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Incompressible fluid flows with a velocity of 10 m/sec through a pipe of diameter of 2.1 m and cross-sectional area of 3.464 m^2.At the end of the pipe, there is a well contoured circular body that makes an obstacle for the flow and lets the flow diverge into two paths each with the velocity of V_2. Determine the V_2 if the annular gap is 0.1 m? 0.1 m: V2 V = 10 m/sec %3D V2 none O 55.13 m/sec O 70.15 m/sec O 43.08 m/sec 89.12 m/sec

Incompressible fluid flows with a velocity of 10 m/sec through a pipe of diameter of 2.1 m and cross-sectional area of 3.464 m^2.At the end of the pipe, there is a well contoured circular body that makes an obstacle for the flow and lets the flow diverge into two paths each with the velocity of V_2. Determine the V_2 if the annular gap is 0.1 m? 0.1 m: V2 V = 10 m/sec %3D V2 none O 55.13 m/sec O 70.15 m/sec O 43.08 m/sec 89.12 m/sec

Elements Of Electromagnetics
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
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Incompressible fluid flows with a velocity of 10 m/sec through a pipe of diameter of 2.1 m and cross-sectional area of 3.464 m^2. At the end of the pipe, there is a well contoured circular body that makes an obstacle for the flow and lets the flow diverge into two paths each with the velocity of V_2. Determine the V_2 if the annular gap is 0.1 m? 0.1 m: V2 V = 10 m/sec V2 none O 55.13 m/sec 70.15 m/sec 43.08 m/sec 89.12 m/sec
Transcribed Image Text:Incompressible fluid flows with a velocity of 10 m/sec through a pipe of diameter of 2.1 m and cross-sectional area of 3.464 m^2. At the end of the pipe, there is a well contoured circular body that makes an obstacle for the flow and lets the flow diverge into two paths each with the velocity of V_2. Determine the V_2 if the annular gap is 0.1 m? 0.1 m: V2 V = 10 m/sec V2 none O 55.13 m/sec 70.15 m/sec 43.08 m/sec 89.12 m/sec
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