EBK THERMODYNAMICS: AN ENGINEERING APPR
EBK THERMODYNAMICS: AN ENGINEERING APPR
8th Edition
ISBN: 9780100257054
Author: CENGEL
Publisher: YUZU
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Chapter 17.7, Problem 116P

a)

To determine

The exit velocity, mass flow rate, and exit Mach number if the nozzle is isentropic.

a)

Expert Solution
Check Mark

Answer to Problem 116P

The exit velocity of the stream is 528.5m/s.

The mass flow rate is 36.86kg/s.

The Mach number at the exit of nozzle is 0.917.

Explanation of Solution

For isentropic,

The flow of steam through the nozzle is steady and isentropic.

Write the expression of energy balance equation for the converging-diverging nozzle.

h1+V12/2=h2+V22/2

Inlet velocity is equal to zero V1=0.

V2=2(h1h2) (I)

Here, enthalpy at exit is h2, enthalpy at inlet is h1, velocity of steam at the inlet of nozzle is V1, and velocity of steam at exit of nozzle is V2 .

Write the expression to calculate the exit area of the nozzle.

A2=m˙v2V2m˙=A2V2v2 (II)

Here, mass flow rate of steam is m˙ , specific volume of the steam at the exit is v2 .

Write the expression to calculate the velocity of sound through the steam at the exit of nozzle.

c2=(Pρ)s1/2=(ΔPΔ(1/v))s1/2 (III)

Here, pressure drop in the nozzle is ΔP, and drop in the specific volume of the steam is Δ(1/v).

Write the expression to calculate the Mach number for the steam at the exit of nozzle.

Ma2=V2c2 (IV)

Here, Mach number of the steam at the exit is Ma2 .

Conclusion:

Refer Table A-6, “Superheated water”, obtain the values of h01, and s2s at inlet pressure of 5MPa and temperature of 400°C as 3196.7kJ/kg, and 6.6483kJ/kgK respectively.

Here, stagnation enthalpy at the inlet is h01, at superheated condition the entropy of saturated steam is s2s.

Refer Table A-6, “Superheated water”, obtain the final enthalpy and specific volume at an entropy of 6.6483kJ/kgK and exit pressure of 3MPa as 3057kJ/kg and 0.08601m3/kg.

The stagnation enthalpy of steam at the inlet is equal to the actual enthalpy

at the inlet (h01=h1).

Substitute 3196.7kJ/kg for h1 and 3057kJ/kg for h2 in Equation (II).

V2=2(3196.7kJ/kg3057kJ/kg)=2(3196.7kJ/kg3057kJ/kg)(1000m2/s21kJ/kg)=528.5m/s

Thus, the exit velocity of the stream is 528.5m/s.

Substitute 60cm2 for A, 0.08601m3/kg for v2, and 528.5m/s  for V2 in Equation (III).

m˙=60cm2×528.5m/s0.08601m3/kg=60cm2(1m210000cm2)×528.5m/s0.08601m3/kg=36.86kg/s

Thus, the mass flow rate is 36.86kg/s.

Refer Table A-6, “Superheated water”, obtain the value of specific volume of steam at the entropy of 6.6483kJ/kgK at pressure just below and above the specified pressure of 2.5MPa and 3.5MPa as 0.09906m3/kg and 0.07632m3/kg respectively.

Substitute (35002500)kPa for ΔP, and (10.0990610.07632)kg/m3 for Δ(1/v) in Equation (IV).

c2=((35002500)kPa(10.0990610.07632)kg/m3)1/2=((35002500)kPa(10.0990610.07632)kg/m3(1000m2/s21kPam3))1/2=576.6m/s

Substitute 576.6m/s for c2, and 528.5m/s for V2 in Equation (V).

Ma2=528.5m/s576.6m/s=0.917

Hence, the Mach number at the exit of nozzle is 0.917.

b)

To determine

The exit velocity, mass flow rate, and exit Mach number if the has an efficiency of 94 percent.

b)

Expert Solution
Check Mark

Answer to Problem 116P

The exit velocity of the stream is 512.4m/s.

The mass flow rate is 35.47kg/s.

The Mach number at the exit of nozzle is 0.885.

Explanation of Solution

Nozzle has an efficiency of 94 percent:

Write the expression for the efficiency of nozzle.

ηN=h01h2h01h2s (V)

Here, efficiency of nozzle is ηN, stagnation enthalpy at the inlet is h01, enthalpy at exit is h2, and superheated enthalpy at exit is h2s.

Write the expression of energy balance equation for the converging-diverging nozzle.

h1+V12/2=h2+V22/2

Inlet velocity is equal to zero V1=0.

V2=2(h1h2) (VI)

Here, velocity of steam at the inlet of nozzle is V1, and velocity of steam at exit of nozzle is V2 .

Write the expression to calculate the exit area of the nozzle.

A2=m˙v2V2 (VII)

Here, mass flow rate of steam is m˙ , specific volume of the steam at the exit is v2 .

Write the expression to calculate the velocity of sound through the steam at the exit of nozzle.

c2=(Pρ)s1/2=(ΔPΔ(1/v))s1/2 (VIII)

Here, pressure drop in the nozzle is ΔP, and drop in the specific volume of the steam is Δ(1/v).

Write the expression to calculate the Mach number for the steam at the exit of nozzle.

Ma2=V2c2 (IX)

Here, Mach number of the steam at the exit is Ma2 .

Conclusion:

Refer Table A-6, “Superheated water”, obtain the values of h01, and s2s at inlet pressure of 5MPa and temperature of 400°C as 3196.7kJ/kg, and 6.6483kJ/kgK respectively.

Here, at superheated condition the entropy of saturated steam is s2s.

Refer Table A-6, “Superheated water”, obtain the isentropic final enthalpy value h2s and final specific volume at an entropy of 6.6483kJ/kgK and a pressure of 3MPa as 3057kJ/kg and 0.08666m3/kg.

Substitute 3057kJ/kg for h2s, 3196.7kJ/kg for h01, and 0.90 for ηN in Equation (V).

94%=3196.7kJ/kgh23196.7kJ/kg3057kJ/kg94(1100)=3196.7kJ/kgh23196.7kJ/kg3057kJ/kgh2=3065.4kJ/kg

The stagnation enthalpy of steam at the inlet is equal to the actual enthalpy

at the inlet (h01=h1).

Substitute 3196.7kJ/kg for h1 and 3065.4kJ/kg for h2 in Equation (VI).

V2=2(3196.7kJ/kg3065.4kJ/kg)=2(3196.7kJ/kg3065.4kJ/kg)(1000m2/s21kJ/kg)=512.4m/s

Thus, the exit velocity of the stream is 512.4m/s.

Substitute 60cm2 for A2, 0.08666m3/kg for v2, and 512.4m/s for V2 in Equation (VII).

m˙=60cm2×512.4m/s0.08666m3/kg=60cm2(1m210000cm2)×512.4m/s0.08666m3/kg=35.47kg/s

Thus, the mass flow rate is 35.47kg/s.

Refer Table A-6, “Superheated water”, obtain the value of specific volume of steam Δ(1/v) at the entropy of 0.08666m3/kg at pressure just below and above the specified pressure of 2.5MPa and 3.5MPa as 0.09981m3/kg and 0.07689m3/kg respectively.

Substitute (35002500)kPa for ΔP, and (10.0998110.07689)kg/m3 for Δ(1/v) in Equation (VIII).

c2=((35002500)kPa(10.0998110.07689)kg/m3)1/2=((35002500)kPa(10.0998110.07689)kg/m3(1000m2/s21kPam3))1/2=578.7m/s

Substitute 578.7m/s for c2, and 512.4m/s for V2 in Equation (IX).

Ma2=512.4m/s578.7m/s=0.885

Thus, the Mach number at the exit of nozzle is 0.885.

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Chapter 17 Solutions

EBK THERMODYNAMICS: AN ENGINEERING APPR

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