Roll Speed and Roll Gap Control with Neural Network Compensation

Abstract: In this paper the detailed procedure of roll speed and roll gap control strategy development for a laboratory scale rolling mill is given. The core of the control strategy is the incorporation of feed-forward compensations based on neural network models for the roll force and roll torque, which are the major disturbances introduced during the rolling operation. An integrated computer simulation model is developed to investigate the performance of the proposed control strategies, and results show significant im… Show more

“…The model parameters, such as the inertia, the stiffness of the shafts and the frictions of the individual components are supposed to be known and constant (Mahfouf et al, 2005).…”

Actuator Fault Detection, Isolation Method and State Estimator Design for Hot Rolling Mill Monitoring

“…The model parameters, such as the inertia, the stiffness of the shafts and the frictions of the individual components are supposed to be known and constant (Mahfouf et al, 2005).…”

Actuator Fault Detection, Isolation Method and State Estimator Design for Hot Rolling Mill Monitoring

“…The model parameters, such as the inertia, the stiffness of the shafts and the frictions of the individual components are supposed to be known and constant (Mahfouf et al, 2005). According to the sensors available on the experimental hot rolling Hille mill, a roll speed discrete state space representation can be established as follows: faulty case, the roll speed discrete state space representation becomes as:…”

“…As illustrated in Fig. 2, based on the roll torque estimation performed by a multilayer neural network model (Mahfouf et al, 2005), a feedforward control loop is cancelling its effects upon the roll speed to achieve a fast speed response and to have better disturbance rejection ability coming from the load torque fluctuation during rolling. …”

Actuator/Sensors Fault Diagnosis for an Experimental Hot Rolling Mill - A Case Study

“…(1) Systematic function structure of dynamic over-welding strategy Figure 4 presents the systematic function structure of dynamic over-welding process, where, G is the implementation inner seam of roll gap; B is the implementation inner seam of bending force; G SET is the over-welding roll gap giver; B SET is over-welding bending force giver; TMi is the ith stand outlet tension detector [13,14].…”

Research on the Comprehensive Control Strategy of Over-welding Based on Decoupling- Design for Tandem Cold Mills