Fluid mechanics conservation of momentum problem

AI Thread Summary
The discussion centers on a fluid mechanics problem involving fluid flow through a 180-degree bend in a pipe, specifically calculating the force on the flanges connecting the bend to straight pipe sections. The participant initially applies the Reynolds transport theorem and assumes equal velocities and forces on both sides of the bend, leading to confusion regarding energy loss. They clarify that the inlet pressure is greater than the outlet pressure, indicating energy loss in the system. Ultimately, they resolve the issue by recognizing that gravity accounts for the pressure difference due to the pipe's orientation. The final conclusion emphasizes the importance of considering gravitational effects in fluid dynamics problems.
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Homework Statement


The problem involves fluid flow through a 180 degree bend in a pipe. I am trying to find out the force applied on the flanges connecting the bend to straight pieces of pipe. I am given information on the diameter of the pipe, the length of the pipe, weight flow rate, and pressure at both the inlet and outlet of the 'U'

Homework Equations


The Reynolds transport theorem using linear momentum.

The Attempt at a Solution


I need help figuring out how to approach the problem. A control volume can be defined surrounding the 'U' and cutting through the pipe at the flanges. Since there is only one inlet, one outlet, and no change in volume, the mass flow rate in must be the same as out. The area of the pipe is the same on each side, so it follows that the velocity of the fluid must be the same on each side. But continuing with this logic, the force on each flange would be the same in equal and opposite directions using the Reynolds transport theorem. And I don't see how that can be plausible considering the type of information in the problem statement and it appears that some energy is lost in the pipe. So my question is, where is the flaw in my logic?
 
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Use the linear momentum equation to find the flange reaction force. Looks like everything is in the x-direction. Is P_inlet=P_outlet? Velocities and unit vectors are in the same so angle between them is 0.
 
RTW69 said:
Use the linear momentum equation to find the flange reaction force. Looks like everything is in the x-direction. Is P_inlet=P_outlet? Velocities and unit vectors are in the same so angle between them is 0.

I'm sorry, I failed to specify that, Pin > Pout which I guess is really the kicker here because that would imply energy is lost in the pipe somewhere, but I'm not sure how to work that in.
 
if anyone is curious, I got the problem resolved today. The mass flow rate and velocity are indeed the same, and gravity accounts for the difference in pressure. I didn't realize what the orientation of the pipe was.
 

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