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Sustainability and development impacts of off-grid electrification in developing countries : An assessment of South Africa's rural electrification program / Hållbarhet och utvecklingseffekter av off-grid elektrifiering i utvecklingsländer : En bedömning av Sydafrikas elektrifiering av landsbygden programmetAzimoh, Chukwuma Leonard January 2016 (has links)
Previous studies have shown that provision of sustainable electricity supply to rural households is essential to bring development to off-grid populations. For this reason, most developing countries put large efforts into rural electrification programs to stimulate development and reduce poverty. However, to be sustainable these programs need to recover costs, which poses a challenge to remote low income populations. This often forces governments and other institutions involved in rural electrification to subsidize the electricity production. It also affects the choice of technology and places a barrier on the level of energy provided in line with the ability to pay for services. As a result of this, most programs have failed to achieve the desired objectives, as the technologies used often do not support income generating activities that could increase the payment capabilities of the beneficiaries and contribute to development. This thesis is focused on the rural electrification program of South Africa, the country in sub-Saharan Africa that has the highest access to electricity. It investigates the success elements that influence the sustainability of rural electrification programs and their contributions to socio-economic development. This was achieved by evaluating the South African program that provides solar home systems to off-grid communities, and a hybrid solar-wind mini-grid project in South Africa. The study also draw lessons from other rural electrification programs in neighbouring countries, i.e. an evaluation of a hybrid solar-diesel mini-grid system in Namibia, and a review of two systems, a hybrid solar-biomass mini-grid project in Botswana and a hydro mini-grid program in Lesotho. The study revealed that hydro based hybrid mini-grid systems provide the most cost effective way of bringing energy services to rural settlements. Regardless of technology, successful programs depend on adequate support from the government, implementation of a progressive tariff system that allows the high consuming high income earners and businesses, to cross subsidize the low consuming , low income users. It shows that it is more likely for rural electrification programs to survive if the design considers the existing businesses, population growth and the corresponding load increase. The thesis further shows that provision of sufficient energy to induce income generating activities is essential to decrease the need for subsidies and to ensure the sustainability of programs. In addition, availability of spare parts and a capable management team is essential for the successful operations and maintenance of these systems.
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The socio-economic impact of mini-grid usage in Kenya : A qualitative case study in the rural areas of Kisii and Nyamira / Socioekonomiska effekter av mini-grid-användning i Kenya : En kvalitativ fallstudie gjord på Kisii och Nyamiras landsbygdTorebrandt, Adam January 2022 (has links)
Today, sub-Saharan Africa accounts for 75% of the world population without access to electricity which corresponds to over 500 million people. One strategy to reduce this number and provide access to electricity for more people, is to install mini-grids. The installment of those is currently in progress in Kenya, and this study put focus on the socio-economic benefits families’ experiences when connecting to a mini-grid. By using a literature review to get a socio-technical perspective, and a case study to investigate the situation in the rural communities of Kenya, several findings were discovered. Some benefits identified are that people felt more included in the society by getting access to information (with radio or TV), a possibility to raise the household income (by starting a business using electricity), and a more favorable study environment at home (thanks to electric lights). This, (among other findings), were visualized using personas, to represent the inhabitants in the counties of interest. Lastly, a discussion about sustainable development is included to explain what it means on a bigger scale if households are electrified. / Idag lever 75 % av världens befolkning utan tillgång till elektricitet is subsahariska Afrika, vilket motsvarar över 500 miljoner människor. En strategi för att ge fler tillgång till elektricitet är att installera så kallade mini-grids. Flera projekt där sådana installeras finns i Kenya och denna studie har som mål att undersöka de socio-ekonomiska effekter som uppkommer när familjer ute på landsbygden börjar använda dessa småskaliga energidistribueringsstationer. En litteraturstudie gjordes för att få ett socio-tekniskt perspektiv på dessa system och efter det gjordes en fallstudie för att få en uppfattning om hur situationen med elektrifiering på landsbygden ser ut just nu. Resultatet blev att vissa av de familjer som valde att ansluta sig till ett fristående elnät kände sig mer inkluderade i samhället, eftersom de nu kan få information genom radio eller TV. Dessutom har de bättre möjligheter att höja sin inkomst genom att starta ett mikro-företag tack vare elektriciteten. En ytterligare upptäckt var att de som behöver studera hemifrån får lättare att göra just det tack vare elektrisk belysning inomhus. Dessa fördelar (bland andra) visualiserades med hjälp av personas, vilket är en grupp fiktiva karaktärer som representerar invånarna i de kommuner som var inkluderade i studien. Slutligen diskuterades relationen mellan de socio-ekonomiska fördelarna och en hållbar utveckling för att sätta fingret på hur samhällen kan bli mer hållbara, om tillgång till pålitlig eldistribution finns för invånarna.
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Sustainability of rural energy access in developing countriesMainali, Brijesh January 2014 (has links)
The importance of access to modern energy has been well understood by governments and donor agencies in many developing countries, and significant effort has been made in recent years to address energy access challenges. However, despite these efforts, the International Energy Agency (IEA) has predicted that the energy access problem will remain unresolved by 2030. Therefore, adequate and appropriate action is needed to resolve this problem more quickly. This dissertation analyses policies and their impacts and will help researchers and policy makers in developing countries to (i) understand the impact of policies in the formation of a renewable energy (RE) market, (ii) consider the determinants of technological choices when promoting access to energy services and, (iii) better appreciate the sustainability performance of rural energy. For the purpose of analysis, several country cases from Asia and Sub-Saharan Africa region were carried out as these are the two main regions where the energy access problem are most acute. To understand the impact of policies in the formation of RE based rural electrification market, a case study was conducted in Nepal. The study has shown that rural electrification has been expanding as a consequence of market-oriented policies. When it comes to selection of electrification path-ways, different technological alternatives are analysed in Afghanistan and Nepal, taking levelized cost of electricity (LCOE) as the means to select cost effective options. The analysis has presented best-fit conditions for these various technological pathways in the two countries and verified whether they are following the appropriate and cost effective course in their efforts to expand rural electrification. For understanding the determinants of cooking fuel choices and to analyse policy implications in the transition of large populations from traditional to modern fuels, fuel choices are modelled in the case of China. Choices are modelled (using MESSAGE–ACCESS mod-el) with standard economic variables such as income, technology costs and fuel prices, along with some unique variable such as inconvenience costs. Future access scenarios are designed considering different policy options to accelerate the transition. Sustainability is one of the key concerns in terms of energy access. This dissertation introduces methods for evaluating (i) the sustainability performance of energy technologies and (ii) the status and progress of developing countries in providing sustainable energy access. Different sets of sustainability indicators are considered for the rural energy sector and aggregated to form a single composite index. The energy technology sustainability index (ETSI) is used for assessing the performance of different energy technological systems in the case of India. The analysis reveals that mature technologies such as biomass gasifiers, biogas and micro hydro have relatively better sustainability performance among the options considered, while solar and wind, though showing fairly good improvement in sustainability performance, still have difficulties competing with more mature and conventional technologies without policy support. The Energy Sustainability Index (ESI) has been applied to China, India, South Africa, Sri-Lanka, Bangladesh and Ghana between 1990 and 2010 to evaluate the status and progress made by these countries in rural energy sustainability. The analysis suggests that South Africa’s rural energy sustainability index is highest followed by China, Sri Lanka, India, Bangladesh and Ghana respectively. The rural energy sustainability has improved relatively over time in all countries except Ghana. The dissertation shows that policies are helping the rapid expansion of the RE market though with uneven penetration in rural Nepal. Access to credit and cumbersome subsidy delivery mechanism are perceived as the major factors affecting the expansion of rural electrification, requiring innovation. The electrification pathways taken by Nepal seem functional and moving in the right direction but some flaws in the delivery mechanisms require attention. Meanwhile in Afghanistan, pathways are not well defined and the country lacks a clear-cut national policy framework for the expansion of rural electrification. The analysis on fuel transition shows that even a fast developing country such as China will continue to have serious problems guaranteeing the access to solid fuels for cooking for one third of its rural population by 2030. The problem could be more severe in poorer nations. There-fore, further policy intervention addressing the high implicit discount rate of the poorer section of the population, reducing the upfront cost of more efficient technology (stoves) or the costs of cleaner fuels with subsidies must be considered to promote energy transition. Overall, this dissertation has analysed key issues in the global discussion about sustainable energy access. The methods for sustainability assessment suggested have been specially designed for rural settings in developing countries and are instrumental to assess the performance of rural energy technologies and track the progress of sustainable energy access efforts among rural households. / <p>QC 20140210</p>
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From Gap to Opportunity: The A-B-C Telecom Mini-grid Model for East AfricaRodríguez Gómez, Alberto January 2013 (has links)
Modern energy poverty in sub-Saharan Africa is one of the primary challenges that humanity faces today. Rural electrification in this region is a complex issue that needs to be well understood by developed and developing countries in order to thrive on this situation. Further, due to the significant amount of installed capacity that this market will represent in the coming decades, the impact of this market in climate change could be irreversible. There is, therefore, a need of well addressing this market in order to mitigate and minimize its impact in climate change. This work first presents and studies the rural electrification market in sub- Saharan Africa and second, focuses in Mini-grids, one of the most successful alternatives to grid extension in the last decade. By analyzing the different aspects that a Mini-grid involves and reviewing several case studies worldwide, this thesis tries to identify what are the challenges and opportunities that Mini-grids face to become successful in sub-Saharan Africa, particularly in East Africa where the author has carried a 6-month internship hosted by the company African Solar Designs Ltd (Nairobi, Kenya). Innovative Business models, Policy and Inclusive Business are identified as key aspects of Mini-grids as failures in the experiences in sub-Saharan Africa. The A-B-C Telecom Mini-grid approach (A: Anchor, B: Business; C: Community) is presented here as a commercially viable solution for Mini-grids in rural areas of East Africa, where there is a need of access to modern energy as well as many off-grid Base Telecom Stations that need more affordable electricity. The A-B-C Telecom Mini-grid model is first defined, secondly the technology is simulated and optimized using Homer software; a PV-diesel hybrid Mini-grid is selected the best option for this market. Then the business model for the A-B-C concept is defined and is financially simulated under certain parameters shown. A financial sensitivity analysis is also implemented to understand how viable is the model presented and how sensible to certain financial parameters is. To finish with, this project identifies the model limitations and the major barriers that this model face to succeed; favorable regulatory environment, finance to scale up the concept and donor agencies and rural energy practitioners to understand and switch their approach of rural electrification projects into a more sustainable and commercially viable one.
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Energy-Water-Agriculture Nexus Mini-grids to Power Rural Productive Hubs in Sub-Saharan Africa : A case study of Walta Jalala village in Bedeno Woreda of EthiopiaBiramo, Israel January 2020 (has links)
The thrive to achieve Sustainable Development Goal 7 is never been easy, and numbers are still showing that Sub-Saharan Africa is lagging in access to electricity index. Most of the energy poor communities residing in the rural part of the region, this by itself is a conundrum with multifaceted implications. The high capital expenditure for renewable energy technologies, the low paying ability of the society in Sub-Saharan Africa, the unavailability of anchor customer’s and so on needs new means of approaching the access problem. This study aims to enlighten policy makers on promoting energy as input to production than merely focusing on the access issue. In the report, a renewable mini-grid powering a local economic activity of a remote agrarian village in Ethiopia is discussed. Through a simulation study using PVsyst and Homer Pro tools, a yearly optimized PV diesel hybrid system with rounded up lowest LCOE of $0.17/kWh is obtained for the village in the case study. The LCOE of the mini-grid with lead acid battery and Li-ion battery is also studied at a yearly average operating temperature range of 10 to 40 ℃. The simulation-based study demonstrated that mini-grid systems with lead acid and Li-ion battery have fairly comparable LCOE between 10 to 20 ℃, however the Li-ion battery results in a lower LCOE for operating temperature beyond 25 ℃. The study has shown that mini-grids with productive energy can be cost effective option for powering areas where the grid-connection is cost and time intensive to address the energy poverty issue by 2030 or after.
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Pathways towards universal access to electricity in West Africa : Case study of Mali and SenegalBozzo, Vittorio January 2023 (has links)
Despite the vast solar potential in both Mali and Senegal, the electricity access in both countries remains one of the lowest in the world. The main problem is represented by the disparity between rural and urban settlements. In Senegal, the electricity access for rural areas was lower than 50%, while in Mali was around 35%. Although the grid represents and will still represent the main driver to ensure electricity access, solar off-grid technologies can help reach rural communities living far from the grid. This study used a GIS-based approach to study electricity models for Senegal and Mali. This has been done in order to integrate physical geographical constraints like GHI, slope and grid infrastructure, and socio-demographical constraints like population density, and distance of rural settlements from the grid. The modeling tool OnSSET together with the QGIS mapping tool is used in this thesis.To achieve future electricity targets, the modeling period of this study has been set to 2020-2030. Under this study for both countries, two scenarios have been analyzed. A sensitivity analysis will help to analyze the influence of the demand level and the grid’s generation price on the results of these scenarios. For Mali, an optimistic scenario considering a 100% electrification rate by 2030, with a reliable grid and a low grid electrification price is designed. A second scenario follows an opposite approach where only 70% will have access to electricity, mainly due to an inadequate grid state. For both scenarios, the results show that the population connected to the grid will be between 70% and 60%. The total investment needed to reach universal access in Mali is between $3.7 and $3.2 billion. The highest share of this investment will be dedicated to the implementation and maintenance of the grid, between $2 and $1.6 billion. Stand-Alone and mini-grid PV will contribute to bringing electricity to 10 to 20% of the population. For Senegal, an optimistic scenario considers a really good grid state and a 100% electrification rate. A second pessimistic scenario considers an inadequate state of the grid, with an electricity access level of 90%. The results show that the population connected to the grid will be between 80% and 70%. The investment required to reach universal access by 2030 will be between $2.3 and $1.9 billion. Most of this investment will be dedicated to the maintenance and implementation of the grid. For Senegal stand-alone, PV mini-grids and hydro-mini-grids will bring electricity to between 6 and 10% of the population. / Trots den enorma solpotential som finns i både Mali och Senegal är tillgången till elektricitet i de båda länderna fortfarande en av de lägsta i världen. Det största problemet representeras av skillnaden mellan landsbygd och tätort. I Senegal var eltillgången för landsbygdsområden lägre än 50%, medan den i Mali var omkring 35%. Även om elnätet representerar och fortsatt kommer att representera den främsta drivkraften för att säkerställa tillgång till elektricitet, kan solteknik utanför elnätet bidra till att nå landsbygdssamhällen som är belägna långt från elnätet. Denna studie använde en GIS-baserad metod för att studera elmodeller för Senegal och Mali. Detta har gjorts för att integrera fysiska geografiska begränsningar som GHI (global horisontal solstrålning), lutning och nätinfrastruktur, samt sociodemografiska begränsningar som befolkningstäthet och avståndet mellan bebyggelse på landsbygden från elnätet. Modelleringsverktyget OnSSET tillsammans med kartläggningsverktyget QGIS används i denna avhandling. För att nå framtida elmål har modellperioden för denna studie satts till år 2020-2030. Under denna studieperiod har två scenarier analyserats för båda länderna. En känslighetsanalys kommer att hjälpa till att analysera påverkan av efterfrågenivån och elnätets produktionspris på resultaten av dessa scenarier. För Mali är ett optimistiskt scenario designat, i betraktande av en 100% elektrifieringsgrad till år 2030, med ett tillförlitligt elnät och ett lågt nätelektrifieringspris. I ett andra scenario studeras ett motsatt tillvägagångssätt där endast 70% kommer att ha tillgång till el, främst på grund av ett otillräckligt nättillstånd. För de båda scenarierna visar resultaten att befolkningen som är ansluten till nätet kommer att vara mellan 60% och 70%. Den totala investeringen som krävs för att nå universell tillgång i Mali är mellan 3,2 och 3,7 miljarder dollar. Den största andelen av denna investering kommer att ägnas åt en implementering och ett underhåll av elnätet, vilket är mellan 1,6 och 2 miljarder USD. Fristående elsystem och PV-mininät kommer att bidra till att få el till 10-20% av befolkningen. För Senegal betraktas ett optimistiskt scenario med ett väldigt bra nättillstånd och en 100% elektrifieringsgrad. I ett andra, pessimistiskt scenario, betraktas ett otillräckligt tillstånd av elnätet, med en eltillgångsnivå på 90%. Resultaten visar att befolkningen som är ansluten till elnätet kommer att vara mellan 80% och 70%. Investeringen som krävs för att nå universell tillgång till år 2030 kommer att vara mellan 1,9 och 2,3 miljarder dollar. Det mesta av denna investering kommer att tillägna underhåll och implementering av elnätet. För Senegal kommer fristående elsystem, PV-mininät och hydro-mininät att ge el till mellan 6-10% av befolkningen.
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Geospatial Optimisation Methods for Mini-grid Distribution Networks : MSc Sustainable Energy Engineering (SEE)La Costa, Jessica January 2022 (has links)
In 2019, 770 million people worldwide lived without electricity. As many as 490 million people could be electrified with 210,000 mini-grids by 2030. Obtaining information for decision-making is crucial to determine the viability of such a project. Currently, it is a major challenge for mini-grid developers to gather this information at the speed and scale necessary to make effective investment choices. Village Data Analytics (VIDA) is a decision-making tool used for mini-grid project planning and site selection. This paper presents a method to estimate the cost of a mini-grid distribution network on a site-by-site basis. This method can estimate the total demand, potential connections, distribution infrastructure components and corresponding costs for each site. The model can make predictions for 50 sites within two hours so the tool is especially useful for preliminary estimates in the planning phase. A more detailed study of the individual sites is recommended. Comparison with a benchmark has shown that on-site conditions often reveal activities that can only be captured by a survey. However, collecting on-site data is time-consuming and costly. Therefore, GIS and modelling tools can serve as a good approximation of the on-ground reality and are relevant to accelerate planning and support timely decision-making. / 2019 levde 770 miljoner människor världen över utan elektricitet. Så många som 490 miljoner människor skulle kunna elektrifieras med 210 000 mininät till 2030. Att få information för beslutsfattande är avgörande för att avgöra om ett sådant projekt är lönsamt. För närvarande är det en stor utmaning för utvecklare av mininät att samla in denna information i den hastighet och skala som krävs för att göra effektiva investeringsval. Village Data Analytics (VIDA) är ett beslutsfattande verktyg som används för projektering av mininät och platsval. Det här dokumentet presenterar en metod för att uppskatta kostnaden för ett distributionsnät för mininät på plats för plats. Denna metod kan uppskatta den totala efterfrågan, potentiella anslutningar, komponenter för distribution sinfrastruktur och motsvarande kostnader för varje plats. Modellen kan göra förutsägelser för 50 platser inom två timmar, så verktyget är särskilt användbart för preliminära uppskattningar i planeringsfasen. En mer detaljerad studie av de enskilda platserna rekommenderas. Jämförelse med ett riktmärke har visat att förhållanden på plats ofta avslöjar aktiviteter som bara kan fångas genom en undersökning. Men att samla in data på plats är tidskrävande och kostsamt. Därför kan GIS- och modelleringsverktyg fungera som en bra approximation av verkligheten på marken och är relevanta för att påskynda planering och stödja beslutsfattande i rätt tid.
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Sistemas fotovoltaicos integrados ao perfil de uso da edificação / Integrated photovoltaic systems to use the building profileMárcia Rose Alves de Macedo Azzolino Ricetta 08 December 2010 (has links)
Nos últimos anos, o consumo de energia vem crescendo mundialmente nos grandes centros urbanos, e esforços na área de eficiência energética estão sendo implantados, a fim de reduzir o consumo no horário da ponta e interrupções da rede. O aproveitamento das fontes renováveis, como o fotovoltaico em uma edificação se torna um atrativo a mais para a matriz energética num momento em que o país prima pela universalização dos serviços de energia e a classificação de edifícios comerciais, de serviço e públicos, além dos residenciais quanto à eficiência energética através do Procel Edifica (RTQ-C e RTQ-R). Os sistemas fotovoltaicos podem configurar perfis de uso nas edificações de modo a gerar energia para consumo próprio ou ligado à rede e ainda ter influência na arquitetura do prédio com revestimento: os perfis podem está em telhados, fachadas ou janelas, amenizando em alguns casos a carga térmica no prédio com sombreamento arquitetônico. Hoje, com o avanço da tecnologia no setor de armazenagem é possível, o atendimento com segurança e eficiência a uma edificação ou direcionar esta armazenagem a uma demanda específica como o atendimento à demanda de ciclo profundo, tais como, iluminação externa e recarga de veículos elétricos. Partindo da premissa de sistemas interruptos de energia, UPS, uso de fonte secundária como FV, baterias e Flywheel é apresentado uma forma de melhor gerenciar a energia armazenada, podendo estender a vida útil da bateria e conseqüentemente de todo o sistema fotovoltaico na edificação. Esta forma de armazenar energia proporciona um serviço de uso contínuo sem percepção das interrupções da rede com garantia de 20 anos, tal qual o módulo fotovoltaico, com esta proposta as perdas de energia elétrica na edificação serão atenuadas, pois a eletricidade será utilizada de forma eficiente e inteligente. O ponto de partida do estudo de caso no prédio do IBAM são os sistemas fotovoltaicos com geração distribuída (mini-redes) conectados à rede que são instalados para fornecer energia ao consumidor, complementando a quantidade de energia demandada, caso haja algum aumento do consumo de energia na edificação, ou ainda utilizar o sistema fotovoltaico na hora da ponta e interrupções do sistema da rede no período fora da ponta. A estocagem inercial por meio do Flywheel tem um papel fundamental nesta mini-rede (Flywheel, bateria VRLA, UPS, inversor e STS), pois a sua utilização pode ser apontada como uma inovação tecnológica quanto à regulação de tensão no sistema de energia elétrica, além de preparar a edificação para o smart-grid. Esta configuração de acumulação de energia permitiu a analise do deslocamento desta energia armazenada para o consumo no horário de ponta, mudando o conceito de sistemas fotovoltaicos autônomos no meio urbano e rural no país. Este conceito de armazenagem se confirma então como um aporte na eficiência de energia na edificação, podendo carrear economia de energia substancial, além de proporcionar uma confiabilidade no serviço de energia, com um baixo retorno do investimento e com uma garantia de funcionamento com pequena ou nenhuma manutenção durante o período de vida de 20 anos. / In recent years, energy consumption is globally growing in urban centers, and efforts in the area of energy efficiency are being implemented to reduce consumption of this at the time of the tip and grid outages. The use of renewable sources such as photovoltaic in a building becomes a more attractive energy matrix for a moment in which Brazil press for universal energy service and labeling of commercial buildings, service and public and residential on the efficiency energy through Procel Build (RTQ RTQ-C and-R). Photovoltaic systems can be used as coatings on buildings to generate energy for its own or connected to the mini-grid and still have influence on the architecture of the building: the coatings can is in roofs, facades or windows, softening in some cases the thermal load on building with architectural shading. Putting photovoltaic panels on the facades of the building allows us to serve the demand of the load with deep cycle, such as exterior lighting and possibly charging for electric vehicles. Today, with advancing technology in the storage industry is possible to service safely and efficiently in a storage building or direct this to a specific demand. Assuming uninterrupted power systems, UPS, use of secondary sources like PV, batteries and Flywheel is presented a way to better manage the stored energy and can extend battery life and consequently the entire PV system in the building. This way of storing energy provides a service perception of continuous use without interruption of the network with 20-year warranty, like the PV module, with this proposed loss of electricity in the building will be softened because the electricity will be used efficiently and intelligently. The starting point of the case study conducted in a commercial building in Rio de Janeiro is the photovoltaic systems with distributed generation (mini-grids) that are connected to the grid installed to provide power close to consumers, enhancing the amount of energy ofered if there is some increase in energy consumption in the building, or to use the PV system at the time of the tip and the grid system outages during off-peak. The storage through the inertial flywheel has a key role in this mini-grid (Flywheel, VRLA battery, UPS, inverter and STS), because their use can be considered a technological innovation for the voltage regulation in electric power system, and to prepare the building for the smart-grid. The accumulation of power by batteries and Flywheel UPS allowed the analysis of displacement of energy stored for consumption at peak hours, the same being managed by mini-grids, changing the concept of photovoltaic systems in urban and rural areas in Brazil . This form of storage is then confirmed as an intake of energy efficiency in building, as well as for the Brazilian energy matrix. Thus may carry substantial energy savings, and provide a service reliability of power, with a low return on investment and a guarantee of operation with little or no maintenance during the life of 20 years.
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Sistemas fotovoltaicos integrados ao perfil de uso da edificação / Integrated photovoltaic systems to use the building profileMárcia Rose Alves de Macedo Azzolino Ricetta 08 December 2010 (has links)
Nos últimos anos, o consumo de energia vem crescendo mundialmente nos grandes centros urbanos, e esforços na área de eficiência energética estão sendo implantados, a fim de reduzir o consumo no horário da ponta e interrupções da rede. O aproveitamento das fontes renováveis, como o fotovoltaico em uma edificação se torna um atrativo a mais para a matriz energética num momento em que o país prima pela universalização dos serviços de energia e a classificação de edifícios comerciais, de serviço e públicos, além dos residenciais quanto à eficiência energética através do Procel Edifica (RTQ-C e RTQ-R). Os sistemas fotovoltaicos podem configurar perfis de uso nas edificações de modo a gerar energia para consumo próprio ou ligado à rede e ainda ter influência na arquitetura do prédio com revestimento: os perfis podem está em telhados, fachadas ou janelas, amenizando em alguns casos a carga térmica no prédio com sombreamento arquitetônico. Hoje, com o avanço da tecnologia no setor de armazenagem é possível, o atendimento com segurança e eficiência a uma edificação ou direcionar esta armazenagem a uma demanda específica como o atendimento à demanda de ciclo profundo, tais como, iluminação externa e recarga de veículos elétricos. Partindo da premissa de sistemas interruptos de energia, UPS, uso de fonte secundária como FV, baterias e Flywheel é apresentado uma forma de melhor gerenciar a energia armazenada, podendo estender a vida útil da bateria e conseqüentemente de todo o sistema fotovoltaico na edificação. Esta forma de armazenar energia proporciona um serviço de uso contínuo sem percepção das interrupções da rede com garantia de 20 anos, tal qual o módulo fotovoltaico, com esta proposta as perdas de energia elétrica na edificação serão atenuadas, pois a eletricidade será utilizada de forma eficiente e inteligente. O ponto de partida do estudo de caso no prédio do IBAM são os sistemas fotovoltaicos com geração distribuída (mini-redes) conectados à rede que são instalados para fornecer energia ao consumidor, complementando a quantidade de energia demandada, caso haja algum aumento do consumo de energia na edificação, ou ainda utilizar o sistema fotovoltaico na hora da ponta e interrupções do sistema da rede no período fora da ponta. A estocagem inercial por meio do Flywheel tem um papel fundamental nesta mini-rede (Flywheel, bateria VRLA, UPS, inversor e STS), pois a sua utilização pode ser apontada como uma inovação tecnológica quanto à regulação de tensão no sistema de energia elétrica, além de preparar a edificação para o smart-grid. Esta configuração de acumulação de energia permitiu a analise do deslocamento desta energia armazenada para o consumo no horário de ponta, mudando o conceito de sistemas fotovoltaicos autônomos no meio urbano e rural no país. Este conceito de armazenagem se confirma então como um aporte na eficiência de energia na edificação, podendo carrear economia de energia substancial, além de proporcionar uma confiabilidade no serviço de energia, com um baixo retorno do investimento e com uma garantia de funcionamento com pequena ou nenhuma manutenção durante o período de vida de 20 anos. / In recent years, energy consumption is globally growing in urban centers, and efforts in the area of energy efficiency are being implemented to reduce consumption of this at the time of the tip and grid outages. The use of renewable sources such as photovoltaic in a building becomes a more attractive energy matrix for a moment in which Brazil press for universal energy service and labeling of commercial buildings, service and public and residential on the efficiency energy through Procel Build (RTQ RTQ-C and-R). Photovoltaic systems can be used as coatings on buildings to generate energy for its own or connected to the mini-grid and still have influence on the architecture of the building: the coatings can is in roofs, facades or windows, softening in some cases the thermal load on building with architectural shading. Putting photovoltaic panels on the facades of the building allows us to serve the demand of the load with deep cycle, such as exterior lighting and possibly charging for electric vehicles. Today, with advancing technology in the storage industry is possible to service safely and efficiently in a storage building or direct this to a specific demand. Assuming uninterrupted power systems, UPS, use of secondary sources like PV, batteries and Flywheel is presented a way to better manage the stored energy and can extend battery life and consequently the entire PV system in the building. This way of storing energy provides a service perception of continuous use without interruption of the network with 20-year warranty, like the PV module, with this proposed loss of electricity in the building will be softened because the electricity will be used efficiently and intelligently. The starting point of the case study conducted in a commercial building in Rio de Janeiro is the photovoltaic systems with distributed generation (mini-grids) that are connected to the grid installed to provide power close to consumers, enhancing the amount of energy ofered if there is some increase in energy consumption in the building, or to use the PV system at the time of the tip and the grid system outages during off-peak. The storage through the inertial flywheel has a key role in this mini-grid (Flywheel, VRLA battery, UPS, inverter and STS), because their use can be considered a technological innovation for the voltage regulation in electric power system, and to prepare the building for the smart-grid. The accumulation of power by batteries and Flywheel UPS allowed the analysis of displacement of energy stored for consumption at peak hours, the same being managed by mini-grids, changing the concept of photovoltaic systems in urban and rural areas in Brazil . This form of storage is then confirmed as an intake of energy efficiency in building, as well as for the Brazilian energy matrix. Thus may carry substantial energy savings, and provide a service reliability of power, with a low return on investment and a guarantee of operation with little or no maintenance during the life of 20 years.
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Evaluation of mini-grid versus stand-alone projects: a tool for decision-making on household connections in last-mile rural electrification projectsNoguera Alonso, Irene January 2022 (has links)
Electrification of isolated rural areas in developing countries is a key action for the total eradication of energy poverty. A growing number of authors argue that this electrification should be done with distributed energy systems that combine different renewable energy sources, rather than trying to reach these communities with grid extensions. This is evidenced by numerous projects that have been carried out over the last years in different developing countries with different needs, climatic conditions and resources. These projects have very scarce resources and therefore need to be optimised. To do so, it would be very important to standardise their design, but this is very difficult as there are many variables involved. One of the most common design decisions that remains to be standardised is the question: What is the best way to bring the electricity supply to all the houses in the rural area being electrified? This Master Thesis has worked on solving this question by developing a prefeasibility tool which includes a mathematical model of the energy dispatch which minimizes the OPEX, a function which calculates the CAPEX and a final function which obtains the LCOE of the system by using the outputs of the forementioned model and tool. The tool has been implemented into the programming language Julia. Some of the parameters that need to be input to the model are the number of households, geographical distances between households, types of cables, transformers, generation technologies installed powers, among others. Besides, once the tool has been developed a series of tryouts and analysis have been carried out to confirm the robustness of the tool as well as to learn more about the behaviour of the costs structure. By carrying out the analysis of the results, the tool has successfully proven its validity. Moreover, a sensitivity analysis has been carried out to answer questions like which is the cheapest option, keeping a household isolated from the clusters or creating a stand-alone system for it? To sum up, as it has been said, this thesis has tried to answer the question settled previously with the aim of creating a useful and standard tool that could help other similar projects in their decision-making processes. / Elektrifiering av isolerade landsbygdsområden i utvecklingsländer är en nyckelåtgärd för att totalt utrota energifattigdomen. Ett växande antal författare hävdar att denna elektrifiering bör göras med distribuerade energisystem som kombinerar olika förnybara energikällor, snarare än att försöka nå dessa samhällen med nätutbyggnader. Det vittnar om ett flertal projekt som har genomförts under de senaste åren i olika utvecklingsländer med olika behov, klimatförhållanden och resurser. Dessa projekt har mycket knappa resurser och behöver därför optimeras. För att göra det skulle det vara mycket viktigt att standardisera deras design, men detta är mycket svårt eftersom det finns många variabler inblandade. Ett av de vanligaste designbesluten som återstår att standardisera är frågan: Vad är det bästa sättet att få elförsörjningen till alla hus på landsbygden som elektrifieras? Denna masteruppsats har arbetat med att lösa denna fråga genom att utveckla ett prefeasibility-verktyg som inkluderar en matematisk modell av energisändningen som minimerar OPEX, en funktion som beräknar CAPEX och en slutlig funktion som erhåller LCOE för systemet genom att använda utdata från den tidigare nämnda modellen och verktyget. Verktyget har implementerats i programmeringsspråket Julia. Några av parametrarna som behöver matas in i modellen är bland annat antalet hushåll, geografiska avstånd mellan hushållen, typer av kablar, transformatorer, genereringsteknik installerad kraft. När verktyget har utvecklats har dessutom en serie tester och analyser genomförts för att bekräfta verktygets robusthet samt för att lära sig mer om hur kostnadsstrukturen fungerar. Genom att genomföra analysen av resultaten har verktyget framgångsrikt bevisat sin giltighet. Dessutom har en känslighetsanalys genomförts för att svara på frågor som vilket år det billigaste alternativet, hålla ett hushåll isolerat från klustren eller skapa ett fristående system för det? Sammanfattningsvis, som det har sagts, har denna avhandling försökt besvara den tidigare ställda frågan i syfte att skapa ett användbart och standardverktyg som skulle kunna hjälpa andra liknande projekt i deras beslutsprocesser.
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