In the arbitrary artery shown in the figure below assume that the radius of the blood vessel at (inlet 1) is 1.1 cm, at (inlet 2) 1.7 cm, at (outlet 1) 1.5cm, and at (outlet 2) 1.61 cm. Branches 1, 2, 3 and 4 make a 155°, a 30°, a 210°, and 300° with the horizontal direction, respectively. The velocity is 100, 85, and 112.1 cm/s at branches1, 3, and, 4 respectively. Assume steady flow at this particular

In the arbitrary artery shown in the figure below assume that the radius of the blood vessel at (inlet 1) is 1.1 cm, at (inlet 2) 1.7 cm, at (outlet 1) 1.5cm, and at (outlet 2) 1.61 cm. Branches 1, 2, 3 and 4 make a 155°, a 30°, a 210°, and 300° with the horizontal direction, respectively. The velocity is 100, 85, and 112.1 cm/s at branches1, 3, and, 4 respectively. Assume steady flow at this particular

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

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Applied Fluid Mechanics

A fluid is a substance that is continuously deformed by the application of shear stress. The rate of deformation of a fluid depends on its viscosity. The fluid tries to flow when it interacts with some other system.

Question

In the arbitrary artery shown in the figure below
assume that the radius of the blood vessel at (inlet
1) is 1.1 cm, at (inlet 2) 1.7 cm, at (outlet 1) 1.5cm,
and at (outlet 2) 1.61 cm. Branches 1, 2, 3 and 4
make a 155°, a 30°, a 210°, and 300° with the
horizontal direction, respectively. The velocity is 100,
85, and 112.1 cm/s at branches1, 3, and, 4
respectively. Assume steady flow at this particular
instant in time and that the volume of interest is non-
deformable.
Determine the volume flow rate at outlet 2?
Inlet 1
Branch 1
Branch 2
Inlet 2
Branch 3
Branch 4
Outlet 1
Outlet 2
a. 791.986 cm^3/s
b. 912.404 cm^3/s
c. 0.000 cm^3/s
d. None of the given answers is true
e. 112.100 cm^3/s
f. 124.853 cm^3/s
Clear my choice

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