F1 will see a complete change in engine regulations in 2014, and we're having a closer look at what that means exactly
It would just be pumped out by the engine, and you have just wasted fuel.erikejw wrote:Is it allowed during mid corner to inject fuel into the combustion chamber(to have that behaviour when throttle is below 30%) but not ignite it? It could be useful in qualy.
Ok, so what about inject it into the prechamber and have a prechamber design that keeps some of the fuel until ignition, preferably in a way that does ignite all of it at once(is that even possible)?wuzak wrote:It would just be pumped out by the engine, and you have just wasted fuel.erikejw wrote:Is it allowed during mid corner to inject fuel into the combustion chamber(to have that behaviour when throttle is below 30%) but not ignite it? It could be useful in qualy.
I am convinced that all manufacturers still use pneumatic valves - they still offer a significant power advantage with even just 6 cylinders. Desmodromic valves were really just a way of side-stepping spring dynamics problems in the past - today these issues are well understood and everyone can design reliable 15k rpm valvetrains with springs.roon wrote:Thanks, gg. The point about high speed control limits makes sense. Keeping in mind the efficiency formula, one wonders what is left to be optimized in the valvetrain. Do springless, captive cam (desmodromic) systems consume less engine power? On one hand, they have more cam-riding surfaces. I assume a spring loaded valve, while consuming energy to compress the spring, returns some energy to the system upon valve closing. I'd wager an F1 optimized convential cam drive is pretty efficient & lightweight as-is. Maybe roller bearings are employed in the current formula.
These camless systems would surely have been considered if they are as efficient as they claim to be, although durability & development payoff are considerations as well. To the latter: how many HP does it take to spin the camshafts?
I don't think its allowed.Mudflap wrote:I am convinced that all manufacturers still use pneumatic valves - they still offer a significant power advantage with even just 6 cylinders. Desmodromic valves were really just a way of side-stepping spring dynamics problems in the past - today these issues are well understood and everyone can design reliable 15k rpm valvetrains with springs.roon wrote:Thanks, gg. The point about high speed control limits makes sense. Keeping in mind the efficiency formula, one wonders what is left to be optimized in the valvetrain. Do springless, captive cam (desmodromic) systems consume less engine power? On one hand, they have more cam-riding surfaces. I assume a spring loaded valve, while consuming energy to compress the spring, returns some energy to the system upon valve closing. I'd wager an F1 optimized convential cam drive is pretty efficient & lightweight as-is. Maybe roller bearings are employed in the current formula.
These camless systems would surely have been considered if they are as efficient as they claim to be, although durability & development payoff are considerations as well. To the latter: how many HP does it take to spin the camshafts?
As for cam bearings - again, pretty sure the cams have no bearings, running right no the head material - this seems to work just fine on high speed motorcycle engines. Remember that at operating temperatures the friction differences between roller and plain bearings are negligible. Yes the exhaust lobe loads will be much greater due to the high cylinder pressures but I have no doubt that relatively 'normal' bearing specific pressures can be achieved.
hurril wrote:I don't think its allowed.Mudflap wrote:I am convinced that all manufacturers still use pneumatic valves - they still offer a significant power advantage with even just 6 cylinders. Desmodromic valves were really just a way of side-stepping spring dynamics problems in the past - today these issues are well understood and everyone can design reliable 15k rpm valvetrains with springs.roon wrote:Thanks, gg. The point about high speed control limits makes sense. Keeping in mind the efficiency formula, one wonders what is left to be optimized in the valvetrain. Do springless, captive cam (desmodromic) systems consume less engine power? On one hand, they have more cam-riding surfaces. I assume a spring loaded valve, while consuming energy to compress the spring, returns some energy to the system upon valve closing. I'd wager an F1 optimized convential cam drive is pretty efficient & lightweight as-is. Maybe roller bearings are employed in the current formula.
These camless systems would surely have been considered if they are as efficient as they claim to be, although durability & development payoff are considerations as well. To the latter: how many HP does it take to spin the camshafts?
As for cam bearings - again, pretty sure the cams have no bearings, running right no the head material - this seems to work just fine on high speed motorcycle engines. Remember that at operating temperatures the friction differences between roller and plain bearings are negligible. Yes the exhaust lobe loads will be much greater due to the high cylinder pressures but I have no doubt that relatively 'normal' bearing specific pressures can be achieved.
They maybe using a crank offset. This effects the piston liner friction from the side thrust reaction force from combustion, it has other effects like a slight increase of the actual stroke length plus other powertrain dynamics that are still being studied and understood.roon wrote:Unless there would be a beneficial function to a flexible crankshaft (beyond what is commonplace). Flexing axially or within the throws. The reason for the new crankshaft regs is probably just to limit development costs for ever lighter & thinner cranks. But I wonder if one of the manufacturers was doing something clever beyond lightweighting.
I was picturing something like a whirling jump rope, with the crankshaft throw(s) warping outwards at speed to alter stroke & compression, or provide shock absorbtion.
Which leads me to wonder how the FIA inspects swept volume. By CAD drawings? Or by physical inspection during homologation?
Surely in a vee engine if teh offset benefits one bank it is detrimental on the other?Muniix wrote:They maybe using a crank offset. This effects the piston liner friction from the side thrust reaction force from combustion, it has other effects like a slight increase of the actual stroke length plus other powertrain dynamics that are still being studied and understood.roon wrote:Unless there would be a beneficial function to a flexible crankshaft (beyond what is commonplace). Flexing axially or within the throws. The reason for the new crankshaft regs is probably just to limit development costs for ever lighter & thinner cranks. But I wonder if one of the manufacturers was doing something clever beyond lightweighting.
I was picturing something like a whirling jump rope, with the crankshaft throw(s) warping outwards at speed to alter stroke & compression, or provide shock absorbtion.
Which leads me to wonder how the FIA inspects swept volume. By CAD drawings? Or by physical inspection during homologation?
This piston liner friction effects the apparent inertia of the cranktrain which effects the friction and vibration and hence fuel use. Since the cylinder pressure varies so much throughout the crank/rod angle of the cycle with the boosted engines this would provide some friction reduction and saving of fuel. Their is also a slight change to the piston velocity and acceleration profiles.
Marc
otoh and fwiw at this moment it seems to me .....wuzak wrote:Surely in a vee engine if teh offset benefits one bank it is detrimental on the other?Muniix wrote:They maybe using a crank offset. This effects the piston liner friction from the side thrust reaction force from combustion, it has other effects like a slight increase of the actual stroke length plus other powertrain dynamics that are still being studied and understood.
This piston liner friction effects the apparent inertia of the cranktrain which effects the friction and vibration and hence fuel use. Since the cylinder pressure varies so much throughout the crank/rod angle of the cycle with the boosted engines this would provide some friction reduction and saving of fuel. Their is also a slight change to the piston velocity and acceleration profiles.
Marc
That all depends on the EVC event, and back pressure in the exhaust manifold. Seeing as you have complete control over the back pressure(and intake plennum pressure) in these engines, you can reduce pumping losses during the compression stroke with the right exhaust valve timing and MGU-H, relief valve, and wastegate control.Tommy Cookers wrote:otoh and fwiw at this moment it seems to me .....wuzak wrote:Surely in a vee engine if teh offset benefits one bank it is detrimental on the other?Muniix wrote:They maybe using a crank offset. This effects the piston liner friction from the side thrust reaction force from combustion, it has other effects like a slight increase of the actual stroke length plus other powertrain dynamics that are still being studied and understood.
This piston liner friction effects the apparent inertia of the cranktrain which effects the friction and vibration and hence fuel use. Since the cylinder pressure varies so much throughout the crank/rod angle of the cycle with the boosted engines this would provide some friction reduction and saving of fuel. Their is also a slight change to the piston velocity and acceleration profiles.
Marc
friction effect benefits are detrimental (ie self-cancel) only where the V has banks 'spread' for space reasons eg VR6/Lancia type and 1970s Morini
(engines where notionally one cylinder bank is displaced in one direction and the other bank in the opposite direction)
otherwise ie if the both cylinder banks are displaced in the same direction the friction benefit is realised (do any production Vs have this ?)
though we must remember in a high speed engine the friction related to reciprocation may exceed the friction related to the power stroke
and with our highly boosted ultra lean 'heat dilution' engine the benefits available are relatively less than with conventional engines
because the HD engine piston/rod is working unusually hard on the compression stroke the friction is then unusually high
and the offset conventionally favourable (ie favourable on the power stroke) is unfavourable ie detrimental on the compression stroke
Variable jet nozzle? Piezoelectric control?FW17 wrote: ↑31 Mar 2017, 20:05http://web.ics.purdue.edu/~lqiao/Public ... bility.pdf
Nozzle profiles of the jet injector also has a huge bearing
Supersonic nozzle, shaped to cope with shock waves, & not 'choke' at such speed...godlameroso wrote: ↑31 Mar 2017, 21:31Variable jet nozzle? Piezoelectric control?FW17 wrote: ↑31 Mar 2017, 20:05http://web.ics.purdue.edu/~lqiao/Public ... bility.pdf
Nozzle profiles of the jet injector also has a huge bearing
When your talking about "reducing pumping losses during the compression stroke" are you referring to compression losses from the effort/negative work or the actual highly dynamic pressure environments in pumping available to the engine management.godlameroso wrote: ↑12 Mar 2017, 16:57That all depends on the EVC event, and back pressure in the exhaust manifold. Seeing as you have complete control over the back pressure(and intake plennum pressure) in these engines, you can reduce pumping losses during the compression stroke with the right exhaust valve timing and MGU-H, relief valve, and wastegate control.Tommy Cookers wrote:otoh and fwiw at this moment it seems to me .....wuzak wrote:Surely in a vee engine if teh offset benefits one bank it is detrimental on the other?
friction effect benefits are detrimental (ie self-cancel) only where the V has banks 'spread' for space reasons eg VR6/Lancia type and 1970s Morini
(engines where notionally one cylinder bank is displaced in one direction and the other bank in the opposite direction)
otherwise ie if the both cylinder banks are displaced in the same direction the friction benefit is realised (do any production Vs have this ?)
though we must remember in a high speed engine the friction related to reciprocation may exceed the friction related to the power stroke
and with our highly boosted ultra lean 'heat dilution' engine the benefits available are relatively less than with conventional engines
because the HD engine piston/rod is working unusually hard on the compression stroke the friction is then unusually high
and the offset conventionally favourable (ie favourable on the power stroke) is unfavourable ie detrimental on the compression stroke
