drgondog
Major
Timppa - excellent link - good foundation tutorial. Wrong to apply universally without careful understanding of significant variations between aircraft that are accounted for by 'rough estimates' and 'assumtions' in his model.
I will give some detailed thoughts perhaps tomorrow when I have time to discuss specifics (if you wish).
Here are some immdediate observations.
Thrust based on Hp. The equation is correct for Thp for sea level but does not include exhaust thrust, or if applicable - Meredith effect'. Not so important for SL, very important for 30,000 feet.
I scanned the report so may have missed whether he not only introduces the Hp contribution from max available at the altitude point where the supercharger can no longer supply 100% requirements, but also the mass flow rate through the propeller disk as density reduces with height.
I did not take particular note regarding fundamental comparison of Hp vs altitude differences between different engines as a function of supercharger/turbo efficiency.
His tutorial regarding the factors and approach at Calculating Thrust available from a prop/engine/gear standpoint from the view of a preliminary design standpoint is very good - and necessary when a significant body of flight test data across an entire altitude/hp/boost and speed results are not available.
In this forum, neither flight test nor manufacturer specs are 100% reliable, nor are all the aircraft data available for the ships we wish to compare.
Drag = He correctly balances Total Drag with the Thrust.
He illustrates Cd0 and IIRC used 'about .020' for the P-51D. It may be off a little but the important point is that Total Drag = Induced plus Parasite (sum of all non lift components) Drag. He is able to manipulate the relative contributions at each point in the velocity and Lift range correctly as long as he is in level flight. He correctly obtains Induced Drag (for the wing) as a function of CL.
I take issue that this is adequate for the full range of CL's from straight and level flight to max bank/max CL flight for maintaining altitude - as we are trying to do with these equations. I may have missed where he factors in Trim Drag.
Cd0, as presented, is the level flight clean Parasite Drag which, for this build up for a Mustang, is Cd0 of the clean wing/body/tail combo. This means no elevator or rudder or aileron (or manuevering flap or full flap) deflections to incrementally provide lift(and drag) forces to the system.
Before we get tangled up in semantics I realize 'delta CD' for the flap/manuevering flap deployment is not an add to parasite drag - but it is an add to the total drag of the system offsetting available Thrust to reach equilibrium.
Skip the transition however and go straight to CLmax.
For the clean (no flap, manuevering flap - elevator, rudder or aileron deflection) configuration the Cd0 is still useful - but not of itself enough as the a/c is in a max bank angle with necessary rudder, elevator, aileron deflection - all contibuting measurable and significant drag incrementally to the clean configuration Induced and Parasite Drag. So, you have to calculate Trim drag.
In the case of a P-38J-25, when only manuevering flaps are deployed, you have to determine the contribution to Total CL max, as well as the extra drag, of this new wing body combination because it a.) should slow the a/c down (some), and b.) tighten the turn (some) in contrast to clean turn configuration.
You will not know until you have introduced the new factors into the free body force balance whether the P-38 has improved turn performance relative to max turn rate of turn... but you cannot insert level flight 'clean' - and flaps down Vstall in these equations for a P-38 with 8 degree manuevering flaps down..
I did this overview in a hurry - I will come back and edit the brainfarts later.
