Optimization of equivalent modulus of RAP-geopolymer-soil mixtures using response surface methodology

Q1 Chemical Engineering Journal of King Saud University, Engineering Sciences Pub Date : 2024-09-01 DOI:10.1016/j.jksues.2022.06.005

Huda S. Abdulwahed, Khalid R. Aljanabi, Ahmed H. Abdulkareem

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Abstract

This study focuses on assessing the resilient characteristics of a clayey soil modified with a fly ash (FA)-based geopolymer and reclaimed asphalt pavement (RAP) as an unpaved road material. RAP-geopolymer-soil mixtures were designed using the response surface methodology-central composite design with 0–40% RAP and 0–25% FA. The repeated-load California bearing ratio (CBR) testing method was used to determine the recoverable and permanent deformations and then obtain the equivalent (resilient) modulus (M_equ). The M_equ values were used to develop predictive models and determine the optimum soil–RAP–geopolymer mixture. The effects of the load level and soaking period on the stiffness of the optimum mixture were also investigated. The results revealed that the geopolymer binder played a significant role in enhancing the stiffness of the mixtures, with the maximum M_equ obtained at 25% FA and 0% RAP. However, it was determined that RAP has an adverse effect on the stiffness for almost all the studied cases and more significantly for the 40% RAP and 0% FA mixture. The optimal mixture was found to be 25% FA and 30% RAP. The developed model exhibited excellent predictive capability based on ANOVA results. The optimum mixture exhibited stress-softening behavior at an increased load level. No clear trend was observed in the effect of the soaking period on the resilient modulus within the examined soaking period range. Overall, this study agrees with several pavement design guidelines to limit the RAP content used in road applications owing to uncertain adequacy. Additionally, it suggests that the geopolymer binder is an effective stabilizer with excellent environmental and economic potential.

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利用响应面法优化 RAP-地聚合物-土壤混合物的等效模量

本研究的重点是评估使用粉煤灰（FA）土工聚合物和再生沥青路面（RAP）改性的粘性土壤作为未铺设路面的道路材料的回弹特性。采用响应面方法--中心复合设计法设计了 RAP-土工聚合物-土壤混合物，其中 RAP 占 0-40%，FA 占 0-25%。采用重复加载加州承载比（CBR）测试法确定可恢复变形和永久变形，然后获得等效（弹性）模量（Mequ）。Mequ 值用于开发预测模型和确定最佳土壤-RAP-地聚合物混合物。此外，还研究了荷载水平和浸泡期对最佳混合物刚度的影响。结果表明，土工聚合物粘结剂在增强混合物刚度方面发挥了重要作用，在 25% FA 和 0% RAP 时获得了最大 Mequ。然而，在几乎所有研究案例中，RAP 都对刚度产生了不利影响，40% RAP 和 0% FA 混合物的影响更为明显。最佳混合物为 25% 的 FA 和 30% 的 RAP。根据方差分析结果，所开发的模型具有出色的预测能力。最佳混合物在荷载水平增加时表现出应力软化行为。在考察的浸泡期范围内，没有观察到浸泡期对弹性模量的明显影响趋势。总之，这项研究与一些路面设计指南一致，即由于不确定是否足够，限制道路应用中的 RAP 含量。此外，它还表明土工聚合物粘结剂是一种有效的稳定剂，具有出色的环保和经济潜力。

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 King Saud University, Engineering Sciences Chemical Engineering-Fluid Flow and Transfer Processes

CiteScore

12.10

自引率

0.00%

发文量

审稿时长

63 days

期刊介绍： Journal of King Saud University - Engineering Sciences (JKSUES) is a peer-reviewed journal published quarterly. It is hosted and published by Elsevier B.V. on behalf of King Saud University. JKSUES is devoted to a wide range of sub-fields in the Engineering Sciences and JKSUES welcome articles of interdisciplinary nature.