2. Consider the following piping system, which has a mass flowrate of 12 kg/s:Liquid level4.1 mOpen to AtmosphereStorage TankDisuction=4.026-inchPump0.6 me suction 65J/kge discharge 555 J/kgDischarge 3.068-inch1.2 mDetermine the velocity in the discharge side.e. Determine the velocity on the suction side.f.Determine the pressure at Point 3 (the inlet to the pump).Pressure in Vessel = 3.4 bar = 3.4×105 Pa5.8 mg. Determine the work required for the pump (which is 65% efficient).h. Determine the pressure at Point 4 (the discharge of the pump).Liquid level2.9 mProcess Vessel

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2. Consider the following piping system, which has a mass flowrate of 12 kg/s: Liquid level 4.1 m Open to Atmosphere Storage Tank Diction=4.026-inch 0.6m Pump ection 651/kg echarge555 J/kg d. Determine the velocity in the discharge side. Determine the velocity on the suction side. e. Discharge 3.068-inch 12m Pressure in Vessel = 3.4 bar = 3.4x10³ Pa 5.8 m f. Determine the pressure at Point 3 (the inlet to the pump). g. Determine the work required for the pump (which is 65% efficient). Determine the pressure at Point 4 (the discharge of the pump). h. Liquid level 2.9m Process Vessel

2. Consider the following piping system, which has a mass flowrate of 12 kg/s: Liquid level 4.1 m Open to Atmosphere Storage Tank Diction=4.026-inch 0.6m Pump ection 651/kg echarge555 J/kg d. Determine the velocity in the discharge side. Determine the velocity on the suction side. e. Discharge 3.068-inch 12m Pressure in Vessel = 3.4 bar = 3.4x10³ Pa 5.8 m f. Determine the pressure at Point 3 (the inlet to the pump). g. Determine the work required for the pump (which is 65% efficient). Determine the pressure at Point 4 (the discharge of the pump). h. Liquid level 2.9m Process Vessel

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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