Scholarly record
LOW CARBON BINDERS WITH ASH MICROSPHERE
Abstract
Construction technologies are among the most critical in terms of negative impact on the environment. Burnt binders, primarily cement and air-lime, emit significant volumes of carbon dioxide and man-made heat. At the same time, a large amount of hydrocarbon fuel is also consumed for their firing. Therefore, to achieve sustainable development goals, the development of alternative binder formulations or innovative ways to produce traditional binders with low carbon emissions is necessary. The synthesis of low-carbon binder compositions that provide the required properties is based on the use of mineral or organomineral compositions with the use of highly dispersed fillers or modifiers. Technogenic resources are used as such fillers, including those extracted by the fuel industry - REA-gypsum, fly ash, bottom ash and their individual components. Recently, interest in aluminosilicate microspheres has been growing. They are isolated from ash and slag waste from coal power plants. When they are removed hydraulically, the calcium content in the waste decreases due to its fairly high solubility. The paper presents the results of a study of the physical and mechanical properties of cementless compositions for additive technologies based on aluminosilicate microspheres. Microspheres have a number of unique properties. The synergistic effect is achieved by combining a self-reinforced matrix, which ensures the stability of the mixture during the process of stone formation with a rapid increase in strength with the participation of microspheres, necessary when using compositions in additive technologies.
Publication Impact Profile
- Citations
- Scopus - Citation Indexes: 1
- Captures
- Mendeley - Readers: 3
Publication details
References14
Mustafin N.Sh., Baryshnikov A.A., The progressive technology in construction. 3D printer, Regional development, Russia, vol. 1, pp. 6, 2016;
Vatin N.I., Chumakova L.I., Goncharov I.S., Zykova V.V., Karpine A.N., Kim A.A., Finashenkov E.A., 3D Printing in construction, Construction of unique buildings and structures, Russia, vol. 1(52), pp. 27-46, 2017;
Mukhametrakhimov R.H., Vakhitov I.M., Additive technology for the construction of buildings and structures using a construction 3D printer, KGASU News, Russia, vol. 4(42), pp. 350�359, 2017;
Petropavlovskaya V.B., Artamonova S.V., Shchipanskaya E.O., Ratkevich E.A., Petropavlovskii K.S., Environmental management in ash and slag waste management in Russia, International scientific and practical conference �Ensuring sustainable development: agriculture, ecology and earth science� (AEES 2021), pp. 012135, 2022; DOI: 10.1088/1755-1315/1010/1/012135
Petropavlovskaya V.B., Novichenkova T.B., Mikaelyan Kh.A., Petropavlovskii K.S., Ash cement compositions, Vestnik of Tver State Technical University. Series �Building. Electrical engineering and chemical technology�, Russia, vol. 2 (18), pp. 12-21. 2023;
Gasainiev R.M., Archakov A.T., Balaev A.Z., Ragimov Sh.N.,Kurbaliev M.R., Features of manufacturing technology using a 3D printer, Innovations and investments, Russia, pp. 238-241, 2018;
Mukhametrakhimov R., Lukmanova L., Structure and properties of mortar printed on a 3D printer, Magazine of Civil Engineering, vol. 102, Iss. 2, ��. 10206, 2021;
Lao W., Li M., Tjahjowidodo T., Variable-geometry nozzle for surface quality enhancement in 3D concrete printing, Addit Manuf. Elsevier, vol. 37, ��. 101638, 2021. DOI: 10.1016/J.ADDMA.2020.101638;
Buswell R.A., Leal de Silva W.R., Jones S.Z., Dirrenberger J. 3D printing using concrete extrusion: A roadmap for research, Cem. Concr. Res., vol. 112, pp. 37-49, 2018; DOI: 10.1016/j.cemconres.2018.05.006
Shatalova S.V., Chernysheva N.V., Elistratkin M.Yu., Drebezgova M.Yu., Masalitina S.V., Rheological properties of gypsum cement binders and molding mixtures based on them for 3d additive construction technologies, Building materials, Russia, vol. 8, pp. 23-30, 2022. DOI: 10.31659/0585-430X-2022-805-8-23-30;
Chen Y., Chaves Figueiredo S., Li Z., Chang Z., Jansen K., Copuroglu O., Schlangen E., Improving printability of limestone-calcined clay-based cementitious materials by using viscosity-modifying admixture, Cem. Concr. Res. Elsevier Ltd., vol. 132, pp. 106040, 2020; DOI: 10.1016/j.cemconres.2020.106040
Mukhametrakhimov R.H., Ziganshina L.V., Types of concrete and mortar defects in additive manufacturing technology, Proceedings of the Kazan State University of Architecture and Civil Engineering, Russia, vol. 1(67), pp. 107-116, 2024. DOI: 10.48612/NewsKSUAE/67.11.
Korolev E.V., Zyong T.K., Inozemcev A.S., Method for providing internal hydration care for cement in 3D printing compositions, Vestnik MGSU, Russia, vol. 15. Iss. 6, pp. 834-846, 2020. DOI: 10.22227/1997-0935.2020.6.834-846;
Udodov S.A., Belov F.A., Zolotukhina A.E., Update of the dry construction mixture for 3d-printing by the method of mathematica, European scientific conference: Collection of materials of the V International Scientific and Practical Conference, Russia, Part 1, pp. 132�138, 2017;
Citing literature
Number of times cited according to Crossref: 1
View or Download full articleAccess options
SWS access login
Login as SWS Scientific CommitteeLogin as SWS Scientific PartnerLogin as SWS AuthorAuthors and approved SWS contributors will read and export their own linked papers after identity matching by SWS profile, email and SGEM GlobalID.
For librarian assistance: [email protected]
Purchase Instant Access
- Article can be downloaded after successful payment.
- Article may be used according to SWS library access terms.
- Article cannot be redistributed.