That way you can take those numbers and rehydrate them with the proper environmental and aircraft parameters to get the actual aerodynamic forces.
In other words, for simplicity.
On the actual topic, the question concerns the induced drag of a moving airfoil. It would seem inaccurate to claim velocity constant or ignore it. Aren't we attempting to understand what individual effect causes tip vortice strength to change?
Sorry, I'm not attempting to be difficult. I really don't understand how you can eliminate a variable in this case. I realize most of science is about setting the majority of the variables constant so you can understand how changing one variable effects the outcome of the grand design. (Matt, this is what I did earlier post that you asked about. More on that in a second.)
In this case, I'd be curious to understand velocities impact on vortex strength because it seems important to me. Why is it unimportant? This is what I'm looking to understand. Thanks for the patients tgray.
tgrayson said:
Yes, but it does time some amount of time for equilbrium to be established. If you cram the throttle forward, you'll see some increase in airspeed until the aircraft has time to pitch itself up and thus reestablish the trimmed airspeed. During that non-equilibrium situation, induced drag will go up as a quantity even if the AoA doesn't change.
This was in response to me holding all variables constant in a formula so I could better understand velocities impact on induced drag. When you look at these formula's, the process I used there is common place in the scientific world. Here, from a book tgray recommended I buy to better learn physics (University Physics):
"As a first step in dealing with a problem of nature it is often necessary to idealize the situation and to make simplifying assumptions concerning the process."
They later go on to discuss the importance of determining conditions of equilibrium as the first, most important step. However, that is for a later discussion. The point here is; we can set every letter in any formula constant to "idealize the situation" so we can better understand how manipulating each variable will effects the aircraft.
For example, you can find every formula where velocity is present. From there you can hold every variable constant in every formula except velocity. We can simply work with lift, having 2 variables in that formula that will readily change: lift coefficient (by changing AOA) and velocity (airspeed).
The rest: lift, wing area, and air density, will remain relatively constant and can be ignored. Since lift can always be simplified to equal weight, as a condition of equilibrium, we can rewrite the lift formula for AOA and velocity:
AOA = 1 / 0.5 * Weight
or
Weight = 1 / 0.5 * AOA
Remember, wing area and air density are constant, so why clutter the formula. Also, lift is constant so I set lift equal to '1' which is why there is a '1' in this formula. Leave them out and only work with things that change, it is simpler. Do you think the formula's we are using include all variables?
Finally, add weight to the first formula there and what happens to AOA? Performing similar processes on other formulai can give similar insights. Furthermore, it leaves no question as to the true answer to "what controls what." It isn't a debatable question in the scientific world.
