Question 18.4: Estimate the heat transfer rate required to heat low-pressur...
Estimate the heat transfer rate required to heat low-pressure gaseous carbon tetrachloride (\text{CCl}_4) from 500. to 1200. \text{K} in a steady state, steady flow, single-inlet, single-outlet, aergonic (i.e., zero work) process at a flow rate of 1.00 \text{kg/min}.
\text{}The system here is just the gas in the heating zone. Neglecting the flow stream kinetic and potential energies, the energy rate balance for this system reduces to
\dot{Q} + \dot{m} (h_\text{in} − h_\text{out}) = 0
so that
\dot{Q} = \dot{m} (h_\text{in} − h_\text{out}) = \dot{m}c_p (T_\text{out} − T_\text{in})
For \text{CC1}_4, b = 5; consequently, F = 3b = 15. Then, Eq. (18.28) gives
c_p = R+ c_v = (1 + \frac{F}{2}) R (18.28)
c_p = (1 + 15/2)R = 8.5 × R
Now, the molecular mass of carbon tetrachloride is
M = 12.0 + 4(35.5) = 154 \text{kg/kgmole}
and its gas constant is
R = \frac{ℜ}{M} = \frac{8.3143 \text{kJ/(kgmole.K})}{154 \text{kg/kgmole}} = 0.0540 \text{kJ/(kg.K)}
so
c_p = 8.5 [0.0540 \text{kJ/(kg.K)}] = 0.459 \text{kJ/(kg.K)}
Therefore,
\dot{Q} = (1.00 \text{kg/min}) [0.459 \text{kJ/(kg.K)}] (1200. − 500. \text{K}) = 321 \text{kJ/min}