Solving a problem using energy and conservative forces concepts

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Hernaner28
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Homework Statement


attachment.php?attachmentid=46109&stc=1&d=1334149747.jpg


It asks me to work out the work done by force P and it tells me that the ball m has a CONSTANT speed during its displacement.

That diagram is taken from a book which has already solved the exercise without using the concepts of energy and conservative forces. It used a complicated way of integrating to determinate the work of P. So since all the forces are conservative this could be solved easily, couldn't it?

Homework Equations


The Attempt at a Solution


If the speed is constatnt then the ΔK is 0. And we know that ΔK=W so W=0. And we also know that the potential energy ΔU=-W so ΔU=0. But after that I end up writing the integral of P when I don't want to do that. Thanks!
 
on Phys.org
delta U=-W, are you sure?
 
darkxponent said:
delta U=-W, are you sure?

Yes, that's a definition. The change of potential energy is ΔU=-W - what's wrong with it?
 
well this applies only when the object is acted apon by conservative forces only. That is delta U +delta K =0.
 
Yes I know but are you saying that in this system there's a force which is non-conservative? There's the tension, the weight and force P... oh, force P? hmm...
 
You can solve it withput using integral. Just concentrate on work done on the particle by the individual forces
 
OK I'll write that down for each force, but is this a conservative system, right? Now you've said that I am in doubt if P is or not conservative.
Thanks
 
p os not conservagive force. Work done by p depends on path taken. You can see from the figure. Only those forces are conservative which do not change the total energy of particle. P does changes the kinetic energy of body and hence it is non-conservagive
 
Hmmm.. I see. So there's no need to use energy concepts either.

[tex]\begin{array}{l}<br /> {W_T} = 0\\<br /> {W_T} = {W_P} + {W_W} + {W_{tension}}\\<br /> 0 = {W_P} - mgh\\<br /> {W_P} = mgh<br /> \end{array}[/tex]

Is this right?

Thanks!