pgfpro wrote:The 1988 RA168-E Honda engine in fuel saving mode was most efficient at 12000 rpm running 2.5bar with a BSFC of 272g/kWh making 620PS and using around 124kg/hr.If you drop the boost to 1.9bar you could get to the 100kg/hr 2014 rule. By keeping the same 272g/kWh BSFC the same engine would now make 502HP at 12000rpm.
The new DI 2014 engine I would guess have a much better BSFC number of around 225g/kWh, this would increase the power level to around 597HP. This 225g/kWh IMO would be a very conservative number. I project that we will see more around the likes of 212g/kWh BSFC number. This would increase the power to around 631HP.
The new 2014 engines will have a lot more new technology that will improve drastically over the RA168E.
Fast Burning Head Design
Lean Burn Power/FC DI
Increased VE Much Higher Compressor Efficiency above 80% Much Higher Turbine Efficiency also above 80%
Keeping in mind this is only running the petrol engine, at any given time you could have another 100+HP the electric motor could add to it.
That's quite a lot of pondering !
Where does this 26% improvement in SFC come from ?
Much of the new design/technology that is valuable in road engines (and is supported in the 2014 rules) has little value in F1
Present F1 combustion works well enough at 20000 rpm (due to fast-burn properties in F1 fuel for last 20 years), so how can faster burn be gainful in the 2014 10000-120000 rpm engines ?
FB is all about reducing NOx at source in road engine ? thus eliminating the reduction catalyst, (which can't work in the presence of oxygen and must have a stoichiometric (ie fuel-wasteful for road use) mixture).
This FB is a delayed, then fast, burn to reduce 'hot time' that produces NOx ?
Lean Burn is primarily to enable reduced power operation with less throttling than traditionally needed (improving economy). This is only valuable in road use, F1 is essentially full throttle or none (in part aided by short shifting).
I'm sceptical about the other areas for major gains, just because you call something TERS doesn't mean you can often pull 100 bhp electrically free of fuel consumption. Turbines use pressure drop, you can't use the same pressure drop at the piston and the turbine , (of course there will be transients, periods of bleeding down unwanted turbine rpm).
Fuel allowance will be cut year-on-year ?
Technically there is huge potential in the fuel, mysteriously there now seems (even in the current rules) no limit on octane number. Still calling it 'pump fuel' ?
There seems to be some new methods of efficiently making Triptane (2,2,3-trimethyl butane), there must be some reason for this interest ?
A bit like isooctane,Triptane is a natural ingredient (at low levels) of crude oil, so is legitimate.
Naturally 112 octane, it is outstandingly sensitive to organometallc octane boosters and could thus be valuable if a modern substitute for TEL 'lead' was found acceptable.
With the TEL at the engine-fouling limit it was a '300 octane' fuel, ie rich mixture PN of 300, meaning a rich-supercharged tripling of 100 octane power, hence the name Triptane. Typically part-Triptane fuel allowed raising CR for major gains in economy even with some power gains.
TEL was always far from the only game in town, it was dropped because of its toxicity (to catalysts really), maybe we won't always need catalysts (of the current type) ?
Triptane has a higher heat content in the combustion-appropriate quantity than the established high octane alternative,Toluene.
Using very high octane fuel for economy via very high CR with boost IMO wouldn't give significant dissociation reactions ?
