高强钢RHS特拉斯节点的损伤准则探讨

IF 1.2 Q3 CONSTRUCTION & BUILDING TECHNOLOGY

Steel Construction-Design and Research Pub Date : 2022-07-15 DOI:10.1002/stco.202100027

Meera Mohan, T. Wilkinson

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引用次数: 1

摘要

本文描述了高强度钢RHS K间隙桁架节点的结构变形和材料断裂行为的有限元模拟。研究的基本范围是检验在屈服应力为355mpa或更低时，基于低强度、高韧性钢行为的接头强度预测是否适用于高强度、低韧性、450mpa的钢。有限元可靠性分析表明，对于与局部屈曲、屈服和变形相关的破坏模式(弦侧壁破坏、弦面塑化和有效宽度减小导致的支撑破坏)，现有的方法可以通过修改扩展到更高强度的管，但对于与断裂或延性相关的破坏模式或脆性破坏模式(拉撑撕裂和弦冲剪)，需要一个强度降低修正因子。有限元模拟结合了损伤力学方法来校准断裂和变形模式下的实验结果。本文提出了一种新的强度公式，并将高等级钢的降延性与一个不基于屈服应力的修正函数结合起来，而是识别材料的降极限应变、断裂损伤参数和极限应力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Damage criterion approach to high‐strength steel RHS truss joints

This paper describes finite element simulations of the structural deformation and material fracture behaviour of high‐strength steel RHS K gap truss joints. The fundamental scope was to examine whether the joint strength predictions based on the behaviour of lower strength and more ductile steel with a yield stress of 355 MPa or less would hold good for higher strength 450 MPa steel with a lower ductility. The FEA reliability analysis indicates that for failure modes associated with local buckling, yielding and deformation (chord side wall failure, chord face plastification and brace failures due to reduced effective width), the existing approach could, with modifications, be extended to cover higher strength tubes, but for failure modes associated with fracture or ductility or modes liable to brittle failure (tearing in the tension brace and chord punching shear), a strength reduction modifying factor was required. The finite element simulations incorporated a damage mechanics approach to calibrate experimental results in both the fracture and deformation modes of failure. The paper proposes a new formulation for strength and incorporates reduced ductility in high‐grade steel with a modifier function that is not based on yield stress, instead recognizes the reduced ultimate strains, damage parameter for fracture and ultimate stress of the material.

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来源期刊

Steel Construction-Design and Research CONSTRUCTION & BUILDING TECHNOLOGY-

CiteScore

3.00

自引率

6.20%

发文量

期刊介绍： Steel Construction publishes peerreviewed papers covering the entire field of steel construction research. In the interests of "construction without depletion", it skilfully combines steel with other forms of construction employing concrete, glass, cables and membranes to form integrated steelwork systems. Since 2010 Steel Construction is the official journal for ECCS- European Convention for Constructional Steelwork members. You will find more information about membership on the ECCS homepage. Topics include: -Design and construction of structures -Methods of analysis and calculation -Experimental and theoretical research projects and results -Composite construction -Steel buildings and bridges -Cable and membrane structures -Structural glazing -Masts and towers -Vessels, cranes and hydraulic engineering structures -Fire protection -Lightweight structures