固溶温度对LNG储罐用高锰钢组织与性能的影响

doi:10.13251/j.issn.0254-6051.2026.01.018

金属热处理 ›› 2026, Vol. 51 ›› Issue (1): 124-132.DOI: 10.13251/j.issn.0254-6051.2026.01.018

固溶温度对LNG储罐用高锰钢组织与性能的影响

齐祥羽^1,2, 刘攀³, 严玲^1,2, 苏幼明⁴, 刘鹏程^1,2, 刘粤龙⁴

1.海洋装备用金属材料及其应用国家重点实验室, 辽宁鞍山 114009;
2.鞍钢集团钢铁研究院, 辽宁鞍山 114009;
3.国家管网集团建设项目管理分公司, 河北廊坊 065001;
4.国家管网集团闽投(福建)天然气有限责任公司, 福建漳州 363106

收稿日期:2025-08-04 修回日期:2025-11-06 出版日期:2026-01-25 发布日期:2026-01-27
通讯作者: 刘攀,工程师,E-mail:liupan01@pipechina.com.cn
作者简介:齐祥羽(1988—),男,工程师,博士,主要研究方向为材料成形过程中的组织性能控制,E-mail:qixiangyu881029@163.com,

Effect of solution treatment temperature on microstructure and properties of high manganese steel for liquefied natural gas tanks

Qi Xiangyu^1,2, Liu Pan³, Yan Ling^1,2, Su Youming⁴, Liu Pengcheng^1,2, Liu Yuelong⁴

1. State Key Laboratory of Metal Material for Marine Equipment and Application, Anshan Liaoning 114009, China;
2. Iron and Steel Research Institute of ANGANG Group, Anshan Liaoning 114009, China;
3. Construction Project Management Branch of China National Petroleum Pipeline Network Group Co., Ltd., Langfang Hebei 065001, China;
4. Pipe China Fujian Investment Co., Ltd., Zhangzhou Fujian 363106, China

Received:2025-08-04 Revised:2025-11-06 Online:2026-01-25 Published:2026-01-27

摘要/Abstract

摘要： 通过OM、SEM、EBSD、EPMA、TEM等分析手段和拉伸、冲击和硬度测试研究了固溶温度对LNG储罐用高锰钢显微组织和力学性能的影响。结果表明:试验钢在500 ℃固溶处理时,其组织性能与热轧钢板相比未发生明显变化;固溶温度为600~800 ℃时,奥氏体晶粒尺寸为10~15 μm,晶界处析出大量碳化物,屈服强度由400 MPa降低至379 MPa,抗拉强度几乎无变化,为879~880 MPa,-196 ℃冲击吸收能量较差,仅50 J左右;当固溶温度升高至900~1000 ℃时,屈服强度和抗拉强度急剧降低,-196 ℃冲击吸收能量升高。当热轧钢板在600~800 ℃固溶处理时,沿晶界析出的(Cr, Mn)₂₃C₆型碳化物显著降低了奥氏体晶界间的结合力,降低了冲击裂纹形成功和裂纹扩展功,从而严重恶化试验钢的低温韧性。当固溶温度升高至1000 ℃后,试验钢的-196 ℃冲击吸收能量达180 J,晶界处的碳化物完全回溶,晶粒长大,在冲击载荷作用下产生大量机械孪晶,甚至激活二次孪晶系统,有效抑制裂纹的行核和扩展,是试验钢低温韧性优异的主要原因。

关键词: 高锰钢, 固溶处理, 低温冲击韧性, 机械孪晶, (Cr, Mn)₂₃C₆型碳化物

Abstract: Effect of solution treatment temperature on microstructure and mechanical properties of a high manganese steel for LNG storage tanks was studied by means of OM, SEM, EBSD, EPMA, TEM and tensile, impact and hardness tests. The results show that compared with the hot-rolled steel plates, there is no significantly change in microstructure and properties of the steel after solution treatment at 500 ℃. When the solution treatment temperature is 600-800 ℃, the austenite grain size is 10-15 μm, and a large amount of carbides precipitate at the austenite grain boundaries, so that the yield strength decreases from 400 MPa to 379 MPa, while the tensile strength remains almost unchanged (879-880 MPa), meanwhile, the impact absorbed energy at -196 ℃ is poor, which is only about 50 J. When the solution treatment temperature rises to 900-1000 ℃, the yield strength and tensile strength decrease sharply, and the impact absorbed energy at -196 ℃ increases. When the solution treatment temperature is 600-800 ℃, the (Cr, Mn)₂₃C₆ carbides precipitated along the grain boundaries significantly reduce the bonding force of austenite grain boundaries, lower the impact crack formation energy and crack propagation energy, and thus seriously deteriorate the low-temperature impact toughness of the steel. When the solution treatment temperature rises to 1000 ℃, the impact absorbed energy at -196 ℃ is 180 J, the carbides at the grain boundaries completely dissolve back, the grains grow, and a large number of mechanical twins are generated under impact loads, even activating the secondary twin system, effectively suppressing the nucleation and propagation of cracks, which is the main reason for the excellent low-temperature toughness of the steel the impact abserbed energy at -196 ℃ is 180 J.

Key words: high manganese steel, solution treatment, low-temperature impact toughness, mechanical twin, (Cr, Mn)₂₃C₆ type carbide

中图分类号:

TG156

齐祥羽, 刘攀, 严玲, 苏幼明, 刘鹏程, 刘粤龙. 固溶温度对LNG储罐用高锰钢组织与性能的影响[J]. 金属热处理, 2026, 51(1): 124-132.

Qi Xiangyu, Liu Pan, Yan Ling, Su Youming, Liu Pengcheng, Liu Yuelong. Effect of solution treatment temperature on microstructure and properties of high manganese steel for liquefied natural gas tanks[J]. Heat Treatment of Metals, 2026, 51(1): 124-132.

参考文献

[1] Yang J, Dong H G, Li P, et al. Analysis of microstructural evolution and mechanical properties in the simulated heat-affected zone of Fe-23Mn-0.45C-1.5Al high-Mn austenitic steel[J]. Journal of Materials Research and Technology, 2022, 20: 1110-1126.
[2] Sohn S S, Hong S, Lee J H, et al. Effects of Mn and Al contents on cryogenic-temperature tensile and Charpy impact properties in four austenitic high-Mn steels[J]. Acta Materialia, 2015, 100: 39-52.
[3] Park M, Kang M, Park G W, et al. The effects of post weld heat treatment for welded high-Mn austenitic steels using the submerged arc welding method[J]. Journal of Materials Research and Technology, 2022, 18: 4497-4512.
[4] Wang Y W, Wang H H, Su Y H, et al. Cryogenic impact fracture behavior of a high-Mn austenitic steel using electron backscatter diffraction and neutron Bragg-edge transmission imaging[J]. Materials Science and Engineering A, 2023, 887: 145768.
[5] 张福成, 陈晨, 刘帅, 等. 高锰钢研究进展: 成分、组织和性能调控[J]. 钢铁, 2024, 59(3): 1-18, 78.
Zhang Fucheng, Chen Chen, Liu Shuai, et al. A review on high manganese steels: Control of chemical composition, microstructure and properties[J]. Iron and Steel, 2024, 59(3): 1-18, 78.
[6] Tang L, Wang L, Wang M, et al. Synergistic deformation pathways in a TWIP steel at cryogenic temperatures: in situ neutron diffraction[J]. Acta Materialia, 2020, 200: 943-958.
[7] Tao X, Thomas J C, Ao Q S, et al. Active screen plasma nitriding of Fe-24Mn-2Al-0.45C TWIP steel: Microstructure evolution and a synergistic selective oxidation mechanism[J]. Acta Materialia, 2022, 241: 118418.
[8] Ren J K, Chen Q Y, Chen J, et al. On mechanical properties of welded joint in novel high-Mn cryogenic steel in terms of microstructural evolution and solute segregation[J]. Metals, 2020, 10(4): 478.
[9] 陈俊, 刘宁, 刘振宇, 等. LNG储罐用高锰钢合金化设计及强韧性[J]. 中国冶金, 2023, 33(6): 73-80.
Chen Jun, Liu Ning, Liu Zhenyu, et al. Alloying design as well as strength and toughness of high Mn steels for LNG tank building[J]. China Metallurgy, 2023, 33(6): 73-80.
[10] Luo Q, Wang H H, Li G Q, et al. On mechanical properties of novel high-Mn cryogenic steel in terms of SFE and microstructural evolution[J]. Materials Science and Engineering A, 2019, 753: 91-98.
[11] Chen J, Ren J K, Liu Z Y. Deformation microstructures as well as strengthening and toughening mechanisms of low-density high Mn steels for cryogenic applications[J]. Journal of Materials Research and Technology, 2021, 13: 947-961.
[12] 齐祥羽, 严玲, 王长顺, 等. LNG储罐用高锰钢中厚板生产技术开发[J]. 轧钢, 2023, 40(2): 24-29.
Qi Xiangyu, Yan Ling, Wang Changshun, et al. Production technology development of high manganese steel plate for liquefied natural gas tanks[J]. Steel Rolling, 2023, 40(2): 24-29.
[13] Zhang S C, Wang H H, Wang Y W, et al. Study on the novel high manganese austenitic steel welded joints by arc welding for cryogenic applications of LNG tanks[J]. Materials, 2023, 16(6): 2381.
[14] 于洪军, 程福超, 马泽天, 等. 不同水韧处理工艺下铌微合金化高锰钢的组织演变和力学性能[J]. 金属热处理, 2022, 47(4): 151-154.
Yu Hongjun, Cheng Fuchao, Ma Zetian, et al. Microstructure evolution and mechanical properties of Nb-alloyed high manganese steel under different water toughening processes[J]. Heat Treatment of Metals, 2022, 47(4): 151-154.
[15] 孙士斌, 陈文聪, 王东胜, 等. 固溶处理对新型全奥氏体高锰低温钢微观组织、力学性能及摩擦性能的影响[J]. 摩擦学报, 2024, 44(5): 655-665.
Sun Shibin, Chen Wencong, Wang Dongsheng, et al. Effect of solution treatment on wear resistance of a new type of austenitic high manganese low temperature steel[J]. Tribology, 2024, 44(5): 655-665.
[16] 杨壹, 刘让贤, 杨浩坤, 等. 固溶温度对轻质高锰钢组织及性能的影响[J]. 金属热处理, 2023, 48(8): 113-117.
Yang Yi, Liu Rangxian, Yang Haokun, et al. Effect of solution temperature on microstructure and properties of lightweight high manganese steel[J]. Heat Treatment of Metals, 2023, 48(8): 113-117.
[17] Kang S, Jung Y S, Jun J H, et al. Effects of recrystallization annealing temperature on carbide precipitation, microstructure, and mechanical properties in Fe-18Mn-0.6C-1.5Al TWIP steel[J]. Materials Science and Engineering A, 2010, 527: 745-751.
[18] 杨江. 低温高锰钢焊接热影响区组织演变与力学性能研究[D]. 大连: 大连理工大学, 2022.
Yang Jiang. Microstructural evolution and mechanical properties in heat-affected zone of cryogenic high-Mn steel[D]. Dalian: Dalian University of Technology, 2022.
[19] Chen J, Ren J K, Liu Z Y, et al. Interpretation of significant decrease in cryogenic-temperature Charpy impact toughness in a high manganese steel[J]. Materials Science and Engineering A, 2018, 737: 158-165.
[20] Jeong S, Lee Y C, Park G, et al. Phase transformation and the mechanical characteristics of heat-affected zones in austenitic Fe-Mn-Al-Cr-C lightweight steel during post-weld heat treatment[J]. Materials Characterization, 2021, 177: 111150.
[21] Chen P, Li X, Yi H. The κ-carbides in low-density Fe-Mn-Al-C steels: A review on their structure, precipitation and deformation mechanism[J]. Metals, 2020, 10: 1021-1035.
[22] Kim K W, Park S J, Moon J, et al. Characterization of microstructural evolution in austenitic Fe-Mn-Al-C lightweight steels with Cr content[J]. Materials Characterization, 2020, 170: 110717.
[23] Lejcek P, Hofmann S. Thermodynamics and structural aspects of grain boundary segregation[J]. Critical Reviews in Solid State and Materials Sciences, 1995, 20: 1-85.
[24] Dong R F, Li J S, Zhang T B, et al. Elements segregation and phase precipitation behavior at grain boundary in a Ni-Cr-W based superalloy[J]. Materials Characterization, 2016, 122: 189-196.
[25] 郭倩颖, 李彦默, 陈斌, 等. 高温时效处理对S31042耐热钢组织和蠕变性能的影响[J]. 金属学报, 2021, 57(1): 82-94.
Guo Qianying, Li Yanmo, Chen Bin, et al. Effect of high-temperature ageing on microstructure and creep properties of S31042 heat-resistant steel[J]. Acta Metallurgica Sinica, 2021, 57(1): 82-94.

固溶温度对LNG储罐用高锰钢组织与性能的影响

Effect of solution treatment temperature on microstructure and properties of high manganese steel for liquefied natural gas tanks

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	王天琪, 李浩然, 刘海华, 李晨东. 热处理对316L钢/Inconel625镍基合金双金属增材结构件微观组织与力学性能的影响[J]. 金属热处理, 2026, 51(1): 207-213.
[2]	庄迎. 碳含量与固溶处理对316不锈钢板的晶间腐蚀与高温性能的影响[J]. 金属热处理, 2025, 50(9): 109-112.
[3]	杨恬, 孙上清, 田彦文, 王涛, 任勇. 固溶处理温度和冷却速率对TC6钛合金组织与性能的影响[J]. 金属热处理, 2025, 50(9): 151-155.
[4]	杨富云, 桑绍柏, 杨启宝, 李亚伟, 王恒, 朱天彬. 超高锰钢Fe-24Mn-4Cr-0.6C的氧化行为[J]. 金属热处理, 2025, 50(8): 24-29.
[5]	王潇维, 郭胤岑, 樊善明, 彭明军, 张帅博, 段永华, 周晓龙, 李萌蘖. 固溶时效处理对轧制Al-Mg-Si合金组织与力学性能的影响[J]. 金属热处理, 2025, 50(8): 137-143.
[6]	汤耀景, 潘福荣, 郑杨, 王林海, 王宝旦, 鲍臣鹏, 徐彬, 岳亮. 斜坡固溶处理对镍基单晶高温合金组织与性能的影响[J]. 金属热处理, 2025, 50(8): 162-168.
[7]	张皓月, 唐正友, 崔峰, 张瀚文, 王镇轩. 固溶温度对Fe-Mn-Al-C奥氏体低密度钢组织与性能的影响[J]. 金属热处理, 2025, 50(7): 18-23.
[8]	甘婵, 陈懿, 张义飞, 臧千昊, 陈洪美. 固溶处理对Mg-6Gd-3Y-1.5Zn-0.6Zr稀土镁合金组织的影响[J]. 金属热处理, 2025, 50(7): 73-80.
[9]	苗秉希, 康纪龙, 马志尧, 李嘉胜, 王星浩, 高明玉, 褚克, 强小虎. Al-20Si-xCu过共晶合金的固溶处理及力学性能[J]. 金属热处理, 2025, 50(7): 112-117.
[10]	陈越, 冯绍棠, 汤皓元, 李恒, 孙彦华, 岳有成, 谭国寅, 吴昌贵. 固溶处理对7075铝合金挤压棒材组织与性能的影响[J]. 金属热处理, 2025, 50(7): 255-259.
[11]	向雨欣, 何建丽, 王志海, 刘锦林. 固溶处理对WE43稀土镁合金组织和性能的影响[J]. 金属热处理, 2025, 50(5): 168-174.
[12]	吕晗, 石帅, 马腾飞, 赵林林, 郭瑞华, 安会龙, 赵燕青. 固溶温度对Fe-Mn-Al-C轻质奥氏体钢组织与性能的影响[J]. 金属热处理, 2025, 50(5): 258-262.
[13]	李侠, 贾品峰, 耿旭, 崔东卫. 固溶工艺对2A12铝合金组织与性能的影响[J]. 金属热处理, 2025, 50(4): 213-217.
[14]	郭旭东, 邹仕军, 卢影峰, 龙泽熙. 固溶工艺对7C04铝合金组织与性能的影响[J]. 金属热处理, 2025, 50(3): 132-137.
[15]	杨婷, 潘进, 王程明, 马成, 佘亚东. 焊材用低温高锰钢的热变形行为与热加工图[J]. 金属热处理, 2025, 50(3): 220-226.