Please use this identifier to cite or link to this item: http://ena.lp.edu.ua:8080/handle/ntb/49571
Title: Дослідження сонячних колекторів, інтегрованих у конструкцію скляного фасаду будівлі/споруди: необхідність та особливості
Other Titles: Research of solar collectors integrated into the design of the building/structure glass facade: necessity and features
Authors: Венгрин, І.
Venhryn, Iryna
Affiliation: Національний університет “Львівська політехніка”
Lviv Polytechnic National University
Bibliographic description (Ukraine): Венгрин І. Дослідження сонячних колекторів, інтегрованих у конструкцію скляного фасаду будівлі/споруди: необхідність та особливості / І. Венгрин // Theory and Building Practice. — Lviv : Lviv Politechnic Publishing House, 2019. — Vol 1. — No 1. — P. 38–46.
Bibliographic description (International): Venhryn I. Research of solar collectors integrated into the design of the building/structure glass facade: necessity and features / Iryna Venhryn // Theory and Building Practice. — Lviv : Lviv Politechnic Publishing House, 2019. — Vol 1. — No 1. — P. 38–46.
Is part of: Theory and Building Practice, 1 (1), 2019
Issue: 1
Volume: 1
Issue Date: 23-Mar-2019
Publisher: Видавництво Львівської політехніки
Lviv Politechnic Publishing House
Place of the edition/event: Львів
Lviv
Keywords: сонячна енергія
сонячний колектор
фактор
скляний фасад
фотоелемент
solar energy
solar collector
factor
glass facade
solar cell
Number of pages: 9
Page range: 38-46
Start page: 38
End page: 46
Abstract: Проаналізовано необхідність розроблення сонячних колекторів, інтегрованих у конструкцію будівлі/споруди скляного фасаду. Обґрунтовано необхідність розвитку в Україні відновлюваних джерел енергії за рахунок параметра енергоємності валового внутрішнього продукту України та фізичного зношення установок в паливно-енергетичному комплексі. Обґрунтовано, що сонячна енергетика як один з видів загальнодоступних ресурсів у сфері альтернативних технологій має перспективи розвитку. В праці знайдено нові технологічні рішення, що дають змогу поєднати сонячне електро- і теплопостачання з урахуванням тенденції еволюції скляних фасадів. Для дослідження описано методи випробувань сонячних колекторів і фотоелементів відповідно до нормативної літератури. Основні критерії, що впливають на коефіцієнт корисної дії в конструкції, такі: інтенсивність випромінювання сонячної енергії, температура навколишнього середовища, конструктивні особливості та встановлені експлуатаційні характеристики сонячного колектора.
The work is devoted to the analysis of the need for the development of solar collectors integrated into the design of the building / structure glass facade. In particular, the necessity for Ukraine to develop renewable energy sources through the parameter of energy intensity of the Ukraine gross domestic product and the physical wear of the installation in fuel-energy complex. It was analyzed that the solar energy as one of the types of generally available resources in the field of alternative technologies has been prospects for development. Through the using of very small amount of solar energy installations in comparison with the solar energy volume that receives the Earth's surface relative to energy consumption on Earth, it can be seen the prospects of such resource. It has been noted that the territory of Ukraine receives a sufficient amount of solar energy for its use by solar installations. In this paper, conducts the search of new alternative technological solutions that allow to combine the installation of solar eletro- and heat supply with the design of the glass facade in view of the trend of glass facades evolution in developed countries. Test methods of solar collectors and solar cells according to the normative literature are described for the research. The main criterias that determine the coefficient of performance parameter are: the intensity of solar energy radiation, the ambient temperature, the design features of the solar collector, the initially established operating the solar collector characteristics. The factors that should have a significant impact on the efficiency of the design are determined for the laboratory stand study. In particular: the distance between the solar cell and the solar collector; the simulated intensity flow of thermal energy; the angle between active surface of the solar collector and the projection of the heat flow direction in the vertical plane of the solar collector; heat carrier flow rate installed in the solar heating system; air velocity; the angle between active surface of the solar collector and the projection of the wind flow direction in the vertical plane of the solar collector; the angle between the solar collector surface and the projection of the heat flow direction in the horizontal plane of the solar collector.
URI: http://ena.lp.edu.ua:8080/handle/ntb/49571
ISSN: 2707-1057
Copyright owner: © Національний університет “Львівська політехніка”, 2019
© Венгрин Ірина, 2019
URL for reference material: http://energetika.in.ua
References (Ukraine): Smenkovskyi, A. Yu., Vorontsov, S. B., & Biehun S. V. (2012). Threats to Ukraine's energy security in the
face of increasing competition in global and regional energy markets. NISS, Kyiv, 136. (in Ukrainian)
Mysak, Y. S. (2014). Solar energy: theory and practice. Lviv, 340. (in Ukrainian)
Ukraine 2030 (2017). The doctrine of balanced development. Calvaria, Lviv, 164. (in Ukrainian)
Energy (2019): History, present and future. Retrieved from http://energetika.in.ua (11.2019). (in Ukrainian)
Pivniak, H. H., Shkrabets, F. P. (2013). Alternative energy in Ukraine. NGU, Dnipro, 109. (in Ukrainian)
Еuropean Photovoltaic Industry Association (2011), SG6: Solar photovoltaic electricity empowering the world.
Greenpeace International, 6. (in English)
Naraievskyi, S. V. (2017). Comparative characteristics of the efficiency of solar energy in the leading countries
of the world. Mukachevo state University, 10. (in Ukrainian)
Chwieduk, D. (2014). Solar Energy in Buildings. Thermal Balance for Efficient Heating and Cooling, USA, 362. (in English)
Zapryvoda, V. I. (2002). Geometric modeling of solar radiation receipt on the surface of spatial coatings of
architectural objects (Doctoral dissertation). Kyiv. (in Ukrainian)
Mathiesen, B. V., Lund, H., & Wenzel, H. (2015). Smart energy systems for coherent 100% renewable energy
and transport solutions. Applied Energy, 145, 139–154. (in English)
Sig Chai, D., Wena, J. Z., Nathwani, J. (2013). Simulation of cogeneration within the concept of smart energy
networks. Energy Convers Manage, 75, 453–465. (in English)
Lund, H., Andersen, A. N., & Connolly, D. (2012). From electricity smart grids to smart energy systems – a
market operation based approach and understanding. Energy, 42, 96–102. (in English)
Nakashydze, L. V., Shevchenko, M. V. (2017). Solar collectors – energy-active fences as an element of the air
conditioning system of buildings. Construction, materials science, mechanical engineering, 99. (in Ukrainian)
Kuvshynov, V. V. (2013). Methods for calculating and improving the efficiency of thermal photoelectric
installations. SNUNEI, Sevastopol, 2 (46), 166–171. (in Ukrainian)
Fryd, S. E. (1988). Methods of thermal testing of solar collectors. Moscow, JIHT USSR Academy of sciences,
p. 57. (in Russian)
Yatsuk, V. O., Malachivskyi, P. S. (2008). Methods for improving measurement accuracy. ‘Beskydbit’, Lviv, 368. (in Ukrainian)
Vasylykha, Kh. V. (2017). Improvement of the regulatory and technical base for testing solar converters
(Doctoral dissertation). Lviv, 203. (in Ukrainian)
Zhmakyn, L. Y., Kozyrev, Y. V., Kriukov, A. A. (2013). Solar water heaters made of textile materials.
Application of new textile and composite materials in technical textiles: scientific and practical conference 2013.
KSTU, Kazan, 199. (in Russian)
Shapoval, S. P. (2010). Efficiency of the ‘delta system’ of flat solar collectors at different angles of their
installation. Bulletin of the National University, Lviv, 664, 331–335. (in Ukrainian)
Pona, O. M. (2018). Improving the efficiency of a combined heat supply system with a solar roof (Doctoral
dissertation). Lviv, 200. (in Ukrainian)
Shapoval, S. P. (2010). Patent of Ukraine 53370. Kyiv: State Patent Office of Ukraine. (in Ukrainian)
Daffy, Dzh. A., Bekman U. A. (1977). Thermal processes using solar energy. Moscow, Myr, 420. (in Russian)
References (International): Smenkovskyi, A. Yu., Vorontsov, S. B., & Biehun S. V. (2012). Threats to Ukraine's energy security in the
face of increasing competition in global and regional energy markets. NISS, Kyiv, 136. (in Ukrainian)
Mysak, Y. S. (2014). Solar energy: theory and practice. Lviv, 340. (in Ukrainian)
Ukraine 2030 (2017). The doctrine of balanced development. Calvaria, Lviv, 164. (in Ukrainian)
Energy (2019): History, present and future. Retrieved from http://energetika.in.ua (11.2019). (in Ukrainian)
Pivniak, H. H., Shkrabets, F. P. (2013). Alternative energy in Ukraine. NGU, Dnipro, 109. (in Ukrainian)
European Photovoltaic Industry Association (2011), SG6: Solar photovoltaic electricity empowering the world.
Greenpeace International, 6. (in English)
Naraievskyi, S. V. (2017). Comparative characteristics of the efficiency of solar energy in the leading countries
of the world. Mukachevo state University, 10. (in Ukrainian)
Chwieduk, D. (2014). Solar Energy in Buildings. Thermal Balance for Efficient Heating and Cooling, USA, 362. (in English)
Zapryvoda, V. I. (2002). Geometric modeling of solar radiation receipt on the surface of spatial coatings of
architectural objects (Doctoral dissertation). Kyiv. (in Ukrainian)
Mathiesen, B. V., Lund, H., & Wenzel, H. (2015). Smart energy systems for coherent 100% renewable energy
and transport solutions. Applied Energy, 145, 139–154. (in English)
Sig Chai, D., Wena, J. Z., Nathwani, J. (2013). Simulation of cogeneration within the concept of smart energy
networks. Energy Convers Manage, 75, 453–465. (in English)
Lund, H., Andersen, A. N., & Connolly, D. (2012). From electricity smart grids to smart energy systems – a
market operation based approach and understanding. Energy, 42, 96–102. (in English)
Nakashydze, L. V., Shevchenko, M. V. (2017). Solar collectors – energy-active fences as an element of the air
conditioning system of buildings. Construction, materials science, mechanical engineering, 99. (in Ukrainian)
Kuvshynov, V. V. (2013). Methods for calculating and improving the efficiency of thermal photoelectric
installations. SNUNEI, Sevastopol, 2 (46), 166–171. (in Ukrainian)
Fryd, S. E. (1988). Methods of thermal testing of solar collectors. Moscow, JIHT USSR Academy of sciences,
p. 57. (in Russian)
Yatsuk, V. O., Malachivskyi, P. S. (2008). Methods for improving measurement accuracy. ‘Beskydbit’, Lviv, 368. (in Ukrainian)
Vasylykha, Kh. V. (2017). Improvement of the regulatory and technical base for testing solar converters
(Doctoral dissertation). Lviv, 203. (in Ukrainian)
Zhmakyn, L. Y., Kozyrev, Y. V., Kriukov, A. A. (2013). Solar water heaters made of textile materials.
Application of new textile and composite materials in technical textiles: scientific and practical conference 2013.
KSTU, Kazan, 199. (in Russian)
Shapoval, S. P. (2010). Efficiency of the ‘delta system’ of flat solar collectors at different angles of their
installation. Bulletin of the National University, Lviv, 664, 331–335. (in Ukrainian)
Pona, O. M. (2018). Improving the efficiency of a combined heat supply system with a solar roof (Doctoral
dissertation). Lviv, 200. (in Ukrainian)
Shapoval, S. P. (2010). Patent of Ukraine 53370. Kyiv: State Patent Office of Ukraine. (in Ukrainian)
Daffy, Dzh. A., Bekman U. A. (1977). Thermal processes using solar energy. Moscow, Myr, 420. (in Russian)
Content type: Article
Appears in Collections:Theory and Building Practice. – 2019. – Vol. 1, No. 1



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