"Control of Continuous Tandem Cold Metal Rolling Process" is a complex multivariable control process involving continuous cold rolling of metal strip. The following is a detailed analysis of this process:
I. Process Overview
In the continuous tandem cold rolling process, the metal strip is rolled through a series of motor-driven working rolls, each supported by larger support rolls, gradually pressing the strip to the required thickness. The process is highly nonlinear and multivariable, and there are many engineering challenges in the control process.
II. Control Challenges
Multivariable Complexity: The process involves multiple variables that affect each other, such as roll speed, pressure, temperature, and the material and thickness of the strip, which increases the difficulty of control.
Dynamic Changes: During the rolling process, the rolling speed will change and the product characteristics will change rapidly, which requires the control system to respond quickly and adjust the relevant parameters.
Thickness and Hardness Disturbances: During the cold rolling process, the thickness and hardness of the strip may be affected by multiple disturbances, which will affect the quality and thickness accuracy of the final product.
Control strategies
To address these challenges, researchers and engineers have developed a variety of control strategies, including the state-dependent Riccati equation approach. This approach has achieved remarkable success in stand-alone cold rolling processes and shows similar potential in continuous tandem cold rolling.
Technical details
State-dependent Riccati equation: This approach achieves precise thickness control by calculating the optimal control input in real time and adapting to changes in system state.
Simulation verification: New control strategies are usually tested in a simulation environment to verify their effectiveness and reliability in actual applications.
Performance optimization: The control accuracy and efficiency of the cold rolling process can be further improved by continuously optimizing control parameters and algorithms.
Application examples
In actual applications, continuous tandem cold rolling mills are widely used to produce a variety of high-quality cold-rolled steel plates and strips. Through precise thickness and shape control, the final product is ensured to meet strict tolerance requirements and have good surface quality and mechanical properties.
VI. Conclusion
In summary, "Control of Continuous Tandem Cold Metal Rolling Process" is a complex and important industrial process, and its control strategies and technologies are of great significance to improving product quality and production efficiency. With the continuous advancement of control theory and technology, more innovative control methods will be applied to this field in the future.
The tandem cold rolling process involves passing a metal strip through a series of independently driven work roll pairs, each supported by a larger diameter backup roll. Figure 1 shows a typical five-stand cold rolling process. As the strip passes through each work roll pair, the thickness of the strip is gradually reduced due to extremely high compressive stresses in the small area between the rolls, i.e., the roll bite. The necessary compressive force is applied by a screw device driven by a hydraulic cylinder or an electric motor.
Process instrumentation monitors the rolling force of each mill stand, the strip tension between adjacent mill stands, the strip thickness at the mill entry and at the exit of the first and last stands, the position signals of the work roll position actuators (hydraulic cylinders or screws), and the speed of the work rolls.
Unlike independent mills, which stop rolling when changing coils, strip is continuously fed into the mill from the upstream process through a strip storage device to achieve uninterrupted rolling. At the entrance of the upstream process, the incoming coil is welded to the coil being processed. As the weld approaches the mill, the mill speed is reduced to reduce the risk of strip breakage as the weld passes and to keep within the required cutting speed range of the shear.
Once the weld leaves the mill and reaches the shear, it is cut and the separated strip head is directed to an available rewinding device, with the pinch rolls closed to maintain tension during the rapid transfer. When tension is established, the pinch rolls open and the mill is accelerated to the required operating speed.