Progress on modeling and simulation of directional solidification of superalloy turbine blade casting 被引量：6

Progress on modeling and simulation of directional solidification of superalloy turbine blade casting

下载PDF

导出

摘要 Directional solidified turbine blades of Ni-based superalloy are widely used as key parts of the gas turbine engines.The mechanical properties of the blade are greatly influenced by the final microstructure and the grain orientation determined directly by the grain selector geometry of the casting.In this paper,mathematical models were proposed for three dimensional simulation of the grain growth and microstructure evolution in directional solidification of turbine blade casting.Ray-tracing method was applied to calculate the temperature variation of the blade.Based on the thermo model of heat transfer,the competitive grain growth within the starter block and the spiral of the grain selector,the grain growth in the blade and the microstructure evolution were simulated via a modified Cellular Automaton method.Validation experiments were carried out,and the measured results were compared quantitatively with the predicted results.The simulated cooling curves and microstructures corresponded well with the experimental results.The proposed models could be used to predict the grain morphology and the competitive grain evolution during directional solidification. Directional solidified turbine blades of Ni-based superalloy are widely used as key parts of the gas turbine engines. The mechanical properties of the blade are greatly influenced by the final microstructure and the grain orientation determined directly by the grain selector geometry of the casting. In this paper, mathematical models were proposed for three dimensional simulation of the grain growth and microstructure evolution in directional solidification of turbine blade casting. Ray-tracing method was applied to calculate the temperature variation of the blade. Based on the thermo model of heat transfer, the competitive grain growth within the starter block and the spiral of the grain selector, the grain growth in the blade and the microstructure evolution were simulated via a modified Cellular Automaton method. Validation experiments were carried out, and the measured results were compared quantitatively with the predicted results. The simulated cooling curves and microstructures corresponded well with the experimental results. The proposed models could be used to predict the grain morphology and the competitive grain evolution during directional solidification.

作者 Xu Qingyan Liu Baicheng Pan Dong Yu Jing

机构地区 Key Laboratory for Advanced Materials Processing Technology

出处《China Foundry》 SCIE CAS 2012年第1期69-77,共9页 中国铸造（英文版）

基金 financially supported by the National Basic Research Program of China (No.2005CB724105,2011CB706801) National Natural Science Foundation of China (No.10477010) National High Technology Research,Development Program of China (No.2007AA04Z141) Important National Science & Technology Specific Projects (No.2009ZX04006-041,2011ZX04014-052)

关键词 Ni-based superalloy MICROSTRUCTURE directional solidification MODELING Ni-based superalloy microstructure directional solidification modeling

分类号 TG146.15 [金属学及工艺—金属材料] TP391.9 [自动化与计算机技术—计算机应用技术]

引文网络
相关文献

参考文献5

1Jing YU,Qingyan XU,Baicheng LIU,Jiarong LI,Hailong YUAN,Haipeng JIN.Experimental Study and Numerical Simulation of Directionally Solidified Turbine Blade Casting[J].Journal of Materials Science & Technology,2008,24(3):369-373. 被引量：4
2Jing YU,Qingyan XU,Kai CUI,Baicheng LIU,Akihiko KIMATSUKA.Numerical Simulation of Solidification Process on Single Crystal Ni-Based Superalloy Investment Castings[J].Journal of Materials Science & Technology,2007,23(1):47-54. 被引量：9
3钟振纲.受控单晶晶种制取方法──单晶铸件定向凝固工艺研究之一[J].材料工程,1996,24(9):39-41. 被引量：1
4Jiarong LI, Shizhong LIU and Zhengang ZHONGBeijing Institute of Aeronautical Materials, Beijing 100095, China.Solidification Simulation of Single Crystal Investment Castings[J].Journal of Materials Science & Technology,2002,18(4):315-318. 被引量：7
5Jiarong LI, Shizhong LIU, Hailong YUAN and Zhengang ZHONGNational Key Laboratory of Advanced High Temperature Structural Materials, Beijing Institute of Aeronautical Materials, Beijing 100095, China.Solidification Simulation of Investment Castings of Single Crystal Hollow Turbine Blade[J].Journal of Materials Science & Technology,2003,19(6):532-534. 被引量：9

二级参考文献28

1Ph.D.Candidate:Sun JianXi’an University of Technolgy, Xi’an 710048, ChinaSupervisor:Yu Changzhao (Tsinghua University, Beijing 100084, China)Li Yuzhu (Tsinghua University, Beijing 100084, China)Chen Changzhi (Tsinghua University, Beijing 100084, China)Members of Dissertation Defense Committee:Gao Jizhang (China Institute of Water Resources and Hydropower Research), ChairmanLi Guifen (China Institute of Water Resources and Hydropower Research)Cui Guangtao (Tianjing University)Wang Xingkui (Tsinghua University)Yu Changzhao (Tsinghua University)Li Yuzhu (Tsinghua University)Chen Changzhi (Tsinghua University).FLOOD DISCHARGE AND ENERGY DISSIPATION BY JETS FROM OUTLETS IN HIGH ARCH DAM[J].Journal of Hydrodynamics,2003,15(1):122-122. 被引量：39
2[1]D.N.Duhl: Superalloys 2, John Wiley Sons, 1987, 189.
3[2]J.S.Tu and R.K.Foran: JOM, 1992, 44(6), 26.
4[3]K.O.Yu, J.A.Oti, M.Robinson and R.G.Carlson: Superalloys 1992, TMS, 1992, 135.
5[4]A.L.Purvis, C.R.Hanslits and R.S.Diehm: JOM, 1994, 46(1),38.
6[5]W.Shyy: JOM, 1996, 48(3), 24.
7[6]M.M.Vehn, D.Dedecke and P.R.Sahm: Superalloys 1996, TMS,1996, 471.
8[7]Kefu ZHANG: Ph. D. Thesis, Northwestern Polytechnical University, 1990. (in Chinese)
9[8]Jiarong LI: Aviation Production Engineering, 1998, (2), 14. (inChinese)
10[9]J.R.Li, Z.G.Zhong, D.Z.Tang, S.Z.Liu, P. Wei, P.Y.Wei,Z.T.Wu, D.Huang and M.Han: Superalloys 2000, TMS, 2000,777.

共引文献23

1王同敏,苏彦庆,郭景杰,I. OHNAKA,H. YASUDA.Structure simulation in unidirectionally solidified turbine blade by dendrite envelope tracking model (Ⅱ): model validation and defects prediction[J].中国有色金属学会会刊：英文版,2006,16(4):753-759. 被引量：4
2薛明,曹腊梅,刘世忠,李嘉荣.定向凝固过程中型芯、型壳温度场数值模拟[J].热加工工艺,2006,35(21):86-87. 被引量：3
3薛明,曹腊梅,刘世忠,李嘉荣.定向凝固过程中型芯型壳温度场数值模拟[J].铸造,2007,56(3):287-289. 被引量：4
4Dou Yangqing Bu Kun Dou Yangliu Dong Yiwei.Reversing design methodology of investment casting die profile based on ProCAST[J].China Foundry,2010,7(2):132-137. 被引量：11
5米国发.Microstructure of a Spray Deposited Intermetallic Compound Alloy of Ni-Al-Mo System[J].Journal of Wuhan University of Technology(Materials Science),2010,25(3):375-378.
6熊继春,李嘉荣,刘世忠.镍基单晶高温合金DD6的表面再结晶(英文)[J].Chinese Journal of Aeronautics,2010,23(4):478-485. 被引量：4
7谢洪吉,李嘉荣,金海鹏,刘世忠,熊继春.DD6单晶高温合金导向叶片定向凝固过程数值模拟[J].材料工程,2011,39(11):58-61. 被引量：7
8ZHANG Hang XU QingYan TANG Ning PAN Dong LIU BaiCheng.Numerical simulation of microstructure evolution during directional solidification process in directional solidified (DS) turbine blades[J].Science China(Technological Sciences),2011,54(12):3191-3202. 被引量：7
9ZHOU YiZhou,SUN XiaoFeng.Effect of solidification rate on competitive grain growth in directional solidification of a nickel-base superalloy[J].Science China(Technological Sciences),2012,55(5):1327-1334. 被引量：4
10周君华,孙长波,尚伟,李波.ProCAST软件在熔模铸造工艺优化中的应用[J].材料科学与工艺,2013,21(5):109-112. 被引量：12

同被引文献49

1李殿中,康秀红,夏立军,李依依.可视化铸造技术的研究与应用[J].铸造,2005,54(2):148-152. 被引量：28
2胡红军,杨明波,罗静,王春欢,陈康.ProCAST软件在铸造凝固模拟中的应用[J].材料科学与工艺,2006,14(3):293-295. 被引量：53
3胡红军,杨明波,龚喜兵,李国瑞.铸造工艺的数值模拟优化[J].兵器材料科学与工程,2006,29(6):51-53. 被引量：15
4薛红军,谢清程,周剑平,易小冬.某型调距桨装置桨毂强度有限元分析研究[J].船舶工程,2007,29(1):28-30. 被引量：14
5于靖,许庆彦,李嘉荣,袁海龙,刘世忠,柳百成.镍基高温合金多叶片定向凝固过程数值模拟[J].金属学报,2007,43(10):1113-1120. 被引量：22
6Reed R C: The Supemlloys Fundamental and Applications [M]. Cambridge: Cambridge University Press, 2006.
7Auburtin P, Wang T, Cockcrofl S L, et al. Freckle formation and freckle criterionin superalloy castings [J] ~ MetaUurgical andMate- rials Transactions B, 2000,31B(4): 801-811.
8Auburtin P, Cockcrofl S L, Mitchell A. Liquid density inversions during the solidification of superalloys and their relationship to freckle formation in castings [C] // Superalloys 1996. Los Ange- les : The Minerals, Metals & Mateials Society, 1996 : 443-450.
9Jasinski T, Rohsenow W M, Witt A F. Heat transfer analysis of the Bridgrnan-Stockbargerconfigurationforcrystalgrowth: I. Ana- lytical treatment of the axial temperature profile [J]. Journal of CrystalGrowth, 1983,61(2) : 339-354.
10JasinskiT,WittAF,RohsenowWM. Heattransferanalysisofthe Bridgman-Stockbarger configuration for crystal gowth: II. Ana- lytical treatment of radial temperature variations [J]. Journal of Crystal Growth, 1984,67(2) : 193-184.

引证文献6

1Wang Tongmin,Li Jia,Wu Li,Jie Jinchuan,Cao Zhiqiang,Kang Huijun.Simulation study on three casting processes for a marine propeller hub body[J].China Foundry,2013,10(6):360-366. 被引量：2
2王嘉诚,曲元哲,沈楚伦,杨弋涛.上倾倒框铸铝件铸造工艺设计及模拟优化[J].精密成形工程,2018,10(6):88-94. 被引量：5
3高斯峰.单晶叶片模拟件制备过程中温度场的数值模拟研究[J].热加工工艺,2015,44(19):93-96. 被引量：2
4蔡虎,王嘉诚,付文笙,曲元哲,杨弋涛.基于计算机模拟的支架铸钢件铸造工艺设计及优化[J].精密成形工程,2019,11(4):153-161. 被引量：10
5吴健,王晶,苏斌,董鲜峰,王震宏.铍铝合金支撑座熔模铸造数值模拟[J].铸造,2020,69(4):407-411. 被引量：2
6宗学文,王磊,刘文杰,张斌,张凌峰.抽拉速率对螺旋选晶器选晶行为和晶体取向演变的影响[J].稀有金属材料与工程,2021,50(7):2366-2374.

二级引证文献20

1杨一群,李军义,王东新,刘兆刚,谢垚.精密铸造Be-Al合金复杂支架铸件[J].特种铸造及有色合金,2022,42(1):129-132. 被引量：1
2赵洁洁.计算机调压医疗器械铸造控制系统设计与实现[J].现代制造技术与装备,2023,59(S01):28-30.
3王丽.基于CAD技术分析大型铸钢件铸造工艺优化[J].广西农业机械化,2019(6):32-32. 被引量：1
4韩敬波.现代教师观念素质的构成分析[J].教学与管理（中学版）,2000(9):6-7. 被引量：3
5王嘉诚,曲元哲,沈楚伦,杨弋涛.上倾倒框铸铝件铸造工艺设计及模拟优化[J].精密成形工程,2018,10(6):88-94. 被引量：5
6蔡虎,王嘉诚,付文笙,曲元哲,杨弋涛.基于计算机模拟的支架铸钢件铸造工艺设计及优化[J].精密成形工程,2019,11(4):153-161. 被引量：10
7徐文峰.铸造炉门框的铸造工艺设计及优化[J].科技视界,2019(17):15-17.
8李艳芹,丁昌,吴超,张德海.锅炉给水预热器管板的优化设计与分析[J].精密成形工程,2020,12(3):131-136. 被引量：1
9马煜林,刘少华,纪良鑫,王芃喆,李婷惠子,魏长锁,赵林.基于ProCAST吸阀壳体铸铝件铸造工艺设计[J].铸造,2021,70(1):94-98. 被引量：5
10陈捷文,柯志敏,陈鹏辉.增压缸体铸件的铸造工艺设计与优化[J].铸造设备与工艺,2021(1):12-16.

1彭立明,毛协民,徐匡迪.Simulation and control model for interactions among process parameters of directional solidification continuous casting[J].中国有色金属学会会刊：英文版,2000,10(4):449-452. 被引量：1
2Xu Qingyan,Zhang Hang,Liu Baicheng.Multiscale modelling and simulation of single crystal superalloy turbine blade casting during directional solidification process[J].China Foundry,2014,11(4):268-276. 被引量：2
3D.Z.Li,Z.Y.Hu,Q.Li,Y.Y.Li.MICROSTRVCTURE SIMULATION AND PROCESS OPTIMIZATION OF TURBINE BLADE CASTINGS[J].Acta Metallurgica Sinica(English Letters),1998,11(5):383-390. 被引量：2
4PAN Li-bo HUA Lin LAN Jian.Modeling and Simulation of Radial-Axial Large Ring Rolling[J].Computer Aided Drafting,Design and Manufacturing,2007,17(1):19-24. 被引量：1
5L.Yang,Q.X.Liu,Y.C.Zhou,W.G.Mao,C.Lu.Finite Element Simulation on Thermal Fatigue of a Turbine Blade with Thermal Barrier Coatings[J].Journal of Materials Science & Technology,2014,30(4):371-380. 被引量：15
6Jing YU,Qingyan XU,Baicheng LIU,Jiarong LI,Hailong YUAN,Haipeng JIN.Experimental Study and Numerical Simulation of Directionally Solidified Turbine Blade Casting[J].Journal of Materials Science & Technology,2008,24(3):369-373. 被引量：4
7TAO Yu JIA Jian LIU Jian-tao.Microstructure Characterization and Mechanical Properties of FGH 95 Turbine Blade Retainers[J].Journal of Iron and Steel Research(International),2010,17(9):73-78. 被引量：4
8Fajie Duan, Zhiqiang Fang, Yuyang Sun State Key Lab of Precision Measuring Technology & Instruments, Tianjin University, P. R. China.Optical Fiber Sensor's Applied in Vibration Measurement of Turbine Blade[J].光学学报,2003,23(S1):823-824.
9Akanji Olaitan Lukman,Obadele Babatunde Abiodun,Oluranti Sadiku-Agboola,Patricia Abimbola Popoola,Emmanuel Rotimi Sadiku.Modeling and Simulation of Hydrogen Storage Device for Fuel Cell Plant[J].Journal of Chemistry and Chemical Engineering,2012,6(7):604-612.
10王同敏,Itsuo OHNAKA,Hideyuki YASUDA,苏彦庆,郭景杰.Structure defect prediction of single crystal turbine blade by dendrite envelope tracking model[J].中国有色金属学会会刊：英文版,2006,16(B02):582-585. 被引量：1

China Foundry

2012年第1期

浏览历史

内容加载中请稍等...