Abstract:The effect of carbon content on the microstructure and mechanical properties of Q235B steel for electric power tower fittings was studied by mechanical properties test and microstructural observation of a series of hanging plate fittings with different compositions and five groups of test steels with different carbon contents. The strengthening effect of Q235B steel depended on the composite action of various strengthening methods. With the increase of carbon content, the solid solution strengthening effect in ferrite matrix was enhanced. With the increase of volume fraction of the second phase (i.e., pearlite), the strengthening effect was enhanced. The following conclusions were obtained: the pearlite content in microstructure of Q235B steel increased with the increase of carbon content, leading to the increase of tensile strength but the decrease of plasticity and toughness. As the carbon content (mass fraction) was less than 0.068%, the pearlite content in the structure was low, and the strength of the material decreased. For the sake of service safety of electric power tower fittings, its carbon content in Q235B steel should not be less than 0.068% within the standard range to ensure the sufficient strength.
陈鹏, 刘晓明, 李振荣, 韩少强, 刘明, 钟振前. 电力铁塔金具材料碳含量与组织和性能关系探讨[J]. 冶金分析, 2022, 42(3): 84-89.
CHEN Peng, LIU Xiaoming, LI Zhenrong, HAN Shaoqiang, LIU Ming, ZHONG Zhenqian. Discussion on the relationship between carbon content and microstructure and properties of electric power tower fittings. , 2022, 42(3): 84-89.
[1] 邹国林,从怀贤,吕泉根,等.我国架空输电线路金具技术发展及应用[J].江苏电机工程,2012,31(6):82-84. ZOU Guolin,CONG Huaixian,LÜ Quangen,et al. Development and application of chinese overhead transmission line fitting technology[J].Jiangsu Electrical Engineering, 2012,31(6):82-84. [2] 陈胜男,何卫,杜挺,等.输电线路金具用材料及其应用技术研究进展[J].电工技术,2019(15):149-153. CHEN Shengnan,HE Wei,DU Ting,et al.Research progress on materials for transmission line fittings and their processing technology[J].Electric Engineering,2019(15):149-153. [3] 王宝东,姜喜全,陈平,等.寒冷地区输电线路金具材料的试验研究与选择[J].吉林电力,2018,46(3):31-33. WANG Baodong,JIANG Xichuan,CHEN Ping.Test and study on the material of transmission line fittings in the cold region[J].Jilin Electric Power,2018,46(3):31-33. [4] 柴志华,张树林,蔚泽廷.220kV忻义线116号金具断裂分析[J].山西电力,2013(2):67-69. CHAI Zhihua,ZHANG Shulin,WEI Zeting.The fracture analysis of No.116 fitting on the 220 kV Xinyi line[J].Shanxi Electric Power,2013(2):67-69. [5] 刘禹门.铁素体珠光体钢的变形和断裂[J].金属热处理学报,1982,3(1):1-10. LIU Yumen.Deformation and fracture of ferrite-pearlite steel[J].Transactions of Metal Heat Treatment,1982,3(1):1-10. [6] 任学冲,王国珍,王玉良,等.铁素体-珠光体组织中解理微裂纹形成的细观力学分析[J].兰州理工大学学报,2004,30(5):1-4. REN Xuechong,WANG Guozhen,WANG Yuliang,et al.Mesoscopic mechanical analysis of cleavage micro-crack forming in ferrite-pearlite microstructure[J].Journal of Lanzhou University of Technology,2004,30(5):1-4. [7] 徐永波,刘民治.珠光体组织的形变、裂纹形核与扩展微观过程的动态研究[J].金属学报,1982,18(1):58-63. XU Yongbo,LIU Minzhi.Dynamic study of crack nucleation and propagation of pearlite during deformation[J].Acta Metallurgica Sinica,1982,18(1):58-63. [8] 刘靖,鹿守理.低碳钢组织与力学性能关系[J].北京科技大学学报,2002,24(2):208-210. LIU Jing,LU Shouli.Relationship between microstructure and properties in low carbon steel[J].Journal of University of Science and Technology Beijing,2002,24(2):208-210.
