MODEL OF STRESS-STRAIN STATE OF THREE-LAYERED REINFORCED CONCRETE STRUCTURE BY THE FINITE ELEMENT METHODS

Vu Dinh Tho, E. Korol, V. Rimshin, P. Anh
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引用次数: 2

Abstract

The object of the study is multi-layer reinforced concrete structures of concrete with various physical and mechanical characteristics of materials - concrete and reinforcement under the influence of loading. Analysis of the stress state of multilayer reinforced concrete beams by using different materials is a complex problem due to the different mechanical and physical characteristics of materials and the cracking behavior of concrete. This article presents an analysis of the stress-strain state of three-layered reinforced concrete structures using the finite element method in the program ANSYS Mechanical. Numerical modeling allows on ANSYS allows combining different combinations of loads, the variability of the strength and deformation characteristics of materials and various types of reinforcement in multilayer reinforced concrete beams. Comparison is made between the experimental results, numerical results and finite element analyses with respect to initial crack formation and the ultimate load capacity of beams. The results of the study were shown that as the grade of concrete in the external layer increases from B15 to B20 and the grade of lightweight concrete in the internal layer increases from B0.75 to B1.5, the crack resistance can be increased by 59.7% and the bearing capacity of the test beam is increased by 16.4%. When the thickness of the external layers varies from 40mm to 80mm, making the crack resistance increased by 47.5% and the bearing capacity of three-layer concrete beams greatly increased by 6.7%. The obtained scientific results enable to determine rational parameters for modeling various structural solutions of multilayer reinforced concrete structures.
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用有限元方法建立三层钢筋混凝土结构的应力-应变状态模型
本课题研究的对象是多层钢筋混凝土结构中具有各种物理力学特性的混凝土材料——混凝土和钢筋在荷载作用下的作用。由于材料的力学和物理特性以及混凝土的开裂行为不同,采用不同材料的多层钢筋混凝土梁的应力状态分析是一个复杂的问题。本文采用ANSYS力学分析软件对三层钢筋混凝土结构的应力-应变状态进行了有限元分析。在ANSYS上的数值模拟允许在多层钢筋混凝土梁中结合不同的荷载组合、材料的强度和变形特性的可变性以及各种类型的钢筋。对梁的初始裂纹形成和极限承载能力进行了试验结果、数值结果和有限元分析的比较。研究结果表明:当外层混凝土等级由B15提高到B20,内层轻量化混凝土等级由B0.75提高到B1.5时,试验梁的抗裂能力可提高59.7%,承载力可提高16.4%。当外层厚度在40mm ~ 80mm范围内变化时,使三层混凝土梁的抗裂能力提高47.5%,承载力大大提高6.7%。所得结果为多层钢筋混凝土结构各种结构解的建模确定合理参数提供了科学依据。
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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CiteScore
0.80
自引率
0.00%
发文量
43
审稿时长
4 weeks
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