Viscous liquid between two circular discs.

AI Thread Summary
The discussion revolves around solving a homework problem involving a viscous liquid between two circular discs. Participants explore how to derive the velocity profile and pressure drop, emphasizing the relationship between pressure gradient, velocity, and viscosity. One user seeks clarification on whether they can calculate the supported weight without completing part b, while others suggest integrating shear stress over the disc area to determine the force exerted by the fluid. The conversation highlights the importance of understanding fluid dynamics concepts, particularly regarding pressure and shear stress in this context. Ultimately, the integration of pressure and shear stress is necessary for accurate calculations.
guitar24
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Homework Statement



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That is the problem statement. I can't seem to get started on part a.

For part b I can find the velocity profile of the viscous liquid form the equations of motion relating velocity and change in pressure, find the avg velocity, and find the change in pressure from that.

Any hints ??

Thank you!
 
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This is a creeping motion fluids problem like something you experience in a bearing. In this case the pressure gradient in the radial direction equals the Laplacian of the radial velocity times the viscosity. You indicate you can solve for the pressure and velocity profiles so you already are aware of the equation involved. If you integrate the pressure over the area of the disk, that should give you the weight that can be supported.
 
Thank you for your reply.

So there is no way I can find the weight that can be supported without finding the pressure drop and doing part b first?

I was thinking about integrating the stress Tau(rz) over the area of the top plate to find the force of the fluid on the solid. Would this be correct?
 
Thank you, I understand it a little better now and the velocity profile I got is the same. But that reference still doesn't mention anything about a force acting on the disc. Regarding to what I said earlier, can I integrate Tau(rz) over the area of the disc to find the force on the plate by the liquid?
 
How do you define Tau(rz). Is it shear stress?
 
Yes but nvm that isn't correct. I am sure I have to integrate the change in pressure + Tau (zz) (normal stress, but this is 0 for any fluid solid interface) over the disc area. I see what you were saying in your initial comment and you were right. Thank you!
 

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