Q1: Water is flowing from tank A to tank B as shown in the following figure. The flow is steady so that the water level in tank B does not change. Find h, in the figure. The density is constant. The flow is inviscid and irrotational. Hint: apply Bernoulli's equation between the free surface and the discharge for tanks A and B individually. Then, since the flow rate leaving tank A (and entering tank B) must equal the rate leaving tank B, these two Bernoulli's Equations can be substituted and solved for one unknown. 1 -10.0 cm d=0.01 m Tank A

Q1: Water is flowing from tank A to tank B as shown in the following figure. The flow is steady so that the water level in tank B does not change. Find h, in the figure. The density is constant. The flow is inviscid and irrotational. Hint: apply Bernoulli's equation between the free surface and the discharge for tanks A and B individually. Then, since the flow rate leaving tank A (and entering tank B) must equal the rate leaving tank B, these two Bernoulli's Equations can be substituted and solved for one unknown. 1 -10.0 cm d=0.01 m Tank A

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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Concept explainers

Fluid Kinematics

The branch of science that deals with objects which are either in motion or stationary are studied under the branch of classical mechanics. Fluid mechanics is a subcategory of classical mechanics that deals with the behavior of fluids at rest (fluid statics) or in motion (posing some velocity). In fluid kinematics, studies focus on the associated motion of fluid particles or groups of particles, and its associated parameters like displacements, velocity, and acceleration without concerning about the forces that caused the motion. All the laws of classical mechanics are applied in the study of fluid kinematics.

Question

Q1: Water is flowing from tank A to tank B as shown in the following figure. The flow is steady so that
the water level in tank B does not change. Find h, in the figure. The density is constant. The flow is
inviscid and irrotational.
Hint: apply Bernoulli's equation between the free surface and the discharge for tanks A and B
individually. Then, since the flow rate leaving tank A (and entering tank B) must equal the rate leaving
tank B, these two Bernoulli's Equations can be substituted and solved for one unknown.
1
10.0 cm
= 0.01 m
Tank A
士
Tank B
d 0.02 m
Figure 1. Q1

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