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(Ann) #1
560 ENGINEERING THERMODYNAMICS

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(iv)Brake thermal efficiency :

Brake thermal efficiency =

W
hhf

brake
1 − 3

=
225
3037 6 428.8. −
= 0.086 or 8.6%. (Ans.)

(v)Relative efficiency :
Relative efficiency on the basis of indicated work

=

W
hh
W
hh

f

f

indicated
1

1

3

3



=

W
W

indicated = 281 25
495 8

.

. = 0.567 or 56.7%. (Ans.)


Relative efficiency on the basis of brake work

=

W
hh
W
hh

f

f

indicated
()

()

1

1

3

3



=

W
W

brake =^225
495 8. = 0.4538 or 45.38%. (Ans.)

Example 12.11. Superheated steam at a pressure of 10 bar and 400°C is supplied to a
steam engine. Adiabatic expansion takes place to release point at 0.9 bar and it exhausts into a
condenser at 0.3 bar. Neglecting clearance determine for a steam flow rate of 1.5 kg/s :
(i)Quality of steam at the end of expansion and the end of constant volume operation.
(ii)Power developed.
(iii)Specific steam consumption.
(iv)Modified Rankine cycle efficiency.
Solution. Fig. 12.14 shows the p-V and T-s diagrams for modified Rankine cycle.
From steam tables :



  1. At 10 bar, 400°°°°°C : h 1 = 3263.9 kJ/kg, v 1 = 0.307 m^3 /kg, s 1 = 7.465 kJ/kg K
    2. At 0.9 bar : ts 2 = 96.7°C, hg 2 = 2670.9 kJ/kg, sg 2 = 7.3954 kJ/kg K,
    vg 2 = 1.869 m^3 /kg

  2. At 0.3 bar : hf 3 = 289.3 kJ/kg, vg 3 = 5.229 m^3 /kg
    (i) Quality of steam at the end of expansion, Tsup2 :
    For isentropic expansion 1-2, we have
    s 1 = s 2


= sg 2 + cp loge
T
T

sup
s

2
2
7.465 = 7.3954 + 2.1 loge
Tsup 2
()96.7 273+











465 3954
1

F −
HG

I
KJ
= loge

Tsup 2
369 7.
or loge

Tsup 2
369 7.
= 0.0033

Tsup 2
369 7.

= 1.0337 or Tsup 2 = 382 K
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