Fiber reinforcement effectiveness in two different sand specimens

IF 1.1 Q4 ENGINEERING, GEOLOGICAL

Soils and Rocks Pub Date : 2023-04-27 DOI:10.28927/sr.2023.012422

Murilo Conceição, Camilla Pinto, M. Carvalho, S. Machado

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引用次数: 0

Abstract

Fiber Reinforced Soils (FRS) are mixtures of discrete fibers with the soil to create a composite with improved mechanical properties compared to unreinforced material that depends on several soil and fiber properties. Therefore, comparative studies are needed to better understand their influence on FRS mechanical response. This paper analyzes the results of a comprehensive triaxial testing program performed on specimens of two different sands at the same relative density focusing on how the grain size distribution affects the composite behavior in terms of shear strength and dilatancy. It is shown that the grain size curve’s uniformity coefficient (Cu) is one of the critical variables controlling FRS’s dilatancy. Dune sand specimens (Cu = 1.79) presented dilatancy even for confining stresses as high as 300 kPa. The shear gains due to reinforcement were controlled by fiber length (L) and percentage (Pf), and size and shape of soil particles. River sand specimens with L = 51 mm and 1% fiber addition (dry mass) presented increments of 47.7 kPa in soil cohesion and a 5.2o increase in the soil friction angle compared to unreinforced material.

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纤维增强在两种不同砂样中的有效性

纤维增强土(FRS)是离散纤维与土壤的混合物，与依赖于几种土壤和纤维特性的非增强材料相比，它具有更好的机械性能。因此，需要进行比较研究，以更好地了解它们对FRS力学响应的影响。本文对两种不同砂在相同相对密度下的三轴综合试验结果进行了分析，重点分析了粒径分布对复合材料抗剪强度和剪胀性能的影响。结果表明，晶粒尺寸曲线的均匀性系数(Cu)是控制FRS剪胀的关键变量之一。当围应力高达300 kPa时，沙丘砂(Cu = 1.79)仍呈现剪胀现象。加固后的抗剪增益受纤维长度(L)和百分比(Pf)以及土粒大小和形状的控制。L = 51 mm、纤维添加量(干质量)为1%的河砂试件与未加筋相比，粘聚力增加47.7 kPa，摩擦角增加5.2 %。

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

Soils and Rocks ENGINEERING, GEOLOGICAL-

CiteScore

1.00

自引率

20.00%

发文量

期刊介绍： Soils and Rocks publishes papers in English in the broad fields of Geotechnical Engineering, Engineering Geology and Environmental Engineering. The Journal is published in April, August and December. The journal, with the name "Solos e Rochas", was first published in 1978 by the Graduate School of Engineering-Federal University of Rio de Janeiro (COPPE-UFRJ).