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Chapter 15: Q21P (page 412)

Question:(I) A heat engine does 9200 J of work per cycle while absorbing 25.0 kcal of heat from a high-temperature reservoir. What is the efficiency of this engine?

Short Answer

Expert verified

The efficiency of the heat engine is \(8.79\% \).

Step by step solution

01

Understanding the working of the heat engine

The efficiency of the heat engine is dependent on the work done and the heat provided to the engine.

The heat can be absorbed from the higher temperature reservoir. The remaining heat can be rejected to the lower temperature reservoir. An engine changes the heat into the required mechanical work.

02

Identification of given data

The given data can be listed below as:

  • The heat absorbed by the heat engine is\({Q_{\rm{H}}} = 25{\rm{ kcal}}\left( {\frac{{4186{\rm{ J}}}}{{1{\rm{ kcal}}}}} \right) = 104650{\rm{ J}}\).
  • The work done by the heat engine is \(W = 9200{\rm{ J}}\).
03

Determination of the efficiency of the heat engine

The efficiency of the heat engine can be expressed as:

\(e = \left( {\frac{W}{{{Q_{\rm{H}}}}}} \right)\)

Here,\({Q_{\rm{H}}}\)is the heat supplied to the heat engine.

Substitute the values in the above equation.

\(\begin{aligned}{c}e &= \left( {\frac{{9200{\rm{ J}}}}{{104650{\rm{ J}}}}} \right)\\e &= 0.0879\\e &= 0.0879 \times 100\% \\e &= 8.79\% \end{aligned}\)

Thus, the efficiency of the heat engine is \(8.79\% \).

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Most popular questions from this chapter

Question:(II) A heat engine uses a heat source at 580°C and has an ideal (Carnot) efficiency of 22%. To increase the ideal efficiency to 42%, what must be the temperature of the heat source?

(II) Energy may be stored by pumping water to a high reservoir when demand is low and then releasing it to drive turbines during peak demand. Suppose water is pumped to a lake 115 m above the turbines at a rate of\({\bf{1}}{\bf{.00 \times 1}}{{\bf{0}}{\bf{5}}}\;{\bf{kg/s}}\)for 10.0 h at night. (a) How much energy (kWh) is needed to do this each night? (b) If all this energy is released during a 14-h day, at 75% efficiency, what is the average power output?

Question: Give three examples, other than those mentioned in this Chapter, of naturally occurring processes in which order goes to disorder. Discuss the observability of the reverse process.

(II) Sketch a PV diagram of the following process: 2.5 L of ideal gas at atmospheric pressure is cooled at constant pressure to a volume of 1.0 L, and then expanded isothermally back to 2.5 L, whereupon the pressure is increased at constant volume until the original pressure is reached.

Question: An ideal heat pump is used to maintain the inside temperature of a house at \({T_{{\rm{in}}}} = 22{\rm{^\circ C}}\) when the outside temperature is \({T_{{\rm{out}}}}\). Assume that when it is operating, the heat pump does work at a rate of 1500 W. Also assume that the house loses heat via conduction through its walls and other surfaces at a rate given by \(\left( {650\;{{\rm{W}} \mathord{\left/

{\vphantom {{\rm{W}} {{\rm{^\circ C}}}}} \right.} {{\rm{^\circ C}}}}} \right)\left( {{T_{{\rm{in}}}} - {T_{{\rm{out}}}}} \right)\). (a) For what outside temperature would the heat pump have to operate all the time in order to maintain the house at an inside temperature of 22°C? (b) If the outside temperature is 8°C, what percentage of the time does the heat pump have to operate in order to maintain the house at an inside temperature of 22°C?
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