Finite Element Simulation of Nanostructuring Burnishing / Kuznetsov V. P.,Smolin I. Yu.,Dmitriev A. I.,Konovalov D. A.,Makarov A. V.,Kiryakov A. E.,Yurovskikh A. S. // PHYSICAL MESOMECHANICS. - 2013. - V. 16, l. 1. - P. 62-72.

ISSN/EISSN:

1029-9599 / нет данных

Type:

Article

Abstract:

Dynamics simulation of burnishing of a thin steel layer beneath an indenter applied with a constant force and then moving with a constant velocity was performed by the finite element method in the plane strain approximation. The indenter was modeled by a perfectly rigid body, and the steel was modeled by an elastoplastic body with isotropic hardening according to an experimentally defined law. The regularities of changes in the stress-strain state of the material near the treated surface were studied and mechanisms of the formation of a nanostructured layer were disclosed. The effect of the friction coefficient and the burnishing force on the height of a bulge of edged material was analyzed. The results of studies agree well with experimental data.

Author keywords:

nanostructuring burnishing; surface layer; finite element simulation; cyclic alternate action BALL; STEEL; DEFORMATION; LAYER; TOOL

DOI:

10.1134/S1029959913010074

Web of Science ID:

ISI:000318609300007

Соавторы в МНС:

Другие поля

Поле	Значение
Month	JAN
Publisher	SPRINGER
Address	233 SPRING ST, NEW YORK, NY 10013 USA
Language	English
Keywords-Plus	BALL; STEEL; DEFORMATION; LAYER; TOOL
Research-Areas	Mechanics; Materials Science
Web-of-Science-Categories	Mechanics; Materials Science, Characterization \& Testing
Author-Email	smolin@ispms.tsc.ru
ResearcherID-Numbers	Dmitriev, Andrey/D-6611-2014 Smolin, Igor/N-8345-2013 Makarov, Aleksey/D-5663-2016 Коновалов, Дмитрий/E-9029-2016
ORCID-Numbers	Smolin, Igor/0000-0003-3167-9530 Makarov, Aleksey/0000-0002-2228-0643 Коновалов, Дмитрий/0000-0002-8255-0457 Kuznetsov, Viktor/0000-0001-8949-6345
Funding-Acknowledgement	program of the Department of Energy, Engineering, Mechanics {[}09-T-1-1002, 13.3]; Control Processes RAS {[}13]; integration project of SB RAS {[}127]; RFBR grant {[}11-08-01025-a]
Funding-Text	The work was partially support by project Nos. 09-T-1-1002 and 13.3 under program of the Department of Energy, Engineering, Mechanics, and Control Processes RAS No. 13, integration project of SB RAS No. 127, and RFBR grant No. 11-08-01025-a.
Number-of-Cited-References	32
Usage-Count-Since-2013	19
Journal-ISO	Phys. Mesomech.
Doc-Delivery-Number	139UC