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Bibliographies thématiques / SOLAR PV SYSTEM

Littérature scientifique sur le sujet « SOLAR PV SYSTEM »

Auteur : Grafiati

Publié le 11 septembre 2023

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Articles de revues sur le sujet "SOLAR PV SYSTEM"

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Jia Joon, Chong, et Kelvin Chew Wai Jin. « Design of Augmented Cooling System for Urban Solar PV System ». MATEC Web of Conferences 335 (2021) : 03002. http://dx.doi.org/10.1051/matecconf/202133503002.

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Solar photovoltaic (PV) panels have been widely used to convert the renewable energy from the sun to electrical energy to power electrical loads but suffers from relatively low efficiency between 15% to 22%. Typically, the panels have an average lifespan of 25 to 30 years but could degrade quicker due to the panel overheating. Beyond the optimum working temperature of 25°C, a drop of efficiency by 0.4 to 0.5% for every 1°C had been reported. For solar PV applications in urban regions, passive cooling is beneficial due to limited amount of space and lower energy consumption compared to active cooling. A solar PV system with augmented cooling was conducted at a balcony of a condominium from 10am until 2pm. The solar PV system consisted of an Arduino controller, solar panel module, temperature sensor and LCD monitor. Reusable cold and hot gel packs were attached to the bottom of the solar PV. Both setups of solar PV panel with and without the cooling system were placed at the balcony simultaneously for measurement of temperature, output voltage and current. From this research, the outcome of implementing a cooling system to the solar PV increases the efficiency of the energy conversion.

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Elias, M. A., R. M. Jais, N. Muda, N. A. Azlin et N. M. Ahmad. « Research on Different Types of Cooling System on Ground Mounted Solar Photovoltaic System for Electrical Output Enhancement ». Journal of Physics : Conference Series 2051, n^o 1 (1 octobre 2021) : 012071. http://dx.doi.org/10.1088/1742-6596/2051/1/012071.

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Abstract Solar photovoltaic (PV) can be used to generate power by using semiconductor materials to convert solar energy into electricity. In Malaysia, solar PV technology plays a significant role in increasing renewable energy generation capacity target at 20% by 2025. Malaysia’s strategic location at the equator makes it possible to achieve this target. However, several challenges need to be mitigated when implementing this technology, among others is the effect of temperature on solar PV system performance. Solar PV panel is currently rated at a range of efficiency between 13% to 20%. The efficiency of the PV panel is affected by temperature where the PV power and efficiency decrease at the rate of -0.5%/°C and -0.05%/°C respectively as the ambient temperature increases. This study aims to evaluate the effectiveness of different types of PV cooling systems in reducing the solar PV panel temperature. In this study, the PV systems were retrofitted by two types of cooling system which are passive cooling and active cooling systems. The results of panel temperatures were measured against the control system without the cooling mechanism. The research was conducted in real operating condition with direct sunlight. Active cooling system reduced the temperature of the PV system and improved the electrical output by 4.9% while the best passive cooling system improved the output by 3%. Factors contributing to the results are also discussed in this paper.

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Mansur, T. M. N. T., N. H. Baharudin et R. Ali. « Sizing and Cost Analysis of Self-Consumed Solar PV DC System Compared with AC System for Residential House ». Indonesian Journal of Electrical Engineering and Computer Science 10, n^o 1 (1 avril 2018) : 10. http://dx.doi.org/10.11591/ijeecs.v10.i1.pp10-18.

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<p>The use of solar photovoltaic (PV) system has grown significantly in Malaysia after Renewable Energy Act has been gazetted in 2011.The objective of this paper is to highlight the technical and economic analysis of solar PV DC system to generate enough energy for residential customer group that consumed 200 kWh per month so that they are less dependent on energy from the utility grid. The results are then compared to the solar PV AC system with similar load setup. The methodology involves gathering solar energy resource, configuring daily load demand, sizing PV array, battery bank and inverter and lastly simulation of the design system by using Homer software. Based on Homer simulation, the solar PV AC system required slightly larger PV array sizes than the solar PV DC system to compensate losses due to the inverter efficiency which is not counted in DC system.Moreover, the solar PV AC system is almost 8.0% more expensive with 6% higher COE than the solar PV DC system due to the present of inverter.Lastly, both systems will benefit from reduction of energy consumed up to 2,434 kWh annually and to the environmental aspect, will avoid 1.7 tons of CO<sub>2</sub> releases into the atmosphere.</p>

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Amin, Nurhani, Agustinus Kali, Muchsin et Firman Syam. « Automatic dual-axis solar tracker system design ». MATEC Web of Conferences 331 (2020) : 06002. http://dx.doi.org/10.1051/matecconf/202033106002.

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Sunlight is one of the energy that can be used to generate electricity. Converting solar energy into electrical energy required a device called Photo-Voltaic (PV). However, output of PV hardly depends on the position of PV to the sun. The maximum PV output will reach when the sun position perpendicular to the surface of PV. Therefore, the device that can track the position of PV is needed. The aim of this research is to design a track solar system using Arduino and LDR sensor to follow the sun movement. This method will be applied to a 80 Wp solar panel. The output of the tracker solar system was compared to the fixed PV. The result shows that the output voltage of the tracker solar system reached 18. 81 V that was higher than the fixed PV about 18,56 V and the output current of the tracker solar system reached 4,27 A that was higher than the fixed PV about 4,19 A.

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Kuang, Wendy Yiwen, Chethana Illankoon et Sadith Chinthaka Vithanage. « Grid-Connected Solar Photovoltaic (PV) System for Covered Linkways ». Buildings 12, n^o 12 (5 décembre 2022) : 2131. http://dx.doi.org/10.3390/buildings12122131.

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Solar photovoltaic (PV) technology is a current trend worldwide, offering many environmental benefits. With the flagship SolarNova Programme in Singapore, solar PV has gained its momentum. However, it remains important to explore new avenues to introduce solar PV in the urban settings. The housing development board (HDB) green towns promote sustainable living. Therefore, introducing solar PV is essential. This research study aims to propose and conduct an economic evaluation on solar PV for the HDB’s covered linkways. HDB covered linkways connect buildings within the green towns. Hence, installing solar PV systems in covered linkways facilitates to self-produce required energy and export extra electricity to the grid. This research study used PVWatts calculator to calculate the power generation. A thin film solar PV is used for the study with fixed array type and azimuth is 180°. Four solar PV systems, namely (1) 4 kW, (2) 5 kW, (3)10 kW, and (4) 20 kW, were evaluated in this research study. The initial cost ranges from S$7000 to S$38,000 for the four types. For 4 kW and 5 kW systems, the payback period is 6.22 years. The highest payback period is for a 20-kW system, which is 7.4 years. The 10-kW system generates a significant portion of the electricity requirements, and the payback period is 6.04 years. This research contributes to the solar PV domain by proposing a novel grid-connected solar PV system for covered linkways while identifying the most cost-effective solution.

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Banait, Shweta, Sandeep Kumar, Sanket Shindkar et Akshay Jagdale. « SOLAR PV SYSTEM USING MICROCONTROLLER. » International Journal of Advanced Research 5, n^o 2 (28 février 2017) : 2401–6. http://dx.doi.org/10.21474/ijar01/3423.

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Ashhab, Moh’d Sami S., Hazem Kaylani et Abdallah Abdallah. « PV solar system feasibility study ». Energy Conversion and Management 65 (janvier 2013) : 777–82. http://dx.doi.org/10.1016/j.enconman.2012.02.030.

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Syahindra, Kianda Dhipatya, Samsul Ma’arif, Aditya Anindito Widayat, Ahmad Fakhrul Fauzi et Eko Adhi Setiawan. « Solar PV System Performance Ratio Evaluation for Electric Vehicles Charging Stations in Transit Oriented Development (TOD) Areas ». E3S Web of Conferences 231 (2021) : 02002. http://dx.doi.org/10.1051/e3sconf/202123102002.

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Transit Oriented Development (TOD) areas are locations that have limited land area. Solar PV systems are planned to be installed in these areas to support electric vehicles such as e-scooters, electric cars, motorcycles, and buses. However, solar PV systems in general require a large land area. The purpose of this paper is to find out and compare the Performance Ratios (PR) of a solar PV system installed on the rooftop with a floating solar PV system installed on the lake to determine which solar PV system fits better for TOD areas. PR analysis uses two methods, PVSyst software simulation and is validated using mathematical calculations. The result of the PR of floating solar PV is 76.39% using PVSyst simulation and 80.24% using mathematical calculation. Meanwhile, the PR of rooftop solar PV is 82.69% using PVSyst simulation and 73.41% using mathematical calculation. The significant factors that influence PR value are the energy produced by the solar PV system, its losses, and albedo value of the reflector surface for bifacial solar PV. Albedo value has to be maximized in order to obtain a higher performance ratio value. Based on this study, both rooftop and floating PV systems are equally suitable for TOD areas.

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Azmi, M. S. F. M., M. H. Hussain, S. R. A. Rahim, E. C. Mid, A. S. Shaari, N. Hashim, N. Husny et M. F. Ahmad. « Hybrid Cooling System for Solar Photovoltaic Panel ». Journal of Physics : Conference Series 2550, n^o 1 (1 août 2023) : 012004. http://dx.doi.org/10.1088/1742-6596/2550/1/012004.

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Abstract Solar photovoltaic (PV) panel is one of the renewable sources of energy and produced daily nowadays. Solar panel systems have efficiency influenced by different factors, such as ambient temperature, solar panel temperature, sunlight, weather, and irradiation. The increasing of the temperature of the solar PV panel decreases its efficiency and lifetime. Thus, to maintain and decrease the temperature of the PV cell, cooling system is required. This paper presents the hybrid (water and air) cooling system method for solar PV panel. The method has been designed and developed to lower and stable the operating temperature of the system considering different weather conditions. The results revealed that the hybrid cooling system has shown improvement of output power solar PV panel as compared with water cooling system only. Furthermore, the proposed method managed to improve efficiency approximately to 4.5%.

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Hossain, Ridwone, Al Jumlat Ahmed, Sheik Md Kazi Nazrul Islam, Nirupam Saha, Preetom Debnath, Abbas Z. Kouzani et M. A. Parvez Mahmud. « New Design of Solar Photovoltaic and Thermal Hybrid System for Performance Improvement of Solar Photovoltaic ». International Journal of Photoenergy 2020 (15 juillet 2020) : 1–6. http://dx.doi.org/10.1155/2020/8825489.

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Solar photovoltaic (PV) and solar thermal systems are most widely used renewable energy technologies. Theoretical study indicates that the energy conversion efficiency of solar photovoltaic gets reduced about 0.3% when its temperature increases by 1°C. In this regard, solar PV and thermal (PVT) hybrid systems could be a solution to draw extra heat from the solar PV panel to improve its performance by reducing its temperature. Here, we have designed a new type of heat exchanger for solar PV and thermal (PVT) hybrid systems and have studied the performance of the system. The PVT system has been investigated in comparison with an identical solar PV panel at outdoor condition at Dhaka, Bangladesh. The experiments show that the average improvement of open circuit voltage (Voc) is 0.97 V and the highest improvement of Voc is 1.3 V. In addition, the overall improvement of output power of solar PV panel is 2.5 W.

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Thèses sur le sujet "SOLAR PV SYSTEM"

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Franklin, Edward A. « Mounting Your Solar Photovoltaic (PV) System ». College of Agriculture, University of Arizona (Tucson, AZ), 2017. http://hdl.handle.net/10150/625443.

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Ghaghazanian, Arash. « System Integration of PV/T Collectors in Solar Cooling Systems ». Thesis, Högskolan Dalarna, Energiteknik, 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:du-19554.

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The demand for cooling and air-conditioning of building is increasingly ever growing. This increase is mostly due to population and economic growth in developing countries, and also desire for a higher quality of thermal comfort. Increase in the use of conventional cooling systems results in larger carbon footprint and more greenhouse gases considering their higher electricity consumption, and it occasionally creates peaks in electricity demand from power supply grid. Solar energy as a renewable energy source is an alternative to drive the cooling machines since the cooling load is generally high when solar radiation is high. This thesis examines the performance of PV/T solar collector manufactured by Solarus company in a solar cooling system for an office building in Dubai, New Delhi, Los Angeles and Cape Town. The study is carried out by analyzing climate data and the requirements for thermal comfort in office buildings. Cooling systems strongly depend on weather conditions and local climate. Cooling load of buildings depend on many parameters such as ambient temperature, indoor comfort temperature, solar gain to the building and internal gains including; number of occupant and electrical devices. The simulations were carried out by selecting a suitable thermally driven chiller and modeling it with PV/T solar collector in Polysun software. Fractional primary energy saving and solar fraction were introduced as key figures of the project to evaluate the performance of cooling system. Several parametric studies and simulations were determined according to PV/T aperture area and hot water storage tank volume. The fractional primary energy saving analysis revealed that thermally driven chillers, particularly adsorption chillers are not suitable to be utilizing in small size of solar cooling systems in hot and tropic climates such as Dubai and New Delhi. Adsorption chillers require more thermal energy to meet the cooling load in hot and dry climates. The adsorption chillers operate in their full capacity and in higher coefficient of performance when they run in a moderate climate since they can properly reject the exhaust heat. The simulation results also indicated that PV/T solar collector have higher efficiency in warmer climates, however it requires a larger size of PV/T collectors to supply the thermally driven chillers for providing cooling in hot climates. Therefore using an electrical chiller as backup gives much better results in terms of primary energy savings, since PV/T electrical production also can be used for backup electrical chiller in a net metering mechanism.

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Kristofersson, Filip, et Sara Elfberg. « Maximizing Solar Energy Production for Västra Stenhagenskolan : Designing an Optimal PV System ». Thesis, Uppsala universitet, Institutionen för teknikvetenskaper, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-384723.

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Skolfastigheter is a municipality owned real estate company that manages most of the buildings used for lower education in Uppsala. The company is working in line with the environmental goals of the municipality by installing photovoltaic systems in schools and other educational buildings. Skolfastigheter are planning to install a photovoltaic system in a school in Stenhagen. The purpose of this study is to optimally design the proposed system. The system will be maximized, which in this study entails that the modules will be placed on every part of the roof where the insolation is sufficient. The system will also be grid connected. The design process includes finding an optimal placement of the modules, matching them with a suitable inverter bank and evaluating the potential of a battery storage. Economic aspects such as taxes, subsidies and electricity prices are taken into account when the system is simulated and analyzed. A sensitivity analysis is carried out to evaluate how the capacity of a battery bank affects the self-consumption, self-sufficiency and cost of the system. It is concluded that the optimal system has a total peak power of almost 600 kW and a net present value of 826 TSEK, meaning that it would be a profitable investment. A battery bank is excluded from the optimal design, since increasing the capacity of the bank steadily decreased the net present value and only marginally increased the self-consumption and self-sufficiency of the system.

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John, Shobin. « Solar PV Cell Utilization and Charging System Development ». Thesis, Högskolan i Halmstad, Akademin för ekonomi, teknik och naturvetenskap, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:hh:diva-40669.

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This study is a result of master’s thesis in renewable engineering at Halmstad during spring term 2019. The main contribution of the present work focuses on the development of a significant approach to identify best possible surfaces finish strategy in terms of solar battery charging. The aim of the thesis was to analyze, compare different battery charging method and implement PV cell system to run oil pump. I would like to emphasize my thanks Professor Jonny Hylander for his support guidance, opportunely posed questions that raised new lines of thought and motive to get good work on the thesis. I would like to emphasis sincere thanks and gratitude to Mei Gong to guide throughout the thesis and support during urgent need. I am grateful to other dissertation committee members for enlightening and inspiring discussion and their advice provided us guidelines in difficult times. I would like as a final word of appreciation to thank the people of masters and research group at Halmstad University for their thoughtful comments and suggestion, which continually improve the quality of the dissertation

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Tefera, Misrak A. « Electricity Production from Concentrated Solar Power and PV System in Ethiopia ». Thesis, Högskolan i Halmstad, Akademin för ekonomi, teknik och naturvetenskap, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:hh:diva-40426.

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Ethiopia has been facing problems regarding power generation, distribution, balancingbetween demand and supply and access to modern energy service. About 92.4% of energysupply is from biomass (mostly in traditional) 5.7% oil which is not friendly with theenvironment and about 1.6% of energy supply is from renewable energy resource,hydropower plants.Being dependent on hydropower plant causes the country to face many challenges indistribution and balancing demand and supply. This thesis provides another way ofconsidering and implementing renewable energy resource (solar energy resource) throughtechnologies like grid-connected roof mounted solar PV system and CSP plant with the helpof PVGIS, PVWatt and SAM software.This thesis aims to come up with an idea that will work out for current engineering, socialand political issue that is seen in the country. Considering new way in planting PV system onthe roof is strongly recommended and increasing the alternative sites for power generationalong with the appropriate technology is recommended as another way. The possibility andpower generating efficiency is checked through each application.Based on the demonstration in all software’s used, it is clearly visible that the country couldhave been satisfied the needed demand and become the hub of east Africa as mentioned inthe policy and strategy. However, this dependency causes the country to insufficiently supplythe need. Apart from the possibilities and estimation, ideas that might help the country tocome over these challenges are provided in recommendation section.

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Perez, de la Mora Nicolas. « Energy Storage for a Grid-Connected PV-System : A Feasibility Study ». Thesis, Högskolan Dalarna, Maskinteknik, 2013. http://urn.kb.se/resolve?urn=urn:nbn:se:du-12794.

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The work presented in this thesis concerns the dimensioning of an Energy Storage System (ESS) which will be used as an energy buffer for a grid-connected PV plant. This ESS should help managing the PV plant to inject electricity into the grid according to the requirements of the grid System Operator. It is desired to obtain a final production not below 1300kWh/kWp with a maximum ESS budget of 0.9€/Wp. The PV plant will be sited in Martinique Island and connected to the main grid. This grid is a small one where the perturbations due clouds in the PV generation are not negligible anymore. A software simulation tool, incorporating a model for the PV-plant production, the ESS and the required injection pattern of electricity into the grid has been developed in MS Excel. This tool has been used to optimize the relevant parameters defining the ESS so that the feed-in of electricity into the grid can be controlled to fulfill the conditions given by the System Operator. The inputs used for this simulation tool are, besides the conditions given by the System Operator on the allowed injection pattern, the production data from a similar PV-plant in a close-by location, and variables for defining the ESS. The PV production data used is from a site with similar climate and weather conditions as for the site on the Martinique Island and hence gives information on the short term insolation variations as well as expected annual electricity production. The ESS capacity and the injected electric energy will be the main figures to compare while doing an economic study of the whole plant. Hence, the Net Present Value, Benefit to Cost method and Pay-back period studies are carried on as dependent of the ESS capacity. The conclusion of this work is that it is possible to obtain the requested injection pattern by using an ESS. The design of the ESS can be made within an acceptable budget. The capacity of ESS to link with the PV system depends on the priorities of the final output characteristics, and it also depends on which economic parameter that is chosen as a priority.

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Deng, Wenpeng. « A solar PV-LED lighting system with bidirectional grid ballasting ». Thesis, University of Cambridge, 2015. https://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.709190.

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VERMA, PALLAVI. « CONTROL OF SOLAR PV SYSTEM BASED MICROGRID FOR ENHANCED PERFORMANCE ». Thesis, DELHI TECHNOLOGICAL UNIVERSITY, 2021. http://dspace.dtu.ac.in:8080/jspui/handle/repository/18879.

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With the depletion of non-renewable resources and growing public awareness about the advantages of green energy, alternative renewable sources are evolving as a significant source of energy since past few years. Furthermore, the electrical grid is on the verge of a paradigm shift, from centralized power generation, transmission, and huge power grids towards distributed generation (DG). DG fundamentally uses small-scale generators like photovoltaic (PV) panels, wind turbine, fuel cells, small and micro hydropower, diesel generator set, etc., and is limited to small distribution networks to produce power close to the end users. Renewable energy sources (RES) are essential components of DG because they are more environment friendly than conventional power generators and once established maintenance cost is also low. One of the most popular renewable energy source is solar energy because it is abundant, accessible and can be easily converted into electricity. The electricity produced from SPV system can be utilized by the local loads within the microgrid or it can be integrated with conventional grid. Microgrid (MG), which is a cluster of distributed generation, renewable sources, and local loads connected to the utility grid provides solution to manage local generations and loads as a single grid level entity. It has the potential to maximize overall system efficiency, power quality, and energy surety for critical loads. A microgrid can operate either in stand-alone mode or grid connected mode. Due to abundant availability of solar energy, an SPV based microgrid is widely used around the world. Due to intermittent nature of solar energy, stand-alone SPV based microgrid needs an energy storage system also, whereas in grid connected system, the microgrid is connected to conventional grid which takes care of the solar intermittency by having bi-directional flow of power. Depending on the technical specifications, grid-connected solar PV- based microgrid can be single-stage or double-stage. In single stage configuration, PV array is directly connected to a DC/AC converter whereas in double-stage configuration, DC/DC converter is coupled in between the solar PV array and PV inverter and provides the desired fixed DC voltage to the inverter. The present work aims at modelling, design, development and control of a solar PV vii based microgrid for enhanced performance. Also, the characterization studies of the developed system have been carried out. Modeling of the system is required in order to predict its behaviour under both steady and dynamic states. Characterization studies such as sensitivity and reliability analysis are used to evaluate the performance of the system. Sensitivity analysis is the performance evaluation technique for evaluating the change in the system’s performance with respect to the change in its parameters. The sensitivity functions for solar cell and boost converter with respect to influential parameters have been developed using first derivative of Taylor’s series. Reliability analysis for electrical and electronic components of the system have been performed using pareto analysis and reliability model of the PV based microgrid has been developed using reliability block diagram for different PV array configurations. The Fault tree analysis (FTA) model of the system has been developed to find the cause of failure and to step the events leading to failure serially. Further, Markov’s model has been used to develop the reliability functions of individual components and hence, the reliability of complete grid connected PV system has been calculated. Solar PV system gives maximum power under uniform shading. But many a times PV panels are non-uniformly irradiated and this condition is known as called partial shading condition (PSC). PSC occur due to shadow of big trees, nearby buildings and dense clouds etc. PSC in PV system is an inevasible situation and exhibits multiple peaks, consisting of a single global maximum power point and many local maximum power points, in its power-voltage curve. PSC makes tracking of global maximum power point more difficult and also reduces the efficiency of the system. The conventional MPPT control algorithms work well under uniform shading condition but under partial shading scenario, they may not be able to track global peak out of multiple peaks. Therefore, an efficient controller is required to overcome the raised issue. Further, various PV array configurations such as series, series-parallel, total cross tied, bridge linked etc. may be used to improve the system efficiency. In the present work, novel maximum power point control algorithms viz. an asymmetrical fuzzy logic control (AFLC) and asymmetrical interval type-2 FLC (AIT-2 FLC) are developed for stand-alone PV system under partial shading condition. The developed algorithms are tested for different PV array configurations. viii In stand-alone PV system, the power supplied to the load depends upon the available solar energy. The output of SPV is intermittent in nature as it depends on the environmental conditions. This intermittency problem can be addressed by adding an energy storage system along with PV system. Battery is the most commonly used energy storage device and is very pivotal in maintaining continuity of power to the load. But when two or more energy sources are connected, then control of dc link voltage at common coupling point (CCP) is an area of concern. Therefore, in a SPV system with BESS a controller is required which can maintain constant DC link voltage irrespective of system transients. The PI controller is commonly used controller for controlling dc- link voltage, but it cannot regulate DC-link voltage under dynamic operating conditions and have overshoots and long settling time in its response. Suitable intelligent controllers are designed to replace the conventional PI controller, as they provide a better transient response. In order to overcome the drawbacks of the conventional PI control algorithm, nonlinear autoregressive moving average-L2 (NARMA-L2) control algorithm is proposed and developed for the stand-alone PV system with BESS. The proposed control scheme maintains the voltage across DC-link under change in irradiation and load condition. In a grid connected SPV based microgrid, the output of boost converter i.e., DC link is connected to voltage source inverter which is connected to grid at the point of common coupling (PCC). Voltage source inverter converts the generated DC power from PV system to AC of required voltage and frequency, as well as maintains the balance of power between the SPV system, load, and grid. The inverter is regulated by the interfacing controllers for effective operation and grid synchronization. The interfacing controllers are used to control the output of PV inverter for its efficient utilization and for improving power quality at PCC by providing reactive power compensation, harmonics compensation and load balancing. Conventional control algorithm like synchronous reference frame theory (SRFT) uses proportional integral (PI) controller for DC-link voltage regulation. These controllers are not best suited for SPV based microgrid as the overshoots and long settling time in their response are inevitable. In order to overcome this, novel smooth Least Mean Square (SLMS), improved zero attracting LMS (IZALMS) and reweighted L0 norm variable step size continuous mixed p-norm (RL0-VSSCMPN) based adaptive interfacing control algorithms are proposed ix and developed for the PV based microgrid. The efficacy of the proposed control algorithms has been tested on hardware prototype developed in the laboratory using MicroLab box (dSPACE 1202). The developed prototype system acts as distribution static compensator (DSTATCOM) and consists of inverter that is tied in parallel to the grid at the point of common coupling. FLUKE power analyzer has been used to measure the response of the system. The research work presented in the thesis is expected to provide good exposure to design, development and control of the solar PV based microgrid.

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Manhal, Ali, et Ali Tammam M. « Solar Tent : A Photovoltaic Generator Model for a Flexible Fabric with Inbuilt Cells ». Thesis, Högskolan Dalarna, Energiteknik, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:du-30552.

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Natural disasters and conflicts in many different parts of the world force thousands of people to get displaced from their homes and live in refugee camps temporarily or permanently. For refugee families, lack of energy access has great impact on their lives. Tarpon Solar Company has developed a solar tent which is a combination of laminated cloth and flexible solar cells. In addition to producing renewable electricity, it can create a comfortable outdoor shelter from sun, rain and wind. The aims of this study were to define and size the solar system of the tent in both AC and DC systems and optimize the tent to work in different locations around the world. Besides designing a monitoring system for the solar tent to evaluate the performance. In addition, defining the social aspect and the consumer behavior for a better solar tent future design. As a case study, Tarpon AC solar tent in Glava, Sweden has been installed to cover the basic needs of the tent users. To understand the solar tent performance in different weather zones, 4 different locations were suggested. A monitor system was designed to monitor the tent solar system performance. The simulation software PVsyst was used to size the PV system in the different locations with different solar data. The PVsyst simulation results showed that the current Tarpon solar tent with 32 photovoltaic modules is extremely oversized to cover the basic needs loads (Lighting, mobile charging and ventilation) in the emergency cases. The current Tarpon solar tent has a standard number of photovoltaic modules integrated in the tent fabric while the photovoltaic modules number should vary from one location to another according to the weather data and solar irradiation. In this case the current Tarpon solar system used in Glava, Sweden can be optimized by decreasing the number of photovoltaic modules to only 6 photovoltaic modules instead of 32 modules. The study also shows that the features of the off-grid system components (battery and charge controller) are different from one location to another according to the criteria of selection. This study concludes that for the temporary short-term emergency use of the tent where only basic needs loads are needed, DC system is better than AC system in terms of energy efficiency, system size and cost in the different proposed locations. While AC system is better when using the tent for prolonged time in terms of user flexibility and ability to extend the system. Understanding the consumer behavior and the goal of the tent whether to be used for an emergency short term shelter or a permanent shelter for a prolonged time are important factors for a better solar tent design.

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Solanes, Bosch Júlia. « Investigation of the Performance of a Large PV system ». Thesis, Högskolan i Gävle, Energisystem, 2017. http://urn.kb.se/resolve?urn=urn:nbn:se:hig:diva-25163.

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One of the main social challenges that society is facing nowadays is the energy crisis. So, head towards renewable energy resources such as solar, hydraulic, wind, geothermal and biomass, could be the best solution. Solar photovoltaic is one of the most promising sources to produce electricity due to its cleanness, noiselessness and sustainability, and the fact that it is inexhaustible. However, the power output of the PV systems varies notably because of the ambient conditions: temperature and solar radiation. The main aim of this thesis is to study if the PV system installed on the wall of the new football arena Gavlehov in Gävle is providing the amount of power promised before the installation. To achieve reliable results, the first step is to develop and install a monitoring system for recording the real power of the system and the ambient conditions at the same time. After that, an evaluation of the performance of the system during one week will be done, comparing the theoretical power and the real power obtained. The theoretical power will be calculated in two ways: using the data from a pyranometer and on the other hand, from a reference solar cell. This will permit to compare which one matches better with the reality. Different factors such as the temperature, the irradiance and the angle of incidence are studied to know the real influence that they have on the performance of a PV installation. The results obtained show that the measurement system installed is reliable and that the model used to evaluate the system is correct. It can be concluded that using a reference solar cell to calculate the theoretical power of the system is easier to align and it has the same angular behaviour as a PV module than employing a pyranometer. Regarding the installation, all the panels work similarly and the system works at nominal power. So, it provides the amount of power promised before the installation. Key words: Renewable energy, PV system, solar radiation, nominal power, pyranometer, solar cell.

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Livres sur le sujet "SOLAR PV SYSTEM"

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Goodrich, Alan C. Solar PV manufacturing cost model group : Installed solar PV system prices. Golden, Colo.] : National Renewable Energy Laboratory, 2011.

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Neelanarayanan, dir. Solar PV Based Wireless Remote Airfield Lighting System. VIT University Chennai, India : Association of Scientists, Developers and Faculties, 2014.

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Emery, K. Monitoring system performance : Venue : PV Module Reliability Workshop. Golden, Colo.] : National Renewable Energy Laboratory, 2011.

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Cartmell, Ben. A multi-operational, combined PV/Thermal and solar air collector system : Application, simulation and performance evaluation. Leicester : De Montfort University, 2004.

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Goodrich, Alan. Residential, commercial, and utility-scale photovoltaic (PV) system prices in the United States : Current drivers and cost-reduction opportunities. Golden, Colo : National Renewable Energy Laboratory, 2012.

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6

Sumathi, S., L. Ashok Kumar et P. Surekha. Solar PV and Wind Energy Conversion Systems. Cham : Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-14941-7.

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(Organization), IT Power, dir. Solar photovoltaic power generation using PV technology. [Manila?] : Asian Development Bank, 1996.

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Lowder, Travis. The potential of securitization in solar PV finance. Golden, CO : National Renewable Energy Laboratory, 2013.

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Institute for Energy (European Commission) et European Commission. Joint Research Centre., dir. PV status report 2008 : Research, solar solar cell production and market implementation of photovoltaics. Luxembourg : Office of Official Publications of the European Communities, 2008.

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Ray, George, Bush Brian, National Renewable Energy Laboratory (U.S.) et Colorado Renewable Energy Conference (2009), dir. Estimating solar PV output using modern space/time geostatistics. Golden, Colo.] : National Renewable Energy Laboratory, 2009.

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Chapitres de livres sur le sujet "SOLAR PV SYSTEM"

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Kaushika, N. D., Anuradha Mishra et Anil K. Rai. « Solar PV System Economics ». Dans Solar Photovoltaics, 143–54. Cham : Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-72404-1_13.

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van Sark, Wilfried, Atse Louwen, Odysseas Tsafarakis et Panos Moraitis. « PV System Monitoring and Characterization ». Dans Photovoltaic Solar Energy, 553–63. Chichester, UK : John Wiley & Sons, Ltd, 2017. http://dx.doi.org/10.1002/9781118927496.ch49.

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Muneer, Tariq, et Yash Kotak. « Performance of Solar PV Systems ». Dans Solar Photovoltaic System Applications, 107–35. Cham : Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-14663-8_5.

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Mohanty, Parimita, Tariq Muneer, Eulalia Jadraque Gago et Yash Kotak. « Solar Radiation Fundamentals and PV System Components ». Dans Solar Photovoltaic System Applications, 7–47. Cham : Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-14663-8_2.

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Mohanty, Parimita, K. Rahul Sharma, Mukesh Gujar, Mohan Kolhe et Aimie Nazmin Azmi. « PV System Design for Off-Grid Applications ». Dans Solar Photovoltaic System Applications, 49–83. Cham : Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-14663-8_3.

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Mohanty, Parimita, et Mukesh Gujar. « PV Component Selection for Off-Grid Applications ». Dans Solar Photovoltaic System Applications, 85–106. Cham : Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-14663-8_4.

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Dhruv, Vyas, Chudasama Richa, Ambaleeya Afasana, Bosamiya Swati, Gajjar Rital et Pandya Rajen. « Grid Integration of Solar PV System ». Dans Lecture Notes in Electrical Engineering, 135–45. Singapore : Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-15-0226-2_11.

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Sharma, K. Rahul, Debajit Palit et P. R. Krithika. « Economics and Management of Off-Grid Solar PV System ». Dans Solar Photovoltaic System Applications, 137–64. Cham : Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-14663-8_6.

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Kala, Peeyush. « Artificial Intelligence in PV System ». Dans Applied Soft Computing and Embedded System Applications in Solar Energy, 65–82. First edition. | Boca Raton, FL : CRC Press, 2021. | : CRC Press, 2021. http://dx.doi.org/10.1201/9781003121237-4.

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Jose, Kiran, S. Sheik Mohammed et O. Mohammed Mansoor. « Performance Study of Solar PV System with Bifacial PV Modules ». Dans Lecture Notes in Electrical Engineering, 659–70. Singapore : Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-19-4971-5_48.

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Actes de conférences sur le sujet "SOLAR PV SYSTEM"

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Stone, Kenneth W., Vahan Garboushian et Herb Hayden. « Design and Performance of the Amonix High Concentration Solar PV System ». Dans ASME Solar 2002 : International Solar Energy Conference. ASMEDC, 2002. http://dx.doi.org/10.1115/sed2002-1047.

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Amonix has designed, manufactured, installed, and tested over 500 kW of high concentrating PV systems based around a concentrating silicon cell that set a new world efficiency record in 1992. This paper describes the development of this product as well as the physical and operating characteristics of the system. The operating characteristics that make this system attractive for grid, distributed, and off-grid are discussed. Data is presented that demonstrates the high daily power generating capability and the energy performance of the concentrating PV system. Other attributes of the system are also discussed such as the automatic/unattended operation, the short installation time, etc. An array installed at Pomona, CA is described, it has operated unattended for over 3 years and is still producing power today.

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El-Shatter, Thanaa F., Mona N. Eskandar et Mohsen T. El-Hagry. « Hybrid PV/Fuel Cell System Design and Simulation ». Dans ASME 2001 Solar Engineering : International Solar Energy Conference (FORUM 2001 : Solar Energy — The Power to Choose). American Society of Mechanical Engineers, 2001. http://dx.doi.org/10.1115/sed2001-134.

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Abstract In this paper, a hybrid Photovoltaic (PV)-fuel cell generation system employing an electrolyzer for hydrogen generation is designed and simulated. The system is applicable for remote areas or isolated loads. Fuzzy regression model (FRM) is applied for maximum power point tracking (MPPT) to extract maximum available solar power from PV arrays under variable insolation conditions. The system incorporates a controller designed to achieve continuous supply power to the load via the PV array or the fuel cell, or both according to the power available from the sun. The simulation results show that the system can run without power shortage for more than four days even in case of zero insolation.

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Chikwendu, Tochukwu. « Solar Energy in Pueblo : PV System Owners’ Perspective ». Dans American Solar Energy Society National Solar Conference 2017. Freiburg, Germany : International Solar Energy Society, 2017. http://dx.doi.org/10.18086/solar.2017.03.02.

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Larsen, Chris, Jennifer Szaro, William Wilson et Kevin Lynn. « An Alternative Approach to PV System Life Cycle Cost Analysis (PV LCC) : Phase II ». Dans ASME 2005 International Solar Energy Conference. ASMEDC, 2005. http://dx.doi.org/10.1115/isec2005-76079.

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This analysis expands the photovoltaic (PV) life cycle cost (LCC) results presented at ASES 2004. That paper presented the model and concept used to develop PV LCC, and it showed the results of the analysis of over one hundred systems monitored by the Florida Solar Energy Center (FSEC). FSEC began tracking cost, performance and reliability data for systems installed in Florida in 1998, with data now available through a web-accessible database. For the majority of the 124 systems, installed cost information was collected as part of the state’s PV rebate and PV for schools programs. Results presented previously [1] indicated that over an assumed 20–30 system life time a PV system will have a positive life cycle cost. That is, a negative total return on investment. These results were based on actual cost, performance, maintenance, and reliability data. In the baseline case, average total system costs over the lifetime were 32.4¢/kWh while electricity savings totaled 3.7¢/kWh netting a life cycle cost of 28.7¢/kWh. While based on actual data from over 100 installed systems — some installed for over 6 years — a number of conservative assumptions also drove the analysis, such as the exclusion of the state’s rebate programs (varying from $2 to $5 per DC Watt) which impacted nearly all of the systems in the analysis. Since the first presentation of these results the PV LCC model has been further developed to incorporate additional performance information and expands the sample of systems incorporated. This paper will thus provide further insight into the relative importance of various up-front and on-going costs to the overall lifetime economics of a system. The paper will also address additional sensitivity analysis performed. Particular attention is paid to inverter mean time between failure (MTBF), the impact of incentives, and basic financial assumptions used in the model such as the discount rate and electricity rates. Various scenarios are considered in asking the question of what is necessary for the system LCC to break-even.

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Wohlgemuth, John, et Sarah Kurtz. « International PV QA Task Force's proposed comparative rating system for PV modules ». Dans SPIE Solar Energy + Technology, sous la direction de Neelkanth G. Dhere, John H. Wohlgemuth et Rebecca Jones-Albertus. SPIE, 2014. http://dx.doi.org/10.1117/12.2067927.

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Larsen, Chris, Jennifer Szaro et William Wilson. « An Alternative Approach to PV System Life Cycle Cost Analysis ». Dans ASME 2004 International Solar Energy Conference. ASMEDC, 2004. http://dx.doi.org/10.1115/isec2004-65082.

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This analysis uses actual installed system costs from available data to better assess and understand the real installed and life cycle costs for small-scale photovoltaic (PV) installations. Most PV systems are sold on the basis of first cost, but in addition to these first costs, system owners must consider operation and maintenance (O&M) costs and down time, as well as energy savings [1]. The challenge in developing realistic life cycle costs is that most databases have only new data available, and only one database — that maintained by the Florida Solar Energy Center (FSEC) — contains performance information along with cost and maintenance data. The goals of this effort are to: 1. Characterize the actual life cycle costs (LCC) of PV systems installed in Florida and tracked since 1998. 2. Develop a benchmark of PV LCC that will aid in prioritizing cost improvement steps and feed into the U.S. Department of Energy and its subcontractors’ efforts to develop a baseline for grid-connected small residential and larger commercial PV system costs. 3. Develop an easy to use and modify LCC model that allows sensitivity analysis and input of new data as it becomes available. The PV system LCC model developed and used here is based on statistical methods, which provide us with a range of expected outcomes. The Monte Carlo technique allows the use of repeated simulation iterations to mimic a population sample. For inputs, the model relies largely on data from FSEC’s performance and maintenance databases, and where appropriate simplifying assumptions are explained. Beyond establishing an LCC baseline, this project considers the sensitivity of the total LCC to various inputs and thereby provides guidance on the question of where to put valuable resources to substantially reduce PV system costs. Further discussion is offered concerning the additional value of this model in determining the impact of various methods of PV system performance tracking.

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Sanidad, L., Y. Baghzouz, R. Boehm et Earl Hodge. « Field Tests of a PV-Powered Air Monitoring System ». Dans ASME 2001 Solar Engineering : International Solar Energy Conference (FORUM 2001 : Solar Energy — The Power to Choose). American Society of Mechanical Engineers, 2001. http://dx.doi.org/10.1115/sed2001-133.

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Abstract A compact stand-alone PV power system was recently designed and built to run an air sampler for environmental monitoring at the Nevada Test Site. This paper presents an overview of the system design and analysis of some of the recorded daily cycles of various power flows during the summer period. The system long-term performance during both high and low solar resource periods is simulated with the computer code PVFORM using historical weather data.

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Kaushik, A., et A. Golnas. « PV system reliability : lessons learned from a fleet of 333 systems ». Dans SPIE Solar Energy + Technology, sous la direction de Neelkanth G. Dhere, John H. Wohlgemuth et Kevin W. Lynn. SPIE, 2011. http://dx.doi.org/10.1117/12.893172.

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Wei, Bing, et Fei Ma. « Exergy Analysis of PV-Water Cooling System and PV-SAHP System ». Dans ASME 2010 4th International Conference on Energy Sustainability. ASMEDC, 2010. http://dx.doi.org/10.1115/es2010-90386.

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With the increase of the energy crisis and environmental pollution, the solar energy as a clean and renewable energy is paid more attention. The photovoltaic cells are being widely used, and many researchers are studying the light and heat integration of photovoltaic systems (PV/T). PV-water cooling system and PV-SAHP system are all the integration of solar photovoltaic systems and thermal utilization system, which use the solar energy to supply the electric power and space heating or daily hot water. Due to the difference of the equipment installations and application conditions, two systems are different from their system efficiencies. To analyze the system exergy is of great significance, as the energy loss and utilization deficiency can be identified through the exergy analysis, and based on the analyzed results the system efficiency can be improved. Furthermore the system can be optimized by the exergy efficiency calculation. In this paper the exergy values of two systems are analyzed, the energy loss and utilization deficiency are analyzed, and the exergy efficiencies are obtained. The work will be good references for the application and optimization of solar photovoltaic systems and thermal utilization system.

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Lynn, Kevin, Jennifer Szaro, William Wilson et Michael Healey. « A Review of PV System Performance and Life-Cycle Costs for the SunSmart Schools Program ». Dans ASME 2006 International Solar Energy Conference. ASMEDC, 2006. http://dx.doi.org/10.1115/isec2006-99112.

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In January of 2003, the Florida Department of Environmental Protection/Florida Energy Office (DEP/FEO) allocated $600,000 in hardware funds toward the installation of photovoltaic (PV) solar systems on Florida schools. As a result of this program, grid-connected PV systems less than six kilowatts in size were installed on 29 schools in the State of Florida. The Florida Solar Energy Center (FSEC) has monitored these systems for approximately one year of operation. The performance of 28 of these systems was analyzed using standard performance parameters such as the performance ratio, PV array efficiency, inverter efficiency, and PV system efficiency. In addition, a life-cycle cost analysis was conducted using new cost data values and updated market assumptions. These data will serve as a benchmark to compare against future systems with respect to performance vs. installed system cost.

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Rapports d'organisations sur le sujet "SOLAR PV SYSTEM"

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Mills, A., A. Botterud, J. Wu, Z. Zhou, B.-M. Hodge et M. Heaney. Integrating Solar PV in Utility System Operations. Office of Scientific and Technical Information (OSTI), novembre 2013. http://dx.doi.org/10.2172/1107495.

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Mills, A., A. Botterud, J. Wu, Z. Zhou, B.-M. Hodge et M. Heany. Integrating Solar PV in Utility System Operations. Office of Scientific and Technical Information (OSTI), octobre 2013. http://dx.doi.org/10.2172/1164898.

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Peek, Richard T. Innovative Ballasted Flat Roof Solar PV Racking System. Office of Scientific and Technical Information (OSTI), décembre 2014. http://dx.doi.org/10.2172/1167673.

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Conger, Steven. Highly Effective Steel Cable Solar PV Mounting System. Office of Scientific and Technical Information (OSTI), octobre 2017. http://dx.doi.org/10.2172/1808878.

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Ramos, Jaime. Operation of Grid-tied 5 kWDC solar array to develop Laboratory Experiments for Solar PV Energy System courses. Office of Scientific and Technical Information (OSTI), décembre 2012. http://dx.doi.org/10.2172/1061479.

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Kollins, K., B. Speer et K. Cory. Solar PV Project Financing : Regulatory and Legislative Challenges for Third-Party PPA System Owners. Office of Scientific and Technical Information (OSTI), novembre 2009. http://dx.doi.org/10.2172/969152.

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Furman, Burford, Laxmi Ramasubramanian, Shannon McDonald, Ron Swenson, Jack Fogelquist, Yu Chiao, Alex Pape et Mario Cruz. Solar-Powered Automated Transportation : Feasibility and Visualization. Mineta Transportation Institute, décembre 2021. http://dx.doi.org/10.31979/mti.2021.1948.

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A solar-powered automated transportation network (ATN) connecting the North and South campuses of San José State University with three passenger stations was designed, visualized, and analyzed in terms of its energy usage, carbon offset, and cost. The study’s methodology included the use of tools and software such as ArcGIS, SketchUp, Infraworks, Sketchup, Rhinoceros, and Autodesk 3DS Max. ATN vehicle energy usage was estimated using data from the university’s Park & Ride shuttle bus operation and by modeling with SUMOPy, the advanced simulation suite for the micro-traffic simulator SUMO. The energy study showed that an extensive solar photovoltaic (PV) canopy over the guideway and stations is sufficient for the network to run 24/7 in better-than-zero net-metered conditions—even if ridership were to increase 15% above that predicted from SJSU Park & Ride shuttle data. The resulting energy system has a PV-rated output of 6.2 MW, a battery system capacity of 9.8 MWh, and an estimated cost of $11.4 million USD. The solar ATN also produces 98% lower CO2 and PM2.5 emissions compared to the Park & Ride shuttle bus. A team of experts including urban planners, architects, and engineers designed and visualized the conceptual prototype, including a comprehensive video explaining the need for solar ATN and what a typical rider would experience while utilizing the system. This research demonstrates both benefits and challenges for solar-powered ATN, as well as its functionality within the urban built environment to serve diverse San José neighborhoods.

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Stern, M., G. Duran, G. Fourer, K. Mackamul, W. Whalen, M. van Loo et R. West. Development of a low-cost integrated 20-kW-AC solar tracking subarray for grid-connected PV power system applications. Final technical report. Office of Scientific and Technical Information (OSTI), juin 1998. http://dx.doi.org/10.2172/656846.

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Doyle, C., A. Truitt, D. Inda, R. Lawrence, R. Lockhart et M. Golden. Solar Access to Public Capital (SAPC) Working Group : Best Practices in PV System Installation ; Version 1.0, March 2015 ; Period of Performance, October 2014 - September 2015. Office of Scientific and Technical Information (OSTI), mars 2015. http://dx.doi.org/10.2172/1215054.

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Stern, M., R. West, G. Fourer, W. Whalen, M. Van Loo et G. Duran. Development of a low-cost integrated 20-kW ac solar tracking sub- array for grid-connected PV power system applications. Phase 1, Annual technical report, 11 July 1995--31 July 1996. Office of Scientific and Technical Information (OSTI), juin 1997. http://dx.doi.org/10.2172/549670.

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