ArticleName |
Calculation and experimental technique for evaluating the parameters of the contact interaction
of a strip billet with a roll tool in the ERW mill lines |
ArticleAuthorData |
National University of Science and Technology “MISiS”, Moscow, Russia:
S. V. Samusev, Dr. Eng., Prof., Metal Forming Dept. V. A. Fadeev, Post-Graduate, Metal Forming Dept., e-mail: fdv_viktor@mail.ru A. S. Budnikov, Cand. Eng., Associate Prof., Metal Forming Dept. M. B. Savonkin, Cand. Eng., Associate Prof., Metal Forming Dept. |
Abstract |
A technique for determining the areas of contact surfaces for the lower and upper roll tools is presented. The study of contact surfaces was carried out on contact prints obtained as a result of the experiment. The drawbacks of the existing method of fixing the imprints of contact surfaces, in which the contact of the strip (tubular billet) with the rolls was determined through the paper, were analyzed and taken into account. A technique for fixing contact prints is proposed, in which there is a direct contact of the strip with the rolls. Parameters of the obtained contact prints of the strip with the lower and upper rolls for all forming stands electric of ERW mill 30–50 were measured. As a result of measurements of contact prints, additional parameters of the boundaries of contact surfaces are introduced. For the bottom and top rolls, the length of the contact was taken along the bottom and the flange of the roll, respectively. It was found that, in the first approximation, the contact surfaces can be rather exactly approximated by a power function. The internal contact surfaces of the strip with the upper rolls were approximated using a decreasing power function, while the external ones with the lower rolls — using an increasing power function. On the basis of experimental data and analysis of indentation parameters, a technique has been developed for determining the contact surfaces of a strip with lower and upper rolls of various configurations. The input boundary of the contact surface was determined by the shape index m. Comparison of the input boundaries of the contact surfaces obtained in the experiment and by the technique shows a high convergence. |
References |
1. Kolikov A. P., Zvonarev D. Yu., Taupek I. M., Sidorova T. Yu. Mathematical simulation of strip plastic deformation process in the whole technological stage of manufacture of large-diameter tubes. Chernye Metally. 2017. No. 7. pp. 41–45. 2. Odesskiy P. D., Gurov S. V., Arsenkin A. M., Gizatullin A. B., Bragin A. A., Titkin А. А. Electric resistance longitudinal-welded highstrength tubes for responsible building constructions. Stal. 2016. No. 7. pp. 73–81. 3. Lifanov V. Ya. Tube industru today and tomorrow. Materials of 23rd International Scientific-Practical conference “Tubes-2018”. Chernye metally. 2018. No. 12. pp. 78–81. 4. Ilyichev V. G. Efficiency of modern production technologies and quality of large-diameter pipes. Chernye metally. 2019. No. 9. pp. 17–24. 5. Zhigulev G. P., Skripalenko M. N., Fadeev V. A. et al. Correction to: Modeling of deformation zone during plate stock molding in three–roll plate bending machine. Metallurgist. 2020. Vol. 64. p. 848 (2020). DOI: 10.1007/s11015–020–01062–0. 6. Kolikov A. P., Zvonarev D. Yu., Taupek I. M. Modeling of the stress–strain state of a metal during plastic forming of a sheet blank and welding of large diameter pipes. Report 1. Chernye Metally. 2020. No. 2. pp. 33–40 7. Frunkin D., Gurevich L., Novikov R., Bannikov A., Serov A., Dyatlov N. Welded pipe geometry changing during the expanding process. IOP Conference Series: Materials Science and Engineering. 2018. 450. 032048. DOI: 10.1088/1757-899X/450/3/032048. 8. Jiaojiao Cheng, Jianguo Cao, Jianwei Zhao, Jiang Liu, Rongguo Zhao, Shiquan Liu. The flower pattern and rolls design for ERW pipes with the different specification in the flexible roll forming process. Thin-Walled Structures. 2020. Vol. 154. No. 106809. DOI: 10.1016/j.tws.2020.106809. 9. Tovmasyan M. A., Samusev S. V. Effect of the Nonuniform Distribution of the Mechanical Properties of Rolled Sheets on the Shape of a Round Billet after Forming in Making Large–Diameter Pipes. Russ. Russian Metallurgy (Metally). 2020. pp. 589–596. DOI: 10.1134/S0036029520050158 10. Shinkin V. N. Analytical calculation of steel billet’s shape at production of large diameter pipes on presses of TESA 1020. Chernye metally. 2020. No. 3. pp. 31–35. 11. Li J. -X., Xie L. -Y., Wang J. -J. et al. Numerical study of the forming process of high frequency welded pipe. J. Shanghai Jiaotong Univ. (Sci.). 2010. Vol. 15. pp. 236–240. DOI: 10.1007/s12204-010-8131-9. 12. Kasaei M. M., Moslemi Naeini H., Salmani Tehrani M., Azizi Tafti R. Numerical and experimental investigation of strip deformation in cage roll forming process for pipes with low ratio of thickness/diameter. AIP Conference Proceedings. 2010. Vol. 1315. pp. 593–598. 13. Kadach M. V., Gamin Yu. V., Solonin A. N. et al. Converting highboron steel pipe from round to hexagonal cross section. Steel in Translation. 2014. Vol. 44. pp. 783–786. DOI: 10.3103/S0967091214110084. 14. Goncharuk A. V., Gamin Y. V., Sharafanenko I. K. et al. Piercing of a Billet in a Mill with Guide Disks. Russian Metallurgy (Metally). 2020. pp. 1637–1642. DOI: 10.1134/S003602952013011X. 15. Kadach M. V., Koshmin A. N., Gamin Y. V., Romantsev B. A. Obtaining steel tubular items of variable cross-section along their length. Chernye Metally. 2019. No. 4. pp. 37–41. 16. Malakhov A. Y., Saikov I. V., Denisov I. V. et al. Study of the Features of Obtaining Bimetallic Pipes and Rods by Explosion Welding with Subsequent Hot Deformation. Inorg. Mater. Appl. Res. 2020. Vol. 11. pp. 1222–1228. DOI: 10.1134/S2075113320050202. 17. Abeyrathna B., Rolfe B., Hodgson P. et al. An extension of the flower pattern diagram for roll forming. Int. J. Adv. Manuf. Technol. 2016. Vol. 83. pp. 1683–1695. DOI: 10.1007/s00170-015-7667-0. 18. Shatalov R. L., Maksimov E. A. Analysis of efficiency of asymmetric rolling technology for increase of precision of rolled strips. Metallurg. 2016. No. 7. pp. 80–84. 19. Weiye Chen, Jinmao Jiang, Dayong Li, Tianxia Zou, Yinghong Peng. Flower pattern and roll positioning design for the cage roll forming process of ERW pipes. Journal of Materials Processing Technology. 2019. Vol. 264. pp. 295–312. DOI: 10.1016/j.jmatprotec.2018.09.007. 20. Han S.-W., Park Y. C., Kim H.-K., Kang S.-C. Effect of Strain Hardening on Increase in Collapse Pressure during the Manufacture of ERW Pipe. Appl. Sci. 2020. Vol. 10. pp. 5005. DOI: 10.3390/app10145005. 21. Nguyen D. C., Efremov D. B. The method for determining the profile of large diameter pipes and the optimal technological mode during calibration–bending in the weld zone. IOP Conference Series: Materials Science and Engineering. 2020.Vol. 862. Iss. 3. 22. Iguchi K., Kuriyama Y., Moroi N., Hama T., Takuda H. Deformation behavior of high strength steel sheet during roll forming of electric resistance welded pipe. Steel Research International. 2012, Special issue. pp. 927–930. 23. Kolikov A. P., Romanenko V. P., Sheikh-Ali A. D. et al. Machines and equipment of tube production. Мoscow: MISiS. 1998. 541 p. 24. Samusev S. V., Fadeev V. A. Study of the contact interaction of a strip with work rolls during continuous scelping of welded pipes in a TESA line. Chernye Metally. 2020. No. 2. pp. 41–46. 25. Samusev S. V., Fadeev V. A. Physical simulation of continuous forming process for longitudinal-welded tubes in the area of ERW mill open roll grooves. Izvestiys vysshikh uchebnykh zavedeniy. Chernaya metallurgiya. 2019. Vol. 62. No. 7. pp. 531–538. DOI: 10.17073/0368–0797–2019–7–531–538. |