THERMODYNAMICS: ENG APPROACH LOOSELEAF
THERMODYNAMICS: ENG APPROACH LOOSELEAF
9th Edition
ISBN: 9781266084584
Author: CENGEL
Publisher: MCG
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Chapter 9.12, Problem 135P

A pure jet engine propels an aircraft at 240 m/s through air at 45 kPa and −13°C. The inlet diameter of this engine is 1.6 m, the compressor pressure ratio is 13, and the temperature at the turbine inlet is 557°C. Determine the velocity at the exit of this engine’s nozzle and the thrust produced. Assume ideal operation for all components and constant specific heats at room temperature.

Expert Solution & Answer
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To determine

The velocity at the exit of this engine’s nozzle and the thrust produced.

Answer to Problem 135P

The velocity at the exit of this engine’s nozzle is 564.8m/s.

The thrust produced by the engine is 94520N.

Explanation of Solution

Draw the Ts diagram for pure jet engine as shown in Figure (1).

THERMODYNAMICS: ENG APPROACH LOOSELEAF, Chapter 9.12, Problem 135P

Consider that the aircraft is stationary, and the velocity of air moving towards the aircraft is V1=240m/s, the air will leave the diffuser with a negligible velocity (V20).

Diffuser:

Write the expression for the energy balance equation for the diffuser.

E˙inE˙out=ΔE˙system (I)

Here, the rate of energy entering the system is E˙in, rate of energy leaving the system is E˙out, and the rate of change in the energy of the system is ΔE˙system.

Write the temperature and pressure relation for the process 1-2.

P2=P1(T2T1)k/(k1) (II)

Here, the specific heat ratio of air is k, pressure at state 1 is P1, pressure at state 2 is P2, temperature at state 1 is T1 and temperature at state 2 is T2.

Compressor:

Write the pressure relation using the pressure ratio for the process 2-3.

P3=P4=(rp)(P2) (III)

Here, the pressure ratio is rp, pressure at state 3 is P3 and pressure at state 4 is P4.

Write the temperature and pressure relation for the process 2-3.

T3=T2(P3P2)(k1)/kT3=T2(rp(k1)/k) (IV)

Here, temperate at state 3 is T3.

Turbine:

Write the temperature relation for the compressor and turbine.

wcomp,in=wturb,outh3h2=h4h5cp(T3T2)=cp(T4T5)

T3T2=T4T5T5=T4T3+T2 (V)

Here, the specific heat at constant pressure is cp, enthalpy at state 2 is h2, enthalpy at state 3 is h3, enthalpy at state 4 is h4, enthalpy at state 5 is h5, work input to the compressor is wcomp,in, work output from turbine is wturb,out, temperature at state 4 is T4 and temperature at state 5 is T5.

Nozzle:

Write the temperature and pressure relation for the isentropic process 4-6.

T6=T4(P6P4)(k1)/k (VI)

Here, pressure at state 6 is P6 and temperature at state 6 is T6.

Write the energy balance equation for the nozzle.

E˙inE˙out=ΔE˙system (VII)

Write the expression to calculate the specific volume at state 1 v1.

v1=RT1P1 (VIII)

Here, gas constant is R , temperature at state 1 is T1 and pressure at state 1 is P1.

Write the expression to calculate the mass flow rate of propeller m˙p.

m˙p=A1Vinletv1=πD24Vinletv1 (IX)

Here, propeller diameter is D, area is A1 and inlet velocity is Vinlet.

Write the expression to calculate the thrust force generated by the propeller (F).

F=m˙p(VexitVinlet) (X)

Here, the thrust force produced by engine is F, mass flow rate of air is m˙, inlet velocity of air is Vinlet, and outlet velocity of air is Vexit.

Conclusion.

From Table A-2a, “Ideal-gas specific heats of various common gases”, obtain the following values for air at room temperature.

k=1.4cp=1.005kJ/kgK

The rate of change in the energy of the system (ΔE˙system) is zero for the steady state system.

Substitute 0 for ΔE˙system Equation (I).

E˙inE˙out=0E˙in=E˙outh1+V122=h2+V222

0=h2h1+V22V1220=cp(T2T1)V22V122 (XI)

Here, inlet velocity is V1 or Vinlet and velocity at state 2 is V2.

Substitute 0 for V2, 13°C for T1, 240m/s for V1, and 1.005kJ/kgK for cp in Equation (XI).

0=1.005kJ/kgK(T2(13°C))V22(240m/s)22T2=(13+273)K+(240m/s)2(2)(1.005kJ/kgK)(1kJ/kg1000m2/s2)T2=288.7K

Substitute 45kPa for P1, 288.7K for T2, 13°C for T1, and 1.4 for k to find P2 in Equation (II).

P2=(45kPa)(288.7K13°C)1.4/1.41=(45kPa)(288.7K(13+273)K)1.4/1.41=64.88kPa

Substitute 13 for rp, and 64.88kPa for P2 in Equation (III).

P3=P4=(13)(64.88kPa)=843.5kPa

Substitute 288.7K for T2, 1.4 for k, and 13 for rp in Equation (IV).

T3=(288.7K)(13)1.41/1.4=600.7K

Substitute 557°C for T4, 600.7K for T3, and 288.7K for T2 in Equation (V).

T5=(557°C600.7K+288.7K)=(557+273)K600.7K+288.7K=518K

Substitute 557°C for T4, 1.4 for k, 45kPa for P6, and 843.5kPa for P4 in Equation (VI).

T6=(557°C)(45kPa843.5kPa)1.41/1.4=(557+273)K(45kPa843.5kPa)1.41/1.4=359.3K

The rate of change in the energy of the system (ΔE˙system) is zero for the steady state system.

Substitute 0 for ΔE˙system Equation (VII).

E˙in=E˙outh5+V522=h6+V6220=h6h5+V62V5220=cp(T6T5)V62V522 (XII)

Here, velocity at stat 5 is V5, exit velocity is V6 or Vexit and temperate at state 6 is T6.

Since, V5=V2

Substitute 0 for V5, 518K for T5, 359.3K for T6, and 1.005kJ/kgK for cp to find V6 in Equation (XII).

0=1.005kJ/kgK(359.3K518K)V6202V6=2(1.005kJ/kgK)(518K359.3K)(1000m2/s21kJ/kg)V6=564.8m/sV6=Vexit=564.8m/s

Thus, the velocity at the exit of this engine’s nozzle is 564.8m/s.

Substitute 0.287kPam3/kgK for R , 13°C for T1 and 45kPa for P1 in Equation (VIII).

v1=0.287kPam3/kgK(13°C)45kPa=0.287kPam3/kgK(13+273)K8psia=1.658m3/kg

Substitute 1.6m3 for D, 240m/s for Vinlet and 1.658m3/kg for v1 in Equation (IX).

m˙p=π(1.6m3)24240m/s1.658m3/kg=291kg/s

Substitute 291kg/s for m˙p, 240m/s for Vinlet and 564.8m/s for Vexit in Equation (X).

F=291kg/s(564.8m/s240m/s)=94520kgm/s2(1N1kgm/s2)=94520N

Thus, the thrust produced by the engine is 94520N.

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Chapter 9 Solutions

THERMODYNAMICS: ENG APPROACH LOOSELEAF

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