Effect of solution temperature on microstructure and properties of Fe-Mn-Al-C lightweight austenitic steel

doi:10.13251/j.issn.0254-6051.2025.05.040

Abstract

Abstract: Effect of solution temperature on microstructure, mechanical properties and fracture morphology of the Fe-Mn-Al-C lightweight austenitic steel was studied by means of optical microscope, scanning electron microscope, spectrometer, tensile testing machine, and impact testing machine. The results show that the tested steel exhibits a density of 6.92 g·cm^-3, corresponding to a density reduction of approximately 11.95% compared to pure iron. Optimal mechanical properties achieve after solution treatment at 1000 ℃ for 1 h, with product of strength and elongation of 37.80 GPa·%, yield strength of 586 MPa, tensile strength of 864 MPa, elongation of 43.7%, and impact absorbed energy of 110.3 J at -20 ℃. Between 900-1050 ℃, as the solution treatment temperature increases, the intergranular κ^*-carbides gradually dissolve, while there are still a large number of small granular κ′-carbides inside the austenite grains that can hinder dislocation movement, and the grain size gradually increases. While, when the solution treatment temperature exceeds 1000 ℃, the phenomenon of abnormal grain growth leads to significant deterioration of the mechanical properties of the material. With the increase of solution temperature, the density of dimples on the impact fracture increases, and the size and depth show a clear growth trend. At the same time, the tearing edge also increases significantly. This microscopic feature is well matched with the improvement of macroscopic mechanical properties.

Key words: solution treatment, high manganese austenitic steel, low density steel, microstructure, mechanical properties

CLC Number:

TG161

Lü Han, Shi Shuai, Ma Tengfei, Zhao Linlin, Guo Ruihua, An Huilong, Zhao Yanqing. Effect of solution temperature on microstructure and properties of Fe-Mn-Al-C lightweight austenitic steel[J]. Heat Treatment of Metals, 2025, 50(5): 258-262.

References

[1] 谢敬佩. 耐磨铸钢及熔炼[M]. 北京: 机械工业出版社, 2003: 45-52.
[2] 刘少尊, 王春旭, 厉勇, 等. 时效温度对固溶态Fe-Mn-Al-C低密度钢性能与析出相的影响[J]. 金属热处理, 2015, 40(11): 103-107.
Liu Shaozun, Wang Chunxu, Li Yong, et al. Effect of aging temperature on properties and precipitation of Fe-Mn-Al-C low-density steel[J]. Heat Treatment of Metals, 2015, 40(11): 103-107.
[3] 赵燕青, 齐建军, 孙力, 等. 终轧温度对高锰奥氏体低温钢组织和力学性能的影响[J]. 河北冶金, 2022(6): 14-16, 22.
Zhao Yanqing, Qi Jianjun, Sun Li, et al. Effect of finishing rolling temperature on microstructure and mechanical properties of high manganese austenitic low temperature steel[J]. Hebei Metallurgy, 2022(6): 14-16, 22.
[4] Chen S P, Rana R, Haldar A, et al. Current state of Fe-Mn-Al-C low density steels[J]. Progress in Materials Science, 2017, 89: 345-391.
[5] 满廷慧, 彭伟, 王子波, 等. Fe-Mn-Al-C低密度钢研究现状及展望[J]. 中国冶金, 2022, 32(1): 11-20.
Man Tinghui, Peng Wei, Wang Zibo, et al. Research progress and prospect of Fe-Mn-Al-C low-density steels[J]. China Metallurgy, 2022, 32(1): 11-20.
[6] 章小峰, 李家星, 万亚雄, 等. 低密度中有序析出相的研究进展[J]. 材料导报, 2019, 33(12): 3979-3989.
Zhang Xiaofeng, Li Jiaxing, Wan Yaxiong, et al. Research progress of ordered precipitates in low-density steels[J]. Materials Reports, 2019, 33(12): 3979-3989.
[7] 魏学源, 尚进, 陈斌, 等. 固溶温度对热轧Fe-Mn-Al-C低密度高强钢组织和性能的影响[J]. 金属热处理, 2019, 44(8): 142-146.
Wei Xueyuan, Shang Jin, Chen Bin, et al. Effect of solution treatment temperature on microstructure and properties of hot-rolled Fe-Mn-Al-C low density high strength steel[J]. Heat Treatment of Metals, 2019, 44(8): 142-146.
[8] Zhang J, Jiang Y, Zheng W, et al. Revisiting the formation mechanism of intragranular κ-carbide in austenite of a Fe-Mn-Al-Cr-C low-density steel[J]. Scripta Materialia, 2021, 199(3): 113836.
[9] 刘春泉, 彭其春, 薛正良, 等. Fe-Mn-Al-C系列低密度高强钢的研究现状[J]. 材料导报, 2019, 33(15): 2572-2581.
Liu Chunquan, Peng Qichun, Xue Zhengliang, et al. Research situation of Fe-Mn-Al-C system low-density high-strength steel[J]. Materials Reports, 2019, 33(15): 2572-2581.
[10] 邢梅, 林方敏, 唐立志, 等. Al元素对Fe-Mn-Al-C系低密度钢的影响特性综述[J]. 中国冶金, 2022, 32(2): 15-26.
Xing Mei, Lin Fangmin, Tang Lizhi, et al. Effect of Al on properties of Fe-Mn-Al-C low density steel[J]. China Metallurgy, 2022, 32(2): 15-26.

[1]	Tong Shankang, Wang Wei, Gan Xiaolong, Xue Zhengliang, Tian Hao, Li Desheng, Xu Guang. Microstructure evolution and mechanical properties of bearing steel for tunnel boring machine during hot rolling and spheroidizing annealing process [J]. Heat Treatment of Metals, 2025, 50(5): 9-15.
[2]	Zeng Kailun, Wang Yingchun, Yang Bin, Qiu Xuyangfan, Gu Jinbo, Chi Hongxiao, Cheng Xingwang. Effect of cryogenic treatment on microstructure and mechanical properties of a low carbon Cr-Co-Mo-Ni high alloy bearing steel [J]. Heat Treatment of Metals, 2025, 50(5): 22-26.
[3]	Xie Zhaoyuan, Yin Defu, Jiang Ting, Zhou Dayuan, Wang Kaizhong, Ding Lei. Formation and elimination of abnormal ultra-fine microstructure on surface of GCr15 bearing steel bar [J]. Heat Treatment of Metals, 2025, 50(5): 27-32.
[4]	Guo Chuncheng, Li Haihong, Zeng Xijun, Zhou Kai, Xin Zhenfei, Chi Hongxiao, Ma Dangshen. Effect of Mo on high-temperature long-term mechanical properties and microstructure evolution of a heat-resistant bearing steel [J]. Heat Treatment of Metals, 2025, 50(5): 51-56.
[5]	Zhao Jiali, Song Jinhao, Xin Ruishan, Zhang Xinjie, Shang Xuyang, Zhao Leijie, Wang Yanhui. Surface microstructure and properties of a novel carburized 22Cr2Ni3SiMo bearing steel [J]. Heat Treatment of Metals, 2025, 50(5): 66-71.
[6]	Zhao Zibo, Hui Weijun, Zhao Xiaoli, Zheng Hongwei, Jiang Ye, Wang Shuai. Effect of nickel on CCT curve and hardenability of a Si-Mn-Cr-B type ultrahigh strength spring steel [J]. Heat Treatment of Metals, 2025, 50(5): 72-78.
[7]	Zhao Miaomiao, Du Linxiu, Cao Yi, Huang Yan. Microstructure nanostructuring and mechanical properties of304 stainless steel containing copper [J]. Heat Treatment of Metals, 2025, 50(5): 101-106.
[8]	Huo Litu, Ma Tao, Gao Jianxin, Bi Xiao, Li Yungang. Research status of Fe-Mn-Al-C low-density steel and prospect of Nb alloying application [J]. Heat Treatment of Metals, 2025, 50(5): 116-123.
[9]	Yuan Zhizhong, Niu Zongran, Wang Zhiyuan, Ju Yulin, Xu Huixia, Liao Jun, Yu Yang, Cheng Xiaonong. Effect of solution time on microstructure and properties of powder stainless steel D41A [J]. Heat Treatment of Metals, 2025, 50(5): 132-139.
[10]	Hua Xuebing, Yuan Qing, Zhang Qingxiao, Xiong Le. Effect of annealing temperature on microstructure and properties of a bimodal ultrafine-grained high-strength steel [J]. Heat Treatment of Metals, 2025, 50(5): 152-159.
[11]	Zou Zezhi, Chen Zhiyan, Liu Huiqun, Wu Haihong. Effect of aging process on microstructure and mechanical properties of C17200 beryllium bronze [J]. Heat Treatment of Metals, 2025, 50(5): 160-167.
[12]	Xiang Yuxin, He Jianli, Wang Zhihai, Liu Jinlin. Effect of solution treatment on microstructure and properties of WE43 rare earth magnesium alloy [J]. Heat Treatment of Metals, 2025, 50(5): 168-174.
[13]	Niu Xuemei, Jing Linwang, Huang Yao, Yan Xianguo, Chen Zhi. Effect of cryogenic treatment on microstructure and mechanical properties of 6061 aluminum alloy [J]. Heat Treatment of Metals, 2025, 50(5): 175-180.
[14]	Chen Rui, Chen Baoan, Li Menglin, Han Yu, Zhu Zhixiang, Hou Shixiang, Yang Changlong, Zheng Wei. Precipitation behavior and recrystallization of Al-Fe-Cu alloy wire during annealing [J]. Heat Treatment of Metals, 2025, 50(5): 189-194.
[15]	Li Zheng, Zhang He, Wang Piaoyang, Fu Wenjun, Xu Yujun. Effect of PWHT on microstructure and properties of Q690D steel butt joints [J]. Heat Treatment of Metals, 2025, 50(5): 208-213.