A pressurized tank of water has a 10-cm-diameter orifice at the bottom, where water discharges to the atmosphere. The water level is 2.5 m above the outlet. The tank air pressure above the water level is 250 kPa (absolute) while the atmospheric pressure is 100 kPa. Neglecting frictional effects, determine the initial discharge rate of water from the tank.

Question

Physics

Cyrus Swanson

14 June, 15:40

A pressurized tank of water has a 10-cm-diameter orifice at the bottom, where water discharges to the atmosphere. The water level is 2.5 m above the outlet. The tank air pressure above the water level is 250 kPa (absolute) while the atmospheric pressure is 100 kPa. Neglecting frictional effects, determine the initial discharge rate of water from the tank.

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Answers (1)

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Luca Nolan · Answer 1

Answer: 0.15m³/s

Explanation:

To solve this question, we are going to have to apply Bernoulli's equation.

[ (P1/ρg) + (V1²/2g) + Z1] = [ (P2/ρg) + (V2²/2g) + Z2]

V1 and V2 represent the velocities of the fluid at levels 1 and 2 respectively.

Note that, the diameter of the tank is very much larger than that of the nozzle, as such, it can be neglected. V1 = 0

Z2 also is 0

Substituting in the equation, we have

[ (250*10^3/1000g) + (0/2g) + 2.5] = [ (100*10^3/1000g) + (V2²/2g) + 0]

250/g + 2.5 = 100/g + V2²/2g

250 + 2.5g = 100 + V2²/2

Using g = 9.8

250 + 2.5*9.8 = 100 + V2²/2

250 + 24.5 = 100 + V2²/2

274.5 - 100 = V2²/2

174.5 = V2²/2

349 = V2²

V2 = 18.68m/s

V = Q/A

A = πd²/4

A = [π * (10*10^-2) ²]/4

A = 7.85*10^-3m²

Q = VA

Q = 18.68 * 7.85*10^-3

Q = 0.15m³/s