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Teplofizika vysokikh temperatur
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Teplofizika vysokikh temperatur, 2014, Volume 52, Issue 5, Pages 760–776
DOI: https://doi.org/10.7868/S0040364414050019
(Mi tvt202)
 

This article is cited in 17 scientific papers (total in 17 papers)

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Principles of heat accumulation and heat-accumulating materials in use

B. D. Babaev

Daghestan State University
References:
Abstract: This work is aimed at analysis of materials proposed for heat accumulation. The heat-accumulating materials are classified against the composition class and the operation principles. The principles of heat accumulation and the prospective energy intensive heat-accumulating compositions and the method of their production are shown.
Received: 24.12.2013
Accepted: 15.04.2014
English version:
High Temperature, 2014, Volume 52, Issue 5, Pages 736–751
DOI: https://doi.org/10.1134/S0018151X14050010
Bibliographic databases:
Document Type: Article
UDC: 620.92.004.4; 620.93
Language: Russian
Citation: B. D. Babaev, “Principles of heat accumulation and heat-accumulating materials in use”, TVT, 52:5 (2014), 760–776; High Temperature, 52:5 (2014), 736–751
Citation in format AMSBIB
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Linking options:
  • https://www.mathnet.ru/eng/tvt202
  • https://www.mathnet.ru/eng/tvt/v52/i5/p760
  • This publication is cited in the following 17 articles:
    1. T. D. Slavnov, E. M. Egorova, I. K. Garkushin, A. V. Burchakov, M. A. Demina, “Phase Tree, Analysis of Crystallizing Phases, and Description of Chemical Interaction in the Ca,Ba||F,Cl Three-Component Reciprocal System”, Russ. J. Inorg. Chem., 2024  crossref
    2. R. Z. Aminov, M. V. Garievskii, D. M. Anoshin, “Development of Design Solutions for a Latent Heat Thermal Energy Storage under Conditions of Its Operation in a Single Energy Complex with an NPP”, Therm. Eng., 71:3 (2024), 203  crossref
    3. V. V. Makarova, A. V. Vlasova, S. V. Antonov, Yu. Yu. Borisova, D. N. Borisov, M. R. Yakubov, “Effect of Surfactants on the Structure, Thermal Conductivity, and Rheology of Composites Based on Paraffin and Petroleum Asphaltenes”, Energy Fuels, 38:12 (2024), 11204  crossref
    4. T. D. Slavnov, E. M. Egorova, I. K. Garkushin, A. V. Burchakov, M. A. Demina, “Phase tree, analysis of crystallizing phases and description of chemical interaction in the three-component reciprocal system Ca,Ba| |F,Cl”, Žurnal neorganičeskoj himii, 69:1 (2024), 83  crossref
    5. Valery Yurin, Michael Garievsky, Daniil Anoshin, “Conditions for economic efficiency of latent heat thermal energy storage systems at nuclear power plants”, Nuclear Engineering and Design, 429 (2024), 113581  crossref
    6. R.Z. Aminov, D.M. Anoshin, M.V. Garievsky, “Numerical modeling of discharge modes and evaluation of the major characteristics of latent heat thermal energy storage at a nuclear power plant”, Journal of Energy Storage, 99 (2024), 113209  crossref
    7. Michael G. Mauk, Felix Ansah, Mohamed El-Tholoth, “Chemical Heating for Minimally Instrumented Point-of-Care (POC) Molecular Diagnostics”, Biosensors, 14:11 (2024), 554  crossref
    8. M. I. Milekhin, E. V. Umerenkov, “Thermal accumulators of phase change based on paraffin”, Proceedings of the SWSU, 28:3 (2024), 36  crossref
    9. A. V. Fedyukhin, V. A. Karasevich, M. S. Povernov, O. V. Afanaseva, “Teplovoi akkumulyator s teploizolyatsionnym materialom na osnove aerogelya”, Vestnik MGSU, 19:12 (2024), 1963  crossref
    10. Svetlana N. Gorbacheva, Yulia Yu. Borisova, Veronika V. Makarova, Sergey V. Antonov, Dmitry N. Borisov, Makhmut R. Yakubov, “Modified Technogenic Asphaltenes as Enhancers of the Thermal Conductivity of Paraffin”, Molecules, 28:3 (2023), 949  crossref
    11. Victor M. Nazarychev, Artyom D. Glova, Sergey V. Larin, Alexey V. Lyulin, Sergey V. Lyulin, Andrey A. Gurtovenko, “Cooling-Rate Computer Simulations for the Description of Crystallization of Organic Phase-Change Materials”, IJMS, 23:23 (2022), 14576  crossref
    12. S. V. Larin, V. V. Makarova, S. N. Gorbacheva, M. R. Yakubov, S. V. Antonov, N. I. Borzdun, A. D. Glova, V. M. Nazarychev, A. A. Gurtovenko, S. V. Lyulin, “Impact of conjugated polymer addition on the properties of paraffin–asphaltene blends for heat storage applications: Insight from computer modeling and experiment”, The Journal of Chemical Physics, 157:19 (2022)  crossref
    13. Cherunova I., Kornev N., Lukyanova E., Varavka V., “Development and Study of the Structure and Properties of a Composite Textile Material With Encapsulated Heat-Preserving Components For Heat-Protective Clothing”, Appl. Sci.-Basel, 11:11 (2021), 5247  crossref  isi  scopus
    14. Indira Aimbetova, Ulanbator Suleimenov, Raimberdy Ristavletov, Omirserik Baigenzhenov, “Study of shrinkage of heat storage materials for building envelope structures”, IOP Conf. Ser.: Mater. Sci. Eng., 862:6 (2020), 062066  crossref
    15. Baba Dzhabrailovich Babaev, Valeriy Vladimirovich Kharchenko, Vladimir Panchenko, Advances in Environmental Engineering and Green Technologies, Handbook of Research on Smart Computing for Renewable Energy and Agro-Engineering, 2020, 1  crossref
    16. P. Shi, B. K. Quinn, Yu. Zhang, X. Bao, Sh. Lin, “Comparison of the intrinsic optimum temperatures for seed germination between two bamboo species based on a thermodynamic model”, Glob. Ecol. Conserv., 17 (2019), e00568  crossref  isi  scopus
    17. I. O. Aimbetova, U. S. Suleymenov, O. A. Kostikov, K. E. Imanaliev, R. A. Ristavletov, M. A. Kambarov, “Energoactive multilayered construction of fencing with a thermal-accumulating layer”, Bull. Natl. Acad. Sci. Rep. Kazakhstan, 2018, no. 4, 57–62  isi
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