Research and Development of 10B38 Boron Containing
Cold Heading Steel

doi:10.20057/j.1003-8620.2023-00210

Abstract

Abstract: The strength and plasticity of 10B38 boron containing cold heading steel under different high temperature condi⁃ tions were studied using high-temperature tensile testing method. The results showed that the tensile strength decreased significantly from 124. 8 MPa to 22. 9 MPa at temperatures ranging from 700 to 950 ℃； At 950 to 1 150 ℃， the tensile strength was 12. 7 to 25. 5 MPa. In terms of thermoplastic properties， the cross-sectional shrinkage rate at 700-750 ℃ was 56%-72%； When the temperature was between 800 and 1 050 ℃， the cross-sectional shrinkage rate was ≥ 75%； When the temperature was between 1 050 and 1 150 ℃， the cross-sectional shrinkage rate was greater than 65%. Based on the above experimental data， the strength of the secondary cooling water in continuous casting was optimized from a specific water content of 1. 35 L/kg to a specific water content of 1. 25 L/kg. After optimization， the crack index of the continuous casting slab was significantly reduced. The dynamic CCT curves of 10B38 boron containing cold heading steel were mea⁃ sured， The experimental results showed that when the cooling rate was 0. 2-1 ℃/s， the test steel was mainly composed of softer ferrite structure； When the cooling rate was 3-10 ℃/s， the experimental steel was mainly composed of pearlite struc⁃ ture； When the cooling rate was 20 ℃/s and 30 ℃/s， the structure of the test steel was flat noodles martensite+pearlite； When the cooling rate was 50 ℃/s， a complete martensitic structure was formed at room temperature. The experimental re⁃ sults showed that by reducing the cooling rate to 0. 5-2 ℃/s， ideal ferrite and pearlite hot-rolled structures can be obtained.

Key words: 10B38 Cold Heading Steel, High-temperature Tensile, CCT Curves

摘要： 采用高温拉伸试验方法，研究了不同高温条件下10B38含硼冷镦钢的强度和塑性。试验结果表明，在热强性方面，700～950 ℃时抗拉强度由124. 8 MPa大幅下降到22. 9 MPa；950～1 150 ℃时抗拉强度为12. 7～25. 5 MPa。在热塑性方面，700～750 ℃时试验钢的断面收缩率为 56%～72%；800～1 050 ℃时，试验钢的断面收缩率≥75%； 1 050～1 150 ℃时，断面收缩率＞65%。根据以上试验数据，将连铸二次冷却水强度由比水量1. 35 L/kg优化为比水量 1. 25 L/kg，优化后连铸坯裂纹指标有明显降低。测定了 10B38含硼冷镦钢的过冷奥氏体连续冷却转变曲线，试验结果表明，当冷却速率为0. 2～1 ℃/s，试验钢以较软的铁素体组织为主；当冷却速率为3～10 ℃/s，试验钢以珠光体组织为主；当冷却速率为20、30 ℃/s时，试验钢为板条马氏体+珠光体组织；当冷却速率为50 ℃/s时，室温时形成完全马氏体组织。试验及生产试制结果表明，降低冷却速率到 0. 5～2 ℃/s，能获得理想的铁素体和珠光体热轧组织。

关键词: 10B38冷镦钢, 高温拉伸, CCT曲线

CLC Number:

TG142. 1

Ma Liguo, Guo Dayong, Wang Bingxi, Gao Hang , Zhang Bo, Pan Yang. Research and Development of 10B38 Boron Containing Cold Heading Steel[J]. Special Steel, 2024, 45(3): 10-14.

马立国, 郭大勇, 王秉喜, 高航, 张博, 潘阳.

10B38含硼冷镦钢的研制与开发

[J]. 特殊钢, 2024, 45(3): 10-14.

[1]	Yang　Ting, Duan　Luzhao, Liu　Xu, Bai　Lijuan, Zhang　Yunfei, Sun　Li. Continuous Cooling Phase Transformation Prediction Model of 20CrMnTiH [J]. Special Steel, 2024, 45(1): 82-86.
[2]	Liu Zhaoxia, Liu Jun, Xu Guangqing, Ning Kangkang , Xu Xiaohong. Continuous Cooling Transformation Behavior of Austenite in EH47 Crack-Resistant Steel [J]. Special Steel, 2020, 41(4): 68-70.
[3]	Li Shilin , Ruan Shipeng , Wang Lijun , Wang Ningtao, . Continuous Cooling Transformation Behavior of Hot Deformation Austenite in 15MnVB Steel 160 mm x 160 mm Casting Billet [J]. Special Steel, 2019, 40(3): 5-7.
[4]	Pan Xianming, Du Kun, Li Gang, Xiang Huajun, Yang Huangguang , Wang Chuan. A Study on CCT Curves and Quenching-Tempering Process of New HSLA Steel S690 Φ219 mm x 14 mm Seamless Tube [J]. Special Steel, 2018, 39(4): 12-16.
[5]	Dong Qing, Kong Lingbo, Li Shilin. Effect of Cooling Rate on Structure and Cold-Heading Crack of Ф6.5〜12mm Coil of Steel SCM435 [J]. Special Steel, 2017, 38(6): 37-39.
[6]	Li Shengli , Sun Ao , Sun Yiting , Zhou Cheng , Yan Ling. Dynamic Continuous Cooling Transformation Curves of High Strength Hull Structural Steel EH460 [J]. Special Steel, 2017, 38(2): 64-66.
[7]	Hua Wenlin, Yang Xiuzhi, Yang Chunjie , Dong Chunfa. Behavior of Phase Transformation of X70 V-Nb Microalloying Steel Tube for Deep-Sea Pipe-Line during Continuous Cooling [J]. Special Steel, 2017, 38(1): 66-69.
[8]	Wen Cheng , Jiang Bo , Yang Zhong, Wang Hailong, Liu Yazheng. A Study on Continuous Cooling Transformation of ø170 mm Hot-Rolled Products of Non-Quenching-and-Tempering Steel C38N2 [J]. Special Steel, 2014, 35(1): 57-60.
[9]	Zhu Min , Ren Anchao , Xu Guang, Ji Yu. Continuous Cooling Transformation Curves of H Beam Steel 0.11C-0. 25Si-1.50Mn-0.038Nb for Offshore Oil Platform [J]. Special Steel, 2012, 33(6): 36-38.
[10]	Wang Shengzhao , Zhao Gang, Bao Siqian. Phase Transformation and Structure of Steel WL510 for Automobile Beam during Continuous Cooling [J]. Special Steel, 2012, 33(6): 56-58.
[11]	Wang Qian, Yuan Zexi, Song Xinli. Measurement of CCT Curves and Effect of Cooling Rate on Structure of a Pipeline Steel L360NB [J]. Special Steel, 2012, 33(5): 54-56.
[12]	Mao Xinping , Xie Liqun. Continuous Cooling Transformation Curves of Steel 30CrMo Produced by Thin Slab Casting and Rolling Process and Its Application [J]. Special Steel, 2012, 33(3): 44-46.
[13]	Wang Fengqi , Xu Guang , Chen Jing , Bu Conghua , Zou Hang. Continuous Cooling Transformation Curves of C-Mn-Si Series Super-Bainite Steel [J]. Special Steel, 2012, 33(2): 68-70.
[14]	Zeng Xianping, Lu Junyi , Wang Wenlu. Effect of Cooling Rate of Hot-Deformed Austenite on Structure and Property of X80 Pipeline Steel [J]. Special Steel, 2010, 31(1): 63-65.
[15]	Wang Bowen , Hang Naiqin. Optimization for Control-Cooling Process of High Speed Rolled Wire of Steel 82A [J]. Special Steel, 2009, 30(6): 14-16.

Research and Development of 10B38 Boron Containing Cold Heading Steel

10B38含硼冷镦钢的研制与开发

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