INTENSIVE WAYS OF PRODUCING CARBONATE CURING BUILDING MATERIALS BASED ON LIME SECONDARY RAW MATERIALS
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Abstract
Abstract: the article is dedicated to the research and development of intensive methods for curing products by capturing and binding CO2. It aims to improve and increase the productivity of technologies for the production of artificially carbonated building materials and products. Soda production wastes, limestone dust and finely dispersed limestone dust were used as the research objects. Secondary raw materials have been investigated using modern methods of phase composition and granulometry test. Intensive methods of production of accelerated carbonation of systems consisting of soda wastes were tested using multi-parameter optimization methods. The effects of recycled lime materials on the strength and hydrophysical properties of the obtained material were determined. The secondary raw materials effect depended on the composition of the raw mixture, molding conditions, CO2 concentration applied to the carbonate curing chamber, and the duration of exposure to environments with high CO2 content. It was found that the most effective way of providing accelerated carbonation curing of construction materials and products is a combined carbonation method, combining the principles of dynamic and static methods. It was concluded that the optimal CO2 concentration in the gas-air mixtures used for carbonate curing is 30%–40%.
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References
Gartner E. Industrially interesting approaches to “low-CO2” cements // Cement and Concrete Research. – 2004. – Volume 34, Issue 9. – Pр. 1489-1498. DOI:
Karen L. Scrivener, Vanderley M. John, Ellis M. Gartner. Eco-efficient cements: Potential economically viable solutions for a low-CO2 cement-based materials industry // Cement and Concrete Research. – 2018. – Vol. 114. – Pp. 2-26.
Li C., Nie Z., Cui S., Gong X., Wang Z., Meng X. The life cycle inventory study of cement manufacture in China // Journal of Cleaner Production. – 2014. – Volume 72 (1). – Pр. 204-211.
Shi C., Jimenez A.F., Palomo A. New cements for the 21st century: the pursuit of an alternative to Portland cement // Cement and Concrete Research. – 2011. – Volume 41(7). – Pр. 750-763.
Mote C., Dowling J., Zhou J. The power of an idea: the international impacts of the grand challenges for engineering // Engineering. – 2016. – Volume 2. – Pр. 4-7.
Barcelo, L., Kline, J., Walenta, G. et al. // Cement and carbon emissions. Mater Struct. – 2014. – 47. 1055-1065.
U.S. Patent No. 9,868,667, «Bonding Element, Bonding Matrix and Composite Material Having the Bonding Element and Method of Manufacturing Thereof».
Amoureux J., Siffert P., Massue J.P., Cavadias S., Trujillo B., Hashimoto K., Rutberg P., Dresvin S., Wang X. Carbon dioxide: a new material for energy storage // Progress in Natural Science: Materials International. – 2014. – Volume 24. – Pр. 295-304.
Yootaek Kim and Kyongwoo Lee. Mechanical properties of non-cement mortars fabricated under supercritical carbonation conditions without alkali activators and composed of fly ash and fused waste slag // Materials Today: Proceedings. – 2016. – Volume 3. – Pр. 381-390.
Damyanti Badagha, Modhera C.D., Grade M. Concrete using industrial waste to minimize cement content incorporating CO2 emission concept: an experimental investigation // Materials Today: Proceedings. – 2017. – Volume 4. – Pр. 9768-9772.
Humbert P. S., Castro-Gomes J. P., Savastano H. Clinker-free CO2 cured steel slag based binder: Optimal conditions and potential applications. Construction and Building Materials. – 2019. – Volume 210. – Pp. 413-421.
Ghouleh Z., Guthrie R., Shao Y. High-strength KOBM steel slag binder activated by carbonation // Construction and Building Materials. – 2015. – Volume 99. – Pp. 175-183.
Huang H., Wang T., Kolosz B., Andresen J. and etc. Life-cycle assessment of emerging CO2 mineral carbonation-cured concrete blocks: Comparative analysis of CO2 reduction potential and optimization of environmental impacts // Journal of Cleaner Production. – 2019. – Volume 241. – Article 118359.
Ghouleh Z., Guthrie R., Shao Y. Production of carbonate aggregates using steel slag and carbon dioxide for carbon-negative concrete // Journal of CO2 Utilization. – 2017. – Volume 18. – Pp. 125-138.
Lyubomirskiy N., Bakhtin A., Bakhtina T. Physicochemical principles of CO2 sequestration in building materials based on nepheline slime // IOP Conf. Series: Materials Science and Engineering (MSE). – 2018. – Volume 463. – Article 032065.
Bakhtina T., Lyubomirskiy N., Bakhtin A. Dolomite binding materials with low CO2 emission // Materials Today: Proceedings. – 2019. – Volume 19. – No 5. – Pp. 1998-2004.
Bikbulatov I.Kh., Nasyrov R.R., Daminov R.R., Voronin A.Yu. Method of utilization of the main waste of soda ash production // Electronic scientific journal Oil and gas business. – 2 (2007). – Pp. 1-16.
Kurbangaleev M.H., Khasanova A.A., Yanbekov L.F. The use of solid solid waste soda production as a raw material for commercial products // Сollected papers Сities of russia: problems of construction, engineering, landscaping and ecology. – 2015. – Pр. 59-62.
Dzhandullaeva M., Adilova М., Aliyeva Z., Kholmukhamatova F. The use of carbonate waste soda production as a raw material in the production of silicate bricks // Universum: Technical Sciences. – 2018. – Volume 12. – Pр. 77-80.
Lyubomirskiy N.V., Nikolaenko V.V., Nikolaenko E.Y. Changes in the physicomechanical properties of materials of carbonate hardening on the basis of lime and lime stone systems with the course of time // Materials Today: Proceedings. – 2019. – Volume 19. – No 5. – Pp. 1917-1921.
Lyubomirskiy N., Fic S., Fedorkin S. Investigation of Physical and Mechanical Properties of Construction Materials of Forced Carbonate Hardening // Materials Science Forum. – 2018 – Volume 931 – Pp. 475-480.
Lyubomirskiy N., Bakhtina T., Bakhtin A., Fedorkin S. The carbonate hardening lime construction material properties formation during their long-term storage and use under normal conditions // Materials Science Forum. – 2019. – Volume 974. – Pp. 187-194.
Ukraine Patent 28051, «Device for studying the carbonation process», N. Lyubomirskiy, S. Fedorkin, T. Loktionova (Bakhtina), А. Bakhtin.
Lyubomirskiy N.V., Fedorkin S.I., Bakhtin A.S., Bakhtina T.A. Structuring of composite systems based on lime harden through carbonation and secondary limestone raw materials // Malaysian Construction Research Journal (MCRJ). – 2017. – Volume 23. – No 3 – Pp. 15-26.
Nalimov V.V., Chernova N.A. Statistical methods of planning extreme experiments. – Moscow: Nauka. – 1965. – 340 p.
Ermakov S.M., Jigkyavskiy A.A. The mathematical theory of optimal experiment. – Moscow: Nauka. – 1987. – 318 p.
Cizer О., K. Van Balen, J. Elsen, D. Van Gemert. Crystal morphology of precipitated calcite crystals from accelerated carbonation of lime binders. In Proceedings of the 2nd International Conference on Accelerated Carbonation for Environmental and Materials Engineering, 1–3 October 2008, Rome, Italy. – Pр. 149–158.
De Silva P., Bucea L., Moorehead D.R., Sirivivatnanon V. Carbonate binders: Reaction kinetics, strength and microstructure // Cement & Concrete Composites. – 2006. – No. 28 – Pp. 613–620.
Van Balen K. Carbonation reaction of lime, kinetics at ambient temperature // Cement & Concrete Research. – 2005. – Volume 35, Issue 4 – Pр. 647-657.
Duygu Ergenç, Rafael Fort Accelerating carbonation in lime-based mortar in high CO2 environments // Construction and Building Materials. – 2018. – Volume 188. – Pp. 314-325.
Liwu Mo, Feng Zhang, Daman K. Panesar, Min Deng Development of low-carbon cementitious materials via carbonating Portland cement–fly ash–magnesia blends under various curing scenarios: a comparative study // Journal of Cleaner Production – 2017. – Volume 163. – Pp. 252-261.
Shamsad Ahmad et al. Effects of carbonation pressure and duration on strength evolution of concrete subjected to accelerated carbonation curing // Construction and Building Materials. – 2017. – Volume 136. – Pp. 565-573.
A. Moropoulou et al. Strength development and lime reaction in mortars for repairing historic masonries // Cement and Concrete Composites. – 2005. – Vol. 27. Issue 2. – P.p. 289-294.
Tiefeng Chen, Xiaojian Gao. Effect of carbonation curing regime on strength and microstructure of Portland cement paste // Journal of CO2 Utilization. – 2019. – Volume 34. – Pp. 74-86.
Pedro S. Humbert, João Castro-Gomes. CO2 activated steel slag-based materials: A review // Journal of Cleaner Production. – 2019. – Volume 208. – Pp. 448-457.
Liwu Mo, Feng Zhang, Min Deng. Mechanical performance and microstructure of the calcium carbonate binders produced by carbonating steel slag paste under CO2 curing // Cement and Concrete Research. – 2016. – Volume 88. – Pр. 217-226.
Liu Qian, Liu Jiaxiang, Qi Liqian. Effects of temperature and carbonation curing on the mechanical properties of steel slag-cement binding materials // Construction and Building Materials. – 2016. – Volume 124. – Pp. 999-1006.
Tao Wang et al. Accelerated mineral carbonation curing of cement paste for CO2 sequestration and enhanced properties of blended calcium silicate // Chemical Engineering Journal. – 2017. – Volume 323. – P.p. 320-329.
Özlem Cizer, Koen Van Balen, Jan Elsen, Dionys Van Gemert Real-time investigation of reaction rate and mineral phase modifications of lime carbonation / Construction and Building Materials. – 2012. – Volume 35 – Pp. 741-751.
Robert M. Lawrence et al. Effects of carbonation on the pore structure of non-hydraulic lime mortars // Cement and Concrete Research. – 2007. – Volume 37. Issue 7. – Pр. 1059-1069.
T.A. Plekhanova, J. Keriene, A. Gailius, G.I. Yakovlev. Structural, physical and mechanical properties of modified wood–magnesia composite – Construction and Building Materials. – 2007. – Volume 21. Issue 9. – Pр. 1833-1838.
L.Pu, C. Unluer. Investigation of carbonation depth and its influence on the performance and microstructure of MgO cement and PC mixes // Construction and Building Materials. – 2016. – Volume 120. – Pр. 349-363.