通过机器学习预测掺入铜矿尾矿作为补充胶凝材料的可持续水泥浆的抗压强度

IF 6.5 2区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY
Eka Oktavia Kurniati , Hang Zeng , Marat I. Latypov , Hee Jeong Kim
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引用次数: 0

摘要

铜矿开采会产生大量铜矿尾矿 (CMT),因此必须采取适当的废物处理和处置措施。通过用 CMT 替代部分水泥作为补充胶凝材料 (SCM),我们旨在同时解决两个环境问题:减少垃圾填埋场中的铜矿废物,以及通过减少水泥用量来降低体现碳。将 CMT 回收利用作为水泥替代品的探索需要评估其对材料性能(如抗压强度)的影响。在本文中,我们通过机器学习来解决这一问题,机器学习的特点是将大型公共数据与我们自己的 CMT 掺合水泥抗压强度小数据进行数据融合。我们开发并严格评估了三种机器学习模型:简单线性模型、高斯过程和随机森林,它们可预测不同混合设计(如不同的 CMT 用量和水粘合剂比率)和固化龄期的 CMT 掺合水泥浆的抗压强度。随机森林模型中的超参数通过贝叶斯优化法进行了调整。在对模型进行综合评估后,我们发现随机森林模型可以准确估计不同混合设计中水泥浆的抗压强度。此外,SHAPLE Additive exPlanation(SHAP)、Individual Conditional Expectation(ICE)和Partial Dependence Plots(PDP)的结果表明,水泥、磨细高炉矿渣、超塑化剂和固化龄期对抗压强度有积极影响。这项研究有助于加快可持续材料技术的发展,从而获得最佳的混合设计和理想的抗压强度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Machine learning for predicting compressive strength of sustainable cement paste incorporating copper mine tailings as supplementary cementitious materials

Copper mining produces significant amounts of copper mine tailings (CMT), necessitating appropriate waste handling and disposal practices. By substituting a portion of cement with CMT as supplementary cementitious materials (SCMs), we aim to address two environmental issues simultaneously: reducing copper mine waste in landfills and decreasing embodied carbon by using less cement. The exploration of CMT recycling as a cement replacement requires evaluation of its impact on material performance, such as compressive strength. In this paper, we address this by machine learning that features data fusion of large public data with our own small data on compressive strength of CMT-incorporated cement. We developed and critically evaluated three machine learning models: a simple linear model, Gaussian process, and random forest that predict the compressive strength of CMT-incorporated cement pastes with different mix designs (e.g., varying amounts of CMT and water-binder ratios) and curing ages. Hyperparameters in the random forest model were tuned using Bayesian optimization. Following a comprehensive evaluation of the models, we find that the random forest model can accurately estimate the compressive strength of cement paste across the mix designs. Furthermore, results from SHapley Additive exPlanation (SHAP), Individual Conditional Expectation (ICE), and Partial Dependence Plots (PDP) revealed that cement, ground-granulated blast furnace slag, superplasticizers, and curing ages positively influence compressive strength. This study contributes to acceleration of sustainable material technology to obtain the best mix design and desired compressive strength.

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来源期刊
CiteScore
7.60
自引率
19.40%
发文量
842
审稿时长
63 days
期刊介绍: Case Studies in Construction Materials provides a forum for the rapid publication of short, structured Case Studies on construction materials. In addition, the journal also publishes related Short Communications, Full length research article and Comprehensive review papers (by invitation). The journal will provide an essential compendium of case studies for practicing engineers, designers, researchers and other practitioners who are interested in all aspects construction materials. The journal will publish new and novel case studies, but will also provide a forum for the publication of high quality descriptions of classic construction material problems and solutions.
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