Study of thermal-physical properties of porous ceramic insulation products

Cover Page

Cite item

Full Text

Abstract

The detailed description of the main parameters, influencing the thermal insulation characteristics of building walls is presented in this article. In addition the analysis of this parameters study in modern construction practice is made. The main characteristics of concrete based on porous expanded clay granules are presented, including the results of studies of capillary absorption, moisture transfer rate and moisture absorption properties of porous expanded clay concrete samples affecting the thermal conductivity coefficient. The research results are presented in the context of thermal insulation and fire-resistant ceramic granules application as fillers in porous concrete walls. On the basis of results of study of the organomineral additives influence on the thermal conductivity coefficient of porous expanded clay concrete the study of porous expanded clay concrete samples were carried out. The porous and dense wall concrete sorption moisture and vapour permeability are determined in laboratory conditions. Also the main changes of these parameters at different values of relative humidity of surrounding air are determined.

About the authors

Ye. Kocherov

South-Kazakhstan University named after M. Auezov

Email: Erkebulan083@mail.ru
ORCID iD: 0009-0003-8257-1981

A. Agabekova

Khoja Akhmet Yassawi International Kazakh-Turkish University

Email: altolkyn.agabekova@ayu.edu.kz
ORCID iD: 0000-0001-5977-6653

L. Ramatullaeva

South-Kazakhstan University named after M. Auezov

Email: ramatullaeva_l@mail.ru
ORCID iD: 0000-0003-1771-9903

A. Mamitova

South-Kazakhstan University named after M. Auezov

Email: a-mamitova@mail.ru
ORCID iD: 0000-0003-2334-145X

B. Medeshev

Tashkent state transport university

Email: baxtiyor_medeshev@tstu.uz
ORCID iD: 0009-0000-9912-7578

R. Razikov

Tashkent state transport university

Email: rozikov_r@bk.ru
ORCID iD: 0009-0003-3994-0630

S. Syrlybekkyzy

M.Sh. Yesenov Caspian University of Technology and Engineering

Email: samal.syrlybekkyzy@yu.edu.kz
ORCID iD: 0000-0002-0260-0611

A. Kolesnikov

South-Kazakhstan University named after M. Auezov

Email: kas164@yandex.kz
ORCID iD: 0000-0002-8060-6234

References

  1. Kocherov E.N., Kolesnikov A.S., Mamitova A.D. Research of clay raw materials of south Kazakhstan for thermal insulating keramzit production. Environmental Technologies and Engineering for Sustainable Development (ETESD‑2023). I. Tashkent. October 14, 2023. P. 37 – 43.
  2. Donayev A., Shapalov S., Sapargaliyeva B., Ivakhniyuk G. Studies of waste from the mining and metallurgical industry with determination of its impact on the life of the population. News of the National Academy of Sciences of the Republic of Kazakhstan. Series Geology and Technical Sciences. 2022. (4). P. 55 – 68.
  3. Nadirov K.S., Zhantasov M.K., Bimbetova G.Z., Sadyrbayeva A.S., Orynbasarov A.K., Sakybayev B.A. The study of the gossypol resin impact on adhesive properties of the intermediate layer of the pipeline three‑layer rust protection coating. International Journal of Adhesion and Adhesives. 2017. 78. P. 195 – 199. doi: 10.1016/j.ijadhadh.2017.07.001
  4. Sapargaliyeva B.O., Bychkov A.Y., Alferyeva Y.O., Syrlybekkyzy S., Altybaeva Z.K., Nurshakhanova L.K., Seidaliyeva L.K., Suleimenova B.S., Zhidebayeva A.E. et al. Thermodynamic modeling of the formation of the main minerals of cement clinker and zinc fumes in the processing of toxic technogenic waste of the metallurgical industry. Rasayan Journal of Chemistry. 2022. 15 (8). P. 2181 – 2187.
  5. Zhangabay N., Suleimenov U., Utelbayeva A., Fediuk R., Amran M. Analysis of a stress–strain state of a cylindrical tank wall vertical field joint zone. Buildings. 2022. 12 (9). P. 1445.
  6. Zhantasov M. K., Bimbetova G. Z., Sadyrbayeva A. S., Orynbasarov A. K., Kutzhanova A. N., Turemuratov R. S., Botabaev N. E., Zhantasova D. Examination of optimal parameters of oxy‑ethylation of fatty acids to produce demulsifiers for deliquefaction in the skimming and oil treatment system. Chemistry Today. 2016. 34 (1). P. 72 – 77.
  7. Zhangabay N., Baidilla I., Tagybayev A., Anarbayev Y., Kozlov P. Thermophysical indicators of elaborated sandwich cladding constructions with heat‑reflective coverings and air gaps. Case Studies in Construction Materials. 2023. 18. e02161.
  8. Kocherov Ye.N., Kolesnikov A., Makulbekova G., Mamitova A., Ramatullaeva L., Medeshev B., Kolesnikova O. Investigation of the physico‑chemical and mechanical properties of expanded ceramsite granules made on the basis of coal mining waste. Journal of Composites Science. 2024. 8 (8). 306. doi: 10.3390/jcs8080306
  9. Akhmatov M.A. Lightweight concrete and reinforced concrete structures on aggregates from stone waste and loose porous rocks. Nalchik. Publishing house Kokov V.M. KBGSHA. 2010. 165 p.
  10. Mordzich M. M. Technology and physico‑mechanical properties of claydite foam concrete for monolithic and prefabricated construction. Science and Technique. 2019. 18 (4). P. 292 – 302.
  11. Samokhvalov O.V., Galitskov S.Ya., Fadeev A.S. Analysis of technological limitations for obtaining durable expanded clay. INTERSTROYMEKH‑2014. Proceedings of the International Scientific and Technical Conference. Samara. Samara State Architectural‑Construction University. 2014. P. 156 – 159.
  12. Rubashkina T.I. Non‑stationary calculation of thermal protection of building envelopes. Modern Technologies. System Analysis. Modeling. 2014. 2 (42). P. 188 – 195.
  13. Sandan A.S. Study of the kinetics of increase in the strength of concrete from expanded clay concrete mixture by step‑by‑step introduction of heat. Bulletin of the Tuva State University. 2012. 3. P. 24 – 29.
  14. Roshchupkina I.Yu., Denisov D.Yu. Study of the phase composition of expanded clay based on waste from a mining and processing plant during coal enrichment. Bashkir Chemical Journal. 2010. 17 (2). P. 136 – 139.
  15. Gorin V.M., Tokareva S.A., Kabanova M.K. High‑strength expanded clay and keramdor for load‑bearing structures and road construction. Construction Materials. Moscow. ZAO SORM. 2010. 1 (661). P. 9 – 11.
  16. Gorin V.M., Tokareva S.A., Vytchikov Yu.S., Belyakov I.G., Shiyanov L.P. Application of wall stones from sand‑free expanded clay concrete in housing construction. Construction Materials. Moscow. ZAO SORM. 2010. 2 (662). P. 15 – 18.
  17. Rakhimov R.Z., Rakhimova N.R. Scientific, experimental, technical, economic and technological prerequisites for managing the structure and properties of filled artificial building composite materials. Urban Development. 2011. 3 (13). P. 73 – 79.
  18. Abdrakhimova E.S., Abdrakhimov V.Z., Kayrakbaev A.K. Innovative directions for the use of waste from the fuel and energy complex in the production of thermal insulation materials. Aktobe. Kazakh‑Russian International University. 2015. 276 p.
  19. Samokhvalov O.V., Galitskov S. a., Pyshkin A.S., Fadeev A S. On the influence of thermal power and torch length on the strength and weight characteristics of expanded clay. INTERSTROYMEKH‑2014. Proceedings of the International Scientific and Technical Conference. Samara. Samara State Architectural‑Construction University. 2014. P. 101 – 104.
  20. Maksimov S.V. Wall products. Directions of technology development. Bulletin of UlSTU. 2017. 4. P. 46 – 48.
  21. Abdrakhimova E.S., Kayrakbaev A.K. Use of waste from the fuel and energy complex in the production of thermal insulation materials based on liquid glass compositions. Aktobe. Kazakh‑Russian International University. 2016. 140 p.
  22. Sandan A.S. Influence of methods and modes of processing expanded clay concrete on its properties. Industrial and Civil Engineering. Moscow. 2007. 3. P. 53 – 54.
  23. Makulbekova G.O., Kocherov E.N., Kenzhalieva G.D. Study of sorption moisture and vapor absorption of expanded clay concrete walls. Complaints of the Gyly men Bilіmnіn Hotshysy Republican Magazine. Nur‑Sultan. 2020. 2 (2). P. 165 – 170.
  24. Karpov D.F. Thermal imaging method for determining humidity fields of building envelope surfaces. Vestnik BSTU im. V. G. Shukhova. 2019. 6. P. 28 – 33.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Согласие на обработку персональных данных

 

Используя сайт https://journals.rcsi.science, я (далее – «Пользователь» или «Субъект персональных данных») даю согласие на обработку персональных данных на этом сайте (текст Согласия) и на обработку персональных данных с помощью сервиса «Яндекс.Метрика» (текст Согласия).