Answer:
a. The fuel formula is C10H20 (dec-1-ene)
b. The heat given-off to the cooling system of the reactor represents the Higher Heating Value (HHV) of the gaseous hydrocarbon fuel
c. LHV = 44.36 KJ/kg
d. ΔH (formation) = -6669.6 KJ/mol
Step-by-step explanation:
Molecular weight = 140, Molar H/C ratio = 2.0
a) To determine the fuel formula, we represent the information we have as equations
Molecular weight of C = 12, Molecular weight of H = 1
CxHy = 140g
12 · x + 1 · y = 140 ·········Eqn 1
y = 2x ·········Eqn 2
Substitute y = 2x into Eqn 1, we have:
12 (x) + 1 (2x) = 140
12x + 2x = 140
14x = 140
x = 10
Substitute x into Eqns 2, we have:
y = 2 x 10 = 20
∴ the fuel formula is C10H20 (dec-1-ene)
b) The heat given-off to the cooling system of the reactor represents the Higher Heating Value (HHV) of the gaseous hydrocarbon fuel . HHV refers to the amount of heat given-off in the combustion of a specified amount of fuel which was initially at 25°C and cooled back to a temperature of 25°C.
c) We will use LHV formula given as:
LHV = HHV – [2.441 (0.09H + M) ÷ 1000]
where:
LHV = lower heating value of fuel in MJ/kg
HHV = higher heating value of fuel in MJ/kg
M = Weight % of moisture in fuel
H = Weight % of hydrogen in fuel
HHV = 47.5 MJ/kg, M = 0, H = mass of hydrogen ÷ total mass of fuel
⇒ H = 20 ÷ 140 = 0.143 * 100 = 14.3 kg per 100 kg, Latent heat of steam (at 25°C) = 2441 KJ/kg
LHV = 47.5 - [2441 * (0.09 * 14.3 + 0) ÷ 1000]
LHV = 47.5 - 3.14 = 44.36
LHV = 44.36 KJ/kg
d) To get the enthalpy of the combustion of the fuel, we have:
fuel + air - - - - > carbon dioxide + water
C10H20 + 15 O2 - - - - > 10 CO2 + 10 H20
Enthalpy (formation) = Enthalpy (product) - Enthalpy (reactant)
ΔH (CO2) = -393.5 kJ/mol, ΔH (H2O) = -285.8 kJ/mol, ΔH (C10h20) = - 123.4KJ/mol
ΔH (formation) = 10 * (-393.5) + 10 * (-285.8) - (-123.4)
ΔH (formation) = -3935 - 2858 + 123.4
ΔH (formation) = -6669.6 KJ/mol