Acta Metall Sin  1996, Vol. 32 Issue (7): 742-748    DOI:

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MATHEMATICAL MODEL OF FLUID FLOW,TEMPERATURE CONTROL AND INCLUSION BEHAVIOUR IN CONTINUOUS CASTING TUNDISH

SHENG Dongyuan; NI Mansen; DENG Kaiwen; LIU Jiaqi; GAN Yong; XIAO Zeqiang (National Research & Engineering Center of Continuous Casting Technology;Gentral Iron and Steel Research Institute; Ministry of Metallurgical industry;Beijing 100081)(Manuscript received 1995-11-09; in revised form 1996-04-17)

SHENG Dongyuan; NI Mansen; DENG Kaiwen; LIU Jiaqi; GAN Yong; XIAO Zeqiang (National Research & Engineering Center of Continuous Casting Technology;Gentral Iron and Steel Research Institute; Ministry of Metallurgical industry;Beijing 100081)(Manuscript received 1995-11-09; in revised form 1996-04-17). MATHEMATICAL MODEL OF FLUID FLOW,TEMPERATURE CONTROL AND INCLUSION BEHAVIOUR IN CONTINUOUS CASTING TUNDISH. Acta Metall Sin, 1996, 32(7): 742-748.

Abstract References Related Articles Recommended Metrics Download:  PDF(453KB)  Export:  BibTeX | EndNote (RIS)       Abstract  A mathematical model and corresponding computational results describing the three-dimensional turbulent flow, thermal dispersion and inclusion behavior in tundish were presented in this study. The predicted flow fields were compared with the measurements in aqueous model. Building up the synthetic mathematical model of tundish process and simulating it by computer may efficiently modify the working conditions and improve continuous casting technology.Correspondent: SHENG Dongyuan, National Research & Engineering Center of Continuous Casting Technology, Gentral Iron and Steel Research Institute, Ministry of Metallurgical Industry, Beijing 100081 Key words:  continuous casting tundish      fluid flow      heat transfer      inclusion behavior      mathematical model      Received:  18 July 1996      Service E-mail this article Add to citation manager E-mail Alert RSS （） Articles by authors URL:  https://www.ams.org.cn/EN/     OR     https://www.ams.org.cn/EN/Y1996/V32/I7/742 1McleanAed．,TundishMetallurgy,Vol．Ⅰ&Ⅱ,Warrendale,PA:TheIronandSteelSociety,Inc,19902贺友多,SahaiY．金属学报,1988;24:B793 朱本立,王建军,戴朝珊,吴琪澳,沈建国,樊俊飞．钢铁,1994;29(8):194 LaunderBE,SpaldingDB．CompMathApplMechEng,1974;3:2865JooS,GuthrieRIL．metallTrans,1993;24B:7556IlegbusiOJ,SzekelyJ．MathematicalModelingofMaterialsProcessingOperation,Warrendale,PA:TMS,1987:4097PatankarSV．NumericalHeatTransferandFluidFlow,NewYork,NY:McGraw-Hill,19808LeeSM,KooYS,KangT．LeeIR,ShinYK．Proc．6thInt．Iron&SteelCong,Tokyo:ISIJ,1990:239 [1] PENG Zhiqiang, LIU Qian, GUO Dongwei, ZENG Zihang, CAO Jianghai, HOU Zibing. Independent Change Law of Mold Heat Transfer in Continuous Casting Based on Big Data Mining[J]. 金属学报, 2023, 59(10): 1389-1400. [2] TANG Haiyan, LIU Jinwen, WANG Kaimin, XIAO Hong, LI Aiwu, ZHANG Jiaquan. Progress and Perspective of Functioned Continuous Casting Tundish Through Heating and Temperature Control[J]. 金属学报, 2021, 57(10): 1229-1245. [3] Shoumei XIONG, Jinglian DU, Zhipeng GUO, Manhong YANG, Mengwu WU, Cheng BI, Yongyou CAO. Characterization and Modeling Study on Interfacial Heat Transfer Behavior and Solidified Microstructure of Die Cast Magnesium Alloys[J]. 金属学报, 2018, 54(2): 174-192. [4] Dunming LIAO, Liu CAO, Fei SUN, Tao CHEN. Research Status and Prospect on Numerical Simulation Technology of Casting Macroscopic Process[J]. 金属学报, 2018, 54(2): 161-173. [5] Xiaoyu CHONG, Guangchi WANG, Jun DU, Yehua JIANG, Jing FENG. Numerical Simulation of Temperature Field and Thermal Stress in ZTAp/HCCI Composites DuringSolidification Process[J]. 金属学报, 2018, 54(2): 314-324. [6] Chuansong WU, Hao SU, Lei SHI. Numerical Simulation of Heat Generation, Heat Transfer and Material Flow in Friction Stir Welding[J]. 金属学报, 2018, 54(2): 265-277. [7] Heng SHAO,Yan LI,Hai NAN,Qingyan XU. RESEARCH ON THE INTERFACIAL HEAT TRANSFER COEFFECIENT BETWEEN CASTING AND CERAMIC SHELL IN INVESTMENT CASTING PROCESS OF Ti6Al4V ALLOY[J]. 金属学报, 2015, 51(8): 976-984. [8] Yongyou CAO, Shoumei XIONG, Zhipeng GUO. DEVELOPMENT OF AN INVERSE HEAT TRANSFER MODEL BETWEEN MELT AND SHOT SLEEVE AND ITS APPLICATION IN HIGH PRESSURE DIE CASTING PROCESS[J]. 金属学报, 2015, 51(6): 745-752. [9] Guoxiang XU, Weiwei ZHANG, Peng LIU, Baoshuai DU. NUMERICAL ANALYSIS OF FLUID FLOW IN LASER+GMAW HYBRID WELDING[J]. 金属学报, 2015, 51(6): 713-723. [10] WANG Xinxin, FAN Ding, HUANG Jiankang, HUANG Yong. NUMERICAL SIMULATION OF HEAT TRANSFER AND FLUID FLOW IN DOUBLE ELECTRODES TIG ARC-WELD POOL[J]. 金属学报, 2015, 51(2): 178-190. [11] Xuewei YAN,Ning TANG,Xiaofu LIU,Guoyan SHUI,Qingyan XU,Baicheng LIU. MODELING AND SIMULATION OF DIRECTIONAL SOLIDIFICATION BY LMC PROCESS FOR NICKEL BASE SUPERALLOY CASTING[J]. 金属学报, 2015, 51(10): 1288-1296. [12] LI Yan, FENG Yanhui, ZHANG Xinxin, WU Chuansong. A DYNAMIC HEAT SOURCE MODEL WITH RESPECT TO KEYHOLE EVOLUTION IN PLASMA ARC WELDING[J]. 金属学报, 2013, 49(7): 804-810. [13] ZHANG Tao WU Chuansong CHEN Maoai. MODELLING FLUID FLOW AND HEAT TRANSFER PHENOMENA IN KEYHOLING STAGE OF PLASMA ARC WELDING[J]. 金属学报, 2012, 48(9): 1025-1032. [14] CHENG Baisong, XIAO Namin, LI Dianzhong, LI Yiyi. SENSITIVITY ANALYSIS OF THE EFFECT OF INTERFACIAL HEAT TRANSFER COEFFICIENT ON DISTORTION SIMULATION DURING QUENCHING[J]. 金属学报, 2012, 48(6): 696-702. [15] GAO Ao WANG Qiang LI Dejun JIN Baigang WANG Kai HE Jicheng. EFFICIENCY AND INFLUENCING FACTORS OF ELECTROMAGNETIC STEEL-TEEMING TECHNOLOGY[J]. 金属学报, 2010, 46(5): 634-640. No Suggested Reading articles found! Viewed Full text Abstract Cited   Shared      Discussed