Calculating the Spring Constant for Bungee Jumping

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To calculate the spring constant for bungee jumping using Hooke's Law, the formula k = F/x can be applied, where F is the force (735N) and x is the change in length of the rope. Since the rope doubles in length when the force is applied, the displacement x equals the original length L. The relationship between gravitational potential energy (GPE) and elastic potential energy (EPE) can be expressed as mgh = 0.5 k x², with x still representing the length L. It's crucial to note that at the bottom of the jump, impulsive forces can be approximately twice the jumper's weight, which poses safety risks such as cord breakage. Understanding these dynamics is essential for safe bungee jumping practices.
wangking
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Hey, i need some help here
I'm trying to figure out the spring constant for bungee jump

Say, I'm 735N and the rope will apparently double in length when i jump off it.
I don't know the length of the rope thought.
but i do know it does have a spring constant.
How to find out is the spring constant using the Hooke's Law F=-KX

Please help :)
 
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oh, we are trying to find the N/m ratio
how could i do that
 
F= -k/x --> |k| = F/x you cannot find it without some information on its stretching. O I just read that it doubles in length.
 
The rope doubles in length when 735N is added, so does that mean that
k would be equal to 735N/the length of the rope.
k = 735 / L
 
yes. When it has doubled its length it has displaced L from it equilibrium position.
 
Thanks homie, so is the
(the change in F) proportional to (the change in x) = k
 
If i were using the f = k x equation, and then use
EPE formula = half k x squared
Which is also equal to GPE so could i say
mgh = half k x squared,
and is the x still L
 
wangking said:
If i were using the f = k x equation, and then use
EPE formula = half k x squared
Which is also equal to GPE so could i say
mgh = half k x squared,
and is the x still L

Yes, this is the point where all the kinetic energy was converted into elastic potential energy.
 
If this is more that just a thought exercise you should be aware that at the bottom of the jump impulsive forces equal to approximately twice your weight act on the bungee cord.

There have been fatalities due to cord breakages from this cause.

Anyone who has had dealings with rope rigging will be familiar with snatch forces.
 

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