纯铁中间层对热轧不锈钢复合板性能的影响

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摘要针对不锈钢和碳钢热轧复合时，结合界面容易形成脆性化合物而影响复合板机械性能的问题。本文在轧制温度为1000℃、1100℃以及1200℃，压下量约为70%条件下，进行了添加不同厚度纯铁中间层的真空热轧复合实验；通过光学显微镜、SEM观察以及拉伸试验等，研究了纯铁中间层对复合板界面微观组织和拉伸性能的影响。结果表明，当加入不同厚度纯铁中间层时，同温度下不锈钢/碳钢复合板拉伸性能都有不同程度的提高。并且在小于70%压下量下，2mm厚度的纯铁中间层可以完全阻止碳钢中的碳元素向不锈钢侧扩散，避免了碳铬化合物的形成，使结合界面的组织得到改善、机械性能得到提高。

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关键词 ：不锈钢复合板, 热轧复合, 纯铁中间层, 机械性能

Abstract：In view of the problem that brittle compounds are easily formed at the bonding interface of stainless steel and carbon steel during hot rolling, which affects the mechanical properties of composite plates. In this paper, the vacuum hot rolling composite experiment with different thickness of pure iron interlayer was carried out under the conditions of rolling temperature of 1000℃, 1100℃, 1200 ℃and reduction of about 70%. The effect of pure iron interlayer on the interfacial microstructure and tensile properties of composite plate was studied by optical microscopy, SEM observation and tensile test. The results show that the tensile properties of stainless steel/carbon steel composite plates are improved to varying degrees at the same temperature when different thickness of pure iron interlayer was added. And under less than 70% reduction，2 mm thick pure iron interlayer can completely prevent the carbon element in carbon steel from diffusing to stainless steel side, avoid the formation of carbochromium compounds, so as to improve the microstructure of the bonding interface and mechanical properties.

Key words： stainless steel clad plate hot rolled composite pure iron interlayer mechanical properties

收稿日期: 2019-08-09 出版日期: 2020-03-19

引用本文:

赵云鹏余超肖宏吴宗河许朋朋谢红飙. 纯铁中间层对热轧不锈钢复合板性能的影响[J]. , 2020, 55(5): 0-0. Hong Xiao. Effect of pure iron interlayer on mechanical properties of hot rolled stainless steel clad plate. , 2020, 55(5): 0-0.

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[1]	T. Koseki，J. Inoue，S. Nambu，Development of multilayer steels for improved combinations of high strength and high ductility[J], Materials Transactions，2014，55（2）：227-237.
[2]	SU Hang，LUO Xiao-bing，CHAI, Feng，et al. Manufacturing Technology and Application Trends of Titanium Clad Steel Plates[J]. Journal of Iron and Steel Research, International，2015，22（11）：977-982.
[3]	Bouaziz O，Masse J P，Petitgand G，et al. A Novel Strong and Ductile TWIP/Martensite Steel Composite[J]. Advanced Engineering Materials，2016，18（1）：6-59.
[4]	YU Chao，XIAO Hong，YU Hui，et al. Mechanical properties and interfacial structure of hot-roll bonding TA2/Q235B plateusing DT4 interlayer[J]. Materials Science and Engineering：A，2017，695（1）：120.
[5]	代响林，刘宝玺，马久乐，等. 真空热轧法制备不锈钢复合板组织和力学性能[J]. 钢铁，2017，52（2）：65. （DAI Xiang-lin，LIU Bao-xi，MA Jiu-le，et al. Microstructure and mechanical properties of stainless steel clad plate prepared by vacuum hot rolling[J]. Iron and Steel，2017，52（2）：65.）
[6]	LI Long，YIN Fu-xing，Kotobu Nagai. Progress of laminated materials and clad steels production[J]. Materials Science Forum，2011：439-447.
[7]	ZHANG Shao-kun，XIAO Hong，XIE Hong-biao. The preparation and property research of the stainless steel/iron scrap clad plate[J]. Journal of Materials Processing Technology，2014，214（6）：1205.
[8]	Kacar R , Acarer M. An investigation on the explosive cladding of 316L stainless steel-din-P355GH steel[J]. Journal of Materials Processing Technology，2004，152（1）：91-96.
[9]	Ka?ar R，Acarer M. Microstructure–property relationship in explosively welded duplex stainless steel–steel[J]. Materials Science & Engineering A (Structural Materials: Properties, Microstructure and Processing)，2003，363（1-2）：290-296.
[10]	张心金，李龙，刘会云，等. 中间夹层在金属复合板制造过程中的应用[J]. 轧钢，2013，30（6）：45.（ZHANG Xin-jin，LI Long，LIU Hui-yun，et al. Application of insert layer in manufacturing clad metal plates[J]. Steel Rolling，2013，30（6）：45.）
[11]	谢红飙,王德蔚,余超,等.纯铁做中间材制备不锈钢/碳钢热轧复合板[J]. 钢铁，2017，52（12）：48-53. （XIE Hong-biao,WANG De-wei，YU Chao，et al. Stainless steel/carbon steel composite plate prepared by hot-roll bonding with pure iron as intermediate material[J]. Iron and Steel，2017，52（12）：48-53. ）
[12]	刘宝龙，张慧芳，肖振兴，等. 316L/Q345R热轧复合板界面组织演变及性能[J]. 钢铁，2017，52（5）：72.（LIU Bao-long，ZHANG Hui-fang，XIAO Zhen-xing，et al. Microstructure evolution and properties of interface in 316L/Q345R hot rolled clad plate[J]. Iron and Steel，2017，52（5）：72.）
[13]	LI Hao，ZHANG Li-yuan，ZHANG Bo-yang，et al. Microstructure characterization and mechanical properties of stainless steel clad plate[J]. Materials，2019，12：509
[14]	CHEN C X，LIU M Y，LIU B X，et al. Tensile shear sample design and interfacial shear strength of stainless steel clad plate[J]. Fusion Engineering and Design，2017，125：431-441.
[15]	LIU B X，WANG S，FANG W，et al. Microstructure and mechanical properties of hot rolled stainless steel clad plate by heat treatment[J]. Materials Chemistry and Physics，2018，216：460-467.
[16]	WANG S，LIU B X，CHEN C.X，et al. Microstructure, mechanical properties and interface bonding mechanism of hot-rolled stainless steel clad plates at different rolling reduction ratios[J]. Journal of Alloys and Compounds，2018，766：517-526.
[17]	LIU B X，YIN F X，DAI X L，et al. The tensile behaviors and fracture characteristics of stainless steel clad plates with different interfacial status[J]. Materials Science & Engineering A，2017，679：172-182.
[18]	JING Y，QIN Y，ZANG X M，et al. The bonding properties and interfacial morphologies of clad plate prepared by multiple passes hot rolling in a protective atmosphere[J]. Journal of Materials Processing Technology，2014（214）：1686.
[19]	YANG Gong-xian，XU Yong-feng，JIANG Lei，et al. High temperature tensile properties and fracture behavior of cast nickel-base K445 superalloy[J]. Progress in Natural Science: Materials International，2011，21（5）：418-425.