A survey of grinding circuit control methods: from decentralized PID controllers to multivariable predictive controllers

A conventional grinding circuit consisting of one open-loop rod mill and on e closed-loop ball mill is essentially a two-inputX two-output system, assu ming that the classifier pump box level is controlled by a local loop. The inputs are the ore and water feed rates and the outputs are the product fin eness and the circulating load. The design problem is to find a control alg orithm and a tuning procedure which satisfy specified servo and regulatory robust performances. A first approach is to use decentralized PID controlle rs and systematic tuning methods which take into account loop interactions. Another technique consists of adding decouplers or pseudo-decouplers to th e decentralized controllers. Finally, the design of a fully multivariable c ontroller is a possible option. To face the problem of performance robustne ss related to change of process dynamics, two options are studied. A design criterion involving the minimization of a penalized quadratic function on a future trajectory can be used. A second alternative is to track process d ynamics changes using adaptive process modelling. The paper will present a comparison of these various strategies, for a simulated grinding circuit. A benchmark test, involving a sequence of disturbances (grindability, feed s ize distribution, change of cyclone number...) and setpoint changes, is use d to compare the performances of the controllers. (C) 2000 Elsevier Science S.A. All rights reserved.