Tension controls are crucially important, both for the runnability of the machine and for the overall quality of the product. However, this control is quite often executed imperfectly or even incorrectly because of poor design or engineering. Many times the selected components themselves are good, but they are still incorrect for the specific application, or the application can be derailed by the wrong type of installation. More often than not, the controller tunes the web tension based on a poor and heavily distorted signal, or the controller output is not used in an optimal way.
The typical requirement for a tension control accuracy is 1 percent at constant speed and 2–4 percent in speed changes, based on the measured signal. But it is not unusual to see a tension signal distortion to be about 10–200 percent off. An independent reference may be difficult to obtain, and so the degree of distortion is evaluated indirectly.
There are many factors that can undermine good quality tension control; these must be accounted for when designing your application. Here is a bulleted list of things to consider when planning a tension measurement and control application. The list may not be comprehensive and is just headlines, without further explanation of the deeper meaning, as each one of those can include information worthy of a separate article. The team we work with has a long history of researching, working, and solving these issues.
Web tension control is used to improve web handling during machine speed changes and to compensate for machine directional variations of the paper. Because tension control is the outmost control loop, the response time is slow compared to that of torque control or speed control. Typically, response time of tension control is about 10 times slower than that of speed control, in the range of 10–30 s. Thus any fast process disturbances influencing the web tension, such as coating beam closing and opening or an excessive paper sheet moisturizing effect, are compensated for using a separate feedforward effect on the drive’s speed or torque reference.
Tension can exist in material, which is somewhat elastic. Optimal tension improves the runnability of the machine. Tension that is too high can have negative side effects, seen before the material breaks, so be reasonable. One of the side effects is that high tension can permanently deform the material so it loses part of its elasticity for good. In every phase of post processing the product requires typical tension, which is higher than used earlier for the material. So be careful not to distrain the whole capacity of web elasticity too early, so as to aggravate any later processing.
Last, but not least, you can hardly live without good quality tension controls. But to be honest, if the machine is well tuned and the state of changes properly compensated for, the tension controls are more or less passive observers in the background, doing minimal work. Heavy corrections from tension control indicate either poor tuning of sectional drives or insufficient compensations—or, in the worst case, controller measures based only on a distorted tension signal, as a false positive. To tune the machine well, first you need a good quality tension signal as a base for your work. Tuning tension controllers may be a later or last point of interest, though, as an overall and outermost loop of control.
Advances in load cell system technology can help improve the reliability and accuracy of these applications.
Accurate web tension measurement and control is essential to achieve high levels of quality and productivity. Modern load cell systems provide the reliability and performance required for these applications, and they are designed to function well in harsh environments.
Knowing what the tension actually is at various key points in a machine or process line is fundamental to ensuring high quality and efficient operations in all types of web converting processes. Web tension measurement and control are equally important in converting, as well as film, foil, textile, and nonwoven manufacturing.
Essentially it is the ability to dynamically control the mechanical tension in any material being processed at any point in the process phase while it is accelerating, decelerating, or at constant speed. It is required in any web handling and converting machinery to achieve production with both high and consistent quality, to achieve high productivity with the minimum of unscheduled production stops, and to increase the machine speed.
Important requirements for reliable web tension measurement and control include long-term stable sensitivity—the secret to good and reliable repeatability—robust construction to withstand real production environments, recalibration-free load cells minimizing maintenance costs, and user friendliness to minimize the time for setup and commissioning.
Tapio Talvitie is product manager in winding applications of PM Drives, working for ABB in Finland. He has 30 years of experience with sectional drives in the paper industry, working as commissioning engineer, SW application engineer, lead engineer, and now as research and development developer. He works on paper machines, winders, on-line and off-line coaters, calenders, and reelers, with a special interest in control philosophies.
Martin Ottosson is marketing communications manager for ABB product group force measurement and ABB global media relations manager for measurement and analytics. He has more than 20 years of experience in the measurement products business, mainly with force measurement in the metals and paper industries. He is author of about 100 application stories from customer sites worldwide.
Source: ISA News