Concrete Technology and Sustainably Development from Past to Future
Keywords:
Sustainability development, environment, issue, economic issue, social issue, concrete, cement production, Pozzolanic material, recycling west material
Abstract
A large number of concrete production today has a bad effect on environment resource and energy. Thus this issue of concrete technologies have an impact on the environment which is a critical problem in global warming. The current paper reviews the concrete technology and sustainable development from past to future and investigates sustainable concrete and material practice. Although while comparing these factors with the past, current and future prospective concrete sustainability development, this research found that the main cause of global warming is emission during concrete and cement production. The solution of environment problem is not to replace the concrete by other substances and it can reduce the amount of cement with cementitious materials. The best approach for reducing the amount of in environments is using Pozzolanic material and waste material, which both plays a vital role in the sustainable concrete structure.
References
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[37] Sakai K. Sustainability in fib Model Code 2010 and its future perspective. Structural Concrete. 2013 Dec; 14(4):301-8.
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[2] Mulder KF. Strategic competences for concrete action towards sustainability: An oxymoron? Engineering education for a sustainable future. Renew Sustain Energy Rev. 2016 Mar 25:1-6.
[3] Bjork, F. "Concrete Technology and Sustainable Development." CANMET/ACI International Symposium on Concrete Technology for Sustainable Development. 1999.
[4] Cheung, M., and S. Foo. "Technology Real Property Services Branch Public Works and Government Services Canada." Use of Fly Ash in Concrete: proposed PWGSC Guidelines, CAN MEET International Symposium on Concrete Technology for Sustainable Development. 1999.
[5] Bueckert, D., Canadian Press AThe World Braces for 6 Billion@, Vancouver Sun, September 24, 1999.
[6] Juenger MC. sustainable Low CO2 cement concrete. Routledge Handbook of Sustainable and Resilient Infrastructure. 2018 Dec 17:377.
[7] Gjorv O, Sakai K. Concrete technology for a sustainable development in the 21st century. CRC Press; 2014 Apr 21.
[8] Sim, Jongsung, Minkwan Ju, and Kihong Lee. "Thirty Years Researches on Development for Sustainable Concrete Technology." In MATEC Web of Conferences, vol. 138, p. 03008. EDP Sciences, 2017.
[9] Sakai K, Noguchi T. The sustainable use of concrete. CRC press; 2012 Jul 26.
[10] Swamy RN. Designing concrete and concrete structures for sustainable development. In Sustainable Development of the Cement and Concrete Industry. Proceedings of CANMET/ACI International Symposium, Ottawa, Canada 1998 Oct 21 (pp. 245-255).
[11]Jahren P, Sui T. Concrete and sustainability. CRC Press; 2013 Jul 16.
[12] Jonsung S, Lee KH. Sustainable Concrete Technology. Civil Engineering Dimension. 2015 Dec 18; 17(3):158-65.
[13] Kulkarni V.R. Concrete Sustainability: Current Status in India and Crucial Issues for the Future. Presented at Concrete Sustainability through Innovative Materials and Techniques, Roving National Seminars, Bangalore, and January 10–14, 2011.
[14] Mehta, P.K, AAdvancements in Concrete Technology@, Concrete International, June 1999, pp.69-76.
[15] Mehta, P.K., “Bringing the Concrete Industry into a New Era of Sustainable Development,” Proceedings of the Mario Collepardi Symposium on Advances in Concrete Technology, pp. 49–68, 1997.
[16] Malhotra VM, Mehta PK. Pozzolanic and Cementitious Materials, Gordon and Breach Publishers, SA, 1996, 191 pp. Coarse aggregate.;1225(1225):1225.
[17] Swamy RN. Design for durability and strength through the use of fly ash and slag in concrete. Special Publication. 1997 Aug 1; 171:1-72.
[18] Al-Mana AB, Haneef M, Maslehuddin M. Effect of cement replacement, content, and type on the durability performance of fly ash concrete in the Middle East. Cement, Concrete and Aggregates. 1986 Jan 1; 8(2):86-96.
[19] Swamy RN. Designing concrete and concrete structures for sustainable development. In Sustainable Development of the Cement and Concrete Industry. Proceedings of CANMET/ACI International Symposium, Ottawa, Canada 1998 Oct 21 (pp. 245-255).
[20] Mukherjee SP, Vesmawala G. Literature review on technical aspect of sustainable concrete. International Journal of Engineering Science Invention. 2013 Aug; 2(8):1-9.
[21] Altwair NM, Kabir S. Green concrete structures by replacing cement with pozzolanic materials to reduce greenhouse gas emissions for sustainable environment. InProceedings of 6th International Engineering and Construction Conference (IECC’6), Cairo, Egypt 2010 Jun 28 (pp. 28-30).
[22] Meyer C. The greening of the concrete industry. Cement and concrete composites. 2009 Sep 1; 31(8):601-5.
[23] Ismail MS, Waliuddin AM. Effect of rice husk ash on high strength concrete. Construction and building materials. 1996 Oct 1; 10(7):521-6.
[24] Owaid HM, Hamid RB, Taha MR. A review of sustainable supplementary cementitious materials as an alternative to all-Portland cement mortar and concrete. Australian Journal of Basic and Applied Sciences. 2012 Sep; 6(9):287-303.
[25] Brito J, Silva R. Use of waste materials in the production of concrete. InKey Engineering Materials 2015 (Vol. 634, pp. 85-96). Trans Tech Publications.
[26] Martins P, Brito JD, Rosa A, Pedro D. Mechanical performance of concrete with incorporation of coarse waste from the marble industry. Materials Research. 2014 Oct; 17(5):1093-101.
[27]André A, de Brito J, Rosa A, Pedro D. Durability performance of concrete incorporating coarse aggregates from marble industry waste. Journal of Cleaner Production. 2014 Feb 15; 65:389-96.
[28] D. Silva, F. Gameiro, J. de Brito, Mechanical properties of structural concrete containing fine aggregates from waste generated by the marble quarrying industry, J. Mater. Civ. Eng. dx.doi.org/1061/ (ASCE) MT.1943, (2014).
[29]Gameiro F, De Brito J, da Silva DC. Durability performance of structural concrete containing fine aggregates from waste generated by marble quarrying industry. Engineering Structures. 2014 Feb 1; 59:654-62.
[30] Valadares F, Bravo M, de Brito J. Concrete with used tire rubber aggregates: Mechanical performance. ACI Materials Journal-American Concrete Institute. 2012 May 1; 109(3):283.
[31] Bravo M, de Brito J. Concrete made with used tyre aggregate: durability-related performance. Journal of Cleaner Production. 2012 Apr 1; 25:42-50.
[32] Correia JR, Marques AM, Pereira CM, De Brito J. Fire reaction properties of concrete made with recycled rubber aggregate. Fire and Materials. 2012 Mar; 36(2):139-52.
[33] Marques AM, Correia JR, De Brito J. Post-fire residual mechanical properties of concrete made with recycled rubber aggregate. Fire Safety Journal. 2013 May 1; 58:49-57.
[34] Serpa D, de Brito J, Pontes J. Concrete made with recycled glass aggregates: Mechanical performance. ACI Mater. J. [accepted for publication]. 2015 Jan 1.
[35] de Castro S, de Brito J. Evaluation of the durability of concrete made with crushed glass aggregates. Journal of Cleaner Production. 2013 Feb 1; 41:7-14.
[36] Babafemi A, Šavija B, Paul S, Anggraini V. Engineering Properties of Concrete with Waste Recycled Plastic: A Review. Sustainability. 2018 Oct 25; 10(11):3875.
[37] Sakai K. Sustainability in fib Model Code 2010 and its future perspective. Structural Concrete. 2013 Dec; 14(4):301-8.
[38] Sobotka T, Skirbekk V, Philipov D. Economic recession and fertility in the developed world. Population and development review. 2011 Jun; 37(2):267-306.
[39] Henry M, Kato Y. Perspectives on sustainable practice and materials in the Japanese concrete industry. Journal of Materials in Civil Engineering. 2011 Sep 16; 24(3):275-88.
[40] Isaia G, Gastaldini A. Concreto “verde” com teores muito elevados de adições minerais: um estudo de sustentabilidade. InI Conferência Latino-Americana de Construção Sustentável X Encontro Nacional de Tecnologia do Ambiente construído, São Paulo, SP. Anais... CD-ROM 2004 Jul.
[41] Khokhar MI, Rozière E, Turcry P, Grondin F, Loukili A. Mix design of concrete with high content of mineral additions: Optimisation to improve early age strength. Cement and Concrete Composites. 2010 May 1; 32(5):377-85.
[42] Joseph P, Tretsiakova-McNally S. Sustainable non-metallic building materials. Sustainability. 2010 Feb; 2(2):400-27.
Published
2019-05-01
How to Cite
Hafizyar, R., & Hunar Dheyaaldin, M. (2019, May 1). Concrete Technology and Sustainably Development from Past to Future. Sustainable Structures and Materials, An International Journal, 2(1), 1-13. https://doi.org/https://doi.org/10.26392/SSM.2019.02.01.001
Section
SSMIJ (Regular Issues)
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