Study the Effect of Using Ceramic Waste Powder as Partial Replacement for Cement on Concrete Properties

Attaelmanan, Moatasim; Kambal, Mahgoub Elhaj Mahgoub; Mansour, Mohammed Izzeldeen

doi:10.54388/jkues.v1i1.125

Cited by 5 publications

(5 citation statements)

References 30 publications

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“…The minimum value is 13 MPa given by the 20% concrete rate of substitution of silica fume with recycled ceramic fillers (Figure 6 (b)), this result can be explained by the high absorption of recycled ceramic fillers that influences the hydration reaction [29].…”

Section: Flexural Tensile Strength On Non-thermally Treated Concretementioning

confidence: 93%

Preliminary Study on the Use of Recycled Glass, Ceramics, and Granite as Fillers in Ultra-High Performance Fiber Concrete

Boulkenafet,

Adbelouahed,

Hebhoub

et al. 2024

ACSM

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Waste recovery and environmental protection and the production of low-cost UHPFC are the most trends areas of current researchers. Ultrafine (silica fume) is the basic component of ultra-high-performance fiber concrete (UHPFC), which is very sophisticated and its manufacture is limited by the capacity of some industries. This work, which falls within this context, aims to recover waste (glass, ceramics, and granite) as recycled fillers partially substituted silica fumes in the composition of the UHPFC. The study consists of two parts, the first is to find a formulation based on local materials, the second is to replace the silica fumes by recycled fillers with the percentage of 10% and 20%. The tests carried out on the fresh state mixtures are density, workability and occluded air, and on hardened state are the compressive and flexural tensile strength, sclerometer, ultrasound regarding untreated concrete, and the performance in compressive and tensile strength concerning the concrete heat treated at 90℃, as well as durability parameters (water absorption and chlorides penetrations). The results show that recycled ceramic fillers and 20% of the recycled granite fillers present an acceptable compressive strength, the recycled fillers increase the flexural tensile strength of the UHPFC and the heat treatment improves the mechanical strength. Recycled fillers affect sustainability parameters.

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Section: Flexural Tensile Strength On Non-thermally Treated Concretementioning

confidence: 93%

Preliminary Study on the Use of Recycled Glass, Ceramics, and Granite as Fillers in Ultra-High Performance Fiber Concrete

Boulkenafet,

Adbelouahed,

Hebhoub

et al. 2024

ACSM

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“…Moreover, the compressive strength of the resulting concrete was enhanced by up to 15% when 15% of the cement was replaced with CWP [71]. CWP cement concrete exhibited a decreased workability retention [72]. Studies have determined that the uneven size distribution of ceramic waste constituents is responsible for the lack of consistency in the workability of concrete [22].…”

Section: Concrete-incorporated Ceramic Sludge 61 Fresh Propertiesmentioning

confidence: 99%

“…CWP reduced the workability of fresh concrete [25]; however, when CWP was utilized as the sole replacement for cement, a rapid increase in the concrete-mixture slump was observed, indicating its plasticizing effect. Moreover, the compressive strength of the resulting concrete was enhanced by up to 15% when 15% of the cement was replaced with CWP [72]. CWP cement concrete exhibited a decreased workability retention [73].…”

Section: Fresh Propertiesmentioning

confidence: 99%

Review of the Properties of Sustainable Cementitious Systems Incorporating Ceramic Waste

Al-Fakih,

Odeh,

Mahamood

et al. 2023

Buildings

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Global carbon dioxide emissions can be attributed to Portland cement production; thus, an alternative cementitious system is essential to reduce cement demand. Ceramic waste powder (CWP), which contains high proportions of silica and alumina, has emerged as a promising alternative because of its chemical composition. This review discusses the potential of CWP as an alternative cementitious system and its effects on the physical, mechanical, and durability properties of cementitious systems. The findings revealed that the utilization of CWP in cementitious systems has positive effects on their physical, mechanical, and durability properties owing to the chemical composition of CWP, which can act as a filler material or contribute to the pozzolanic reaction. A pozzolanic reaction occurs between the silica and alumina in the CWP and calcium hydroxide in the cement, resulting in the production of additional cementitious materials such as calcium silicate hydrates and calcium aluminate hydrates. These additional materials can improve the strength and durability of cementitious systems. Various studies have demonstrated that CWP can be effectively used as a partial replacement for cement in cementitious systems. This can reduce the carbon footprint of construction activities by reducing the demand for Portland cement. However, the optimal amount and particle size of CWP have not been fully determined, and further research is required to optimize its use in cementitious systems. In addition, the technical and economic challenges associated with the use of CWP in construction must be further investigated to ensure its effective implementation.

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“…Currently, this waste is not being recycled in any form. However, ceramic waste exhibits durability, hardness, and high resistance to biological, chemical, and physical degradation [9]. Despite designated areas for waste dumping, ceramic industries often dispose of the Ceramic waste powder (CWP) in nearby pits or vacant spaces near their units.…”

Section: Introductionmentioning

confidence: 99%

“…Consequently, it becomes crucial to swiftly dispose of ceramic waste and explore its utilisation in the construction industry. With the continuous accumulation of ceramic waste daily, there is mounting pressure on the ceramic industries to find a sustainable solution for its disposal [9].…”

Section: Introductionmentioning

confidence: 99%

Enhancing Subgrade Properties of Black Cotton Soil through the Combined Use of Sugarcane Bagasse Ash and Ceramic Waste Powder

Gouda,

Santosh,

Sitarami Reddy

et al. 2024

IOP Conf. Ser.: Earth Environ. Sci.

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This study explores the potential of Sugarcane Bagasse Ash (SBA) and Ceramic Waste Powder (CWP) in enhancing the poor black cotton (BC) soils, known for their swelling and shrinking tendencies due to high clay content. BC soils can compromise construction stability when exposed to moisture. The research involves mixing BC soil with varying proportions of SBA and CWP: 2.5% SBA and 5% CWP, 5% SBA and 10% CWP, 7.5% SBA and 15% CWP, and 10% SBA and 20% CWP. Laboratory tests show that higher SBA and CWP ratios reduce plasticity, free swell index, and Optimum Moisture Content (OMC) in the soil. This indicates that SBA and CWP additions mitigate soil plasticity and swelling. Moreover, parameters such as Maximum Dry Density (MDD), California Bearing Ratio (CBR), and unconfined compressive strength improve as SBA and CWP content increases, indicating enhanced soil strength. Laboratory findings support using up to 7.5% SBA and 15% CWP for effective subgrade soil stabilisation. A Plaxis 2D model confirms that these proportions significantly enhance pavement subgrade stability. In summary, this study demonstrates the positive impact of SBA and CWP on BC soils, reducing plasticity and swelling and improving soil strength. Using specific proportions of SBA and CWP effectively enhances subgrade soil stability, as verified by Plaxis 2D modelling.

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Study the Effect of Using Ceramic Waste Powder as Partial Replacement for Cement on Concrete Properties

Cited by 5 publications

References 30 publications

Preliminary Study on the Use of Recycled Glass, Ceramics, and Granite as Fillers in Ultra-High Performance Fiber Concrete

Preliminary Study on the Use of Recycled Glass, Ceramics, and Granite as Fillers in Ultra-High Performance Fiber Concrete

Review of the Properties of Sustainable Cementitious Systems Incorporating Ceramic Waste

Enhancing Subgrade Properties of Black Cotton Soil through the Combined Use of Sugarcane Bagasse Ash and Ceramic Waste Powder

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