Analysis of Mechanical and Environmental Effects of Utilizing Waste Glass for the Creation of Sustainable Ultra-High Performance Concrete

Typically, waste glass industry contributes to various harmful environmental impacts. Glass manufacturing relies on considerably extreme temperature values. 22 million tons in Europe and 95 million tons of carbon dioxide are generated globally per annum. Meantime, scholars noted that million tons of...

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Main Authors: Ismaeel A.M., Usman F., Hayder G., Al-Ani Y.
Other Authors: 58313095100
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Published: International Information and Engineering Technology Association 2024
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spelling my.uniten.dspace-343092024-10-14T11:18:58Z Analysis of Mechanical and Environmental Effects of Utilizing Waste Glass for the Creation of Sustainable Ultra-High Performance Concrete Ismaeel A.M. Usman F. Hayder G. Al-Ani Y. 58313095100 55812540000 56239664100 55337314700 construction environmental impact mechanical properties pollution Ultra-High Performance Concrete waste glass Typically, waste glass industry contributes to various harmful environmental impacts. Glass manufacturing relies on considerably extreme temperature values. 22 million tons in Europe and 95 million tons of carbon dioxide are generated globally per annum. Meantime, scholars noted that million tons of waste glass produced worldwide yearly could cause elevated levels of water and air pollution due to the accumulation of waste glass in landfills. In this setting, researchers dedicated numerous efforts to create feasible strategies and active solutions to alleviate all these significant numbers. One of those solutions is the waste glass recycling. It is reported that recycling waste glass provides efficient air pollution and water contamination mitigation by roughly 20% and 50%, respectively. One sector that took into account this valuable idea is the concrete industry. Scientists discovered that substituting specific ratios of cement/ sand with waste glass (including 0%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, and 90%) in concrete could achieve substantial added values in terms of mechanical properties, such as better durability, abrasion resistance, flexural strength, compressive strength, and splitting tensile strength. Few, at the same time, found that adding waste glass into concrete could reduce facilities� cooling and heating loads due to the decline in the concrete�s thermal conductivity. Nonetheless, the available literature lacks adequate proofs associated with this fact. Additionally, different peer-reviewed articles did not address the application of this concept on Ultra-High Performance Concrete (UHPC) but on regular concrete. To bridge this knowledge gap, this manuscript is guided to provide more databases on the influence of cement/ sand replacement with waste glass on concrete�s thermal characteristics yet paying special attention on UHPC. A comprehensive review is implemented in this context to shed light on these aspects. Based on the thorough review carried out in this article, the outcomes revealed that employing waste glass in concrete and UHPC could attain multiple advantages, like (i) Enhancing variant UHPC and concrete�s mechanical properties (containing split tensile strength, compressive strength, compaction, durability, flexural strength, bulk density, and shrinkage resistance), (ii) fostering thermal conductivity and thermal resistance, helping make the building of this new concrete mix more energy efficient, (iii) minimizing glass industry�s adverse environmental effect, (iii) preserving natural resources, and (iv) reducing the overall budget of UHPC production. However, it is crucial to conduct further experimental and numerical analyses on waste glass replacement with concrete to offer more pieces of evidences and facts of the importance of waste glass replacement in boosting UHPC thermal performance in small and large-scale facilities. � 2023 Lavoisier. All rights reserved. Final 2024-10-14T03:18:58Z 2024-10-14T03:18:58Z 2023 Article 10.18280/acsm.470208 2-s2.0-85161899874 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85161899874&doi=10.18280%2facsm.470208&partnerID=40&md5=40fc6d67067a804c11ada524001076b2 https://irepository.uniten.edu.my/handle/123456789/34309 47 2 111 123 All Open Access Bronze Open Access International Information and Engineering Technology Association Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic construction
environmental impact
mechanical properties
pollution
Ultra-High Performance Concrete
waste glass
spellingShingle construction
environmental impact
mechanical properties
pollution
Ultra-High Performance Concrete
waste glass
Ismaeel A.M.
Usman F.
Hayder G.
Al-Ani Y.
Analysis of Mechanical and Environmental Effects of Utilizing Waste Glass for the Creation of Sustainable Ultra-High Performance Concrete
description Typically, waste glass industry contributes to various harmful environmental impacts. Glass manufacturing relies on considerably extreme temperature values. 22 million tons in Europe and 95 million tons of carbon dioxide are generated globally per annum. Meantime, scholars noted that million tons of waste glass produced worldwide yearly could cause elevated levels of water and air pollution due to the accumulation of waste glass in landfills. In this setting, researchers dedicated numerous efforts to create feasible strategies and active solutions to alleviate all these significant numbers. One of those solutions is the waste glass recycling. It is reported that recycling waste glass provides efficient air pollution and water contamination mitigation by roughly 20% and 50%, respectively. One sector that took into account this valuable idea is the concrete industry. Scientists discovered that substituting specific ratios of cement/ sand with waste glass (including 0%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, and 90%) in concrete could achieve substantial added values in terms of mechanical properties, such as better durability, abrasion resistance, flexural strength, compressive strength, and splitting tensile strength. Few, at the same time, found that adding waste glass into concrete could reduce facilities� cooling and heating loads due to the decline in the concrete�s thermal conductivity. Nonetheless, the available literature lacks adequate proofs associated with this fact. Additionally, different peer-reviewed articles did not address the application of this concept on Ultra-High Performance Concrete (UHPC) but on regular concrete. To bridge this knowledge gap, this manuscript is guided to provide more databases on the influence of cement/ sand replacement with waste glass on concrete�s thermal characteristics yet paying special attention on UHPC. A comprehensive review is implemented in this context to shed light on these aspects. Based on the thorough review carried out in this article, the outcomes revealed that employing waste glass in concrete and UHPC could attain multiple advantages, like (i) Enhancing variant UHPC and concrete�s mechanical properties (containing split tensile strength, compressive strength, compaction, durability, flexural strength, bulk density, and shrinkage resistance), (ii) fostering thermal conductivity and thermal resistance, helping make the building of this new concrete mix more energy efficient, (iii) minimizing glass industry�s adverse environmental effect, (iii) preserving natural resources, and (iv) reducing the overall budget of UHPC production. However, it is crucial to conduct further experimental and numerical analyses on waste glass replacement with concrete to offer more pieces of evidences and facts of the importance of waste glass replacement in boosting UHPC thermal performance in small and large-scale facilities. � 2023 Lavoisier. All rights reserved.
author2 58313095100
author_facet 58313095100
Ismaeel A.M.
Usman F.
Hayder G.
Al-Ani Y.
format Article
author Ismaeel A.M.
Usman F.
Hayder G.
Al-Ani Y.
author_sort Ismaeel A.M.
title Analysis of Mechanical and Environmental Effects of Utilizing Waste Glass for the Creation of Sustainable Ultra-High Performance Concrete
title_short Analysis of Mechanical and Environmental Effects of Utilizing Waste Glass for the Creation of Sustainable Ultra-High Performance Concrete
title_full Analysis of Mechanical and Environmental Effects of Utilizing Waste Glass for the Creation of Sustainable Ultra-High Performance Concrete
title_fullStr Analysis of Mechanical and Environmental Effects of Utilizing Waste Glass for the Creation of Sustainable Ultra-High Performance Concrete
title_full_unstemmed Analysis of Mechanical and Environmental Effects of Utilizing Waste Glass for the Creation of Sustainable Ultra-High Performance Concrete
title_sort analysis of mechanical and environmental effects of utilizing waste glass for the creation of sustainable ultra-high performance concrete
publisher International Information and Engineering Technology Association
publishDate 2024
_version_ 1814060089054593024
score 13.214268