Exploring the structural behavior of recycled aggregates concrete pipe under dynamic loads through experimental and numerical investigation

Periodicals of Engineering and Natural Sciences (PEN) Pub Date : 2023-05-22 DOI:10.21533/pen.v11i3.3610

Shaymaa Abdelghany Mohamed, Mahdisabber Whaib, Marawan Mohammed Hamid, Mohammed Elwi, Wameedh Ghassan Abdul-Hussein

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Abstract

The most used material in construction is concrete. This study aimed to investigate the impact of recycled aggregate on compressive and tensile strength in concrete. To address the issue of accumulating tons of recycled aggregates, a new method was developed using chemical additive fractions to convert these aggregates into valuable products. The overconsumption of materials is a significant problem that leads to route overflow, pollution, and road fragmentation. The mechanical properties of corroded concrete pipes were also examined through a series of tests and the development of an ABAQUS-based 3D finite element model. It was discovered that the inside of the pipe wall was more vulnerable to damage than the outside, with corroded areas experiencing large stresses and strains. As corrosion depth increased, so did maximum principal stress and hoop strain in the affected region. Fear increased rapidly at first (0-10°), then decreased rapidly (10-45°), before gradually decreasing with increasing erosion latitude (45-180°). Additionally, both circumferential strain and maximum principal stress increased rapidly with greater depth of coverage or increasing moving loads.

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通过试验和数值研究，探讨了再生骨料混凝土管道在动荷载作用下的结构性能

建筑中使用最多的材料是混凝土。本研究旨在探讨再生骨料对混凝土抗压和抗拉强度的影响。为了解决回收骨料堆积成吨的问题，开发了一种使用化学添加剂馏分将这些骨料转化为有价值产品的新方法。材料的过度消耗是导致路线溢出、污染和道路破碎的一个重要问题。通过一系列试验和基于abaqus的三维有限元模型的开发，研究了腐蚀混凝土管道的力学性能。研究发现，管壁内部比外部更容易受到破坏，腐蚀区域承受着较大的应力和应变。随着腐蚀深度的增加，腐蚀区域的最大主应力和环向应变也随之增加。恐惧度在初始阶段(0-10°)迅速上升，随后迅速下降(10-45°)，然后随着侵蚀纬度的增加(45-180°)逐渐下降。此外，周向应变和最大主应力都随着覆盖深度的增加或移动载荷的增加而迅速增加。

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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Periodicals of Engineering and Natural Sciences (PEN)

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