An algorithm for calculating the shade created by greenhouse integrated photovoltaics

Theodoros Petrakis , Vasileios Thomopoulos , Angeliki Kavga , Athanassios A. Argiriou

Energy, Ecology and Environment ›› 2024, Vol. 9 ›› Issue (3) : 272 -300.

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Energy, Ecology and Environment ›› 2024, Vol. 9 ›› Issue (3) : 272 -300. DOI: 10.1007/s40974-023-00306-4
Original Article

An algorithm for calculating the shade created by greenhouse integrated photovoltaics

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Abstract

Integration of photovoltaic modules into greenhouse roofs is a novel and intriguing method. The cost of products grown in greenhouses is particularly high because of their high energy consumption for heating and cooling, and at the same time the increase in demand for available land, increasing its cost and creating spatial issues, the integration of photovoltaics on the roof of greenhouses is a highly viable solution. Simultaneously, the use of solar radiation is critical to maintain optimal crop development, while also being a renewable energy source. However, photovoltaics reduce the incoming solar radiation in the greenhouse, due to their shade. Shading can be either beneficial for the crops or not, depending on the crop type, thus it is vital to find the shading caused by photovoltaics both temporally and spatially. In this study, a model calculating the shading in a greenhouse due to roof-integrated photovoltaics is developed, based on the Sun position, the geometry of both the greenhouse and of the roof-integrated photovoltaics and their position on the greenhouse roof. Calculating the coefficient of variation of radiation data, for the shaded and unshaded areas using the proposed algorithm, it was found the coefficient of variation for the shaded areas is lower than that for the unshaded areas for a least 76% of the time. Also, the radiation values under the shaded area are more uniform. The proposed model is a tool for PV designers, operators, and owners, in order to optimize the potential of their solar panel installations.

Keywords

Shading / Photovoltaics / Greenhouses / Agrivoltaics / Algorithm

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Theodoros Petrakis, Vasileios Thomopoulos, Angeliki Kavga, Athanassios A. Argiriou. An algorithm for calculating the shade created by greenhouse integrated photovoltaics. Energy, Ecology and Environment, 2024, 9(3): 272-300 DOI:10.1007/s40974-023-00306-4

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Ahemd HA, Al-Faraj AA, Abdel-Ghany AM. Shading greenhouses to improve the microclimate, energy and water saving in hot regions: A review. Sci Horticult, 2016, 201: 36-45

[2]

Aira JR, Gallardo-Saavedra S, Eugenio-Gozalbo M Analysis of the viability of a photovoltaic greenhouse with semi-transparent amorphous silicon (a-si) glass. Agronomy, 2021, 11(6): 1097

[3]

Anderson K, Mikofski M. Slope-aware backtracking for single-axis trackers. Tech Rep, 2020

[4]

Angmo P, Phuntsog N, Namgail D, et al (2021) Effect of shading and high temperature amplitude in greenhouse on growth, photosynthesis, yield and phenolic contents of tomato (lycopersicum esculentum mill.). Physiol Molecul Biol Plants 27(7):1539–1546. https://doi.org/10.1007/s12298-021-01032-z
[5]

Arias-Rosales A, LeDuc PR. Shadow modeling in urban environments for solar harvesting devices with freely defined positions and orientations. Renew Sustain Energy Rev, 2022, 164

[6]

Barron-Gafford GA, Pavao-Zuckerman MA, Minor RL Agrivoltaics provide mutual benefits across the food-energy-water nexus in drylands. Nature Sustain, 2019, 2(9): 848-855

[7]

Baxevanou C, Fidaros D, Katsoulas N Simulation of radiation and crop activity in a greenhouse covered with semitransparent organic photovoltaics. Appl Sci, 2020, 10(7): 2550

[8]

Blando F, Gerardi C, Renna M Characterisation of bioactive compounds in berries from plants grown under innovative photovoltaic greenhouses. J Berry Res, 2018, 8(1): 55-69

[9]

Carlini M, Castellucci S, Mennuni A Numerical modeling and simulation of pitched and curved-roof solar greenhouses provided with internal heating systems for different ambient conditions. Energy Rep, 2020, 6: 146-154

[10]

Colin Koeniguer E, Nicolas JM. Change detection based on the coefficient of variation in sar time-series of urban areas. Remote Sens, 2020

[11]

Cossu M, Ledda L, Urracci G An algorithm for the calculation of the light distribution in photovoltaic greenhouses. Solar Energy, 2017, 141: 38-48

[12]

Cossu M, Cossu A, Deligios PA Assessment and comparison of the solar radiation distribution inside the main commercial photovoltaic greenhouse types in europe. Renew Sustain Energy Rev, 2018, 94: 822-834

[13]

Cossu M, Yano A, Solinas S Agricultural sustainability estimation of the European photovoltaic greenhouses. Eur J Agron, 2020, 118

[14]

de Sá BA, Dezuo T, Ohf D. Shadow modelling algorithm for photovoltaic systems: extended analysis and simulation. J Control Autom Electr Syst, 2022, 33: 1507-1518

[15]

Dean JC, Kusaka R, Walsh PS Plant sunscreens in the uv-b: ultraviolet spectroscopy of jet-cooled sinapoyl malate, sinapic acid, and sinapate ester derivatives. J Am Chem Soc, 2014, 136(42): 14780-14795

[16]

Duffie JA, Beckman WA, Blair N (2020) Solar radiation. In: Duffie JA, Beckman WA, Blair N (eds) Solar Engineering of Thermal Processes, Photovoltaics and Wind, 5th edn. John Wiley & Sons, Inc, Hoboken, New Jersey, p 3–44, https://doi.org/10.1002/9781118671603.ch1
[17]

Ezzaeri K, Fatnassi H, Wifaya A Performance of photovoltaic canarian greenhouse: a comparison study between summer and winter seasons. Solar Energy, 2020, 198: 275-282

[18]

Fernández-Ahumada LM, Ramírez-Faz J, López-Luque R A novel backtracking approach for two-axis solar pv tracking plants. Renew Energy, 2020, 145: 1214-1221

[19]

Hassanien RHE, Li M. Influences of greenhouse-integrated semi-transparent photovoltaics on microclimate and lettuce growth. Int J Agri Biol Eng, 2017, 10(6): 11-22

[20]

Hassanien RHE, Li M, Yin F. The integration of semi-transparent photovoltaics on greenhouse roof for energy and plant production. Renew Energy, 2018, 121: 377-388

[21]

Hemming S, de Zwart F, Elings A Remote control of greenhouse vegetable production with artificial intelligence-greenhouse climate, irrigation, and crop production. Sensors, 2019, 19(8): 1807

[22]

Iqbal M (1983) Chapter 1 - sun-earth astronomical relationships. In: Iqbal M (ed) An Introduction to Solar Radiation. Academic Press, p 1–28, https://doi.org/10.1016/B978-0-12-373750-2.50006-9
[23]

Isied RS, Mengi E, Zohdi TI (2022) A digital-twin framework for genomic-based optimization of an agrophotovoltaic greenhouse system. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 478(2267). https://doi.org/10.1098/rspa.2022.0414
[24]

Jin D, Su X, Li Y, et al (2023) Effect of red and blue light on cucumber seedlings grown in a plant factory. Horticulturae 9(2). https://doi.org/10.3390/horticulturae9020124, https://www.mdpi.com/2311-7524/9/2/124
[25]

Kavga A, Trypanagnostopoulos G, Zervoudakis G, et al (2018) Growth and physiological characteristics of lettuce (Lactuca sativa l.) and rocket (Eruca sativa mill.) plants cultivated under photovoltaic panels. Notulae Botanicae Horti Agrobotanici Cluj-Napoca 46(1):206–212. https://doi.org/10.15835/nbha46110846
[26]

Kim HK, Lee SY, Kwon JK Evaluating the effect of cover materials on greenhouse microclimates and thermal performance. Agronomy, 2022

[27]

Kitta E, Katsoulas N (2020) Effect of shading on photosynthesis of greenhouse hydroponic cucumber crops. Ital J Agrometeorol (1):41-48. https://doi.org/10.13128/ijam-871
[28]

Krüger H, Grün E (2014) Chapter 29 - dust in the solar system. In: Spohn T, Breuer D, Johnson TV (eds) Encyclopedia of the Solar System (Third Edition), third edition edn. Elsevier, Boston, p 657–682, https://doi.org/10.1016/B978-0-12-415845-0.00029-3
[29]

Liu J, van Iersel M. Photosynthetic physiology of blue, green, and red light: Light intensity effects and underlying mechanisms. Front Plant Sci, 2021, 12

[30]

López-Díaz G, Carreño-Ortega Ángel, Fatnassi H The effect of different levels of shading in a photovoltaic greenhouse with a north-south orientation. Appl Sci, 2020, 10(3): 882

[31]

Ma DD, Carpenter NR, Maki H Greenhouse environment modeling and simulation for microclimate control. Comput Electron Agri, 2019, 162: 134-142

[32]

Moretti S, Marucci A. A photovoltaic greenhouse with variable shading for the optimization of agricultural and energy production. Energies, 2019, 12(13): 2589

[33]

Pälike H (2005) Earth | orbital variation (including milankovitch cycles). In: Selley RC, Cocks LRM, Plimer IR (eds) Encyclopedia of Geology. Elsevier, Oxford, p 410–421, https://doi.org/10.1016/B0-12-369396-9/00123-4
[34]

Reed GF, Lynn F, Meade BD (2002) Use of coefficient of variation in assessing variability of quantitative assays. Clin Vaccine Immunol 9(6):1235–1239. https://doi.org/10.1128/cdli.9.6.1235-1239.2002
[35]

Rosa-Clot M, Tina GM (2018) Chapter 2 - photovoltaic electricity. In: Rosa-Clot M, Tina GM (eds) Submerged and Floating Photovoltaic Systems. Academic Press, p 13–32, https://doi.org/10.1016/B978-0-12-812149-8.00002-8
[36]

Roxani A, Zisos A, Sakki GK Multidimensional role of agrovoltaics in era of eu green deal: Current status and analysis of water; energy; food; land dependencies. Land, 2023

[37]

Salgado-Conrado L, Lopez-Montelongo A, Alvarez-Macías C Review of heliodon developments and computational tools for building shadow analysis. Buildings, 2022, 12(5): 627

[38]

Shin J, Hwang I, Kim D Evaluation of the light profile and carbon assimilation of tomato plants in greenhouses with respect to film diffuseness and regional solar radiation using ray-tracing simulation. Agric For Meteorol, 2021, 296

[39]

Snee RD. Validation of regression models: methods and examples. Technometrics, 1977, 19(4): 415-428

[40]

Spencer JW. Fourier series representation of the position of the sun. Search, 1971, 2: 162-172
[41]

Sun W, Wei X, Zhou B Greenhouse heating by energy transfer between greenhouses: system design and implementation. Appl Energy, 2022, 325

[42]

Tang Y, Ma X, Li M The effect of temperature and light on strawberry production in a solar greenhouse. Solar Energy, 2020, 195: 318-328

[43]

Trommsdorff M, Kang J, Reise C Combining food and energy production: Design of an agrivoltaic system applied in arable and vegetable farming in germany. Renew Sustain Energy Rev, 2021, 140

[44]

Waller R, Kacira M, Magadley E et al (2021) Semi-transparent organic photovoltaics applied as greenhouse shade for spring and summer tomato production in arid climate. Agronomy 11(6):1152. https://doi.org/10.3390/agronomy11061152
[45]

Waller R, Kacira M, Magadley E Evaluating the performance of flexible, semi-transparent large-area organic photovoltaic arrays deployed on a greenhouse. AgriEngineering, 2022, 4(4): 969-992

[46]

Wang Z (2019) Chapter 2 - the solar resource and meteorological parameters. In: Wang Z (ed) Design of Solar Thermal Power Plants. Academic Press, p 47–115, https://doi.org/10.1016/B978-0-12-815613-1.00002-X
[47]

Xu G, Xu J (2013) Keplerian Orbits, Springer Berlin Heidelberg, Berlin, Heidelberg, pp 27–38. https://doi.org/10.1007/978-3-642-32793-3_3
[48]

Yano A, Cossu M. Energy sustainable greenhouse crop cultivation using photovoltaic technologies. Renew Sustain Energy Rev, 2019, 109: 116-137

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