Measurement systems for the energy produced by a photovoltaic system and consumed by a building in the Lublin Science and Technology Park

• Autorzy: Małek Arkadiusz

Identyfikatory

DOI

10.35784/IAPGOS.221

Warianty tytułu

PL

Systemy pomiaru energii produkowanej przez system fotowoltaiczny i pobieranej przez budynek Lubelskiego Parku Naukowo-Technologicznego

• Języki publikacji: EN

Abstrakty

EN

The article contains a description of systems for measuring the energy produced by the photovoltaic system and its consumption by a building. The photovoltaic system consists of two micro-installations supplying two parts of the Lublin Science and Technology Park. An internet platform for monitoring photovoltaic plant operation is presented. The power generated and the amount of electricity produced are assessed. Also, an innovative system for monitoring and analysing the consumption and production as well as the efficient use of electricity in individual parts of the building is described. Based on the measurements carried out, the production of energy exceeded its consumption in one part of the building.

PL

W artykule zawarto opis innowacyjnych systemów do pomiaru energii produkowanej przez system fotowoltaiczny oraz pobieranej przez budynek. System fotowoltaiczny składa się z dwóch mikroinstalacji zasilających dwa segmenty Lubelskiego Parku Naukowo-Technologicznego. Przedstawiono platformę internetową do monitoringu pracy systemu fotowoltaicznego. Dokonano oceny generowanej mocy oraz ilości produkowanej energii elektrycznej. Następnie opisano innowacyjny system do monitoringu, analizy zużycia i produkcji oraz efektywnego wykorzystywania energii elektrycznej w poszczególnych segmentach budynku.

Słowa kluczowe

EN

photovoltaic systems; energy measurement; energy management; smart devices

PL

system fotowoltaiczny; pomiar energii; zarządzanie energią; inteligentne urządzenie

• Wydawca: Wydawnictwo Politechniki Lubelskiej
• Czasopismo: Informatyka, Automatyka, Pomiary w Gospodarce i Ochronie Środowiska
• Rocznik: 2019
• Tom: T. 9, nr 4
• Strony: 87--92
• Opis fizyczny: Bibliogr. 36 poz., rys., tab.

Twórcy

autor

Małek Arkadiusz

• University of Economics and Innovation in Lublin, Faculty of Transport and Computer Science, Lublin, Poland

Bibliografia

• [1] Al Essa M.J.M.: Home energy management of thermostatically controlled loads and photovoltaic-battery systems. Energy 176/2019, 742–752
• [2] Aoun N., Bailek N.: Evaluation of mathematical methods to characterize the electrical parameters of photovoltaic modules. Energy Conversion and Management 193/2019, 25–38.
• [3] Azizi A., Logerais P.O., Omeiri A.: Impact of the aging of a photovoltaic module on the performance of a grid-connected system. Photovoltaic Energy 174/2018, 445–454.
• [4] Bień A., Janicki A.: Simple and efficient profiling of electricity consumer. Wiadomości Elektrotechniczne 3/2019, 42–45 [DOI: 10.15199/74.2019.3.8].
• [5] Bliss M., Betts T., Gottschalg R.: Interlaboratory comparison of short-circuit current versus irradiance linearity measurements of photovoltaic devices. Photovoltaic Energy 82/2019, 256–263.
• [6] Choudhary P., Srivastava R.K.: Sustainability perspectives- a review for photovoltaic photovoltaic trends and growth opportunities. Journal of Cleaner Production 227/2019, 589–612.
• [7] Cibira G.: Relations among photovoltaic cell electrical parameters. Applied Surface Science 461/2018, 102–107.
• [8] Coria G., Penizzotto F., Pringles R.: Economic analysis of photovoltaic projects: The Argentinian renewable generation policy for residential sectors. Renewable Energy 133/2019, 1167–1177.
• [9] Dubard J., Filtz J.R., Cassagne V., Legrain P.: Photovoltaic module performance measurements traceability: Uncertainties survey. Measurement 51/2014, 451–456.
• [10] Gallardo-Saavedra S., Hernández-Callejo L., Duque-Pérez O.: Quantitative failure rates and modes analysis in photovoltaic plants. Energy 183/2019, 825–836.
• [11] Gao Q., Zhang Y., Yu Y., Liu Z.: A direct current-voltage measurement method for smart photovoltaic modules with submodule level power optimizers. Photovoltaic Energy 167/2018, 52–60.
• [12] Głuchy D.: The comparative analysis of the profitability of investments in the renewable energy source. Informatyka, Automatyka, Pomiary w Gospodarce i Ochronie Środowiska 4b/2012, 28–31.
• [13] Grabowski, Ł.: The productivity of photovoltaic structures mounted on the roof of city bus. Logistyka 3/2014, 2114–2120.
• [14] Hai Vu N., Pham T.-T., Shin S.: Flat concentrator photovoltaic system for automotive applications. Photovoltaic Energy 190/2019, 246–254.
• [15] Imbuluzqueta G., Yurrita N., Aizpurua J., Cano F.J., Zubillaga O.: Composite material with enhanced ultraviolet performance stability for photovoltaic modules. Photovoltaic Energy Materials and Photovoltaic Cells 200/2019, 109947.
• [16] Janicki A.: Enhancing Electricity Meters with Smart Functionality Using Metering System with Optical Sensors. ALLSENSORS 2019.
• [17] Judzińska-Kłodawska A.: Energy consumption in electric cars and environment impact. Autobusy: technika, eksploatacja, systemy transportowe 6/2014, 149–151.
• [18] Katayama N., Osawa S., Matsumoto S., Nakano T., Sugiyama M.: Degradation and fault diagnosis of photovoltaic cells using impedance spectroscopy. Photovoltaic Energy Materials and Photovoltaic Cells 194/2019, 130–136.
• [19] Krupa K., Kamiński J.: Impact analysis of electromobility development on Poland’s electricity consumption. Rynek Energii 6/2017, 8–13.
• [20] Lay-Ekuakille A., Ciaccioli A., Griffo G.: Effects of dust on photovoltaic measurements: A comparative study. Measurement 113/2018, 181–188.
• [21] Lis P. Piesyk J.: Energy consumption and energy efficiency of buildings. Fizyka Budowli w Teorii i Praktyce 3/2016, 21–28.
• [22] Liu G., Kong L., Yang W, Mao H.: Pressure engineering of photovoltaic perovskites. Materials Today 27/2019, 91–106.
• [23] Liu J., Jia D., Gardner J.M., Johansson E.M.J., Zhang X.: Metal nanowire networks: Recent advances and challenges for new generation photovoltaics. Materials Today Energy 13/2019, 152–185.
• [24] Lu X., Lin P., Cheng S.: Fault diagnosis for photovoltaic array based on convolutional neural network and electrical time series graph. Energy Conversion and Management 196/2019, 950–965.
• [25] Łukaszewski, J.: Trzy trendy na 2019 rok, które zmienią filozofię produkcji, zarządzanie i zużycie energii. Napędy i Sterowanie 2/2019, 46–47.
• [26] Małek A., Filipowicz I.: Charging the electric vehicle from the photovoltaic minicarport. AUTOBUSY–Technika, Eksploatacja, Systemy Transportowe 11/2018, 37–40 [DOI: 10.24136/atest.2018.343].
• [27] Małek A., Kowalczyk D.: Photovoltaic carport for electric vehicle charging. Autobusy: technika, eksploatacja, systemy transportowe 11/2016, 93–97.
• [28] Siadkowska K. Grabowski Ł.: Safety of using mobile photovoltaic installations. Logistyka 6/2014, 9476–9485.
• [29] Tatsi E., Griffini G.: Polymeric materials for photon management in photovoltaics. Photovoltaic Energy Materials and Photovoltaic Cells 196/2019, 43–56.
• [30] Wielgus J., Kasperek D., Małek A., Łusiak T.: Developed generations of electric buses produced by Ursus. Autobusy: technika, eksploatacja, systemy transportowe 11/2017, 20–25.
• [31] Yin E., Li Q., Xuan Y.: Experimental optimization of operating conditions for concentrating photovoltaic-thermoelectric hybrid system. Journal of Power Sources 422/2019, 25–32.
• [32] Zarajczyk K., Małek A., Kośko M.: Constructional and functional assumptions of a Ursus Elvi vehicle with an electric drive. Autobusy: technika, eksploatacja, systemy transportowe 6/2018, 309–313 [DOI: 10.24136/atest.2018.082].
• [33] http://lpnt.pl/ (access 2019.07.09).
• [34] http://server.growatt.com/login.do (access 2019.07.09).
• [35] https://onemeter.com/pl/ [access 2019.07.09).
• [36] http://renovi.pl/naslonecznienie-w-polsce/ (access 2019.10.02).

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).