Integral Form of the Momentum Equation - Reducer Question

AI Thread Summary
The discussion revolves around calculating the total force needed to support a reducer with a specified internal volume and mass while pumping oil. The reducer connects two pipelines of different diameters, and the problem involves applying the principle of conservation of mass and momentum to find the force. Participants clarify that the reducer's volume refers to its internal space, typically shaped as a tapered fitting. One user shares their approach, focusing on the change in momentum of the oil to determine the force exerted on the reducer. The final answer provided is F = −3.4xˆ + 1.66yˆ kN, although there are concerns about the methods used to arrive at this solution.
MrWinesy
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Homework Statement



The internal volume of the reducer is 0.2m^3 and its mass is 25 kg. The fluid being pumped is oil (specific gravity of 0.72).
Evaluate the total force that must be provided to support the reducer.

d1 = 0.4m
d2 = 0.2m
u1 = 3m/s
p1 = 58.7 kPa
p2 = 49kPa (gauge)


Homework Equations




Qin=Qout

mdot=ρ*A*u

A=(∏*d^2)/4


The Attempt at a Solution



Tried. Failed. Help.
 
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the answer is apparently F = −3.4xˆ +1.66yˆ kN but I am in need of the working please.
 
What does a 'reducer" do?
 
A reducer couples a larger diameter pipeline to a smaller diameter pipeline, hence the two diameters specified in the OP.
 
SteamKing said:
A reducer couples a larger diameter pipeline to a smaller diameter pipeline, hence the two diameters specified in the OP.

Thanks SK!

But - what is meant by its volume? Is it a tapered section of pipe going from the larger to the smaller diameter?
 
It can be. More often it is a cast fitting, either flanged or suited to welding, with a curved transition between the larger and smaller diameters, so that the overall length of the fitting is kept small. The volume, I believe, is just what it implies, the volume of the internal space of the reducer.
 
SteamKing said:
It can be. More often it is a cast fitting, either flanged or suited to welding, with a curved transition between the larger and smaller diameters, so that the overall length of the fitting is kept small. The volume, I believe, is just what it implies, the volume of the internal space of the reducer.

yea this is right. it can be basically thought of as a converging pipe and the question is based on the internal volume as this helpful fella said. and the mass is the mass of the actual reducer.

i have obtained the answer but not confident on my methods. anyone else had any luck?
 
Thanks to my friend Chestermiller from a similar previous problem, the approach here is to consider the change in momentum per unit time of the oil and equate that to the (longitudinal) force exerted on the reducer.
 

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