Examination of the thermal efficiency of the solar collector integrated into the light transparent building facade

Шаповал, С. П.; Желих, В. М.; Венгрин, І. І.; Миронюк, Х. В.; Генсецький, М. П.; Shapoval, Stepan; Zhelykh, Vasyl; Venhryn, Iryna; Myroniuk, Khrystyna; Gensetskyi, Mykola

doi:doi.org/10.23939/jtbp2020.01.030

Please use this identifier to cite or link to this item: https://oldena.lpnu.ua/handle/ntb/55663

Title:	Examination of the thermal efficiency of the solar collector integrated into the light transparent building facade
Other Titles:	Визначення теплової ефективності сонячного колектора інтегрованого в світлопрозорий фасад будівлі
Authors:	Шаповал, С. П. Желих, В. М. Венгрин, І. І. Миронюк, Х. В. Генсецький, М. П. Shapoval, Stepan Zhelykh, Vasyl Venhryn, Iryna Myroniuk, Khrystyna Gensetskyi, Mykola
Affiliation:	Національний університет “Львівська політехніка” Lviv Polytechnic National University
Bibliographic description (Ukraine):	Examination of the thermal efficiency of the solar collector integrated into the light transparent building facade / Stepan Shapoval, Vasyl Zhelykh, Iryna Venhryn, Khrystyna Myroniuk, Mykola Gensetskyi // Theory and Building Practice. — Lviv : Lviv Politechnic Publishing House, 2020. — Vol 2. — No 1. — P. 30–37.
Bibliographic description (International):	Examination of the thermal efficiency of the solar collector integrated into the light transparent building facade / Stepan Shapoval, Vasyl Zhelykh, Iryna Venhryn, Khrystyna Myroniuk, Mykola Gensetskyi // Theory and Building Practice. — Lviv : Lviv Politechnic Publishing House, 2020. — Vol 2. — No 1. — P. 30–37.
Is part of:	Theory and Building Practice, 1 (2), 2020
Issue:	1
Issue Date:	10-Feb-2020
Publisher:	Видавництво Львівської політехніки Lviv Politechnic Publishing House
Place of the edition/event:	Львів Lviv
DOI:	doi.org/10.23939/jtbp2020.01.030
Keywords:	сонячне випромінювання сонячний колектор світлопрозорий фасад solar radiation solar collector light transparent facade
Number of pages:	8
Page range:	30-37
Start page:	30
End page:	37
Abstract:	Описано перспективність розвитку напрямку сонячної енергетики в Україні. Інтерес до ефективного використання сонячного випромінювання сонячними колекторами обґрунтовує актуальність і доцільність досліджень з проблеми використання в них такої енергії. Проаналізовано, що сонячна енергетика залишається найперспективнішим напрямком для генерації теплової енергії внаслідок: встановленого обсягу надходження сонячного випромінювання на територію України та зношеність технологічного обладнання, що працють на традиційному органічному паливі. Окрім цього, враховуючи тенденцію побудови скляних фасадів у галузі будівництва, в праці запропонованого сонячний колектор інтегрований в світлопрозорий фасад будівлі з метою економії площі, на яку встановлюються установки сонячних колекторів та збереження викопних видів палива. За інтенсивності імітованого сонячного випромінювання 900 Вт/м2, що потрапляло на поглинаючу поверхню сонячного колектора, температура на виході із сонячного колектора досягала 22,9 ºС. Порівнюючи зміни миттєвої потужності сонячного колектора Qск, Вт/м2 встановлено, що на 60 хв експерименту за інтенсивності імітованого сонячного випромінювання 900 Вт/м2, вона була більшою за 250 Вт/м2. Коефіцієнт корисної дії експериментального сонячного колектора в режимі прямотечії теплоносія в системі за інтенсивності імітованого сонячного випромінювання 900 Вт/м2 досягав ≈33 %. Встановлено, що запропонований сонячний колектор за інтенсивностей, що відповідатимуть потужності сонячного випромінювання в літній період року, в рeжимі прямотечії теплоносія через конструкцію соячного колектора є ефективним джерелом низькопотенційного тепло- постачання. Перспективним напрямом подальших досліджень залишається встановлення ефективності такого колектора за інших інтенсивностей імітованого сонячного випромінювання та за інших режимів роботи теплоносія через конструкцію сонячного колектора в системі сонячного теплопостачання. The work describes the prospects for the development of solar energy in Ukraine. Interest in the effective use of solar radiation by solar collectors justifies the relevance and expediency of research on the problem of using such energy in them. It is analyzed that solar energy remains a promising direction for generating thermal energy due to: the increased volume of solar radiation entering the territory of Ukraine and the wear or tear of technological equipment running on traditional organic fuel. Also, if taking into account the trend of building glass facades in the field of construction, in the work proposed solar collector which was integrated into the light transparent facade of the building. The solar collector model was developed for the purpose of in order to save space where solar collectors should be installed and to save fossil fuels. The temperature at the outlet of the solar collector reached 22.9 °C according to the intensity of the simulated solar radiation of 900 W/m2, which fell on the absorbing surface of the solar collector. Comparing the changes in the instantaneous power of the solar collector QSC, W/m2, it was found that at 60 minutes of the experiment was greater than 250 W/m2 under the intensity of the simulated solar radiation of 900W/m2. The efficiency of the experimental solar collector reached ≈33% in the direct heat carrier mode in the system according to the intensity of the simulated solar radiation. It was established, that the proposed solar collector in the mode of direct heat carrier was the effective source of low potential heat supply under intensities which could correspond to the power of solar radiation at summer time of the year. The promising direction for further research will be the efficiency establishing of the collector under simulated intensities of the solar radiation and other modes of operation of the heat carrier.
URI:	https://ena.lpnu.ua/handle/ntb/55663
Copyright owner:	© Національний університет “Львівська політехніка”, 2020 © Shapoval S., Zhelykh V., Venhryn I., Myroniuk Kh., Gensetskyi M., 2020
References (Ukraine):	Zolotko, K. (1998) Development of calculation methods and selection of rational parameters of heat supply systems with flat solar collectors. (Doctoral dissertation), 207. (in Russian) Mysak, Y., Vozniak, О., Datsko, О., Shapoval, S. (2014) Solar energy: theory and practice. Lviv Politechnic National University, 340. (in Ukrainian) Kutnyi, B., Osipa, M. (2014). Results of experimental studies of the solar collector. Collection of scientific papers, series: industrial engineering, construction of Poltava national technical University named after Yuri Kondratyuk, 1(40), 6. (in Ukrainian) Salvi, Swapnil & Bhalla, Vishal & Taylor, Robert & Khullar, Vikrant & Otanicar, Todd & Phelan, Patrick & Tyagi, Himanshu. (2018). Technological Advances to Maximize Solar Collector Energy Output: A Review. Journal of Electronic Packaging, 140. (in English) Vozniak, О., Shapoval, S., Pona, O., Venhryn, I. (2014) Influence of the direction and speed of the air flow on the operation of the solar collector without a transparent coating. Construction and technogenic safety, 50, 49–52. (in Ukrainian) Pasichnyk, P., Pryimak, O. (2013) Analysis of the properties of textile materials for the absorbing element of the solar energy collector. Energy efficiency in construction and architecture, 4, 201–204. (in Ukrainian) Syvoraksha, V., Zolotko, K., Markov, V., Petrov, B. (2001) Influence of the heat-sensing element design on the efficiency of the solar collector. Ecotechnologies and resource conservation, 2, 70–73. (in Russian) Zhelykh, V., Piznak, B. (2013) Comparative analysis of calculated models of polymer solar collectors. Energy efficiency in construction and architecture, 4, 109–113. (in Ukrainian) Shapoval, S., Zhelykh, V., Venhryn, I., & Kozak, K. (2020). Simulation of thermal processes in the solar collector which is combined with external fence of an energy efficient house. Proceedings of CEE 2019, Advances in Resource-saving Technologies and Materials in Civil and Environmental Engineering, 510–517. (in English) Filipowicz, M., Przenzak, E., Figaj, R. D. (2019). Building solar cooling systems based on thermally driven chillers as an alternative approach to classic electrical cooling systems. Construction of optimized energy potential, (1), 67–76. (in English) Khotin, S. (2001) Development and research of a concentrating collector with vacuumed heat sinks. (Doctoral dissertation). (in Ukrainian) Buonomano, A., Calise, F., Palombo, A. (2018). Solar heating and cooling systems by ab-sorption and adsorption chillers driven by stationary and concentrating photovolta-ic/thermal solar collectors: Modelling and simulation. Renewable and Sustainable Energy Reviews 82 (2), 1874–1908. (in English) Lamnatou, C., Mondol, J., Chemisana, D., Maurer C. (2015). Modelling and simulation of Building- Integrated solar thermal systems: Behaviour of the system. Renewable and Sus-tainable Energy Reviews 45, 36–51. (in English) Shapoval, S., Shapoval, P., Zhelykh, V., Pona, O., Spodyniuk, N., Gulai, B., Myroniuk, K. (2017). Ecological and energy aspects of using the combined solar collectors for low-energy houses. Chemistry and Chemical Technology, 11(4), 503–508. (in English) Venhryn, I. (2019) Research of solar collectors integrated into the construction of the glass facade of a building / construction: necessity and features. Theory and Building Practice, 38–46. (in Ukrainian)
References (International):	Zolotko, K. (1998) Development of calculation methods and selection of rational parameters of heat supply systems with flat solar collectors. (Doctoral dissertation), 207. (in Russian) Mysak, Y., Vozniak, O., Datsko, O., Shapoval, S. (2014) Solar energy: theory and practice. Lviv Politechnic National University, 340. (in Ukrainian) Kutnyi, B., Osipa, M. (2014). Results of experimental studies of the solar collector. Collection of scientific papers, series: industrial engineering, construction of Poltava national technical University named after Yuri Kondratyuk, 1(40), 6. (in Ukrainian) Salvi, Swapnil & Bhalla, Vishal & Taylor, Robert & Khullar, Vikrant & Otanicar, Todd & Phelan, Patrick & Tyagi, Himanshu. (2018). Technological Advances to Maximize Solar Collector Energy Output: A Review. Journal of Electronic Packaging, 140. (in English) Vozniak, O., Shapoval, S., Pona, O., Venhryn, I. (2014) Influence of the direction and speed of the air flow on the operation of the solar collector without a transparent coating. Construction and technogenic safety, 50, 49–52. (in Ukrainian) Pasichnyk, P., Pryimak, O. (2013) Analysis of the properties of textile materials for the absorbing element of the solar energy collector. Energy efficiency in construction and architecture, 4, 201–204. (in Ukrainian) Syvoraksha, V., Zolotko, K., Markov, V., Petrov, B. (2001) Influence of the heat-sensing element design on the efficiency of the solar collector. Ecotechnologies and resource conservation, 2, 70–73. (in Russian) Zhelykh, V., Piznak, B. (2013) Comparative analysis of calculated models of polymer solar collectors. Energy efficiency in construction and architecture, 4, 109–113. (in Ukrainian) Shapoval, S., Zhelykh, V., Venhryn, I., & Kozak, K. (2020). Simulation of thermal processes in the solar collector which is combined with external fence of an energy efficient house. Proceedings of CEE 2019, Advances in Resource-saving Technologies and Materials in Civil and Environmental Engineering, 510–517. (in English) Filipowicz, M., Przenzak, E., Figaj, R. D. (2019). Building solar cooling systems based on thermally driven chillers as an alternative approach to classic electrical cooling systems. Construction of optimized energy potential, (1), 67–76. (in English) Khotin, S. (2001) Development and research of a concentrating collector with vacuumed heat sinks. (Doctoral dissertation). (in Ukrainian) Buonomano, A., Calise, F., Palombo, A. (2018). Solar heating and cooling systems by ab-sorption and adsorption chillers driven by stationary and concentrating photovolta-ic/thermal solar collectors: Modelling and simulation. Renewable and Sustainable Energy Reviews 82 (2), 1874–1908. (in English) Lamnatou, C., Mondol, J., Chemisana, D., Maurer C. (2015). Modelling and simulation of Building- Integrated solar thermal systems: Behaviour of the system. Renewable and Sus-tainable Energy Reviews 45, 36–51. (in English) Shapoval, S., Shapoval, P., Zhelykh, V., Pona, O., Spodyniuk, N., Gulai, B., Myroniuk, K. (2017). Ecological and energy aspects of using the combined solar collectors for low-energy houses. Chemistry and Chemical Technology, 11(4), 503–508. (in English) Venhryn, I. (2019) Research of solar collectors integrated into the construction of the glass facade of a building, construction: necessity and features. Theory and Building Practice, 38–46. (in Ukrainian)
Content type:	Article
Appears in Collections:	Theory and Building Practice. – 2020. – Vol. 2, No. 1

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