Waste marble powder/dust

Demirel, Bahar; Alyamaç, Kürşat Esat

doi:10.1016/b978-0-08-102156-9.00006-7

Cited by 31 publications

(30 citation statements)

References 43 publications

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“…are very well eminent. The nature of basalt fiber and its properties are discussed in detail by Jamshaid and Mishra, 17 Ralph et al, 18 Dhand et al, 19 Bhat et al 20,21 and Dalinkevich et al 22 Demirel and Alyamac 23 pen-down the nature and properties of marble dust particulates. Jin et al 24 discussed the synthesis, properties, and application of epoxy resin.…”

Section: Introductionmentioning

confidence: 99%

Parametric optimization and ranking analysis of hybrid epoxy polymer composites based on mechanical, thermo-mechanical and abrasive wear performance

Kumar

Tak

et al. 2020

High Performance Polymers

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In this research work, designing and fabrication of hybrid epoxy polymer composite materials had been carried out. It consists of basalt fiber (constant fraction) and marble dust particulates (0–10 wt% @ step of 2.5%) ensuing five compositions namely, MBE-0, MBE-2.5, MBE-5, MBE-7.5, and MBE-10. The specimen’s undergone physical, mechanical, and thermo-mechanical characterizations followed by three-body abrasive wear performance evaluation. Parametric optimizations of the wear have been evaluated with the Taguchi technique. The performance data are used to rank the compositions using a hybrid AHP-VIKOR selection making tool. It has been observed that voids content improves with reinforcement up to 5 wt% marble dust reinforcement, thereafter, it deteriorates sharply. The mechanical properties with 5 wt% marble dust reinforcement found to be highest. The thermo-mechanical characteristics like modulus and damping improve with marble dust reinforcement and temperature. The Cole-Cole plots reveal the heterogeneity present in the composites. The Taguchi’s analysis reveals the order of operating factors influencing specific wear rate as abrading distance > normal load > reinforcement composition > abrasive size. The steady state-specific wear rate of the composites reveals decremented rate across the abrading distance range irrespective of reinforcement proportions and at any specific abrading distance the order it followed as MBE-5 < MBE-7.5 < MBE-2.5 < MBE-10 < MBE-0. The ranking analysis using hybrid AHP-VIKOR technique predicts the ranking sequence as MBE-5 > MBE-7.5 > MBE-2.5 > MBE-10 > MBE-0, which are in-line with subjective analysis.

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Section: Introductionmentioning

confidence: 99%

Parametric optimization and ranking analysis of hybrid epoxy polymer composites based on mechanical, thermo-mechanical and abrasive wear performance

Kumar

Tak

et al. 2020

High Performance Polymers

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“…Also, Figure 3 presents an example of a scanning electron microscope (SEM) micrographs of marble dust particles. As reported previously, the specific gravity of this material varies over a wide range between 2.39 and 3.16 due to the difference in the structural and chemical properties of the marble stones [15]. Similarly, the chemical compositions of marble dust various based on the type of stone used.…”

Section: Engineering Properties Marble Dustmentioning

confidence: 58%

Sustainable Recycling of Marble Dust as Cement Replacement in Concrete: Advances and Recent Trends

Habib¹,

Habib²

2021

Cement Industry - Optimization, Characterization and Sustainable Application

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In recent years, many researchers in the construction industry had taken up the challenge to incorporate non-biodegradable wastes as partial replacement of cement and/or natural aggregates in the daily production of cement-based materials. Various efforts were intended to understand the influence of using marble dust in concrete due to its availability and a relatively high volume of the generation that causes serious environmental problems. Previous studies have utilized marble dust as a replacement of cement, fine aggregate, or total paste in the concrete and mortar mixtures. In general, several investigations have shown that up to a certain cement replacement ratio, marble dust can positively impact on the strength and microstructure properties of concrete. Furthermore, the results have indicated that the considerably high degree of fineness in the marble dust provides sufficient cohesiveness of mortar and concrete even in low w/c ratio conditions. Hence, this powder can be utilized as a filler to improve the flowability of cement-based materials. Consequently, this chapter aims to summarize recent investigations on the properties of concrete incorporating marble waste as cement replacement materials, highlight the potential gaps in the literature, and propose a prediction model for estimating the compressive and flexural strengths of concrete with marble dust using regression analysis.

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“…Typically marble dust is composed of the following major constituents; Lime(CaO): 38-42%, Silica(SiO2): 20-25%, Alumina(Al2O3): 2-4%, Oxides (NaO and MgO): 1.5-2.5%, Carbonates(MgCO3): 30-32% [23]. Further details on the physical, chemical, and morphological properties of waste marble dust, its applications and the role of its management in achieving a sustainable environment and construction are well detailed in the extensive study by [31]. Figure 1 shows samples of waste marble dust obtained from the Kenya Marble and Quarries Limited, Industrial Area, Nairobi.…”

Section: Marble Dustmentioning

confidence: 99%

Evaluation of the Performance of Waste Marble Dust as a Mineral Filler in Hot-Mix Asphalt Concrete

Sang

Idowu

Okumu

2021

JCEST

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As the construction industry continues to evolve globally, there is a need to develop best practices geared towards achieving sustainable construction. Asphalt concrete’s demand has been increasing steadily with an estimated global demand of 122.5 million tons in 2019. This is driven primarily by the growth in construction activities in developing countries as each country works towards enhancing its transportation facilities to cater to the ever-expanding population. Hence, there are needs to develop newer and more efficient means of asphalt consumption. One of such is identifying cheaper or waste materials for use in Asphalt production. This study, therefore, examined the viability of waste marble dust (WMD), an industrial waste produced during the shaping and polishing of marble blocks and also during its extraction from the mines, as a mineral filler in Hot-mix asphalt (HMA) concrete. Engineering properties such as Marshall stability and flow, Void characteristics, Indirect tensile strength and Tensile strength ratio properties were examined. It was observed that the addition of WMD steadily increased the Marshall Stability and indirect tensile strength values and lowered the voids percentages. The study’s major finding is that waste marble dust is highly suitable as a mineral filler in HMA and a 3% by volume addition of WMD in HMA at 4.5% binder content produced the most optimal mix for use in road pavements.

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Waste marble powder/dust

Cited by 31 publications

References 43 publications

Parametric optimization and ranking analysis of hybrid epoxy polymer composites based on mechanical, thermo-mechanical and abrasive wear performance

Parametric optimization and ranking analysis of hybrid epoxy polymer composites based on mechanical, thermo-mechanical and abrasive wear performance

Sustainable Recycling of Marble Dust as Cement Replacement in Concrete: Advances and Recent Trends

Evaluation of the Performance of Waste Marble Dust as a Mineral Filler in Hot-Mix Asphalt Concrete

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