Simulation of the forging process incorporating strain-induced phase transformation using the finite volume method (Part II; Effects of strain rate on structural change and mechanical behavior)

被引：0

作者：

Ding, P. ^{[1
]}

Ju, D.-Y. ^{[1
]}

Inoue, T. ^{[1
]}

Imatani, S. ^{[1
]}

De Vries, E. ^{[1
]}

机构：

[1] Technical Division, MSC.Software Japan Ltd., 2-39, Akasaka 5-Chome, Minato-ku, Tokyo, Japan

来源：

| 2001年 / Society of Materials Science Japan卷 / 07期

关键词：

Austenitic transformations - Computer simulation - Finite volume method - Metal extrusion - Plastic flow - Stainless steel - Strain rate;

D O I：

暂无

中图分类号：

学科分类号：

摘要：

In Part I, based on the framework of metallo-thermo-mechanics, a finite volume method formulated in the Eulerian description has been set up to simulate the forging process and corresponding strain-induced austenitic-martensite phase transformation. The approach has been developed and implemented in the commercial computer program MSC.SuperForge. In this paper, numerical simulations for SUS304 stainless steel on backward and forward extrusions are carried out in order to verify the method proposed in Part I. Furthermore, the effects of strain rate on the austenitic-martensite phase transformation and the aggregate flow stress are studied.

引用

共 11 条

[1] Simulation of the forging process incorporating strain-induced phase transformation using the finite volume method (Part II; effects of strain rate on structural change and mechanical behavior)
Ding, PR
Ju, DY
Inoue, T
Imatani, S
de Vries, E
MATERIALS SCIENCE RESEARCH INTERNATIONAL, 2001, 7 (01): : 27 - 33
[2] Forging process simulation incorporating strain-induced phase transformation by the finite volume method
Ding, P
Inoue, T
Imatani, S
Ju, DY
de Vries, E
SIMULATION OF MATERIALS PROCESSING: THEORY, METHODS AND APPLICATIONS, 2001, : 103 - 108
[3] Simulation of the forging process incorporating strain-induced phase transformation using the finite volume method (Part I; basic theory and numerical methodology)
Ding, PR
Inoue, T
Imatani, S
Ju, DY
de Vries, E
MATERIALS SCIENCE RESEARCH INTERNATIONAL, 2001, 7 (01): : 19 - 26
[4] Finite element simulation on strain-induced martensitic transformation effects in TRIP steel sheet forming
Dan, W. J.
Zhang, W. G.
Li, S. H.
Lin, Z. Q.
COMPUTATIONAL MATERIALS SCIENCE, 2007, 39 (03) : 593 - 599
[5] Study of the Dynamic Strain-Induced Transformation Process of a Low-Carbon Steel: Experiment and Finite Element Simulation
He, Lei
Ruan, Ruijie
Lin, Chen
Dai, Ting
Hu, Xianjun
Krakauer, Bruce W.
Zhu, Mingfang
ADVANCES IN MATERIALS SCIENCE AND ENGINEERING, 2016, 2016
[6] Quasi-adiabatic effects during the high strain rate deformation of dispersed-phase systems with strain-induced martensitic transformation
De Cooman, BC
Samek, L
Mahieu, J
Van Slycke, J
Verleysen, P
Degrieck, J
Lin, L
Wang, L
Wei, XC
Peng, S
AUSTENITE FORMATION AND DECOMPOSITION, 2003, : 537 - 548
[7] Plastic deformation of polyethylene and ethylene copolymers - Part II Heterogeneous crystal slip and strain-induced phase change
Seguela, R
Elkoun, S
Gaucher-Miri, V
JOURNAL OF MATERIALS SCIENCE, 1998, 33 (07) : 1801 - 1807
[8] Plastic deformation of polyethylene and ethylene copolymers: Part II Heterogeneous crystal slip and strain-induced phase change
R Seguela
S Elkoun
V Gaucher-Miri
Journal of Materials Science, 1998, 33 : 1801 - 1807
[9] Strain-induced structural transformation of single-phase Al-Cu-Fe icosahedral quasicrystal during mechanical milling
Mukhopadhyay, N. K.
Ali, F.
Srivastava, V. C.
Yadav, T. P.
Sakaliyska, M.
Surreddi, K. B.
Scudino, S.
Uhlenwinkel, V.
Eckert, J.
PHILOSOPHICAL MAGAZINE, 2011, 91 (19-21) : 2482 - 2490
[10] EFFECTS OF STRAIN STATE AND STRAIN RATE ON DEFORMATION-INDUCED TRANSFORMATION IN 304 STAINLESS-STEEL .1. MAGNETIC MEASUREMENTS AND MECHANICAL-BEHAVIOR
HECKER, SS
STOUT, MG
STAUDHAMMER, KP
SMITH, JL
METALLURGICAL TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE, 1982, 13 (04): : 619 - 626

← 1 2 →