How is the integral expression for contact time derived?

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rohanc
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Don't know if this is the correct place to post this, this is not an assignment question, but I am terribly stuck with this.

While going through the derivation of contact time for a hertzian contact as given in problem 3 at the following link http://s17.postimg.org/t1kq6mlxr/Capture.png , I am not able to understand how the integral form for contact time has come into picture. I understand that the twice the integral of displacement over velocity from x=0 to x=x0 gives the total contact time. But can anyone please explain the in-between steps to get the same (how did the 1/sqrt(1-(x/x0)^5/2) come about? I understand that this is a very trivial problem but it will be a great help to understand the steps.
 
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rohanc said:
Don't know if this is the correct place to post this, this is not an assignment question, but I am terribly stuck with this.

While going through the derivation of contact time for a hertzian contact as given in problem 3 at the following link http://s17.postimg.org/t1kq6mlxr/Capture.png , I am not able to understand how the integral form for contact time has come into picture. I understand that the twice the integral of displacement over velocity from x=0 to x=x0 gives the total contact time. But can anyone please explain the in-between steps to get the same (how did the 1/sqrt(1-(x/x0)^5/2) come about? I understand that this is a very trivial problem but it will be a great help to understand the steps.

rohanc said:
Don't know if this is the correct place to post this, this is not an assignment question, but I am terribly stuck with this.

While going through the derivation of contact time for a hertzian contact as given in problem 3 at the following link http://s17.postimg.org/t1kq6mlxr/Capture.png , I am not able to understand how the integral form for contact time has come into picture. I understand that the twice the integral of displacement over velocity from x=0 to x=x0 gives the total contact time. But can anyone please explain the in-between steps to get the same (how did the 1/sqrt(1-(x/x0)^5/2) come about? I understand that this is a very trivial problem but it will be a great help to understand the steps.

You have an equation of the form
[tex]\left( \frac{dx}{dt}\right)^2 + c\, x^{5/2} = K[/tex]
so
[tex]\frac{dx}{dt} = \sqrt{K -c\, x^{5/2}}[/tex]
(assuming ##dx >0##), hence
[tex]dt = \frac{dx}{\sqrt{K -c\, x^{5/2}}}[/tex]