PSYCHROMETRICS 469
dharm
\M-therm\Th10-1.pm5
(ii)Heat added to air per minute :
Enthalpy, h 2 = cptdb + Whvapour
= 1.005 × 30 + 0.0109 × [hg + 1.88 (tdb – tdp)]
= 1.005 × 30 + 0.0109 [2556.3 + 1.88 (30 – 15.5)]
= 58.31 kJ/kg of dry air
Mass of dry air in 90 m^3 of air supplied
ma =
pV
RT
ppV
RT
=()tv−
= −××
×+
(.. )
()
1 0132 0 01755 10 90
287 273 20
5
= 106.5 kg/min.
Amount of heat added per minute
= 106.5 (h 2 – h 1 ) = 106.5 (58.31 – 47.85) ~−1114 kJ. (Ans.)
Example 10.7. Sensible cooling : 40 m^3 of air at 35°C DBT and 50% R.H. is cooled to
25 °C DBT maintaining its specific humidity constant. Determine :
(i)Relative humidity (R.H.) of cooled air ;
(ii)Heat removed from air.
Solution. For air at 35°C DBT and 50% R.H. :
pvs = 0.0563 bar (At 35ºC, from steam tables)
φ = p
p
v
vs
∴ pv = φ × pvs = 0.5 × 0.0563 = 0.02815 bar
W 1 =
622 622 02815
0132 02815
p
pp
v
tv−
= ×
− = 0.0177 kg/kg of dry air
h 1 = cp tdb 1 + W 1 [hg 1 + 1.88 (tdb 1 – tdp 1 ]
tdp 1 ~− 23ºC (corresponding to 0.02815 bar)
∴ h 1 = 1.005 × 35 + 0.0177 [2565.3 + 1.88 (35 – 23)] = 80.98 kJ/kg of dry air
For air at 25°C DBT :
(i)R.H. of cooled air :
Since the specific humidity remains constant the vapour pressure in the air remains constant.
φ =
p
p
v
vs
=0 02815
0 0317
.
.
= 0.888 or 88.8%
i.e., Relative humidity of the cooled air = 88.8%. (Ans.)
(ii)Heat removed from air :
h 2 = cp tdb 2 + W 2 [hg 2 + 1.88 (tdb 2 – tdp 2 )]
= 1.005 × 25 + 0.0177 [2547.2 + 1.88 (25 – 23)]
= 70.27 kJ/kg of dry air.
To find mass of dry air (ma), using the relation :
pava = maRaTa
∴ ma = pv
RT
aa
aa
= −××
×+
(.. )
()
1 0132 0 02815 10 40
287 273 35
5
= 44.57 kg
∴ Heat removed from 40 m^3 of air
= ma (h 1 – h 2 ) = 44.57 (80.98 – 70.27) = 477.3 kJ. (Ans.)
Q WW
ttdp dp pv
12 0 0177
2123
==
==°
L
NM
O
QP
.kg/kgof dryair
Csince doesnotchange