seal failure Scavenge pump failure Scavenge hose failure Wastegate failure or sticking
Common Turbo Problems
Turbochargers
Bearings Compressor Damage
Engine Cooling
Vent oil cap after shutdown (minimize corrosion)
Watch EGTs and trend data (ignition and fuel injection anomalies)
In-flight mag checks (look for hot or cold EGTs) Oil samples (watch for iron, nickel,
almuminum) Watch for peak TIT drift (up or down)
◦ Drift up is usually ignition or low compression◦ Drift down is usually a probe going bad
Things that you can do
The best way to prolong your engine’s life and improve safety is to know how to balance parameters◦ Trade one temp for another◦ Engine limits are not intended to provide longest
life, but are instead proven to be acceptable for short durations
◦ Add fuel only as necessary to achieve a good balance during climb Less fuel means more power! (power means heat)
The best pilots can juggle
A. 360° CHT – 1650° TITB. 400° CHT – 1580°TIT
Which is worse???
A. 360° CHT – 1650° TIT◦ The TIT is an exhaust gas temp, the CHT affects
the engine’s ability to dissipate heat◦ A cooler CHT can transfer more heat away from
a valveB. 400° CHT – 1580°TIT
◦ Less differential from valve to seat and guides removes less heat from valve
◦ Localized oil temps will be hotter at valve guides
Which is worse???
How hot is too hot???◦ CHT or EGT/TIT, not both (valve wear)◦ High TIT equals more exhaust wear
Lean of Peak, no free lunch◦ Lose speed (less power at same power setting)◦ Wear exhaust (higher EGTs, more oxidation)◦ Not as smooth (slight roughness or surging)◦ Cooler CHTs (helps offset the higher EGTs and cool
valves)
Operations
Continental◦ 20% fuel savings ($28,000 over 2000 hours)
1500 hrs x 21GPH x $4.50/gal - 20%◦ 2% speed loss ($9,000 additional aircraft cost over 2000
hours) 1500 hrs x 200kts - 2% / 196kts x $300/hr
◦ Increased exhaust wear costs ($3000 over 2000 hours) Lycoming
◦ 25% fuel savings ($35,000 over 2000 hours) 1500 hrs x 21GPH x $4.50/gal -25%
◦ 10% speed loss ($50,000 additional cost over 2000 hours) 1500 hrs x 200kts - 10% / 180kts x $300/hr
◦ Increased exhaust wear costs ($10,000 over 2000 hours)
LOP Cost Comparison
How to change your ignition timing???◦ Engine speed
Higher RPM = less advance (less time to burn) 2500 RPM = 1 Revolution every .024 seconds
Lower RPM = more advance (more time to burn) 2300 RPM = 1 Revolution every .026 seconds or 9% more time
◦ Mixture ratio ROP Leaner mixture = more advance (burns faster – sharper power
pulse) Richer mixture = less advance (burns slower – softer power pulse)
◦ Mixture ratio LOP Richer mixture = more advance (burns faster – sharper power
pulse) Leaner mixture = less advance (burns slower – softer power
pulse)
Ignition timing and combustion speed
Lower RPM
Higher RPM
Affects of RPM on “Combustion timing”
Earlier Peak Pressure, More Time to Burn, More Cooling Time per Cycle, Less HP, Cooler EGT, Cooler CHT
Later Peak Pressure, Less Time to Burn, Less Cooling Time per Cycle, More HP, Hotter EGT, Hotter CHT
Intake Compression Exhaust
Intake Compression Combustion Exhaust
Combustion
TDC Peak Pressure
TDC Peak Pressure
ROP Combustion
LOP Combustion
Affects of mixture on “combustion timing”
Faster Combustion, Sharper Pulse, Cooler EGT, Hotter CHT
Slower Combustion, Lower Pressure, Hotter EGT, Cooler CHT
Intake Compression Combustion Exhaust
Intake Compression Combustion Exhaust
TDC Peak Pressure
TDC Peak Pressure
Rich of peak, lean to peak, lean of peak TIT peak method, a.k.a.“the factory
method” Fuel flow method JPI lean find “Lean L” method JPI lean find “Lean R” method “The big pull”
Leaning TechniquesNo wonder you’re confused!
Continental◦ LOP, FF x 15 = HP◦ ROP, FF x 13.25 = HP (Can vary a lot)
Lycoming◦ LOP, FF x 14 = HP◦ ROP, FF x 12 = HP (Can vary a lot)
What’s My Horsepower???