Page 67 - Coulson Richardson's Chemical Engineering Vol.6 Chemical Engineering Design 4th Edition
P. 67
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CHEMICAL ENGINEERING
Solution
Reaction: C 2 H 4 C Cl 2 ! C 2 H 4 Cl 2
Stoichiometric factor 1.
mols DCE produced ð 1
Overall yield (including physical losses) D ð 100
mols ethylene fed
94
D ð 100 D 94 per cent
100
mols DCE produced
Chemical yield (reaction yield) D ð 100
mols ethylene converted
94
D ð 100 D 94.5 per cent
99
The principal by-product of this process is trichloroethane.
2.14. RECYCLE PROCESSES
Processes in which a flow stream is returned (recycled) to an earlier stage in the processing
sequence are frequently used. If the conversion of a valuable reagent in a reaction process
is appreciably less than 100 per cent, the unreacted material is usually separated and
recycled. The return of reflux to the top of a distillation column is an example of a
recycle process in which there is no reaction.
In mass balance calculations the presence of recycle streams makes the calculations
more difficult.
Without recycle, the material balances on a series of processing steps can be carried
out sequentially, taking each unit in turn; the calculated flows out of one unit become
the feeds to the next. If a recycle stream is present, then at the point where the recycle
is returned the flow will not be known as it will depend on downstream flows not yet
calculated. Without knowing the recycle flow, the sequence of calculations cannot be
continued to the point where the recycle flow can be determined.
Two approaches to the solution of recycle problems are possible:
1. The cut and try method. The recycle stream flows can be estimated and the calcu-
lations continued to the point where the recycle is calculated. The estimated flows
are then compared with the calculated and a better estimate made. The procedure
is continued until the difference between the estimated and the calculated flows is
within acceptable limits.
2. The formal, algebraic, method. The presence of recycle implies that some of the
mass balance equations will have to be solved simultaneously. The equations are
set up with the recycle flows as unknowns and solved using standard methods for
the solution of simultaneous equations.
With simple problems, with only one or two recycle loops, the calculation can often be
simplified by the careful selection of the basis of calculation and the system boundaries.
This is illustrated in Examples 2.4 and 2.13.
