Heiwa,
Questions:
1. Do you, or do you not agree that, if dropped onto a solid surface, the peak force of a crushed and compacted mass of 3 stories of WTC would generate a higher AVERAGE force on the solid surface than the same pre-crushed structure?
2. Do you, or do you not agree that, if dropped onto a solid surface, the peak force of a crushed and compacted mass of 3 stories of WTC would generate a higher PEAK force on the solid surface than the same pre-crushed structure?
Answers:
1. So we have two structures; one, C1, is 3 floors high with columns between the floors and the other, C2, is same as C1 but floors and columns have been compressed into a thin layer of rubble. C1 and C2 is dropped on a solid surface.
...
[1B] When C2 contacts the solid surface, evidently the bottom rubble parts of C1 contacts the solid surface but there is no real impact. The remaining rubble parts then just pile up on the other rubble parts on ground. The force F2 that the rubble applies on the solid surface is small.
So it would appear F1>F2!
...
[2B] When C2 contacts the solid surface, i.e. the rubble parts pile up on the solid surface, F2 just gets slowly bigger; no impact, no deformation of C2, just equilibrium during complete process.
So again F1>F2.
I am only going to address your answers to 1B & 2B, here.
1B. "... the bottom rubble parts of C1 contacts the solid surface but there is no real impact."
2B. "... the rubble parts pile up on the solid surface, F2 just gets slowly bigger; no impact ..."
You seem to be saying that "if an object is below a certain size, it cannot exert a force on something else thru change in its own momentum." Am I interpreting you correctly??
PLEASE ANSWER THESE QUESTIONS.
They are at the very heart of this discussion.
1. Do you agree with the principle of conservation of momentum, as expressed by the Impulse-momentum equation:
∫[F dt] = ∆[m v] ?
2A. Do you agree that there is no place in that equation where it says " This equation applies only if m is greater than m
min" [some minimum value of mass] ?
2B. If you answered "no" to 2A, please explain how it is that gas molecules can propel a rocket or a jet, since that equation defines a rocket's performance.
("m
min" must be less than a single water vapor molecule for the space shuttle to get off the ground.)
2C. If you answered "no" to 2A, do you wish to change your mind in light of 2B?
3. Do you believe that the TOTAL momentum change of any mass (a monolithic block, a bunch of rubble, a gas, etc) will be precisely equal to the vector sum of the momentum change of all the constituent components of that mass, right down to the atomic, and subatomic, scales?
4. In the case of C1 (as built 3 stories) & C2 (same 3 stories, crushed down), the total masses are defied as equal. ASSUMING that both C1 & C2 were moving at the same speed prior to impact, do you agree that the TOTAL momentum change that results from the collision is exactly the same?
If you have answered "No" to any of the questions above, then you need to take a remedial course in physics and/or mechanics.
If you have answered "Yes" to {1, 2A, 3 & 4}, then you must agree that the total momentum change for the two cases is identically the same.
∆[m
Total v]
C1 = ∆[m
Total v]
C2
And that means that the TOTAL impluses applied to the ground in both collisions are the same:
∫[F dt]
C1 = ∫[F dt]
C2
On a plot of Force (y axis) versus time (x axis), the ∫[F dt] is equal to the area under the curve.
Now, two last questions...
Assume a "reasonable" force vs. time curve. I'd recommend a Weibull distribution, since it can be easily adjusted to represent both hard & soft collisions, while maintaining a constant Cumulative Distribution Function.
5. Do you understand that increasing the time duration of any collision, while maintaining the same total impulse, AUTOMATICALLY and INESCAPABLY decreases the average force of that collision?
6. Finally, do you understand that ALL of the above is true REGARDLESS of how any of the pieces in any mass in any collision are attached to any other piece(s)??
TomK
