Global ETD Search

21	Développement de cellules photovoltaïques à hétérojonction de silicium et contacts interdigités en face arrière / Development of interdigitated back contact silicon heterojunction solar cells De Vecchi, Sylvain 01 July 2013 (has links) Cette thèse est axée sur la fabrication et l’optimisation d’une nouvelle structure permettant théoriquement d’améliorer les performances des cellules à base de silicium cristallin. Cette nouvelle architecture de cellule utilise la technologie des hétérojonctions de silicium a-Si:H/ c-Si (Si-HJ) appliquée sur des structures à contacts interdigités en face arrière (IBC). Le potentiel de rendement des cellules IBC Si-HJ est supérieur à 25%, mais leur fabrication nécessite une localisation des couches de a-Si:H de dopage différent et de leurs métallisations. L’intégration de ces étapes dans un procédé simplifié utilisant des techniques industrielles (PECVD, pulvérisation, sérigraphie et laser) a été étudiée. De plus, une structure obtenue sans séparation entre le BSF et l’émetteur est présentée, permettant de réduire le nombre d’étapes de fabrication. Les avantages ainsi que les limites liés à cette architecture simplifiée ont été illustrés du point de vue expérimental et par simulation. Dans le cadre de ces travaux, le rendement maximum atteint sur les dispositifs IBC Si-HJ simplifiés de 25cm² est de 19% (substrats de type n), ce qui constitue le 3e meilleur résultat au niveau mondial. Les performances des cellules restent encore limitées par l’absorption des couches de a-Si:H utilisées pour la passivation de la face avant, et par la conductivité des couches dopées en face arrière. De nombreuses pistes d’amélioration sont explorées dans cette étude. Un procédé de métallisation innovant a également été élaboré pour le passage sur des substrats de grande taille (150cm²). Il permet de limiter les pertes résistives tout en offrant de la flexibilité au niveau de la géométrie des contacts. La mise en module de cellules ayant ce design de métallisation a ensuite été étudiée, et un module de 4 cellules IBC Si-HJ a pu être fabriqué. / This thesis studies the fabrication and the optimization of a new structure to enhance the efficiency of crystalline silicon based solar cells. This new cell design uses a-Si:H/c-Si heterojunction (Si-HJ) technology applied on interdigitated back contact structures (IBC). With IBC Si-HJ solar cells, the efficiency potential is theoretically higher than 25%. Their fabrication requires to pattern doped a-Si:H and the associated metallization on the same side. The implementation of those process steps has been carefully studied. All processes used in this study are potentially industrial (PECVD, sputtering, screen-printing, and laser) and the obtained structure without buffer layer between the BSF and the emitter allows to reduce fabrication steps. Issues linked to this design have been investigated. Within the frame of this work, the maximum efficiency reached on reduced size devices (25cm²) with n-type substrate and is 19% which is the 3rd best result worldwide. The cell performances are still limited by the absorption of front surface passivating layer (a-Si:H) and by the low doped layer conductivity. Several optimization ways are explored in this study. An innovative metallization process is then elaborated to allow large area solar cell fabrication while limiting resistive losses and offering more flexibility on metallized pattern. The interconnection and the encapsulation of cells with this metallization design have been illustrated and a module with 4 cells has been fabricated. Electrostatique Photovoltaïsme Cellule photovoltaïque Silicium cristallin Procédé de metalisation Electrostatics Photovoltaics Photovoltaic Cell Crystalline Silicon Metallizing 537.540 72
22	Studium změny vlastností perovskitovských fotovoltaických článků za dobu jejich života / Characterization of the perovskit photovoltaic cells Dvořák, Tomáš January 2017 (has links) The thesis discusses the problematics of perovskite solar cells. The introduction deals with the history of the solar cells as the next part is dedicated to generations of them as well as to their principle and the variables measured in photovoltaic cells. The next part deals with perovskites, their properties and structure. Later the part about perovskite solar cells follows. The last part is dedicated to experiments which were executed on samples of perovskite solar cells.
23	Časové změny vlastností fotovoltaických článků / Time changes of the photovoltaic cells properties Kvapil, Jakub January 2018 (has links) The thesis is about the problematics of perovskite, production of perovskite structure and measurment of photovoltaic cells. The introduction deals with material properties and sctructure of perovskite. There is explained a problem of perovskit photovoltaic cells and production of perovskite structure. Then the measurement methods are explained, which are used for evaluation of photovoltaic cells properties.
24	Vliv okolních podmínek na recyklaci solárních modulů / The influence of environmental conditions of the recycling of solar modules Langer, Filip January 2021 (has links) This thesis is focused on experiments, goal of which is to separate protective glass apart from thin layer solar panel. This could lead to less expensive and more efficient recycling. We try to achieve the separation of the glass by thawing ethylene vinyl acetate layer, which serves as insulant and bonding material. Experiments are concluded in high temperature dryer and high temperature vacuum oven on samples of thin layer solar panel, which is for the purposes of experiments cut into same pieces by water jet cutting machine. The initiatory experiments in dryer and oven are to determine value of ethylene vinyl acetate thaw point in tested samples of panel. The thaw point is determined to be 340 °C. When exposed to this temperature, the ethylene vinyl acetate thaws enough for glass to be able to be extracted with minimal physical strength. The process is accompanied by fire destruction of tedlar layer and creation of exhaust gases. Following experiments in vacuum and nitrogen environment are to test their influence on thawing process. Exposing sample to temperature of 340 °C in vacuum led to no new results. Exposing sample to temperature of 340 °C in nitrogen environment prevented fire and achieved same level of thawing of ethylene vinyl acetate while creating less exhaust gases. Even though the fire was prevented, tedlar layer was still destroyed by the high temperature. Furthermore, particles of evaporated ethylene vinyl acetate condensed on surface of module in form of dust. Following experiments studied absorption of panel and influence of accessible solvents on thawing process. It was determined that panel is able to absorb approximately 2 % of acetone, 0,4 % of isopropyl alcohol and 0,11 % of distilled water in its own weight. Experiments with modules soaked in these solvents proved no new results in thawing process. By observing samples of ethylene vinyl acetate taken from module, thawed out of module after experiment in vacuum oven and dust condensed on surface of module after experiment in nitrogen environment, it was proven that the condensed dust is indeed ethylene vinyl acetate.
25	Vyhodnocení vlastností fotovoltaických článků s optickými koncentrátory / Evaluation of photovoltaic cells with optical concentrators Pončík, Vlastimil January 2011 (has links) This work deals about the photovoltaic systems, especially with concentration of the sunlight in use of concentrators that are placed direct on the panel. Concentrated photovoltaics systems employ sunlight concentrated onto photovoltaic surfaces for the purpose of more efficient electrical power production. A photovoltaic cell with concentrator includes difractive optical elements that concentrate light on a photovoltaic chip Flat polycarbonate optical element has difractive gratings on its surface.
26	Optimalizace tepelných vlastností struktur modulů fotovoltaických článků / Optimalisation of thermal properties of solar cell modules Dohnalová, Lenka January 2010 (has links) The topic of presented diploma thesis is study of thermal properties structures of photovoltaic cells. The main goal of this thesis is study of ways of heat spreading from volume and planar materials (conduction, convection and radiation). Then it is needed to determine contributions of heat spread from laminated photovoltaic cell and compare them to results measured by transient pulse method, step wise method and with thermo-camera using. At the beginning of this thesis it will be needed to define heat and ways it’s spread. Heat is closely connected with temperature. That is reason why will be there spoken about temperature and methods of its measuring. Than there will be defined basic thermo-physical parameters of materials. Thermo-physical parameters of materials will be measured by transient methods that will be characterized later and by thermo-camera. This thesis deals with photovoltaic cells, so there will be described their structure, properties, utilization and way of their production. Subsequently after the definition of all needed terms the experimental part of this thesis will be introduced. It will be needed to characterize measured volume material and define its thermo-physical parameters. Using the pulse transient method, step wise method and thermo-camera there will be measured the thermal response of PMMA sample, nonlaminated photovoltaic cell and also samples of laminated photovoltaic cells. Findings of all described methods will be finally compared.
27	Charge transport in organic multi-layer devices under electric and optical fields Park, June Hyoung 17 July 2007 (has links) No description available. Physics, Condensed Matter polymer field effect transistor PEDOT/PSS organic photovoltaic cell dendrimer porphyrin
28	Modélisation numérique de la solidification et de la ségrégation des impuretés lors de la croissance du silicium photovoltaïque à l'aide d'une méthode originale de maillage glissant / Simulation of solidification and segregation of impurities for the crystallization process of photovoltaic silicon with an original moving mesh method Tavernier, Virgile 19 December 2018 (has links) Les panneaux photovoltaïques ont pris ces dernières années une place importante dans le secteur de l’énergie. Les performances de ces panneaux dépendent notamment de la qualité et de l’homogénéité du silicium utilisé et des impuretés qu’il contient. Pour obtenir du silicium photovoltaïque, on peut utiliser un procédé de solidification dirigée afin d’obtenir un lingot de silicium de grade photovoltaïque à partir de silicium de grade métallurgique. Cette approche reste aujourd’hui difficile à simuler efficacement en raison de l’aspect multi-échelle du procédé et du suivi de l’interface mobile avec des transferts de masse et de chaleur à l’interface solide/liquide. Cette thèse présente la mise en œuvre d’une méthode originale de maillage glissant proposée pour réaliser un suivi adaptatif de l’interface mobile, afin d’améliorer l’efficacité des simulations. Dans un premier temps, la modélisation de la solidification dirigée d’un corps pur avec un tel maillage glissant est validée à l’aide d’une solution analytique dans une configuration diffusive de référence. L’impact de la méthode proposée est ensuite étudié dans une configuration de type Bridgman vertical en présence de convection naturelle dans la phase liquide. Dans un second temps, on s’intéresse à la ségrégation des impuretés dans cette même configuration. Pour cela, on propose une modélisation spécifique du rejet d’impuretés à l’interface, et on étudie l’impact sur les simulations de la méthode de maillage glissant proposée. Les résultats et les gains de performance pour les simulations sont discutés en faisant varier des paramètres de calcul et par comparaison avec des données de la littérature. / In recent years, photovoltaic panels took a key role in the energy sector. The efficiency of these panels depends notably on the quality of the processed silicon ingots and on their homogeneity regarding the impurities they include. In order to process photovoltaic silicon, one can use a directional solidification process to obtain a solar grade silicon ingot from a metallurgical grade silicon feedstock. This approach is still nowadays hard to simulate with efficiency because of the multi-scales aspects of the process and because of the front tracking of the interface, where some heat and mass transfer occurs. This thesis presents the implementation of an original moving mesh method, proposed in order to perform an adaptive front tracking of the moving interface. The aim is to improve the efficiency of the numerical simulations. In a first time, the directional solidification model of a pure substance with such a moving mesh is validated against an analytical solution based on a purely diffusive reference configuration. The influence of the proposed method is then studied on a vertical Bridgman configuration with natural convection in the liquid phase. In a second time, the segregation of impurities is considered in the same configuration. For this study, a specific model for the rejection of impurities is proposed at the solid/liquid interface, and the influence of the proposed moving mesh method on the results is as well explored. Finally, the results and the performance improvements for the numerical simulations are discussed through variations of the calculation parameters and through comparisons against data from the literature. Photovoltaique Silicium photovoltaïque Maillage glissant Modélisation numérique Solidification Cas de Stefan Modélisation thermique Photovoltaic Cell Sliding mesh Numerical modeling Solidification Case of Stefan Thermal Modelling 532.072
29	Aplicações de técnicas de impressão à dispositivos eletrônicos orgânicos / Applications of printing techniques for organic electronic devices Rebello, Pedro Henrique Pereira 27 January 2014 (has links) O trabalho desta dissertação versou sobre avanços em tecnologias de eletrônica impressa de baixo custo. Em particular, aplicamos as técnicas de impressão por serigrafia e por jato de tinta para confeccionar dispositivos eletrônicos e optoeletrônicos. O primeiro dispositivo construído foi resistências impressas por jato de tinta tendo como matérias primas o poli(3,4-etileno dióxido tiofeno) com sulfonato de poliestireno (PEDOT:PSS) e nanopartículas de prata sobre substratos de vidro. Os valores das resistências foram analisados em se variando parâmetros de impressão. Como segundo dispositivo, imprimimos pela técnica de serigrafia sobre vidro e kapton, antenas de cartões de RFIDs (Radio-Frequency Identifications), também com os dois materiais: tinta de prata e PEDOT:PSS. Os RFIDs foram projetados para operar em frequências entre 860 MHz e 960 MHz. A antena de PEDOT:PSS mostrou alcance de 0,45 m, enquanto que a de tinta prata teve alcance de 1,6 m em 860 MHz e de 4 m em 960 MHz. Fabricamos também células eletroquímicas emissoras de luz (Organic Light Emitting Electrochemical Cells - OLECs), no qual substituímos o eletrodo transparente de óxido de índio (ITO), por um feito de PEDOT:PSS, aplicado por serigrafia sobre vidro. A camada ativa da célula luminescente foi feita por uma mistura de óxido de polietileno complexado com sal de lítio e um polímero luminescente derivado de polifluoreno que emite no verde. As curvas características de corrente e luminância em função da voltagem externa aplicada mostrou o bom desempenho das células fabricadas. Finalmente, produzimos células fotovoltaicas orgânicas, em que o eletrodo transparente, também de PEDOT:PSS, foi depositado por serigrafia sobre vidro. A camada ativa nesse caso foi um sistema bifásico feito de poli(3hexiltiofeno) (P3HT) e um éster, o [6,6]-fenil-C61-ácido metil-butírico (PCBM). Esse dispositivo apresentou um Fator de Preenchimento de 0,47 e uma eficiência externa de aproximadamente 2%. / The work developed along this thesis presents advances in printed electronic technologies of low cost. In particular we applied printable serigraphic and Inkjet technologies to produce electronic and optoelectronic devices. First, we produced resistances having poly(3,4-ethylenedioxythiophene) poly(styrenesulfonate) (PEDOT:PSS) and silver paint as active materials, using an Inkjet printer on glass substrate. We made studies of the resistance performance varying some printed parameters. Then, by serigraphy screen printing was printed, on substrates of kapton and glass, an antenna in an Radio-Frequency Identification card (RFID), also from PEDOT:PSS and from silver paint. This RFID was projected to operate in a frequency range from approximately 860 MHz to 960 MHz. The antenna made of PEDOT:PSS operated in a distance of 0.45 m, while that of silver varied from 1.6 m at 860 MHz to 4 m at 960 MHz. In an Organic Light Emitting Electrochemical Cell (OLEC) we applied one of the electrodes, a PEDOT:PSS layer, as a transparent electrode by serigraphy on glass substrate for made to replace of ITO. The active layer was a mixture of a poly(ethylene oxide) complexed with lithium salt and a derivative of polyfluorene that is a green emitter. The characteristic curves of current and luminance against the applied external voltage assured us the good performance of the device. Similar result was obtained with the performance of an organic photovoltaic (OPV), in which the active layer was a biphasic system made by poly(3-hexylthiophene) (P3HT) and [6,6]-phenyl-C61-butyric acid methyl ester (PCBM), in which the transparent electrode (PEDOT:PSS) was also printed by serigraphy on glass substrate. In this device we obtained a Fill Factor of 0.47 and an external efficiency of almost 2%. Célula luminescente orgânica Células fotovoltáica orgânica Eletrônica impressa Eletrônica orgânica Organic electronics Organic luminescent cell Organic photovoltaic cell Printed electronics RFID RFID
30	Conception et réalisation d'une nouvelle architecture multi-entrées multi-sorties pour la gestion de micro puissance dans les systèmes autonomes / Conception et réalisation d'une nouvelle architecture multi-entrées multi-sorties pour la gestion de micro puissance dans les systèmes autonomes Ramond, Adrien 22 November 2011 (has links) L'autonomie énergétique des systèmes embarqués est un frein majeur au développement de l'intelligence ambiante et de l'internet des objets. Cette thèse présente un système générique de gestion de micro-puissance capable d'alimenter un nœud de réseau de capteurs autonomes et communicant sans fil (WSN). L'architecture proposée est basée sur un convertisseur DC/DC abaisseur simple inductance multi-entrées multi-sorties (SI MIMO) associé à un circuit de recherche du point de puissance maximal (MPPT) très basse consommation. Nous montrons dans ce travail que cette famille de convertisseurs permet d'hybrider efficacement plusieurs sources et plusieurs éléments de stockage pour fournir les tensions régulées nécessaires à l'alimentation électrique d'un nœud de WSN. Pour ce faire, et dans le cadre du projet PCB², nous avons réalisé un convertisseur SI MIMO à base de composants discrets ultra basse consommation sur carte PCB. Ce convertisseur interface un récupérateur piézoélectrique, une cellule photovoltaïque et une batterie fine au LIPON (Lithium Phosphorous Oxynitride) enterrée dans le circuit imprimé, pour alimenter un capteur de température enregistreur. Le développement de modèles pour chacun de ces dispositifs et leur implémentation dans un environnement de simulation système en VHDL-AMS a permis, dans un premier temps, de valider le concept présenté, puis, a guidé le travail de conception et d'optimisation du circuit du démonstrateur. Le rendement ainsi obtenu avoisine 55% dans les conditions normales d'utilisation et tend vers 70% lorsque le niveau de puissance qui transite dans le convertisseur dépasse 500 µW. / Energy supply of embedded systems is limiting the development of the internet of things and more generally of the ambient intelligence paradigm. This thesis presents a generic micro-power management system able supply a wireless sensor node. The proposed architecture is based on a Single Inductor Multi Inputs Multi Outputs (SI MIMO) DC/DC converter coupled to an ultra low power Maximum Power Point Tracking circuit. In this work, we show that this family of converter allows to efficiently hybridizing several power sources with power storage elements in order to provide different DC regulated voltages that can supply a sensor node. In this end, and in the framework of the PCB² project, we realized a SI MIMO converter made of discrete components on a printed circuit board. This converter interfaces a piezoelectric generator, a photovoltaic cell, and a thin-film LIPON Lithium Phosphorous Oxynitride) battery buried in the PCB, in order to power a temperature data-logger. The concept validation and the design of the demonstrator have been done thanks to devices modeling and system simulations in a VHD-AMS environment. The efficiency of the circuit is about 55% in standard usage conditions and reaches 70% when the power passing through the converter exceeds 500µW. DC/DC SI MIMO MPPT Générateur piézoélectrique Cellule photovoltaïque Batterie LIPON WSN DC/DC SI MIMO MPPT Piezoelectric generator Photovoltaic cell LIPON battery WSN 530 621.381 620.5

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