A plug in the bottom of a pressurized tank is conical in shape, as shown in the figure below. The air gage pressure is 40 kPa and the liquid in the tank has a specific weight of 27 kN/m³. Determine the (a) magnitude, (b) direction, and (c) line of action of the force exerted on the curved surface of the cone within the tank due to the 40-kPa pressure and the liquid. Assume h = 2.9 m. T 1 m Air Liquid 60⁰ 40 kPa

A plug in the bottom of a pressurized tank is conical in shape, as shown in the figure below. The air gage pressure is 40 kPa and the liquid in the tank has a specific weight of 27 kN/m³. Determine the (a) magnitude, (b) direction, and (c) line of action of the force exerted on the curved surface of the cone within the tank due to the 40-kPa pressure and the liquid. Assume h = 2.9 m. T 1 m Air Liquid 60⁰ 40 kPa

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Description: A plug in the bottom of a pressurized tank is conical in shape, as shown in the figure below. The air gage pressure is 40 kPa and theliquid in the tank has a specific weight of 27 kN/m³. Determine the (a) magnitude, (b) direction, and (c) line of ac

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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Question

A plug in the bottom of a pressurized tank is conical in shape, as shown in the figure below. The air gage pressure is 40 kPa and the
liquid in the tank has a specific weight of 27 kN/m³. Determine the (a) magnitude, (b) direction, and (c) line of action of the force
exerted on the curved surface of the cone within the tank due to the 40-kPa pressure and the liquid.
Assume h = 2.9 m.
(a) Fc=
(b)
(c)
kN
1 m
Air
Liquid
60°
40 kPa

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