Flow from a tank.For the tank shown in figure below, compute the velocity of flow from the nozzle and thevolume flow rate for a range of depth from 3.0 m to 0.5 m in steps of 0.5 m. The diameterof the jet at the nozzle is 50 mm.INIHUse Bernoulli's equation between points 1 and 2.(s/w) ?A (w) y yadə3.02.5P,ly + Z, + V,?/2g = P2/ y + Z, + V,2/2g2.0Assume the datum to pass horizontally throughpoint 2. Therefore,1.5P,ly + Z, + V,4/2g = P y + Z, + V,/2g0.52.Also, note that by using Bernoulli's equation, thefollowing Torricelli's theorem is proved.V2 = /2gh%3D4.

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Flow from a tank. For the tank shown in figure below, compute the velocity of flow from the nozzle and the volume flow rate for a range of depth from 3.0 m to 0.5 m in steps of 0.5 m. The diameter of the jet at the nozzle is 50 mm. Depth h (m) INIH Use Bernoulli's equation between points 1 and 2. 3.0 2.5 P,ly + Z, + V,²/2g = P2/ y + Z2 + V½2/2g %3D Assume the datum to pass horizontally through point 2. Therefore, 1.5 1.0 %3D 0.5 Bzz?A + Z + 1 řd = BZz'A + 'z + N'd Also, note that by using Bernoulli's equation, the following Torricelli's theorem is proved. V2 = 2gh %3D

Flow from a tank. For the tank shown in figure below, compute the velocity of flow from the nozzle and the volume flow rate for a range of depth from 3.0 m to 0.5 m in steps of 0.5 m. The diameter of the jet at the nozzle is 50 mm. Depth h (m) INIH Use Bernoulli's equation between points 1 and 2. 3.0 2.5 P,ly + Z, + V,²/2g = P2/ y + Z2 + V½2/2g %3D Assume the datum to pass horizontally through point 2. Therefore, 1.5 1.0 %3D 0.5 Bzz?A + Z + 1 řd = BZz'A + 'z + N'd Also, note that by using Bernoulli's equation, the following Torricelli's theorem is proved. V2 = 2gh %3D

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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