mgssuvestВестник МГСУVestnik MGSU1997-09352304-6600Moscow State University of Civil Engineering (National Research University) (MGSU)10.22227/1997-0935.2024.2.258-269mgssuvest-189Research ArticleСтроительное материаловедениеConstruction material engineeringПрименение техногенного сырья в процессе синтеза пеностекла с гетерогенной микроструктуройUsing anthropogenic raw materials in the process of synthesizing foam glass with heterogeneous microstructurehttps://orcid.org/0000-0001-6117-7529ФедосовС. В.FedosovS. V.

Сергей Викторович Федосов — доктор технических наук, профессор кафедры технологии и организации строительного производства, академик РААСН

129337, г. Москва, Ярославское шоссе, д. 26

РИНЦ ID: 105900, Scopus: 7005670404, ResearcherID: B-2409-2017

Sergey V. Fedosov — Doctor of Technical Sciences, Professor of the Department of Technology and Organization of Construction Production, Academician RAASN

26 Yaroslavskoe shosse, Moscow, 129337

ID RSCI: 105900, Scopus: 7005670404, ResearcherID: B-2409-2017

fedosov-academic53@mail.ruhttps://orcid.org/0000-0001-8460-9056БакановМ. О.BakanovM. O.

Максим Олегович Баканов — доктор технических наук, доцент, начальник учебно-научного комплекса «Пожаротушение», советник РААСН

153040, г. Иваново, пр. Строителей, д. 33

РИНЦ ID: 802943, Scopus: 57204434215, ResearcherID: O-1809-2017

Maksim O. Bakanov — Doctor of Technical Sciences, Associate Professor, Head of the educational and scientific complex “Fire Extinguishing”, Advisor to RAASN

33 Stroiteley ave., Ivanovo, 153040

ID RSCI: 802943, Scopus: 57204434215, ResearcherID: O-1809-2017

mask-13@mail.ruhttps://orcid.org/0000-0002-7552-1885ГрушкоИ. С.GrushkoI. S.

Ирина Сергеевна Грушко — кандидат технических наук, доцент кафедры промышленного, гражданского строительства, геотехники и фундаментостроения

346428, г. Новочеркасск, ул. Просвещения, д. 132

РИНЦ ID: 562201, Scopus: 35519681000, ResearcherID: A-3310-2014

Irina S. Grushko — Candidate of Technical Sciences, Associate Professor of the Department of Industrial, Civil Engineering, Geotechnical and Foundation Engineering

132 Prosvescheniya st., Novocherkassk, 346428

ID RSCI: 562201, Scopus: 35519681000, ResearcherID: A-3310-2014

grushkois@gmail.comНациональный исследовательский Московский государственный строительный университет (НИУ МГСУ)РоссияMoscow State University of Civil Engineering (National Research University) (MGSU)Russian FederationИвановская пожарно-спасательная академия Государственной противопожарной службы Министерства Российской Федерации по делам гражданской обороны, чрезвычайным ситуациям и ликвидации последствий стихийных бедствий (Ивановская пожарно-спасательная академия ГПС МЧС России)РоссияIvanovo Fire Rescue Academy of State Firefighting Service of Ministry of Russian Federation for Civil Defense, Emergencies and Elimination of Consequences of Natural Disasters (IFRA of SFS of EMERCOM of Russia)Russian FederationЮжно-Российский государственный политехнический университет (НПИ) имени М.И. Платова (ЮРГПУ (НПИ))РоссияM.I. Platov South-Russian State Polytechnic University (NPI) (SRSPU (NPI))Russian Federation202415032024192258269Copyright © Федосов С.В., Баканов М.О., Грушко И.С., 20242024Федосов С.В., Баканов М.О., Грушко И.С.Fedosov S.V., Bakanov M.O., Grushko I.S.This work is licensed under a Creative Commons Attribution 4.0 License.https://www.vestnikmgsu.ru/jour/article/view/189Введение

Введение. Теплоизоляционные материалы, включая пеностекло, применяются для снижения теплопотерь в зданиях. Пеностекло обладает низкой теплопроводностью, высокой прочностью и экологической безопасностью. Исследования ученых, в том числе И.И. Китайгородского и Б.К. Демидовича, направлены на контроль процесса синтеза пеностекла и регулирование процесса кристаллизации. Снижение стоимости пеностекла возможно путем использования отходов промышленного производства. На примере золошлаковых отходов электрической станции в Ростовской области исследована возможность их повторного применения при получении пеностекла.

Материалы и методы

Материалы и методы. Изучение состава шихты пеностекла включает подготовку сырья, формовку и обжиг. Исследования структуры проводились с помощью автоматического дифрактометра, микротомографа и растрового электронного микроскопа. Проведены испытания свойств образцов пеностекла, таких как теплопроводность, прочность, плотность и воздействие нагрузки.

Результаты

Результаты. Состав сырьевых материалов для пеностекла: стеклобой, золошлаковая смесь и Na2B4O7·10H2O. Синтез пеностекла осуществлялся с использованием антрацита, диоксида циркония, оксида хрома и оксида магния. Исследования показали образование кристаллических фаз в аморфном каркасе пеностекла. Подтверждено наличие кварца, пироксена, кристобалита, эсколаита и волластонита в составе пеностекла.

Выводы

Выводы. Разработаны составы шихты и технологический режим синтеза, получены 9 модификаций пеностекла с равномерной пористой структурой и различным содержанием кристаллических фаз. Кристаллические включения расположены равномерно. В роли центров кристаллизации выступают присутствующие в сырьевых компонентах кристаллические фазы (в составе золошлаковой смеси) и дополнительные инициаторы кристаллизации (оксид хрома, диоксид циркония и оксид магния). Показано соответствие свойств пеностекла требованиям стандарта.

Introduction

Introduction. Thermal insulation materials, including foam glass, are used to reduce heat losses in buildings. Foam glass has low thermal conductivity, high strength and environmental safety. Researches of scientists, including I.I. Kitaygorodsky and B.K. Demidovich, are aimed at controlling the process of foam glass synthesis and regulating the crystallization process. The cost reduction of foam glass is possible through the utilization of industrial waste.

Materials and methods

Materials and methods. The potential for reusing and obtaining foam glass is being studied using ash and slag waste from a power station in the Rostov region. The study of foam glass batch mixture includes preparation of raw materials, molding and firing. The research of the structure was conducted using an automatic diffractometer, micro-tomograph, and scanning electron microscope. Tests were carried out to assess the properties of foam glass specimens, such as thermal conducti-vity, strength, density, and load impact. The composition of raw materials for foam glass include broken glass, ash and slag mixture and Na2B4O7·10H2O. Foam glass synthesis was performed using anthracite, zirconium dioxide, chromium oxide, and magnesium oxide.

Results

Results. The research revealed the formation of crystalline phases in the amorphous foam glass framework. The presence of quartz, pyroxene, cristobalite, eskolaite, and wollastonite in foam glass composition was confirmed.

Conclusions

Conclusions. Batch compositions and synthesis parameters were developed, leading to the production of nine modifications of foam glass with uniform porous structure and varying content of crystalline phases. Crystalline inclusions are evenly distributed. The role of crystallization centres is played by the crystalline phases present in the raw materials (in the composition of ash-and-slag mixture) and additional crystallization initiators (chromium oxide, zirconium dioxide and magnesium oxide). The conformity of foam glass properties to standard requirements was demonstrated.

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The authors declare that there are no conflicts of interest present.