Kara Stall, Andrea Culhane, Likun Sun, Rachel Chicchi Cross, Matthew Steiner
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The A656/A656M Gr. 80 plate material showed more variation between the two different plate thicknesses in both mechanical behavior and microstructure due to differences in steel production. The 0.375 in. thick plate exhibited a clear yield plateau with an ultimate/yield stress ratio similar to the Gr. 50 material. In contrast, the 0.5 in. plate did not have a yield plateau and reached lower ultimate strain. The residual stress testing was performed using a sectioning technique for one A572/A572M Gr. 50 and five A656/A656M Gr. 80 built-up sections that were fabricated from 0.5 in. and 0.375 in. plate material. Residual stresses obtained from measurements were compared to previously published predictive models. The ECCS model and BSK99 models were found to be reasonable predictors of residual stresses for all specimens except the one section fabricated from 0.5 in. thick Gr. 80 plate. When comparing the Gr. 50 and Gr. 80 specimens of the same cross-sectional geometry, the residual stresses were similar, implying that cross-sectional geometry is more prevalent than the nominal yield stress in determining residual stresses in built-up I-sections.","PeriodicalId":11618,"journal":{"name":"Engineering Journal","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-07-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Tensile Coupon Testing and Residual Stress Measurements of High-Strength Steel Built-Up I-Shaped Sections\",\"authors\":\"Kara Stall, Andrea Culhane, Likun Sun, Rachel Chicchi Cross, Matthew Steiner\",\"doi\":\"10.62913/engj.v61i3.1326\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"High strength structural steels (with yield stresses greater than 65 ksi) may have notably different material characteristics when compared to structural steels conventionally used in building construction [i.e., ASTM A992/A992M (2022) or A572/A572M Gr. 50 (2021)]. This paper presents findings from an experimental program that investigated the material characterization of ASTM A656/A656M Gr. 80 (2024) plate steel. The results obtained were compared to conventional ASTM A572/A572M Gr. 50 steel. Two types of testing were performed for this work: tensile coupon testing and residual stress testing. The tensile coupon testing was carried out for both the A656/A656M Gr. 80 and A572/A572M Gr. 50 plate material. The A656/A656M Gr. 80 plate material showed more variation between the two different plate thicknesses in both mechanical behavior and microstructure due to differences in steel production. The 0.375 in. thick plate exhibited a clear yield plateau with an ultimate/yield stress ratio similar to the Gr. 50 material. In contrast, the 0.5 in. plate did not have a yield plateau and reached lower ultimate strain. The residual stress testing was performed using a sectioning technique for one A572/A572M Gr. 50 and five A656/A656M Gr. 80 built-up sections that were fabricated from 0.5 in. and 0.375 in. plate material. Residual stresses obtained from measurements were compared to previously published predictive models. The ECCS model and BSK99 models were found to be reasonable predictors of residual stresses for all specimens except the one section fabricated from 0.5 in. thick Gr. 80 plate. 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引用次数: 0
摘要
高强度结构钢(屈服应力大于 65 ksi)与建筑施工中常用的结构钢[即 ASTM A992/A992M (2022) 或 A572/A572M Gr. 50 (2021)]相比,可能具有明显不同的材料特性。本文介绍了一项实验计划的结果,该计划研究了 ASTM A656/A656M Gr. 80 (2024) 板钢的材料特性。获得的结果与传统的 ASTM A572/A572M Gr. 50 钢进行了比较。这项工作进行了两种类型的测试:拉伸试样测试和残余应力测试。对 A656/A656M Gr. 80 和 A572/A572M Gr. 50 钢板材料都进行了拉伸试样测试。由于钢材生产的不同,A656/A656M Gr. 80 钢板材料在机械性能和微观结构方面的差异较大。0.375 英寸厚的钢板表现出明显的屈服平台,极限/屈服应力比与 Gr.相比之下,0.5 英寸厚的钢板没有屈服高原,极限应变也较低。残余应力测试采用切片技术,对由 0.5 英寸和 0.375 英寸钢板材料制成的一个 A572/A572M Gr. 50 和五个 A656/A656M Gr. 80 构建截面进行了测试。通过测量获得的残余应力与之前公布的预测模型进行了比较。结果发现,ECCS 模型和 BSK99 模型是所有试样残余应力的合理预测模型,只有一个试样是用 0.5 英寸厚的 Gr. 80 板材制造的。在比较横截面几何形状相同的 Gr. 50 和 Gr. 80 试样时,残余应力相似,这意味着横截面几何形状比标称屈服应力更能决定加固 I 型截面中的残余应力。
Tensile Coupon Testing and Residual Stress Measurements of High-Strength Steel Built-Up I-Shaped Sections
High strength structural steels (with yield stresses greater than 65 ksi) may have notably different material characteristics when compared to structural steels conventionally used in building construction [i.e., ASTM A992/A992M (2022) or A572/A572M Gr. 50 (2021)]. This paper presents findings from an experimental program that investigated the material characterization of ASTM A656/A656M Gr. 80 (2024) plate steel. The results obtained were compared to conventional ASTM A572/A572M Gr. 50 steel. Two types of testing were performed for this work: tensile coupon testing and residual stress testing. The tensile coupon testing was carried out for both the A656/A656M Gr. 80 and A572/A572M Gr. 50 plate material. The A656/A656M Gr. 80 plate material showed more variation between the two different plate thicknesses in both mechanical behavior and microstructure due to differences in steel production. The 0.375 in. thick plate exhibited a clear yield plateau with an ultimate/yield stress ratio similar to the Gr. 50 material. In contrast, the 0.5 in. plate did not have a yield plateau and reached lower ultimate strain. The residual stress testing was performed using a sectioning technique for one A572/A572M Gr. 50 and five A656/A656M Gr. 80 built-up sections that were fabricated from 0.5 in. and 0.375 in. plate material. Residual stresses obtained from measurements were compared to previously published predictive models. The ECCS model and BSK99 models were found to be reasonable predictors of residual stresses for all specimens except the one section fabricated from 0.5 in. thick Gr. 80 plate. When comparing the Gr. 50 and Gr. 80 specimens of the same cross-sectional geometry, the residual stresses were similar, implying that cross-sectional geometry is more prevalent than the nominal yield stress in determining residual stresses in built-up I-sections.