J.A.W. wrote:Document tabulating WW2 American aero-engine serviceability.. http://www.usaaf.net/digest/t115.htm
MONTHLY MAINTENANCE MAN HOURS PER ENGINE IN USD FROM JULY 1943 TO AUGUST 1945
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J.A.W. wrote:Document tabulating WW2 American aero-engine serviceability.. http://www.usaaf.net/digest/t115.htm
Slight correction. Many superchargers of the day were variable speed superchargers. The merlins and griffons (and some American designs), once matured in design, used 2 speed superchargers while the Germans favoured hydraulic couplings for their superchargers.wuzak wrote:Yes, the help use the exhaust thrust. But also eliminate the engine mounted supercharger, relying on turbos only for supercharging, freed up several hundred hp.Tommy Cookers wrote:the VDT was intended at speed to reduce the TC exhaust recovery path and open a exhaust jet path ?
On R-4360 VDT was tried on a B-50. But the flight engineer had to monitor and control it constantly.Tommy Cookers wrote:the airframe changes (eg needed to the B50) were judged to be excessive
Higher boost improved performance at low altitude. That is the critical altitude or full throttle height was lower at a higher boost level, above which the extra boost could not be maintained.Tommy Cookers wrote:and ..... when fuel quality was raised CRs were usually held and mep/boost raised
this should have increased the exhaust thrust even with the usual simple exhaust systems
Exhaust thrust was far more important at high altitudes, where engine power was reducing and propeller efficiency was lower.
Not sure. There are figures about.Tommy Cookers wrote:so how much exhaust jet thrust (or equivalent hp) would eg a 2000 hp Mustang or Spitfire have had when high and fast ?
We can say that the Mosquito picked up ~10mph by changing to ejector exhausts.
The aime was to get more exhaust thrust, though the end shape was sometimes modified to reduce exhaust glare for night flying.Tommy Cookers wrote:what did the Merlin 1940 'ejector exhausts do ? (these were then dropped) increase crankshaft power ? increase jet effect by entrainment ?
The ejector exhausts were refined throughout the war.
W said ....wuzak wrote:Tommy Cookers wrote:and ..... when fuel quality was raised CRs were usually held and mep/boost raised this should have increased the exhaust thrust ......
TC and others might find this interesting and you guys and girls may have seen these types of graphs before but I'll post them anyway. They are supposed to be the general relationships of the thrust generated on various types of aircraft.Tommy Cookers wrote:W said ....wuzak wrote:Tommy Cookers wrote:and ..... when fuel quality was raised CRs were usually held and mep/boost raised this should have increased the exhaust thrust ......
Exhaust thrust was far more important at high altitudes, where engine power was reducing and propeller efficiency was lower.
TC says ....
the exhaust thrust was greater at altitude because the ambient pressure was lower
and its efficiency increases with speed (this also tending to increase with altitude)
I think the inevitability of prop efficiency reduction was debunked by this stage (eg the 647 mph turboprop B-47)
Are you referring to F1 here or just wheel driven car speed records on the whole?Tommy Cookers wrote:there is a speed record category for wheel-driven cars
how much exhaust thrust can be obtained ? (eg maybe enhanced by some mixing effect with air)
is (any) exhaust thrust really legal ?
Current wheel drive LSR is held by a gas turbine.gruntguru wrote:The question of exhaust thrust assisting land speed record cars of the "wheel driven" category would be relevant in all cases but particularly for a gas turbine car. I assume there is a category?
Not sure on that one Tommy.Tommy Cookers wrote:W said ....
Exhaust thrust was far more important at high altitudes, where engine power was reducing and propeller efficiency was lower.
TC says ....
the exhaust thrust was greater at altitude because the ambient pressure was lower
and its efficiency increases with speed (this also tending to increase with altitude)
I think the inevitability of prop efficiency reduction was debunked by this stage (eg the 647 mph turboprop B-47)
Daimler Benz engines had the hydraulic coupling on its engines. Junkers and BMW engines had multi-speed gear boxes. Two speed in the BMW 801 and Jumo 211, up to 3 speeds in the Jumo 213.trinidefender wrote:Slight correction. Many superchargers of the day were variable speed superchargers. The merlins and griffons (and some American designs), once matured in design, used 2 speed superchargers while the Germans favoured hydraulic couplings for their superchargers.
http://www.spitfireperformance.com/merlin66hpchart.jpgtrinidefender wrote:This allowed them to produce more power lower down with high octane fuel while at the same time at high altitude the superchargers were shifted into a high speed gear where they ran much faster and allowed higher compression ratios of the supercharger. Usually the higher supercharger compression ratios causes detonation/pre-ignition however the raised octane of the fuel allowed the engine to resist the higher operating temps with the increased supercharger compression ratios. In essence the high speed gear/hydraulic drive allowed designers to massively increase the full throttle height of the engine.
Those charts just tell me that raising the boost pressure of the supercharger resulted in a lower full throttle height (or critical altitude, whichever you prefer) for the RR Merlin 66 at 20,000 ft it shows that at full throttle the wastegate would be fully closed closed and you would get 18 lbs of boost. It isn't saying that the two different pressures give the same power, it is saying that at that altitude this supercharger will give that boost pressure. If I remember correctly the 5 minute combat limit for the merlin 66 was something like 18 lbs of boost pressure although I cannot remember on which fuel that was.wuzak wrote:Daimler Benz engines had the hydraulic coupling on its engines. Junkers and BMW engines had multi-speed gear boxes. Two speed in the BMW 801 and Jumo 211, up to 3 speeds in the Jumo 213.trinidefender wrote:Slight correction. Many superchargers of the day were variable speed superchargers. The merlins and griffons (and some American designs), once matured in design, used 2 speed superchargers while the Germans favoured hydraulic couplings for their superchargers.
Most American designs used distinct gear ratios too.
The two stage V-1710 used fluid couplings, and there was a fluid coupling drive for the R-2800 that powered the F8F-2 (post war). Also an experimental V-1650 (Merlin) with a fluid coupling supercharger drive built by Packard.
http://www.spitfireperformance.com/merlin66hpchart.jpgtrinidefender wrote:This allowed them to produce more power lower down with high octane fuel while at the same time at high altitude the superchargers were shifted into a high speed gear where they ran much faster and allowed higher compression ratios of the supercharger. Usually the higher supercharger compression ratios causes detonation/pre-ignition however the raised octane of the fuel allowed the engine to resist the higher operating temps with the increased supercharger compression ratios. In essence the high speed gear/hydraulic drive allowed designers to massively increase the full throttle height of the engine.
http://www.spitfireperformance.com/griffonhp_b.jpg
You can see from these charts that the Merlin 66 had the same power at around 20,000ft whether its max boost was set to +28psi or +18psi.
For the Griffon it is around 26,000ft for +25psi or +18psi.
You are correct that the high gear can give more boost (and power) than maintaining low gear.
But you also notice that the Full Throttle height is reduced with increased boost.
Daimler Benz's high CR/low boost formula meant that the supercharger wasn't required to provide high pressure ratios, so its full throttle or critical altitude was higher.
It is a hp chart, so where the lines meet is the same hp.trinidefender wrote:Those charts just tell me that raising the boost pressure of the supercharger resulted in a lower full throttle height (or critical altitude, whichever you prefer) for the RR Merlin 66 at 20,000 ft it shows that at full throttle the wastegate would be fully closed closed and you would get 18 lbs of boost. It isn't saying that the two different pressures give the same power, it is saying that at that altitude this supercharger will give that boost pressure. If I remember correctly the 5 minute combat limit for the merlin 66 was something like 18 lbs of boost pressure although I cannot remember on which fuel that was.
I think maybe very late war they were authorised.trinidefender wrote:As far as I'm aware they never ran (authorised at least, who knows what the mechanics did in the field) boost pressures up to 28 lbs in the RR Merlin 66.
The Merlin 63 had the same supercharger as the 66, just different gears.trinidefender wrote:Although the you should have used the Merlin 63 as a better example as its super charger was redesigned and re-heard to work at higher altitudes. The MK 66 was purposefully designed to produce more power at lower altitudes.
The 63 was the earlier engine. I believe the 66 had some strengthening compared to the 63, and I'm not sure if the 63 was allowed to use +25psi.trinidefender wrote:The Mk 63 merlin was fitted in the Spitfire F MK IX while the MK 66 Merlin was fitted to the spitfire LF MK IX, the lower altitude derivative of the MK IX Spitfire.
The extra capacity certainly helped in the power stakes, but I still think the pressure ratio of the supercharger was important for high altitude performance.trinidefender wrote:You also have to remember that the DB601 was 34 litres and the DB605 was an even bigger 35.7 litres. The merlin on the other hand was a piffling 27 litres.
From my knowledge it is more this large capacity that allowed higher full throttle heights than the high compression/low boost mantra. I'm not saying that they don't help but it always seemed that the large capacity had the most impact.