Numerical Analysis of Geogrids and Recycled Concrete Aggregate for Stabilizing Road Embankments

IF 0.6 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Annales De Chimie-science Des Materiaux Pub Date : 2023-08-31 DOI:10.18280/acsm.470404

Marwa Abdulkareem Mohammed AL-DULAIMI, Mohsen Seyedi

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引用次数: 0

Abstract

The amplification of urban development and the extension of road networks necessitate a comprehensive understanding of various soil improvement techniques for civil engineering applications. Soil enhancement methods, typically trusted and practical, are pivotal in addressing geotechnical engineering challenges. This study focuses on the numerical evaluation of the efficacy of geogrids and recycled concrete aggregate (RCA) in the stabilization of road embankments. Critical soil properties such as water absorption, soil erosion, and settlement susceptibility are significantly improved through these methods, promoting sustainable land use, environmental conservation, and infrastructure durability. Literature reveals that the use of geogrids or waste materials like RCA contributes effectively to soil layer enhancement. In this investigation, road embankment models, with and without the aforementioned improvements, were developed and assessed under vehicular load conditions. The findings demonstrated that the incorporation of geogrids or RCA significantly bolsters the stability of road embankments. A noteworthy reduction in vertical settlement, up to 45%, was achieved when geogrids and RCA were concurrently utilized in the embankment. This suggests that these methods, individually or in combination, could provide a viable solution for enhancing the performance and stability of road infrastructures. Further research is proposed to explore the long-term performance of these enhancement methods under various environmental and load conditions.

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土工格栅和再生混凝土骨料稳定路堤的数值分析

城市发展的扩大和道路网络的扩展需要全面了解土木工程应用中的各种土壤改良技术。土壤增强方法通常是可靠和实用的，是解决岩土工程挑战的关键。本文对土工格栅和再生混凝土骨料(RCA)在路堤稳定中的效果进行了数值评价。这些方法显著改善了土壤的吸水率、土壤侵蚀率和沉降敏感性等关键土壤特性，促进了土地的可持续利用、环境保护和基础设施的耐久性。文献表明，使用土工格栅或废物如RCA有助于有效地增加土层。在本次调查中，在车辆荷载条件下，开发和评估了有和没有上述改进的道路路基模型。研究结果表明，土工格栅或RCA的结合显著增强了路堤的稳定性。当土工格栅和RCA同时用于路堤时，垂直沉降显著减少了45%。这表明，这些方法，单独或结合起来，可以为提高道路基础设施的性能和稳定性提供一个可行的解决方案。进一步研究这些增强方法在各种环境和荷载条件下的长期性能。

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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来源期刊

Annales De Chimie-science Des Materiaux 工程技术-材料科学：综合

CiteScore

1.70

自引率

25.00%

发文量

审稿时长

>12 weeks

期刊介绍： The ACSM is concerning the cutting-edge innovations in solid material science. The journal covers a broad spectrum of scientific fields, ranging all the way from metallurgy, semiconductors, solid mineral compounds, organic macromolecular compounds to composite materials. The editorial board encourages the submission of original papers that deal with all aspects of material science, including but not limited to synthesis and processing, property characterization, reactivity and reaction kinetics, evolution in service, and recycling. The papers should provide new insights into solid materials and make a significant original contribution to knowledge.