SECOND LAW OF THERMODYNAMICS AND ENTROPY 281dharm
/M-therm/th5-4.pm52TSpV = Cn
T 1 1
4T 2dS3=
0 287
14 1290 6
380
0 287
0 5211
0 1363.
.
log
.
.log
.
−.
× eeHFG IKJ+ HGF IKJ= – 0.192 + 0.385 = 0.193 kJ/kg K (increase). (Ans.)
Example 5.35. (a) Show that approximate change of entropy during a polytropic process
equals the quantity of heat transferred divided by the mean absolute temperature.
(b) One kg of air at 290 K is compressed in a cylinder according to the polytropic law
pv1.3= constant. If the compression ratio is 16, calculate the entropy change of air during the
compression process stating whether it is an increase or decrease.
What would be the percentage error if the entropy change is calculated by dividing the
quantity of heat exchanged by the mean absolute temperature during the process?
Take γ = 1.4 and cv = 0.718 kJ/kg K.
Solution. (a) In Fig. 5.41 curve 1-2 represents the
polytropic process (pvn = c) from state point 1 to state point
- The area under the process curve 1-2 on T-S diagram
represents the heat transferred during the process. The slope
of the curve 1-2 is usually small and can be considered to be
a straight line (shotted dotted).
Heat transferred = Area of trapezium 1-2-3-4
= Base × mean ordinate
= dS ×
TT 12
2F +
HGI
KJ
= Entropy change × mean absolute
temperature during the processor, Entropy change =
Heat transferred
Mean absolute temperature
(b) Given : m = 1 kg ; T 1 = 290 K ; pv1.3 = constant ; r = 16 ; γ = 1.4 ; cv = 0.718 kJ/kg K
For a polytropic process : T
Tv
vn
2
11
21
=
F
HGI
KJ−or, T 2 = 290 × (16)1.3–1 = 666.2 KNow, s 2 – s 1 = c n
nT
veT−
−F
HGI
KJF
HGI
KJγ
12
1log ... per kg= 0 718
13 14
13 1666 2
290
.
..
.
log
−.
−F
HGI
KJF
HGI
e KJ = – 0.199 kJ/kg K. (Ans.)
The –ve sign indicates decrease in entropy.
Heat transferred during the process is given by,Q =
γ
γγ
γγ
γ−
−
×=
−
−
×
−
−
=
−
−F
HGI
KJn W nRTT
ncv n
111 1() (^12) (T
1 – T 2 ) ...per kg
= 0 718
14 13
13 1
.
..
.
−
−
F
HG
I
KJ
(290 – 666.2) = – 90.04 kJ/kg Q c
R
v= −
F
HG
I
γ 1 KJ
Fig. 5.41