CONNECT FOR THERMODYNAMICS: AN ENGINEERI
CONNECT FOR THERMODYNAMICS: AN ENGINEERI
9th Edition
ISBN: 9781260048636
Author: CENGEL
Publisher: MCG
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Chapter 9.12, Problem 136P

A turbojet aircraft is flying with a velocity of 280 m/s at an altitude of 9150 m, where the ambient conditions are 32 kPa and −32°C. The pressure ratio across the compressor is 12, and the temperature at the turbine inlet is 1100 K. Air enters the compressor at a rate of 50 kg/s, and the jet fuel has a heating value of 42,700 kJ/kg. Assuming ideal operation for all components and constant specific heats for air at room temperature, determine (a) the velocity of the exhaust gases, (b) the propulsive power developed, and (c) the rate of fuel consumption.

a)

Expert Solution
Check Mark
To determine

The velocity of the exhaust gases.

Answer to Problem 136P

The velocity of the exhaust gases is 832.7m/s.

Explanation of Solution

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

CONNECT FOR THERMODYNAMICS: AN ENGINEERI, Chapter 9.12, Problem 136P

Consider, the pressure is Pi , the specific volume is vi, the temperature is Ti, the entropy is si, the enthalpy is hi corresponding to ith state.

Consider that the aircraft is stationary, and the velocity of air moving towards the aircraft is V1=280m/s, the air will leave the diffuser with a negligible velocity (V20).

Diffuser (For process 1-2):

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

E˙inE˙out=ΔE˙system (I)

Here, the energy entering the system is E˙in, 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.

Compressor (For process 2-3)

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

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

Here, the pressure ratio is rp.

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

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

Turbine (For process 4-5)

Write the temperature relation for the compressor and turbine to calculate the temperature at state 5 (T5).

T3T2=T4T5T5=T4T3+T2 (V)

Nozzle (For process 5-6)

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

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

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

E˙inE˙out=ΔE˙system (VII)

Conclusion:

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

cp=1.005kJ/kgKcv=0.718kJ/kgKR=0.287kJ/kgKk=1.4

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

Substitute 0 for ΔE˙system in Equation (I).

E˙in=E˙outh1+V122=h2+V222

0=h2h1+V22V1220=cp(T2T1)V22V122T2=T1V22V122cp (VIII).

Here, the specific heat at constant pressure of air is cp.

Substitute 0 for V2, 32°C for T1, 280m/s for V1, and 1.005kJ/kgK for cp to find T2. Also convert kJ/kg to m2/s2 using suitable conversion factor in Equation (VIII).

T2=(32°C)+(280m/s)2(2)(1.005kJ/kgK)=(32+273)K+(280m/s)2(2)(1.005kJ/kgK)(1kJ/kg1000m2/s2)=280.0K

Substitute 32 kPa for P1, 280.0 K for T2, 32°C for T1, and 1.4 for k to find P2 in Equation (II).

P2=(32kPa)(280.0K32°C)1.4/1.41=(32kPa)(280.0K(32+273)K)1.4/1.41=54.10kPa

Substitute 12 for rp, and 54.10 kPa for P2 in Equation (III).

P3=P4=(12)(54.10kPa)=649.2kPa

Substitute 280.0 K for T2, 1.4 for k, and 12 for rp in Equation (IV).

T3=(280.0K)(12)0.4/1.4=569.5K

Substitute 1,100 K for T4, 569.5 K for T3, and 280.0 K for T2 in Equation (V).

T5=(1,100569.5+280.0)K=810.5K

For process 5-6 (Nozzle)

Substitute 1100 K for T4, 1.4 for k, 32 kPa for P6, and 649.2 kPa for P4 in Equation (VI).

T6=(1100K)(32kPa649.2kPa)1.41/1.4=465.5K

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

Substitute 0 for ΔE˙system in Equation (VII).

E˙in=E˙outh5+V522=h6+V6220=h6h5+V62V522

0=cp(T6T5)V62V522V62=2cp(T5T6)V6=2cp(T5T6) (IX)

Substitute 810.5 K for T5, 465.5 K for T6, and 1.005kJ/kgK for cp to find V6 in Equation (IX).

V6=(2)(1.005kJ/kgK)(810.5465.5)K=(2)(1.005kJ/kgK)(810.5465.5)K(1000m2/s21kg/K)=832.7m/s

Thus, the velocity of the exhaust gases is 832.7m/s.

b)

Expert Solution
Check Mark
To determine

The propulsive power produced by the turbojet engine.

Answer to Problem 136P

The propulsive power produced by the turbojet engine is 7738kW.

Explanation of Solution

Nozzle (For process 5-6)

Write the expression to calculate the propulsive power produced by the turbojet engine (W˙p).

W˙p=m˙(VexitVinlet)Vaircraft (X)

Here, the velocity of the aircraft is Vaircraft, the velocity of the inlet air is Vinlet, the exit velocity of the exhaust gases is Vexit and the mass flow rate of air through the

 engine is m˙.

Conclusion:

Substitute 50kg/s for m˙, 832.7m/s for Vexit, 280m/s for Vinlet, and 280m/s for Vaircraft to find W˙p in Equation (X).

W˙p=(50kg/s)[(832.7280)m/s](280m/s)=(50kg/s)[(832.7280)m/s](280m/s)(1kJ/kg1,000m2/s2)=7738kW

Thus, the propulsive power produced by the turbojet engine is 7738kW.

c)

Expert Solution
Check Mark
To determine

The rate of fuel consumption.

Answer to Problem 136P

The rate of fuel consumption is 0.6243kg/s.

Explanation of Solution

Write the expression to calculate the heating value of the fuel for the turbojet engine (Q˙in).

Q˙in=m˙(h4h3)=m˙cp(T4T3) (XI)

Write the expression to calculate the mass flow rate of fuel for the turbojet engine (m˙fuel).

m˙fuel=Q˙inHV (XII)

Here, the calorific value of the fuel is HV.

Conclusion.

Substitute 50kg/s for m˙, 1.005kJ/kgK for cp, 569.5 K for T3, and 1100 K for T4 in Equation (XI).

Q˙in=(50kg/s)(1.005kJ/kgK)(1100569.5)K=26657kJ/s

Substitute  42700kJ/kg for HV, and 26657kJ/s for Q˙in in Equation (XII).

m˙fuel=26657kJ/s42700kJ/kg=0.6243kg/s

Thus, the rate of fuel consumption is 0.6243kg/s.

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Chapter 9 Solutions

CONNECT FOR THERMODYNAMICS: AN ENGINEERI

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