Revised Soil Classification System: Implementation and Engineering Implications

IF 3.9 2区工程技术 Q1 ENGINEERING, GEOLOGICAL

Journal of Geotechnical and Geoenvironmental Engineering Pub Date : 2023-11-01 DOI:10.1061/jggefk.gteng-10447

Gloria M. Castro, Junghee Park, J. Carlos Santamarina

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引用次数: 3

Abstract

Soil classification systems help geotechnical engineers anticipate soil properties and provide early guidance for engineering analyses. Current soil classification systems recognize the central role of particle size and inherent differences between coarse- and fine-grained fractions. However, they adopt fixed classification boundaries irrespective of a broad range of fines plasticity and particle shape, disregard the distinct fines thresholds for mechanical and hydraulic properties, and overlook pore-fluid chemistry effects on fines behavior. The Revised Soil Classification System (RSCS) addresses these limitations and benefits from published data and physical insights gained during the last century. By comparison, the classification boundaries in the prevailing Unified Soil Classification System (USCS) resemble those in the RSCS only for the case of angular sands and gravels mixed with low-plasticity fines; in all other cases, extensive data sets corroborate the transition thresholds adopted in the RSCS. The complete logic tree for the RSCS facilitates its implementation; it is available as user-friendly Excel macro and a mobile application that automatically produce the soil-specific classification charts and show the soil classification in terms of the controlling fraction for both mechanical and hydraulic properties. Multiple studies have demonstrated the predictive power of the RSCS in terms of soil properties (e.g., compressibility, strength, hydraulic conductivity, and capillarity), soil phenomena (e.g., fines migration and bioactivity), and the preliminary selection of geotechnical solutions (e.g., soil improvement).

查看原文本刊更多论文

修订土壤分类系统:实施及工程意义

土壤分类系统帮助岩土工程师预测土壤性质，并为工程分析提供早期指导。当前的土壤分类系统认识到颗粒大小的中心作用以及粗粒和细粒组分之间的固有差异。然而，它们采用了固定的分类边界，而不考虑细粒塑性和颗粒形状的广泛范围，忽略了细粒力学和水力性能的不同阈值，并且忽略了孔隙流体化学对细粒行为的影响。修订的土壤分类系统(RSCS)解决了这些局限性，并从上个世纪公布的数据和物理见解中获益。相比之下，目前流行的统一土壤分类系统(USCS)的分类边界与RSCS的分类边界相似，仅在角砂和砾石混合低塑性细粒的情况下;在所有其他情况下，广泛的数据集证实了RSCS采用的过渡阈值。完整的RSCS逻辑树便于实现;它可以作为用户友好的Excel宏和移动应用程序，自动生成特定于土壤的分类图表，并根据机械和水力特性的控制分数显示土壤分类。多项研究已经证明了RSCS在土壤特性(如压缩性、强度、水力导电性和毛细性)、土壤现象(如细粒迁移和生物活性)以及岩土工程解决方案(如土壤改良)的初步选择方面的预测能力。

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

Journal of Geotechnical and Geoenvironmental Engineering 工程技术-地球科学综合

CiteScore

7.50

自引率

7.70%

发文量

222

审稿时长

12 months

期刊介绍： The Journal of Geotechnical and Geoenvironmental Engineering covers the broad area of practice known as geotechnical engineering. Papers are welcomed on topics such as foundations, retaining structures, soil dynamics, engineering behavior of soil and rock, site characterization, slope stability, dams, rock engineering, earthquake engineering, environmental geotechnics, geosynthetics, computer modeling, groundwater monitoring and restoration, and coastal and geotechnical ocean engineering. Authors are also encouraged to submit papers on new and emerging topics within the general discipline of geotechnical engineering. Theoretical papers are welcomed, but there should be a clear and significant potential for practical application of the theory. Practice-oriented papers and case studies are particularly welcomed and encouraged.