Warianty tytułu
Metodyczne aspekty wyznaczania parametrów charakteryzujących bilans cieplny tunelu foliowego
Języki publikacji
Abstrakty
W pracy przedstawiono metodykę do wyznaczania wielkości charakteryzujące bilans cieplny w obiekcie ogrodniczym. Szczegółowej analizie poddano współczynnik przenikania ciepła przez transparentną osłonę tunelu foliowego oraz współczynnik konwersji energii promieniowania słonecznego w ciepło. Badania przeprowadzono w rzeczywistym obiekcie przy zamkniętych wietrznikach, w którym podczas badań nie uprawiano roślin. Powierzchnia użytkowa tunelu wynosiła 144 m2, osłony 289 m2, zaś jego pojemność była równa 508 m3(abstrakt oryginalny)
The paper presents methodology of measuring the values which characterize the thermal balance in a horticultural facility. Thermal transmittance through a plastic tunnel cover and the ratio of solar radiation energy conversion into heat were analysed in detail. The research was carried out in real time with closed ventilators, where no plants were cultivated during the tests. The utility surface area was 144 m2, the cover was 289 m2 and its volume was 508 m3.(original abstract)
Twórcy
autor
- University of Agriculture in Cracow, Poland
autor
- University of Agriculture in Cracow, Poland
autor
- University of Agriculture in Krakow
Bibliografia
- Abdel-Ghany, A.M. (2011). Solar energy conversions in the greenhouses. Sustainable Cities and Society, Vol. 1, 219-226.
- Al-Helal, I.M., Abdel-Ghany, A.M. (2011). Energy partition and conversion of solar and thermal radiation into sensible and latent heat in a greenhouse under arid conditions. Energy and Buildings, Vol. 43, 1740-1747.
- Cabrera, F.J., Baille, A., Lopez, J.C., Gonzalez-Real, M.M., Perez-Parra, J. (2009). Effects of cover diffusive properties on the components of greenhouse solar radiation. Biosystems Engineering, Vol. 103, 344-356.
- Canakci, M., Emekli, N.Y., Bilgin, S., Caglayan, N. (2013). Heating requirement and its costs in greenhouse structures: A case study for Mediterranean region of Turkey. Renewable and Sustainable Energy Reviews, Vol. 24, 483-490.
- El-Maghlany, W.M., Teamah, M.A., Tanaka, H., (2015). Optimum design and orientation of the greenhouses for maximum capture of solar energy in North Tropical Region. Energy Conversion and Management, Vol. 105, 1096-1104.
- Hassanien, R., H. E., Li, M., Lin, W.D. (2016). Advanced applications of solar energy in agricultural greenhouses. Renewable and Sustainable Energy Reviews, Vol. 54, 989-1001.
- Kurpaska, S. (2014). Energy effects during using the glass with different properties in a heated greenhouse. Technical Sciences, Vol. 17(4), 351-360.
- Kurpaska, S. (2007). Szklarnie i tunele foliowe. Inżynieria i procesy. PWRiL, Poznań. ISBN 978-83-09-01024-1.
- Lamnatou, Chr., Chemisana, D., (2013). Solar radiation manipulations and their role in greenhouse claddings: Fresnel lenses, NIR- and UV-blocking materials. Renewable and Sustainable Energy Reviews, Vol. 18, 271-287.
- Martinovic, G., Simon, J., (2014). Greenhouse microclimatic environment controlled by a mobile measuring station. NJAS - Wageningen. Journal of Life Sciences, Vol. 70-71, 61-71.
- Ntinas, G.K., Fragos, V.P., Nikita-Martzopoulou, Ch. (2014). Thermal analysis of a hybrid solar energy saving system inside a greenhouse. Energy Conversion and Management, Vol. 81 428-439.
- Raczek, A., Wachowicz, E. (2014). Heat and mass exchange model in the air inside a greenhouse. Agricultural Engineering. Vol. 149, 185-195.
- Singh, D., Basu, Ch., Meinhardt-Wollweber, M., Roth, B. (2015). LEDs for Energy Efficient Greenhouse Lighting. Renewable and Sustainable Energy Reviews, Vol. 49, 139-147.
- Vadiee, A., Martin, V. (2014). Energy management strategies for commercial greenhouses. Applied Energy, Vol. 114, 880-888.
Typ dokumentu
Bibliografia
Identyfikatory
Identyfikator YADDA
bwmeta1.element.ekon-element-000171494930