Pump transfers water from tank A to tank D as shown in the figure in question A differential pressure gauge is installed on the pump data: - Suction pipe length: 5 m Supply pipe length: 20 m - Pipe diameter (uniform): 100 mm Longitudinal coefficient of friction: 0.03 -Differential pressure gauge shows:] 2.5 [bar The angles have a short radius - The kinematic viscosity of water: vw = 10-6 m2 / sec A. Calculate the pump capacity in units [. [Liter / sec B. Calculate the pressures p1 and p2 at the inlet and outlet of the pump in units [. [Bar C. Calculate the roughness of the piping in mm units.

Pump transfers water from tank A to tank D as shown in the figure in question A differential pressure gauge is installed on the pump data: - Suction pipe length: 5 m Supply pipe length: 20 m - Pipe diameter (uniform): 100 mm Longitudinal coefficient of friction: 0.03 -Differential pressure gauge shows:] 2.5 [bar The angles have a short radius - The kinematic viscosity of water: vw = 10-6 m2 / sec A. Calculate the pump capacity in units [. [Liter / sec B. Calculate the pressures p1 and p2 at the inlet and outlet of the pump in units [. [Bar C. Calculate the roughness of the piping in mm units.

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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Formül; Tmaks T TL Gyab³G' }z5için c = c2 -(1 – 0,630b/a) M-(Izy .z= ly.y) + My(1.z – Izy .y) 4.ly – Izy Oz + dy, tan20, = Му vQ T- It 10 cm Og + dy x- Gy cos20 +Tysin20 , Jort= 2 2 2 600 N X Ly = *% sin20 + Eycos20 , omarsmin = 9s + Oy + , + r 14 cm B Tmaks + rảy Vertical load is applied to point B of a 10 mm radius cylindrical bar as shown in the figure. Calculate the shear stress occurring at point A. О 56,03 МPа O 53,48 MPa 49,78 MPa O 78,82 MPa 43.37 MPa
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