Thermal and Mechanical Properties of Concrete Incorporating Silica Fume and Waste Rubber Powder

Using waste rubber tires for concrete production will reduce the demand for natural aggregate and help to reduce environmental pollution. The main challenge of using waste rubber tires in concrete is the deterioration of mechanical properties, due to poor bonding between rubber and cement matrix. Th...

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Veröffentlicht in:	Polymers 2022-11, Vol.14 (22), p.4858
Hauptverfasser:	Lakhiar, Muhammad Tahir, Kong, Sih Ying, Bai, Yu, Susilawati, Susilawati, Zahidi, Izni, Paul, Suvash Chandra, Raghunandan, Mavinakere Eshwaraiah
Format:	Artikel
Sprache:	eng
Schlagworte:	Aggregates Cement Compressive strength Concrete properties Density Elastic properties Heat transfer Interfacial bonding Linear equations Mechanical properties Modulus of elasticity Particle size Portland cements Rubber Shrinkage Silica Silica fume Splitting Sustainable development Tensile strength Thermal conductivity Thermodynamic properties Tires Water absorption Workability
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container_title	Polymers
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creator	Lakhiar, Muhammad Tahir Kong, Sih Ying Bai, Yu Susilawati, Susilawati Zahidi, Izni Paul, Suvash Chandra Raghunandan, Mavinakere Eshwaraiah
description	Using waste rubber tires for concrete production will reduce the demand for natural aggregate and help to reduce environmental pollution. The main challenge of using waste rubber tires in concrete is the deterioration of mechanical properties, due to poor bonding between rubber and cement matrix. This research aims to evaluate the mechanical and thermal properties of rubberised concrete produced by using different proportions of rubber powder and silica fume. Ordinary Portland cement was partially replaced with silica fume by amounts of 5%, 10%, 15% and 20%, while sand was replaced by 10%, 20% and 30% with waste rubber powder. Tests were carried out in order to determine workability, density, compressive strength, splitting tensile strength, elastic modulus, thermal properties, water absorption and shrinkage of rubberised concrete. The compressive strength and splitting tensile strength of concrete produced using waste rubber powder were reduced by 10-52% and 9-57%, respectively. However, the reduction in modulus of elasticity was 2-36%, less severe than compressive and splitting tensile strengths. An optimum silica fume content of 15% was observed based on the results of mechanical properties. The average shrinkage of concrete containing 15% silica fume increased from -0.051% to -0.085% at 28 days, as the content of waste rubber powder increased from 10% to 30%. While the thermal conductivity of rubberised concrete was reduced by 9-35% compared to the control sample. Linear equations were found to correlate the density, splitting tensile strength, modulus of elasticity and thermal conductivity of concrete with silica fume and waste rubber powder.
doi_str_mv	10.3390/polym14224858
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An optimum silica fume content of 15% was observed based on the results of mechanical properties. The average shrinkage of concrete containing 15% silica fume increased from -0.051% to -0.085% at 28 days, as the content of waste rubber powder increased from 10% to 30%. While the thermal conductivity of rubberised concrete was reduced by 9-35% compared to the control sample. 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The main challenge of using waste rubber tires in concrete is the deterioration of mechanical properties, due to poor bonding between rubber and cement matrix. This research aims to evaluate the mechanical and thermal properties of rubberised concrete produced by using different proportions of rubber powder and silica fume. Ordinary Portland cement was partially replaced with silica fume by amounts of 5%, 10%, 15% and 20%, while sand was replaced by 10%, 20% and 30% with waste rubber powder. Tests were carried out in order to determine workability, density, compressive strength, splitting tensile strength, elastic modulus, thermal properties, water absorption and shrinkage of rubberised concrete. The compressive strength and splitting tensile strength of concrete produced using waste rubber powder were reduced by 10-52% and 9-57%, respectively. However, the reduction in modulus of elasticity was 2-36%, less severe than compressive and splitting tensile strengths. 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An optimum silica fume content of 15% was observed based on the results of mechanical properties. The average shrinkage of concrete containing 15% silica fume increased from -0.051% to -0.085% at 28 days, as the content of waste rubber powder increased from 10% to 30%. While the thermal conductivity of rubberised concrete was reduced by 9-35% compared to the control sample. 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subjects	Aggregates Cement Compressive strength Concrete properties Density Elastic properties Heat transfer Interfacial bonding Linear equations Mechanical properties Modulus of elasticity Particle size Portland cements Rubber Shrinkage Silica Silica fume Splitting Sustainable development Tensile strength Thermal conductivity Thermodynamic properties Tires Water absorption Workability
title	Thermal and Mechanical Properties of Concrete Incorporating Silica Fume and Waste Rubber Powder
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