| METALS AND METAL MATRIX COMPOSITES |
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| Experimental Study on Mechanical Properties of High Strength Q460 Steel After Foam Extinguishing |
| CHEN Guangpeng1, ZHANG Chuntao1,2
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1 School of Civil Engineering and Architecture, Southwest University of Science and Technology, Mianyang 621010, China
2 Shock and Vibration of Engineering Materials and Structures Key Laboratory of Sichuan Province, Mianyang 621010, China |
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Abstract High strength Q460 steel is extensively used in building construction due to its potential benefits over high strength and cost efficiency. Its performance in fire is very important to assess the extent of its fire damage and reusability. This paper presents the details of an experimental investigation on the post-fire mechanical properties of high strength Q460 steel after air and firefighting foam cooling. Tensile tests are performed on specimens exposed to elevated temperatures varying from 200 ℃ to 900 ℃ and then cooled down to room temperature in air or in extinguisher foam. The results from this investigation provided post-fire stress-strain curves, yield strengths, ultimate strength, elastic modulus, ultimate elongation and their residual factors. Systematic comparative analysis for the differences of mechanical properties of Q460, Q690 and Q235 steels are carried out. Significant differences are observed on the surface after exposing different high temperature and cooling in various media. The inf-luence of high temperature and cooling methods on elastic modulus is negligible, while sharp reduction is especially noted in the yield strength, ultimate strength and ultimate elongation. In addition, it is found that the loss of mechanical properties of Q460 steel is negligible for exposure tempe-rature up to 500 ℃ and cooling in air or in extinguisher foam. When exposed to 900 ℃, the yield strength, ultimate strength and ultimate elongation of high strength Q460 steel cooling in air are able to retain 38%, 67% and 107% of their ambient temperature capacity, whereas the yield strength, ultimate strength and ultimate elongation after foam extinguishing can retain 39%, 67% and 131% of their ambient temperature capacity. Finally, predictive equations are proposed for simple evaluation of post-fire material performance of Q460 steel. The results can be used to eva-luate the mechanical performance of Q460 steel structures after fire.
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Published: 23 March 2021
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| Fund:Natural Science Foundation of China (51508482), National College Student Innovation and Entrepreneurship Training Program (S202010619026) and Postgraduate Innovation Fund Project by Southwest University of Science and Technology (20ycx0044). |
About author:: Guangpeng Chen graduated from Southwest University of Science and Technology with a bachelor's degree in engineering in June 2018. From September 2018 to the present, he is studying for a master's degree at Southwest University of Science and Technology, and is engaged in the research of engineering structure, enginee-ring materials and engineering mechanics.
Chuntao Zhang is an associate professor of Southwest University of Science and Technology. He graduated from the School of Civil Engineering of Chongqing University in December 2012, and is mainly engaged in the research of structural engineering, fatigue damage and reliability analysis. He has published more than 50 articles in major domestic and foreign journals and applied for more than 10 patents. |
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1 Shi G,Ban H Y, Shi Y J, et al. Engineering Mechanics,2013,30(1),1(in Chinese).
施刚,班慧勇,石永久,等.工程力学,2013,30(1),1.
2 Luo Y F, Ren C C, Qiang X H, et al. Journal of Tianjin University(Science and Technology),2016,49(S1),104(in Chinese).
罗永峰,任楚超,强旭红,等.天津大学学报(自然科学与工程技术版),2016,49(S1),104.
3 Li G Q, Wang W Y. China Civil Engineering Journal,2017,50(12),1(in Chinese).
李国强,王卫永.土木工程学报,2017,50(12),1.
4 Wang W Y, Liu T Z. Journal of Building Materials,2016,19(1),171(in Chinese).
王卫永,刘天姿.建筑材料学报,2016,19(1),171.
5 Li G Q, Lv H B, Zhang C. Journal of Building Structures,2017,38(5),109(in Chinese).
李国强,吕慧宝,张超.建筑结构学报,2017,38(5),109.
6 Qiang X H, Wu N D, Jiang X, et al. Journal of Tongji University(Natural Science),2016,44(7),1076(in Chinese).
强旭红,武念铎,姜旭,等.同济大学学报(自然科学版),2016,44(7),1076.
7 Gao X F, Zhang X P, Liu H B, et al. Construction and Building Mate-rials,2018,165,82.
8 Wang Y L, Song K X, Zhang Y M, et al. Materials Science & Enginee-ring A,2019,746,127.
9 Metallic materials-tensile testing at elevated temperature: GB/T 4338-2006, Standards Press of China, 2006(in Chinese).
金属材料高温拉伸试验方法:GB/T 4338-2006,中国标准出版社,2006.
10 Li H T, Ben Y. Journal of Constructional Steel Research,2018,148,562.
11 Li G Q, Huang L, Zhang C. Journal of Tongji University(Natural Science),2018,46(2),170(in Chinese).
李国强,黄雷,张超.同济大学学报(自然科学版),2018,46(2),170.
12 Li Guoqiang, Huang Lei, Zhang Chao. Journal of Architecture and Civil Engineering,2018,35(3),1(in Chinese).
李国强,黄雷,张超.建筑科学与工程学报,2018,35(3),1.
13 Qiang X H, Wu K D, Jiang X, et al. Journal of Hunan University(Natural Science),2018,45(11),37(in Chinese).
强旭红,毋凯冬,姜旭,等.湖南大学学报(自然科学版),2018,45(11),37.
14 Zhang Y J, Zhu Y, Zhao S, et al. Structural Engineers,2009,25(5),104(in Chinese).
张有桔,朱跃,赵升,等.结构工程师,2009,25(5),104.
15 Ding F X, Yu Z W, Wen H L. Journal of Building Materials,2006,9(2),245(in Chinese).
丁发兴,余志武,温海林.建筑材料学报,2006,9(2),245. |
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2021, Vol. 35 
