EBK THERMODYNAMICS: AN ENGINEERING APPR
EBK THERMODYNAMICS: AN ENGINEERING APPR
8th Edition
ISBN: 8220100257056
Author: CENGEL
Publisher: YUZU
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Chapter 2.8, Problem 52P
To determine

The additional power required to achieve the desired acceleration.

The additional power required to achieve the desired acceleration when the total mass of the car is 700kg.

Expert Solution & Answer
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Answer to Problem 52P

The additional power required to achieve the desired acceleration is 77.8kW.

The additional power required to achieve the desired acceleration when the total mass of the car is 700kg is 38.9kW.

Explanation of Solution

Write the energy balance equation for a control volume when the car cruising is taken as the system.

E˙inE˙out=dEsystem/dt (I)

Here, rate of energy transfer entering the system is E˙in, rate of energy transfer leaving the system is E˙out, rate of change in internal, kinetic, and potential energies per unit time is dEsystem/dt.

Since no energy is leaving the system, the rate of energy transfer leaving the system is zero.

E˙out=0

Substitute 0 for E˙out in Equation (I).

E˙in0=dEsystem/dtE˙in=dEsystem/dtE˙in=ΔEsysΔt (II)

Here, change in the internal energy of the system is ΔEsys and change in time is Δt.

Rewrite Equation (II) when rate of work done on the system.

W˙in=ΔKEΔt=m(V22V12)2Δt (III)

Here, change in kinetic energy is ΔKE, additional power required to achieve the acceleration is W˙in, mass of the car is m and initial and final velocities of the car are V1 and V2 respectively.

Conclusion:

Substitute 1400kg for m, 110km/h for V2, 70km/h for V1, and 5s for Δt in Equation (III).

W˙in=(1400kg)((110km/h)2(700km/h)2)2(5s)=(1400kg)((110km/h×1m/s3.6km/h)2(70km/h×1m/s3.6km/h)2)(10s)=(1400kg)(555.56m2/s2)(10s)(1kJ/kg1000m2/s2)=77.8kJ/s

=77.8kJ/s(1kW1kJ/s)=77.8kW

Thus, the additional power required to achieve the desired acceleration is 77.8kW.

Substitute 700kg for m, 110km/h for V2, 70km/h for V1, and 5s for Δt in Equation (III).

W˙in=(700kg)((110km/h)2(70km/h)2)2(5s)=(700kg)((110km/h×1m/s3.6km/h)2(70km/h×1m/s3.6km/h)2)(10s)=(700kg)(555.56m2/s2)(10s)(1kJ/kg1000m2/s2)=38.9kJ/s

=38.9kJ/s(1kW1kJ/s)=38.9kW

Thus, additional power required to achieve the desired acceleration when the total mass of the car is 700kg is 38.9kW.

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Chapter 2 Solutions

EBK THERMODYNAMICS: AN ENGINEERING APPR

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