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Technical and economic analysis and assessment of the possibility of building an agrophotovoltaic installation based on an existing solar power plant
Języki publikacji
Abstrakty
Celem pracy jest wykazanie wielowymiarowych korzyści wynikających ze zbudowania systemu fotowoltaicznego na terenach rolnych przeznaczonych pod uprawę szparagów. Przeprowadzone zostaną analizy energetyczne, agronomiczne oraz ekonomiczne. Na potrzeby szeroko zakrojonych analiz energetycznych wykorzystane będą dane nasłonecznienia i produkcji energii elektrycznej pochodzące z istniejącej elektrowni słonecznej położonej na terenie zachodniej Ukrainy. Analiza agronomiczna z kolei obejmie dogłębną analizę warunków uprawy szparagów na żyznych ziemiach ukraińskich z uwzględnieniem warunków pogodowych, jakości gleby oraz potrzeb nawadniania roślin. Istotną częścią pracy będzie również analiza ekonomiczna określająca opłacalność przeprowadzenia inwestycji budowy farmy agrofotowoltaicznej. Kalkulacje ekonomiczne przeprowadzone będą na podstawie analizy średnich cen energii elektrycznej oraz cen skupu szparagów, obowiązujących dla rynku ukraińskiego. W podsumowaniu pracy zaproponowane zostaną również możliwe sposoby usprawnienia systemu agrofotowoltaicznego oraz uzasadnienie takiego wyboru.
The aim of the paper is to demonstrate the multidimensional benefits resulting from building a photovoltaic system in agricultural areas intended for asparagus cultivation. Energy, agronomic and economic analyzes will be conducted. For the purposes of extensive energy analyses, solar irradiation and energy production data from an existing solar power plant located in western Ukraine will be used. The agronomic analysis, in turn, will include an in-depth analysis of the conditions for growing asparagus in fertile Ukrainian lands, taking into account weather conditions, soil quality and plant irrigation needs. An important part of this paper will also be an economic analysis determining the profitability of the investment in building an agrophotovoltaic farm. Economic calculations will be made based on the analysis of average electricity prices and asparagus purchase prices applicable to the Ukrainian market. Economic calculations will be carried out on the basis of an analysis of average electricity prices and asparagus purchase prices applicable to the Ukrainian market. The summary of the work will also propose possible ways to improve the agrophotovoltaic system and justify such a choice.
Wydawca
Czasopismo
Rocznik
Tom
Strony
233--238
Opis fizyczny
Bibliogr. 30 poz., rys., tab.
Twórcy
autor
- Politechnika Poznańska, Instytut Elektrotechniki i Elektroniki Przemysłowej, ul. Piotrowo 3a, 60-965 Poznań
autor
- Politechnika Poznańska, Instytut Elektrotechniki i Elektroniki Przemysłowej, ul. Piotrowo 3a, 60-965 Poznań
autor
- Politechnika Poznańska, Instytut Elektrotechniki i Elektroniki Przemysłowej, ul. Piotrowo 3a, 60-965 Poznań
autor
- Politechnika Lwowska, Instytut Energetyki i Systemów Sterowania, ul. S. Bandery 12, 79-013 Lwów
Bibliografia
- [1] Blankenship R., Tiede D., Barber J., W. Brudvig G., Fleming G., Ghirardi M., Gunner M., Junge W., Kramer D., Melis A., Moore T., Moser C., G. Nocera D., Nozik A., R. Ort D., Parson W., Prince R., Sayre R. (2011) Comparing photosynthetic and photovoltaic efficiencies and recognizing the potential for improvement. Science (New York, NY). 332. https://doi.org/10.1126/science.1200165
- [2] Nonhebel S. (2005) Renewable energy and food supply: will there be enough country? Renew. Sust. Energy Rev. 9:191– 201. https://doi.org/10.1016/j.rser.2004.02.003
- [3] Goetzberger A., Zastrow A. (1982) On the coexistence of solar energy conversion and plant cultivation. Int. J. Solar Energy. 1:55–69. https://doi.org/10.1080/01425918208909875
- [4] Valle B., Simonneau T., Sourd F., Pechier P., Hamard P., Frisson T., Ryckewaert M., Christophe A. (2017) Increasing the total productivity of a land by combining mobile photovoltaic panels and food crops. Appl. Energy. 206:1495–1507. https://doi.org/10.1016/j. apenergy.2017.09.113
- [5] Elamri Y., Cheviron B., Lopez J.M., Dejean C., Belaud G. (2018) Water budget and crop modelling for agrivoltaic systems: application that irrigated lettuces. Agric. Water Manag. 208:440–453. https://doi.org/10.1016/j.agwat.2018.07.001
- [6] Hannah L., Roehrdanz P.R., Ikegami M., Shepard A.V., Shaw M.R., Tabor G., Zhi L., Marquet P.A., Hijmans R.J. (2013) Climate change, wine, and conservation. Proc. Natl. Acad. Sci. USA. 110:6907–6912. https://doi.org/10.1073/pnas.1210127110
- [7] Hassanpour Adeh E., Selker J.S., Higgins C.W. (2018) Remarkable agrivoltaic influence he soil moisture, micrometeorology and water- use efficiency. PLOS ONE 13(11):e0203256. https://doi.org/10.1371/journal.pone.0203256
- [8] Ravi S., Macknick J., Lobell D., Field C., Ganesan K., Jain R., Elchinger M., Stoltenberg B. (2016) Colocation opportunities for large solar infrastructures and agriculture in drylands. Appl. Energy. 165:383–392. https://doi.org/10.1016/j.apenergy.2015.12.078
- [9] Casarin D. (2012) R.E.M. Talk about the "Agrovoltaic": when agriculture discovers the photovoltaic, [Electronic resource]. Access mode: http://www.genitronsviluppo.com/2012/07/30/rem-agrovoltaico/ (in Italian)
- [10] Rem Tec (2017) AGROVOLTAICO® TECHNOLOGY, [Electronic resource]. Access mode: https://www.remtec.energy/en/agrovoltaico/
- [11] Corditec (2017) Our plant – Eco Field , [Electronic resource]. Access mode: http://corditec.it/solare/pagecampo.php?page=impianto&title=c ampo%20d%27eco&id=77 (in Italian)
- [12] Dupraz C., Marrou H., Talbot G., Dufour L., Nogier A., Ferard Y. (2011) Combining solar photovoltaic panels and food crops for optimizing land use: towards new agrivoltaic schemes. Renew. Energy. 36: 2725–2732. https://doi.org/10.1016/j.renene.2011.03.005
- [13] Marrou H., Dufour L., Wery J. (2013) How does a shelter of solar panels influence water flows in a soil – crop system? Eur. J. Agron. 50:38–51. https://doi.org/10.1016/j.eja.2013.05.004
- [14] Valle B., Simonneau T., Sourd F., Pechier P., Hamard P., Frisson T., Ryckewaert M., Christophe A. (2017) Increasing the total productivity of a land by combining mobile photovoltaic panels and food crops. Appl. Energy. 206:1495–1507. https://doi.org/10.1016/j. apenergy.2017.09.113
- [15] Fraunhofer Chile Research (2017) FIC AGRO PV Metropolitan Region: project progress. Presentation. March 2017. (in Spanish)
- [16] Kinney K., Minor R., Barron-Gafford G. (2016) Testing predictions used to build an agrivoltaics installation on a small scale educational model. University of Montana, [Electronic resource]. Access mode: http://digitalcommons.calpoly.edu/star/386
- [17] Pallone T. (2017) Agrivoltaics: how plants grown under Solar panels can benefit humankind, [Electronic resource]. Access mode: http://insights.globalspec.com/article/4802/agrivoltaicshow- plants-grown-under-solar-panels-canbenefithumankind? id=-777656564
- [18] A. Weselek, A. Ehmann, S. Zikeli, I. Lewandowski, S. Schindele, et al. Agrophotovoltaic systems: applications, challenges, and opportunities. A review. Agronomy for Sustainable Development, 2019, 39 (4), pp.35. ff10.1007/s13593-019-0581-3ff. ffhal-02877032
- [19] Tonking New Energy (2018) Changshan PV station, [Electronic resource]. Access mode: http://tonkingtech.com/english/news_show.aspx?newsCateid=1 17&cateid=117&NewsId=137
- [20] Campana P.E., Leduc S., Kim M., Olsson A., Zhang J., Liu J., Kraxner F., McCallum I., Li H., Yan J. (2017) Suitable and optimal locations for implementing photovoltaic water pumping systems for grassland irrigation in China. Appl. Energy. 185:1879–1889. https://doi.org/10.1016/j.apenergy.2016.01.004
- [21] Du F., Deng W., Yang M., Wang H., Mao R., Shao J., Fan J., Chen Y., Fu Y., Li C., He X., Zhu Y., Zhu S. (2015) Protecting grapevines from rainfall in rainy conditions reduces disease severity and enhances profitability. Crop Prot. 67:261–268. https://doi.org/10.1016/j.cropro.2014.10.024
- [22] Amaducci S., Yin X., Colauzzi M. (2018) Agrivoltaic systems that optimize land use for electric energy production. Appl. Energy. 220:545–561. https://doi.org/10.1016/j.apenergy.2018.03.081
- [23] Zoellner J., Schweizer-Ries P., Wemheuer C. (2008) Public acceptance of renewable energies: results from case studies in Germany . Energy Policy. 36:4136–4141. https://doi.org/10.1016/j.enpol.2008.06.026
- [24] DAKAR Eleks. Real-time power system management tool for modeling, analysis, planning, and optimization of modern electrical networks. [Electronic resource]. Access mode: https://dakar.eleks.com/en/
- [25] State register of plant varieties suitable for distribution in Ukraine. Kyiv: Derzhkomstat of Ukraine, 2020. 447 p. (in Ukrainian)
- [26] I.S. Kudinenko. Mathematics of agribusiness: cultivation of asparagus. 2018. [Electronic resource]. Access mode: https://kurkul.com/blog/584-matematika-agrobiznesuviroschuvannya- sparji (in Ukrainian)
- [27] Mariupol Farm "AZOV". How many seedlings per hectare – Calculator. [Electronic resource]. Access mode: https://plodopitomnik.com.ua/raschet-sazhencev-na-gektar/ (in Ukrainian)
- [28] F. Belane. Asparagus. - Agropromizdat, 1986.- 128 p. (in Russian)
- [29] N. Biliera. Fertigation is innovative approach to fertilization of agricultural crops. Agronom. – 12.07.2018 [Electronic resource]. Access mode: https://www.agronom.com.ua/fertygatsiya-innovatsijnyj-pidhiddo- udobrennya-kultur. (in Ukrainian)
- [30] Dutko A., Technical and economic analysis and evaluation of the efficiency of the creation of an agrovoltaic installation on the basis of an existing photovoltaic power plant, Master thesis, Poznan University of Technology, (2022)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-7032569e-764e-40d8-80e0-cb6ee644de91
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