Axial velocity for fully developed flow in a pipe

AI Thread Summary
The axial velocity for fully developed laminar flow in a pipe is expressed as vx=2*u*(1-r^2/ro^2), derived from the Navier-Stokes equations. This equation indicates that the velocity varies with the radius, reaching zero at the pipe wall. The discussion suggests researching Hagen-Poiseuille flows, which are relevant for pressure-driven pipe flow. Additionally, there are analytic solutions for various duct geometries, with a recommendation for the book "Viscous Flow" by White for further reference. The search for free resources on this topic yielded no results.
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Homework Statement


The book I am reading just randomly states that the axial velocity for a fully developed laminar flow in a pipe is vx=2*u*(1-r^2/ro^2). i am not sure where this comes from. does come from the navier stokes equations?

also, is there a book that lists other types of axial velocities for flows in a duct with different width and height ratios?

Homework Equations


navier stokes?

The Attempt at a Solution

 
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I think you would be wise to do a google search Hagen-Poisoulle flows. Flows like these are pressure driven, essentially reducing to pipe flow.

That equation looks like the velocity at a certain radius, given the maximum velocity u. That is, when the radius is ro, you get 1-(ro/ro) or 0 -> no flow on the pipe wall.

Also, yes there are analytic solutions for different geometries. I have "Viscous Flow Flow" by White which I believe lists solutions for different geometries.
 
Thanks, ill look up some stuff on Hagen-Poisoulle flows.

Unfortunately i couldn't find any free pdfs of that book from google :(
 
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