Rational design solutions for deep excavations using soil nail wall systems

IF 2.8 Q2 MINING & MINERAL PROCESSING
Ahmad Alkhdour, Amjad A Yasin, Oleksii Tiutkin
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引用次数: 0

Abstract

Purpose. The study aims to optimize the design and reduce soil nail length in deep excavations with a soil nail system in fast-draining soils. Additionally, it investigates the parameters influencing slope stability in fast-draining soils. Methods. Integrating field and lab data with soil nail properties and advanced modeling, this study investigates how fixed nail length, inclination and spacing affect the stability of a 20 m-deep excavation in fast-draining soil. Findings. The study findings reveal that optimal parameters, such as nail spacing and inclination angle, have been identified for reinforcing deep excavation walls, ensuring stability with minimal nail length. Notably, the stability of excavation walls can be achieved without the need to increase the length of the soil nails. The recommended parameters are characteristic of an 8-meter-long soil nail system, a 30-degree inclination angle, and a spacing of 1.5×1.5 meters. Originality. This study presents a novel perspective on the structural characteristics of soil nails by determining emphasizing nail spacing, inclination angle, and fixed nail length. It offers a comprehensive framework for designing soil nail walls in fast-draining soils during deep excavations, contributing to advancements in open-cut excavation practices. Practical implications. The study offers practical implications for designers involved in deep slope earthworks, enabling the development of efficient and rational design solutions that ensure excavation stability and prevent displacement during excavation while reducing costs and project duration.
深基坑土钉墙系统的合理设计方案
目的。本研究旨在优化设计快速排水土钉系统,缩短深基坑土钉长度。此外,还研究了影响快排水土边坡稳定性的参数。方法。本研究将现场和实验室数据与土钉特性和先进的模型相结合,研究了固定钉长度、倾角和间距对快排水土壤中20m深基坑稳定性的影响。发现。研究结果表明,确定了深基坑支护的最佳支护参数,如钉距和倾角,以最小的钉长保证基坑支护的稳定性。值得注意的是,开挖墙的稳定性可以在不需要增加土钉长度的情况下实现。推荐参数为土钉系统长8米,倾角30度,间距1.5×1.5米。创意。本研究通过确定土钉间距、倾斜角度和固定长度,提出了土钉结构特征的新视角。它为深基坑快速排水土壤中土钉墙的设计提供了一个全面的框架,促进了露天开挖实践的进步。实际意义。该研究为参与深坡土方工程的设计师提供了实际意义,使他们能够制定有效和合理的设计方案,以确保开挖稳定性和防止开挖过程中的位移,同时减少成本和工程工期。
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来源期刊
Mining of Mineral Deposits
Mining of Mineral Deposits MINING & MINERAL PROCESSING-
CiteScore
5.20
自引率
15.80%
发文量
52
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