Average force exerted on the coin by the soil

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Homework Help Overview

The problem involves a coin of mass 10g that is dropped from a height and penetrates 5cm into the soil after falling for 10 seconds. The objective is to calculate the average force exerted on the coin by the soil.

Discussion Character

  • Exploratory, Assumption checking, Mathematical reasoning

Approaches and Questions Raised

  • Participants discuss using different equations of motion, such as F=ma and F= m(v-u)/t, to approach the problem. There is consideration of the average force and the need to determine initial and final velocities during the penetration phase. Some participants suggest calculating the free fall velocity before addressing the soil penetration.

Discussion Status

Multiple approaches have been proposed, including using equations of motion and energy considerations. Participants have provided hints and guidance on how to relate the variables involved, although there is no explicit consensus on a single method. The discussion reflects a productive exploration of the problem.

Contextual Notes

Participants note the lack of information regarding the time it takes for the coin to come to rest in the soil, which complicates the application of certain equations. There is also a recognition of the forces acting on the coin during its motion.

terainfizik
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Homework Statement


A coin of mass 10g is dropped from the top of a tall building. If after failing for 10s , it falls intosoil and penetrates to a depth of 5cm, calculate

(Q) the average force exerted on the coin by the soil.


Homework Equations





The Attempt at a Solution


Should I use F=ma ? or use F= m( v-u ) / t ? to get the solution ?
Give me hint !
 
Last edited:
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terainfizik said:

Homework Statement


A coin of mass 10g is dropped from the top of a tall building. If after failing for 10s , it falls intosoil and penetrates to a depth of 5cm, calculate

(Q) the average force exerted on the coin by the soil.


Homework Equations





The Attempt at a Solution


Should I use F=ma ? or use F= m( v-u ) / t ? to get the solution ?
Give me hint !


Given that they ask for the average force and that anyway you don't know anything else but the begin and end velocities (in the soil), it is the second of your formulas that you should use.
 
vanesch said:
Given that they ask for the average force and that anyway you don't know anything else but the begin and end velocities (in the soil), it is the second of your formulas that you should use.

The end of the velocities ( in the soil ) should be zero ? Is that mean F= m(v-u)/t , where m= weight of coin , v= ending speed of dropping into the soil ? and u=initial speed of dropping from the building ( zero also ? )
Guide me please.
 
terainfizik said:
The end of the velocities ( in the soil ) should be zero ? Is that mean F= m(v-u)/t , where m= weight of coin , v= ending speed of dropping into the soil ? and u=initial speed of dropping from the building ( zero also ? )
Guide me please.

The end velocity in the soil is zero of course, because when it has penetrated its 5 cm, I guess it is not moving anymore. The begin velocity in the soil is however, the velocity the object obtained in free fall.

So you should first solve the free fall problem to get this "final" velocity of the fall (which is the initial velocity of the next stage of motion: the penetration in the soil).
 
terainfizik said:
Should I use F=ma ? or use F= m( v-u ) / t ? to get the solution ?
The first equation would work just fine, once you calculate the acceleration. Since you don't have the time that it takes the coin to come to rest, that second equation won't help (unless you figure out the time first!).

Another approach is to consider the work done on the coin by the soil. That's the approach I would recommend.
 
Doc Al said:
The first equation would work just fine, once you calculate the acceleration. Since you don't have the time that it takes the coin to come to rest, that second equation won't help (unless you figure out the time first!).

Another approach is to consider the work done on the coin by the soil. That's the approach I would recommend.

That's also an idea.

The way I wanted to propose this was:
you calculate the average force by having "start velocity minus final velocity"/t, but with t as of yet unknown.

That average force gives you (containing the unknown t) the average acceleration, and then you use s = a(t)/2 t^2 = 5cm to solve for the unknown t.
 
It's all good--any of these three approaches will work just fine, if you are careful. So pick one and get busy! :smile:

Note: Once the coin hits the soil there are two forces acting on it.
 
Doc Al said:
Another approach is to consider the work done on the coin by the soil. That's the approach I would recommend.

I think Doc is right on this one. I can't seem to solve this problem using momentum.
0 = (m)(v) + (F1)(t1) - (F2)(t1); t1 is the impact time, F1 is gravity, F2 is soil
0 = (m)(g)(t2) + (m)(g)(t1) + (F2)(t1); t2 is fall time (10s)
0 = (0.010)(9.8)(10) + (0.010)(9.8)(t1) + (F2)(t1)
F2 is the answer to the problem and t1 is unknown
t1 is derived from:
d = (1/2)(a)(t^2); d is 5cm, a is unknown
a is derived from:
(v1 - v2)/t; where t is the same t as the above equation

It's like one would need to substitute a bunch of things over and over again to get the right answer.

Energy is very straight forward
0 = (1/2)(m)(v^2) + (m)(g)(d) - (F)(d); d is the soil distance of 5cm, F is soil
0 = (1/2)(m)[(g)(t)]^2 + (m)(g)(d) + (F)(d)
0 = (1/2)(0.010)[(9.8)(10)]^2 + (0.010)(9.8)(0.05) - (F)(0.05)
Solve for F
 
Thank you for giving me these hints . I have worked it out . You guys shows clear statements working .
 
  • #10
ShawnD said:
I think Doc is right on this one. I can't seem to solve this problem using momentum.
0 = (m)(v) + (F1)(t1) - (F2)(t1); t1 is the impact time, F1 is gravity, F2 is soil
0 = (m)(g)(t2) + (m)(g)(t1) + (F2)(t1); t2 is fall time (10s)
0 = (0.010)(9.8)(10) + (0.010)(9.8)(t1) + (F2)(t1)
F2 is the answer to the problem and t1 is unknown
t1 is derived from:
d = (1/2)(a)(t^2); d is 5cm, a is unknown
a is derived from:
(v1 - v2)/t; where t is the same t as the above equation

Yes, but this is easy:

v2 = 0
a = v1/t, hence d = 1/2 v1/t (t^2) = 1/2 v1 t from which follows t = 2 d / v1
F = m v1/t = m v1^2/(2 d)

But if you want to take into account the extra m.g acting, then we have to add this: F' = F + m.g

Now, it is true that the energetic approach is clearly the most straightforward one...
 

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