PROPERTIES OF PURE SUBSTANCES 87Dharm
\M-therm/th3-2.p65Main
(20 bar, 250°C)Boiler B
with superheater
(20 bar, 350°C)1Boiler B
(20 bar)2Fig. 3.13
Equating (i) and (ii) with (iii), we get
3106.8 + 908.6 + x 2 × 1888.6 = 5763.6
4015.4 + 1888.6x 2 = 5763.6∴ x 2 =57636 40154 18886 ..−. = 0.925
Hence, quality of steam supplied by the other boiler = 0.925. (Ans.)
Example 3.20. Determine the entropy of 1 kg of wet steam at a pressure of 6 bar and
0.8 dry, reckoned from freezing point (0°C).
Solution. Mass of wet steam, m = 1 kg
Pressure of steam, p = 6 bar
Dryness fraction, x = 0.8
At 6 bar. From steam tables,
ts = 158.8°C, hfg = 2085 kJ/kg
Entropy of wet steam is given byswet = cpw logeT xh
Ts fg(^273) s
- (where cpw = specific heat of water)
= 4.18 loge
1588 273
273
0 8 2085
1588 273
..
(. )
F +
H
I
K+
×
= 1.9165 + 3.8700 = 5.7865 kJ/kg K
Hence, entropy of wet steam = 5.7865 kJ/kg K. (Ans.)
Example 3.21. Steam enters an engine at a pressure 10 bar absolute and 400°C. It is
exhausted at 0.2 bar. The steam at exhaust is 0.9 dry. Find :
(i)Drop in enthalpy ;
(ii)Change in entropy.
Solution. Initial pressure of steam, p 1 = 10 bar
Initial temperature of steam, tsup = 400°C
Final pressure of steam, p 2 = 0.2 bar
Final condition of steam, x 2 = 0.9