Calculating Impact Speed: 100 Meter Fall with and without Air Resistance

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SUMMARY

The impact speed of a body falling from 100 meters without air resistance is calculated to be 99 miles per hour (44 meters per second). When considering air resistance, the drag force must be included in the calculations, which can be modeled using the equation f = -cv², where c is the drag coefficient. For a person weighing 68 kg in a pencil position, the estimated air resistance ranges from 2 N to 18 N, leading to a maximum impact speed of approximately 44.0 m/s. In a spread eagle position, the maximum speed is estimated to be no less than 40 m/s, indicating that body position significantly affects the final speed.

PREREQUISITES
  • Understanding of basic physics concepts, particularly Newton's laws of motion
  • Familiarity with drag force and its calculation in fluid dynamics
  • Knowledge of calculus for more precise estimations of motion
  • Ability to calculate cross-sectional area and its impact on air resistance
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  • Learn about drag coefficients and how to calculate them for different shapes
  • Study the principles of fluid dynamics, focusing on viscous and quadratic drag
  • Explore numerical methods for solving differential equations related to falling objects
  • Investigate the effects of body position on terminal velocity in free fall
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This discussion is beneficial for physics students, educators, and anyone interested in understanding the dynamics of free fall and the effects of air resistance on falling objects.

honeydukes
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Hello!

I am doing a project with a few other people. It is sort of a mock trial. None of us are physics wiz's. We need to know the speed a body would impact the ground from a fall of 100 meters. We figured out that it would be 99 miles per hour/44 meters per second WITHOUT air resistance. But we need to know what it would be WITH air resistance. The person is about 5'10 and weighs about 150lbs/68kg. Your help would be much appreciated! Thanks!
 
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honeydukes said:
Hello!

I am doing a project with a few other people. It is sort of a mock trial. None of us are physics wiz's. We need to know the speed a body would impact the ground from a fall of 100 meters. We figured out that it would be 99 miles per hour/44 meters per second WITHOUT air resistance. But we need to know what it would be WITH air resistance. The person is about 5'10 and weighs about 150lbs/68kg. Your help would be much appreciated! Thanks!

You'll need to add a drag term to your force balance equation. IIRC from my undergraduate mechanics, there can be a viscous drag, which is proportional to the velocity, or a quadratic drag, which is proportional to the square of the velocity. I think that above a few meters per second, the quadratic drag term is used in a typical approximate calculation. So, the drag force should be f = -cv^2. You can approximate the drag coefficient with something like c= \frac{1}{2} C_D S\rho. C_D is a dimensionless term related to the geometry of the falling object, S is the cross-sectional area of the falling obect and \rho is the density of air.
 
As suggested by Geoff's post, the cross-sectional area is important here. This is the surface area that "meets" the oncoming wind and it will be very different for the position that the person takes. In the "pencil" position (straight up and down), a 68 kg person is not going to have experienced much significant air resistance (this is a 4.5 second fall, you know). My estimate has a maximum of 18 N and a minimum of 2 N of air resistance, so let's say 10 N of air resistance. This would make the acceleration atthe bottom about 9.6 m/s^2. The average acceleration would then be 9.7 m/s^2 (this is dirty estimation, please understand) so the maximum speed would be about 44.0 m/s instead of 44.3 m/s.

You'd really need to bring out calculus to do a better estimation if the person falls in a spread eagle position.
 
A quick estimate of a spread eagle fall still gets a maximum speed of no LESS than 40 m/s. This was found by overestimating just about every factor. I haven't worked in fluid dynamics for a while, so if anyone has a smaller maximum speed, I'd like to know what I missed.
 
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Thread 'Does acceleration affect impact energy vs constant velocity?'

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