金属材料本构模型的研究进展
Research Development of the Constitutive Models of Metal Materials
摘 要
介绍了金属材料加工硬化、动态回复和动态再结晶流变行为的传统本构模型; 概述了统一本构理论模型的产生、通用形式和共同特点, 并对Miller、Walker、B-P和Chaboche等几种典型的统一本构模型重点进行了介绍。
应力-应变曲线
统一本构理论模型
动态回复
动态再结晶
加工硬化
constitutive relation
stress-strain curve
unified constitutive theory model
dynamic recovery
dynamic recrystallization
work hardening
Abstract
The traditional constitutive models of working hardening, dynamic recovery and dynamic recrystallization rheological behavior of metal materials are introduced. The generation, common forms and features of unified constitutive theoretical model are summarize, and several kinds of typical models, including Miller, Walker, B-P and Chaboche models are emphatically introduced.
中图分类号 TB125 TB741
所属栏目 综述
基金项目
收稿日期 2011/3/9
修改稿日期 2011/10/3
网络出版日期
作者单位点击查看
备注彭鸿博(1972-), 男, 天津人, 讲师, 硕士。
引用该论文: PENG Hong-bo,ZHANG Hong-jian. Research Development of the Constitutive Models of Metal Materials[J]. Materials for mechancial engineering, 2012, 36(3): 5~10
彭鸿博,张宏建. 金属材料本构模型的研究进展[J]. 机械工程材料, 2012, 36(3): 5~10
被引情况:
【1】吴志荣,胡绪腾,辛朋朋,宋迎东, "基于Chaboche模型的金属材料稳态循环应力-应变曲线的本构建模方法",机械工程材料 37, 92-95(2013)
【2】陈亚军,高春瑾,杨旭东,褚玉龙, "不同温度下1Cr18Ni9Ti钢高温疲劳与蠕变的交互作用",机械工程材料 40, 93-96(2016)
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参考文献
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【32】周柏卓, 杨士杰, 聂景旭.正交各向异性材料构件粘塑性损伤寿命研究[J].航空发动机,2001(2):4-7.
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【35】HART E W. Constitutive relations for the nonelastic deformation of metals [J].Journal of Engineering Material and Technology,1976,7:193-202.
【2】LUDWIKSON D C. Modified stress-strain relation for fcc metals and alloys[J].Metall Trans,1971,2(10):2825-2828.
【3】TIAN X, ZHANG Y S. Mathematical description for flow curves of some stable austenitic steels[J].Mater Sci Eng A,1994,174:1-3.
【4】JOHSON G R, COOK W H. A constitutive model and data for metals subjected to large strains, high strain rates and high temperatures[C]// Proceedings of the Seventh International Symposium on Ballistics.The Hague, Netherlands:[s.n],1983.
【5】ZERILLI F J, ARMSTRONG R W. Description of tantalum deformation behavior by dislocation mechanics based constitutive relations[J].J Appl Phys,1990,68(4):1580-1591.
【6】ZERILLI F J, ARMSTRONG RW. Dislocation-mechanics-based constitutive relations for material dynamics calculations[J].J Appl Phys,1987,61(5):1816-1825.
【7】KHAN A S, LIANG Ri-qiang. Behaviors of three BCC metal over a wide range of strain rates and temperatures: experiments and modeling[J].International Journal of Plasticity,1999,15:1089-1109.
【8】彭建祥, 李英雷, 李大红.纯钽动态本构关系的实验研究[J].爆炸与冲击,2003,23(2):183-187.
【9】胡昌明,贺红亮,胡时胜.45号钢的动态力学性能研究[J].爆炸与冲击,2003,23(2):188-192.
【10】张宏建, 温卫东, 崔海涛, 等.不同温度下IC10 合金的本构关系[J].航空学报,2008,29(2):499-504.
【11】ZHANG Hong-jian, WEN Wei-dong, CUI Hai-tao. Behaviors of IC10 alloy over a wide range of strain rates and temperatures:experiments and modeling[J].Materials Science & Engineering A,2009,504:99-103.
【12】张宏建, 温卫东, 崔海涛, 等.Z-A模型的修正及在预测本构关系中的应用[J].航空动力学报,2009,24(6):1311-1315.
【13】ZHANG Hong-jian, WEN Wei-dong, CUI Hai-tao, et al. A study on flow behaviors of alloy IC10 over a wide range of temperatures and strain rates[C]// 2008 TMS Annual Meeting & Exhibition on Fabrication,Materials,Processing and Properties.USA, San Francisco,California: [s.n],2009.
【14】ZHANG Hong-jian, WEN Wei-dong, CUI Hai-tao, et al. A modified Zerilli-Armstrong model for alloy IC10 over a wide range of temperatures and strain rates[J].Materials Science & Engineering A,2009,527:328-333.
【15】KREUSS G. Deformation, rocessing, and structure[M].Metals Park,Ohio:ASM,1984.
【16】ZHOU M, CLODE M P. A constitutive model and its identification for the deformation characterized by dynamic recovery[J].Journal of Engineering Materials and Technology,1997,119:138-142.
【17】ZHOU M, CLODE M P. Constitutive equations for modeling flow softening due to dynamic recovery and heat generation during plastic deformation[J].Mechanics of Materials,1998,27:63-76.
【18】MUKHOPADHYAY A, HOWARD I C, SELLARS C M. Development and validation of a finite element model for hot rolling using ABAQUS/STANDARD[J].Materials Science and Technology,2004,20:1123-1133.
【19】CHO J R, JEONG H S, CHA D J, et al. Prediction of microstructural evolution and recrystallization behaviors of a hot working die steel by FEM[J].Journal of Materials Processing Technology,2005,160:1-8.
【20】KWAK H J, LEE K J, KWON O J, et al. Prediction of recrystallization behaviors in hot forging by the finite element method[J].J Korean Soc Technol Plast,1996,5(4):305-319.
【21】LAASRAOUI A, JONAS J J. Recrystallization of austenite after deformation at high temperature and strain rates analysis and modeling[J].Metallurgical Transactiongs,1991,22(1):151-160.
【22】NEDOMA J. On a coupled Stefan-like problem in thermo-visco-plastic rheology[J].Journal of Computational and Applied Mathematics,1997,84:45-80.
【23】ZHANG Hong-jian, WEN Wei-dong, CUI Hai-tao, et al. Recrystallization behaviors of alloy IC10 at elevated temperature:experiments and modeling[J].Journal of Materials Science,2011,46(4):1076-1082.
【24】ZHANG Hong-jian, WEN Wei-dong, CUI Hai-tao, et al. Study on recrystallization behaviors of alloy IC10 at elevated temperature[J].Transactions of Nanjing University of Aeronautics and Astronautics,2011,28(1):81-86.
【25】MILLER A K. Unified constitutive equations for creep and plasticity[M].America:Elsevier Applied Science Publication Ltd,1987.
【26】WALKER K P. Research and development program for nonlinear structural modeling with advanced time-temperature dependent constitutive relationships[R].[S.l.]:[s.n],1981.
【27】BODNER S R. Unified plasticity-an engineering approach[R].[S.l.]:[s.n],2001.
【28】FREED A D, CHABOCHE J L, WALKER K P. On the thermodynamics of stress rate in the evolution of back stress in viscoplasticity[R].[S.l.]:[s.n],1991.
【29】冯明珲.粘弹塑性统一本构理论[D].大连:大连理工大学,2000.
【30】周柏卓, 张晓霞, 罗焰明.正交各向异性材料粘塑性统一本构模型[J].推进技术,1998,19(1):89-93.
【31】周柏卓, 聂景旭, 杨士杰.正交各向异性材料粘塑性损伤统一本构关系研究[J]. 航空动力学报,1999,14(4):357-360.
【32】周柏卓, 杨士杰, 聂景旭.正交各向异性材料构件粘塑性损伤寿命研究[J].航空发动机,2001(2):4-7.
【33】胡仁高, 卿华.涡轮叶片的粘塑性分析[J].燃气涡轮试验与研究,2006,19(2):18-21.
【34】张克实, BROCKS W. Chaboche热粘塑性损伤模型的应用研究[J].航空动力学报,2002,17(5):615-622.
【35】HART E W. Constitutive relations for the nonelastic deformation of metals [J].Journal of Engineering Material and Technology,1976,7:193-202.
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