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F1 will see a complete change in engine regulations in 2014, and we're having a closer look at what that means exactly
And how would you cool the other side? Either way heat must be dissipated.djos wrote:Hi all, I haven't read the 2014 engine rules in detail so this may be a dumb question:
Would it be possible to use really tiny intercoolers that are actively assisted by solid state electrical devices (TEC's) linked on the hot side via heat pipes to the engine radiators?
In theory they could be powered by excess energy not allowed to be used by the drive train and potentially result in higher horsepower and smaller, lower CoG radiator packaging?
Thoughts? legal or illegal?
As I said in my post, heat pipes linked to the main radiators. I realize TEC's aren't "free" cooling but I'm wondering if the charge cooling (TEC's can produce sub 0 temps) producing more engine power and smaller intercoolers might be worth the effort if legal?Owen.C93 wrote:And how would you cool the other side? Either way heat must be dissipated.djos wrote:Hi all, I haven't read the 2014 engine rules in detail so this may be a dumb question:
Would it be possible to use really tiny intercoolers that are actively assisted by solid state electrical devices (TEC's) linked on the hot side via heat pipes to the engine radiators?
In theory they could be powered by excess energy not allowed to be used by the drive train and potentially result in higher horsepower and smaller, lower CoG radiator packaging?
Thoughts? legal or illegal?
Could you please explain the mechanics behind this statement??Tommy Cookers wrote: 6 cylinders would allow a higher CR than 4 cylinders would
Though there are many v twin bike engines that exceeds 0,4 l per cylinder. Also the high revving ones. Ducatis 1198/1199 are 0,6 l per cylinder and they rev over 10k rpm. I'm not saying they are the most efficient engines but there must be some reason to use this solution.Blanchimont wrote:In the book Motorradtechnik by Jürgen Stoffregen (BMW), one can read that the thermal efficiency is the highest for single cylinder volumes of 0,25 to 0,4 l. The 2013 F1 engine (0,3l / cylinder) and the 2014 one (0,266l / cylinder) are placed it this range. The reasoning behind is that in smaller cylinders the distances from the spark plug to the cylinder walls are smaller, this should help that the fuel is activated by the flame in a shorter time period.
Smaller surface-volume ratios of the combustion chamber can decrease energy losses through the surface.
Larger bore also creates a larger surface area for the same volume so you increase heat losses in the engine. It has a surprisingly large impact on thermal efficiency.Holm86 wrote:
I recon their large bore makes them able to fit much larger intake valves causing the engine to have perhaps slightly lower thermal efficiency but larger volumetric efficiency.
More air only means more power if you're not already limited in fuel flow. In this case, it'll just make the engine run leaner, since they would already be up against the fuel flow limit.djos wrote:As I said in my post, heat pipes linked to the main radiators. I realize TEC's aren't "free" cooling but I'm wondering if the charge cooling (TEC's can produce sub 0 temps) producing more engine power and smaller intercoolers might be worth the effort if legal?
I already said that the TE would decrease? And if the impact really is that large, again why do the massive ship engines have such high thermal efficiency? And beside that modern coatings could help with the heat losses.Owen.C93 wrote:Larger bore also creates a larger surface area for the same volume so you increase heat losses in the engine. It has a surprisingly large impact on thermal efficiency.Holm86 wrote:
I recon their large bore makes them able to fit much larger intake valves causing the engine to have perhaps slightly lower thermal efficiency but larger volumetric efficiency.
The concept is simplicity itself. In a normally-configured engine, the conrod sits at an angle, pushing the piston against the cylinder wall. Increased friction saps power and requires stronger components, increasing reciprocating mass, which also wastes energy during the power stroke, also reducing power. Reposition the cylinder (the CBR and Ninja move it forwards a couple millimeters) and that conrod now travels straight up and down during the power stroke. Voila, less force pushing the piston sideways and therefore less friction. As a result, the length of the piston skirts can be reduced and the size of the rods, pistons and bearings can also be decreased.
Discussing the benefits, Honda says, “Another slick bit of design work further reduces engine friction: The cylinder centerline is offset from the center of the crankshaft 4mm toward the exhaust side. Doing so reduces the lateral resistance generated between the piston and the cylinder during the power stroke. Granted, it’s a small increment, but it’s an ingenious design element exemplifying attention to detail that yields free benefits.”
The full article hereSo why don’t all engines offset their cylinders, reaping frictional and reciprocating mass benefits? According to Kevin Ash, the arrangement does have its disadvantages. Kev writes, “The power stroke takes longer, which is good for a high revving engine as it allows more time for efficient combustion, but it also makes controlling vibration more difficult as the secondary out-of-balance forces become more complex and asymmetric.”
A longer stroke is necessitated and the power stroke requires more time, which can lead to vibration problems. The v-twin in the Hesketh Vulcan used offset cylinders, which were partly to blame for that bike’s significant vibes.
I was suggesting that it is not clear that 400cc cyls would be better than 267cc cyls in 2014 F1Holm86 wrote:Could you please explain the mechanics behind this statement??Tommy Cookers wrote: 6 cylinders would allow a higher CR than 4 cylinders would
Blanchimont wrote: ... one can read that the thermal efficiency is the highest for single cylinder volumes of 0,25 to 0,4 l. ... in smaller cylinders the distances from the spark plug to the cylinder walls are smaller, this should help that the fuel is activated by the flame in a shorter time period.
Smaller surface-volume ratios of the combustion chamber can decrease energy losses through the surface.
I wonder if some of the benefits of this offset in reducing side loads and friction could be obtained without most of the disadvantages of offset. By using the MGUK to apply torque in a large pulse to accelerate the crankshaft for a few degrees immediately after ignition, most of the combustion force could go to accelerating the piston for a short time (until the con rod geometry is more favorable). Then the MGUK could apply no torque during the most unfavorable upstroke time, so that some deceleration would reduce the side force.Tommy Cookers wrote:the Honda kind of offset was very fashionable 100 years ago in GP cars, known as desaxe (with accents that I can't generate here)
yes it makes sense in inline road car engines for slow speed running
given that engine height is often crucial to body lines, and that Honda etc often uses a surprising long stroke
IMO the leading benefit is to allow such a reduced piston height, that would give slap if offset was not used
(motorcycles are maybe different, typically having much larger bore:stroke ratios than cars, and reach much higher rpm)
the traditional argument against offset is that it worsens the geometry on the upstroke, and so increases the side force then
side forces will come both from combustion loads and from inertia loads (from reciprocation of piston mass etc)
given that at high rpm even in road cars the reciprocating inertia loads are larger than the combustion loads
offset, particularly in racing, can in this respect be regarded as worse than useless
and offset appears to increase vibration somewhat
...
EDIT - IMO the (rather limited) reference that Holm gave essentially agrees what I had posted here
in part it seems to parallel F1 developments with pistons (Kawasaki claiming squatter, lighter pistons from crank offset)
it seems that crank offset in an inline engine and gudgeon/wrist pin offset eg in the F1 V8 achieve the same thing .....
lighter, squatter, pistons that give more power by allowing higher rpm and by having less frictional swept area
All these rules are not considering the fuel formula. I'm convinced it will create different optima across all motor sport technology. Every single parameter needs to be re optimized. I'm pretty sure they did massive simulations before they designed the engines. And they would have done even more simulations if there had been any significant freedom of choice as there is in LMP1.Blanchimont wrote:In the book Motorradtechnik by Jürgen Stoffregen (BMW), one can read that the thermal efficiency is the highest for single cylinder volumes of 0,25 to 0,4 l. The 2013 F1 engine (0,3l / cylinder) and the 2014 one (0,266l / cylinder) are placed it this range. The reasoning behind is that in smaller cylinders the distances from the spark plug to the cylinder walls are smaller, this should help that the fuel is activated by the flame in a shorter time period.
Smaller surface-volume ratios of the combustion chamber can decrease energy losses through the surface.
I'm surprised you make all these statements knowing nothing at all about the combustion process of the 2014 engines and how it compares to systems you know. Do you really believe that things will even be remotely similar to anything that has run in F1 or comparable categories of motor sport? These engines and the LMP1 engines will be a land slide in technology and everbody who claims he knows all about them must be either involved in one of the projects or he is speaking from an incredible hybris.Tommy Cookers wrote:I was suggesting that it is not clear that 400cc cyls would be better than 267cc cyls in 2014 F1
the 267cc will have smaller valves and smaller pistons
the 267cc valves will run cooler due the shorter conduction path to the seat (which is larger relative to the heat flow)
the 267cc pistons will run cooler due to the shorter conduction path from crown to cylinder walls (also larger relative to heat flow)
valve temp and/or piston crown temp determine how high the CR can be without detonation
(certainly when the old British motorcycles used the same bore:stroke ratio with 350cc and 500cc the 350cc had higher CR)
this is part of the reason why SI engines can never have the huge cylinder sizes possible in CI engines
the other factor being, as another poster said, the smaller cylinder will have quicker combustion because of smaller flame travel
also the 267cc friction would not be as unfavourable as we might guess
because its piston speed would be lower and its piston travel shorter (and it has only 4 main bearings)
(and of course the V6 is better structurally for the F1car than an inline 4)
true, when the real fuel quantity limit was imposed on 80s turbo F1, one new 4 cyl design appeared
WhiteBlue wrote:I'm absolutely hopping mad to see these things on the test tracks from next month. I hope there will be a bunch of things revealed. It is such a shame that we do not have any freedom in design in F1 any more. It was killed by the cost argument. But now they have frozen it on top because the cost cutting argument never stood up in reality. They could have easily left the displacement and engine config unlimited for 2 years and started to freeze it from the third year. All of this really is a shame.