Vliyanie teploakkumuliruyushchey steny s vodyanym teploobmennikom na okhlazhdayushchuyu nagruzku v zdanii. Chast' 2
- Authors: Dzhenblat S.1, Volkova O.V.1
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Affiliations:
- Issue: Vol 109, No 4 (2020)
- Pages: 16-21
- Section: Articles
- URL: https://freezetech.ru/0023-124X/article/view/104043
- DOI: https://doi.org/10.17816/RF104043
- ID: 104043
Cite item
Abstract
The paper presents the results of mathematical modeling and experimental research of the effect of a heataccumulating wall with a water heat exchanger on building cooling. It is shown that the use of such a wall reduces electric power consumption and improves the thermal comfort in the premises under climatic conditions of Latakia in Syria. The results of mathematical modeling using the TRNSYS program made it possible to define the effective location of the wall towards the sun, as well as the parameters and operation mode of the water heat exchanger. To verify the adequacy of the model the experimental studies of two rooms were carried out. One of the rooms was a reference and the second had a heataccumulating wall with a water heat exchanger designed in conformity with the data resulted from the modeling. The experimental results showed a satisfactory convergence with the results of mathematical modeling
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About the authors
Sil'vana Dzhenblat
Email: silvana.jenblat@gmail.com
Ol'ga Vladimirovna Volkova
Email: volga.v@mail.ru
References
- Carli M., Deckee H. Development of a simplified method for sizing ThermoActive Building Systems (TABS). - Italia: University of Padua, 2014. - 85 p.
- George R., Namee W., Kasim T. et al. The reference in solar thermal energy and its applications. -Syria: Al baath university, 2009. - 670 p.
- Glück B., Windisch K. Strahlungsheizung. Theorie und Praxis. - Germany, Karlsruhe: Verlag C. F. Müller, 1982. - 507 p.
- Ibrahim M., Wurtz E., Biwole P., Achard P. Transferring the south solar energy to the north facade through embedded water pipes // Journal of Energy. 2014. V. 78. P. 834-845.
- Izquierdo B. et al. A numerical study of external building walls containing phase change materials (PCM) // Journal of Applied Thermal Engineering. 2012. V. 47, P. 73-85.
- Jin X., Zhang S., XU X., Zhang X. Effects of PCM state on its phase change performance and the thermal performance of building walls // Building and winter of Environment. 2014. V. 81. P. 334-339.
- Kashif I. et al. Performance evaluation of PVTrombe wall for sustainable building development //Journal of Procedia CIRP. 2015. V. 26, P. 624-629.
- Klein S. A. et al. TRNSYS: a transient simulation program/ User Manual. -USA: University of WisconsimMadison. 2006, version 16.1.
- Koschenz M., Lehmann B. EMPA, Abteilung Energiesysteme/Haustechnik, CH8600 Dübendorf (Switzerland); Stefan Holst, TRANSSOLAR// Energietechnik GmbH, D70569 Stuttgart (Germany), 2000.
- Oropeza I., Alberg P. Active and passive cooling methods for dwellings: A review // Renewable and Sustainable Energy Reviews. 2018. V. 82. P. 531-544.
- Perna et al. Trombe wall management in summer conditions: An experimental study // Journal of Solar Energy. 2012. V. 86. P. 2839 -2851.
- Shen. J. et al. Numerical study on thermal behavior of classical or composite Trombe solar walls // Journal of Energy and Buildings. 2007. V. 39. P. 962-974.
- Stevanovic S. Optimization of passive solar design strategies: a review // Renew Sustain Energy Rev. 2013. V. 25. P. 177-196.
- SUN et al. The applicability of the wall implanted with heat pipes in China // Journal of Energy and Buildings. 2015. V. 104. P. 36-46.
- Wang R.Z., Xu Z.Y. et al. Advances in Solar Heat and Cooling. 1 edition. - Woodhead Publishing. Series in Energy book (102), 2016. - 596 p.
- YU et al. A thermoactivated wall for load reduction and supplementary cooling with free to lowcost thermal water // Journal of Energy. 2016. V. 99. P. 250-265.