Abstract An interconnected chemical or metallurgical plant is viewed as a combination of separators, reactors and mixers. The operation of these units may be described in terms of non-linear split factors, conversions and yields. The mass balance coefficient matrix may be transformed into an M-Matrix. Ostrowski's inequality may then be used to provide linear inequalities based on the row sums of the transformed coefficient matrix. The production rates of components are “quasi” monotonic with regard to these row sums. The mass balance equations, together with the inequalities may be transformed into linear constraints for use in either Parametric Linear or Non-Linear Programming. If split factors, conversions and yields are independant, then Parametric L. P. may be used directly. If dependant, however, the row sums are useful parameters which may be used to improve objective functions depending monotonically on production rate in Non-Linear systems. The method has been applied to a flotation plant where production is maximised using L. P.
[1]
Atsunobu Ichikawa,et al.
Synthesis of optimal processing system by an integrated approach
,
1972
.
[2]
L. T. Fan,et al.
Synthesis of an optimal large‐scale interconnected system by structural parameter method coupled with multilevel technique
,
1973
.
[3]
M. J. Bush,et al.
Optimal synthesis of waste treatment plants
,
1978
.
[4]
H. P. Hutchison,et al.
Process optimisation using linear models
,
1980
.
[5]
L. T. Fan,et al.
Optimal synthesis of process systems Necessary condition for optimal system and its use in synthesis of systems
,
1973
.
[6]
P. A. Cook.
Estimates for the inverse of a matrix
,
1975
.
[7]
James C.A. Green.
The design of a flotation network using inequalities
,
1982
.