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With the track debut of the new V6 turbo engines coming closer and closer, teams are admitting that one of the major challenges of getting and efficient and reliable package will be managing the cooling systems.
Absolutely, but you can imagine his input.raymondu999 wrote:Would be interesting to consider that that engine was probably designed with Newey's input in mind, given that RBR is now Renault's de facto works team.
Back in 2009 mclaren did have assymetric sidepods to house the KERS.aussiegman wrote:Ah...No. Uneven distribution of airflow over the rear wing and other surfaces would result. Maybe OK in NASCAR seeing they only turn one way.turbof1 wrote:Yeah, that's going to be a bitch to position inside the car. We might see assymetric sidepods.
More likely the water radiator will be in one side and the intercooler the other.
Sure, however in 2009 McLaren for Malaysia did introduce IIRC a marginally wider, rounded section in the lower rear bodywork above the floor but under the exhaust opening (which was also larger left to right) which was used to house the KERS electronics package which is not really relative in size to either an intercooler nor a radiator.turbof1 wrote:Back in 2009 mclaren did have assymetric sidepods to house the KERS.
IMHO, I wouldn't think you want to be splitting the intercooler side to side. If you could run one each side I think that would be the simplest solution.turbof1 wrote:The big issue is that the water radiators are too big to fit in one sidepod. You need both to get the right amount of cooling.
Is the intercooler splittable? Like 1 entry in each sidepod and somewhere inside the car they converge?
(Also, to be completely honest, mclaren later in that season reverted back to symmetric sidepods.)
Radiator size is not just a function of maximum power -air speed and fluid speeds through the care play a big part in what you need in terms of rads .rjsa wrote:I'd say radiators need around 1/3 less area. Simple math really, they'll burn 100Kg of fuel instead of 150Kg over the same period of time.
time has a place in all this as well maybe?It's got nothing to do with the fuel tank size, but the amount of fuel burnt over the race distance and the energy flow inside the engine.marcush. wrote:Radiator size is not just a function of maximum power -air speed and fluid speeds through the care play a big part in what you need in terms of rads .rjsa wrote:I'd say radiators need around 1/3 less area. Simple math really, they'll burn 100Kg of fuel instead of 150Kg over the same period of time.
So the problem starts with slower speeds but high loads .Given a turbo engine does produce more power down the revband as well it seems possible your cooling demands are rising compared to a succer...
You may have less energy available -but i don´t think even Adrian Newey has reduced the radiator size of his latest creations based on their strategy not to fill the tank completely..Maximum cooling demand is a function of how quickly you can burn the fuel at what efficiency not how much fuelallocation you got....but then A top fuel dragster does not even have a water radiator ,no?
Exactly, on averagen, not considering anything else. Just a base number for a first round in the project spiral, if anyone is familiar with the concept.turbof1 wrote:1/3 on average, but temperatures inside the car aren't constant. The car still needs sufficient cooling at its peak energy consumption, like qualy and a part of the race.
That won't be even near to it. By my figuring the ERS will have a transfer of 542 MJ total from all recoveries and use of the recovered energy. The KERS in comparison was having 44 MJ. If you consider a minimum of 4 % heat rejection per transition you have to get rid of 22 MJ heat in 2014 and 1.8 MJ in 2013. The energy rejection from the ERS will rise by a factor of 12.Holm86 wrote:Don't forget that the ERS systems will need about double the cooling of what they have now.
That is a good starting point and absolutely correct. But there is more reduction to the radiator capacity. The reduced fuel flow will be converted with higher thermal and mechanical efficiency. Mechanical efficiency because down sizing and down speeding will produce less friction. Thermal efficiency because the engine will not use fuel for cooling but run on stoichiometric AFR or even under it on occasions like safety cars. This will raise the engine temperature, but most of the surplus heat will be going out of the exhaust valves to push the turbine. So expect more than 30% reduction of radiator capacity, probably more like 40%.rjsa wrote:I'd say radiators need around 1/3 less area. Simple math really, they'll burn 100Kg of fuel instead of 150Kg over the same period of time.