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.
He typically is pretty reliable with the 'rumors' and 'mumblings' going on track side. When it comes to 'rumors' I tend to trust his more than most. But take it for what you will.Blackout wrote:James Allen reliable?ajnšpric_pumpa wrote:Thanks @Dren for that link,Omnicorse said recently that it will be 15Bhp but it is Omnicorse after all.
Allen is a bit more reaible i would say.
Arai said 15hp.
How did you alter the a:f ratio? Of course reducing the fuel flow will create lower in cylinder temps and hence pressure. However leaving the fuel flow the same at 100kg/hr and increasing airflow to increase a:f ratio should not lower the temp that much.ringo wrote:I have inputted the high a:f into my calculator, and ive realized that Honda's engine cannot be used as a prime example. There is a great power loss when compared to stoichometry. The flame temperature in the cylinder just too low. I notice high boost is used momentarily, it may be some fuel saving tactic, but high a:f doesn't really have any theoretical advantage, it must be some real life occurrence in the cylinders that may have been referred to in the engine thread.
Honda's engine is underpowered, and maybe they are just doing things a bit differently with their unit. It would be good to see data from a mercedes or ferrari engine.
ringo wrote:I have inputted the high a:f into my calculator, and ive realized that Honda's engine cannot be used as a prime example. There is a great power loss when compared to stoichometry. The flame temperature in the cylinder just too low. I notice high boost is used momentarily, it may be some fuel saving tactic, but high a:f doesn't really have any theoretical advantage, it must be some real life occurrence in the cylinders that may have been referred to in the engine thread.
Honda's engine is underpowered, and maybe they are just doing things a bit differently with their unit. It would be good to see data from a mercedes or ferrari engine.
In my above quote my reference to lean out the A/F ratio, I didn't state what the A/F ratio is? In my calculations and sims I'm talking no more then stoich up to 16:1 A/F ratio being max. Any leaner as you stated you start losing exhaust temperature.The reason I think its so is because as you approach the upper rpm fuel limit you can load the turbo with the MGUH and lean the A/F ratio and pull more energy from the turbo. If you run it full rich you will be hitting the fuel limit at a lower boost with less energy. The difference from my calculations are about 20HP.
Are we sure that the 2.29 bar are charge air pressure?pgfpro wrote:I'm trying to find exhaust back pressure on the telemetry but can't see it? I would think they would have it right with the turbo outputs? It should shadow the intake boost numbers to some degree until they load the turbo for more MGUH energy.Thunders wrote:Don't know about the Drive section but:
81376 rpm should be Turbo rpm
2.29 bar should be Charge Air Pressure
TExl should be Exhaust temperature of the left Cylinder Bank
TExr same on the right hand side
The other 2 could be Fuel usage.
I can alter A:F and stick to max permitted fuel flow at the specified rpm. I didn't reduce the fuel flow, but as a result of the increase mass of air, the combustion temperatures will drop. The engine is not necessarily more efficient if there are increased pumping loses either. Your thermal efficiency loss is mostly in combustion.trinidefender wrote:
How did you alter the a:f ratio? Of course reducing the fuel flow will create lower in cylinder temps and hence pressure. However leaving the fuel flow the same at 100kg/hr and increasing airflow to increase a:f ratio should not lower the temp that much.
How can it be some fuel saving tactic? The whole formula is that a more efficient engine produces more power.
I'm not so sure that your calculator can work out the additional variables created by stratified injection combustion.
Ok i see.pgfpro wrote:ringo wrote:I have inputted the high a:f into my calculator, and ive realized that Honda's engine cannot be used as a prime example. There is a great power loss when compared to stoichometry. The flame temperature in the cylinder just too low. I notice high boost is used momentarily, it may be some fuel saving tactic, but high a:f doesn't really have any theoretical advantage, it must be some real life occurrence in the cylinders that may have been referred to in the engine thread.
Honda's engine is underpowered, and maybe they are just doing things a bit differently with their unit. It would be good to see data from a mercedes or ferrari engine.In my above quote my reference to lean out the A/F ratio, I didn't state what the A/F ratio is? In my calculations and sims I'm talking no more then stoich up to 16:1 A/F ratio being max. Any leaner as you stated you start losing exhaust temperature.The reason I think its so is because as you approach the upper rpm fuel limit you can load the turbo with the MGUH and lean the A/F ratio and pull more energy from the turbo. If you run it full rich you will be hitting the fuel limit at a lower boost with less energy. The difference from my calculations are about 20HP.
So I think they are running full power rich and as they approach the higher rpm before they up shift is when they could get the most output from the turbine by running stoich or a little leaner then stoich.
What I am getting at is that many here are all arguing cases for and against running anything from stoichiometric to quite lean. The problem I see with that is that we are basing this (air mass flow numbers obtained through pressure ratios and temperatures) off of calculations used for working out stoichiometry for normal car petrol.Tommy Cookers wrote:the stoichiometric mass (if nothing's unavailable for combustion) is apparently due only to the proportion of hydrogen to carbon ?
eg pentane is C5H12 and its stoichiometric mass ratio is 15.22
dodecane ( a typical major constituent of gasoline) is C12H26 and its SMR is 14.88 (makes sense)
benzene is (similar to distinctive constituents of 100/130 Avgas) is C6H6 and its SMR is 13.25 (why Avgas SMR is a bit low)
a higher ratio of hydrogen to carbon gives (ignoring eg double bonds) a higher mass-specific calorific value, a prime requirement
I don't see that this takes us anywhere startling, though
