Revolução tecnológica na indústria de energia elétrica com smart grid, suas consequências e possibilidades para o mercado consumidor residencial brasileiro / The technological revolution in electricity industry with smart grid, its consequences and possibilities for the brazilian residential consumer market

Fróes Lima, Carlos Alberto, 1963-

21 August 2018

Orientador: Gilberto De Martino Jannuzzi / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-21T01:56:13Z (GMT). No. of bitstreams: 1 FroesLima_CarlosAlberto_D.pdf: 5418325 bytes, checksum: b0c14191595c15d33ea2a9082c7c0429 (MD5) Previous issue date: 2012 / Resumo: Este trabalho parte da premissa que as tecnologias para smart grid se apresentam como oportunidade para criar um novo negócio de energia. Todos os stake-holders devem ser envolvidos, e organizados para construir ou modernizar a rede de energia em seus aspectos de qualidade, disponibilidade, infraestrutura, padronização, interoperabilidade, confiabilidade e sustentabilidade. Deve-se também buscar a consciência de uso/demanda, de renda e de entendimento dos clientes de forma adequada. Pondera-se que as estratégias governamentais, no âmbito da legislação e da regulamentação, devem ser objetivas para garantir o novo negócio e proteger o interesse público. Os consumidores (como clientes) devem ser ouvidos, tornando-se partícipes ativos no mercado de energia. Com o desenvolvimento de um relacionamento dinâmico a indústria de energia necessitará de novas condições e requisitos operacionais que devem ser criados para garantir a transformação dentro e fora do ambiente de negócios regional. Foram estudadas novas tecnologias, novas possibilidades de serviços e preços. Incentivos, bem como a evolução das normas regulatórias apareceram como fundamentais para manter e expandir o fornecimento da energia e gerenciar a demanda, com implicações na melhora do relacionamento e nos investimentos/receitas para o capital investido, que necessitam resultar na ampliação da percepção de valor da energia pelos clientes. Uma avaliação para o caso brasileiro é feita considerando-se a experiência internacional até a data e através de exemplo de aplicação em consumidores residenciais como um estudo de caso. Demonstra-se o impacto para e do consumidor doméstico nos processos de uso da energia, bem como a evolução necessária de sistemas, estratégias para que se alcance o desejado momento histórico do desenvolvimento, da reorganização do mercado de energia e da legislação/regulamentação. Em suma, a evolução do negócio de energia no Brasil é um fato que, para sua eficácia, deve ser estrategicamente planejado nos diversos âmbitos de aplicação de tecnologias e modelagem do negócio, receber incentivos e ser regulado. Questões relacionadas aos investimentos a serem realizados e o retorno destes investimentos devem ser respondidas caso a caso, segundo a realidade regional das concessões, segundo as previsões de compartilhamento de custos com os consumidores e também totalmente relacionadas com a regulamentação adotada. A possiblidade da oferta de serviços e produtos para atendimento e ampliação do espaço de atuação das concessionárias brasileiras é uma transformação necessária para seu reconhecimento como provedoras de soluções energéticas. / Abstract: The smart grid technologies present themselves as opportunities to create new energy business. All stake holders must be involved, organizing, building and upgrading the power grid in its aspects of quality, availability, infrastructure, standards, reliability, interconnectivity, and sustainability. It is necessary the awareness target of supply-demand, incomes and strongly understand their clients. The Governmental strategies must be clear, with regulatory and legislative initiatives to foster new business and protect the public interest. Consumers (as clients) must be heard, as they become active players in the energy market. As they develop a dynamic relationship with the operating power industry new conditions and requirements need to be created in order to lead the strategic transformation inside and outside regional businesses. Deals on new energy sources, new technologies, new possibilities of differentials service and prices were studied. Incentives as well as the evolution of regulation rules seem a fundamental role to maintain and to expand the power supply and demand-side management, with implications for a better relationship between client-consumers, dealers and incomes/revenues on invested capital. It is also important to relate and to rethink the affordability of the tariffs and energy delivery costs to clients. An evaluation to the Brazilian market was done, considering the up to date international experiences and running an application, specially built to demonstrate the domestic consumption, as a case study. This implemented case is presented in order to demonstrate the domestic consumer impact to the energy use as well as the required evolution of systems and strategies to move on to this historical moment of development and reorganization of the energy market as well as the legislation/regulation. To sum up, evolving energy business in Brazil does not appear in this analysis merely as a possibility but as fact to be accomplished. It should be strategically planned considering the scope of a number of different technology applications, business models and be promoted by the policies agencies. Questions related to investments and their profits should be answered according to the regional energy business, as well as the consumer's participation and obviously new legislation and market regulation. Services and products to be offered by the Brazilian energy dealers should evolve correspondingly in order to improve business and recognition as energy solution providers / Doutorado / Planejamento de Sistemas Energeticos / Doutor em Planejamento de Sistemas Energéticos

Energia - Consumo

Eficiência energética

Smart power grids

Energy consumption

Energy efficiency

Configuring the Urban Smart Grid: Transitions, Experimentation, and Governance

Levenda, Anthony Michael

30 September 2016

In the face of challenges of energy security, decarbonization, resilience, and the replacement of aging infrastructure systems, federal, state, and local actors are facilitating the development of smart electricity networks to transition towards a more sustainable electricity system. In the United States, development of "smart grids" is being pursued as a national policy mandate and goal, promising that the deployment of smart grid technologies -- referring in general to digital information and communication technologies that sense, monitor, control and manage the electric grid -- will make electricity systems more environmentally sustainable and reliable, and at the same time, provide opportunities for growth and innovation. This dissertation examines and analyzes three interconnected issues relating to these sociotechnical changes in electricity infrastructure: the material and discursive construction of the smart grid, urban smart grid experimentation, and the mobility of smart grid models and knowledge. A conceptual framework is proposed for investigating sociotechnical transitions that accounts for dimensions of power and politics that are commonly overlooked in conventional analysis, and highlights how governance regimes shape and are shaped by sociotechnical change. Utilizing Foucauldian discourse analysis and relational comparative case study methodology, this dissertation analyzes the development of the smart grid as a governmental program highlighting its rationalities, techniques, and imagined subjects. The findings of these analyses suggest that the transition to a smarter grid involves much more than top-down policy mandates; significant urban experimentation is involved, as well as inter-city learning that is shaped by local political economy and broader political rationalities. This dissertation also argues for a synthesis between policy mobilities and sociotechnical transitions theory, highlighting through case studies how urban smart grid experiments are influenced by experiences and knowledge generated from "vanguard" cities. The conclusion of this dissertation is that the creation of the smart grid is far from a purely technical infrastructural intervention, and instead, requires significant changes in the everyday social practices and conduct of energy consumers, while also reconfiguring the city, engaging in a material politics in order to govern energy transitions.

Smart power grids

Power and Energy

Urban Studies and Planning

Desagregação de cargas no contexto smart grid / Load disaggregation in smart grid context

Pedrosa, Jézer Oliveira, 1970-

26 August 2018

Orientadores: Rangel Arthur, Francisco José Arnold / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Tecnologia / Made available in DSpace on 2018-08-26T23:50:19Z (GMT). No. of bitstreams: 1 Pedrosa_JezerOliveira_M.pdf: 1689446 bytes, checksum: fa812fba987c6c905ee50de809f6f732 (MD5) Previous issue date: 2015 / Resumo: Neste trabalho é criada uma base de dados de sinais de corrente de cargas domésticas e é proposta uma técnica para a identificação dessas cargas, etapa necessária para a desagregação das cargas dentro do contexto SMART GRID. A técnica de desagregação proposta baseia-se no uso de redes neurais e na transformada wavelet. A identificação das cargas elétricas tem como objetivo a descoberta de qual equipamento está ligado na rede elétrica. Dessa forma é possível calcular separadamente quanto cada equipamento está consumindo de energia elétrica. Os resultados obtidos a partir das informações extraídas com o emprego dos algoritmos propostos são discutidos e apresentados. Os algoritmos de processamento e identificação das cargas via redes neurais e transformada wavelet foram desenvolvidos no ambiente do MATLAB. Os resultados encontrados comprovam a eficácia da técnica proposta / Abstract: This work aims to create a current signal database of domestic loads and proposes a technique for identifying such loads, necessary step for the disaggregation of loads in the Smart-grid context. The disaggregation of the proposed technique is based on the use of neural networks and wavelet transform. The identification of electrical loads aims to discover what equipment is connected to utility power. Thus it is possible to calculate separately for each device is consuming electricity. The results obtained from the information derived from the proposed algorithms are discussed and presented. The algorithms processing and load identification by wavelet and neural networks were developed using MATLAB environment. The results prove the efficiency of the proposed technique / Mestrado / Tecnologia e Inovação / Mestre em Tecnologia

Redes elétricas inteligentes

Redes neurais (Computação)

Transformada wavelet

Smart power grids

Neural networks

Wavelet transforms

Signal Processing and Machine Learning Methods for Internet of Things: Smart Energy Generation and Robust Indoor Localization

Chen, Leian

January 2022

The application of Internet of Things (IoT) where sensors and actuators embedded in physical objects are linked through wired and wireless networks has shown a rapid growth over the past years in various domains with the benefits of improving efficiency and productivity, reducing cost, providing mobility and agility, etc. This dissertation focuses on developing signal processing and machine learning based techniques in IoT with applications to 1) smart energy generation and 2) robust indoor localization in smart city. Smart grids, in contrast to legacy grids, facilitate more efficient electricity generation and consumption by allowing two-way information exchange among various components in the grid and the users based on the measurements from numerous sensors located at different places. Due to the introduction of information communications, a smart grid is faced with the risk of external attacks which is aimed to take control of the grid. In particular, electricity generation from photovoltaic (PV) systems is a mature power generation technology utilizing renewable resources, owning to its advantages in clean production, reduced cost and high flexibility. However, the performance of a PV system can be susceptible and unstable due to various physical failures and dynamic environments (internal circuit faults, partial shading, etc.). To safeguard the system security, fault or attack detection technologies are of great importance for PV systems and smart grids. Existing approaches on fault or attack detection either rely on the prediction by a predetermined system model which acts as reference data for comparison or can be applied only within a certain set of component (e.g., several PV strings) based on local statistical properties without the capability of generalization. Furthermore, the output performance of a PV system is dynamic under different environmental conditions (irradiance level, temperature, etc.), which can be optimized by the technique of maximum power point tracking (MPPT). However, previous studies on MPPT usually require prior knowledge of the system model or high computational complexity for iterative optimization. Smart city, as another important application of IoT, relies on analysis of the measurement data from sensors located at users and environments to provider intelligent solutions in our daily life. One of the fundamental tasks for advanced location-based services is to accurately localize the user in a certain environment, e.g., on a certain floor inside a building. Indoor localization is faced with challenges of moving users, limited availability of sensors and noisy measurements due to hardware constraints and external interferences. This dissertation first describes our advanced fault/attack detection and localization methods for PV systems and smart grids, then develops our enhanced MPPT techniques for PV systems, and finally presents our robust indoor localization methods for smartphone users, based on statistical signal processing and machine learning approaches. In Chapter 2 and Chapter 3, we proposes fault/attack detection method in PV systems and smart grids respectively in the framework of abrupt change detection utilizing sequential output measurements without assuming any prior knowledge of the system characteristics or particular faulty/attack patterns, such that an alarm will triggered regardless of the magnitude or the type of faulty/attack signals. Starting from the proposed fault detection method in Chapter 2, we present our fault localization method for PV systems in Chapter 4 where the central controller is able to identify the faulty PV strings without full knowledge of each local measurements. Chapter 5 studies the MPPT method under dynamic shading conditions where we adopt neural networks to assist the identification of the global maximum power point by depicting the relationship between the system output power and the operating voltage. In Chapter 6, to tackle the challenge of accurate and robust indoor localization for smart city when sensors provides noisy measurement data, we propose a cooperative localization method which exploits the readings of the received strengths of Wi-Fi signals at the smartphone users and the relative distances among neighboring users to combat the deterioration due to aggregated measurement errors. Throughout the dissertation, our proposed methods are followed by simulations (of a PV system or a grid under various operating conditions) or experiments (of localizing moving users with smartphones to record sensors' measurements). The results demonstrate that our proposed fault/attack detection and localization methods and MPPT schemes can achieve higher adaptivity and efficiency with robustness against various external conditions an lower computational complexity, and our cooperative localization methods have high localization accuracy even given large measurement errors and limited measurement data.

Electrical engineering

Machine learning

Internet of things

Smart power grids

Smart cities

Smartphones

Intelligent Fault Location for Smart Power Grids

Livani, Hanif

24 March 2014

Modernized and advanced electricity transmission and distribution infrastructure ensures reliable, efficient, and affordable delivery of electric power. The complexity of fault location problem increases with the proliferation of unusual topologies and with the advent of renewable energy-based power generation in the smart grid environment. The proliferation of new Intelligent Electronic Devices (IEDs) provides a venue for the implementation of more accurate and intelligent fault location methods. This dissertation focuses on intelligent fault location methods for smart power grids and it aims at improving fault location accuracies and decreasing the cost and the mean time to repair damaged equipment in major power outages subsequently increasing the reliability of the grid. The developed methods utilize wavelet transformation to extract the traveling wave information in the very fast voltage and current transients which are initiated immediately after a fault occurs, support vector machines to classify the fault type and identify the faulted branches and finally Bewley diagrams to precisely locate the fault. The approach utilizes discrete wavelet transformation (DWT) for analysis of transient voltage and current measurements. The transient wavelet energies are calculated and utilized as the input for support vector machine (SVM) classifiers. SVM learns the mapping between inputs (i.e. transient voltages and/or currents wavelet energies) and desired outputs (i.e. faulty phase and/or faulty section) through processing a set of training cases. This dissertation presents the proposed methodologies applied to three complex power transmission systems. The first transmission system is a three-terminal (teed) three-phase AC transmission network, a common topology in high- and extra high-voltage networks. It is used to connect three substations that are wide apart from each other through long transmission lines with a tee-point, which is not supported by a substation nor equipped with a measuring device. The developed method overcomes the difficulties introduced by the discontinuity: the tee point. The second topology is a hybrid high voltage alternative current (HVAC) transmission line composed of an overhead line combined with an underground cable. The proposed fault location method is utilized to overcome the difficulties introduced by the discontinuity at the transition point from the overhead line to the underground cable and the different traveling wave velocities along the line and the cable. The third topology is a segmented high voltage direct current (HVDC) transmission line including an overhead line combined with an underground cable. This topology is widely utilized to transmit renewable energy-based electrical power from remote locations to the load centers such as from off-shore wind farms to on-shore grids. This dissertation introduces several enhancements to the existing fault type and fault location algorithms: improvement in the concept of fault type classification and faulty section identification by using SVMs with smaller inputs and improvements in the fault location in the complex configurations by utilizing less measurements from the terminals. / Ph. D.

Fault Location

Fault Classification

Smart Power Grids

Support Vector Machines

Traveling Waves

Wavelet Transformation

Aspects of autonomous demand response through frequency based control of domestic water heaters

Cooper, Douglas John

January 2018

A dissertation submitted to the Faculty of Engineering and the Built Environment, University of the Witwatersrand, Johannesburg, in fulfilment of the requirements for the degree of Master of Science in Engineering in the School of Electrical and Information Engineering, July 2017 / This dissertation presents the design and testing of controllers intended to provide au- tonomous demand response, through the use of water heater loads and grid frequency measurements. The controllers use measured frequency as an indication of the strain on a utility grid, which allows demand side management to be isolated from any form of central control. Water heaters can operate as exible loads because their power consump- tion can be dispatched or deferred without directly impacting users. These properties make it possible to control individual water heaters based on the functioning of the grid, rather than end user input. The purpose of this research is to ultimately provide a low- cost alternative to a traditional Smart Grid, that will improve the resilience of a grid without negatively impacting users. The controllers presented here focus on ensuring that users receive hot water, while attempting to reduce any imbalance between power generated and power consumed on the grid. Simulations of these controllers in various situations highlight that while the controllers developed respond suitably to variations in the grid frequency and adequately ensure end users receive hot water, the practical bene t of the controllers depends largely on the intrinsic characteristics of the grid. / CK2018

Smart power grids

Water heaters

Electric water heaters

Electric power distribution--Automation

Electric power systems--Load dispatching

Investigation into a high reliability micro-grid for a nuclear facility emergency power supply

Lekhema, Gerard Ratoka

January 2017

A research report submitted to the Faculty of Engineering, University of the Witwatersrand, Johannesburg in partial fulfilment of the requirements for the degree of Master of Science in Engineering, Johannesburg, August 2017 / The objective of this research work is to investigate the use of a high reliability micro grid to supply emergency electrical power to a nuclear facility following loss of offsite power (LOOP) accident. Most of the nuclear facilities around the world utilize diesel generators and battery banks as emergency power to back up the grid power supply. This power supply configuration represents the concept of the micro-grid system. The research work proposes reliability improvement of the emergency power supply by introducing diverse energy sources and energy storage systems. The energy sources and storage systems that were investigated include renewable energy sources, decay heat recovery system and large scale energy storage systems. The investigation results presented include information on the suitable energy sources and energy storage system, establishment of the reliable architectural layout and evaluation of the micro-grid system in terms of capacity adequacy and reliability. / XL2018

Smart power grids

Renewable energy sources

Nuclear power plants--Reliability

Emergency power supply

Electric power systems--Reliability

An analysis and improvement of selected features of power quality of grid-tied alternative energy systems

Gupta, Gunjan

January 2018

Thesis (PhD (Electrical Engineering))--Cape Peninsula University of Technology, 2018. / Electrical energy can be easily used and converted to other forms of energy for various applications. Technological advancement increases the dependency on electricity to a great extent. Various internal and external factors are responsible for the bad quality of power in power systems. The performance of the system is greatly affected by the presence of harmonics, as well as voltage and frequency variations, which leads to the malfunctioning of the device and decline of power quality and supply at load side. The reactive power compensation is carried out for better power quality. The literature survey is done to find the best and efficient scheme for reactive power compensation and mitigation of various power quality problems. The devices which are used to measure various power quality factors are discussed. Various mitigating schemes are surveyed in order to compensate reactive power and to improve the power quality at the distribution end. The integration of the most widely used renewable energy, wind energy in the distribution system creates technical issues like stability of the grid, harmonic distortion, voltage regulation, active and reactive power compensation etc. which are restricted to IEC and IEEE standards. One of the topics this thesis addresses is regulation in the reactive power generated along with voltage regulation by using an effective power electronics device known as a STATCOM. The main power quality factors like overvoltage and voltage flickers are mitigated by establishing STATCOMs in small wind farms. The wind farms are equipped with three wind turbines. These three wind turbines found in the wind farm can be operated together or one after another with an introduced delay. A glitch in even a little piece of a power grid can result in loss of efficiency, income and at times even life. In this manner, it is basic to outline a system which can distinguish the faults of the power system and take a faster response to recover it back to required reactive power. Two devices STATCOM and D-STATCOM are used for this purpose in this thesis. The D-STATCOM circuit and operating principle are also discussed in thesis. Different topologies of D-STATCOM discussed with their benefits and shortcomings. The voltage, current and hybrid technologies of D-STATCOM are also discussed.

Smart power grids

Renewable energy sources

Electric power distribution

Energy development

Electric power system stability

Feeder reconfiguration scheme with integration of renewable energy sources using a Particle Swarm Optimisation method

Noudjiep Djiepkop, Giresse Franck

January 2018

Thesis (Master of Engineering in Electrical Engineering)--Cape Peninsula University of Technology, 2018. / A smart grid is an intelligent power delivery system integrating traditional and advanced control, monitoring, and protection systems for enhanced reliability, improved efficiency, and quality of supply. To achieve a smart grid, technical challenges such as voltage instability; power loss; and unscheduled power interruptions should be mitigated. Therefore, future smart grids will require intelligent solutions at transmission and distribution levels, and optimal placement & sizing of grid components for optimal steady state and dynamic operation of the power systems. At distribution levels, feeder reconfiguration and Distributed Generation (DG) can be used to improve the distribution network performance. Feeder reconfiguration consists of readjusting the topology of the primary distribution network by remote control of the tie and sectionalizing switches under normal and abnormal conditions. Its main applications include service restoration after a power outage, load balancing by relieving overloads from some feeders to adjacent feeders, and power loss minimisation for better efficiency. On the other hand, the DG placement problem entails finding the optimal location and size of the DG for integration in a distribution network to boost the network performance. This research aims to develop Particle Swarm Optimization (PSO) algorithms to solve the distribution network feeder reconfiguration and DG placement & sizing problems. Initially, the feeder reconfiguration problem is treated as a single-objective optimisation problem (real power loss minimisation) and then converted into a multi-objective optimisation problem (real power loss minimisation and load balancing). Similarly, the DG placement problem is treated as a single-objective problem (real power loss minimisation) and then converted into a multi-objective optimisation problem (real power loss minimisation, voltage deviation minimisation, Voltage stability Index maximisation). The developed PSO algorithms are implemented and tested for the 16-bus, the 33-bus, and the 69-bus IEEE distribution systems. Additionally, a parallel computing method is developed to study the operation of a distribution network with a feeder reconfiguration scheme under dynamic loading conditions.

Smart power grids

Algorithms

Swarm intelligence

Electric power systems -- Control

Mathematical optimization

Renewable energy sources

Estudo da microgeração distribuída no contexto de redes Inteligentes / Evaluation of the impact of distributed microgeneration in a smart grid context

Geraldi, Douglas

22 August 2018

Orientador: Luiz Carlos Pereira da Silva / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Elétrica e de Computação / Made available in DSpace on 2018-08-22T01:49:18Z (GMT). No. of bitstreams: 1 Geraldi_Douglas_M.pdf: 3918130 bytes, checksum: a6b640b4707af6b9173674deab29eece (MD5) Previous issue date: 2013 / Resumo: Existe atualmente um consenso de que as Redes Inteligentes favoreçam a solução de diversos problemas presentes no dia a dia das concessionárias distribuidoras de energia elétrica, tais como a gestão inteligente do carregamento e o gerenciamento automático na recuperação do fornecimento de energia (self-healing). Por outro lado, a implantação de tecnologias de redes inteligentes também pode criar novas dificuldades para as distribuidoras. Especial atenção deve ser dada à facilidade do acesso ao sistema elétrico por parte da microgeração - quer seja solar, eólica, micro turbinas a gás, etc. - possibilitada pela substituição dos medidores atuais por medidores inteligentes e por legislação específica recentemente publicada pela ANEEL. Neste trabalho busca-se apontar e quantificar alguns impactos técnicos relacionados à injeção de potência em um circuito secundário de distribuição. Através do estudo de cenários com crescente nível de penetração de microgeradores fotovoltaicos residenciais (tetos solares) são analisados os impactos na curva de carga do prossumidor, no perfil de tensão da rede, nas perdas elétricas e no desequilíbrio de tensão. As simulações dos cenários supracitados são realizadas através do software livre Gridlab-D, desenvolvido pela Pacific Northwest National Laboratory (PNNL) para estudos de aspectos de redes inteligentes via simulação computacional. Uma das vantagens desse pacote é a integração com base de dados meteorológicos, permitindo, por exemplo, a estimativa da geração fotovoltaica mês a mês para um determinado ano constante na base de dados / Abstract: Nowadays, there is a consensus that the Smart Grid can promote the solution of various problems present in distribution utilities, such as intelligent load management and self-healing. How-ever, the deployment of smart grid technologies can also create new difficulties. Special attention should be given to the open access to the electrical grid from the micro-generation plants, such as solar photovoltaic, wind turbines and gas micro-turbines, which will be possible with the re-placement of the current meters for smart meters and by specific regulation recently published by ANEEL. This work intends to identify and quantify some technical impacts related to power injection from micro-generators in a secondary distribution circuit. Through the study of scenarios with increasing penetration of residential photovoltaic micro-generators (solar roofs) some impacts are analyzed: impacts on the load profile of the prosumer; impacts on the voltage profile of the network; impacts on the electrical losses and voltage imbalance. The simulations of the above scenarios are performed by using Gridlab-D, free software developed by Pacific Northwest National Laboratory (PNNL) to study aspects of smart grids via computer simulation. One ad-vantage of this package is the integration with meteorological database, enabling, for example, the estimation of photovoltaic generation every month for a given year contained in the database / Mestrado / Energia Eletrica / Mestre em Engenharia Elétrica

Redes inteligentes de energia

Geração de energia fotovoltaica

Sistemas de energia fotovoltaica

Smart power grids

Photovoltaic power generation

Photovoltaic power systems