Mechanical properties of high strength steels S460 and S690 after fire

被引：0

作者：

Qiang X. ^{[1
]}

Wu N. ^{[1
]}

Jiang X. ^{[1
]}

Luo Y. ^{[1
]}

机构：

[1] College of Civil Engineering, Tongji University, Shanghai

来源：

Harbin Gongye Daxue Xuebao/Journal of Harbin Institute of Technology | 2017年 / 49卷 / 02期

关键词：

High strength steel; Mechanical properties; Post-fire; Predictive equation; Residual factor;

D O I：

10.11918/j.issn.0367-6234.2017.02.021

中图分类号：

学科分类号：

摘要：

The load bearing capacity of steel structures after fire reduces mainly due to the deterioration of its mechanical properties. This paper presented an experimental study on material properties of high strength steels S460 and S690 after fire. The post-fire elastic modulus, yield and ultimate strengths, ductility and stress-strain curves were obtained and compared with the post-fire mechanical properties of mild strength steels. It is found that when the fire temperature from which the high strength steel is cooled down is less than or equal to 600℃, S460 and S690 can regain their original mechanical properties. When the fire temperature is up 1000℃, S460 can also regain more than 75% of its original mechanical properties, but S690 only regains 64.5% of its original elastic modulus, 38.1% of its original yield strength and 57.3% of its original ultimate strength. The mechanical properties of high strength steels are different from mild strength steels. Predictive equations were proposed to evaluate the post-fire material properties of S460 and S690.Comparing with the test results, the predictive equations were validated. The predictive equations can be employed for practical inspection and appraisal of steel structures after fire with members made of S460 and S690, and provide a reference for the revision of current worldwide leading design standards. © 2017, Editorial Board of Journal of Harbin Institute of Technology. All right reserved.

引用

页码：130 / 138

页数：8

共 23 条

[11] Lange J., Wohlfeil N., Examination of the mechanical properties of the microalloyed grain refined steel S460 at elevated temperatures, Bautechnik, 84, pp. 711-720, (2007)
[12] Schneider R., Lange J., Constitutive equations of structural steel S460 at high temperatures, Nordic Steel Construction Conference 2009, pp. 204-211, (2009)
[13] Schneider R., Lange J., Constitutive equations and empirical creep law of structural steel S460 at high temperatures, Structures in Fire 2010, pp. 703-710, (2010)
[14] Schneider R., Lange J., Material and creep behavior of S460 in case of fire experimental investigation and analytical modeling, International Conference Application of Structural Fire Engineering, pp. 55-60, (2011)
[15] Young B., Chen J., Uy B., Behavior of high strength structural steel at evaluated temperatures, J Struct Eng ASCE, 132, pp. 1948-1954, (2006)
[16] Chen J., Cao P., Experimental investigation into mechanical properties of steel post high temperatures, Journal of PLA University of Science and Technology, 11, 3, (2010)
[17] Ding F., Yu Z., Wen H., Experimental research on mechanical properties of Q235 steel after high temperature treatment, Journal of Building Materials, 9, 2, (2006)
[18] Zhang Y., Zhu Y., Zhao S., Et al., Experimental research on mechanial properties of steel cooled in different modes after high temperature treatment, Structural Engineers, 25, 5, (2009)
[19] BS 5950-8, tructural use of steelwork in building-part 8: Code of practice for fire resistant design, (1998)
[20] Hot rolled products of structural steels-part 3: Technical delivery conditions for normalized/normalized rolled weldable fine grain structural steels, (2004)

← 1 2 3 →