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用于预测掺入再生塑料骨料和工业废灰的绿色自密实混凝土抗压强度的软计算技术。

Soft computing techniques to predict the compressive strength of green self-compacting concrete incorporating recycled plastic aggregates and industrial waste ashes.

作者信息

Faraj Rabar H, Mohammed Azad A, Omer Khalid M, Ahmed Hemn Unis

机构信息

Civil Engineering Department, College of Engineering, University of Sulaimani, Sulaimani, Kurdistan Region Iraq.

Civil Engineering Department, University of Halabja, Halabja, Kurdistan Region Iraq.

出版信息

Clean Technol Environ Policy. 2022;24(7):2253-2281. doi: 10.1007/s10098-022-02318-w. Epub 2022 May 2.

DOI:10.1007/s10098-022-02318-w
PMID:35531082
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9058435/
Abstract

ABSTRACT

Rapid urbanization and industrialization with corresponding economic growth have increased concrete production, leading to resource depletion and environmental pollution. The mentioned problems can be resolved by using recycled aggregates and industrial waste ashes as natural aggregate and cement replacement in concrete production. Incorporating different by-product ashes and recycled plastic (RP) aggregates are viable options to produce sustainable self-compacting concrete (SCC). On the other hand, compressive strength is an essential characteristic among other evaluated properties. As a result, establishing trustworthy models to forecast the compressive strength of SCC is critical to saving cost, time, and energy. Furthermore, it provides valuable instruction for planning building projects and determining the best time to remove the formwork. In this study, four alternative models were suggested to predict the compressive strength of SCC mixes produced by RP aggregates: the artificial neural network (ANN), nonlinear model, linear relationship model, and multi-logistic model. To do so, an extensive set of data consisting of 400 mixtures were extracted and analyzed to develop the models, various mixture proportions and curing times were considered as input variables. To test the effectiveness of the suggested models, several statistical evaluations, including coefficient of determination ( ), scatter index, root mean squared error (RMSE), mean absolute error (MAE), and Objective (OBJ) value were utilized. Compared to other models, the ANN model performed better to forecast the compressive strength of SCC mixes incorporating RP aggregates. The RMSE, MAE, OBJ, and values for this model were 5.46 MPa, 2.31 MPa, 4.26 MPa, and 0.973, respectively.

摘要

摘要

快速的城市化和工业化以及相应的经济增长增加了混凝土产量,导致资源枯竭和环境污染。上述问题可通过在混凝土生产中使用再生骨料和工业废灰替代天然骨料和水泥来解决。掺入不同的副产品灰和再生塑料(RP)骨料是生产可持续自密实混凝土(SCC)的可行选择。另一方面,抗压强度是其他评估性能中一项重要特性。因此,建立可靠的模型来预测自密实混凝土的抗压强度对于节省成本、时间和能源至关重要。此外,它为规划建筑项目和确定拆除模板的最佳时间提供了有价值的指导。在本研究中,提出了四种替代模型来预测由RP骨料生产的自密实混凝土混合料的抗压强度:人工神经网络(ANN)、非线性模型、线性关系模型和多元逻辑模型。为此,提取并分析了包含400种混合料的大量数据以建立模型,各种混合料比例和养护时间被视为输入变量。为了测试所提模型的有效性,采用了几种统计评估方法,包括决定系数( )、离散指数、均方根误差(RMSE)、平均绝对误差(MAE)和目标(OBJ)值。与其他模型相比,人工神经网络模型在预测掺入RP骨料的自密实混凝土混合料的抗压强度方面表现更好。该模型的RMSE、MAE、OBJ和 值分别为5.46MPa、2.31MPa、4.26MPa和0.973。

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