Efficacy of the Simplex-Centroid Method for Optimization of Mixtures of Soil, Ladle Furnace Slag and Fly Ash Applied in Pavement Construction

Integrating industrial wastes into soils to enhance their properties is a potential solution to current waste management challenges. Since the current literature lacks systematic studies on the mechanical performance of mixtures of soil, ladle furnace slag (LFS) and fly ash (FA), this research inves...

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Bibliographic Details
Published inSustainability Vol. 16; no. 17; p. 7726
Main Authors Rodrigues, Mateus Henrique Ribeiro, Silva, Taciano Oliveira da, Pitanga, Heraldo Nunes, Pedroti, Leonardo Gonçalves, Rodrigues, Klaus Henrique de Paula, Lopes, Emerson Cordeiro, Nalon, Gustavo Henrique
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 05.09.2024
Subjects
By products
Cement
Construction industry
Design of experiments
Engineering
Highway construction
Investigations
Mathematical models
Mineralogy
Optimization
Particle size
Slag
Variables
Waste management
Brazil
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Summary:Integrating industrial wastes into soils to enhance their properties is a potential solution to current waste management challenges. Since the current literature lacks systematic studies on the mechanical performance of mixtures of soil, ladle furnace slag (LFS) and fly ash (FA), this research investigated the chemical stabilization of two different soils (clayey or sandy soil) using a concomitant mix of distinct types of industrial wastes: LFS and FA. A design of experiments (DoE) methodology was employed to systematically generate distinct mixtures for each soil sample, utilizing a simplex-centroid design. The mixtures were subjected to unconfined compressive strength (UCS), California Bearing Ratio (CBR) and resilient modulus (RM) tests. The industrial by-products improved the mechanical properties of the soils, providing UCS, CBR index and RM increases up to 130.5%, 324.4% and 132.6%, respectively. Synergistic and antagonistic effects related to the combination of different wastes were discussed, based on mathematical models with coefficients of determination ranging from 0.760 to 0.998, in addition to response surfaces generated for each response variable. The desirability function was applied to identify the optimal component proportions. The best mixture proportion was 80% soil, 20% LFS and 0% FA, which improved the formation of cemented compounds that contributed to the enhanced mechanical strength. The use of industrial waste for soil stabilization has therefore proven to be technically feasible and environmentally friendly.
ISSN:2071-1050
2071-1050
DOI:10.3390/su16177726