Influence of forging equipment on microstructure and mechanical properties of TA15 titanium alloy
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摘要: 采用Deform软件对TA15钛合金在液压和锤压锻造条件下的变形进行模拟并采用两种锻造设备进行生产对比,结果表明:采用Deform软件液压模块对TA15钛合金进行锻造,等效应变沿厚度方向呈对称分布,中心位置等效应变最大,而采用锤击模块进行模拟,近下模位置等效应变较小,近上模具位置等效应变较大。TA15钛合金锻件中心位置片层α相厚度均粗于表层片层α相,采用400 kJ对击锤生产的TA15钛合金锻件,相较于100 MN油压机生产锻件,片层α相厚度较小。TA15钛合金锻件表层位置抗拉强度均高于其中心位置,采用400 kJ对击锤生产的TA15钛合金锻件抗拉强度较高。Abstract: Deform software were employed to simulate hydraulic press and hammer press forging processes of TA15 titanium alloy, and two kinds of forging equipment were used to produce TA15 titanium alloy forgings. The results show that when hydraulic module of deform software is used to deform TA15 titanium alloy, the equivalent strain distributes symmetrically along the thickness direction, and the equivalent strain at the center is the largest. However, the equivalent effect near the lower die becomes smaller and the equivalent effect near the upper die becomes larger. The center thickness of lamellar α phase is higher than that of surface. The thickness of lamellar α phase is fine than produced by 400 kJ counter hammer of TA15 titanium alloy. The tensile strength of TA15 titanium alloy forgings at the surface is higher than that of center. The tensile strength of TA15 titanium alloy forging produced by 400 kJ counter hummer is higher.
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Key words:
- TA15 titanium alloy /
- forging equipment /
- deform simulation /
- lamellar α phase /
- mechanical properties
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图 2 TA15钛合金不同锻造设备条件Deform模拟等效应变分布
(a) 400 kJ对击锤; (b) 100 MN油压机
Figure 2. The deform simulate equivalent strain of TA15 titanium alloy at various deformation equipments
图 3 不同锻造设备条件下锻件3D显微组织
(a) 400 kJ对击锤; (b) 100 MN油压机
Figure 3. The 3 direction microstructure of TA15 titanium alloy at various deformation equipments
图 4 不同锻造设备TA15钛合金锻件沿厚度方向显微组织
(a) 400 kJ对击锤锻造后锻件表面; (b) 400 kJ对击锤锻造后锻件心部; (c) 100 MN油压机锻造后锻件表层; (d) 100 MN油压机锻造后锻件心部
Figure 4. The microstructure of TA15 titanium alloy along thickness at various deformation equipments
表 1 TA15钛合金化学成分
Table 1. Chemical compositions of TA15 titanium alloy
% Ti Al V Mo Zr C Fe Si O N H Bal. 6.83 2.26 1.81 2.22 0.006 0.047 0.024 0.11 0.006 0.0025 
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表 2 TA15钛合金锻件变形参数
Table 2. The experiments conditions of TA15 titanium alloy forging deformation
试验条件 润滑方式 模具温度/℃ 加热温度/℃ 变形量/% 锤击模块 0.3 300 975 35 液压模块 0.3 300 975 35 400 kJ对击锤 石墨粉 300 975 35 100 MN油压机 石墨粉 300 975 35 注:Deform软件进行锤击模拟时,采用总打击能量的70%;400 kJ对击锤的变形采用0.7 GPa风压;Deform软件进行液压模拟和100 MN油压机锻造均采用1 mm/s变形速率。
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表 3 不同锻造设备条件下不同取样位置TA15钛合金锻件力学性能
Table 3. The mechanical properties of TA15 titanium alloy at various deformation equipments and sampling location
锻造设备 Rm/MPa Rp0.2/MPa A/% Z/% 取样位置 400 kJ对击锤 991 920 15.0 47 位置1 980 895 16.5 46 位置2 100 MN油压机 965 877 18.0 49 位置1 945 836 17 49 位置2 注:位置1指厚度方向距离下模20 mm处;位置2指厚度方向中心位置。
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[1] Niinomi M, Akahori T, Takeuchi T, et al. Titanium alloy[J]. Materials Science & Engineering. C, Biomimetic and Supramolecular Systems, 2005,C25(3):417−425. [2] 朱知寿. 新型航空高性能钛合金材料技术研究与发展[M]. 北京: 航空工业出版社, 2013.Zhu Zhishou. Research and development of new aviation high performance titanium alloy material technology[M]. Beijing: Aviation Industry Press, 2013. [3] Bruni S, Martinesi M, Stio M, et al. Effects of surface treatment of Ti–6Al–4V titanium alloy on biocompatibility in cultured human umbilical vein endothelial cells[J]. Acta Biomaterialia, 2005,1(2):223−234. doi: 10.1016/j.actbio.2004.11.001 [4] Wei Zhijian. Study on isothermal forging process of TC11 titanium alloy compressor disk[J]. Mechanic Works (Hot Working), 2003,(3):49−50, 52. (魏志坚. TC11钛合金压气机盘等温锻造工艺研究[J]. 机械工人(热加工), 2003,(3):49−50, 52. [5] Sha Aixue, Li Xingwu, Chu Junpeng. Ordinary annealing of TA15 titanium alloy[J]. Rare Metals, 2003,27(1):213−215. (沙爱学, 李兴无, 储俊鹏. TA15钛合金的普通退火[J]. 稀有金属, 2003,27(1):213−215. doi: 10.3969/j.issn.0258-7076.2003.01.058 [6] Wang Z, Wang X, Zhu Z. Characterization of high-temperature deformation behavior and processing map of TB17 titanium alloy[J]. Journal of Alloys & Compounds, 2017,692:149−154. [7] Li Miaoquan, Li Xiaoli, Long Li, et al. Thermal deformation behavior and processing diagram of TA15 alloy[J]. Rare Metal Materials and Engineering, 2006,35(9):1354−1358. (李淼泉, 李晓丽, 龙丽, 等. TA15合金的热变形行为及加工图[J]. 稀有金属材料与工程, 2006,35(9):1354−1358. doi: 10.3321/j.issn:1002-185X.2006.09.003 [8] Li Xingwu, Sha Aixue, Zhang Wangfeng, et al. TA15 alloy and its application prospect in aircraft structure[J]. Titanium Industry Progress, 2003,20(5):90−94. (李兴无, 沙爱学, 张旺峰, 等. TA15合金及其在飞机结构中的应用前景[J]. 钛工业进展, 2003,20(5):90−94. [9] Wang Bin, Guo Hongzhen, Yao Zekun, et al. Effect of hot pressing parameters on flow stress and microstructure of TA15 alloy[J]. Forging Technology, 2006,(6):106−109. (王斌, 郭鸿镇, 姚泽坤, 等. 热压参数对TA15合金流动应力及显微组织的影响[J]. 锻压技术, 2006,(6):106−109. doi: 10.3969/j.issn.1000-3940.2006.06.031 [10] Wang Zhe, Wang Xinnan, Shang Guoqiang, et al. Study on hot deformation behavior of new ultra-high strength and toughness titanium alloy[J]. Rare Metal Materials and Engineering, 2018,47(3):810−815. (王哲, 王新南, 商国强, 等. 新型超高强韧钛合金热变形行为研究[J]. 稀有金属材料与工程, 2018,47(3):810−815. [11] Zhang Wangfeng, Wang Yuhui, Ma Jimin. Heat treatment strengthening and mechanism of TA15 titanium alloy heavy forgings[J]. Rare Metals, 2010,34(1):1−5. (张旺峰, 王玉会, 马济民. TA15钛合金大锻件热处理强化及机制[J]. 稀有金属, 2010,34(1):1−5. doi: 10.3969/j.issn.0258-7076.2010.01.001 [12] Cao Jingxia, Fang Bo, Huang Xu, et al. Effect of microstructure on mechanical properties of TA15 titanium alloy[J]. Rare Metals, 2004,(2):362−364. (曹京霞, 方波, 黄旭, 等. 微观组织对TA15钛合金力学性能的影响[J]. 稀有金属, 2004,(2):362−364. doi: 10.3969/j.issn.0258-7076.2004.02.018 [13] Xu Wenchen, Shan Debin, Li Chunfeng, et al. Study on dynamic thermal compression behavior and mechanism of TA15 titanium alloy[J]. Journal of Aeronautical Materials, 2005,25(4):10−15. (徐文臣, 单德彬, 李春峰, 等. TA15钛合金的动态热压缩行为及其机理研究[J]. 航空材料学报, 2005,25(4):10−15. doi: 10.3969/j.issn.1005-5053.2005.04.003 [14] Ouyang Delai, Lu Shiqiang, Cui Xia, et al. Study on TA15 titanium alloy by work hardening rate β critical conditions for dynamic recrystallization of zone deformation[J]. Journal of Aeronautical Materials, 2010,30(2):17−23. (欧阳德来, 鲁世强, 崔霞, 等. 应用加工硬化率研究TA15钛合金β区变形的动态再结晶临界条件[J]. 航空材料学报, 2010,30(2):17−23. [15] He Fei, Chen Haifeng, Wang Yuhui. Effect of microstructure on high temperature tensile properties of TA15 alloy[J]. Materials Engineering, 2012,(2):13−15. (贺飞, 陈海峰, 王玉会. 显微组织对TA15合金高温拉伸性能的影响[J]. 材料工程, 2012,(2):13−15. doi: 10.3969/j.issn.1001-4381.2012.02.004 [16] Li Xingwu, Liu Ruimin, Sha Aixue, et al. Effect of microstructure on fatigue properties of TA15 alloy[J]. Acta Metallurgica Sinica, 2002,38(z1):280−281. (李兴无, 刘瑞民, 沙爱学, 等. 显微组织对TA15合金疲劳性能的影响[J]. 金属学报, 2002,38(z1):280−281. doi: 10.3321/j.issn:0412-1961.2002.z1.082 [17] Li Shikai, Xiong Baiqing, Hui Songxiao. Effect of heat treatment system on microstructure and properties of TA15 alloy[J]. Journal of Material Heat Treatment, 2008,(6):82−85. (李士凯, 熊柏青, 惠松骁. 热处理制度对TA15合金组织与性能的影响[J]. 材料热处理学报, 2008,(6):82−85. [18] Liu Ruimin, Li Xingwu, Sha Aixue. Study on microstructure and properties of TA15 alloy plate[J]. Material Development and Application, 2005,(4):27−30. (刘瑞民, 李兴无, 沙爱学. TA15合金板材的组织和性能研究[J]. 材料开发与应用, 2005,(4):27−30. doi: 10.3969/j.issn.1003-1545.2005.04.008 [19] Gan Guoqiang, Li Ping, Xue Kemin. Effect of thermal deformation parameters on microstructure and phase transformation kinetics of TA15 alloy[J]. Functional Materials, 2011,42(B11):828−831. (甘国强, 李萍, 薛克敏. 热变形参数对TA15合金组织的影响及其相变动力学[J]. 功能材料, 2011,42(B11):828−831. [20] Yang Hongtao, He Jianxiong, Tan Yong, et al. Study on microstructure and properties of TA15 titanium alloy ring forgings[J]. Forging Technology, 2005,30(S1):137−139. (杨洪涛, 何剑雄, 谭勇, 等. TA15钛合金环形锻件组织与性能的研究[J]. 锻压技术, 2005,30(S1):137−139. -
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