536 ENGINEERING THERMODYNAMICS
dharm
\M-therm\Th11-2.pm5
Given that the enthalpies of combustion at 25°C are :
C 6 H 6 = – 3169500 kJ/mole
C 8 H 18 = – 5116200 kJ/mole
Both the above figures are for the case where the water in the products is in the vapour
phase.
Solution. (i) Air and benzene vapour :
For benzene, the combustion equation is as follows :
C 6 H 6 (g) + 7.5O 2 (g) + 7.5
79
21
F
HG
I
KJ N^2 (g) = 6CO^2 (g) + 3H^2 O(g) + 7.5
79
21
F
HG
I
KJ N^2 (g)
Since the water in the products is in vapour phase, therefore, the given value of enthalpy of
combustion corresponds to the lower heating value at constant pressure.
i.e., (LHV)p = 3169500 kJ/mole
(LHV)v per kg of mixture =
3169500
12 6 6 1 7 5 32 7 5^79
21
()(.).()×+× + × + FHG IKJ 28
=
3169500
78 240 790++ = 2861 kJ/kg. (Ans.)
Now, (HHV)p = (LHV)p + mhfg
where (HHV)p = Higher heating value at constant pressure,
(LHV)p = Lower heating value at constant pressure,
m = Mass of water formed by combustion.
= 3 × 18 = 54 kg/kg mole of fuel, and
hfg = Latent heat of vapourisation at given temperature per unit mass of water
= 2442 kJ/kg at 25°C.
∴ (HHV)p = 3169500 + 54 × 2442 = 3301368 kJ/mole
Thus, (HHV)p per kg of mixture =
3301368
78 240 790++ = 2980 kJ/kg. (Ans.)
(ii)Air and octane vapour :
(LHV)p = 5116200 kJ/mole of C 8 H 18
For octane, the combustion equation is written as follows :
C 8 H 18 (g) + 12.5O 2 (g) → 8CO 2 (g) + 9H 2 O(g) + 12.5
79
21
F
HG
I
KJ N^2 (g)
(LHV)p per kg of mixture =^5116200
12 8 18 1 12 5 32 12 5^79
21
()..×+ × + × + × × 28
=
5116200
114 400 1317++ = 2794 kJ/kg. (Ans.)
(HHV)p = (LHV)p + mhfg
m = 9 × 18 = 162 kJ/kg mole of fuel
∴ (HHV)p = 5116200 + 162 × 2442 = 5511804
Hence, (HHV)p per kg of mixture =
5511804
114 400 1317++ = 3010 kJ/kg. (Ans.)