Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
9th Edition
ISBN: 9781260048766
Author: CENGEL
Publisher: MCG
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Chapter 7.13, Problem 110P

Helium gas is compressed from 16 psia and 85°F to 120 psia at a rate of 10 ft3/s. Determine the power input to the compressor, assuming the compression process to be (a) isentropic, (b) polytropic with n = 1.2, (c) isothermal, and (d) ideal two-stage polytropic with n = 1.2.

a)

Expert Solution
Check Mark
To determine

The power input of the compressor for isentropic compression process

Answer to Problem 110P

The power input of the compressor for isentropic compression process is 129.8hp.

Explanation of Solution

Write the expression to calculate the mass flow rate m˙.

m˙=P1ν˙1RT1 (I)

Here, initial pressure is P1, rate of initial volume is ν˙1, gas constant is R , and initial temperature is T1.

Write the expression for the power input of the compressor for isentropic compression process.

W˙comp,in=m˙kRT1k1[(P2P1)(k1)/k1] (II)

Here, power input of the compressor is W˙comp,in, mass flow rate of nitrogen is m˙, specific heat ratio is k, gas constant is R, initial temperature is T1, initial pressure is P1 and final pressure is P2.

Conclusion:

From Table A-2E, “Ideal-gas specific heats of various common gases”, the value of gas constant (R) is 0.496Btu/lbmR for and the value of specific heat ratio (k) is 1.4 for helium gas.

Substitute 16psia for P2, 10ft3/s for V2, 0.496Btu/lbmR for R and 545R for T1 in Equation (I).

m˙=16psia×10ft3/s0.496Btu/lbmR×545R=16psia×10ft3/s0.496Btu/lbmR(5.40395psiaft31Btu)×545R=0.1095Ibm/s

Substitute 0.1095Ibm/s for m˙, 1.667 for k, 0.496Btu/lbmR for R, 545R for T1, 120psia for P2 and 16psia for P1 in Equation (II).

W˙comp,in={(0.1095Ibm/s)(1.667)(0.496Btu/lbmR)(545R)1.6671×[(120psia16psia)(1.6671)/1.6671]}W˙comp,in={(0.1095Ibm/s)(1.667)(0.496Btu/lbmR)(545R)0.667×[(120psia16psia)(0.667)/1.6671]}

W˙comp,in=91.74Btu/s(1hp0.7068Btu/s)=129.796hp=129.8hp

Thus, the power input of the compressor for isentropic compression process is 129.8hp.

b)

Expert Solution
Check Mark
To determine

The power input of the compressor for polytropic compression process.

Answer to Problem 110P

The power input of the compressor for polytropic compression process is 100.3hp.

Explanation of Solution

Write the expression for the the power input of the compressor for polytropic compression process.

W˙comp,in=m˙nRT1n1[(P2P1)(n1)/n1] (III)

Here, power input of the compressor is W˙comp,in, mass flow rate of nitrogen is m˙, polytropic index is n, gas constant is R, initial temperature is T1, initial pressure is P1 and final pressure is P2.

Conclusion:

Substitute 1.2 for n , 0.1095Ibm/s for m˙, 1.667 for k, 0.496Btu/lbmR for R, 545R for T1, 120psia for P2 and 16psia for P1 in Equation (III).

W˙comp,in={(0.1095Ibm/s)(1.2)(0.496Btu/lbmR)(545R)1.21×[(120psia16psia)(1.21)/1.21]}={(0.1095Ibm/s)(1.2)(0.496Btu/lbmR)(545R)0.2×[(120psia16psia)(0.2)/1.21]}=70.89Btu/s(1hp0.7068Btu/s)=100.2971hp=100.3hp

Thus, the power input of the compressor for polytropic compression process is 100.3hp.

c)

Expert Solution
Check Mark
To determine

The power input of the compressor for isothermal compression process.

Answer to Problem 110P

The power input of the compressor for isothermal compression process is 84.42hp.

Explanation of Solution

Write the expression to calculate the power input of the compressor for isothermal compression process.

W˙comp,in=m˙RT1ln(P2P1) (IV)

Here, power input of the compressor is W˙comp,in, mass flow rate of nitrogen is m˙, gas constant is R, initial temperature is T1, initial pressure is P1 and final pressure is P2.

Conclusion:

Substitute 0.1095Ibm/s for m˙, 1.667 for k, 0.496Btu/lbmR for R, 545R for T1, 120psia for P2 and 16psia for P1 in Equation (IV).

W˙comp,in=(0.1095Ibm/s)(0.496Btu/lbmR)(545R)ln(120psia16psia)=59.67Btu/s(1hp0.7068Btu/s)=84.42hp

Thus, the power input of the compressor for isothermal compression process is 84.42hp.

d)

Expert Solution
Check Mark
To determine

The expression to calculate the power input of the compressor for two stage compression process

Answer to Problem 110P

The expression to calculate the power input of the compressor for two stage compression process is 105.28hp.

Explanation of Solution

Write the expression to calculate the even pressure or pressure ratio (Px).

Px=P1P2 (V)

Write the expression to calculate the power input of the compressor for two stage compression process.

W˙comp,in=2m˙nRT1n1[(PxP1)(n1)/n1] (VI)

Here, power input of the compressor is W˙comp,in, mass flow rate of nitrogen is m˙,  index is n, gas constant is R, initial temperature is T1, even pressure is Px and final pressure is P2.

Conclusion:

Substitute 120psia for P2 and 16psia for P1 in Equation (V).

Px=(16psia)(120psia)=43.82psia

Substitute 43.82psia for Px , 1.2 for n , 0.1095Ibm/s for m˙, 0.496Btu/lbmR for R, 545R for T1, and 16psia for P1 in Equation (VI).

W˙comp,in={2(0.1095Ibm/s)(1.2)(0.496Btu/lbmR)(545R)1.21×[(43.82psia16psia)(1.21)/1.21]}=74.41Btu/s(1hp0.7068Btu/s)=105.28hp

Thus, the expression to calculate the power input of the compressor for two stage compression process is 105.28hp.

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Chapter 7 Solutions

Thermodynamics: An Engineering Approach

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