Dynamics Modelling of Film Motion at Unit for of Polymeric Film Material Production

New effective dynamic models for motion of polymeric film have been proposed in the paper. These models in contrast to known ones take in to account deformation processes which occur at a unit for polymer-film materials production. It has been shown that the deformation process of a polуmer film in intersectional area determined by its tension depends on ratio of linear section velocities and tension and deformation values in these sections. An analysis of the proposed dynamic models of polymer film motion has shown that a decrease in its deformations in every zone of the unit can be achieved both by changing ratio of input and output velocities and introducing a compensator for perturbing influences due to deformations of the film at the entrance to the zone. Possible channels for automatic control of the unit for polymer-film material production have been identified with the aim of improving quality of products. While using the proposed dynamic models it has been demonstrated that it is necessary to apply systems for automatic measuring of section rotation speed and film tension in the unit for polymer-film material production in order to ensure effective control over an extrusion process. The proposed dynamic model can be efficiently used to create an adaptive system which is applied to control a multi-motor drive of the unit for of polymer-film material production.

1. Sheryshev M. A. (2011) Production of Items From Polymer Sheets and Films. Moscow, Nauchnye Osnovy i Tekhnologii Publ. 556 (in Russian).

2. Evdokimov V. V. (1992) Equipment and Mechanization of Production for Polymer Film Materials and Artificial Leather. Moscow, Legprombytizdat Publ. 272 (in Russian).

3. Lukach Yu. E., Petukhov A. D., Senatos V. A. (1981) Equipment for Production of Polymer films. Moscow, Mashinostroyenie Publ. 222 (in Russian).

4. Kryzhanovsky V. K., Kerber M. L., Burlov V. V. (2008) Production of Items from Polymer Materials. Saint-Petersburg, Professiya Publ. 464 (in Russian).

5. White J., Choi D. (2006) Polyethylen, Polypropylene and Other Polyolefins. Saint-Petersburg, Professiya Publ. 240 (in Russian).

6. Abdel-Bary E. M., Zaikov E. G. (2010) Polymer FIlms. Technologies of Production, Destruction and Stabilization, Application and Recycling. Saint-Petersburg, Professiya Publ. 352 (in Russian).

7. Lebedeva T. M. (2009) Extrusion of Polymer Films and Sheets. Saint-Petersburg, Professiya Publ. 216 (in Russian).

8. Airapetiants G. M., Akulich A. V., Ulianov N. I. (2012) Modernization of Automatic Regulation Systems for Technological Processes. Mogilev, Publishing House of Mogilev State University of Food Technologies. 322 (in Russian).

9. Airapetiants G. M., Yastremsky Yu. N. (1980) Control Method for Process to Obtain Viscose Film Casing: Inventor’s Certificate 712411 USSR.

10. Airapet'yants G. M., Ul'yanov N. I., Kozhevnikov M. M., Yasnitskii V. V. (2014) Development of Mathematical Model for Dynamics of Polymer Film Motion in Unit of Polymer-Film Materials. Vestnik Mogilevskogo Gosudarstvennogo Universiteta Prodovol'stviya [Bulletin of Mogilev State University of Food Technologies], 17 (2), 105–110 (in Russian).