PET FRP-混凝土-钢双层管状残柱轴向压缩性能的多尺度研究

IF 1.8 4区 工程技术 Q3 ENGINEERING, CIVIL
Jinliang Liu, Jinbo Du, Shansong Gao, Hongguang Wang
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引用次数: 0

摘要

本文旨在讨论聚对苯二甲酸乙二醇酯纤维增强聚合物(PET FRP)在 DSTC 结构中的适用性。PET FRP 可为混凝土提供约束,从而提高结构的强度和稳定性。本文基于 26 个接受轴向压缩测试的 DSTC 试样,对 PET FRP-混凝土-钢双层管状支柱(DSTC)的轴向压缩特性进行了实验和响应面分析。每个 DSTC 试样的高度为 600 毫米,外径在 305 至 315 毫米之间,添加的混凝土厚度为 43 毫米。主要参数包括 PET FRP 的层数、混凝土的抗压强度和钢管的厚度。实验结果表明,增加 PET FRP 层数可显著提高极限荷载和极限轴向应变,分别达到 27.34% 和 28.79%。当混凝土的抗压强度从 C30 提高到 C40 时,DSTC 的极限荷载和极限轴向应变值分别增加了 12.54% 和 8.99%。此外,当钢管厚度从 6 毫米增加到 8 毫米时,极限荷载和极限轴向应变分别增加了 34.95% 和 118.90%。这些结果表明,引入 PET FRP 能显著提高 DSTC 的整体性能。增加 PET FRP 层数有助于限制 DSTC 的圆周应变。P6-S8-C40 的极限承载能力和极限轴向应变能力最好,分别达到 3356.18 kN 和 0.1992。本文的主要目的是研究 PET FRP 厚度(不同层)、钢管厚度和混凝土强度对 DSTC 性能、破坏模式和破坏过程的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Multiscale Study on the Axial Compression Performance of PET FRP–Concrete–Steel Double-Skin Tubular Stub Columns

Multiscale Study on the Axial Compression Performance of PET FRP–Concrete–Steel Double-Skin Tubular Stub Columns

In this paper, the aim is to discuss the applicability of polyethylene terephthalate fiber-reinforced polymer (PET FRP) in DSTC structures. PET FRP can improve the strength and stability of structures by providing constraints for concrete. Herein, experimental and response surface analyses of the axial compressive properties of PET FRP–concrete–steel double-skin tubular stub columns (DSTCs) based on 26 DSTC specimens subjected to axial compression testing are presented. The height of each DSTC specimen is 600 mm, the outer diameter is between 305 and 315 mm, and the thickness of the added concrete is 43 mm. The main parameters are the number of layers on the PET FRP, the compressive strength of the concrete, and the thicknesses of the steel tubes. The experimental results show that the ultimate load and ultimate axial strain can be significantly increased by increasing the number of PET FRP layers, reaching 27.34% and 28.79%, respectively. When the compressive strength of the concrete increases from C30 to C40, the ultimate load and ultimate axial strain values of the DSTCs increase by 12.54% and 8.99%, respectively. In addition, as the thickness of the steel tube increases from 6 to 8 mm, the ultimate load and ultimate axial strain increase by 34.95% and 118.90%, respectively. These results indicate that the introduction of PET FRP significantly improves the overall performance of DSTCs. Increasing the number of PET FRP layers helps to limit the circumferential strain of DSTCs. P6-S8-C40 has the best ultimate load-bearing capacity and ultimate axial strain capacity, which reach 3356.18 kN and 0.1992, respectively. The main purpose of this paper is to study the influences of the PET FRP thickness (in different layers), steel tube thickness, and concrete strength on the properties, damage mode and damage process of DSTCs.

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来源期刊
CiteScore
3.90
自引率
5.90%
发文量
83
审稿时长
15 months
期刊介绍: International Journal of Civil Engineering, The official publication of Iranian Society of Civil Engineering and Iran University of Science and Technology is devoted to original and interdisciplinary, peer-reviewed papers on research related to the broad spectrum of civil engineering with similar emphasis on all topics.The journal provides a forum for the International Civil Engineering Community to present and discuss matters of major interest e.g. new developments in civil regulations, The topics are included but are not necessarily restricted to :- Structures- Geotechnics- Transportation- Environment- Earthquakes- Water Resources- Construction Engineering and Management, and New Materials.
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