6063-T5铝合金热变形行为及热加工图研究
Study on hot deformation behavior and hot processing map of 6063-T5 aluminum alloy
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摘要: 采用热模拟试验机对6063-T5铝合金进行轴对称等温热压缩实验,分析热变形过程中热变形参数对其真应力的影响规律,建立自适应系数Arrhenius本构模型和位错密度增长模型,并通过绘制热加工图考查热加工工艺参数对6063-T5铝合金热变形行为的影响.结果表明:随着温度的升高,真应力呈阶梯形下降趋势,材料的软化效果越来越明显;随着应变速率的升高,真应力呈缓慢上升趋势,材料的硬化效果越来越明显;使用决定系数R2作为评估标准构建的自适应系数Arrhenius本构模型与位错密度增长模型可以准确描述热变形参数对6063-T5铝合金热变形行为的影响;使用热加工图进行分析获得了最佳热加工区间变形温度350~525℃、应变速率0.01~1 s-1.Abstract: The thermal simulation testing machine was used to conduct axisymmetric isothermal hot compression experiments on 6063-T5 aluminum alloy. The influence of thermal deformation parameters on the true flow stress was analyzed, and the adaptive coefficient Arrhenius constitutive model and dislocation density growth model were established.The influence of process parameters on the hot deformation behavior of 6063-T5 aluminum alloy was investigated by drawing the hot working diagram. The results showed that, with the increase of temperature, the true stress showed a step-down trend, and the softening effect of the material became more and more obvious. With the increase of strain rate, the true stress increased slowly, and the hardening effect became more and more obvious. The Arrhenius constitutive model which was constructed by using the determination coefficient as the evaluation criterion and the dislocation density growth model can accurately describe the influence of hot deformation parameters on the hot deformation behavior of 6063-T5 aluminum alloy. The hot processing map showed that the optimum deformation temperature and strain rate ranges for the 6063-T5 aluminum alloy were 350~525℃ and 0.01~1 s-1 respectively.
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Key words:
- 6063 aluminum alloy /
- hot deformation behavior /
- constitutive model /
- hot processing map
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[1]
CAI Y,WANG X S,YUAN S J.Analysis of surface roughening behavior of 6063 aluminum alloy by tensile testing of a trapezoidal uniaxial specimen[J].Materials Science and Engineering:A,2016,672:184.
-
[2]
HIRSCH J,AL-SAMMAN T.Superior light metals by texture engineering:optimized aluminum and magnesium alloys for automotive applications[J]. Acta Materialia, 2013,61(3):818.
-
[3]
YE T,LI L X,GUO P C, et al. Effect of aging treatment on the microstructure and flow behavior of 6063 aluminum alloy compressed over a wide range of strain rate[J]. International Journal of Impact Engineering, 2016,90:72.
-
[4]
LOKESH V S S,GOEL S,KUMAR N, et al. A study on fracture toughness and strain rate sensitivity of severely deformed Al 6063 alloys processed by multiaxial forging and rolling at cryogenic temperature[J]. Materials Science and Engineering:A,2017,686:82.
-
[5]
计海涛,于得资,孙绍华. 6063-T5铝合金建筑型材生产工艺优化[J]. 轻合金加工技术,2002,30(8):26.
-
[6]
PARK N,SHIBATA A,TERADA D, et al. Flow stress analysis for determining the critical condition of dynamic ferrite transformation in 6Ni-0.1C steel[J]. Acta Materialia,2013,61(1):163.
-
[7]
MEJÍA I,BEDOLLA-JACUINDE A, MALDONADO C, et al. Determination of the critical conditions for the initiation of dynamic recrystallization in boron microalloyed steels[J]. Materials Science and Engineering:A,2011,528:4133.
-
[8]
QUAN G Z,LUO G C,LIANG J T,et al. Modelling for the dynamic recrystallization evolution of Ti-6Al-4V alloy in two-phase temperature range and a wide strain rate range[J]. Computational Materials Science,2015,97:136.
-
[9]
俞德新,胡欧林,曾瑞祥,等.热处理工艺对低硅Al-Si-Mg铸造铝合金组织和力学性能的影响[J].上海金属,2020,42(4):66.
-
[10]
高俊.6082铝合金热成形行为及其在汽车转向节高温精密锻造的应用[D].长春:吉林大学, 2020.
-
[11]
刘建勃,王智毅,马雄. Al-Mg-Si合金热变形行为与本构关系[J]. 塑性工程学报,2017,24(3):197.
-
[12]
叶文宏. 6A02铝合金热变形行为及杯形件等温锻造数值模拟[D].哈尔滨:哈尔滨工业大学,2016.
-
[13]
CHEN L,ZHAO G Q,YU J Q. Hot deformation behavior and constitutive modeling of homo-genized 6026 aluminum alloy[J]. Materials and Design,2015,74:25.
-
[14]
HUANG Y C,LIU L C,XIAO Z B, et al. Hot Deformation behavior of 6063 aluminum alloy studied using processing maps and microstructural analysis[J].Physics of Metals and Metallography, 2019,120(11):1115.
-
[15]
WU R H,LIU Y,GENG C, et al. Study on hot deformation behavior and intrinsic workability of 6063 aluminum alloys using 3D processing map[J].Journal of Alloys and Compounds,2017,713:1.
-
[16]
MECKING H,KOCKS U F. Kinetics of flow and strain-hardening[J].Acta Metallurgica, 1981,29(11):1865.
-
[17]
SELLARS C M,MCTEGART W J. On the mechanism of hot deformation[J].Acta Metallurgica, 1966,14(9):1136.
-
[18]
ZENER C,HOLLOMON J H. Effect of strain rate upon plastic flow of steel[J].Journal of Applied Physics, 1944,15(1):22.
-
[19]
陈飞.热锻非连续变形过程微观组织演变的元胞自动机模拟[D].上海:上海交通大学,2012.
-
[20]
夏祖瑜.300M钢成形过程动态再结晶的元胞自动机模拟[D].武汉:华中科技大学,2019.
-
[21]
季海鹏.基于元胞自动机法的316LN不锈钢动态再结晶组织预测[D].秦皇岛:燕山大学,2013.
-
[22]
李豪.稀土镁合金动态再结晶动力学研究[D]. 重庆:西南大学,2019.
-
[23]
卞东伟.6063铝合金微观组织演变多尺度本构建模研究[D].银川:宁夏大学,2019.
-
[24]
MCQUEEN H J.Development of dynamic recrystallization theory[J].Materials Science and Engineering:A, 2004,387:203.
-
[25]
MCQUEEN H J. Initiating nucleation of dyna mic recrystallization, primarily in polycrystals[J]. Materials Science and Engineering:A, 1988, 101:149.
-
[26]
MCQUEEN H J,RYAN N D. Constitutive anal ysis in hot working[J]. Materials Science and Engineering:A,2002,322:43.
-
[27]
MADEJ L,SITKO M,PIETRZYK M. Perceptive comparison of mean and full field dynamic recrys tallization models[J]. Archives of Civil and Mechanical Engineering, 2016,16(4):569.
-
[28]
杜大鹏. 基于位错密度的流动应力模型的研究[D]. 上海:上海交通大学,2010.
-
[29]
POLIAK E I,JONAS J J. Initiation of dynamic re crystallization in constant strain rate hot deformation[J]. ISIJ International, 2003,43(5):684.
-
[30]
PRASAD Y V R K. Recent advances in the sci ence of mechanical processing[J]. Indian Jour nal of Technology, 1990,28(6/7/8):435.
-
[31]
PRASAD Y V R K, GEGEL H L, DORAIVELU S M, et al. Modeling of dynamic material behavior in hot deformation:forging of Ti-6242[J]. Metal lurgical Transactions A, 1984, 15(10):1883.
-
[32]
KE B,YE L Y,TANG J G, et al. Hot deforma tion behavior and 3D processing maps of AA7020 aluminum alloy[J]. Journal of Alloys and Compounds, 2020,845:1.
-
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