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Honda F1 project leader Yusuke Hasegawa has outlined a number of reasons why Honda has been struggling so badly in the beginning of the 2017 Formula One season. He confirmed that lots of problems were not discovered while running on the dynamo meter.
Not disagreeing with you, just look at it from another point of view. They designed their turbo based on the combustion technology they had in 2015 and they did not have enough tokens to do a complete power unit layout change. So they were stuck between a rock and a hard place. Once they introduced the combustion update this year, they didn't anticipate how lean they would be able to run and realized quite late that no matter how much they tried to improve the internal geometry of the compressor, that it simply would not be able to flow enough air to fully exploit how lean the new combustion concept allows. I'm sure they're well aware of how much of a step forward is waiting for them next year.PlatinumZealot wrote:The ICE is really honda's problem. Turbo is soo... soo.. they can easily fix that to get a good qualifying, but since the race is where you score points, they sized the turbo for the race. Small power from the ICE means a small turbo for the race. So what we do know is that the ICE is the weakness. Combustion rather. It is too easy to fit a big ass turbo in dyno (or run the engine on compressed air) and fix the power issue (on the dyno to verify things).. so someone with half a brain know it's the ICE that the major weakness.
I bar average pressure during the exhaust stroke = 1 bar loss of BMEPTommy Cookers wrote:well imo it seems as though it is the case ......gruntguru wrote:If that were the case, a change to the cylinder pressure during the power stroke of say 1 bar would only change the BMEP by half a bar (which is not the case). If you check the calculation of BMEP from brake output you will find a term "number of revolutions per power stroke" so a four stroke engine has double the BMEP of a two stroke at the same rpm and power.Tommy Cookers wrote:BMEP is calculated from actual output predominantly occuring 'per active rev' ie during compression and expansion strokes (that's why the calculation of BMEP from measured power differs according to whether the engine is a 2 stroke or a 4 stroke) but the notional '3 bar exhaust' pumping loss as described by gg occurs over a half rev ie 1 stroke only (exhaust) so a 35 bar BMEP engine with 3 bar exhaust pressure reduced to 1 bar will improve the BMEP by about 1 bar (averaged over the 2 strokes) about a 3% BMEP and power improvement
when I calculate the BP from your 35 bar BMEP and 5250 revolutions of a 1600 cc engine running at 10500 rpm I get 490 kW
BMEP in a 4 stroke is the steady fictitious pressure that fictitiously applies throughout the whole revolution of the engine ....
(but only to every other revolution)
and regardless of the fact that in real 4 stroke engines real pressures occur only for half revolutions
BMEP is not a steady fictitious pressure applying to half revolutions
exhaust pressure relief of 2 bar applies for half of each of the above 5250 revolutions (ie for a quarter of the total 10500 revolutions)
so cannot be directly compared to the 35 bar conventional BMEP (because this applies to the whole of the above 5250 revolutions)
exhaust pressure relief of 2 bar for half rev must be replaced by an equivalent 1 bar for the whole rev to calculate power benefit
only if we redefined BMEP as the equivalent fictitious pressure that would be need to be applied for half of the above 5250 revolutions ....
would the new BMEP (still developing the same power that the actual engine does, of course) be directly comparable with the 2 bar .....
this new BMEP would be 70 bar, and so the relief of exhaust scavenge power loss would be 2/70 ie 3% as I suggested before
it would be interesting to see a textbook expression for power loss on the exhaust stroke due to exhaust pressure
Fair enough but the part in bold can't be right... The engineers are not that incompetent, all of that would be known in development. I am pretty sure the compressor flows enough air for what the engine was designed for and more.godlameroso wrote:Not disagreeing with you, just look at it from another point of view. They designed their turbo based on the combustion technology they had in 2015 and they did not have enough tokens to do a complete power unit layout change. So they were stuck between a rock and a hard place. Once they introduced the combustion update this year, they didn't anticipate how lean they would be able to run and realized quite late that no matter how much they tried to improve the internal geometry of the compressor, that it simply would not be able to flow enough air to fully exploit how lean the new combustion concept allows. I'm sure they're well aware of how much of a step forward is waiting for them next year.PlatinumZealot wrote:The ICE is really honda's problem. Turbo is soo... soo.. they can easily fix that to get a good qualifying, but since the race is where you score points, they sized the turbo for the race. Small power from the ICE means a small turbo for the race. So what we do know is that the ICE is the weakness. Combustion rather. It is too easy to fit a big ass turbo in dyno (or run the engine on compressed air) and fix the power issue (on the dyno to verify things).. so someone with half a brain know it's the ICE that the major weakness.
Hindsight is 20/20 as they say.
This is true.. thats why a more "open" or bigger turbine will give more horsepower as the flow goes up. Less power stealing back-pressure. The Mercedes turbine wheel is said to be very big and the waste-gates are the tiniest when you compare it to the others...gruntguru wrote: I bar average pressure during the exhaust stroke = 1 bar loss of BMEP
Work per cycle is the area enclosed by the loops in the pv diagram. Clockwise loops are positive work and anti-clockwise loops are negative (pumping) work.
The high pressure loop is formed by the compression stroke (-ve work created by positive pressure while reducing volume) and the power stroke (+ve work created by positive pressure while increasing volume). The high pressure loop is the only part analysed in the classical Otto cycle analysis.
The low pressure loop is formed by the exhaust stroke (-ve work created by positive pressure while reducing volume) and the intake stroke (-ve work created by negative pressure while increasing volume).
BMEP is work/cycle divided by displacement. Note that displacement is Vmax - Vmin on the pv diagram.
So if you increase the exhaust pressure by 1 bar, the pumping work will increase by 1bar x displacement and the BMEP will reduce by 1 bar x displacement/displacement = 1 bar.
Wikipedia link showing formulas for BMEP for 2 stroke and 4 stroke. https://en.wikipedia.org/wiki/Mean_effective_pressure
http://i.imgur.com/5ghwYMo.jpg
The engineers likely did know they would be limited by turbo size, but because of the tokin limitations (& all the other areas that had to be improved from last year), they likely didn't have enough for the required layout change. Believe the turbo is probably about as big as they can make it in the current configuration, but is currently the limiting factor.PlatinumZealot wrote:Fair enough but the part in bold can't be right... The engineers are not that incompetent, all of that would be known in development. I am pretty sure the compressor flows enough air for what the engine was designed for and more.godlameroso wrote:Not disagreeing with you, just look at it from another point of view. They designed their turbo based on the combustion technology they had in 2015 and they did not have enough tokens to do a complete power unit layout change. So they were stuck between a rock and a hard place. Once they introduced the combustion update this year, they didn't anticipate how lean they would be able to run and realized quite late that no matter how much they tried to improve the internal geometry of the compressor, that it simply would not be able to flow enough air to fully exploit how lean the new combustion concept allows. I'm sure they're well aware of how much of a step forward is waiting for them next year.PlatinumZealot wrote:The ICE is really honda's problem. Turbo is soo... soo.. they can easily fix that to get a good qualifying, but since the race is where you score points, they sized the turbo for the race. Small power from the ICE means a small turbo for the race. So what we do know is that the ICE is the weakness. Combustion rather. It is too easy to fit a big ass turbo in dyno (or run the engine on compressed air) and fix the power issue (on the dyno to verify things).. so someone with half a brain know it's the ICE that the major weakness.
Hindsight is 20/20 as they say.
That's a handy chart Brian - thanks. Suggests that at PR = 3.5 the state of the art for efficiency (dashed line) is about 84% although that Honda outlier hints that better things are possible.Brian Coat wrote:The attached HF118 data shows that even prior to the GE JV, the Honda team were none too shabby at advanced cf compressor design: