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袁保辉等:RH强制脱碳与自然脱碳工艺生产F钢精炼效果分析 ·1115 production.Iron Steel,2010,45(8):33 (梁英教,车荫昌.无机物热力学数据手册.沈阳:东北大学出版 (刘柏松,李本海,朱国森,等.常规RH和RH-TOP工艺精炼IF钢 社,1993) 试验研究.钢铁,2010,45(8):33) [24]Cheng GG,Zhao P,Xu X L,et al.Process of vacuum [15]Li D M,Zhang WH,Lin L P,et al.Application of RH oxygen top- denitrogenation of steel.Iron Steel,1999.34(1):16 blowing technology in No.2 Steel-making Plant,WISCO. (成国光,赵沛,徐学禄,等.真空下钢液脱氨工艺研究.钢铁, Steelmaking,2007,23(6):5 1999,34(1):16) (李大明,张文辉,林立平,等RH顶吹氧技术在武钢第二炼钢厂 [25]Cao S.Control of end nitrogen content in smelting of ultra-low 的应用.炼钢,2007,23(6):5) nitrogen steel with converter.Hebei Metall,2015(10):14 [16]Yuan B H,Liu J H.Zhou H L,et al.The vacuum decarburization (曹盛.超低氨钢转炉终点氨含量控制.河北冶金,2015(10):14) process optimization study of high altitude RH refining equipment. [26]Kitamura T,Miyamoto K,Tsujino R,et al.Mathematical model Steelmaking,2020,36(4):31 for nitrogen desorption and decarburization reaction in vacuum (袁保辉,刘建华,周海龙,等.高海拔RH精炼装置真空脱碳工艺 degasser.ISI/Int,1996,36(4):395 优化研究.炼钢,2020,36(4):31) [27]Wang M,Bao Y P,Cui H,et al.The composition and morphology [17]Liu M,Bai F Q,Chen SS,et al.Application of water irrush source evolution of oxide inclusions in Ti-bearing ultra low-carbon steel standard set in mine water prevention.Miner Eng Res,2014, melt refined in the RH process./SI/Int,2010,50(11):1606 29(3):30 [28]Tang F P,Chang G H,Li H,et al.Inclusions in ultra-low carbon (刘猛,白峰青,陈少帅,等.水源判别标准集在矿并防治水中的 steel.Iron Steel,2007,42(1):20 应用.矿业工程研究,2014,29(3):30) (唐复平,常桂华,栗红,等.超低碳钢钢中夹杂物的研究.钢铁, [18]Xu M.Liu Z C,Yan X,et al.Online detection method for 2007,42(1):20) incremental capacity internal resistance consistency.Energy [29]Dekkers R,Blanpain B,Wollants P,et al.A morphological Storage Sci Technol,2019,8(6):1197 comparison between inclusions in aluminium killed steels and (徐敏,刘中财,严晓,等.容量增量内阻一致性在线检测方法 deposits in submerged entry nozzle.Steel Res Int,2003,74(6): 储能科学与技术,2019,8(6):1197) 351 [19]Hong J C,Wang Z P,Liu P.Big-data-based thermal runaway [30]Wang M,Bao Y P,Yang Q.Effect of Ferro-titanium alloying prognosis of battery systems for electric vehicles.Energies,2017 process on steel cleanness.J Univ Sci Technol Beijing,2013, 10(7):919 35(6):725 [20]Duan F C,Wu HZ.The production practice of ultra-low-carbon (王敏,包燕平,杨荃钛合金化过程对钢液洁净度的影响.北京 steel in thin slab continuous casting.Ind Heat,2007,36(6):73 科技大学学报,2013,35(6):725) (段富春,吴华章.薄板坯连铸超低碳钢生产实践.工业加热 [31]Pan M.Yu H X,Ji CX.et al.Effect of oxygen blowing during RH 2007,36(6):73) treatment on the cleanliness of IF steel.Chin J Eng,2020,42(7): [21]Song MT,Li M G,Yu H C.Research on refining process of ultra- 846 low-carbon steel for thin slab casting.Steelmaking,2009,25(3):8 (潘明,于会香,季晨曦,等,RH精炼过程中吹氧量对1F钢洁净度 (宋满堂,李明光,于华财.超低碳钢薄板坯连铸钢水精炼工艺 的影响.工程科学学报,2020.42(7):846) 的研究.炼钢,2009,25(3):8) [32]Gao S,Wang M,Guo J L,et al.Evaluation of cleanliness and [22]Shen C,Song C,Shu H F,et al.Research of ULC steel production distribution of inclusions in the thickness direction of interstitial route combining RH-LF refining and CSP line.Iron Steel,2008, free(IF)steel slabs.Chin J Eng,2020,42(2):194 43(5):26 (高帅,王敏,郭建龙,等F钢铸坯厚度方向夹杂物分布及洁净 (沈昶,宋超,舒宏富,等.CSP批量生产超低碳钢的RHLF双联 度评估.工程科学学报,2020,42(2):194) 工艺研究.钢铁,2008,43(5):26) [33]Stone R P,Jr.Figas R M,Branion R V.Productivity improvements [23]Liang Y J,Che Y C.Handle of Inorganic Thermody Namic Data. in steelmaking via sensor-based steelmaking process control.Iron Shenyang:Northeast University Press,1993 Steel Technol,2006,3(1):31production. Iron Steel, 2010, 45(8): 33 (刘柏松, 李本海, 朱国森, 等. 常规RH和RH-TOP工艺精炼IF钢 试验研究. 钢铁, 2010, 45(8):33) Li D M, Zhang W H, Lin L P, et al. Application of RH oxygen top￾blowing  technology  in  No.2  Steel-making  Plant,  WISCO. Steelmaking, 2007, 23(6): 5 (李大明, 张文辉, 林立平, 等. RH顶吹氧技术在武钢第二炼钢厂 的应用. 炼钢, 2007, 23(6):5) [15] Yuan B H, Liu J H, Zhou H L, et al. The vacuum decarburization process optimization study of high altitude RH refining equipment. Steelmaking, 2020, 36(4): 31 (袁保辉, 刘建华, 周海龙, 等. 高海拔RH精炼装置真空脱碳工艺 优化研究. 炼钢, 2020, 36(4):31) [16] Liu M, Bai F Q, Chen S S, et al. Application of water irrush source standard  set  in  mine  water  prevention. Miner Eng Res,  2014, 29(3): 30 (刘猛, 白峰青, 陈少帅, 等. 水源判别标准集在矿井防治水中的 应用. 矿业工程研究, 2014, 29(3):30) [17] Xu  M,  Liu  Z  C,  Yan  X,  et  al.  Online  detection  method  for incremental  capacity  internal  resistance  consistency. Energy Storage Sci Technol, 2019, 8(6): 1197 (徐敏, 刘中财, 严晓, 等. 容量增量内阻一致性在线检测方法. 储能科学与技术, 2019, 8(6):1197) [18] Hong  J  C,  Wang  Z  P,  Liu  P.  Big-data-based  thermal  runaway prognosis of battery systems for electric vehicles. Energies, 2017, 10(7): 919 [19] Duan F C, Wu H Z. The production practice of ultra-low-carbon steel in thin slab continuous casting. Ind Heat, 2007, 36(6): 73 (段富春, 吴华章. 薄板坯连铸超低碳钢生产实践. 工业加热, 2007, 36(6):73) [20] Song M T, Li M G, Yu H C. Research on refining process of ultra￾low-carbon steel for thin slab casting. Steelmaking, 2009, 25(3): 8 (宋满堂, 李明光, 于华财. 超低碳钢薄板坯连铸钢水精炼工艺 的研究. 炼钢, 2009, 25(3):8) [21] Shen C, Song C, Shu H F, et al. Research of ULC steel production route  combining  RH-LF  refining  and  CSP  line. Iron Steel,  2008, 43(5): 26 (沈昶, 宋超, 舒宏富, 等. CSP批量生产超低碳钢的RH-LF双联 工艺研究. 钢铁, 2008, 43(5):26) [22] Liang Y J, Che Y C. Handle of Inorganic Thermody Namic Data. Shenyang: Northeast University Press, 1993 [23] ( 梁英教, 车荫昌. 无机物热力学数据手册. 沈阳: 东北大学出版 社, 1993) Cheng  G  G,  Zhao  P,  Xu  X  L,  et  al.  Process  of  vacuum denitrogenation of steel. Iron Steel, 1999, 34(1): 16 (成国光, 赵沛, 徐学禄, 等. 真空下钢液脱氮工艺研究. 钢铁, 1999, 34(1):16) [24] Cao  S.  Control  of  end  nitrogen  content  in  smelting  of  ultra-low nitrogen steel with converter. Hebei Metall, 2015(10): 14 (曹盛. 超低氮钢转炉终点氮含量控制. 河北冶金, 2015(10):14) [25] Kitamura  T,  Miyamoto  K,  Tsujino  R,  et  al.  Mathematical  model for  nitrogen  desorption  and  decarburization  reaction  in  vacuum degasser. ISIJ Int, 1996, 36(4): 395 [26] Wang M, Bao Y P, Cui H, et al. The composition and morphology evolution of oxide inclusions in Ti-bearing ultra low-carbon steel melt refined in the RH process. ISIJ Int, 2010, 50(11): 1606 [27] Tang F P, Chang G H, Li H, et al. Inclusions in ultra-low carbon steel. Iron Steel, 2007, 42(1): 20 (唐复平, 常桂华, 栗红, 等. 超低碳钢钢中夹杂物的研究. 钢铁, 2007, 42(1):20) [28] Dekkers  R,  Blanpain  B,  Wollants  P,  et  al.  A  morphological comparison  between  inclusions  in  aluminium  killed  steels  and deposits  in  submerged  entry  nozzle. Steel Res Int,  2003,  74(6): 351 [29] Wang  M,  Bao  Y  P,  Yang  Q.  Effect  of  Ferro-titanium  alloying process  on  steel  cleanness. J Univ Sci Technol Beijing,  2013, 35(6): 725 (王敏, 包燕平, 杨荃. 钛合金化过程对钢液洁净度的影响. 北京 科技大学学报, 2013, 35(6):725) [30] Pan M, Yu H X, Ji C X, et al. Effect of oxygen blowing during RH treatment on the cleanliness of IF steel. Chin J Eng, 2020, 42(7): 846 (潘明, 于会香, 季晨曦, 等. RH精炼过程中吹氧量对IF钢洁净度 的影响. 工程科学学报, 2020, 42(7):846) [31] Gao  S,  Wang  M,  Guo  J  L,  et  al.  Evaluation  of  cleanliness  and distribution  of  inclusions  in  the  thickness  direction  of  interstitial free(IF) steel slabs. Chin J Eng, 2020, 42(2): 194 (高帅, 王敏, 郭建龙, 等. IF钢铸坯厚度方向夹杂物分布及洁净 度评估. 工程科学学报, 2020, 42(2):194) [32] Stone R P, Jr. Figas R M, Branion R V. Productivity improvements in steelmaking via sensor-based steelmaking process control. Iron Steel Technol, 2006, 3(1): 31 [33] 袁保辉等: RH 强制脱碳与自然脱碳工艺生产 IF 钢精炼效果分析 · 1115 ·
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