Global ETD Search

1	Towards Application of Selectively Transparent and Conducting Photonic Crystal in Silicon-based BIPV and Micromorph Photovoltaics Yang, Yang 11 December 2013 (has links) Selectively-transparent and conducting photonic crystals (STCPCs) made of alternating layers of sputtered indium-tin oxide (ITO) and spin-coated silica (SiO2) nanoparticle films have potential applications in micromorph solar cells and building integrated photovoltaics (BIPVs). In this work, theoretical calculations have been performed to show performance enhancement of the micromorph solar cell upon integration of the STCPC an intermediate reflector. Thin semi-transparent hydrogenated amorphous silicon (a-Si:H) solar cells with STCPC rear contacts are demonstrated in proof-of-concept devices. A 10% efficiency increase in a 135nm thick a-Si:H cell on an STCPC reflector with Bragg peak at 620nm was observed, while the transmitted solar irradiance and illuminance are determined to be 295W/m2 and 3480 lux, respectively. The STCPC with proper Bragg peak positioning can boost the a-Si:H cell performance while transmitting photons that can be used as heat and lighting sources in building integrated photovoltaic applications. amorphous silicon solar cell one dimensional photonic crystal bragg reflector building integrated photovoltaics micromorph 0791 0794
2	Towards Application of Selectively Transparent and Conducting Photonic Crystal in Silicon-based BIPV and Micromorph Photovoltaics Yang, Yang 11 December 2013 (has links) Selectively-transparent and conducting photonic crystals (STCPCs) made of alternating layers of sputtered indium-tin oxide (ITO) and spin-coated silica (SiO2) nanoparticle films have potential applications in micromorph solar cells and building integrated photovoltaics (BIPVs). In this work, theoretical calculations have been performed to show performance enhancement of the micromorph solar cell upon integration of the STCPC an intermediate reflector. Thin semi-transparent hydrogenated amorphous silicon (a-Si:H) solar cells with STCPC rear contacts are demonstrated in proof-of-concept devices. A 10% efficiency increase in a 135nm thick a-Si:H cell on an STCPC reflector with Bragg peak at 620nm was observed, while the transmitted solar irradiance and illuminance are determined to be 295W/m2 and 3480 lux, respectively. The STCPC with proper Bragg peak positioning can boost the a-Si:H cell performance while transmitting photons that can be used as heat and lighting sources in building integrated photovoltaic applications. amorphous silicon solar cell one dimensional photonic crystal bragg reflector building integrated photovoltaics micromorph 0791 0794
3	Experimental investigation of thermal and fluid dynamical behavior of flows in open-ended channels : Application to Building Integrated Photovoltaic (BiPV) Systems Sanvicente, Estibaliz 03 July 2013 (has links) (PDF) Among technologies capable to produce electricity locally without contributing to GHG releases, building integrated PV systems (BIPV) could be major contributor. However, when exposed to intense solar radiation, the temperature of PV modules increase significantly, leading to a reduction in efficiency so that only about 14% of the incident radiation is converted into electrical energy. The high temperature also decrease the life of the modules, thereby making passive cooling of the PV components through natural convection a desirable and cost-effective means of overcoming both difficulties. An experimental investigation of heat transfer and fluid flow characteristics of natural convection of air in vertical and inclined open-ended heated channels is therefore undertaken so as provide reliable information for the design of BIPV. Two experimental set ups were developed and used during the present investigations; one located at the CETHIL laboratory in Lyon, the F-device and the other located at the University of New South Wales in Sydney, the R-device. Both channels consisted of two wide parallel plates each of which could be subjected to controlled uniform or non-uniform heat fluxes. The investigation has been conducted by analyzing the mean wall temperatures, measured by thermocouples and mean velocity profiles and turbulent quantity distributions of the flow, measured with a PIV system. Flow patterns close to the heated faces were also investigated. The study is particularly focused on the transition region from laminar to turbulent flow. Three different heating geometric arrangements are examined in the modified Rayleigh number range from 3.86 x 105 to 6.22 x 106. The first is a vertical channel with one wall uniformly heated while the other was unheated, the second was a vertical channel in which both walls were non-uniformly heated and the third is an inclined channel uniformly heated from above. In the vertical configurations the width-to-height channel aspect ratio was fixed at 1:15 and in the inclined ones at 1:16. It is shown that the flow is very sensitivity to disturbances emanating from the ambient conditions. Moreover, the propagation of vortical structures and unsteadiness in the flow channel which are necessary to enhance heat transfer, occurred downstream of the mid-channel section at Ra* = 3.5 x 106 for uniformly and asymmetrically heated channels inclined between 60° and 90° to the horizontal. Indeed, these unsteady flow phenomena appears upstream the location of the inflexion point observed in the temperature excess distribution of the heated wall. In the case of non-uniform heating on both sides of the channel, a stronger 'disruption mechanism' exists, which leads to enhanced mixing and increased Reynolds stresses over most of the width of the channel. Empirical correlations of average Nusselt number as a function of modified Rayleigh number were obtained for each configuration. Heat Flow Bipv Building Integrated Photovoltaics Natural convection PIV measurements
4	Development and diffusion of building-integrated photovoltaics : analysing innovation dynamics in multi-sectoral technologies Gazis, Evangelos January 2015 (has links) The ongoing transformation of the energy system along a more sustainable trajectory requires advancements in a range of technological fields, as well as active involvement of different societal groups. Integration of photovoltaic (PV) systems in the built environment in particular is expected to play a crucial long-term role in the deployment of renewable energy technologies in urban areas, demanding the successful cooperation of planners, architects, engineers, scientists and users. The realisation of that technological change will require innovation at both an individual (within firms and organisations) and a collective (sector) level, giving rise to systemic approaches for its characterisation and analysis of its drivers. This study investigates the processes that either accelerate or hinder the development and diffusion of Building-Integrated PV (BIPV) applications into the market. Affected by developments in both the renewable energy and construction industries, the BIPV innovation system is a multi-sectoral case that has been explored only partially up to now. Acknowledging the fact that drivers of innovation span the globalised BIPV supply chain, this research adopts both an international and a national spatial perspective focusing on the UK. The analysis is based on a novel analytical framework which was developed in order to capture innovation dynamics at different levels, including technological advancements within firms, competition and synergy with other emerging and established innovation systems and pressures from the wider socio-economic configuration. This hybrid functional framework was conceived by combining elements from three academic strands: Technological Innovation Systems, the Multi-Level Perspective and Business Studies. The empirical research is based on various methods, including desktop research, semi-structured interviews and in-depth firm-level case studies. A thorough market assessment provides the techno-economic background for the research. The hybrid framework is used as a guide throughout the empirical investigation and is also implemented in the analytical part of the study to organise and interpret the findings, in order to assess the overall functionality of the innovation system. The analysis has underlined a range of processes that affect the development and diffusion of BIPV applications including inherent technological characteristics, societal factors and wider transitions within the energy and construction sectors. Future approaches for the assessment and governance of BIPV innovation will need to address its hybrid character and disruptiveness with regards to incumbent configurations, in order to appreciate its significance over the short and long term. Methodological and conceptual findings show that the combination of insights from different analytical perspectives offers a broader understanding of the processes affecting innovation dynamics in emerging technologies. Different approaches can be used in tandem to overcome methodological weaknesses, provide different analytical perspectives and assess the performance of complex innovation systems, which may span multiple countries and sectors. By better reflecting complexities, tensions and synergies, the framework developed here offers a promising way forward for the analysis of emerging sustainable technologies. 621.31
5	Optical Efficiency of Low-Concentrating Solar Energy Systems with Parabolic Reflectors Brogren, Maria January 2004 (has links) <p>Solar electricity is a promising energy technology for the future, and by using reflectors for concentrating solar radiation onto photovoltaic cells, the cost per produced kWh can be significantly reduced. The optical efficiency of a concentrating system determines the fraction of the incident energy that is transferred to the cells and depends on the optical properties of the system components. In this thesis, low-concentrating photovoltaic and photovoltaic-thermal systems with two-dimensional parabolic reflectors were studied and optimised, and a new biaxial model for the incidence angle dependence of the optical efficiency was proposed.</p><p>Concentration of light generally results in high cell temperatures, and the uneven irradiance distribution on cells with parabolic reflectors leads to high local currents and temperatures, which reduce fill-factor and voltage. Cooling the cells by means of water increases the voltage and makes it possible to utilize the thermal energy. The performance of a 4X concentrating photovoltaic-thermal system was evaluated. If operated at 50°C, this system would produce 250 kWh<sub>electrical</sub> and 800 kWh<sub>thermal</sub> per m<sup>2</sup> cell area and year. Optical performance can be increased by 20% by using better reflectors and anti-reflectance glazing.</p><p>Low-concentrating photovoltaic systems for façade-integration were studied and optimised for maximum annual electricity production. The optimisation was based on measured short-circuit currents versus solar altitude. Measurements were performed outdoors and in a solar simulator. It was found that the use of 3X parabolic reflectors increases the annual electricity production by more than 40%. High solar reflectance is crucial to system performance but by using a low-angle scattering reflector, the fill-factor and power are increased due to a more even irradiance on the modules.</p><p>Long-term system performance depends on the durability of the components. The optical properties and degradation of reflector materials were assessed using spectrophotometry, angular resolved scatterometry, Fresnel modelling, optical microscopy, and surface profilometry before and after ageing. The degradation of reflectors was found to be strongly dependent on material composition and environmental conditions. Back surface mirrors, all-metal reflectors, and polymer-metal laminates degraded in different ways, and therefore accelerated ageing must be tailored for testing of different types of reflector materials. However, new types of reflector laminates showed a potential for increasing the cost-effectiveness of low-concentrating solar energy systems.</p> Engineering physics Photovoltaic cells Photovoltaic-thermal systems Parabolic reflectors Optical properties Reflector materials Optical efficiency Accelerated ageing Outdoor ageing Building-integrated photovoltaics Teknisk fysik Engineering physics Teknisk fysik
6	Optical Efficiency of Low-Concentrating Solar Energy Systems with Parabolic Reflectors Brogren, Maria January 2004 (has links) Solar electricity is a promising energy technology for the future, and by using reflectors for concentrating solar radiation onto photovoltaic cells, the cost per produced kWh can be significantly reduced. The optical efficiency of a concentrating system determines the fraction of the incident energy that is transferred to the cells and depends on the optical properties of the system components. In this thesis, low-concentrating photovoltaic and photovoltaic-thermal systems with two-dimensional parabolic reflectors were studied and optimised, and a new biaxial model for the incidence angle dependence of the optical efficiency was proposed. Concentration of light generally results in high cell temperatures, and the uneven irradiance distribution on cells with parabolic reflectors leads to high local currents and temperatures, which reduce fill-factor and voltage. Cooling the cells by means of water increases the voltage and makes it possible to utilize the thermal energy. The performance of a 4X concentrating photovoltaic-thermal system was evaluated. If operated at 50°C, this system would produce 250 kWhelectrical and 800 kWhthermal per m2 cell area and year. Optical performance can be increased by 20% by using better reflectors and anti-reflectance glazing. Low-concentrating photovoltaic systems for façade-integration were studied and optimised for maximum annual electricity production. The optimisation was based on measured short-circuit currents versus solar altitude. Measurements were performed outdoors and in a solar simulator. It was found that the use of 3X parabolic reflectors increases the annual electricity production by more than 40%. High solar reflectance is crucial to system performance but by using a low-angle scattering reflector, the fill-factor and power are increased due to a more even irradiance on the modules. Long-term system performance depends on the durability of the components. The optical properties and degradation of reflector materials were assessed using spectrophotometry, angular resolved scatterometry, Fresnel modelling, optical microscopy, and surface profilometry before and after ageing. The degradation of reflectors was found to be strongly dependent on material composition and environmental conditions. Back surface mirrors, all-metal reflectors, and polymer-metal laminates degraded in different ways, and therefore accelerated ageing must be tailored for testing of different types of reflector materials. However, new types of reflector laminates showed a potential for increasing the cost-effectiveness of low-concentrating solar energy systems. Engineering physics Photovoltaic cells Photovoltaic-thermal systems Parabolic reflectors Optical properties Reflector materials Optical efficiency Accelerated ageing Outdoor ageing Building-integrated photovoltaics Teknisk fysik Engineering physics Teknisk fysik
7	Ανάλυση και εξομοίωση φωτοβολταϊκών πλαισίων λεπτών φιλμ Κοσκινάς, Αθανάσιος 04 October 2011 (has links) Σκοπός της παρούσας διπλωματικής εργασίας είναι μέσα από την πειραματική διαδικασία και την επεξεργασία των αποτελεσμάτων να μελετηθούν τα φωτοβολταϊκά πλαίσια τεχνολογίας λεπτών φιλμ (Thin Films Photovoltaics-TFPV) που υπάρχουν διαθέσιμα στο εργαστήριο Ασύρματης Τηλεπικοινωνίας του Πανεπιστημίου Πατρών στο Τμήμα Ηλεκτρολόγων Μηχανικών και Τεχνολογίας Υπολογιστών και να εξαχθούν συμπεράσματα που θα οδηγήσουν στην κατανόηση της λειτουργίας τους. Η ανάλυσή τους θα διευκρινίσει την λειτουργία τους και σε πραγματικές εφαρμογές. Επιπλέον θα γίνει προσπάθεια πειραματικής εξομοίωσης συνθηκών δοκιμής στους 25οC υπό ηλιακή ακτινοβολία 1000 W/m2 τονίζοντας ότι οι κατασκευαστικές πληροφορίες σε αυτές τις συνθήκες είναι ενδεικτικές και δεν εκφράζουν την συμπεριφορά των πλαισίων σε πραγματικές συνθήκες λειτουργίας. Επίσης θα παρουσιαστεί η επίδραση της τοπικής σκίασης και της αύξησης της προσπίπτουσας ακτινοβολίας σε μέρος ή και σε ολόκληρο το πλαίσιο που προκαλείται από ανάκλαση με τη βοήθεια κατόπτρου. Ειδικότερα παρουσιάζεται η κατάσταση της ενεργειακής πραγματικότητας σήμερα, οι προβληματισμοί για το περιβάλλον, η στροφή στις Ανανεώσιμες Πηγές Ενέργειας και η σημαντικότητα της ενσωμάτωσης φωτοβολταϊκών στα κτήρια. Επίσης παρουσιάζεται η θεωρία της ηλιακής ενέργειας και των φωτοβολταϊκών συστημάτων με τα πλεονεκτήματα και μειονεκτήματά τους. Στην συνέχεια γίνεται αναφορά στη συνδεσιμότητα των φωτοβολταϊκών με την ΔΕΗ και στις ενεργειακές ανάγκες που μπορούν να καλύψουν σε μια κτηριακή εγκατάσταση. Αναλύονται τεχνικές λεπτομέρειες και χαρακτηριστικά μεγέθη των φωτοβολταϊκών στοιχείων καθώς και η εξέλιξη της φωτοβολταϊκής τεχνολογίας ξεκινώντας από το πυρίτιο και καταλήγοντας στα Λεπτά Φιλμ και σε ακόμα νεότερες τεχνολογίες. Στη συνέχεια γίνεται ανάλυση της τεχνολογίας των λεπτών φιλμ προσανατολισμένη στην ενσωμάτωση τους σαν δομικά υλικά σε κατασκευές (BIPV-Building Integrated Photovoltaics).Στην πειραματική διαδικασία επεξηγείται η λογική που ακολουθήθηκε, η πειραματική διάταξη και τα όργανα που χρησιμοποιήθηκαν. Μελετώνται επίσης οι φωτοβολταϊκές παράμετροι και αναλύονται τα πειραματικά δεδομένα. Η ανάλυση γίνεται ως προς την ακτινοβολία, την θερμοκρασία και την εποχή του έτους. Τέλος, τα αποτελέσματα της ανάλυσης, (μέσο ένος προγράμματος στην γλώσσα προγραμματισμού C++), δημιουργούν μια βάση δεδομένων προσπελάσιμη από τον χρήστη για την πρόβλεψη και εξομοίωση των πειραματικών αποτελεσμάτων σε οποιοδήποτε συνδυασμό θερμοκρασίας και ακτινοβολίας. / The purpose of this diploma thesis is to study thin film photovoltaic panels that are available in the wireless communication laboratory in the University of Patras in the department of Electrical and Computer Engineering. Through the experimental process and processing its results our goal was to extract the conclusions that would lead us to a better understanding of their function. Their analysis will determine their usability in real outdoor PV systems. A simulation of the standard test conditions that are set in 250C temperature and 1000 W/m2 radiation is made, pointing out that this information is unable to indicate the actual function of the panels in outdoor conditions. The effects of partial shadowing and increased radiation with mirror system are also presented. More specifically, the energy reality, thoughts about the environment, the global turn towards the renewable energy sources and the significance of photovoltaic integration in buildings (BIPV- Building Integrated Photovoltaics) are mentioned. The theory of solar energy and photovoltaic technology including its advantages and disadvantages is analyzed. Grid-connected PV systems, their contribution in energy production in buildings and the potential of wide application of BIPV is presented. The advantages of thin film as BIPV materials are also mentioned. The experimental parameters, the logics followed in the set up process and the instruments used are part of the complete analysis of thin film parameters in relation to radiation, temperature and time of the year that the measurements occurred. Finally with a C++, a simulation program was created to predict the behavior of the thin film panels in outdoor conditions. Φωτοβολταϊκά πλαίσια Λεπτά φιλμ Άμορφο πυρίτιο Θερμοκρασία Ακτινοβολία Βαθμός απόδοσης 621.381 542 Photovoltaic panels Thin films Amorphus silicon Photovoltaic solar cells CIS Building integrated photovoltaics (BIPV)
8	Experimental investigation of thermal and fluid dynamical behavior of flows in open-ended channels : Application to Building Integrated Photovoltaic (BiPV) Systems / Etude expérimentale du comportement dynamique thermique et fluide des flux dans les canaux ouverts : Application à la création de systèmes photovoltaïques intégrés au bâti (BIPV) Sanvicente, Estibaliz 03 July 2013 (has links) Face à la problématique énergétique, les solutions envisagées dans le domaine du bâtiment s’orientent sur un mix énergétique favorisant la production locale ainsi que l’autoconsommation. Concernant l’électricité, les systèmes photovoltaïques intégrés au bâtiment (BiPV) représentent l’une des rares technologies capables de produire de l’électricité localement et sans émettre de gaz à effet de serre. Cependant, le niveau de température auquel fonctionnent ces composants, influence sensiblement leur efficacité ainsi que leur durée de vie. Ces deux constats mettent en lumière l’importance du refroidissement passif par convection naturelle de ces modules. La configuration privilégiée est une configuration d’intégration au sein d’une enveloppe ventilée qualifiée de double-peau photovoltaïque. La présente étude expérimentale porte sur les transferts de chaleur et les caractéristiques de l’écoulement en convection naturelle dans des canaux chauffés verticaux ou inclinés. Deux bancs d’essais existants ont été complétés afin d’obtenir des données. Ils sont composés de deux plaques planes parallèles séparées par une lame d’air. Les parois sont soumises à des conditions aux limites de type densité de flux imposée. Les températures moyennes à la paroi ont été mesurées par thermocouples. Un système de vélocimétrie par image de particules a permis d’obtenir des profils de vitesse moyenne ainsi que les distributions d’intensité turbulente dans l’écoulement. Les champs de vitesse instantanée ont également été examinés. Trois configurations ont été étudiées avec un nombre de Rayleigh variant entre 3,86 x 105 et 6,22 x 106. La première est un canal vertical avec une des deux parois chauffée uniformément. La seconde est un canal vertical dans lequel les deux parois sont chauffées de façon non-uniforme et alternée. La troisième est de type canal incliné chauffé uniformément sur la paroi supérieure. Le rapport de forme du canal (largeur/hauteur) est de 1/15 pour le deux premières configurations et de 1/16 pour la troisième. Une attention particulière a été portée sur l’identification de la zone de transition laminaire-turbulent. L’étude a permis de mettre en évidence la sensibilité de l’écoulement aux perturbations extérieures. Pour un chauffage uniforme et asymétrique, à partir d’un nombre de Rayleigh Ra* de 3.5 x 106 et pour θ = 60° et 90°, il a été constaté que la propagation de structures cohérentes dans le canal a lieu à partir de la mi-hauteur de ce canal. Ces instabilités favorisent alors les transferts thermiques. Dans le cas d’un chauffage non-uniforme sur les deux parois du canal, l’écoulement est fortement perturbé ce qui conduit à l’augmentation du brassage et de la contrainte de Reynolds sur la majorité de la largeur du canal. Enfin, pour chacune des configurations, des corrélations permettant de quantifier les transferts de chaleur à la paroi et au sein de la lame d’air (nombre de Nusselt moyen en fonction du nombre de Rayleigh) ont été établies. / Among technologies capable to produce electricity locally without contributing to GHG releases, building integrated PV systems (BIPV) could be major contributor. However, when exposed to intense solar radiation, the temperature of PV modules increase significantly, leading to a reduction in efficiency so that only about 14% of the incident radiation is converted into electrical energy. The high temperature also decrease the life of the modules, thereby making passive cooling of the PV components through natural convection a desirable and cost-effective means of overcoming both difficulties. An experimental investigation of heat transfer and fluid flow characteristics of natural convection of air in vertical and inclined open-ended heated channels is therefore undertaken so as provide reliable information for the design of BIPV. Two experimental set ups were developed and used during the present investigations; one located at the CETHIL laboratory in Lyon, the F-device and the other located at the University of New South Wales in Sydney, the R-device. Both channels consisted of two wide parallel plates each of which could be subjected to controlled uniform or non-uniform heat fluxes. The investigation has been conducted by analyzing the mean wall temperatures, measured by thermocouples and mean velocity profiles and turbulent quantity distributions of the flow, measured with a PIV system. Flow patterns close to the heated faces were also investigated. The study is particularly focused on the transition region from laminar to turbulent flow. Three different heating geometric arrangements are examined in the modified Rayleigh number range from 3.86 x 105 to 6.22 x 106. The first is a vertical channel with one wall uniformly heated while the other was unheated, the second was a vertical channel in which both walls were non-uniformly heated and the third is an inclined channel uniformly heated from above. In the vertical configurations the width-to-height channel aspect ratio was fixed at 1:15 and in the inclined ones at 1:16. It is shown that the flow is very sensitivity to disturbances emanating from the ambient conditions. Moreover, the propagation of vortical structures and unsteadiness in the flow channel which are necessary to enhance heat transfer, occurred downstream of the mid-channel section at Ra* = 3.5 x 106 for uniformly and asymmetrically heated channels inclined between 60° and 90° to the horizontal. Indeed, these unsteady flow phenomena appears upstream the location of the inflexion point observed in the temperature excess distribution of the heated wall. In the case of non-uniform heating on both sides of the channel, a stronger ‘disruption mechanism’ exists, which leads to enhanced mixing and increased Reynolds stresses over most of the width of the channel. Empirical correlations of average Nusselt number as a function of modified Rayleigh number were obtained for each configuration. Energétique Transfert de chaleur Thermique des bâtiments Convection naturelle Bâtiment Photovoltaique Photovoltaique intégrée au bâtiment Mesures thermiques Bipv Heat Flow Bipv Building Integrated Photovoltaics Natural convection PIV measurements 536.230 72
9	Etude des transferts thermo-convectifs dans un canal semi-ouvert : Application aux façades type double-peau / Study of convective heat transfer in an open-ended channel : Application to photovoltaic double-Skin Facades Zoubir, Amine 05 February 2014 (has links) Notre investigation porte sur la simulation numérique des échanges thermo-convectifs dans un canal vertical ouvert à flux imposé. Cette étude rentre dans le cadre des recherches sur le rafraîchissement passif des composants PV intégrés au bâtiment. À cet effet, un code numérique en Différences Finies est utilisé pour résoudre les équations de Navier-Stokes et simuler la convection naturelle dans un canal. Ce problème reste difficile à résoudre parce que l'écriture des conditions aux limites d'entrée et de sortie reste un problème ouvert. Notre travail consiste d'abord en étude des différentes conditions aux limites pour le benchmark numérique AMETH. Les travaux réalisés ont permis de faire un premier choix sur les conditions aux limites. L'étude s'oriente ensuite sur la qualification et la quantification numériques et expérimentales pour deux fluides : l'air (convection-rayonnement) et l'eau (convection pure). Les résultats numériques/expérimentaux ont été comparés et les discordances ont été analysées. Plusieurs aspects phénoménologiques (rayonnement entre surfaces, variation des propriétés thermo-physiques, variation du nombre de Prandtl) ont été abordés afin de caractériser leurs influences respectives sur l'écoulement et le transfert thermique. Enfin, dans le but d'apporter des éléments de réponses sur les conditions aux limites dynamiques, nous avons simulé la convection naturelle d'un canal dans une cavité et tenté une modélisation. / The present investigation deals with natural convection flow in a vertical open-ended channel with wall constant heat flux. This study falls under the framework of research on passive cooling of building integrated PV components. For this purpose, a numerical code developed with Finite Differences scheme is used to solve Navier-Stokes equations and simulate the natural convection in a channel. This problem is difficult to solve because the writing of inlet/outlet boundary conditions remains an open problem. First, our work consists of studying different boundary conditions for the the numerical benchmark AMETH. The work carried out has enabled a first choice of boundary conditions. The study then focuses on numerical and experimental quantification and qualification for two fluids : air ( convection - radiation) and water ( pure convection) . Experimental and numerical results were compared and discrepancies were analyzed. Several phenomenological aspects ( surface radiation, thermophysical properties variation, Prandtl number variation ) were discussed in order to characterize their influence on flow and heat transfer. Finally, in order to provide some answers on dynamical boundary conditions, we simulated natural convection of a channel inside a cavity and tried a modeling. Energétique Transfert de chaleur Thermique des bâtiments Convection naturelle Photovoltaïque intégré au bâtiment Façade double-Peau Energetcis Heat transfer Building physics Natural convection Building Integrated Photovoltaics Double-Skin facade 536.230 72
10	Integrability Evaluation Methodology for Building Integrated Photovoltaic's (BIPV) : A Study in Indian Climatic Conditions Eranki, Gayathri Aaditya January 2016 (has links) (PDF) India’s geographical location renders it with ample solar-energy potential ranging from 4-7 kWh/m2 daily and 2,300–3,200 sunshine hours annually. The diverse nature of human settlements (scattered low-rise to dense high-rise) in India is one of the unexplored avenues of harnessing solar energy through electricity generation using photovoltaic (PV) technology. Solar energy is a promising alternative that carries adequate potential to support the growing energy demands of India’s burgeoning population. A previous study estimates, by the year 2070, with 425 million households (of which utilizing only 20 %), about 90 TWh of electrical energy can be generated utilizing solar energy. PV is viable for onsite distributed (decentralized) power generation offering advantages of size and scale variability, modularity, relatively low maintenance and integration into buildings (no additional demand land). The application of solar PV technology as the building envelope viz., walls, façade, fenestration, roof and skylights is termed Building Integrated Photovoltaic (BIPV). Apart from generating electricity, PV has to also function as a building envelope, which makes BIPV systems unique. Even with a gradual rise in the number of BIPV installations across the world over the years, a common consensus on their evaluation has not yet been developed. Unlike PV in a ground mounted system, its application in buildings as an envelope has huge implications on both PV and building performance. The functions of PV as a building material translates well beyond electricity generation alone and would also have to look into various aspects like the thermal comfort, weather proofing, structural rigidity, natural lighting, thermal insulation, shading, noise protection safety and aesthetics. To integrate PV into a residential building successfully serving the purpose (given the low energy densities of PV and initial cost), would also mean considering factors like the buildings electricity requirement and economic viability. As many studies have revealed, 40% of electricity consumed in a building is utilized for maintaining indoor thermal comfort. Tropical regions, such as India, are generally characterized by high temperatures and humidity attributed to good sunlight, therefore, the externality considered for this study has been the impact of BIPV on the thermal comfort. Passive designs need to regulate the buildings solar exposure by integrating a combination of appropriate thermal massing, material selection, space orientation and natural ventilation. On the other hand, PV design primarily aims to maximize solar to generate maximum energy. The design requirements for climate-responsive building design may thus infringe upon those required for optimal PV performance. Regulating indoor thermal comfort in tropical regions poses a particular challenge under such conditions, as the indoor temperature is likely to be sensitive to external temperature variations. In addition, given current performance efficiencies for various PVs, high initial cost and space requirement, it is also crucial to ascertain PV’s ability to efficiently support buildings energy requirement. Thus, BIPV would require addressing, concurrently, design requirements for energy-efficient building performance, effective PV integration, and societal feasibility. A real time roof integrated BIPV system (5.25 kW) installed at the Center for Sustainable Technologies at the Indian Institute of Science, Bangalore has been studied for its PV and building thermal performance. The study aims at understanding a BIPV system (based on crystalline silicon) from the technical (climate-responsiveness and PV performance), social (energy requirement and energy efficiency) and economical (costs and benefits) grounds and identifies relevant factors to quantify performance of any BIPV system. A methodology for BIPV evaluation has been proposed (Integrability Methodology), especially for urban localities, which can also be adopted for various PV configurations, building typologies and climatic zones. In the process, a novel parameter (thermal comfort energy) to evaluate the thermal performance of naturally ventilated buildings combining climate-responsiveness and thermal comfort aspects has also been developed. An Integrability Index has also been devised, integrating various building performance factors, to evaluate and compare the performance of BIPV structures. The methodology has been applied to the 5.25 kW BIPV system and the index has been computed to be 0.17 (on a scale of 0 – 1). An insulated BIPV system (building applied photovoltaic system) has been found to be favorable for the climate of Bangalore than BIPV. BIPV systems have also been compared across three different climates (Bangalore, Shillong and Delhi) and given the consideration of the same system for comparison, the system in Delhi is predicted to have a higher Integrability than the other two systems. The current research work is a maiden effort, that aims at developing and testing a framework to evaluate BIPV systems comprising technical, social and economic factors. Indian Climatic Conditions Building Integreated Photovoltaic Building Integrated Photovoltaic System BIPV Systems Building Integrated Photovoltaics Integrability Assessment Methodology Integrability Evaluation Methodology Sustainable Technology

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