Q) Water at 4°C enters a tank of diameter DT = 50.5 cm at a constantmass flow rate of min= 1.1 kg/s. An orifice at the bottom withdiameter D. = 10.5 mm allows water to drain. The frictionalDTlosses can be negligible. If the tank is initially empty, determinethe maximum height that the water will reach in the tank andderive the integration relation to calculate the time that is neededto reach this height.Do

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Q) Water at 4°C enters a tank of diameter DT = 50.5 cm at a constant mass flow rate of min 1.1 kg/s. An orifice at the bottom with diameter Do = 10.5 mm allows water to drain. The frictional losses can be negligible. If the tank is initially empty, determine the maximum height that the water will reach in the tank and DT derive the integration relation to calculate the time that is needed to reach this height. Do

Q) Water at 4°C enters a tank of diameter DT = 50.5 cm at a constant mass flow rate of min 1.1 kg/s. An orifice at the bottom with diameter Do = 10.5 mm allows water to drain. The frictional losses can be negligible. If the tank is initially empty, determine the maximum height that the water will reach in the tank and DT derive the integration relation to calculate the time that is needed to reach this height. Do

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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