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极端顶点设计方法对残余土壤复合材料力学和形态行为的作用。

Role of extreme vertex design approach on the mechanical and morphological behaviour of residual soil composite.

机构信息

Department of Civil Engineering, Akwa Ibom State University, Ikot Akpaden, Nigeria.

Department of Civil Engineering, Kampala International University, Kampala, Uganda.

出版信息

Sci Rep. 2023 May 16;13(1):7933. doi: 10.1038/s41598-023-35204-6.

DOI:10.1038/s41598-023-35204-6
PMID:37193752
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10188442/
Abstract

This research work reports the usability of binary additive materials known as tile waste dust (TWD) and calcined kaolin (CK) in ameliorating the mechanical response of weak soil. The extreme vertex design (EVD) was adopted for the mixture experimental design and modelling of the mechanical properties of the soil-TWD-CK blend. In the course of this study, a total of fifteen (15) design mixture ingredients' ratios for water, TWD, CK and soil were formulated. The key mechanical parameters considered in the study showed a considerable rate of improvement to the peak of 42%, 755 kN/m and 59% for California bearing ratio, unconfined compressive strength and resistance to loss in strength respectively. The development of EVD-model was achieved with the aid of the experimental derived results and fractions of component combinations through fits statistical evaluation, analysis of variance, diagnostic test, influence statistics and numerical optimization using desirability function to analyze the datasets. In a step further, the non-destructive test explored to assess the microstructural arrangement of the studied soil-additive materials displayed a substantial disparity compared to the corresponding original soil material and this is an indicator of soil improvement. From the geotechnical engineering perspective, this study elucidates the usability of waste residues as environmental friendly and sustainable materials in the field of soil re-engineering.

摘要

本研究报告了二元添加剂材料(即瓷砖废料粉尘(TWD)和煅烧高岭土(CK))在改善弱土机械性能方面的可用性。采用极端顶点设计(EVD)进行混合实验设计和土-TWD-CK 混合物力学性能建模。在本研究中,总共制定了 15 种(15)设计混合物成分的水、TWD、CK 和土壤的比例。研究中考虑的关键力学参数显示出相当大的改进,峰值分别提高了 42%、755 kN/m 和 59%,用于加州承载比、无侧限抗压强度和强度损失抵抗力。通过拟合统计评估、方差分析、诊断测试、影响统计和数值优化(使用理想函数分析数据集),利用实验得出的结果和组分组合的分数,实现了 EVD 模型的开发。更进一步,探索了非破坏性测试以评估所研究的土壤添加剂材料的微观结构排列,与相应的原始土壤材料相比显示出实质性差异,这是土壤改良的一个指标。从岩土工程的角度来看,本研究阐明了将废物残渣作为环保和可持续材料在土壤再工程领域的可用性。

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