Calculate the height of the second reservoir (H2), and the pressure head, velocity head and elevation head at point 3 (mid‐point of the pipe).SN=21 The figure shows two reservoirs connected by a pipe. The discharge rate in the pipe is known tobe equal to SN/100 (m/s) (where SN is the sum of your student number).Calculate the height of the second reservoir (H2), and the pressure head, velocity head andelevation head at point 3 (mid-point of the pipe).Hi = 300 mH2datumSN/1000%3DL = 100 x SN (m)D = 0.3 m

The internal energy of a fluid due to pressure exerted on its container is known as pressure head…

The figure shows two reservoirs connected by a pipe. The discharge rate in the pipe is known to be equal to SN/100 (m³/s) (where SN is the sum of your student number). Calculate the height of the second reservoir (H2), and the pressure head, velocity head and elevation head at point 3 (mid-point of the pipe). Hi = 300 m H2 datum A = SN/1000 L = 100 x SN (m) D = 0.3 m %3D

The figure shows two reservoirs connected by a pipe. The discharge rate in the pipe is known to be equal to SN/100 (m³/s) (where SN is the sum of your student number). Calculate the height of the second reservoir (H2), and the pressure head, velocity head and elevation head at point 3 (mid-point of the pipe). Hi = 300 m H2 datum A = SN/1000 L = 100 x SN (m) D = 0.3 m %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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