Transactions of Materials and Heat Treatment

Title：Optimization of forging process for large Zr-4 alloy ingot based on numerical simulation

Authors： Wei Xinmin1 2 Zhang Bing1 Chu Linhua2

Unit： (1. School of Metallurgical Engineering Xi′an University of Architecture and Technology Xi′an 710055 China 2. State Nuclear Baoti Zirconium Industry Co. Ltd. Baoji 721013 China)

KeyWords： Zr-4 alloy forging microstructure numerical simulation Simafactforming

ClassificationCode：TG316

year,vol(issue):pagenumber：2018,43(5):0-0

Abstract：

Forging process design is one of the difficulties in the manufacture of nuclear grade zirconium alloys, and it is also the key to obtain high quality products. For the processing of large-scale Zr-4 alloy ingots, Simufactforming software was used to simulate the forging process. Comparison of the simulation and actual temperature results for forging bar surface, combined with the microscopic observation of metallographic structure after forging, the influence laws of different processing temperatures on the microstructure of final forging billet were analyzed. The results show that compared with the microstructure obtained by the traditional forging process in β phase region, the grains size of forged billet under the optimized low temperature and high α phase zone is obviously smaller.The results of numerical simulation are agreed well with the results of actual forging test. The process design before forging and the forming mechanism of forging structure can be analyzed by finite element numerical simulation technology well. Thus, the numerical simulation technology can play a very good role in auxiliary analysis and has a high value to engineering application.

Funds：

作者简介：卫新民（1984-），男，学士，工程师 Email：jimmy0209@163.com

Reference：

［1］Terrani K A. Fabrication and preliminary evaluation of metal matrix microencapsulated fuels
［J］.Journal of Nuclear Materials, 2012,427(2):79-86.

［2］刘建章.核材料科学与工程:核结构材料
［M］. 北京：化学工业出版社，2007.

Liu J Z. Nuclear Materials Science and Engineering: Nuclear Structural Materials
［M］.Beijing:Chemical Industry Press,2007.

［3］林海,唐志今,林莺莺,等.TAl5钛合金框等温锻造工艺研究
［J］.航空材料学报,2011,31(12):14-18.

Lin H, Tang Z J,Lin Y Y, et al.TA15 bulkhead isothermal die forming
［J］.Journal of Aeronautical Materials,2011,31(12):14-18.

［4］张海燕，程明，赵忠，等. GH4169合金涡轮盘热模锻中晶粒尺寸演变的数值模拟与分析
［J］.锻压技术,2017,42(2): 1-5.

Zhang H Y, Cheng M, Zhao Z,et al.Numerical simulation and analysis on grain size evolution during the hot die forging for alloy GH4169 turbine disk
［J］.Forging ＆ Stamping Technology,2017,42(2): 1-5.

［5］侯会喜.钛合金锻造模拟成形技术发展现状
［J］.长沙航空职业技术学院学院,2008,8(1):55-58.

Hou H X. Present situations of simulation forming technology for titanium alloy forging
［J］.Journal of Changsha Aeronautical Vocational and Technical College,2008,8(1):55-58.

［6］李晓丽,李淼泉,李锋，等.TC6合金等温锻造过程中晶粒尺寸的数值模拟
［J］.中国有色金报,2005,15(9):1333-1336.

Li X L,Li M Q,Li F,et al. Numerical simulation of grain size during isothermal forging of TC6 alloy
［J］.The Chinese Journal of nonferrous metals,2005,15(9):1333-1336.

［7］张毅宁,张悦,李萍,等.Ti-6Al-4V-2Fe合金的多向锻造工艺有限元模拟及微观组织研究
［J］.锻压技术，2017,42(8):12-16.

Zhang Y N, Zhang Y, Li P, et al. FEM simulation and microstructure investigation on multidirectional forging process for alloy Ti6Al4V2Fe
［J］.Forging ＆ Stamping Technology, 2017,42(8):12-16.

［8］陆璐,王照旭,崔红霞,等.塑性有限元在金属体积成形过程中应用的进展
［J］.材料导报,2016,30(1):106-108.

Lu L,Wang Z X,Cui H X,et al.Progress of application of finite element method in metals massive forming process
［J］.Material Review,2016,30(1):106-108.

［9］龙丽. TA15合金锻造过程的数值模拟
［D］.西安：西北工业大学. 2005.

Long L.Numerical Simulation of Forging Process of TA15 Alloy
［D］. Xi′an:Northwestern Polytechnical University,2005.

［10］Erich Tenckhoff. Mechanic properties of Zr-4 alloys on the different temperatures
［J］. Nuclear Engineering and Design, 2013，20 (2)：79.

［11］Kapoor R, Chakravartty J K. Characterization of hot deformation behavior of Zr-4 in β phase
［J］. Journal of Nuclear Materials,2007, 362:75-86.

［12］Cescuti J P. Thermomechanical finite element calculation of threedimensional hot forging with remeshing
［J］. Advanced Technology of Plasticty,1987,11:1051-1058.

［13］王蕊宁. Ti53311S、TP650和Zr-4合金热加工性的研究
［D］.西安：西安建筑科技大学,2008.

Wang R N. Research on Hot Working Properties of Ti53311S, TP650 and Zr-4 Alloys
［D］.Xi′an:Xi′an University of Architecture and Technology,2008.

［14］Chakravartty J K, Banerjee S, Prasad Y V R K,et al. Hot working characteristics of Zr-4 in the temperature range of 650-1050 ℃
［J］. Journal of Nuclear Materials, 1992,187:206-271.

Service：

【This site has not yet opened Download Service】【Add Favorite】