Your search keyword '"GLASS waste"' showing total 2,806 results

1. Harnessing earthquake generated glass and plastic waste for sustainable construction

Author

Khurshid, Fazilah and Gunal, Ayse Yeter

Published

2024

2. Preparation of lightweight foam glass-ceramics from copper slag tailings: Secondary aluminum slag as pore-forming agent.

Author

Zhang, Lixing, Liang, Lisi, Li, Yi, Chen, Jin, Cui, Zhongyi, Qiao, Jiangyu, Zhang, Zhuyue, Wang, Zeming, Xu, Qiang, and Zhao, Chen

Subjects

*COPPER slag, *RAW materials, *GLASS waste, *METAL wastes, *ALUMINUM nitride, *GLASS-ceramics

Abstract

To address metallurgical waste residue pollution, this study utilized copper slag tailings (CST) and waste glass (WG) as primary raw materials, with secondary aluminum dross (SAD) as a pore-forming agent, to produce lightweight spontaneous foam glass-ceramics. The effects of raw material ratios, sintering temperature (1120–1160 °C), and sintering time (0–40 min) on foam glass-ceramics properties were investigated, elucidating the correlations between various properties. Under optimal preparation conditions (CST: WG: SAD = 7:11:2, sintered at 1150 °C for 20 min), the foam glass-ceramics exhibited a bulk density of 0.41 g/m³, compressive strength of 2.32 MPa, open porosity of 61.02 %, 2-h water absorption of 83.76 %, and mean pore size of 3.12 mm. The sintering process transformed raw materials into substances like diopside subsilic ferrian, which enhanced the strength of lightweight foam glass-ceramics. Harmful substances in the raw materials can be immobilized within the internal structure of foam glass-ceramics, ensuring excellent environmental safety. Additionally, comprehensive characterization was conducted on the foam glass-ceramics, elucidating their composition, structure, and pore-forming mechanisms. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effect of alumina source on the retention of rhenium during low-activity waste feed conversion to glass.

Author

Eret, Matouš, Löwy, Laura, Kloužek, Jaroslav, Cincibusová, Petra, Vernerová, Miroslava, Lhotka, Miloslav, Kohoutková, Martina, Michalcová, Alena, Brus, Jiří, Hrma, Pavel, Kruger, Albert A., and Pokorný, Richard

Subjects

*GLASS waste, *RADIOACTIVE wastes, *GIBBSITE, *CYANITE, *ALUMINUM oxide

Abstract

Volatility of technetium poses a challenge during the vitrification of low-activity waste (LAW) feed to glass. Although this is typically resolved through recycle loops, this can lead to other problems, such as sulfate phase formation. Thus, ensuring high single-pass retention of Tc (or Re, its non-radioactive surrogate) is required for enabling high waste-loading formulations. In our previous study, we observed significantly higher Re retention in final waste glass produced from a LAW melter feed containing gibbsite as the alumina source compared to a compositionally similar feed containing kyanite. To investigate this effect, we prepared representative LAW melter feeds with kyanite and gibbsite as alumina sources and measured the Re retention in the produced glasses. We found that the Re retention is consistently higher in glasses produced with gibbsite, by up to 20 %. We attribute this result to the formation of nanocrystalline alumina in melter feeds containing gibbsite. Possessing a high surface area, nanocrystalline alumina can adsorb the perrhenate-containing molten salt, increasing the rate at which Re is incorporated into the alkali-alumino-boro-silicate glass-forming melt. In addition, we demonstrate that replacing kyanite with gibbsite in LAW melter feeds has no adverse effects on their processing during vitrification. [ABSTRACT FROM AUTHOR]

Published

2024

4. Effect of Waste Glass Powder Replacement of Hydraulic Lime on Properties of Natural Hydraulic Lime Mortars.

Author

Sahin, Murat and Ozyigit, Polat

Subjects

*ULTRASONIC testing, *LIME (Minerals), *GLASS waste, *POWDERED glass, *MORTAR, *POZZOLANIC reaction

Abstract

This paper investigates the effects of the partial replacement of natural hydraulic lime (NHL) with waste glass powder (GP) on the physical, mechanical, and microstructural properties of NHL mortars. In the experimental study, five mixtures containing up to 50% GP were prepared to evaluate its effect on the flow, carbonation, unit weight, water absorption, porosity, ultrasonic pulse velocity, capillary water absorption, compressive strength, and microstructure of NHL mortars. The experimental results suggest that the partial replacement of NHL with GP significantly affects the properties of NHL mortars. A reduction in compressive strength was observed with increasing GP content in mortars at both early and later stages. Nevertheless, the compressive strength difference between samples containing 50% GP and the reference was found to be relatively minor at 91 days, implying an enhanced pozzolanic reaction over time. The incorporation of GP improved the consistency and capillary water absorption of mortars, while the opposite was observed for ultrasonic pulse velocity, porosity, and water absorption. The microstructural analysis revealed distinct changes in the structure of samples incorporating GP. The partial substitution of hydraulic lime with GP could be beneficial in reducing the CO2 emissions of NHL mortars. [ABSTRACT FROM AUTHOR]

Published

2024

5. Cold Consolidation of Pharmaceutical Waste Glass Powders Through Alkali Activation and Binder Jet 3D Printing.

Author

Elsayed, Hamada, Gobbin, Filippo, Barci, Alberto, Bernardo, Enrico, and Colombo, Paolo

Subjects

*GLASS waste, *BINDING agents, *BOROSILICATES, *WATER immersion, *IMMERSION in liquids, *GLASS recycling

Abstract

The recent COVID-19 emergency has led to an impressive increase in the production of pharmaceutical vials. This has led to a parallel increase in the amounts of waste glass; manufacturers typically recover material from faulty containers by crushing, giving origin to an unrecyclable fraction. Coarse fragments are effectively reused as feedstock for glass melting; on the contrary, fine powders (<100 microns), contaminated by metal and ceramic particles due to the same crushing operations, are landfilled. Landfilling is also suggested for pharmaceutical containers after medical use. This study aims at proposing new opportunities for the recycling of fine glass particles, according to recent findings concerning alkali activation of pharmaceutical glass, combined with novel processing, i.e., binder jetting printing. It has already been shown that pharmaceutical glass, immersed in low-molarity alkaline solution (not exceeding 2.5 M NaOH), undergoes surface dissolution and hydration; cold consolidation is later achieved, upon drying at 40–60 °C, by a condensation reaction occurring at hydrated layers of adjacent particles. Binder jetting printing does not realize a full liquid immersion of the glass powders, as the attacking solution is selectively sprayed on a powder bed. Here, we discuss the tuning of key parameters, such as the molarity of the attacking solution (from 2.5 to 10 M) and the granulometry of the waste glass, to obtain stable printed blocks. In particular, the stability depends on the formation of bridges between adjacent particles consisting of strong T-O bonds (Si-O-Si, Al-O-Si, B-O-Si), while degradation products (concentrating Na ions) remain as a secondary phase, solubilized by immersion in boiling water. Such stability is achieved by operating at 5 M NaOH. [ABSTRACT FROM AUTHOR]

Published

2024

6. Synergy between Ca2+ and high ionic field‐strength cations during the corrosion of alkali aluminoborosilicate glasses in hyper‐alkaline media.

Author

Qin, Qianhui, Stone‐Weiss, Nicholas, Shi, Nian, Mukherjee, Pinaki, Ren, Jinjun, and Goel, Ashutosh

Subjects

*GLASS waste, *BOROSILICATES, *GEOLOGICAL repositories, *NUCLEAR models, *CALCIUM ions

Abstract

One major factor impeding the design of nuclear waste glasses with enhanced waste loadings is our insufficient understanding of their composition–structure–durability relationships, specifically in the environments the waste form is expected to encounter in a geological repository. In particular, the high field‐strength cations (HFSCs) are an integral component of most waste streams. However, their impact on the long‐term performance of the glassy waste form remains mostly undeciphered. In this context, the present study aims to understand the impact of some HFSCs (i.e., Nb5+, Zr4+, Ti4+, and La3+) on the dissolution behavior of alkali/alkaline‐earth aluminoborosilicate‐based model nuclear waste glasses in hyper‐alkaline media. At pH = 13, the studied glasses dissolve through the dissolution–reprecipitation mechanism, with Ca precipitation being the most vital step to passivation. In Ca‐free glasses, although the HFSCs slow down the forward rate, they do not seem to impact the residual rate behavior of glasses. The presence of Ca2+, however, initiates the rapid precipitation of network polymerizing HFSCs (i.e., Nb5+, Zr4+, and Ti4+) into a Ca2+/HFSCs‐based passivating layer, thus suggesting a synergy between Ca2+ and HFSCs that contributes to the enhanced long‐term durability of the glasses. Such synergy is not strongly evident for La3+, but instead, a potential La/Si affinity is observed upon the formation of the alteration layer. [ABSTRACT FROM AUTHOR]

Published

2024

7. Synthesis of xonotlite using quartz glass powder waste as a silicon source.

Author

Liu, Wengang, Zhang, RuiRui, Liu, Wenbao, Li, Weichao, and Wang, Shuaichao

Subjects

*POWDERED glass, *FUSED silica, *GLASS waste, *GLASS construction, *RAW materials

Abstract

Quartz glass powder is a type of silicon-rich industrial waste. Accumulation of this waste has led to resource wastage and environmental pollution. In this paper, quartz glass powder is used as raw material for preparing xonotlite through hydrothermal synthesis. The effects of Ca/Si (C/S) molar ratio, liquid/solid ratio, reaction temperature, and reaction time on the conversion of quartz are studied. The phase and structural changes of glass powder are analyzed by X-ray diffraction (XRD) and scanning electron microscopy (SEM). Based on this, the conversion mechanism of quartz in glass powder is explained. The dissolution rate of quartz in an alkaline solution is a critical factor that restricts hydrothermal reactions. The conversion rate of quartz can be effectively increased by raising reaction temperature and extending reaction time. When the reaction temperature is 240 °C and the reaction time reaches 14 h, the conversion of quartz can reach 94.5 wt%. This study reveals the conversion mechanism of quartz in hydrothermal reactions and provides a theoretical basis for the efficient utilization of glass powder. [ABSTRACT FROM AUTHOR]

Published

2024

8. Assessment of Various Mitigation Strategies of Alkali-Silica Reactions in Concrete Using Accelerated Mortar Test.

Author

Almakrab, Abdullah, Elshazli, Mohamed T., Ibrahim, Ahmed, and Khalifa, Yasser A.

Subjects

*CONCRETE durability, *GLASS waste, *REINFORCED concrete, *ACCELERATED life testing, *COMPRESSIVE strength

Abstract

The widespread use of reinforced concrete continues to face challenges, particularly in mitigating alkali-silica reaction (ASR), due to its detrimental effects on concrete strength and durability. This paper investigates the effectiveness of using binary supplementary cementitious materials (SCMs) in mitigating ASR by incorporating metakaolin (MK) and waste glass powder (GP) as partial replacements for cement. Additionally, the potential of a new cement product, "NewCem Plus" (NCM), along with the use of basalt fibers and lithium, was evaluated through a 14-day accelerated mortar bar test following the ASTM C1260. This study also assessed concrete's properties such as its compressive strength and workability using the flow test. The results indicated that MK was effective, reducing expansion by 79%, 84%, and 88% with 10%, 20%, and 30% cement replacement, respectively, compared to the control mixture. On the other hand, GP showed a more modest reduction in expansion, with 10%, 20%, and 30% replacement levels reducing expansion by 20%, 43%, and 75%, respectively. Furthermore, the addition of lithium to MK significantly mitigated ASR, reducing expansion below the ASTM threshold. However, mixtures containing NewCem Plus, lithium, and basalt fibers showed minimal impact on ASR reduction. These findings underscore the viability of using binary or ternary blends of SCMs to mitigate ASR in concrete, encouraging their adoption in future concrete applications. [ABSTRACT FROM AUTHOR]

Published

2024

9. Recycled cathode ray tube waste glasses for radiation shielding applications: Role of Na2CO3.

Author

Alzahrani, Jamila S., Alrowaili, Z.A., Olarinoye, I.O., Alshahrani, B., and Al-Buriahi, M.S.

Subjects

*CATHODE ray tubes, *MASS attenuation coefficients, *GLASS waste, *THERMAL neutrons, *POWDERED glass

Abstract

The aim of the study is to evaluate the ability of cathode-ray tube funnel waste glasses (CRT-F) to shield photons (gamma and X-ray) and other forms of radiation with rest masses (i.e., neutrons and charged particles) after their Pb content was reclaimed. The lead (Pb) content of cathode-ray tube funnel waste glasses (CRT-F) was reduced using Na 2 CO 3 as the reducing agent CRT-F(Na 2 CO 3). CRT-F and CRT-F(Na 2 CO 3) were produced using the melt and quench processes using the powder of pristine funnel glass from discarded cathode ray tube glass and the reduced glass powder, respectively, as the starting materials. The X-ray fluorescence technique was adopted for determining the chemical composition of CRT-F and CRT-F(Na 2 CO 3) glasses. The parameters relating to the gamma photon, fissile neutron, moderated neutron, slow neutron, and charged radiation (β, H+, He2+, and C6+) attenuation abilities of pristine CRT-F and CRT-F(Na 2 CO 3) were evaluated. The FLUKA simulation code and XCOM were used to estimate the mass attenuation coefficient of the glasses. The stopping power (S p) and range (R) of β, H+, and He2+ were evaluated by using the NIST data-based calculators (ESTAR for β, PSTAR for H+, and ASTAR for He2+) while S p and R data for C6+ was determined using SRIM. The cross section for fast, thermal (25 meV), and slow neutrons (0.1–10 meV) was also estimated. The Pb reclamation from the CRT-F drastically increased the half value layer of photons by at least a factor of 4 at 0.1 MeV and by more than 90 % at 10 MeV. The CRT-F interacts more with fissile and thermal neutrons compared to CRT-F(Na 2 CO 3). Although, CRT-F showed a better ability to attenuate all the radiation types considered, both glasses are better absorbers of radiation (especially photons) than some common shields. The reduction of Pb weight in CRT-F resulted in a drastic reduction in the ability of the glass to attenuate radiation; the resulting glass (CRT-F(Na 2 CO 3)) is however, an environmentally safer glass shield. [ABSTRACT FROM AUTHOR]

Published

2024

10. Structure–property relations of sodium iron phosphate nuclear waste glasses: Effects of iron redox ratio and glass composition.

Author

Kalahe, Jayani, Lu, Xiaonan, Riley, Brian J., Vienna, John D., and Du, Jincheng

Subjects

*PHOSPHATE glass, *GLASS waste, *RADIOACTIVE wastes, *MOLECULAR dynamics, *CHEMICAL bond lengths

Abstract

Iron phosphate glasses, known for their exceptional chemical durability and potential applicability in nuclear waste management, have gained significant attention over the years. The structures of these glasses are complicated by the coexistence of Fe3+ and Fe2+, which plays a crucial role in determining their structures and properties. This work uses molecular dynamics simulations to study the structural changes in Na2O–Fe2O3–P2O5 glasses with varying glass composition and Fe2+/Fe3+ redox ratio. It was found that the redox ratio and modifier contents significantly affected the short‐range and medium‐range orders in the glasses. Significant changes in the local environments around P5+ and Fe3+ were observed, as reflected by the bond distances and coordination numbers. Na+ cations are found to preferentially associate with Fe3+ (rather than Fe2+),  whereas Fe2+ has stronger association with P5+ than Na+, confirming the structural role of Fe2+ as a glass modifier. The disruptions in P–O–P linkages upon increasing FeO suggest that FeO causes glass depolymerization. These glasses achieved higher connectivity with increasing Fe3+/(Fe3++Fe2+)${\mathrm{Fe}}^{3+}/({\mathrm{Fe}}^{3+}+{\mathrm{Fe}}^{2+})$ ratios, conerting phosphorous Q2 to Q3 units and iron Q5 units to Q4 units. The decrease of nonbridging oxygen fractions with increasing Fe3+/(Fe3++Fe2+)${\mathrm{Fe}}^{3+}/({\mathrm{Fe}}^{3+}+{\mathrm{Fe}}^{2+})$ ratios, through creating P–O–Fe linkages, is the main reason of enhanced network connectivity. Quantitative structure–property relationship analyses with different structural descriptors were used to correlate with measured properties. The analyses provided valuable insights into structure–property relationships, emphasizing the importance of choosing relevant energy parameters and defining glass network connectivity, particularly in Fnet descriptors. It was found the Fe–O–P linkage density exhibits strong correlations to measured dissolution rates, supporting the importance of these linkages in improving the chemical durability in iron phosphate glasses. [ABSTRACT FROM AUTHOR]

Published

2024

11. Alkali-Silica Reaction and Residual Mechanical Properties of High-Strength Mortar Containing Waste Glass Fine Aggregate and Supplementary Cementitious Materials.

Author

Eu, Hamin, Kim, Gyuyong, Son, Minjae, Sasui, Sasui, Lee, Yaechan, Choi, Hyeonggil, Kang, Sukpyo, and Nam, Jeongsoo

Subjects

GLASS waste, HIGH strength concrete, FLY ash, CEMENT composites, POZZOLANIC reaction, MORTAR

Abstract

This paper presents the influence of supplementary cementitious materials (SCMs), such as fly ash (FA), silica fume (SF), ground granulated blast furnace slag (GGBS), and waste glass fine aggregate (GA), on the alkali-silica reaction (ASR) in high-strength and normal-strength mortar using an accelerated mortar bar test (AMBT). Residual mechanical properties and scanning electron micrographs were used to assess the changes in the matrix. GA reduced the mechanical properties of both normal-strength (NGA_OPC) and high-strength mortars (HGA_OPC), contributing to a decline in overall performance. This phenomenon was a result of the slipping of the GA from the matrix owing to its smooth surface. However, the inclusion of reactive SF and GGBS in the HGA improved the slip phenomenon of the GA, leading to a significant enhancement in its mechanical properties. Following the ASR expansion measurement, HGA_OPC demonstrated an ASR expansion rate approximately three times higher than that of NGA_OPC. This was attributed to the dense structure of HGA_OPC, which resulted in greater expansion than that of NGA_OPC. However, with the incorporation of SCMs into both HGA and NGA, a significant reduction in ASR expansion was observed. This was attributed to the delayed ASR of GA due to alkali activation or the pozzolanic reaction of the SCMs. Continuous exposure to the AMBT environment can lead to the destruction of GA. This was caused by the inner ASR that originated from the surface crack of the GA, which resulted in a reduction in the flexural strength of the mortar. The HGA with SF exhibited the highest resistance to ASR expansion and residual mechanical properties' degradation. Therefore, various durability and long-term performance-monitoring studies on ultra-high-performance concrete or high-strength cementitious composites with very high SF contents and GA can be conducted. [ABSTRACT FROM AUTHOR]

Published

2024

12. Investigation on effects of waste glass powder reinforced HDPE composites for sustainability.

Author

Pandey, Sandeep Kumar and Gupta, Rajeev Nayan

Subjects

*GLASS waste, *POWDERED glass, *THERMOPLASTIC composites, *AERODYNAMIC heating, *HIGH density polyethylene

Abstract

The current study explores the fabrication of 3D printing filament using waste glass powder (WGP) and high-density polyethylene (HDPE) thermoplastic aiming to enhance the mechanical properties and sustainability of the composite material. The matrix and filler were blended in varying weight ratios (HDPE: WGP) of 100:0, 95:5, 90:10, 85:15, and 80:20 to prepare a raw material for filament extrusion. The filament of diameter 1.65 ± 0.05 mm diameter was extruded. Thereafter, a chemical and thermo-mechanical characterization of extruded filament was conducted. Fourier-transform infrared spectroscopy (FTIR) analysis confirmed the successful integration of WGP into the HDPE matrix, while X-ray diffraction (XRD) examination revealed alterations in crystallinity attributed to WGP reinforcement. Thermogravimetric Analyzer (TGA) analysis demonstrated enhanced thermal stability upon WGP incorporation, which is attributed to its role as a thermal barrier. Tensile test exhibit 45.41% and 17.22% increase in yield stress and ultimate tensile stress for 90:10 composition ratio, respectively. Moreover, including waste glass powder in HDPE, thermoplastic composite offers a sustainable solution for repurposing glass waste, thereby reducing the volume of glass destined for landfills or incineration. Potential applications of this composite filament include its use in construction, automotive, and packaging industries through 3D printing, where improved mechanical properties and sustainability are highly valued. [ABSTRACT FROM AUTHOR]

Published

2024

13. Recent Progress on the Synthesis and Applications of Zeolites from Industrial Solid Wastes.

Author

Zhang, Wentao, Zhang, Ting, Lv, Yinmei, Jing, Tao, Gao, Xu, Gu, Ziqi, Li, Shiyang, Ao, Hailing, and Fang, De

Subjects

*INDUSTRIAL wastes, *GLASS waste, *WASTE recycling, *SOLID waste, *COAL ash, *FLY ash

Abstract

Zeolites have been increasingly applied in various fields such as energy conversion, environmental remediation, chemical production, and so on, being used as membranes, catalysts, and supports due to their large specific areas and strong gas adsorption. And, developing low-cost strategies for the preparation of zeolites has attracted the extensive attention of researchers. Coal fly ash, waste glass, discard zeolites, and slags are typical industrial wastes and rich in Si and Al, indicating that these industrial wastes can be utilized as alternative raw materials of zeolite synthesis. Firstly, the chemical composition and properties of these industrial wastes are summarized. Then, the strategies involved in synthesizing different zeolites from various industrial wastes are discussed. In addition, the applications of these zeolites are comprehensively reviewed. [ABSTRACT FROM AUTHOR]

Published

2024

14. Expansion Control of Alkali-Activated Materials Using Waste Glass Cullet from Photovoltaic Panels as Fine Aggregates.

Author

Yamanouchi, Ryo, Yasui, Kentaro, Yamada, Hiroshi, Fukunaga, Takayuki, and Harada, Hideki

Subjects

*GLASS waste, *FLY ash, *COMPRESSIVE strength, *SLAG, *MORTAR, *MECHANICAL heat treatment

Abstract

Glass cullet (GC) generated from the disposal of photovoltaic (PV) panels are typically landfilled, and effective GC utilization methods must be established for PV generation. In this study, alkali-activated material (AAM) mortars were prepared from the paste of fine blast-furnace slag powder, fly ash, and sodium orthosilicate (SO) and mixed with crushed sand and GC to investigate the potential use of GC as a fine aggregate in AAM. The replacement of crushed sand with GC did not considerably affect the flowability of the mortar, whereas the compressive strength decreased with the increasing GC replacement rates. Although expansion due to the alkali–silica reaction (ASR) was observed in mortars wherein GC replaced crushed sand, the expansion can be controlled by reducing the amount of mixed SO, autoclaving the GC, performing preleaching to remove the Si that causes the ASR, and replacing the blast-furnace slag with fly ash. By enforcing measures against the expansion, the possibility of using GC as fine aggregate is enhanced considerably, thus increasing the feasibility of continuous PV production. [ABSTRACT FROM AUTHOR]

Published

2024

15. Research on Design and Performance of Microsurfacing Asphalt Mixture with Waste Glass Aggregate.

Author

Fan, Yansong, Chen, Meizhu, Liu, Wei, Lv, Zhenglong, Cheng, Ming, and Zhang, Jianwei

Subjects

*GLASS waste, *WASTE recycling, *SOLID waste, *STYRENE-butadiene rubber, *SHEAR strength

Abstract

Waste glass as a solid waste is urgently needed to utilize and alleviate the shortage of natural aggregate. In this paper, a styrene-butadiene rubber (SBR) modified emulsified asphalt microsurfacing mixture was prepared by partially replacing basalt aggregate with waste glass, and the interlayer shear resistance and night visibility were explored. The optimum content of SBR was determined by evaluating the properties of SBR-modified emulsified asphalt. The wet track abrasion and load wheel test were chosen to optimize the content of asphalt. Moreover, Leutner shear strength was measured to characterize the interlayer shear resistance, and the night visibility was certified through qualitative and quantitative methods. The experimental results indicate that modified emulsified asphalt exhibits good properties when the dosage of SBR is 4%. The addition of waste glass exerts a certain weakening effect on interlayer shear resistance of the microsurfacing mixture, but the adverse impact could be neglected when the content of coarse and fine waste glass is less than 15%. The night visibility is improved significantly when the waste glass is added; the retroreflection coefficients are 52.2 and 45.7 mcd/lx/m2 , respectively, when the content of waste glass fine aggregate and waste glass coarse aggregate reaches 20%, and the reflective effect brought by waste glass fine aggregate is more remarkable. The application of waste glass in the microsurfacing mixture realizes the resource utilization of solid waste, provides a safe environment for driving at night, and achieves the effects of traffic guidance and landscape. [ABSTRACT FROM AUTHOR]

Published

2024

16. Strength and Absorption Study on Eco-Efficient Concrete Using Recycled Powders as Mineral Admixtures under Various Curing Conditions.

Author

Herki, Bengin M. A.

Subjects

MANUFACTURING processes, GLASS waste, PORTLAND cement, POWDERED glass, CONCRETE durability

Abstract

Durable building materials are essential for sustainability in construction projects, aiming to reduce environmental damage from the start to the end of a building's life. Reducing the use of Portland cement in concrete production is essential because of the significant CO2 emissions generated globally during its production process. This study investigates the workability, compressive strength, and water absorption of concrete when Portland cement is partially substituted with waste glass powder (WGP) and recycled concrete powder (RCP). These two waste powders can be used to partially substitute Portland cement in order to produce environmentally friendly concrete. The activity of the particles in concrete made from these two waste powders is mostly determined by the type and rate of the powders, as well as the curing methods. Therefore, the current research examines how different curing conditions impact the workability, compressive strength, and water absorption characteristics of this innovative eco-friendly concrete that includes the abovementioned waste powders. According to the experimental results obtained, adequate strength can be achieved using an appropriate replacement level of the powders and curing methods. Therefore, the application of these two recycled mineral admixtures in concrete can save Portland cement and has certain environmental and economic benefits. [ABSTRACT FROM AUTHOR]

Published

2024

17. Flexural behavior of textile reinforced concrete using waste fishing net as continuous reinforcement.

Author

Gopinath, Smitha, Abhirami, A. L., Ganesan, Ishwarya, and Kumar, Nartu Manoj

Subjects

*FISHING nets, *FISH waste, *GLASS waste, *CONCRETE waste, *TEXTILE waste

Abstract

AbstractThe present study investigated the flexural properties of Textile Reinforced Concrete (TRC) incorporated with waste fishing nets as reinforcement with a view to providing a potential solution to the environmental impact caused by these nets. Locally available waste fishing nets having two different mesh sizes and thicknesses were used as textile reinforcement for investigation. The fishing nets composed of nylon fibres were selected due to their potential as a sustainable and cost-effective reinforcement material. TRC composite with A.R. Glass textile was used as a reference specimen and that with A.R. Glass textile and waste fishing net were considered for the flexural tests. The influence of different layers of textiles was also investigated. The epoxy coating was used to coat the waste fishing nets along with A.R. glass textile to develop a hybrid textile. Properties of TRC composites incorporated with uncoated nets were compared with the composites using coated nets in order to understand the effect of coating on the reinforcement. The efficiency of textiles as reinforcement was also analyzed in detail by determining the strength and ductility ratio. Investigating the flexural behaviour of TRC with epoxy-coated waste fishing nets aims to understand this innovative composite material’s mechanical properties and performance. [ABSTRACT FROM AUTHOR]

Published

2024

18. Silica-based geopolymers admixture of borosilicate waste glasses: A green material for gamma radiation shielding applications.

Author

Alomayrah, Norah, Alrowaili, Z.A., Arslan, Halil, Olarinoye, I.O., and Al-Buriahi, M.S.

Subjects

*GLASS waste, *GAMMA rays, *BOROSILICATES, *RADIATION shielding, *ATTENUATION coefficients, *KAOLIN

Abstract

The gamma shielding parameters of an admixture of waste borosilicate glass (BS) and geopolymer (GP) made from activated metakaolin are presented in the present study. The influence of the BS quantity on the density and different gamma shielding quantities is investigated over a wide gamma energy range. Four batches of the G-BS composite were prepared using the solid-state diffusion method, containing 0 (G), 10 % (G-10BS), 20 % (G-20BS), and 30 % (G-30BS) by weight of BS, respectively. The chemical compositions of the G-xBS samples were determined through X-ray fluorescence spectrometry. In addition, the density of the BS-doped geopolymers was determined using the liquid displacement method using deionized water as the displacement fluid. The theoretical determination of estimating shielding parameters began by estimating the mass (μ ρ) and linear (μ) attenuation coefficients of the geopolymers for photon energies in the range of 15 keV to 15 MeV using the XCOM data library. The B and Si content and density of the geopolymer samples increased as the BS weight proportion increased in the geopolymer. The values of the attenuation coefficients (ACs) decreased with energy. For μ, the decrease was from 9.1533 to 0.0355 cm−1, 6.7486 to 0.0374 cm−1, 10.2964 to 0.0396 cm−1, and 10.7722 to 0.0414 cm−1, while for μ ρ , it was 5.3217 to 0.0206 cm2 g-1, 5.3860 to 0.0206 cm2 g-1, 5.3627 to 0.0206 cm2 g-1, and 5.3594 to 0.0206 cm2 g-1, for G, G-10BS, G-20BS, and G-30BS, respectively. There are no significant differences between the photon energy absorption capacity of the geopolymers, especially at energies greater than 1 MeV. The photon buildup factors of the G-xBS samples have very close relative values with no clear order. The introduction of waste borosilicate glass is therefore a way of improving the photon attenuation capacity of geopolymer and, therefore, the potential of shielding applications of geopolymer-based concrete. [ABSTRACT FROM AUTHOR]

Published

2024

19. Investigating the potential of waste glass in paver block production using RSM.

Author

Naik, Bhukya Govardhan, Nakkeeran, G., Roy, Dipankar, and Alaneme, George Uwadiegwu

Subjects

*ULTRASONIC testing, *MINERAL aggregates, *WASTE minimization, *GLASS waste, *ECOLOGICAL impact

Abstract

The global surge in glass waste generation, exceeding 130 million tons annually, presents a pressing environmental issue, compounded by inadequate recycling practices, it is concerning that the global recycling rate for glass waste is below 50%. This research investigates the utilization of WG as a FA substitute in paver block to mitigate the ecological footprint of conventional paver block while enhancing its mechanical properties. WG's unique characteristics, such as high silica content and impermeability, make it a promising alternative. A comprehensive experimental approach, including tests like water absorption, dry density, workability, compressive strength, ultrasonic pulse velocity, and rebound hammer, demonstrated WG's potential to improve concrete's durability and performance. For instance, a 40% WGA replacement reduced the absorption rate 12%, while 20% WGA incorporation-maintained strength properties close to the control mix, with compressive strengths up to 30.80 MPa at 28 days. Employing RSM as predictive models, the study showed R2 values of 0.9513, 0.9983, 0.9156, 0.9925, and 0.9895 for water absorption, dry density, compressive strength, ultrasonic pulse velocity, and rebound hammer, respectively. This study offers supporting global research efforts to advance sustainable and affordable construction materials, leading to a significant reduction in landfill waste and the conservation of precious natural resources worldwide. [ABSTRACT FROM AUTHOR]

Published

2024

20. Predictive models for treated clayey soils using waste powdered glass and expanded polystyrene beads using regression analysis and artificial neural network.

Author

Akis, E. and Cigdem, O. Y.

Subjects

*ARTIFICIAL neural networks, *GLASS waste, *WASTE products, *POWDERED glass, *CLAY soils

Abstract

Waste materials contribute to a wide range of environmental and economic problems. To minimize their effects, a safe strategy for reducing such negative impact is required. Recycling and reusing waste materials have proved to be effective measures in this respect. In this study, an eco-friendly treatment is investigated based on using waste powdered glass (WGP) and EPS beads (EPSb) as mechanical and chemical admixers in soils. For this purpose, Atterberg limit, standard proctor, free swell, and unconfined compression tests are performed on soil samples with different ratios of waste materials at their optimum moisture contents. The obtained test results indicate that adding WGP to cohesive soils increases the unconfined compressive strength (UCS) and reduces free swell (FS). In contrast, using EPSb reduces both FS and UCS of the treated soil samples. An optimum combination of both waste materials is determined for the improvement of the properties of high plasticity clay used in this study. Furthermore, multiple linear regression (MLR) and artificial neural network (ANN) methods are used to predict the FS and UCS of the clayey soils based on the data obtained here and the experimental test results reported in the literature. Once the FS and UCS values of untreated soil and additive percentages are defined as independent variables, both methods are shown to predict the FS and UCS values of the treated soil samples on a satisfactory level with the coefficient of correlation ( R 2 ) values greater than 0.926. Additionally, when only the index properties (liquid limit, plastic limit, and plasticity index) of the soil samples with waste materials are used as dependent variables, the R 2 values obtained by the ANN method are 0.968 and 0.974 for FS and UCS, respectively. The results of the untreated soil samples' FS and UCS tests are known, and the linear regression and ANN techniques yield similar results. Lastly, the ANN method is used to predict the FS and UCS of the treated samples in accordance to the limited predictors (e.g., only the Atterberg limits of the soil sample). [ABSTRACT FROM AUTHOR]

Published

2024

21. Characterization of municipal solid waste in Kuwait: Sector-specific composition analysis and implications.

Author

Aleisa, Esra and Al-Jarallah, Rawa

Subjects

*WASTE paper, *WASTE minimization, *GLASS waste, *WASTE recycling, *WASTE management

Abstract

Municipal solid waste (MSW) characterization plays a pivotal role in devising effective waste management strategies conducive to fostering a circular economy. This study presents composition analysis across twenty-four subcategories sourced from residential, commercial, and industrial sectors in Kuwait. The study is conducted in accordance with the Standard Test Method for Determination of the Composition of Unprocessed Municipal Solid Waste (ASTM D5231). The results indicate that organic waste comprises 45.3%, followed by paper waste (19.9%) and plastics (19.8%). The remaining waste comprises glass waste (3.5%), diapers (2.7%), textiles (2.6%) and other waste. Paper waste (19.9%) consists mainly of mixed paper (12.1%), cardboard (3.7%), newspaper (3.3%), printer printouts (0.6%) and other office paper (0.2%). Plastic waste (19.8%) consists mainly of film (11.2%), PET (3.1%), HDPE (1.1%) and other mixed plastics (4.4%). Residential and mixed areas have the highest proportion of organic waste. Commercial areas produce the highest proportion of wastepaper (22.4%) and textiles (3.7%). Industrial areas produce the highest proportion of plastic waste (29.1%), most of which is film (17.3%). The study also provides an overview of the MSW management system in the country, an overview over the legislative framework, and forecasts of future waste generation rates with comparison to historical baselines. Implications: The precise and up-to-date characterization of municipal solid waste is imperative for scholarly journal submissions, as it establishes a foundational understanding of waste composition, aiding researchers and policymakers in the development of effective waste management strategies, resource recovery initiatives, and sustainable solutions to address the evolving challenges in waste management systems. This study provides detailed composition analysis for twenty-four municipal solid waste (MSW) subcategories collected across different sources: residential, commercial, industrial, and mixed areas. Time series forecasting is applied to predict MSW generation based on historical data obtained through the local municipality over the past decade. Factorial analysis is applied to investigate changes across source areas, and a hypothesis test is used to compare the current MSW composition against previous baselines. The results demonstrated significant variation across most waste categories. The plastic waste proportion has increased by 48.5% compared to 2013 data, despite awareness campaigns. Paper waste has also increased in proportion from 6.8% to 16.2%; this increase is associated with the mixed paper subcategory, which is mostly used for packaging. The composition data provided in this study are necessary for long-term monitoring, strategy assessment, and legislation associated with waste reduction and remediation. [ABSTRACT FROM AUTHOR]

Published

2024

22. A scientometric review of recycled glass waste as an alternative raw material in concrete production.

Author

Kuoribo, Ewald, Shokry, Hassan, Asawa, Takashi, and Mahmoud, Hatem

Subjects

*SUSTAINABILITY, *GLASS recycling, *WASTE recycling, *GLASS waste, *WASTE management

Abstract

The escalating use of glass in an ever-evolving world poses a waste management challenge, with glass waste contributing to non-biodegradable landfill growth. Recycling glass waste emerges as a viable solution, combating the need for additional landfills and the environmental repercussions. This study employs a scientometric and content analysis from the Scopus bibliometric database and explores the functional feasibility and performance characteristics of recycled glass waste (RGW) in sustainable concrete production. Results indicate that Asia dominates research contributions to RGW for concrete production compared to other continents. Glass-mixed concrete properties depend on glass type, particle size, shape, surface texture, replacement ratio, and curing age. The pozzolanic reactivity of recycled glass is correlated with its relative fineness. Finer glass particles were considered more suitable for use due to the enhanced alkali-silica interaction. Utilizing glass powder and fine aggregates improves mechanical properties, but high replacement levels could affect concrete strength development. Additionally, using RGA as a cement and fine aggregate replacement reduces concrete's thermal conductivity. This scientometric analysis not only aids in understanding a comprehensive overview of incorporating recycled glass waste into concrete production but also identifies knowledge gaps, guiding sustainable concrete research and development for addressing waste management challenges linked to the growing use of glass in our contemporary society. [ABSTRACT FROM AUTHOR]

Published

2024

23. Experimental Study on the Suitability of Waste Plastics and Glass as Partial Replacement of Fine Aggregate in Concrete Production.

Author

Legese, Alemu Mosisa, Mitiku, Degefe, Feyessa, Fekadu Fufa, Urgessa, Girum, and Boru, Yada Tesfaye

Subjects

CONCRETE products, PLASTIC scrap, TENSILE strength, GLASS waste

Abstract

Solid waste management is a major environmental challenge, especially in developing countries, with increasing amounts of waste glass (WG) and waste plastic (WP) not being recycled. In Ethiopia, managing WG and WP requires innovative recycling techniques. This study examines concrete properties with WG and WP as partial replacements for fine aggregate. Tests were conducted on cement setting time, workability, compressive strength, splitting tensile strength, and flexural strength. Concrete of grade C-25, with a target compressive strength of 25 MPa, was prepared by partially replacing fine aggregate with WP and WG. The mechanical properties were evaluated after 7 and 28 days of curing. At a 20% replacement level, workability decreased at water–cement ratios of 0.5 and 0.6 but remained stable at 0.4, leading to the selection of the 0.4 ratio for further testing. A 10% replacement of fine aggregate, using a ratio of 3% WP and 7% WG, was found to be optimal, resulting in an increase in compressive strength by 12.55% and 6.44% at 7 and 28 days, respectively. In contrast, a 20% replacement led to a decrease in compressive strength by 14.35% and 0.73% at 7 and 28 days, respectively. On the 28th day, the splitting tensile strength at the optimal replacement level was 4.3 MPa, reflecting an 8.5% reduction compared to the control mix. However, flexural strength improved significantly by 19.7%, from 12.46 MPa to 15.52 MPa. Overall, the incorporation of WG and WP in concrete enhances flexural strength but slightly reduces splitting tensile strength. [ABSTRACT FROM AUTHOR]

Published

2024

24. Studying microbially induced corrosion on glass using ToF-SIMS.

Author

Parker, Gabriel D., Plymale, Andrew, Hager, Jacqueline, Hanley, Luke, and Yu, Xiao-Ying

Subjects

SECONDARY ion mass spectrometry, MICROBIOLOGICALLY influenced corrosion, GLASS waste, ENVIRONMENTAL remediation, SPECTRAL imaging, DEPTH profiling, RADIOACTIVE waste disposal

Abstract

Microbially induced corrosion (MIC) is an emerging topic that has huge environmental impacts, such as long-term evaluation of microbial interactions with radioactive waste glass, environmental cleanup and disposal of radioactive material, and weathering effects of microbes. Time-of-flight secondary ion mass spectrometry (ToF-SIMS), a powerful mass spectral imaging technique with high surface sensitivity, mass resolution, and mass accuracy, can be used to study biofilm effects on different substrates. Understanding how to prepare biofilms on MIC susceptible substrates is critical for proper analysis via ToF-SIMS. We present here a step-by-step protocol for preparing bacterial biofilms for ToF-SIMS analysis, comparing three biofilm preparation techniques: no desalination, centrifugal spinning (CS), and water submersion (WS). Comparisons of two desalinating methods, CS and WS, show a decrease in the media peaks up to 99% using CS and 55% using WS, respectively. Proper desalination methods also can increase biological signals by over four times for fatty acids using WS, for example. ToF-SIMS spectral results show chemical compositional changes of the glass exposed in a Paenibacillus polymyxa SCE2 biofilm, indicating its capability to probe microbiologically induced corrosion of solid surfaces. This represents the proper desalination technique to use without significantly altering biofilm structure and substrate for ToF-SIMS analysis. ToF-SIMS spectral results showed chemical compositional changes of the glass exposed by a Paenibacillus bacterial biofilm over 3-month inoculation. Possible MIC products include various phosphate phase molecules not observed in any control samples with the highest percent increases when experimental samples were compared with biofilm control samples. [ABSTRACT FROM AUTHOR]

Published

2024

25. Use of Lignin, Waste Tire Rubber, and Waste Glass for Soil Stabilization.

Author

Gücek, Süleyman, Gürer, Cahit, Žlender, Bojan, Taciroğlu, Murat V., Korkmaz, Burak E., Gürkan, Kürşat, Bračko, Tamara, Macuh, Borut, Varga, Rok, and Jelušič, Primož

Subjects

RUBBER waste, GLASS waste, PAVEMENT design & construction, ROAD construction, POWDERED glass

Abstract

The complex interactions between soil and additives such as lignin, glass powder, and rubber tires were investigated using principles of material and soil mechanics. Previous research has mainly focused on individual additives in clay soils. In contrast, this study investigates soil improvement with two different types of waste materials simultaneously. The improvement of soil properties by hybrid waste materials was evaluated using several laboratory tests, including the standard Proctor test, the unconfined compressive strength test, the California Bearing Ratio (CBR) test, and cyclic triaxial tests. The aim of this research is to identify key parameters for the design and construction of road pavements and to demonstrate that improving the subgrade with hybrid waste materials contributes significantly to the sustainability of road construction. The mechanical and physical properties were evaluated in detail to determine the optimal mixtures. The results show that the most effective mixture for the combination of waste glass powder and rubber tires contains 20% glass powder and 3% rubber tires, based on the dry weight of the soil. For the combination of waste glass powder and lignin, the optimum mixture consists of 15% glass powder and 15% lignin, based on the dry weight of the soil. These results provide valuable insights into the sustainable use of waste materials for soil stabilization in road construction projects. [ABSTRACT FROM AUTHOR]

Published

2024

26. A Comparative Study of Machine Learning and Conventional Techniques in Predicting Compressive Strength of Concrete with Eggshell and Glass Powder Additives.

Author

Gao, Yan and Ma, Ruihan

Subjects

ARTIFICIAL neural networks, GLASS waste, POWDERED glass, RESPONSE surfaces (Statistics), WASTE products

Abstract

Recent research has focused on assessing the effectiveness of response surface methodology (RSM), a non-machine learning technique, and artificial neural networks (ANN), a machine learning approach, for predicting concrete performance. This research aims to predict and simulate the compressive strength of concrete that replaces cement and fine aggregate with waste materials such as eggshell powder (ESP) and waste glass powder (WGP) for sustainable construction materials. In order to ensure concrete's durability and structural integrity, a compressive strength evaluation is essential. Precise predictions maximize efficiency and advance sustainability, particularly when dealing with waste materials like ESP and WGP. The response surface methodology (RSM) and artificial neural network (ANN) techniques are used to accomplish this for practical applications in the built environment. A dataset comprising previously published research was used to assess ANN and RSM's predictive and generalization abilities. To model and improve the model, ANN used seven independent variables, while three variables, cement, waste glass powder, and eggshell powder, improved the RSM. Both the ANN and RSM techniques are effective instruments for predicting compressive strength, according to the statistical results, which include mean squared error (MSE), determination coefficient (R2), and adjusted coefficient (R2 adj). RSM was able to achieve the R2 by 0.8729 and 0.7532 for compressive strength, while the accuracy of the results for ANN was 0.907 and 0.956 for compressive strength. Moreover, the correlation between ANN and RSM models and experimental data is high. The artificial neural network model, however, exhibits superior accuracy. [ABSTRACT FROM AUTHOR]

Published

2024

27. Glass Waste as a Valuable Additive (Raw Material) Used for Cement Mortars.

Author

Ogrodnik, Paweł, Rutkowska, Gabriela, Chyliński, Filip, Żółtowski, Mariusz, Koda, Eugeniusz, and Sivasuriyan, Arvindan

Subjects

GLASS waste, MORTAR admixtures, COMPRESSIVE strength, BENDING strength, CEMENT admixtures, MORTAR

Abstract

The main objective of this study was to determine the impact of glass waste as a valuable additive in cement mortars. As part of this study, three mortars with different glass waste contents were designed with the addition of 10, 20, and 30% glass waste, as well as a reference mortar without the additive. The selected characteristics of the mixtures were determined, including the consistency, density, air content, and strength properties of the mortar. Strength tests (bending and compressive strength) were performed after 28 and 56 days of maturation. Mortars with the lowest waste content (MC10%) achieved flexural strength of 26% and compressive strength of 18% compared to the average value of standard mortar, whereas MC20% mortars showed a decrease in bending strength of 30% and compressive strength of 24%. Studies have also been conducted to determine the parameters of air trapped in the mortar microstructure and its possible impact on mortar durability in a freezing/thawing environment. A group of experimental studies involved microstructure studies aimed at assessing the changes that occur in mortars containing glass waste. The negative effects of glass waste on the compressive and bending strengths and the positive effect at low temperatures were clearly demonstrated. [ABSTRACT FROM AUTHOR]

Published

2024

28. Optimizing Concrete Strength and Sustainability by Using Blast Furnace Slag and Waste Glass Powder as Additives.

Author

Das, Amar Kumar, Mangaraj, Abhijit, Behera, Rojalin, and Behera, Smrutiranjan

Subjects

INDUSTRIAL wastes, GLASS waste, BASIC oxygen furnaces, WASTE recycling, FLEXURAL strength

Abstract

Construction industry intends to promote effective utilization of waste materials obtained from various sources to develop an eco‐friendly building material for high performance, life cycle sustainability, and reduction of carbon footprints globally. The current study focusses to produce concrete mix by using industrial wastes such as ground granulated blast furnace slag (BOF) and glass powder (GP). Samples are prepared by utilizing industrial wastes partially for M35 grade concrete. The ground granulated BOF and GP are used with 10%–40% and 0.1%–0.4%, respectively, as the partial replacement of cement. Under different curing periods, the specimens were characterized for their physical and mechanical properties. Test results were analyzed to check the workability, compressive strength, flexural strength, and water absorption of the sample mixes prepared. The highest compressive and flexural strength of the samples are found to be 46.23 MPa and 5.13 MPa, at the optimal replacement of BOF and GP in the proportion of 30% and 0.2%, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

29. Preparation of porous plate from municipal solid waste incineration fly ash and its application in a biofilm batch reactor.

Author

Wang, Jing, Liu, Han, Sun, Chang‐Jung, and Fang, Weicheng

Subjects

INCINERATION, SEWAGE purification, GLASS waste, WASTE products, SOLID waste, FLY ash

Abstract

The reutilization of municipal solid waste incineration (MSWI) fly ash is a prominent area of research. This study focused on creating fly ash porous plate filler (FAPPF) by using techniques, such as water extraction, milling, component adjustment, and sintering. The produced FAPPF was then used to cultivate a biofilm for wastewater treatment. The key parameters included a two‐stage water extraction process with a 5:1 liquid‐to‐solid ratio; milling for 1, 2, and 4 h; component adjustment using waste glass powder, milled fly ash, palygorskite powder, and peanut shell powder at a 7:1:1:1 mass ratio; and sintering temperatures ranging from 700 to 1000°C. For the biofilm cultivation and treatment, this study employed semisimulated sewage in a sequencing biofilm batch reactor system. The results revealed the FAPPF had no heavy metal leaching, with a porosity of 48.53%–54.68%. Approximately 90% of its composition was derived from waste materials. Furthermore, scanning electron microscopy microanalysis revealed an internally stable liquid‐phase sintering structure. Finally, a mature biofilm developed in 21 days, achieving maximum removal rates of 95.48% for chemical oxygen demand and 78.4% for ammonia nitrogen. This article confirms the sustainable recycling potential of MSWI fly ash. [ABSTRACT FROM AUTHOR]

Published

2024

30. EVALUATION OF THE PERFORMANCE OF SUSTAINABLE MODIFIED POLYMER CONCRETE MADE FROM VARIOUS WASTE MATERIALS.

Author

Mahdi, Zeinab Raad, Hasan, Shatha Sadiq, Hamoodi, Mustafa Naem, and Fattah, Mohammed Yousif

Subjects

MINERAL aggregates, POLYMER-impregnated concrete, RECYCLED concrete aggregates, GLASS waste, GLASS recycling

Abstract

Due to its superior performance over traditional materials, polymer concrete has emerged as a new engineering material in the current context. The main focus of this study was the design and manufacture of polyester polymer concrete (PC) from various recycled materials for use in various building applications. Four different types of recycled aggregate from easily accessible crushed building materials were employed: waste glass (WG), crushed mortar (CM), crushed clay bricks (CB), and crushed concrete (CC). Sustainable modified polymer concrete (SMPC) specimens were made using a conventional casting method and various replacements for normal sand, such as crushed concrete, mortar, clay bricks, and waste glass (10, 20, 30, and 40 volume percent). The mechanical properties of SMPC with and without recycled aggregate were tested for compressive, tensile, and flexural strength. The findings showed that adding (10%, 20%, 30%, and 40%) of (CC, CM, CB, and WG) as a partial substitute for natural fine aggregate improves the mechanical properties (compressive strength, direct tensile strength, and flexural strength) of SMPC. In comparison to other waste materials, the results of using crushed concrete were the best and highest. Similar to reference PC and SMPC with recycled fine aggregate, the rate of strength evolution with age is roughly the same. This research also looked into how the curing temperature affected the SMPC's compressive strength characteristics. The 20, 40, and 60 °C curing temperature ranges were taken into consideration. The findings demonstrate that the compressive strength of PC, both with and without recycled fine aggregate, is significantly impacted by a curing temperature above 20 °C. [ABSTRACT FROM AUTHOR]

Published

2024

31. Sustainable aerated concrete: Influence of fine glass powder with fly ash and superplasticizer as partial replacement for cement.

Author

Swathy, A. S., Vighnesh, T. S., Athira, P. S., Dinachandran, Nandu, and James, Anu

Subjects

*ALUMINUM powder, *GLASS waste, *FLY ash, *INSULATING materials, *CONCRETE mixing, *AIR-entrained concrete, *POWDERED glass

Abstract

Aerated concrete is a light weight building material with effective insulating and durability properties, thus offering a wide range of options for improving the quality of construction with a reduction in cost. Aerated concrete due to its inherent properties is the best viable option for construction projects which necessitates quick installation and low maintenance, such as precast members. The purpose of this study is to examine the effectiveness of adding glass powder to aerated concrete. Addition of glass powder improves the mechanical properties of aerated concrete, enhances its durability and reduces the environmental impact of normal concrete. Massive volume of glass waste is generated annually, which can be effectively utilized as a construction material owing to the pozzolanic property. The experimental investigation conducted comprises of preparing aerated concrete mixes and assessing the combined influence of cement, fly ash, glass powder, aluminium powder and superplasticizer and evaluating their optimal quantitites and strength development. The results suggest that glass powder is a promising additive for aerated concrete, with potential applications in the construction industry. [ABSTRACT FROM AUTHOR]

Published

2024

32. Effect of waste glass powder on mechanical performance of hot mix asphalt.

Author

Al-Amiri, Yousif and Al-Zerjawi, Ahlam

Subjects

*GLASS waste, *FILLER materials, *ASPHALT pavements, *MINERAL aggregates, *POWDERED glass, *ASPHALT

Abstract

To reduce construction materials cost, the search for waste materials that harm the environment to reuse them optimally reduces the consumption of raw materials and withdraws large quantities of waste generated from domestic and industrial activities, in addition to energy subsidies. Among these wastes especially non-biodegradable solid waste is waste glass. Interestingly, when glass is crushed into sand-like particle sizes, it exhibits aggregated physical properties like natural sand. For this reason, the idea of using crushed glass waste as an alternative to natural aggregate in asphalt mixture when constructing asphalt pavement emerged. This research primarily aims to investigate the possibility of waste disposal by using Waste Glass Powder (WGP) material in HMA mixture. In addition to the influence of adding WGP material on the performance of HMA mixture. To achieve the aim of this research, many important goals and objectives were conducted, which can be summarised as using Marshall method to determine Optimum Asphalt Content (OAC) of Reference Hot Mix Asphalt (RHMA) and Optimum Glass Content (OGC) of Glassy Hot Mix Asphalt (GHMA). Finally, the RHMA and GHMA mixtures were prepared to study the property variation with the optimum percentage of materials in HMA mixture. To investigate the comparative performance of the two types of HMA mixtures, some tests were performed, including Marshall Method Test (MMT), Indirect Tensile Strength (ITS) test, Tensile Strength Ratio (TSR) test, and Oxidative Ageing Test (OAT). The results showed that OAC for RHMA mixture was 5.2% of the total weight of HMA mixture and OGC for GHMA mixture was 15% by weight of the filler material. The volumetric and mechanical properties of modified mixture are improved compared to RHMA mixture; as Mixture Bulk Density (MBD) increased, Air Voids in Total Mixture (VTM) decreased, Voids in Mineral Aggregate (VMA) decreased, Voids Filled with Asphalt (VFA) increased, Marshall Stability (MS) increased, Marshall Flow (MF) decreased, and Marshall Quotient Stiffness (MQS) increased. The sensitivity of thermal cracking, moisture damage, and oxidative ageing also decreased. Also, it was noted from the results that waste glass reusing in asphalt pavement using WGP material in HMA mixture with mixing ratios of 15% by weight of filler material is possible. It also leads to improved performance of asphalt pavement. [ABSTRACT FROM AUTHOR]

Published

2024

33. Determine components of clam shells and glass bottles as the base material for glass ceramics using x-ray fluorescence.

Author

Harkiah, Sasa and Rauf, Nurlaela

Subjects

*X-ray fluorescence, *CERAMIC materials, *GLASS waste, *BALL mills, *CERAMICS, *GLASS-ceramics, *GLASS bottles

Abstract

The waste clam-shells of the species 'Meretrix Lyrata' and waste glass bottles were used as basic materials to produce glass ceramics. The glass ceramics consisted of 70 wt.% clam shell and 30 wt.% glass bottles mixed homogeneously using ball milling. Clam shells and glass bottles were characterized by X-Ray Fluorescence to determine its compound. The XRF showed the clam shells contain 94.45% of CaO, and become 99.48% of CaO after calcination at 900 oC for 2 hours, while the glass bottle contain 80.28% of SiO2 Its promise material for glass ceramics with better mechanical, structural and physical properties. [ABSTRACT FROM AUTHOR]

Published

2024

34. Waste not, cement stronger: Utilizing ceramic and glass waste as additives for improved well casing cementing.

Author

Suhascaryo, K. R. T. Nur, Subiatmono, P., Ilcham, Adi, Zuhaira, Intan, and Prisillia, P. Frisca

Subjects

*GLASS waste, *SHEAR strength, *FUSED silica, *BOND strengths, *COMPRESSIVE strength

Abstract

This research aimed to investigate the effectiveness of waste additives, namely ceramic and glass waste, in increasing the strength of well casing cementing. The compressive strength and shear bond strength of cement samples with silica additives were measured to determine the most effective concentration of additives. The research found that ceramic silica additives and glass additives with a concentration of 35% BWOC yielded the greatest compressive strength and shear bond strength. However, the addition of these additives increased the thickening time of the cement, causing it to dry longer. The implication of this research is that waste additives can be utilized as an alternative to increase the quality of cementing in the oil and gas industry. [ABSTRACT FROM AUTHOR]

Published

2024

35. Current development of waste glass as building construction materials.

Author

Rahmawati, Cut, Zardi, Muhammad, Anggi, Hidayah Rizka Laysa, Akhramurizqi, and Nasruddin

Subjects

*GLASS waste, *GLASS construction, *BUILDING design & construction, *SILICA sand, *MORTAR, *CONSTRUCTION materials, *SPECIFIC gravity

Abstract

Waste of Glass (WGs) is generally sent to landfills even though they are recyclable and essential as a non-biodegradable resource. It should be transformed into new valuable materials such as sand, a building material commonly used in mortar and concrete manufacture, to reduce its disposal in landfills. This study aims to review the use of Waste of Glass sand (WGs) as building construction materials. The result shows that WGs could partially substitute sand due to its beneficial pozzolanic properties. WGs below 20% can replace part of the cement and positively impact mechanical strength. In contrast, substitutes higher than 20% can cause a negative impact because the remaining amount of CaCO3 is not enough to react to produce C-S-H gel. Utilizing WGs as a replacement for fine sand with more than 20% leads to adverse effects. This issue is due to the specific gravity of the glass below the particular gravity of fine natural sand. WGs have partially replaced cement and fine sand at specific proportions. This innovation can be valuable in building construction materials and protecting the environment simultaneously. [ABSTRACT FROM AUTHOR]

Published

2024

36. An investigation on road construction by adding recycled waste with Bitumen.

Author

Chinnusamy, Senthilkumar, Nasiya, K. B., Kumar, R. Deepak, and Thomas, P. Jestin

Subjects

*WASTE recycling, *ROAD construction, *PLASTIC scrap, *WASTE products as building materials, *GLASS waste

Abstract

Industrialization and population increase produce a variety of solid wastes, which is why they are typically thrown away carelessly. Environmental contamination caused by these activities has negative impacts and may be dangerous for the ecosystem. In addition, several researchers have worked must make sure part of these wastes are recycled and used to make other alternative materials as a type of sustainable technology. in an effort to protect the environment. Some of these wastes are regarded as some of the best building substitutes. The feasibility and challenges of utilising various recycled waste materials in building are examined in this study. Small number of the recycled garbage products that are researched include waste glass, Ind. tailings, GPMS, and plastic trash. [ABSTRACT FROM AUTHOR]

Published

2024

37. Fragmentary cement with fly ash and glass fibre reinforcement concrete's strength.

Author

Kalam, Abdul Hameed Abdul, Yeswanth, M., and Kalaiyarasan, G.

Subjects

*GLASS fibers, *FLY ash, *POWDERED glass, *GREENHOUSE gases, *GLASS waste, *CONSTRUCTION materials, *CONCRETE

Abstract

One of the most widely utilised building materials in the modern world is concrete. Cement is an essential part of concrete. Environmental concerns, in addition to deforestation and the combustion of fossil fuels, are very important in today's society. For instance, a large amount of the greenhouse gas carbon dioxide, which accounts for 7% of the emissions of greenhouse gases into the atmosphere of the earth, is released during the manufacture of cement, a crucial component of concrete. It can be difficult to safely dispose of the glass waste that is produced in daily life because it has a short lifespan and is typically either stored or discarded after use. Solving the environmental issue brought on by industrial waste is now of great significance on a global scale. Recent research has shown that waste glass, when utilised in the proper fraction and grade, can be successfully used in concrete as a number of substitutes for the constituents of concrete. Due to its high SiO2 content, When made into a very fine powder, discarded glass demonstrates pozzolanic qualities. As a result, it can partially substitute cement in concrete and contribute to the development of strength. In this study, the effect of adding glass fibres in various volume fractions with 20%, 30%, and 40% fly ash substitution of cement was examined, along with its effects on compressive strength and split tensile strength in comparison to conventional concrete. Overall test results indicate that glass fibre can be used in concrete. According to the research, concrete reaches its maximum strength at 20% glass particles. After 20% glass fibre is added, concrete loses strength and weakens compared to the control. The impact of adding various volume percentages of glass fibres (20%, 30%, and 40%) is investigated in this study. Regarding the concrete's split tensile and compressive strength, the impact of cement substitution was examined. According to the overall test outcome, glass fibre might be used in concrete. The outcome suggests that concrete's maximal strength occurs at a glass powder content of about 20%. Concrete's strength decreases and falls below that of the control at a level of 20% glass fibre [ABSTRACT FROM AUTHOR]

Published

2024

38. Effect of the addition of TiB2 with waste glass powder on microstructure, mechanical and physical behavior of PET-based polymer composite material.

Author

Dwivedi, Shashi Prakash, Sharma, Shubham, Krishna, B. Vijay, Sonia, Pankaj, Saxena, Kuldeep Kumar, Iqbal, Amjad, and Djavanroodi, Faramarz

Subjects

*GLASS waste, *POLYETHYLENE terephthalate, *TITANIUM diboride, *MICROSTRUCTURE, *WETTING

Abstract

In present study, titanium diboride (TiB2) and glass powder waste utilized as reinforcement particles with Polyethylene terephthalate (PET) matrix material in development of a polymer-based composite. The % reinforcement of TiB2and glass powder waste varied from 2.5% to 20%. Micrographs of PET/8.75% TiB2/8.75% glass wastecomposite revealed uniform distribution of TiB2and glass powder in PET-based MMC. Proper wettability between matrix and reinforcement particles were observed for PET/8.75% TiB2/8.75% glass wastecomposite. Results showed that by adding 8.75% of TiB2and 8.75% of glass powder, mechanical properties of PET were improved. [ABSTRACT FROM AUTHOR]

Published

2024

39. Compositional effects on the growth of diopside crystals in the simulated high‐level waste glass.

Author

Jia, Ruidong, Niu, Chenchen, Liu, Xuelian, Xu, Kai, and Tan, Shengheng

Subjects

*RARE earth oxides, *GLASS waste, *ALKALINE earth metals, *CRYSTAL growth, *LIQUID waste

Abstract

Borosilicate glasses are the primary waste forms for the industrial immobilization of high‐level liquid waste. Yet, the compositional variation of waste glasses can form the diopside phase, which can be detrimental to the melting process and the properties of the final glass products. This study prepared simulated waste glasses with variable contents of alkaline earth metals, boron, transition metals, and rare earth metal oxide and subjected them to heat treatments. The effect of the compositional variation on the diopside crystallization behavior was explored using differential scanning calorimetry, X‐ray diffraction, optical microscopy, and scanning electron microscopy‐energy dispersive spectroscopy. The results revealed that the average size of diopside crystals was proportional to the square root of the heat treatment durations. Increased contents of alkaline earth and transition metal oxides could contribute to the growth of diopside crystals, while boron oxide tended to inhibit it. Finally, a prediction model correlating the average crystal size, compositional variation, and heat treatment durations was discussed. [ABSTRACT FROM AUTHOR]

Published

2024

40. Geometrical and chemical effects of water diffusion in silicate gels: Molecular dynamics and random walk simulations.

Author

Hatori, Takuma, Matsubara, Ryuta, Inagaki, Yaohiro, Ishida, Keisuke, and Ohkubo, Takahiro

Subjects

*GLASS waste, *RADIOACTIVE wastes, *RANDOM walks, *MOLECULAR dynamics, *PORE water

Abstract

Understanding mass transport in the alteration layers of glass surfaces is a crucial component of the safety assessment of nuclear waste glass. In this work, we model such an alteration layer as a silicate gel with water through a molecular dynamics (MD) simulation with a reactive force field. Gels with various water contents (WCs) ranging from 5.1 to 30.7wt%$30.7 \,{\rm wt}\%$ are produced via high‐temperature annealing with water and silica. It is found that an increase in the water content destroys the polymerized structure of the silicate network and promotes the formation of silanol groups. The pore size and water connectivity formed by the silicate networks are investigated for the modeled gels. Gel with a WC of 5.7wt%$5.7 \,{\rm wt}\%$ is composed of isolated water in the pores; in contrast, pores filled with interconnected water are formed in gel with a WC of 30.7wt%$30.7 \,{\rm wt}\%$. The water diffusivity in the modeled gel is calculated using the mean‐squared displacement at various temperatures. An attempt is made to formulate a linear relationship between the water diffusivity and porosity derived from the MD simulation. The porosity is calculated using a probe atom with a radius, which was optimized from a linear relationship between the water diffusivity and porosity. This approach successfully explains the water diffusivity in terms of the porosity. Random walk (RW) simulations for the structures derived from the MD simulations are performed to determine the geometrical effects of the pores. The diffusivity obtained from RW simulation is compared with the results of the MD simulations, which include chemical interactions such as the formation and breakage of hydrogen bonds. This comparison highlights how geometrical effects and chemical interactions contribute to water diffusivity depending on the WC. [ABSTRACT FROM AUTHOR]

Published

2024

41. Concrete's fire resistance improvement with waste glass and ceramic aggregates.

Author

Al-jamaily, Naghm Mahdi Saidik, Atiea, Huda M., Jabal, Qusay A., Mahdi, Waseem H., and Alasadi, Laith Abdulrasool

Subjects

GLASS waste, CONCRETE waste, FIRE exposure, WASTE products, MODULUS of elasticity

Abstract

Even though concrete structures are safer than steel structures in terms of fire resistance, the risk exists in concrete structures by spalling or exploding, especially in high-strength concrete. This study aims to produce a particular type of concrete using waste ceramics as fine aggregate and waste glass as coarse aggregate and compare data with normal aggregate concrete. Studies show that using waste ceramic and glass increases the fire resistance of concrete. After fire exposure in the control mix, the residual compressive strength was 10 MPa. The waste aggregate concrete was found to be 26.9 MPa after 800 centigrade exposures, which was an excellent result. Waste materials decreased construction costs and led to a clean environment. [ABSTRACT FROM AUTHOR]

Published

2024

42. High performance building ceramics based on solid waste

Author

Dmitry A. Nemuschenko, Vladimir V. Larichkin, Mihail T. Murav’ev, and Maksim A. Neustroev

Subjects

construction ceramics, coal power plants, ash and slag waste, recycling, glass waste, Environmental sciences, GE1-350

Abstract

The most important environmental problem of coal energy in Russia is the accumulation of solid waste in ash dumps - products of coal combustion. Ash dumps are located on the lands of populated areas and are source of toxic dust, contamination of surface and groundwater with soluble compounds and increased radioactivity. An effective solution to the problem of accumulation of ash and slag waste is its use as secondary raw materials in the construction industry. In this work, physicochemical methods were used to study ash and slag raw materials from coal-fired power plants in Novosibirsk and municipal cullet. Recipes for building ceramics have been developed by varying the content of fly ash and cullet, molding technologies, and modes of drying and firing of products. The influence of various methods of preparing raw materials (grinding, fractionation, ignition, mechanical activation) and methods of processing and dispersing ceramic masses on the physical and mechanical properties of experimental samples was studied. The possibility of obtaining ceramic products that meet the requirements of regulatory documents for construction materials is shown.

Published

2024

43. Investigation of Conditions for Using Mass-Produced Waste Glass as Sustainable Fine Aggregate for Mortar.

Author

Son, Minjae, Kim, Gyuyong, Lee, Sangkyu, Kim, Hongseop, Eu, Hamin, Lee, Yaechan, Sasui, Sasui, and Nam, Jeongsoo

Subjects

GLASS waste, PARTICULATE matter, FLEXURAL strength, MORTAR, COMPRESSIVE strength, MICROCRACKS

Abstract

To address the environmental issues arising from the growing scarcity of natural fine aggregates (NFA) and landfilling of waste glass, research is being conducted globally to utilize waste glass as a sustainable fine aggregate. However, contradictory results have been obtained regarding the effect of the type of waste glass and the physical properties of waste glass fine aggregate (GFA) on concrete, making it challenging to promote the use of GFA in concrete. Therefore, to promote the use of GFA in concrete, it is necessary to examine it under field conditions, such as mass-production processes or real-scale concrete applications. This study introduced a mass-production process for GFA, and the effect of mass-produced GFA on mortar was evaluated. The fine aggregate properties (particle aspect ratio, crushing rate, and solubility) of the GFA and the effects of color, content, and particle size on the mortar properties (compressive strength, flexural strength, and ASR expansion behavior) were analyzed, along with the results reported in previous studies. Consequently, the high aspect ratio and microcracks in the particles of mass-produced GFA led to an increase in the strength reduction and ASR expansion of the mortar. These effects appear to be particularly severe for transparent GFA. Overall, this study proposed the content of GFA within 20% or the replacement of fine particles (< 500 μm) in NFA as a condition for sustainable fine aggregate. [ABSTRACT FROM AUTHOR]

Published

2024

44. Study on fresh and hardened state properties of eco-friendly foamed concrete incorporating waste soda-lime glass.

Author

Mydin, Md Azree Othuman, Jagadesh, P., Bahrami, Alireza, Majeed, Samadar S., Dulaimi, Anmar, and Omar, Roshartini

Subjects

*GLASS, *GLASS waste, *POROSITY, *CONCRETE waste, *GLASS bottles

Abstract

Improper waste management is causing global environmental problems. Waste glass may have adverse impacts on the ecosystem. While a substantial amount of soda-lime glass bottle (SGB) undergoes recycling to create new glass items, a significant volume still ends up in landfills. Therefore, the aim of this study was to explore the potential use of SGB in foamed concrete (FC) production as an aggregate replacement. SGB was substituted for sand in different weight fractions, ranging from 5 to 50%. The fresh state, mechanical, thermal, pore structure, and transport properties were examined. The findings showed a significant enhancement in the FC's mechanical properties when SGB replaced 20% of sand. The compressive, flexural, and splitting tensile strengths exhibited a rise of up to 17.7, 39.4, and 43.8%, respectively. The findings also demonstrated that the addition of SGB improved the thermal conductivity, sorptivity, water absorption, and porosity. The scanning electron microscopy analysis indicated that the inclusion of 20% SGB caused a substantial decrease in void diameter and enhanced its uniformity. A comparison was made between the experimental data and predictions of the mechanical properties using various models of international standards, such as IS 456, ACI 318, NZS-3101, EC-02, AS 3600, and CEB-FIB, along with several references in the literature. The findings implied a strong correlation between the strength properties. The outcomes of this research offer valuable insights into both the possible advantages and constraints of using SGB in FC. Furthermore, this extensive laboratory investigation may serve as a guideline for future study and aid in the advancement of greener and more environmentally friendly FC alternatives. [ABSTRACT FROM AUTHOR]

Published

2024

45. Analysis of the thermal insulation performance of cement with waste glass powder in geothermal well.

Author

Ji, Ying, Song, Li, Sha, Qianqian, Zhu, Gang, Xue, Yuze, Zhang, Tinghui, and Fan, Shuai

Subjects

*GLASS waste, *POWDERED glass, *GEOTHERMAL wells, *THERMAL conductivity, *COMPRESSIVE strength, *THERMAL insulation

Abstract

To improve the heat extraction efficiency from the wellbore fluids to the stratum in the geothermal well, thermal insulation cement, which contains of waste glass powder as a heat-insulating material, is proposed to apply in geothermal well's middle and upper sections in the paper. Effect of such glass powers on mechanic and thermal property of thermal insulation cement was then investigated. Various tests were carried out to measure compressive strength, thermal conductivity, microstructure porosity etc. parameters of the thermal insulation cement. Results showed that the waste glass powder would enhance its the compressive strength and improve its the thermal insulation performance. Correlation study between contents of the added waste glass powder in geothermal cements and its mechanic and thermal property was conducted. It was found that thermal insulation cement exhibited its optimum performance when the added content of glass powers was 20% in weight. Analysis of the microstructure porosity with SEM found that the pores in thermal insulation cement with added waste glass powders were mostly closed, tiny and even, and therefore contributed to the compressive strength of the thermal insulation cement; such pores would be also beneficial to improving its thermal insulation performance. [ABSTRACT FROM AUTHOR]

Published

2024

46. Fabrication of a Concrete Roof Tile by Geopolymerization of Red Clay with Container Glass Wastes.

Author

Bulaybulay, Keith T., Orpeza, Jessel Grace L., and Menchavez, Ruben L.

Subjects

*GLASS waste, *LIGHTWEIGHT materials, *GLASS containers, *CONCRETE, *TILES, *CONSTRUCTION materials, *POLYMER-impregnated concrete

Abstract

We report the production of concrete roof tiles using a red clay-based geopolymer binder with container glass waste and river sand as a concrete filler. Clear and colored container glass wastes were separately ground to powder and blended with low-grade red clay to achieve a SiO2/Al2O3 ratio of approximately 7.0. The powder blends were converted to geopastes with a solid-to-alkali solution ratio of approximately 0.8 using a 12-molar alkali activator solution containing a mixture of potassium hydroxide and sodium hydroxide. Rheological analysis showed that the geopaste binders with transparent and colored glass powders exhibited high shear thinning behavior. A higher viscosity was observed for the geopaste with colored glass powder due to the presence of colorants. Fine and coarse particles of river sand were prepared and mixed with different ratios of geopaste binder to river sand of 1:2.0, 1:2.5, and 1:3.0, respectively. All geopaste and river sand formulations were poured into acetate molds and heated in a metal chamber at 80 °C for 24 h, then aged at room temperature for 14 d. The highest flexural strength of 2.33 MPa was obtained from the formulation with a 1:2 ratio of geopaste with transparent glass powder and fine sand. The measured strength corresponded to an apparent porosity of 6.30% and a water absorption of 4.50%. The bulk density was approximately 1.16 g/cm³, which is classified as a lightweight material. A prototype geopolymer concrete roof tile was successfully produced with a sorption coefficient of approximately 0.170 mm/min1/2. This measured sorption coefficient and the physical properties indicate that the produced roof tile is a potential building material. [ABSTRACT FROM AUTHOR]

Published

2024

47. Properties of Adhesive Mortars Using Waste Glass.

Author

Kotsay, Galyna and Szewczenko, Wiktor

Subjects

*GLASS waste, *WASTE minimization, *GLASS construction, *RECYCLABLE material, *SOLUBLE glass

Abstract

This study investigates the use of waste glass as an active aggregate in glass polymers based on water glass, aiming to enhance the sustainability of construction materials by utilizing recyclable waste. Methodologically, the research employs a combination of water glass as a binder with waste glass, analyzing their chemical interaction and the resulting mechanical properties. The primary findings reveal that the inclusion of finely ground waste glass not only promotes the polycondensation and hardening processes of water glass but also significantly influences the adhesive and cohesive strengths of the developed glass polymers. After 7 days of hardening, the tensile strength of these materials exceeds that of standard concrete with values reaching up to 4.11 MPa, indicating strong adhesion capabilities that could pull out fragments of the concrete substrate. Conclusively, the study underscores the potential of waste glass in improving the structural and economic efficiencies of building materials, contributing to a reduction in landfill waste and offering a promising avenue for the innovative use of recyclable materials in construction. [ABSTRACT FROM AUTHOR]

Published

2024

48. Alkali activation-induced cold consolidation of waste glass: Application in organic-free direct ink writing of photocatalytic dye destructors.

Author

Mahmoud, Mokhtar, Kraxner, Jozef, Mehta, Akansha, Elsayed, Hamada, Galusek, Dušan, and Bernardo, Enrico

Subjects

*GLASS waste, *SUSTAINABILITY, *GLASS fibers, *ALKALIES, *METHYLENE blue

Abstract

Additive manufacturing, with its ability to assemble a variety of materials in complex and customized architectures, is developing rapidly. The integration of technologies and materials into a sustainable production, however, is still challenging. The present investigation offers new functional glass-based products, from nearly room temperature processing, based on direct ink writing (DIW) of pastes from 'light' alkali activation (2.5 M NaOH) of pharmaceutical glass waste, added with 20 wt% of TiO 2 nanoparticles. The inks were refined by the inclusion of porous glass microspheres (PGMs, 20–30 wt%), previously fabricated from fiber glass waste. Printed scaffolds, stabilized by simple drying (i.e. 'unfired'), were successfully applied in the photodegradation of methylene blue. The degradation efficiency reached 100% within 75 min, and the 3D-printed composites could be easily separated from the solution for subsequent reuse. The degradation efficiency declined only by 7.5%, after 5 cycles. [ABSTRACT FROM AUTHOR]

Published

2024

49. Alkali-activated waste glass as an alternative cement for preparation of potential low-carbon concrete.

Author

Zhu, Weiping, Wu, Xianpeng, Pan, Zezhou, Deng, Xuhua, Zheng, Chumao, Qiu, Zhenye, Wang, Daochu, Ling, Zao, Li, Lijuan, Liu, Feng, and Xiong, Zhe

Subjects

*GLASS waste, *CALCIUM silicate hydrate, *WASTE recycling, *SILICA sand, *SAND, *CONCRETE curing

Abstract

The environment is currently confronted with challenges arising from the substantial accumulation of challenging-to-recycle waste glass. To address this issue, the utilization of alkali-activated waste glass (AAWG) emerges as a promising solution for generating potential low-carbon materials. AAWG, serving as a novel binder, is characterized by a lack of Al/Ca, diverging from both geopolymer and calcium silicate hydrate gels. Consequently, variations in gel properties necessitate corresponding adjustments in AAWG preparation methods. However, to date, there has been limited comprehensive exploration by researchers into the effects of curing conditions (humidity, temperature, and duration) on the compressive strengths of AAWG. The interaction among these factors in influencing AAWG compressive strengths remains unclear. Furthermore, the feasibility of employing AAWG as a standalone binder in concrete, along with the performance of the interfacial transition zone around the aggregates, remains uncertain. Considering these unresolved issues, this study investigates the impact of curing conditions (humidity, temperature, and time) on AAWG compressive strengths. Concrete incorporating AAWG as the binder, granite as coarse aggregates, quartz sand as fine aggregates, and silica sand/flour as inert fillers exhibited compressive strengths surpassing 75 MPa. This research contributes to advancing the upcycling of waste glass to produce high-strength concrete. [ABSTRACT FROM AUTHOR]

Published

2024

50. Characteristics of composite briquettes produced from carbonized banana peels and waste glass.

Author

Nyakoojo, Emmanuel Karakwita, Wakatuntu, Joel, Jasper, Eseru, Yiga, Vianney Andrew, Kasedde, Hillary, and Lubwama, Michael

Subjects

GLASS waste, POWDERED glass, GLASS composites, AGRICULTURAL wastes, THERMAL efficiency

Abstract

Briquettes made from carbonized agricultural residues present sustainable material alternatives to wood charcoal and firewood for commercial and industrial applications. However, these briquettes are plagued by property weaknesses including low drop strength and thermal efficiency. Therefore, this study focuses on enhancing the physical, mechanical and thermal properties of composite briquettes produced from carbonized banana peels and waste glass. Composite briquettes comprised of banana peels biochar and waste glass powder (0%, 5%, 10%, 20%, 30%, 40%, and 50%) were developed, characterized, and evaluated using thermo-gravimetric analysis and bomb calorimetry to determine thermo-physical properties and higher heating values, respectively. The thermal efficiency and emissions (CO, CO2, and PM2.5) were assessed using the water boiling test and an emissions monitoring system. Proximate analysis revealed that moisture content, volatile matter, fixed carbon, and ash content of the developed briquettes ranged from 2.5 to 9.7%, 19.2 to 37.2%, 28.7 to 55.6%, and 7.2 to 44.9%, respectively. Drop strength for the briquettes was 84% without waste glass in the composite, increasing to 94–98% with waste glass included in the composite matrix. Higher heating values ranged from 20.1 to 35.8 MJ/kg. Thermal efficiency rose from 22% with no waste glass powder to 40% with 50% waste glass powder addition, while CO and CO2 emissions decreased from 41 to 11 ppm; and 50 to 15 ppm, respectively. PM2.5 remained constant across all banana peel biochar waste glass composites. Notably, even a modest 10% waste glass composition significantly improved drop strength and thermal efficiency, but higher waste glass percentages correlated with elevated ash values and reduced higher heating values. Therefore, the developed composite briquettes can be used in commercial and industrial applications including in some industrial boilers. [ABSTRACT FROM AUTHOR]

Published

2024