204 ENGINEERING THERMODYNAMICS
dharm
/M-therm/Th4-6.pm5
Process of expansion : Reversible adiabatic
As the process is reversible adiabatic, it will be represented by a vertical line on T-s diagram
by 1-2 as it is also constant entropy process.
The condition at point ‘2’ can be calculated by equating the entropy at point ‘1’ and point ‘2’,
i.e., s 1 = s 2 .....per kg of steam
7.102 = sxs sf 222 +− 2 ()g f
= 1.3609 + x 2 (7.2984 – 1.3609)
∴ x 2 =
7 3609
7 3609
.102 1.
.2984 1.
−
− = 0.967
h 2 = hxhf 22 + 2 fg = 439.4 + 0.967 × 2244.1 = 2609.44 kJ/kg
h 1 (at 15 bar and 350°C) = 3147.5 kJ/kg
Applying the first law energy equation for steady flow process,
h 1 + C^1
2
2 = h^2 +
C 22
2 + W
i.e., W = (h 1 – h 2 ) +
CC 12 22
2
F −
HG
I
KJ
= 3147.5 – 2609.44 +
60 180
210
22
3
−
×
F
HG
I
KJ
= 3147.5 – 2609.44 – 14.4 = 523.66 kJ/kg.
Hence work done per kg of steam = 523.66 kJ/kg. (Ans.)
Example 4.60. Steam at 10 bar and 200°C enters a convergent divergent nozzle with a
velocity of 60 m/s and leaves at 1.5 bar and with a velocity of 650 m/s. Assuming that there is no
heat loss, determine the quality of the steam leaving the nozzle.
Solution. Initial pressure of steam, p 1 = 10 bar
Initial temperature of steam, t 1 = tsup = 200°C
Initial velocity, C 1 = 60 m/s
Final velocity, C 2 = 650 m/s
Final pressure, p 2 = 1.5 bar
Heat loss = nil
Quality of steam at the outlet :
It is a steady-state non-work developing system. Applying the steady flow energy equation
to the process, we get
h 1 + C^1
2
2
= h 2 + C^2
2
2
(Q Q = 0, W = 0)
∴ h 2 = h 1 +
CC 12 22
2
F −
HG
I
KJ
At 10 bar, 250ºC : h 1 = 2827.9 kJ/kg (from steam tables)
∴ h 2 = 2827.9 +
60 650
210
22
3
−
×
L
NM
O
QP = 2618.45 kJ/kg