Thermal efficiency analysis of solar heat supply unit combined with glass facade of building

dc.citation.epage6
dc.citation.issue1
dc.citation.spage1
dc.contributor.affiliationНаціональний університет “Львівська політехніка”
dc.contributor.affiliationLviv Polytechnic National University
dc.contributor.authorВенгрин, Ірина
dc.contributor.authorШаповал, Степан
dc.contributor.authorФурдас, Юрій
dc.contributor.authorКасинець, Мар’яна
dc.contributor.authorПізнак, Богдан
dc.contributor.authorVenhryn, Iryna
dc.contributor.authorShapoval, Stepan
dc.contributor.authorFurdas, Yurij
dc.contributor.authorKasynets, Mariana
dc.contributor.authorPiznak, Bohdan
dc.coverage.placenameЛьвів
dc.coverage.placenameLviv
dc.date.accessioned2023-09-14T07:56:02Z
dc.date.available2023-09-14T07:56:02Z
dc.date.created2021-06-01
dc.date.issued2021-06-01
dc.description.abstractУ статті наголошено на розвитку нетрадиційних джерел енергії в Україні. Заакцентовано на потребі вдосконалення існуючих сонячних колекторів та суміщення цих установок із конструкціями зовнішнього огородження для енергоефективних будівель. Враховуючи популярність будівництва із збільшеною площею засклення, запропоновано конструкцію сонячного колектора, суміщеного із скляним фасадом будівлі. Наведено дані щодо зміни приросту температури теплоносія на виході із сонячного колектора. Досліджено, що розроблена модель сонячного колектора дозволяє генерувати 132 Вт/м 2 за дії імітованого інтенсивності сонячної енергії 300 Вт/м 2. Досліджено, що сонячний колектор, суміщений із скляним фасадом будівлі, має ефективність 43 %. Така ефективність буде відповідною для теплопостачання в хмарні дні або ж у період ранкового чи вечірнього теплопостачання, тобто не за максимуму надходження сонячної енергії на конструкцію сонячного колектора.
dc.description.abstractThe work notes the development of non-traditional energy sources in Ukraine. There is a need to improve existing solar collectors and combine these units with structures of external fencing for energy-efficient buildings. Taking into account the popularity of construction with an increased area of glazing, the paper suggests the design of solar collector combined with the glass facade of the building. It gives data about change of the heat carrier temperature at the outlet of the solar collector. It was investigated that the developed model of the solar collector allows generating 132 W/m2 under the effect of the simulated solar energy intensity of 300 W/m2 . Also, it was studied that the solar collector combined with the glass facade of the building has an average thermal efficiency of 43 %. This efficiency was achieved for cloudy days or for morning and evening heat supply, i.e. when the incoming solar energy to the solar collector is not maximal.
dc.format.extent1-6
dc.format.pages6
dc.identifier.citationThermal efficiency analysis of solar heat supply unit combined with glass facade of building / Iryna Venhryn, Stepan Shapoval, Yurij Furdas, Mariana Kasynets, Bohdan Piznak // Energy Engineering and Control Systems. — Lviv : Lviv Politechnic Publishing House, 2020. — Vol 6. — No 1. — P. 1–6.
dc.identifier.citationenThermal efficiency analysis of solar heat supply unit combined with glass facade of building / Iryna Venhryn, Stepan Shapoval, Yurij Furdas, Mariana Kasynets, Bohdan Piznak // Energy Engineering and Control Systems. — Lviv : Lviv Politechnic Publishing House, 2020. — Vol 6. — No 1. — P. 1–6.
dc.identifier.urihttps://ena.lpnu.ua/handle/ntb/59993
dc.language.isoen
dc.publisherВидавництво Львівської політехніки
dc.publisherLviv Politechnic Publishing House
dc.relation.ispartofEnergy Engineering and Control Systems, 1 (6), 2020
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dc.relation.references[10] Lepekh A. (2017) Overview of solar radiation databases. International scientific and technical journal “Modern problems of electro-energy engineering and automation”, рр. 583–584. (in Ukrainian)
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dc.relation.references[12] Trethewey M., Ross M. (2004) Residential building solar thermal analysis. A case study on Sophia Gordon Hall Tufts University, in partial fulfillment of the requirements for the degree of Master of Technology, p. 96.
dc.relation.references[13] Archibald J. (1999) Building Integrated Solar Thermal Roofing Systems History, Current Status and Future Promise. American Solar Roofing Company, p. 6.
dc.relation.references[14] Shapoval S. (2015) Comparison of the results of researching the gelioroof in field and laboratory conditions. Eastern European Journal of Enterprise Technologies, 2/5 (74), pp. 41–45.
dc.relation.references[15] Pluta Z. (2007) Solar energy installations. Publishing house of Warsaw University of Technology, p. 246. (in Polish)
dc.relation.references[16] Zawadzki M. (2003) Solar collectors. Heat pumps. Polish Ecology, p. 276. (in Polish).
dc.relation.references[17] Roger G. Gregoire, P. (1984) Understanding solar food dryers. Volunteers in Technical Assistance, p. 27.
dc.relation.references[18] Patent No. 4201193 (1980). Solar energy absorbing roof.
dc.relation.references[19] Dyb M. (2013) Determination of the optimal angle of inclination of solar receivers in Ukraine. State research Institute of building structures, pp. 217–221. (in Russian)
dc.relation.references[20] Shapoval S., Shapoval P., Zhelykh V., Pona O., Spodyniuk N. & Gulai B. (2017) Ecological and energy aspects of using the combined solar collectors for low-energy houses. Chemistry and Chemical Technology, 11(4), pp. 503–508.
dc.relation.references[21] Florio P., Teissier O. (2015). Estimation of the Energy Performance Certificate of a housing stock characterized via qualitative variables through a typology-based approach model: a fuel poverty evaluation tool. Energy Build, 89, рр. 39–48.
dc.relation.references[22] Kragh J., Wittchen K. (2014) Development of two Danish building typologies for residential buildings. Energy Build, 68, pp. 79–86.
dc.relation.references[23] Shamryna H., Kryvenko E. (2012) Implementation of modern trends in the design of multi-comfort passive houses on the example of architectural objects in the UK. Buildings and structures using new materials and technologies, 3, pp. 85–89. (in Russian)
dc.relation.references[24] Voznyak O., Shapoval S., Pona O., Venhryn I. (2014) Combined solar collector. Bulletin of Lviv Polytechnic National University. Theory and practice of construction, 781, pp. 212–215.
dc.relation.references[25] Shapoval S. (2015) Analysis of efficiency of solar stress coverings. Water and heat supply, air conditioning, 1, pp. 16–18. (in Slovak)
dc.relation.references[26] Shapoval S., Zhelykh V., Venhryn I., Kozak Kh., Krygul R. (2019) Theoretical and experimental analysis of solar enclosure as part of energy efficient house. Eastern-European Journal of Enterprise Technologies, 2/8 (98), pp. 38–46.
dc.relation.referencesen[1] Barzylovych D., Fareniuk H. (2013) Development of the system of normative documents of Ukraine on ensuring energy saving and energy efficiency of buildings. Building construction, 77, pp. 3−9. (in Ukrainian)
dc.relation.referencesen[2] Zaremba I. (2002) International cooperation of Ukraine in the field of energy in the context of energy security. Strategic panorama, 4, pp. 2–5. (in Ukrainian)
dc.relation.referencesen[3] Solar power for two thousand homes. (2008) Green energy, 4 (32), p. 25. (in Ukrainian)
dc.relation.referencesen[4] Holitsyn M., Holitsyn A., Pronina N. (2004) Alternative energy carriers, 159. (in Russian)
dc.relation.referencesen[5] Perlin J. (2013) Let It Shine: The 6,000-Year Story of Solar Energy. New World Library, 519.
dc.relation.referencesen[6] Tuiakhov O. (2007) Renewable and alternative energy sources. Weber, Donetsk, 184. (in Russian)
dc.relation.referencesen[7] Shcherbyna O. (2007) Energy for everyone. Publishing house Padiaka V., 340. (in Ukrainian)
dc.relation.referencesen[8] Braiers T. (1988) 20 structures with solar cells. Myr, 197. (in Russian)
dc.relation.referencesen[9] Zhelykh V., Shapoval S., Venhryn I. (2014) The potential of solar energy in Ukraine for use by low-temperature solar panels. Lviv Polytechnic publishing house, r. 82. (in Ukrainian)
dc.relation.referencesen[10] Lepekh A. (2017) Overview of solar radiation databases. International scientific and technical journal "Modern problems of electro-energy engineering and automation", rr. 583–584. (in Ukrainian)
dc.relation.referencesen[11] Stepanenko O., Dubrovska V. (2014) A passive house is the way to energy efficient use of energy. "Energy: economy, technology, ecology", 3. (in Ukrainian)
dc.relation.referencesen[12] Trethewey M., Ross M. (2004) Residential building solar thermal analysis. A case study on Sophia Gordon Hall Tufts University, in partial fulfillment of the requirements for the degree of Master of Technology, p. 96.
dc.relation.referencesen[13] Archibald J. (1999) Building Integrated Solar Thermal Roofing Systems History, Current Status and Future Promise. American Solar Roofing Company, p. 6.
dc.relation.referencesen[14] Shapoval S. (2015) Comparison of the results of researching the gelioroof in field and laboratory conditions. Eastern European Journal of Enterprise Technologies, 2/5 (74), pp. 41–45.
dc.relation.referencesen[15] Pluta Z. (2007) Solar energy installations. Publishing house of Warsaw University of Technology, p. 246. (in Polish)
dc.relation.referencesen[16] Zawadzki M. (2003) Solar collectors. Heat pumps. Polish Ecology, p. 276. (in Polish).
dc.relation.referencesen[17] Roger G. Gregoire, P. (1984) Understanding solar food dryers. Volunteers in Technical Assistance, p. 27.
dc.relation.referencesen[18] Patent No. 4201193 (1980). Solar energy absorbing roof.
dc.relation.referencesen[19] Dyb M. (2013) Determination of the optimal angle of inclination of solar receivers in Ukraine. State research Institute of building structures, pp. 217–221. (in Russian)
dc.relation.referencesen[20] Shapoval S., Shapoval P., Zhelykh V., Pona O., Spodyniuk N. & Gulai B. (2017) Ecological and energy aspects of using the combined solar collectors for low-energy houses. Chemistry and Chemical Technology, 11(4), pp. 503–508.
dc.relation.referencesen[21] Florio P., Teissier O. (2015). Estimation of the Energy Performance Certificate of a housing stock characterized via qualitative variables through a typology-based approach model: a fuel poverty evaluation tool. Energy Build, 89, rr. 39–48.
dc.relation.referencesen[22] Kragh J., Wittchen K. (2014) Development of two Danish building typologies for residential buildings. Energy Build, 68, pp. 79–86.
dc.relation.referencesen[23] Shamryna H., Kryvenko E. (2012) Implementation of modern trends in the design of multi-comfort passive houses on the example of architectural objects in the UK. Buildings and structures using new materials and technologies, 3, pp. 85–89. (in Russian)
dc.relation.referencesen[24] Voznyak O., Shapoval S., Pona O., Venhryn I. (2014) Combined solar collector. Bulletin of Lviv Polytechnic National University. Theory and practice of construction, 781, pp. 212–215.
dc.relation.referencesen[25] Shapoval S. (2015) Analysis of efficiency of solar stress coverings. Water and heat supply, air conditioning, 1, pp. 16–18. (in Slovak)
dc.relation.referencesen[26] Shapoval S., Zhelykh V., Venhryn I., Kozak Kh., Krygul R. (2019) Theoretical and experimental analysis of solar enclosure as part of energy efficient house. Eastern-European Journal of Enterprise Technologies, 2/8 (98), pp. 38–46.
dc.rights.holder© Національний університет “Львівська політехніка”, 2020
dc.subjectсонячний колектор
dc.subjectскляний фасад будівлі
dc.subjectтемпература теплоносія
dc.subjectтеплова ефективність
dc.subjectенергоефективний будинок
dc.subjectsolar collector
dc.subjectglass facade of building
dc.subjecttemperature of heat carrier
dc.subjectthermal efficiency
dc.subjectenergyefficient house
dc.titleThermal efficiency analysis of solar heat supply unit combined with glass facade of building
dc.title.alternativeАналіз теплової ефективності установки сонячного теплопостачання, суміщеної із конструкцією світлопрозорого фасаду будівлі
dc.typeArticle

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