When a jet of liquid escapes through the orifice of a reservoir driven only by the force of gravity, like the one in figure 3, the velocity distribution at the outlet can be approximated by u = [2g (hz)] ^ (1 // 2) diffuse h is the depth at which the center of the jet is located. Near the hole, the jet is horizontal two-dimensional and of thickness 2L, as shown in the figure. Obtain the general expression to calculate the total flow Q that leaves through the orifice and simplify the result in the limit L << h
When a jet of liquid escapes through the orifice of a reservoir driven only by the force of gravity, like the one in figure 3, the velocity distribution at the outlet can be approximated by u = [2g (hz)] ^ (1 // 2) diffuse h is the depth at which the center of the jet is located. Near the hole, the jet is horizontal two-dimensional and of thickness 2L, as shown in the figure. Obtain the general expression to calculate the total flow Q that leaves through the orifice and simplify the result in the limit L << h
International Edition---engineering Mechanics: Statics, 4th Edition
4th Edition
ISBN:9781305501607
Author:Andrew Pytel And Jaan Kiusalaas
Publisher:Andrew Pytel And Jaan Kiusalaas
Chapter9: Moments And Products Of Inertia Of Areas
Section: Chapter Questions
Problem 9.46P
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When a jet of liquid escapes through the orifice of a reservoir driven only by the force of gravity, like the one in figure 3, the velocity distribution at the outlet can be approximated by u = [2g (hz)] ^ (1 // 2) diffuse h is the depth at which the center of the jet is located. Near the hole, the jet is horizontal two-dimensional and of thickness 2L, as shown in the figure. Obtain the general expression to calculate the total flow Q that leaves through the orifice and simplify the result in the limit L << h
Transcribed Image Text:h
z = +L
z =-L
Figura 3
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