Onyelowe Kennedy C, Kamchoom Viroon, Hanandeh Shadi, Ebid Ahmed M, Viñan Villagran Janneth Alejandra, Martínez Pérez Raúl Gregorio, Caicedo Benavides Fausto Ulpiano, Awoyera Paul, Avudaiappan Siva
Department of Civil Engineering, Michael Okpara University of Agriculture, Umudike, Nigeria.
Department of Civil Engineering, School of Engineering and Applied Sciences, Kampala International University, Kampala, Uganda.
Sci Rep. 2025 Apr 22;15(1):13983. doi: 10.1038/s41598-025-99091-9.
The self-compacting concrete (SCC) mixes were developed using lightweight expandable clay aggregate (LECA) as a partial substitute for coarse aggregate, ground granulated blast-furnace slag (GGBS) as a partial replacement for cement, and combusted bio-medical waste ash (BMWA) as a partial replacement for fine aggregate. The substitution levels for LECA, GGBS, and BMWA were set at 10%, 20%, and 30% of coarse aggregate, cement, and fine aggregate, respectively. M30-grade SCC mixes were designed with two different water-to-binder ratios-0.40 and 0.45-and their compressive strength (CS) was experimentally evaluated. The data entries from the above mix designs and experiments were collected in this research which deals with evaluating the impact of lightweight expandable clay aggregate, metallurgical slag, and combusted bio-medical waste ash on self-compacting concrete. An extensive literature search was used in this project and this produced a global representative database collected from literature. The collected 384 records were divided into training set (300 records = 80%) and validation set (84 records = 20%) in line with the requirements of a more reliable data partitioning. Six advanced machine learning methods such as the Artificial Neural Network (ANN), Support Vector Regression (SVR), K-Nearest Neighbors (KNN), eXtreme Gradient Boosting (XGB), Random Forest (RF), and Adaptive Boosting (AdaBoost) were used to model the concrete behavior. All models were created using "Orange Data Mining" software version 3.36. A combination of error metrics, efficiency metrics and determination/correlation metrics were used to test the models performance and accuracy. Also, the Hoffman and Gardener's method was used to evaluate the sensitivity analysis of the model variables. At the end of the model work, AdaBoost and KNN excel in predictive accuracy with 97.5%, reducing the margin of error and ensuring precise mix designs for SCC. SVR, XGB, and RF also exhibit strong accuracy (96.5-97%), supporting reliable material selection and proportions. AdaBoost and KNN demonstrate the lowest errors (MAE: 0.65 MPa, RMSE: 0.75 MPa), indicating precise performance, minimizing overdesign or underperformance risks, and optimizing material usage. The Hoffman/Gardener's sensitivity analysis produced produced GGBS of 31% and Dens of 26% as the highest impact and this is followed by LECA of 21% and BMWA of 20%. This research enables the optimization of self-compacting concrete mix designs using machine learning, reducing experimental trials, enhancing material efficiency, lowering environmental impact, and promoting sustainable construction through the effective reuse of industrial by-products.
自密实混凝土(SCC)混合料的开发采用了轻质膨胀粘土集料(LECA)作为粗集料的部分替代品、磨细粒化高炉矿渣(GGBS)作为水泥的部分替代品,以及燃烧后的生物医疗废物灰(BMWA)作为细集料的部分替代品。LECA、GGBS和BMWA的替代水平分别设定为粗集料、水泥和细集料的10%、20%和30%。设计了水胶比分别为0.40和0.45的M30级SCC混合料,并对其抗压强度(CS)进行了试验评估。本研究收集了上述配合比设计和试验的数据记录,以评估轻质膨胀粘土集料、冶金矿渣和燃烧后的生物医疗废物灰对自密实混凝土的影响。本项目进行了广泛的文献检索,并建立了一个从文献中收集的具有全球代表性的数据库。根据更可靠的数据划分要求,将收集到的384条记录分为训练集(300条记录 = 80%)和验证集(84条记录 = 20%)。使用了六种先进的机器学习方法,如人工神经网络(ANN)、支持向量回归(SVR)、K近邻(KNN)、极端梯度提升(XGB)、随机森林(RF)和自适应提升(AdaBoost)来模拟混凝土的性能。所有模型均使用“Orange数据挖掘”软件版本3.36创建。使用误差指标、效率指标和决定系数/相关指标的组合来测试模型的性能和准确性。此外,还使用了霍夫曼和加德纳方法来评估模型变量的敏感性分析。在模型工作结束时,AdaBoost和KNN的预测准确率高达97.5%,降低了误差幅度,确保了SCC的精确配合比设计。SVR、XGB和RF也表现出较高的准确率(96.5 - 97%),支持可靠的材料选择和配比。AdaBoost和KNN的误差最低(平均绝对误差:0.65MPa,均方根误差:0.75MPa),表明性能精确,将过度设计或性能不佳的风险降至最低,并优化了材料使用。霍夫曼/加德纳的敏感性分析得出,GGBS的影响最大,为31%,密度的影响为26%,其次是LECA的21%和BMWA的20%。本研究通过机器学习实现了自密实混凝土配合比设计的优化,减少了试验次数,提高了材料效率,降低了环境影响,并通过有效利用工业副产品促进了可持续建设。
