锻压技术

铸态铁镍基耐蚀合金热压缩模拟研究

英文标题：Study on hot compression test for as-cast Fe-Ni based corrosion-resistant alloy

作者：刘海定王东哲黄国平赵安中陈登华

单位：重庆材料研究院有限公司耐腐蚀合金重庆市重点实验室国家仪表功能材料工程技术研究中心

分类号：TG132.3

出版年,卷(期):页码：2016,41(6):138-141

摘要：

通过热模拟压缩试验，得到了温度为900~1200 ℃（温度间隔为50 ℃）、应变速率为0.1 s-1、应变量为35%条件下时效强化型铁镍基耐蚀合金的应力-应变曲线。不同温度对试验合金的热压缩应力-应变曲线有较大影响。随着变形温度的提高，峰值压缩应力逐渐减小，并且降低的幅度由急变缓。试验后样品的硬度也随变形温度的提高而降低。试验后样品的显微组织均几乎保留着原有的铸态组织形貌，呈明显树枝晶，当试验温度较低时，再结晶程度很小，随着温度的提高，再结晶变得更明显，细小的再结晶晶粒有所增加，但远没有达到完成的地步。当温度为1150和1200℃时，显微照片上可见明显的沿晶裂纹，可能与试验温度过高有关，也可能与单道次变形量太大有关。

The stress-strain curves of aging-strength Fe-Ni based corrosion-resistant alloy were obtained by the hot compression test under conditions of temperature 900-1200 ℃(50 ℃ increments per test), strain rate 0.1 s-1 and strain 35%. The stress-strain curves vary greatly at different temperature. The peak compression stress decreases gradually with the increase of temperature, and the decreasing tendency is gradually retarded. After testing, the hardness of samples also decreases with the increase of temperature, however, the microstructure keeps its original cast structure with dendrite. When the test temperature is lower, the recrystallization grain is smaller, and it is more obvious with increasing temperature. Therefore, the tiny recrystallization grain increases, and the recrystallization fraction is far from the complete recrystallization. When test temperatures are 1150 and 1200 ℃, intergranular cracks are found in the micrograph, and it is related to over high temperature or over large single-stroke deformation.

基金项目：

基金项目:国家高技术研究发展计划项目（863计划）（2013AA031005）；重庆市国际科技合作项目（cstc2013gjhz50001）

作者简介：刘海定（1979-），男，硕士，高级工程师 E-mail：haidingliu@qq.com

参考文献：

［1］谢锡善，董建新，胡尧和，等. 铁镍基高温耐蚀合金的研究与发展[J]. 世界钢铁, 2009，(1): 50-55.Xie X S, Dong J X, Hu Y H, et al. Research and development of Fe-Ni Based corrosion-resistant alloys[J]. World Iron & Steel, 2009,(1): 50-55.

［2］刘海定, 王东哲，魏捍东，等. 高性能镍基耐腐蚀合金的开发进展[J]. 材料导报,2013，27(3): 99-105.Liu H D, Wang D Z, Wei H D, et al. Development progress of high-performance nickel-based corrosion-resistant alloys[J]. Materials Review, 2013, 27(3): 99-105.

［3］Decker R F. The evolution of wrought age-hardenable superalloys[J]. The Journal of the Minerals,Metals & Meterials Society, 2006(9): 32-36.

［4］陈正宗，刘正东，包汉生. 铸态耐热合金CN617热变形行为研究[J]. 金属热处理，2014，39(11): 68-72.Chen Z Z, Liu Z D, Bao H S. Hot deformation behavior and processing maps of CN617 nickel-based heat-resistant alloy ingot[J]. Heat Treatment of Metals, 2014, 39(11):68-72.

［5］郭宏钢，王岩，李阳. 617B镍基高温合金铸态组织热变形行为研究[J]. 热加工工艺，2013，42(24): 51-53.Guo H G, Wang Y, Li Y. Research on hot deformation behavior of as-cast structure of 617B nickel-based superalloy[J]. Hot Working Technology, 2013,42(24): 51-53.

［6］刘国伟，赵兴东，杨艳慧，等. 铸态GH706合金的热变形行为研究[J]. 锻压技术，2015，40(9): 117-124.Liu G W, Zhao X D, Yang Y H, et al. Study on hot deformation behavior of cast alloy GH706[J]. Forging & Stamping Technology, 2015, 40(9): 117-124.

［7］王珏，梅莹，王浩宇. 铸态690合金的热压缩变形行为[J]. 材料热处理学报, 2015，36(9): 21-26.Wang J, Mei Y, Wang H Y. Hot compression behavior of as cast 690 alloy[J]. Transactions of Materials and Heat Treatment, 2015, 36(9): 21-26.

服务与反馈：

【文章下载】【加入收藏】