4.5 The carnot cycle  (Page 3/7)

The carnot engine

A Carnot engine has an efficiency of 0.60 and the temperature of its cold reservoir is 300 K. (a) What is the temperature of the hot reservoir? (b) If the engine does 300 J of work per cycle, how much heat is removed from the high-temperature reservoir per cycle? (c) How much heat is exhausted to the low-temperature reservoir per cycle?

Strategy

From the temperature dependence of the thermal efficiency of the Carnot engine, we can find the temperature of the hot reservoir. Then, from the definition of the efficiency, we can find the heat removed when the work done by the engine is given. Finally, energy conservation will lead to how much heat must be dumped to the cold reservoir.

Solution

1. From $e=1-T_{\text{c}}\text{/}{T}_{\text{h}}$ we have
   
   $0.60=1-\frac{300\text{K}}{T_{\text{h}}},$
   
   so that the temperature of the hot reservoir is
   
   $T_{\text{h}}=\frac{300\text{K}}{1-0.60}=750\text{K}.$
2. By definition, the efficiency of the engine is $e=W\text{/}Q$ , so that the heat removed from the high-temperature reservoir per cycle is
   
   $Q_{\text{h}}=\frac{W}{e}=\frac{300\text{J}}{0.60}=500\text{J}.$
3. From the first law, the heat exhausted to the low-temperature reservoir per cycle by the engine is
   
   $Q_{\text{c}}=Q_{\text{h}}-W=500\text{J}-300\text{J}=200\text{J}.$

Significance

A Carnot engine has the maximum possible efficiency of converting heat into work between two reservoirs, but this does not necessarily mean it is $100\text{\%}$ efficient. As the difference in temperatures of the hot and cold reservoir increases, the efficiency of a Carnot engine increases.

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A carnot heat pump

Imagine a Carnot heat pump operates between an outside temperature of $0\text{°C}$ and an inside temperature of $20.0\text{°C}$ . What is the work needed if the heat delivered to the inside of the house is 30.0 kJ?

Strategy

Because the heat pump is assumed to be a Carnot pump, its performance coefficient is given by $K_{\text{P}}=Q_{\text{h}}\text{/}W=T_{\text{h}}\text{/}(T_{\text{h}}-T_{\text{c}}).$ Thus, we can find the work W from the heat delivered $Q_{\text{h}}.$

Solution

The work needed is obtained from

Significance

We note that this work depends not only on the heat delivered to the house but also on the temperatures outside and inside. The dependence on the temperature outside makes them impractical to use in areas where the temperature is much colder outside than room temperature.

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