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Sorry, but you are so far away from thermodynamics, that this sounds like a joke...trinidefender wrote: go and read up about thermodynamics.
Fair enough, thermodynamics concerns the relationship between heat and other forms of energy. I stand corrected. What I said about heat transfer still stands though.basti313 wrote:Sorry, but you are so far away from thermodynamics, that this sounds like a joke...trinidefender wrote: go and read up about thermodynamics.
You might want to do some reading yourself, in the turbo system, you are wanting to cool the intake air, to the outside airstream.trinidefender wrote: And if it was only the end substance than matters when it comes to heat transfer then why do cars use water radiators and not air radiators since they would be much lighter. Also why are additives used to help the water cool better. If what you (ringo) said is true then additive or not the same heat transfer for normal cars would take place but that is simply not true, go and read up about thermodynamics.
No it's not, and no they don't, otherwise you wouldn't see all the pressurised accumulator/header tanks for the cooling systems all over the cars.gilgen wrote:As far as I can ascertain, some, if not all the teams use a waterless coolant. Even modern road cars now use this, and is every bit as effective
IIRC all ancillaries must be driven directly off the engine - alternator, oil pump, water pump(s), etc. I'd assume that would include charge cooling pumps too unless they don't fall under the engine regulations (although I can't see why not)ringo wrote: There are two auxiliary water pumps (not shown) for the water-air intercoolers. I believe they are electronically controlled.
Maybe Mercedes could be doing this, who knows.
Waterless systems still need header tanks etc. Waterless does not mean no liquids! It just means that the liquid used for cooling is a formulation.PhillipM wrote:No it's not, and no they don't, otherwise you wouldn't see all the pressurised accumulator/header tanks for the cooling systems all over the cars.gilgen wrote:As far as I can ascertain, some, if not all the teams use a waterless coolant. Even modern road cars now use this, and is every bit as effective
Actually the table shows water to air as having a higher heat transfer rate than air to air. How is it that it is less efficientPhillipM wrote:You might want to do some reading yourself, in the turbo system, you are wanting to cool the intake air, to the outside airstream.trinidefender wrote: And if it was only the end substance than matters when it comes to heat transfer then why do cars use water radiators and not air radiators since they would be much lighter. Also why are additives used to help the water cool better. If what you (ringo) said is true then additive or not the same heat transfer for normal cars would take place but that is simply not true, go and read up about thermodynamics.
For a car engine, you are wanting to cool the metal block, to the outside air. That's a very different system.
That table you linked, for what is relevant is air>aluminium>air in the case of an air/air exhanger, in your water cooled system, it's air>aluminium>water>aluminium>air.
Even your own table shows you that's not going to be as efficient.
As for additives to the water - about the only thing you can add is a surface tension modifier if you have issues with properly wetting parts of the system walls, that doesn't help heat capacity anyway.
Because it's not water to air. It's water to metal to air. And before that can occure, it's air to metal to water.trinidefender wrote:
Actually the table shows water to air as having a higher heat transfer rate than air to air. How is it that it is less efficient
If you look at the table again you'll realise there is a collom there that gives different heat exchange values through different transmission surfaces. Therefore you point is invalid.PhillipM wrote:Because it's not water to air. It's water to metal to air. And before that can occure, it's air to metal to water.trinidefender wrote:
Actually the table shows water to air as having a higher heat transfer rate than air to air. How is it that it is less efficient
So at the end of it all, it's still air>air, but through even more interfaces.
It's not my point, it was yours, have you actually read *your* table and worked through a simple calc usinhg your very own link? Because it proves the point nicely.trinidefender wrote: If you look at the table again you'll realise there is a collom there that gives different heat exchange values through different transmission surfaces. Therefore you point is invalid.
Because with a water to air intercooler, you aren't going water to air. You're going air to water to air. With some metal in between.trinidefender wrote:Actually the table shows water to air as having a higher heat transfer rate than air to air. How is it that it is less efficient
Additives don't make water cool better. They just change the boiling point and freezing point of the water. They also have anti corrosion and anti scaling properties. For a race car that's going to have all the fluids drained at the end of a race, corrosion is not a problem, engine just has to be flushed out. so water can be used. Freezing isn't a problem either, so glycol is not necessary.trinidefender wrote: And if it was only the end substance than matters when it comes to heat transfer then why do cars use water radiators and not air radiators since they would be much lighter. Also why are additives used to help the water cool better. If what you (ringo) said is true then additive or not the same heat transfer for normal cars would take place but that is simply not true, go and read up about thermodynamics.