Quoc Tuan Phan, M. Kohno, Y. Murakami, Hoang Long Nguyen
{"title":"Modeling of Creep Behavior of High Strength Steel H-SA700 Columns at Elevated Temperature","authors":"Quoc Tuan Phan, M. Kohno, Y. Murakami, Hoang Long Nguyen","doi":"10.3210/fst.41.1","DOIUrl":null,"url":null,"abstract":"Creeps is a significant component affecting steel's behavior at elevated temperatures. This paper describes an approach for using Abaqus finite element models to investigate the creep behavior of high strength steel H-SA700 with a yield strength of at least 700 MPa under high temperature conditions. The creep models developed in this research were used to characterize the creep behavior of steel column. They were based on a set of tensile tests conducted at temperatures ranging from 23 ° C to 600 ° C under constant temperature conditions. The mechanical properties of steel were adopted from the tensile test specified by JIS G 0567. The results of the tensile tests indicated that creep effects occur when the temperature of steel exceeds 400 ° C and the creep effect is regarded to be strongest at 500 ° C. Additionally, a user subroutine CREEP was designed to account for the creep effect of the high strength steel H-SA700. The factors affecting the time-dependent behavior of high strength steel, including the initial imperfection of columns, have been explored. The thermal expansion coefficients of this steel have been also identified. Taking creep behavior into account, it could be able to reasonably simulate the behavior of H-SA700 column during a fire test. Furthermore, this paper develops and explains a process for determining steel creep parameters without creep tests, which can be used to forecast the time-dependent behavior of other steel structures. on the general high temperature tensile test without doing creep test. The application of the developed method in considering thermal creep of steel at elevated temperatures conditions is further shown through the study of time dependent response of a column subjected to a fire. Finally, this paper develops and discusses the procedure for determining steel creep parameters and applying them to predict the creep behavior of other steel structures.","PeriodicalId":12289,"journal":{"name":"Fire Science and Technology","volume":"60 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2022-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Fire Science and Technology","FirstCategoryId":"1087","ListUrlMain":"https://doi.org/10.3210/fst.41.1","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Creeps is a significant component affecting steel's behavior at elevated temperatures. This paper describes an approach for using Abaqus finite element models to investigate the creep behavior of high strength steel H-SA700 with a yield strength of at least 700 MPa under high temperature conditions. The creep models developed in this research were used to characterize the creep behavior of steel column. They were based on a set of tensile tests conducted at temperatures ranging from 23 ° C to 600 ° C under constant temperature conditions. The mechanical properties of steel were adopted from the tensile test specified by JIS G 0567. The results of the tensile tests indicated that creep effects occur when the temperature of steel exceeds 400 ° C and the creep effect is regarded to be strongest at 500 ° C. Additionally, a user subroutine CREEP was designed to account for the creep effect of the high strength steel H-SA700. The factors affecting the time-dependent behavior of high strength steel, including the initial imperfection of columns, have been explored. The thermal expansion coefficients of this steel have been also identified. Taking creep behavior into account, it could be able to reasonably simulate the behavior of H-SA700 column during a fire test. Furthermore, this paper develops and explains a process for determining steel creep parameters without creep tests, which can be used to forecast the time-dependent behavior of other steel structures. on the general high temperature tensile test without doing creep test. The application of the developed method in considering thermal creep of steel at elevated temperatures conditions is further shown through the study of time dependent response of a column subjected to a fire. Finally, this paper develops and discusses the procedure for determining steel creep parameters and applying them to predict the creep behavior of other steel structures.
蠕变是影响钢在高温下性能的一个重要因素。本文介绍了一种利用Abaqus有限元模型研究屈服强度700mpa以上高强度钢H-SA700在高温条件下蠕变行为的方法。采用所建立的蠕变模型对钢柱的蠕变行为进行了表征。它们是基于在恒温条件下在23°C至600°C的温度范围内进行的一组拉伸试验。钢的力学性能采用JIS G 0567规定的拉伸试验。拉伸试验结果表明,当钢的温度超过400℃时,徐变效应就会发生,而在500℃时徐变效应最强。此外,还设计了一个用户子程序creep来解释H-SA700高强度钢的徐变效应。探讨了影响高强钢时效性能的因素,包括柱的初始缺陷。还确定了这种钢的热膨胀系数。考虑蠕变特性,可以合理地模拟H-SA700柱在火灾试验中的行为。此外,本文还开发并解释了一种无需蠕变试验即可确定钢结构蠕变参数的方法,该方法可用于预测其他钢结构的随时间变化的性能。对一般高温拉伸试验不做蠕变试验。该方法在高温条件下考虑钢的热蠕变时的应用,通过对火灾下柱的时效响应的研究进一步得到了证明。最后,本文发展和讨论了确定钢结构蠕变参数的方法,并将其应用于预测其他钢结构的蠕变行为。