Relevant bibliographies by topics / Photovoltaic power systems

Academic literature on the topic 'Photovoltaic power systems'

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Published: 4 June 2021
Last updated: 13 August 2024

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Journal articles on the topic "Photovoltaic power systems"

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Fyali, Jibji-Bukar, and Anaya-Lara Olimpo. "Offline Photovoltaic Maximum Power Point Tracking." E3S Web of Conferences 64 (2018): 06007. http://dx.doi.org/10.1051/e3sconf/20186406007.

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As more renewable energy sources are connected to the electrical grid, it has become important that these sources participate in providing system support. It has become needful for grid-connected solar photovoltaics to participate in support functions like frequency support. However, photovoltaic systems need to implement a maximum power tracking algorithm to operate at maximum power and a method for de-loading photovoltaic systems is necessary for participation in frequency support. Some conventional maximum power tracking techniques are implemented in real time and will not adjust their output fast enough to provide system support while other may respond fast but are not very efficient in tracking the maximum power point of a photovoltaic system. This paper presents an offline method to estimate the maximum power voltage and current based on the characteristics of the photovoltaics module available in the datasheet and using the estimated values to operate the photovoltaics at maximum power. The performance of this technique is compared to the conventional technique. This paper also describes how the photovoltaic system can be de-loaded.
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Vilathgamuwa, Mahinda, Dulika Nayanasiri, and Shantha Gamini. "Power Electronics for Photovoltaic Power Systems." Synthesis Lectures on Power Electronics 5, no. 2 (August 20, 2015): 1–131. http://dx.doi.org/10.2200/s00638ed1v01y201504pel008.

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Bourdoucen, Hadj, Joseph A. Jervase, Abdullah Al-Badi, Adel Gastli, and Arif Malik. "Photovoltaic Cells and Systems: Current State and Future Trends." Sultan Qaboos University Journal for Science [SQUJS] 5 (December 1, 2000): 185. http://dx.doi.org/10.24200/squjs.vol5iss0pp185-207.

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Photovoltaics is the process of converting solar energy into electrical energy. Any photovoltaic system invariably consists of solar cell arrays and electric power conditioners. Photovoltaic systems are reliable, quiet, safe and both environmentally benign and self-sustaining. In addition, they are cost-effective for applications in remote areas. This paper presents a review of solar system components and integration, manufacturing, applications, and basic research related to photovoltaics. Photovoltaic applications in Oman are also presented. Finally, the existing and the future trends in technologies and materials used for the fabrication of solar cells are summarized.
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Hu, Boxun, Yanan Chen, Desheng Kong, and Yiming Yao. "Large, grid-connected solar photovoltaic power plants renewable energy." Applied and Computational Engineering 7, no. 1 (July 21, 2023): 375–89. http://dx.doi.org/10.54254/2755-2721/7/20230328.

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As an essential part of renewable energy, the solar photovoltaic technic grows rapidly with two main types: off-grid and grid-connected systems. This paper focuses on grid-connected solar photovoltaic power plants and introduces the main physical principles of solar photovoltaics. Typical components of solar photovoltaic power plants are also presented, along with their functions. The extraordinary environmental impact and the relatively low and decreasing cost of grid-connected solar photovoltaics reflect its excellent development potential. Compared with other energy, grid-connected solar photovoltaics provides an alternative to conventional fossil fuel generation. With the improvement of silicon purification technology and the working efficiency of solar batteries, the scale of grid-connected solar photovoltaics power plants will be further expanded.
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Okhorzina, Alena, Alexey Yurchenko, and Artem Kozloff. "Autonomous Solar-Wind Power Forecasting Systems." Advanced Materials Research 1097 (April 2015): 59–62. http://dx.doi.org/10.4028/www.scientific.net/amr.1097.59.

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The paper reports on the results of climatic testing of silicon photovoltaic modules and photovoltaic power systems conducted in Russia (Siberia and the Far East). The monitoring system to control the power system work was developed. Testing over 17 years and a large amount of experimental studies enabled us to develop a precise mathematical model of the photovoltaic module in natural environment taking into account climatic and hardware factors.
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Armstrong O Njok and Igwe O Ewona. "Diurnal analysis of enhanced solar photovoltaic systems using automatic cooling mechanism." World Journal of Advanced Engineering Technology and Sciences 5, no. 2 (March 30, 2022): 016–23. http://dx.doi.org/10.30574/wjaets.2022.5.2.0035.

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Africa and Nigeria in particular are blessed with abundance of sunshine throughout the year. Unfortunately, the region is associated with high temperature values which is a major factor militating against the efficiency of photovoltaic systems in use today. Since for each degree rise in temperature, about 0.50% efficiency is lost, then this implies that once a photovoltaic panel enters the Nigeria atmosphere about 5%-10% of its maximum power is lost. To tackle this problem, a cooling mechanism has to be incorporated into photovoltaic system design for adequate cooling and temperature monitoring. A smart automatic cooling mechanism and a smart photovoltaic MPPT tester were deployed in the study. In situ measurements were obtained in outdoor real-time conditions. The results reveal better performances for voltage, current, power and efficiency for the photovoltaic module whose temperatures was regulated not to exceed the threshold temperature of 350C. This study shows and suggest that lowering the panel temperature of photovoltaics through the application of cooling mechanism should be considered in the design of photovoltaic systems.
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Arnaoutakis, Georgios E., and Dimitris A. Katsaprakakis. "Energy Yield of Spectral Splitting Concentrated Solar Power Photovoltaic Systems." Energies 17, no. 3 (January 23, 2024): 556. http://dx.doi.org/10.3390/en17030556.

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Combined concentrated solar power with photovoltaics can provide electricity and heat at the same system while maximizing the power output with reduced losses. Spectral splitting is required in such systems to separate the infrared part of the solar spectrum towards the thermal system, while the visible and near-infrared radiation can be converted by the photovoltaic solar cell. The performance of concentrated solar power plants comprising reflective beam splitters for combined generation of electricity and heat is presented in this work. A 50 MW power plant is considered in this work as a case of study in Southern Crete, Greece. The solar power plant consists of parabolic trough collectors and utilizes beam splitters with varying reflectivity. The dynamic performance of the power plant is modeled, and the annual energy yield can be calculated. Up to 350 MWt of thermal power can be delivered to the photovoltaic system utilizing a 50% reflecting splitter. The penalty to the high-reflectivity system is limited to 16.9% and the annual energy yield is calculated as 53.32 GWh. During summer months, a higher energy yield by up to 84.8 MWh/month is produced at 80% reflectivity compared to 90% as a result of the number of parabolic troughs. The reported energy yields with reflectivity by dynamic modeling can highlight discrete points for improvement of the performance in concentrated solar power photovoltaics.
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Consoli, Alfio, Mario Cacciato, and Vittorio Crisafulli. "Power Converters For Photovoltaic Generation Systems In Smart Grid Applications." Eletrônica de Potência 14, no. 4 (November 1, 2009): 251–57. http://dx.doi.org/10.18618/rep.2009.4.251257.

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Niu, Yitong, Ahmed Mohammed Merza, Suhad Ibraheem Kadhem, Jamal Fadhil Tawfeq, Poh Soon JosephNg, and Hassan Muwafaq Gheni. "Evaluation of wind-solar hybrid power generation system based on Monte Carlo method." International Journal of Electrical and Computer Engineering (IJECE) 13, no. 4 (August 1, 2023): 4401. http://dx.doi.org/10.11591/ijece.v13i4.pp4401-4411.

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<span lang="EN-US">The application of wind-photovoltaic complementary power generation systems is becoming more and more widespread, but its intermittent and fluctuating characteristics may have a certain impact on the system's reliability. To better evaluate the reliability of stand-alone power generation systems with wind and photovoltaic generators, a reliability assessment model for stand-alone power generation systems with wind and photovoltaic generators was developed based on the analysis of the impact of wind and photovoltaic generator outages and derating on reliability. A sequential Monte Carlo method was used to evaluate the impact of the wind turbine, photovoltaic (PV) turbine, wind/photovoltaic complementary system, the randomness of wind turbine/photovoltaic outage status and penetration rate on the reliability of Independent photovoltaic power generation system (IPPS) under the reliability test system (RBTS). The results show that this reliability assessment method can provide some reference for planning the actual IPP system with wind and complementary solar systems.</span>
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Nema Hawas, Majli, Ihsan Jabbar Hasan, and Mohannad Jabbar Mnati. "Simulation and analysis of the distributed photovoltaic generation systems based on DIgSILENT power factory." Indonesian Journal of Electrical Engineering and Computer Science 28, no. 3 (October 7, 2022): 1227. http://dx.doi.org/10.11591/ijeecs.v28.i3.pp1227-1238.

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The voltage <span>stability of the system has become an important component for the steady and dependable functioning of the power system as a result of multiple blackouts around the world (particularly in Iraq). Distributed photovoltaic systems are a subset of decentralized power generating systems that generate electricity using renewable energy sources like solar cells, wind turbines, and water power plants. In order to size a solar-grid-connected home system properly and to confirm the impact of photovoltaics on the system, this article will also do a steady-state analysis. The heating and cooling loads were taken into account when evaluating the residential load profile. With the help of predicted energy use, the photovoltaic (PV) system was sized. The solar system's power output was calculated, and the key variables affecting system performance were examined. The DigSilent power factory 15.2 was used to simulate all of the investigations. This article achieves better system stability outcomes.</span>
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Dissertations / Theses on the topic "Photovoltaic power systems"

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Perez, de Larraya Espinosa Mikel. "Photovoltaic Power Plant Aging." Thesis, Högskolan i Gävle, Avdelningen för byggnadsteknik, energisystem och miljövetenskap, 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:hig:diva-33252.

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One of the most pressing problems nowadays is climate change and global warming. As it name indicates, it is a problem that concerns the whole earth. There is no doubt that the main cause for this to happen is human, and very related to non-renewable carbon-based energy resources. However, technology has evolved, and some alternatives have appeared in the energy conversion sector. Nevertheless, they are relatively young yet. Since the growth in renewable energies technologies wind power and PV are the ones that have taken the lead. Wind power is a relatively mature technology and even if it still has challenges to overcome the horizon is clear. However, in the PV case the technology is more recent. Even if it is true that PV modules have been used in space applications for more than 60 years, large scale production has not begun until last 10 years. This leaves the uncertainty of how will PV plants and modules age. The author will try to analyse the aging of a specific 63 kWp PV plant located in the roof of a building in Gävle, monitoring production and ambient condition data, to estimate the degradation and the new nominal power of the plant. It has been found out that the degradation of the system is not considerable. PV modules and solar inverters were studied, and even if there are more elements in the system, those are the principal ones. PV modules suffered a degradation of less than 5%, while solar inverters’ efficiency dropped from 95,4% to around 93%.
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Tesfahunegn, Samson Gebre. "Fuel Cell Assisted PhotoVoltaic Power Systems." Doctoral thesis, Norges teknisk-naturvitenskapelige universitet, Institutt for elkraftteknikk, 2012. http://urn.kb.se/resolve?urn=urn:nbn:no:ntnu:diva-16942.

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Distributed generation (DG) systems as local power sources have great potential to contribute toward energy sustainability, energy efficiency and supply reliability. This thesis deals with DGs that use solar as primary energy input, hydrogen energy storage and conversion technologies (fuel cells and water electrolyzers) as long term backup and energy storage batteries and supercapacitors as short term backup. Standalone power systems isolated from the grid such as those used to power remote area off-grid loads and grid connected systems running in parallel with the main utility grid or a microgrid for local grid support are treated. As cost is the key challenge to the implementation of PV-hydrogen DGs, the main focus is developing sound control methods and operating strategies to help expedite their viability in the near future. The first part of the thesis deals with modeling of system components such as PV generator, fuel cell, lead acid/Li-ion storage batteries, electrolyzer, supercapacitor, power electronic converters and auxiliaries such as hydrogen storage tank and gas compressor. The subsystems are modeled as masked blocks with connectable terminals in Matlab®/Simulink® enabling easy interconnection with other subsystems. The models of main subsystems are fully/partially validated using measurement data or data obtained from data sheets and literature. The second part deals with control and operating strategies in PV hybrid standalone power systems. The models developed in the first part are used to simulate integrated systems. An attempt is made to provide some answers on how the different power sources and energy storages can be integrated and controlled using power electronics and feedback control to enhance improved performance, longer life time, increased supply reliability and minimize fuel use. To this end, new control methods and operating strategies are proposed to mediate near optimal intersubsystem power flows. The third part of the thesis concerns grid connected PV-Fuel cell power systems. Control schemes and operating strategies for integrating PV and fuel cell hybrids into the grid to serve both local demand and weak grids are investigated. How hydrogen energy storage and conversion technologies can be controlled to suppress PV fluctuations in future utility grids are also explored. A smoothing algorithm enhanced by a stepwise constant forecast is developed to enable more smooth and subhourly dispatchable power to be fed to the grid. The proposed methods were verified through longtime simulation based on realistic irradiance data over a number of typical days/weeks using suitably defined performance indices. It was learned that using power electronics and sound control methods, PV-hydrogen DGs can be flexibly controlled to solve lifetime and performance issues which are generally considered economic bottle necks. For example, conventionally in PV-hydrogen hybrids, to improve performance and life time, more battery capacity is added to operate fuel cell and electrolyzer under more stable power conditions in the face of highly fluctuating PV generation to prevent low state of charge (SOC) operation of the battery. Contrarily, in this thesis a sound control method is proposed to achieve the same objectives without oversizing the battery. It is shown that the proposed method can give up to 20% higher battery mean state of charge than conventional operation while PV fluctuation suppression rates up to 40% for the fuel cell and 85% for the electrolyzer are found for three typical days. It is also established that by predictively controlling battery SOC instead of conventional SOC setpoint control, substantial improvements can be obtained (up to 20-30% increase in PV energy utilization and ca. 25% reduction in fuel usage for considered days). Concerning use of hydrogen storage and conversion technologies in PV fluctuation suppression, results obtained from the developed smoothing mechanism and performance indices show that a trade-off should be made between smoothing performance and dispatchability. It was concluded that the right size of fuel cell and electrolyzer needs to be selected to optimize the dispatch interval and smoothing performance. Finally, a PV-hydrogen test facility which can act as show case for standalone, grid-connected and UPS applications was designed and built. The test facility was used to characterize key subsystems from which component models developed were experimentally validated. The facility also acted as a reference system for most of the investigations made in this thesis.
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Dzimano, Gwinyai J. "Modeling Of Photovoltaic Systems." The Ohio State University, 2008. http://rave.ohiolink.edu/etdc/view?acc_num=osu1228307443.

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Alistoun, Warren James. "Investigation of the performance of photovoltaic systems." Thesis, Nelson Mandela Metropolitan University, 2012. http://hdl.handle.net/10948/d1008396.

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The main objective of this study was to investigate the performance of grid integrated PV systems. A data acquisition (DAQ) system was developed to monitor the performance of an existing grid integrated PV system with battery storage. This system is referred to as a grid assisted PV system. A data logger was used together with the inverters built in data logger to monitor environmental and electrical data on a grid tie PV system which was deployed during this study. To investigate the performance of these grid integrated PV systems PV and BOS device characterization was performed. This was achieved by using current voltage curve tracers and the DAQ system developed. Energy yield estimations were calculated referring to the literature review and a meteorological reference for comparison with measured energy yields from the grid tie PV system.
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Njouakoua, Tchonko Leon. "Reconfigurable photovoltaic modules for robust nanosatellite power systems." Thesis, Cape Peninsula University of Technology, 2018. http://hdl.handle.net/20.500.11838/2620.

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Thesis (MTech (Electrical Engineering))--Cape Peninsula University of Technology, 2018.
Until recently, the focus of most solar technology development for space was towards more efficient, more radiation-resistant and increasingly powerful arrays. During a space mission, solar cells are not only exposed to irradiation by electrons, but also to a range of other particles, like protons. Thus, solar cells on robust nanosatellites are extremely exposed to an environment, which includes the high-energy electrons and protons of the earth’s radiation belts, which leads towards the degradation process of the individual solar cell. Solar cell radiation shielding design ensures the protection of the solar cells from the particular radiation environment found in space. While the design principles of a solar photovoltaic automatic switching fault tolerant system which can detect and bypass faulty photovoltaic cells will be presented through this research work. The ability of such a system to be reconfigured using implemented switching matrix system makes it efficient under various environments and faulty conditions.
National Research Foundation (NRF)
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Carr, Anna J. "A detailed performance comparison of PV modules of different technologies and the implications for PV system design methods /." Access via Murdoch University Digital Theses Project, 2005. http://wwwlib.murdoch.edu.au/adt/browse/view/adt-MU20050830.94641.

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Thantsha, Nicolas Matome. "Spatially resolved opto-electric measurements of photovoltaic materials and devices." Thesis, Nelson Mandela Metropolitan University, 2010. http://hdl.handle.net/10948/1123.

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The objective of this study is to characterize and analyse defects in solar cell devices. Materials used to fabricate solar cells are not defects free and therefore, there is a need to investigate defects in cells. To investigate this, a topographical technique was developed and employed which uses a non-destructive methodology to analyse solar cells. A system was built which uses a technique based on a laser beam induced current (LBIC). LBIC technique involves focusing light on to a surface of a solar cell device in order to create a photo-generated current that can be measured in the external circuit for analyses. The advantage of this technique is that it allows parameter extraction. Parameters that can be extracted include short-circuit current, carrier lifetime and also the external and internal quantum efficiency of a solar cell. In this thesis, LBIC measurements in the form of picture maps are used to indicate the distribution of the localized beam induced current within solar cells. Areas with low minority carrier lifetime in solar cells are made visible by LBIC mapping. Surface reflection intensity measurements of cells can also be mapped using the LBIC system developed in this study. The system is also capable of mapping photo-generated current of a cell below and above room temperature. This thesis also presents an assessment procedure capable of assessing the device and performance parameters with reference to I-V measurements. The dark and illuminated I-V characteristics of solar cells were investigated. The illuminated I-V characteristics of solar cells were obtained using a defocused laser beam. Dark I-V measurements were performed by applying voltage across the cell in the dark and measuring a current through it. The device parameters which describe the behaviour of I-V characteristic were extracted from the I-V data using Particle Swarm Optimization (PSO) method based on a one-and two-diode solar cell models. Solar cells of different technologies were analysed, namely, single-crystalline (c-Si) and multicrystalline (mc-Si) silicon, Edge-defined Film-fed Growth Si (EFG-Si) and Cu(In,Ga)(Se,S)2 (CIGSS) thin film based cells. The LBIC results illustrated the effect of surface reflection features and material defects in the solar cell investigated. IQE at a wavelength of 660 nm were measured on these cells and the results in general emphasised the importance of correcting optical losses, i.e. reflection loss, when characterizing different types of defects. The agreement between the IQE measurements and I-V characteristics of a cell showed that the differences in crystal grains influence the performance of a mc-Si cell. The temperature-dependence of I-V characteristics of a CIGSS solar cell was investigated. The results showed that, for this material, the photo response is reduced at elevated temperatures. In addition to LBIC using a laser beam, solar spectral radiation was employed to obtained device performance parameters. The results emphasised the effect of grain boundaries as a recombination centres for photo-generated hole-pairs. Lastly, mesa diode characterizations of solar cells were investigated. Mesa diodes are achieved by etching down a solar cell so that the plateau regions are formed. Mesa diodes expose the p-n junction, and therefore mesa diode analysis provides a better way of determining and revealing the fundamental current conduction mechanism at the junction. Mesa diodes avoid possible edge effects. This study showed that mesa diodes can be used to characterize spatial non-uniformities in solar cells. The results obtained in this study indicate that LBIC is a useful tool for defect characterization in solar cells. Also LBIC complements other characterization techniques such as I-V characterization.
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Vourazelis, Dimitrios G. "Optimization in solar heating/photovoltaic systems." Monterey, California : Naval Postgraduate School, 1990. http://handle.dtic.mil/100.2/ADA242363.

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Thesis (M.S. in Electrical Engineering)--Naval Postgraduate School, December 1990.
Thesis Advisor(s): Titus, Harold A. Second Reader: Michael, Sherif. "December 1990." Description based on title screen as viewed on March 30, 2010. DTIC Descriptor(s): Heat Transfer, Theory, Theses, Costs, Heating Elements, Fluid Dynamics, Photovoltaic Effect, Solar Heating, Swimming, Optimization, Installation. DTIC Identifier(s): Swimming Pools, Solar Heating, Photovoltaic Supplies, Filter Pumps, Theses. Author(s) subject terms: Optimization, Solar Heating, Photovoltaics. Includes bibliographical references (p. 57). Also available in print.
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Gow, John A. "Modelling, simulation and control of photovoltaic converter systems." Thesis, Loughborough University, 1998. https://dspace.lboro.ac.uk/2134/6871.

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The thesis follows the development of an advanced solar photovoltaic power conversion system from first principles. It is divided into five parts. The first section shows the development of a circuit-based simulation model of a photovoltaic (PV) cell within the 'SABER' simulator environment. Although simulation models for photovoltaic cells are available these are usually application specific, mathematically intensive and not suited to the development of power electronics. The model derived within the thesis is a circuit-based model that makes use of a series of current/voltage data sets taken from an actual cell in order to define the relationships between the cell double-exponential model parameters and the environmental parameters of temperature and irradiance. Resulting expressions define a 'black box' model, and the power electronics designer may simply specify values of temperature and irradiance to the model, and the simulated electrical connections to the cell provide the appropriate I/V characteristic. The second section deals with the development of a simulation model of an advanced PVaware DC-DC converter system. This differs from the conventional in that by using an embedded maximum power tracking system within a conventional linear feedback control arrangement it addresses the problem of loads which may not require the level of power available at the maximum power point, but is also able to drive loads which consistently require a maximum power feed such as a grid-coupled inverter. The third section details a low-power implementation of the above system in hardware. This shows the viability of the new, fast embedded maximum power tracking system and also the advantages of the system in terms of speed and response time over conventional systems. The fourth section builds upon the simulation model developed in the second section by adding an inverter allowing AC loads (including a utility) to be driven. The complete system is simulated and a set of results obtained showing that the system is a usable one. The final section describes the construction and analysis of a complete system in hardware (c. 500W) and identifies the suitability of the system to appropriate applications.
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Ropp, Michael Eugene. "Design issues for grid-connected photovoltaic systems." Diss., Georgia Institute of Technology, 1998. http://hdl.handle.net/1853/13456.

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Books on the topic "Photovoltaic power systems"

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Vilathgamuwa, Mahinda, Dulika Nayanasiri, and Shantha Gamini. Power Electronics for Photovoltaic Power Systems. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-031-02500-6.

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Rekioua, Djamila, and Ernest Matagne. Optimization of Photovoltaic Power Systems. London: Springer London, 2012. http://dx.doi.org/10.1007/978-1-4471-2403-0.

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National Joint Apprenticeship and Training Committee for the Electrical Industry, ed. Photovoltaic systems. 2nd ed. Orland Park, Ill: American Technical Publishers, Inc., 2010.

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Messenger, Roger. Photovoltaic systems engineering. 2nd ed. Boca Raton, FL: CRC Press, 2003.

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Canada. Energy, Mines and Resources Canada., ed. Photovoltaic systems: A buyer's guide. Ottawa: Energy, Mines and Resources Canada, 1989.

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Gandhi, Oktoviano. Reactive Power Support Using Photovoltaic Systems. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-61251-1.

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Coddington, Michael H. Solutions for deploying PV systems in New York City's secondary network system. Golden, Colo.]: National Renewable Energy Laboratory, 2010.

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Canada, Canada Natural Resources, ed. Photovoltaic systems: A buyer's guide. Ottawa: Natural Resources Canada, 2002.

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Photovoltaic System Design Assistance Center., ed. The Design of residential photovoltaic systems. [Albuquerque, N.M.]: Sandia National Laboratories, Photovoltaic System Design Assistance Center, 1988.

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Tanaka, Hideki. Photovoltaics developments, applications, and impact. Hauppauge, NY: Nova Science Publishers, 2009.

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Book chapters on the topic "Photovoltaic power systems"

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Tanrioven, Mugdesem. "Photovoltaic Power Systems." In Photovoltaic Systems Engineering for Students and Professionals, 199–492. Boca Raton: CRC Press, 2023. http://dx.doi.org/10.1201/9781003415572-5.

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Rachid, Ahmed, Aytac Goren, Victor Becerra, Jovana Radulovic, and Sourav Khanna. "Photovoltaic Cells and Systems." In Power Systems, 17–42. Cham: Springer International Publishing, 2023. http://dx.doi.org/10.1007/978-3-031-20830-0_2.

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Patel, Mukund R., and Omid Beik. "Photovoltaic–Battery System." In Spacecraft Power Systems, 41–56. 2nd ed. Boca Raton: CRC Press, 2023. http://dx.doi.org/10.1201/9781003344605-5.

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Ghannam, Rami, Paulo Valente Klaine, and Muhammad Imran. "Artificial Intelligence for Photovoltaic Systems." In Power Systems, 121–42. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-13-6151-7_6.

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Ge, Leijiao, and Yuanzheng Li. "Photovoltaic Prediction and Virtual Collection." In Power Systems, 19–50. Singapore: Springer Nature Singapore, 2023. http://dx.doi.org/10.1007/978-981-99-6758-2_3.

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Rekioua, Djamila, and Ernest Matagne. "Photovoltaic Pumping Systems." In Optimization of Photovoltaic Power Systems, 181–221. London: Springer London, 2012. http://dx.doi.org/10.1007/978-1-4471-2403-0_6.

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Rekioua, Djamila, and Ernest Matagne. "Hybrid Photovoltaic Systems." In Optimization of Photovoltaic Power Systems, 223–73. London: Springer London, 2012. http://dx.doi.org/10.1007/978-1-4471-2403-0_7.

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Schmid, Jürgen. "Small Power Photovoltaic Systems." In Seventh E.C. Photovoltaic Solar Energy Conference, 113–20. Dordrecht: Springer Netherlands, 1987. http://dx.doi.org/10.1007/978-94-009-3817-5_20.

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Farret, Felix A. "Photovoltaic Power Electronics." In Power Electronics for Renewable and Distributed Energy Systems, 61–109. London: Springer London, 2013. http://dx.doi.org/10.1007/978-1-4471-5104-3_3.

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Schmidt, Heribert, Bruno Burger, and Jürgen Schmid. "Power Conditioning for Photovoltaic Power Systems." In Handbook of Photovoltaic Science and Engineering, 954–83. Chichester, UK: John Wiley & Sons, Ltd, 2011. http://dx.doi.org/10.1002/9780470974704.ch21.

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Conference papers on the topic "Photovoltaic power systems"

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Sung, T. "Solar photovoltaic power systems." In IET Workshop on Special Locations: Requirements for Electrical Installations in BS 7671. IEE, 2007. http://dx.doi.org/10.1049/ic:20070787.

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Hoke, Anderson, and Dragan Maksimovic. "Active power control of photovoltaic power systems." In 2013 IEEE Conference on Technologies for Sustainability (Sustech). IEEE, 2013. http://dx.doi.org/10.1109/sustech.2013.6617300.

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Moore, Larry, Hal Post, and Terry Mysak. "Photovoltaic Power Plant Experience at Tucson Electric Power." In ASME 2005 International Mechanical Engineering Congress and Exposition. ASMEDC, 2005. http://dx.doi.org/10.1115/imece2005-82328.

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Tucson Electric Power Company (TEP) currently has nearly 5.0 MWdc of utility-scale grid-connected photovoltaic (PV) systems that have been installed in its service territory since 2000. Most of this installed PV capacity is in support of the Arizona Corporation Commission Environmental Portfolio Standard (EPS) goal that encourages TEP to generate 1.1% of its energy generation through renewable resources by 2007, with 60% of that amount from photovoltaics. The EPS program provides for multi-year, pay-as-you-go development of renewable energy, with kWhac energy production as a key program measurement. A total of 26 crystalline silicon collector systems, each rated at 135 kWdc, have been installed at the Springerville, AZ generating plant by TEP making this one of the largest PV plants in the world. These systems were installed in a standardized, cookie-cutter approach whereby each uses the same array field design, mounting hardware, electrical interconnection, and inverter unit. This approach has allowed TEP to achieve a total installed system cost of $5.40/Wdc and a TEP-calculated levelized energy cost of $0.10/kWhac for PV electrical generation. During this time, much has been learned regarding performance, cost, maintenance, installation and design. This paper presents an assessment of these topics and a perspective associated with this PV experience.
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Zarghami, M., B. Kaviani, F. Tavatli, and M. Vaziri. "Complex power optimization of photovoltaic systems." In 2014 IEEE Power & Energy Society General Meeting. IEEE, 2014. http://dx.doi.org/10.1109/pesgm.2014.6939373.

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Munoz, Javier, and Pablo Diaz. "A virtual photovoltaic power systems laboratory." In 2010 IEEE Education Engineering 2010 - The Future of Global Learning Engineering Education (EDUCON 2010). IEEE, 2010. http://dx.doi.org/10.1109/educon.2010.5492411.

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Carbone, R., C. De Capua, and R. Morello. "Photovoltaic systems for powering greenhouses." In 2011 International Conference on Clean Electrical Power (ICCEP). IEEE, 2011. http://dx.doi.org/10.1109/iccep.2011.6036294.

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Fei Kong, Fanbo He, Zhengming Zhao, and Ting Lu. "Series connected photovoltaic power inverter." In 2013 International Conference on Electrical Machines and Systems (ICEMS). IEEE, 2013. http://dx.doi.org/10.1109/icems.2013.6754461.

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Moreno, Ricardo. "Detailed modelling and simulation of photovoltaic systems." In 2017 IEEE Workshop on Power Electronics and Power Quality Applications (PEPQA). IEEE, 2017. http://dx.doi.org/10.1109/pepqa.2017.7981689.

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"Session TU10: Photovoltaic energy systems II." In 2008 IEEE Power Electronics Specialists Conference. IEEE, 2008. http://dx.doi.org/10.1109/pesc.2008.4592140.

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"Session MO3: Photovoltaic energy systems I." In 2008 IEEE Power Electronics Specialists Conference. IEEE, 2008. http://dx.doi.org/10.1109/pesc.2008.4591896.

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Reports on the topic "Photovoltaic power systems"

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Frantzis, L., and W. P. Teagan. Applications Survey for Remote Photovoltaic Power Systems. Fort Belvoir, VA: Defense Technical Information Center, October 1988. http://dx.doi.org/10.21236/ada201937.

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Wiles, J. Photovoltaic power systems and the National Electrical Code: Suggested practices. Office of Scientific and Technical Information (OSTI), December 1996. http://dx.doi.org/10.2172/486131.

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WILES, JOHN. Photovoltaic Power Systems and the National Electrical Code: Suggested Practices. Office of Scientific and Technical Information (OSTI), March 2001. http://dx.doi.org/10.2172/808812.

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Stolte, W. PVUSA experience with power conversion for grid-connected photovoltaic systems. Office of Scientific and Technical Information (OSTI), November 1995. http://dx.doi.org/10.2172/162188.

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McConnell, R., V. Garboushian, R. Gordon, D. Dutra, G. Kinsey, S. Geer, H. Gomez, and C. Cameron. Low-Cost High-Concentration Photovoltaic Systems for Utility Power Generation. Office of Scientific and Technical Information (OSTI), March 2012. http://dx.doi.org/10.2172/1040623.

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Wen, Bo. Power Electronics Based Self-Monitoring and Diagnosing for Photovoltaic Systems. Office of Scientific and Technical Information (OSTI), August 2022. http://dx.doi.org/10.2172/2337710.

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Backstrom, Robert, and David Dini. Firefighter Safety and Photovoltaic Systems Summary. UL Firefighter Safety Research Institute, November 2011. http://dx.doi.org/10.54206/102376/kylj9621.

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Under the United States Department of Homeland Security (DHS) Assistance to Firefighter Grant Fire Prevention and Safety Research Program, Underwriters Laboratories examined fire service concerns of photovoltaic (PV) systems. These concerns include firefighter vulnerability to electrical and casualty hazards when mitigating a fire involving photovoltaic (PV) modules systems. The need for this project is significant acknowledging the increasing use of photovoltaic systems, growing at a rate of 30% annually. As a result of greater utilization, traditional firefighter tactics for suppression, ventilation and overhaul have been complicated, leaving firefighters vulnerable to potentially unrecognized exposure. Though the electrical and fire hazards associated with electrical generation and distribution systems is well known, PV systems present unique safety considerations. A very limited body of knowledge and insufficient data exists to understand the risks to the extent that the fire service has been unable to develop safety solutions and respond in a safe manner. This fire research project developed the empirical data that is needed to quantify the hazards associated with PV installations. This data provides the foundation to modify current or develop new firefighting practices to reduce firefighter death and injury. A functioning PV array was constructed at Underwriters Laboratories in Northbrook, IL to serve as a test fixture. The main test array consisted of 26 PV framed modules rated 230 W each (5980 W total rated power). Multiple experiments were conducted to investigate the efficacy of power isolation techniques and the potential hazard from contact of typical firefighter tools with live electrical PV components. Existing fire test fixtures located at the Delaware County Emergency Services Training Center were modified to construct full scale representations of roof mounted PV systems. PV arrays were mounted above Class A roofs supported by wood trusses. Two series of experiments were conducted. The first series represented a room of content fire, extending into the attic space, breaching the roof and resulting in structural collapse. Three PV technologies were subjected to this fire condition – rack mounted metal framed, glass on polymer modules, building integrated PV shingles, and a flexible laminate attached to a standing metal seam roof. A second series of experiments was conducted on the metal frame technology. These experiments represented two fire scenarios, a room of content fire venting from a window and the ignition of debris accumulation under the array. The results of these experiments provide a technical basis for the fire service to examine their equipment, tactics, standard operating procedures and training content. Several tactical considerations were developed utilizing the data from the experiments to provide specific examples of potential electrical shock hazard from PV installations during and after a fire event.
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Eiffert, P. Guidelines for the Economic Evaluation of Building-Integrated Photovoltaic Power Systems. Office of Scientific and Technical Information (OSTI), January 2003. http://dx.doi.org/10.2172/15003041.

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Deline, C., B. Marion, J. Granata, and S. Gonzalez. Performance and Economic Analysis of Distributed Power Electronics in Photovoltaic Systems. Office of Scientific and Technical Information (OSTI), January 2011. http://dx.doi.org/10.2172/1004490.

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DePhillips, M. P., P. D. Moskowitz, and V. M. Fthenakis. SUNRAYCE 95: Working safely with lead-acid batteries and photovoltaic power systems. Office of Scientific and Technical Information (OSTI), May 1994. http://dx.doi.org/10.2172/10158667.

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