F1 will see a complete change in engine regulations in 2014, and we're having a closer look at what that means exactly
Sorry yes I got a bit confusedxpensive wrote:I'm afraid you got it a tad confused, Marmorini said "2-4 bar including atmosphere", which means 2-4 bar absolute or 1-3 bar boost.Holm86 wrote: ...
But 2-4 bars of boost incl atmospheric pressure means 3-5 absolute pressure. So 2-2.5 absolute pressure does not fit in.
2.25 bar boost (3.25 bar absolute) at 10 500 rpm, isn't that a bit on the high side?Holm86 wrote:By fast calculation I get 2.25 bars of boost at 10.500 rpm's with 27,7g/s of fuel at stoichiometric AFR.
Boost would then decrease after 10.500 rpm's to 1.6 bars of boost at 15.000 rpm's.
You would need relative high boost when the engine capacity is that small?xpensive wrote:2.25 bar boost (3.25 bar absolute) at 10 500 rpm, isn't that a bit on the high side?Holm86 wrote:By fast calculation I get 2.25 bars of boost at 10.500 rpm's with 27,7g/s of fuel at stoichiometric AFR.
Boost would then decrease after 10.500 rpm's to 1.6 bars of boost at 15.000 rpm's.
When are you going to show it to the public, that Ferrari V6?
Never...
That is more realistic, considering that Honda's 1988 1.5 turbo V6 was some 675 Hp at 2.5 bar absolute and 12 500 rpm.Holm86 wrote: ...
EDIT* Again with a bit confusion. Shouldnt do this while at work
The 2,25 and 1,6 bar is absolute pressure.
Yes. But this is at stoichiometric ratio. I feel they will run a bit richer. Which in this case just means less air. No reason to run higher boost than necessary when i doesnt hurt performance.xpensive wrote:That is more realistic, considering that Honda's 1988 1.5 turbo V6 was some 675 Hp at 2.5 bar absolute and 12 500 rpm.Holm86 wrote: ...
EDIT* Again with a bit confusion. Shouldnt do this while at work
The 2,25 and 1,6 bar is absolute pressure.
matt21 wrote:The engine should be around 600 to 700 mm wide. So the turbo seems not so big to me.WilliamsF1 wrote:1) Why would a low boost engine need such a large turbo spinning at 200,000 rpm?xpensive wrote: I think this image is deliberately misleading, the driven turbine's outlet and the intake-plenum's inlet indicates there will be an intercooler in between, but nobody would place the inlet like that? I believe at this low boost, some 0.7 Bar, there is no need for an intercooler, why we will see the turbo-outlet feeding directly between the two plenums.
2) Why is there such a large airbox leading to the turbine inlet?
The max fuel flow of 100 kg/hr equals 1470 kg of air per hour with an AFR of 1.
For maximum power you have an AFR of around 0.9, what equals 1323 kg/hr of air.
This is around 1100 m³/hr or 18.4 m³/min. or in other words really a lot at max rpm.
With 1 bar absolute you can do 11.25 m³/min at 15.000 rpm.
So if I calculate 18.4/11.25 I come to around 1.6 bar absolute.
Edit: Please note that this calculation is based on the same charge air temperature for both cases. If you raise the temperature the pressure will also rise.
That is indeed a reasonable assumption matt21.matt21 wrote:I think, that there is no differnce between for the boost with or without recovery as it is based on the needed air volume for the maximum fuel flow.
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I agree that boost has nothing to do with recovery. The boost is calculated by the air needed to burn the 27.77g/s of fuel @ 10.500 rpm.matt21 wrote:I think, that there is no differnce between for the boost with or without recovery as it is based on the needed air volume for the maximum fuel flow.
The recovery leads to a higher back pressure which is decreasing the power at the crankshaft due to higher work needed for expelling exhaust gases. With a higher boost you can help the engine by pushing exhaust gases out by fresh air during valve overlap by maintaining a positive pressure ratio p2/p3.
