244 ENGINEERING THERMODYNAMICS
dharm
/M-therm/th5-2.pm5
Since, W 1 – W 2 = W = 400 kJ
W 2 = W 1 – W = 1670 – 400 = 1270 kJ
∴ Q 4 = 3.306 × 1270 = 4198.6 kJ
Q 3 = Q 4 + W 2 = 4198.6 + 1270 = 5468.6 kJ
Q 2 = Q 1 – W 1 = 2500 – 1670 = 830 kJ.
Heat rejection to the 50°C reservoir
= Q 2 + Q 3 = 830 + 5468.6 = 6298.6 kJ. (Ans.)
(ii) Efficiency of actual heat engine cycle,
η = 0.45 ηmax = 0.45 × 0.668 = 0.3
∴ W 1 = η × Q 1 = 0.3 × 2500 = 750 kJ
∴ W 2 = 750 – 400 = 350 kJ
C.O.P. of the actual refrigerator cycle,
C.O.P. = Q
W
4
2
= 0.45 × 3.306 = 1.48
∴ Q 4 = 350 × 1.48 = 518 kJ. (Ans.)
Q 3 = 518 + 350 = 868 kJ
Q 2 = 2500 – 750 = 1750 kJ
Heat rejected to 50°C reservoir
= Q 2 + Q 3 = 1750 + 868 = 2618 kJ. (Ans.)
+Example 5.13. (i) A reversible heat pump is used to maintain a temperature of 0°C in a
refrigerator when it rejects the heat to the surroundings at 25°C. If the heat removal rate from
the refrigerator is 1440 kJ/min, determine the C.O.P. of the machine and work input required.
(ii)If the required input to run the pump is developed by a reversible engine which receives
heat at 380°C and rejects heat to atmosphere, then determine the overall C.O.P. of the system.
Solution. Refer Fig. 5.15 (a).
(i) Temperature, T 1 = 25 + 273 = 298 K
Temperature, T 2 = 0 + 273 = 273 K
Source
25°C
Sink
0°C
Heat
pump
Q 2
Q 1
W
Source
380°C
Source
0°C
Sink (Atmosphere)
25°C
Heat
engine
Heat
pump
Q 3 Q 1
Q 4 Q 2
(a) Single system (b) Combined system
W
Fig. 5.15