Concept explainers
(a)
The total power required to accelerate the car on the uphill road at a constant velocity.
(a)
Answer to Problem 36P
The total power required to accelerate the car on the uphill road at a constant velocity is
Explanation of Solution
The total work required to accelerate the car on the uphill road is equal to the summation of the rates of changes in kinetic and potential energies respectively.
Write the formula to calculate rate of change in kinetic energy of the car
Here, mass of the car is
Write the formula to calculate rate of change in potential energy of the car
Here, acceleration due to gravity is
Write the formula to calculate total power required to accelerate the car on the uphill road
Conclusion:
Since the velocity is constant, the initial and final velocities of the car will be zero.
Then the rate of change in kinetic energy of the car will also be zero.
Substitute
Substitute
The total power required to accelerate the car on the uphill road at a constant velocity is
(b)
The total power required to accelerate the car on the uphill road from rest to the final velocity.
(b)
Answer to Problem 36P
The total power required to accelerate the car on the uphill road from rest to the final velocity is
Explanation of Solution
Conclusion:
Substitute
Substitute
The total power required to accelerate the car on the uphill road from rest to the final velocity is
(c)
The total power required to accelerate the car on the uphill road from initial to the final velocity.
(c)
Answer to Problem 36P
The total power required to accelerate the car on the uphill road from initial to the final velocity is
Explanation of Solution
Conclusion:
Substitute
Substitute
The total power required to accelerate the car on the uphill road from initial to the final velocity is
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Chapter 2 Solutions
EBK THERMODYNAMICS: AN ENGINEERING APPR
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