Systematic multiscale models to predict the compressive strength of self-compacting concretes modified with nanosilica at different curing ages

Systematic multiscale models to predict the compressive strength of self-compacting concretes modified with nanosilica at different curing ages

The evolution of nanotechnology brings materials with novel performance and during last year’s much attempt has been established to include nanoparticles especially nano-silica (NS) into the concrete to improve performance and develop concrete with enhanced characteristics. Generally, NS is incorpor...

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Veröffentlicht in:Engineering with computers 2022-08, Vol.38 (Suppl 3), p.2365-2388
Hauptverfasser: Faraj, Rabar H., Mohammed, Azad A., Mohammed, Ahmed, Omer, Khalid M., Ahmed, Hemn Unis
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Sprache:eng
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CAE) and Design
Calculus of Variations and Optimal Control
Optimization
Classical Mechanics
Compressive strength
Computer Science
Computer-Aided Engineering (CAD
Control
Curing
Forecasting
Formwork
Math. Applications in Chemistry
Mathematical and Computational Engineering
Mathematical models
Mixtures
Nanoparticles
Original Article
Performance enhancement
Performance evaluation
Root-mean-square errors
Self-compacting concrete
Sensitivity analysis
Superplasticizers
Systems Theory
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container_end_page 2388
container_issue Suppl 3
container_start_page 2365
container_title Engineering with computers
container_volume 38
creator Faraj, Rabar H.
Mohammed, Azad A.
Mohammed, Ahmed
Omer, Khalid M.
Ahmed, Hemn Unis
description The evolution of nanotechnology brings materials with novel performance and during last year’s much attempt has been established to include nanoparticles especially nano-silica (NS) into the concrete to improve performance and develop concrete with enhanced characteristics. Generally, NS is incorporated into the self-compacting concrete (SCC) aiming to positively influence the fresh, mechanical, microstructure, and durability properties of the composite. The most important mechanical property for all types of concrete composites is compressive strength. Therefore, developing reliable models for predicting the compressive strength of SCC is crucial regarding saving time, energy, and cost-effectiveness. Moreover, it gives valuable information for scheduling the construction work and provides information about the correct time for removing the formwork. In this study, three different models including the linear relationship model (LR), nonlinear model (NLR), and multi-logistic model (MLR) were proposed to predict the compressive strength of SCC mixtures made with or without NS. In this regard, a comprehensive data set that consists of 450 samples were collected and analyzed to develop the models. In the modeling process, the most important variables affecting the compressive strength such as NS content, cement content, water to binder ratio, curing time from 1 to 180 days, superplasticizer content, fine aggregate content, and coarse aggregate content were considered as input variables. Various statistical assessments such as Root Mean Squared Error (RMSE), Mean Absolute Error (MAE), Scatter Index (SI), OBJ value, and the coefficient of determination ( R 2 ) were used to evaluate the performance of the proposed models. The results indicated that the MLR model performed better for forecasting the compression strength of SCC mixtures modified with NS compared to other models. The SI and OBJ values of the MLR model were 18.8% and 16.7% lower than the NLR model, indicating the superior performance of the MLR model. Moreover, the sensitivity analysis demonstrated that the curing time is the most affecting variable for forecasting the compressive strength of SCC modified with NS.
doi_str_mv 10.1007/s00366-021-01385-9
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In the modeling process, the most important variables affecting the compressive strength such as NS content, cement content, water to binder ratio, curing time from 1 to 180 days, superplasticizer content, fine aggregate content, and coarse aggregate content were considered as input variables. Various statistical assessments such as Root Mean Squared Error (RMSE), Mean Absolute Error (MAE), Scatter Index (SI), OBJ value, and the coefficient of determination ( R 2 ) were used to evaluate the performance of the proposed models. The results indicated that the MLR model performed better for forecasting the compression strength of SCC mixtures modified with NS compared to other models. The SI and OBJ values of the MLR model were 18.8% and 16.7% lower than the NLR model, indicating the superior performance of the MLR model. 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Generally, NS is incorporated into the self-compacting concrete (SCC) aiming to positively influence the fresh, mechanical, microstructure, and durability properties of the composite. The most important mechanical property for all types of concrete composites is compressive strength. Therefore, developing reliable models for predicting the compressive strength of SCC is crucial regarding saving time, energy, and cost-effectiveness. Moreover, it gives valuable information for scheduling the construction work and provides information about the correct time for removing the formwork. In this study, three different models including the linear relationship model (LR), nonlinear model (NLR), and multi-logistic model (MLR) were proposed to predict the compressive strength of SCC mixtures made with or without NS. In this regard, a comprehensive data set that consists of 450 samples were collected and analyzed to develop the models. In the modeling process, the most important variables affecting the compressive strength such as NS content, cement content, water to binder ratio, curing time from 1 to 180 days, superplasticizer content, fine aggregate content, and coarse aggregate content were considered as input variables. Various statistical assessments such as Root Mean Squared Error (RMSE), Mean Absolute Error (MAE), Scatter Index (SI), OBJ value, and the coefficient of determination ( R 2 ) were used to evaluate the performance of the proposed models. The results indicated that the MLR model performed better for forecasting the compression strength of SCC mixtures modified with NS compared to other models. The SI and OBJ values of the MLR model were 18.8% and 16.7% lower than the NLR model, indicating the superior performance of the MLR model. Moreover, the sensitivity analysis demonstrated that the curing time is the most affecting variable for forecasting the compressive strength of SCC modified with NS.</abstract><cop>London</cop><pub>Springer London</pub><doi>10.1007/s00366-021-01385-9</doi><tpages>24</tpages><orcidid>https://orcid.org/0000-0003-0810-3867</orcidid></addata></record>
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subjects CAE) and Design
Calculus of Variations and Optimal Control
Optimization
Classical Mechanics
Compressive strength
Computer Science
Computer-Aided Engineering (CAD
Control
Curing
Forecasting
Formwork
Math. Applications in Chemistry
Mathematical and Computational Engineering
Mathematical models
Mixtures
Nanoparticles
Original Article
Performance enhancement
Performance evaluation
Root-mean-square errors
Self-compacting concrete
Sensitivity analysis
Superplasticizers
Systems Theory
title Systematic multiscale models to predict the compressive strength of self-compacting concretes modified with nanosilica at different curing ages
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