Журналы →  CIS Iron and Steel Review →  2019 →  №2 →  Назад

Rolling and Metal Forming
Название Study of kinematics of elastic-plastic deformation for hollow steel shapes used in energy absorption devices
DOI 10.17580/cisisr.2019.02.06
Автор D. B. Efremov, A. A. Gerasimova, S. M. Gorbatyuk, N. A. Chichenev
Информация об авторе

National University of Science and Technology “MISiS” (Moscow, Russia)

D. B. Efremov, Cand. Eng., Associate Prof., Dept. of Metal Forming
A. A. Gerasimova, Cand. Eng., Associate Prof., Dept. of Engineering of Technological Equipment, e-mail: gerasimova.aa@misis.ru
S. M. Gorbatyuk, Dr. Eng., Prof., Head of Dept. of Engineering of Technological Equipment
N. A. Chichenev, Dr. Eng., Prof., Dept. of Engineering of Technological Equipment, e-mail: chich38@mail.ru

Реферат

The paper presents the study of kinematics of elastic-plastic deformation of hollow steel shapes. This study was aimed on improvement of the force parameters in plastic deformation processes of energy absorbing construction components of hollow shapes used in transport vehicles and rise of passive safety and reliability of technical equipment. Finite element modeling (FEM) of kinematics of the processes was conducted with control of energy absorbing parameters of steel tubes with different cross sections. Specific absorbing energy of all tested tubes was calculated using QForm program for imitation of technological processes as well as for analysis of power characteristics of plastic destruction of manufactured products and essential variation of their shape. The presented results of virtual investigations of bending and upsetting in an edge of a row of hollow shapes as tubes with different cross sections displayed wide possibilities for control and management of absorption process of mechanical energy via choosing the tube design and control of simulation results of energy absorption as well as maximal force on indicating diagram of deformation process. The results of testing testified that rectangular tube of 30×70 mm cross section absorbed more energy in comparison with tubes of other cross sections. However, bending of this tube was accompanied by ultimately high force value in the beginning of deformation, what means high value of object acceleration during its impact. On the contrary, force value decreased sharply at the finishing deformation stage, what increases the risk of deterioration in protected space of an object. Additional possibilities of improvement of functional properties of hollow components presented by tubes with longitudinal dikes were revealed; their usage allows to rise safety of transport vehicles, technological machines and equipment.

Ключевые слова Shapes, deformation, bending, specific absorbing energy, tools, simulation, equipment
Библиографический список

1. WorldAutoSteel. ULSAB. Available at: https://www.worldautosteel.org/projects/ulsab/ (date: 01.02.2019).
2. Bosh R. Automobile directory (translated from English). Мoscow. «Za rulem». 2000. 896 p.
3. Regulations No. 94 of UN European Economic Commission (document E/ECE/324/Rev.1/Add.93/Rev.1 − E/ECE/
TRANS/505). Common prescriptions regarding official approval of transport vehicles meaning protection of driver and passengers in the case of frontal crash. UN. 2007. 86 p.
4. Beng Y. K., Dalimin M. N. et al. Plastic collapse and energy absorption of empty circular aluminum tube under transverse quasi-static loading. J. of Mechanical Science and Technology. 2018. Vol. 32(8). pp. 3611–3616.
5. Gerasimova A. A., Keropyan A. M., Girya A. M. Study of the Wheel-Rail System of Open-Pit Locomotives in Traction Mode. Journal of Machinery Manufacture and Reliability. 2018. Vol. 47(1). pp. 35–38.
6. In sicherer, Leichter Huelle. Die Fahrgastzelle der Zukunft: Strukturen in Spant- und Space-Frame-Bauweise. URL: https://www.dlr.de/Portaldata/1/Resources/standorte/stuttgart/bilder/DLR-Nachrichten-123-Spant-Space-Frame.pdf (accessed: 01.02.2019).
7. Haldenwanger H. G. Zum Einsatz alternativer Werkstoffe und Verfahren im konzeptionellen Leichtbau von Pkw-Karosserien: Dissertation, Tu Dresden, 1997. 102 p.
8. Zarapin A. Yu., Shur A. I., Chichenev N. A. Improvement of the unit for rolling aluminum strip clad with corrosion-resistant steel. Steel in Translation. 1999. Vol. 29(10). pp. 69–71.
9. Gudim Yu. A., Zinurov I. Yu., Kiselev A. D. et al. Rational methods for the intensification of melting in modern arc steelmelting furnaces. Russian metallurgy (Metally). 2008. No. 8. pp. 651–654.
10. Kobelev O. A., Tsepin M. A., Skripalenko M. M. et al. Features of technological layout of manufacture of unique monoblock large-dimension plates. Advanced Materials Research. 2009. Vol. 59. pp. 71–75.
11. S. Lindner. The prospects of decrease of car body weight by usage of Cr–Mn steels. Chernye metally. 2016. No. 5. pp. 65–70.
12. Raedt H.-V., Wilke F., Ernst Ch.-S. Opportunities of mass decreasing in automotive industry. Chernye metally. 2016. No. 6. pp. 61–69.
13. Anderson D. Bright prospects of steel application in automobiles. Chernye metally. 2016. No. 8. pp. 59–67.
14. Wormald T., Schneider N., Gibeau E. Steel provides lightweight construction for pickup automobiles. Chernye metally. 2018. No. 10. pp. 55–58.
15. Danchenko V. N., Kolikov A. P., Romantsev B. A. Technology of tubmeking. Мoscow. Intermet Inzhiniring. 2002. 640 p.
16. Matveev B. N., Nikitina L. A. Current state and prospects of tubemaking in Russia and abroad. Proizvodstvo prokata. 1999. No. 12. pp. 28–32.
17. Gorbatyuk S. M., Gerasimova A. A., Radyuk A. G. Using the Coating for the Diffusion Layer Obtaining on the Walls of the Mold (CCM). Metallurgical and mining industry. 2015. No. 9. pp. 1085–1088.
18. Bondarev B. I. Shapes for special applications made of aluminium and magnesium alloys. Мoscow: Metallurgiya. 1980. 215 p.
19. Keropyan A. M., Gerasimova A. A. Connection between the temperature in the contact area “wheel — rail” system and slope of railroad for industrial railway transport. Izvestiya vuzov. Chernaya metallurgiya. 2017. Vol. 60. No. 5. pp. 355–363.
20. Sidelnikov S. B. Dovzhenko N. N. Voroshilov S. F., Eshkin A. V. Study of combined rolling-extrusion process. Tekhnologiya legkikh splavov. 1993. No. 5. pp. 41–44.
21. Gorbatyuk S. M., Pavlov V. M., Shapoval A. N. et al. Experimental use of rotary rolling mills to deform compacts of refractory metals. Metallurgist. 1998. Vol. 42. pp. 178–183.
22. Gorbatyuk S., Kondratenko V., Sedykh L. Tool stability analysis for deep hole drilling. MATEC Web of Conferences. 2018. Vol. 224. Article No. 01035. DOI: 10.1051/matecconf/201822401035.
23. Kislov V. M. Finite elements method. Methodical recommendations for practical studies. Vladimir. Izd. Vladimirskogo politekhnicheskogo instituta. 1982. 44 p.
24. Kislov V. M. Determination of physical and geometrical parameters of constructions based on the finite elements method. Vladimir. Izd. Vladimirskogo politekhnicheskogo instituta. 1994. 88 p.
25. QForm VX. URL: https://www.qform3d.com/products/qform (accessed: 01.02.2019).

Полный текст статьи Study of kinematics of elastic-plastic deformation for hollow steel shapes used in energy absorption devices
Назад