6. Water flows from a nozzle with a speed of V= 10 m/s and is collected in a container that moves toward the nozzle with a speed of Vev= 4 m/s as shown in the figure below. The moving control surface consists of the inner surface of the container. The system consists of the water in the container at time t=0 and the water between the nozzle and the tank in the constant diameter stream at -0. At time -0.1 s what volume of the system remains outside of the control volume? How much water has entered the control volume during this time period? Repeat the problem for 1-0.3 s. Stream diameter = 0.1 m Nozzle V = 10 m/s V = 4 m/s -3 m Container at r = 0 Stream at r = 0 Moving control volume

6. Water flows from a nozzle with a speed of V= 10 m/s and is collected in a container that moves toward the nozzle with a speed of Vev= 4 m/s as shown in the figure below. The moving control surface consists of the inner surface of the container. The system consists of the water in the container at time t=0 and the water between the nozzle and the tank in the constant diameter stream at -0. At time -0.1 s what volume of the system remains outside of the control volume? How much water has entered the control volume during this time period? Repeat the problem for 1-0.3 s. Stream diameter = 0.1 m Nozzle V = 10 m/s V = 4 m/s -3 m Container at r = 0 Stream at r = 0 Moving control volume

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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Fluid Dynamics

The study of the flow of gases and liquids, usually in and around solid surfaces, is known as fluid dynamics in physics and engineering. Fluid dynamics, for example, can be used to evaluate the movement of air through an airplane wing or the surface of a vehicle. It can also be used in ship design to increase the speed at which ships pass through water.

Question

6. Water flows from a nozzle with a speed of V= 10 m/s and is collected in a container that
moves toward the nozzle with a speed of Vcv= 4 m/s as shown in the figure below. The
moving control surface consists of the inner surface of the container. The system consists
of the water in the container at time =0 and the water between the nozzle and the tank in
the constant diameter stream at -0. At time 0.1 s what volume of the system remains
outside of the control volume? How much water has entered the control volume during this
time period? Repeat the problem for t=0.3 s.
Stream diameter = 0.1 m
Nozzle
V = 10 m/s
V = 4 m/s
3 m
S
B
Container
at r = 0
Stream
at r = 0
Moving
control
volume

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Step 1: To determine The volume of the system and the quantity of the water has entered the control volume.

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