• Покупка статей
  • Telegram_OreMet
Скрыть
Журналы →  Eurasian Mining →  2022 →  №2 →  Назад

PROCESSING AND COMPLEX USAGE OF MINERAL RAW MATERIALS
Название Production of porous geopolymers using ash and slag waste of power plants in the Russian Arctic
DOI 10.17580/em.2022.02.14
Автор Yatsenko E. A., Goltsman B. M., Sergeev V. V.
Информация об авторе

Platov South-Russian State Polytechnic University, Novocherkassk, Russia:

Yatsenko E. A., Head of Department, Professor, Doctor of Engineering Sciences, e_yatsenko@mail.ru
Goltsman B. M., Associate Professor, Candidate of Engineering Sciences


Peter the Great Saint Petersburg Polytechnic University, Saint Petersburg, Russia:

Sergeev V. V., Professor, Corresponding Member of the Russian Academy of Sciences, Doctor of Engineering Sciences
Реферат

Coal combustion at thermal power plants generates much ash and slag waste which amass at waste sites and have a dramatic adverse effect on the environment. In the meanwhile, ash and slag is a valuable source for the production of silicate materials for road making and civil construction. The most promising technology for the synthesis of silicate materials is selected from the viewpoint of energy and resource efficiency—the low-temperature alkaline activation and production of porous geopolymers. A range of mix formulations is developed on the basis of ash and slag from Severodvinsk PP-1, with addition of an alkaline activator (mixture of sodium hydroxide solution and liquid glass), various sponging agents and a foam stabilizer. The increase in the amount of an alkaline activator noticeably decreases the foam stability. The aluminum powder is a less active sponging agent as compared with the hydrogen peroxide solution. The introduction of a foam stabilizer essentially increases the number of pores and decreases the foam density. The synthesis of geopolymeric materials using ash and slag from Apatity PP produced a material with the density of 456 kg/m3 and with the pores 300–600 μm in size upon average. Addition of a surfactant greatly decreases the average size of pores at insignificant reduction in the density of the test samples. On the evidence of the research, the optimal composition of the activation mixture is selected for manufacturing porous geopolymeric materials with a density less than 500 kg/m3, including an alkaline activator, hydrogen peroxide as a sponging agent and a surfactant as a foam stabilizer.

The study was supported by the Russian Science Foundation in the framework of Agreement No. 21-19-00203 Effective Heat-Curable Eco-Geopolymers for Road Construction in the Russian Arctic Using Combustion Waste of Solid Fuels at Local Power Pants under guidance by E. A. Yatsenko.
Ключевые слова Ash and slag waste, thermal power plants, recycling, geopolymers, porous structure, road construction, Arctic zone
Библиографический список

1. Pugach L. I. Energy and ecology: Textbook. Novosibirsk : NGTU, 2003. 504 p.
2. Panteleev V. G., Larina E. A., Melentyev V. A. et al. Composition and properties of TPP ash and slag: Reference guide. Leningrad : Energoatonizdat, 1985. 288 p.
3. Danilovich I. Yu., Skanavi N. A. Use of fuel slags and ash for the production of building materials: Textbook manual for SPTU. Moscow : Vyschaya shkola, 1988. 72 p.
4. Yatsenko E. A., Goltsman B. M. Study of synthesis processes of heat-insulating silicate materials for external protection of steel oil pipelines. CIS Iron and Steel Review. 2020. Vol. 20. pp. 33–36. DOI: 10.17580/cisisr.2020.02.08
5. Yatsenko E. A., Goltsman B. M., Smolii V. A. et al. Foamed slag glass – Eco-friendly insulating material based on slag waste. 2015 IEEE 15th International Conference on Environment and Electrical Engineering, EEEIC 2015 Conference Proceedings. 2015. pp. 819–823. DOI: 10.1109/EEEIC.2015.7165270
6. Wu J. P., Boccaccini A. R., Lee P. D. et al. Glass ceramic foams from coal ash and waste glass: production and characterization. Advances in Applied Ceramics. 2006. Vol. 105, No. 1. pp. 32–39.
7. Delitsyn L. M., Vlasov A. S. The need of applying new approaches for using ash produced at coal-fired thermal power stations. Teploenergetika. 2010. No. 4. pp. 49–55.
8. Yatsenko E. A., Goltsman B. M., Yatsenko L. A. Investigation of the Raw Materials’ composition and ratio influence on the structure and properties of the foamed slag glass. Materials Science Forum. 2016. Vol. 843. pp. 183–188.
9. Kazmina O. V., Kuznetsova N. A. Production of high effective heat insulating construction material based on thermal power ash and slag waste. Refractories and Industrial Ceramics. 2012. No. 1–2. pp. 78–82.
10. Suvorova O. V., Makarov D. V. Foam Glass and Foam Materials Based on Ash-Slag Wastes from Thermal Power Plants (Review). Glass and Ceramics. 2019. Vol. 76. pp. 188–193.
11. Bosnik V. B., Vaisman Ya. I., Ketov A. A. et al. Promising areas for producing bitumen-like materials based on synthetic polymers waste. Ecology and Industry of Russia. 2020. Vol. 24, Iss. 5. pp. 34–39.
12. Ivanov K. S., Korotkov E. A. Investigation of the effect of a layer of granulated foam-glass ceramic on the temperature conditions of frozen soil. Soil Mechanics and Foundation Engineering. 2017. No. 5. pp. 32–37.
13. Bilodeau J. P., Dore G., Pierre P. Gradation influence on frost susceptibility of base granular materials. International Journal of Pavement Engineering. 2008. Vol. 9(6). pp. 397–411.
14. Novais R. M. Pullar R. C., Labrincha J. A. Geopolymer foams: An overview of recent advancements. Progress in Materials Science. 2020. Vol. 109. 100621. DOI: 10.1016/j.pmatsci.2019.100621
15. Bai C., Colombo P. Processing, properties and applications of highly porous geopolymers: A review. Ceramics International. 2018. Vol. 44, Iss. 14. pp. 16103–16118.
16. Zhao J., Tong L., Li B. et al. Eco-friendly geopolymer materials. Journal of Cleaner Production. 2021. DOI: 10.1016/J.JCLEPRO.2021.127085
17. Davidovits J. Geopolymer Chemistry and Applications, 5th ed. France : Geopolymer Institute, 2020. 680 p.
Полный текст статьи Production of porous geopolymers using ash and slag waste of power plants in the Russian Arctic
Назад