flyrotary@lancaironline.net Mailing List Archive

Tracy,

I'm no expert, but I do follow cooling issues with great interest and keep notes on previous attempts and successful outcomes. From these notes I conclude that with different core fin densities and size one core likely to steal from the other core from the available air available. As you described in your own trials, so it's logical to have separate air for each core.

It's also logical to know that higher deltaT in air cooled engines require smaller inlets - trade off is larger tolerances etc.

I'm at a loss to understand similar exit air with the larger delta T, given similar conditions. Seems unlikely to me.

Finally 2 x times the cooling of air cooled engines does seem a rather large difference, unless we are talking 1.5 cu" times the HP and 3 cu"times the HP . I do believe even 1.5 is a very low number. So I will settle for 2 times the HP for air cooled and perhaps with exceptional efficiency 2.5 times the hp for water cooled.

I believe that anything under that limit will result in marginal performance in high HP and exceptionally hot days. As Lynn said there is no such thing as excess cooling and that's true, however the penalty is excess drag. So I'm happy to be given new 'rules of thumb' in the event your results are different. Being conservative I will probably stick to the '3 times' rule of thumb - but I in no way put a mocker on your attempts nor ridicule your endeavours.

George (down under)

I'm wondering if that figure for airflow is true (2x airflow for water cooled vs air cooled). All the measurements I have seen (not many) indicate that the exit air temperature on a Lyc installation is not significantly different than on our water cooled engines. The total heat per HP is not that different so my assumption is that the CFM requirement is not much different.

The only advantage the air cooled engine's higher Dt gives you is that it requires far fewer square inches of surface area to transfer a given number of BTU with a given number of CFM. Our advantage is that we can add surface area a LOT more easily than an air cooled can. You can only put so many fins on a cylinder head.

But I may be missing something. Other thoughts?

Tracy

On Thu, Dec 24, 2009 at 3:38 PM, MONTY ROBERTS <montyr2157@windstream.net> wrote:

Thomas,

Though the Meredith effect is possible in theory if you actually run the numbers you find that the only time it would produce any thrust is at power levels in excess of 1000 hp and flight speeds over 400 mph. Even then the effect is very small and any gain you might get from it will be decimal dust compared to the drag from ingesting extra air. A liquid cooled engine will require ingesting roughly 2X the cooling air compared to an air cooled engine for the same power level. There is no way to make up for that 200 degree extra temp differential you get from an air cooled engine. You can't fool Qdot = mdotCpDeltaT. Liquid cooling has numerous advantages. Drag reduction is not one of them. The "cooling thrust" Myth is a Myth.

At our speeds and power levels you will be wasting your time chasing Mr. Meredith. That does not mean you shouldn't do a good job on the diffuser and the nozzle to minimize drag, but you can forget about any thrust. This is true even if you dump all the heat from the exhaust into the exit air so don't bother. Just point the exhaust aft.

In a piston engine fighter there are tactical advantages to having a slender nose that you can see around. Liquid cooling allows this. It also allows greater power density in the engine because you can have heat transfer through sub cooled boiling at the hot spots in the cooling jacket. It also allows a lower frontal area from a drag standpoint, but you pay by having to reject heat at 200 deg or so less than an air-cooled engine. That is perhaps an acceptable trade off. In practice I am not sure that the big radial aircraft were not superior to the mustangs etc. There is more frontal area with a radial, but there is also more useable internal volume and the cooling drag is less. More internal fuel means more stores and more/larger ammo in the wings. Plus better resistance to battle damage. Sea Fury vs. Mustang? The Sky Raider was in use as late as Vietnam. Anyway it's all hangar flyin' at this point.

None of that applies to us. There are so many real world practical constraints (packaging, size, and weight) to a working cooling system that trying to get the "optimum" is just not feasible. This is doubly so since the gain you are going to be chasing does not exist. There is not enough heat rejection at our power levels, and there is not enough ram pressure to recover at our speeds.

Thermo is as Thermo does.

Monty

----- Original Message ----- From: "Thomas Mann" <tmann@n200lz.com>
To: "Rotary motors in aircraft" <flyrotary@lancaironline.net>
Sent: Wednesday, December 23, 2009 11:55 AM
Subject: [FlyRotary] Re: Meredith Effect - Spitfire

Let's try that again

-----Original Message-----
From: Rotary motors in aircraft [mailto:flyrotary@lancaironline.net] On
Behalf Of Thomas Mann
Sent: Wednesday, December 23, 2009 11:50 AM
To: Rotary motors in aircraft
Subject: [FlyRotary] Meredith Effect - Spitfire

I thought I would share this bit of info I ran into regarding the Meredith
Effect associated with the belly type scoop as was used on the P-51 and
Spitfire.

Enjoy.

T Mann

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