S690Q高强钢对接节点的焊后性能

doi:10.11835/j.issn.2096-6717.2020.014

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S690Q高强钢对接节点的焊后性能
DOI:
                        10.11835/j.issn.2096-6717.2020.014
                    
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作者:
                        周诚彬周诚彬
新加坡理工大学, 新加坡 138683, 新加坡
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陈成陈成
南洋理工大学, 新加坡 639798, 新加坡
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赵明善赵明善
新加坡理工大学, 新加坡 138683, 新加坡
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李子敬李子敬
新南威尔士大学, 堪培拉, 澳大利亚
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冯达清冯达清
南洋理工大学, 新加坡 639798, 新加坡
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中图分类号:TU391;TU511.3
基金项目:Regency Steel Asia Endowment Fund at Nanyang Technological University

Post-welding behaviour of S690Q high strength steel butt joints

Author:

CHIEW Sing Ping
CHIEW Sing Ping
Singapore Institute of Technology, Singapore 138683, Singapore
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CHEN Cheng
CHEN Cheng
Nanyang Technological University, Singapore 639798, Singapore
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ZHAO Ming Shan
ZHAO Ming Shan
Singapore Institute of Technology, Singapore 138683, Singapore
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LEE Chi King
LEE Chi King
University of New South Wales, Canberra, Australia
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FUNG Tat Ching
FUNG Tat Ching
Nanyang Technological University, Singapore 639798, Singapore
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摘要:

通过试验研究了S690Q高强钢对接节点的焊后性能。利用手工电弧焊焊接了3个厚度为8 mm的S690Q高强钢对接节点，焊接过程中对3个节点分别采用不同的焊接热量。在微观层面上，用微观结构测试和微观硬度测试研究焊接对于节点的影响；在宏观层面上，通过拉伸试验研究焊接对于节点力学性能的影响。微观结构测试结果表明，S690Q高强钢的主要微观结构是回火马氏体。焊接后，在粗晶热影响区会转化为粒状贝氏体，在细晶热影响区会转化为铁素体和渗碳体，在回火区部分回火马氏体会分解成铁素体。基于硬度测试结果，可以在热影响区内发现软化层的存在，软化层与母材相比具有较低的硬度。此外，热影响区的宽度也随着焊接热量的升高而增大。拉伸试验表明，焊接对于S690Q高强钢节点的强度具有劣化作用，这主要是由焊接过程中形成的软化层造成的。所有测试节点的失效位置均位于热影响区，而且随着焊接热量的升高，强度的劣化现象也变得越来越严重。

关键词:高强钢;对接节点;微观结构;硬度;拉伸性能

Abstract:

In this study, we investigated the post-welding behaviour of S690Q high strength steel butt joints experimentally. Three S690Q high strength steel butt joints were welded with 8 mm thickness plate by shield metal arc welding with different welding heat inputs. Microstructure observation and micro-hardness test of heat-affected zone were employed to reveal the welding influence on the joints at the micro level, and tensile test of S690Q high strength steel butt joints showed the welding impact at the macro level. The microstructure test indicated that the main microstructure of the S690Q high strength steel was tempered martensite and was transformed to granular bainite in the coarse-grained heat-affected zone and to ferrite and cementite in the fine-grained heat-affected zone after welding of the joints. In the tempering zone, some of the tempered martensite decomposed to ferrite. Based on the hardness test results, it can be observed there is a soft layer in the heat-affected zone with lower hardness compared with the base material. In addition, the width of the heat-affected zone increased in the joint welded with higher heat input. The subsequent tensile test showed that the formation of a soft layer directly impairs the tensile behaviour of S690Q high strength steel butt joints, and the strength deterioration becomes more serious with the increase of the welding heat input.

Key words:high strength steel;butt joint;microstructure;hardness;tensile behavior

参考文献

[1] MIKI C, HOMMA K, TOMINAGA T. High strength and high performance steels and their use in bridge structures[J]. Journal of Constructional Steel Research, 2002, 58(1):3-20.

[2] CHEN J, YOUNG B, UY B. Behavior of high strength structural steel at elevated temperatures[J]. Journal of Structural Engineering, 2006, 132(12):1948-1954.

[3] QIANG X H, BIJLAARD F S K, KOLSTEIN H. Dependence of mechanical properties of high strength steel S690 on elevated temperatures[J]. Construction and Building Materials, 2012, 30:73-79.

[4] CHIEW S P, ZHAO M S, LEE C K. Mechanical properties of heat-treated high strength steel under fire/post-fire conditions[J]. Journal of Constructional Steel Research, 2014, 98:12-19.

[5] QIANG X H, BIJLAARD F S K, KOLSTEIN H. Post-fire mechanical properties of high strength structural steels S460 and S690[J]. Engineering Structures, 2012, 35:1-10.

[6] HOCHHAUSER F, ERNST W, RAUCH R, et al. Influence of the soft zone on the strength of welded modern HSLA steels[J]. Welding in the World, 2012, 56(5/6):77-85.

[7] BOUMERZOUG Z, DERFOUF C, BAUDIN T. Effect of welding on microstructure and mechanical properties of an industrial low carbon steel[J]. Engineering, 2010, 2(7):502-506.

[8] LAMBERT-PERLADE A, GOURGUES A F, PINEAU A. Austenite tobainite phase transformation in the heat-affected zone of a high strength low alloy steel[J]. Acta Materialia, 2004, 52(8):2337-2348.

[9] WOJNOWSKI D, OH Y K, INDACOCHEA J E. Metallurgical assessment of the softened HAZ region during multipass welding[J]. Journal of Manufacturing Science and Engineering, 2000, 122(2):310-315.

[10] MAURER W, ERNST W, RAUCH R, et al. Evaluation of the factors influencing the strength of HSLA steel weld joint with softened HAZ[J]. Welding in the World, 2015, 59(6):809-822.

[11] CHEN C, CHIEW S P, ZHAO M S, et al. Welding effect on tensile strength of grade S690Q steel butt joint[J]. Journal of Constructional Steel Research, 2019, 153:153-168.

[12] KLEIN M, SPINDLER H, LUGER A, et al.Thermomechanically hot rolled high and ultra high strength steel grades-processing, properties and application[J]. Materials Science Forum, 2005, 500/501:543-550.

[13] DE MEESTER B. The weldability of modern structural TMCP steels[J]. ISIJ International, 1997, 37(6):537-551.

[14] Structural Welding Code-Steel:AWS D1.1[S]. American National Standards Institute, Miami, 2008.

[15] LI Y, CROWTHER D N, GREEN M J W, et al. The effect of vanadium and niobium on the properties and microstructure of the intercritically reheated coarse grained heat affected zone in low carbon microalloyed steels[J]. ISIJ International, 2001, 41(1):46-55.

[16] KHAN M I, KUNTZ M L, BIRO E, et al. Microstructure and mechanical properties of resistance spot welded advanced high strength steels[J]. Materials Transactions, 2008, 49(7):1629-1637.

[17] PENG K, YANG C L, FAN C L, et al. Thermal processes, microstructure, and mechanical properties near weld toe in double-sided double gas tungsten arc backing welding joint of 10CrNi₃MoV steel[J]. The International Journal of Advanced Manufacturing Technology, 2018, 96(1-4):677-684.

[18] RAN M M, SUN F F, LI G Q, et al. Experimental study on the behavior of mismatched butt welded joints of high strength steel[J]. Journal of Constructional Steel Research, 2019, 153:196-208.

[19] Metallic Materials-Vickers Hardness Test:BSI 6507-1[S]. British Standards Institution, London, 2005.

[20] Tensile Testing of Metallic Materials:Part1 Method of Test at Ambient Temperature:BSI, EN 10002-1[S]. British Standards Institution, London, 2001.

引用本文

周诚彬,陈成,赵明善,李子敬,冯达清. S690Q高强钢对接节点的焊后性能[J].土木与环境工程学报（中英文）,2021,43(1):64-71. CHIEW Sing Ping, CHEN Cheng, ZHAO Ming Shan, LEE Chi King, FUNG Tat Ching. Post-welding behaviour of S690Q high strength steel butt joints[J]. JOURNAL OF CIVIL AND ENVIRONMENTAL ENGINEERING,2021,43(1):64-71.10.11835/j. issn.2096-6717.2020.014

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收稿日期:2019-05-01
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在线发布日期: 2021-02-02
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