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1	A NEXT GENERATION AIRCRAFT POWER MONITORING SYSTEM Grossman, Hy 10 1900 (has links) ITC/USA 2007 Conference Proceedings / The Forty-Third Annual International Telemetering Conference and Technical Exhibition / October 22-25, 2007 / Riviera Hotel & Convention Center, Las Vegas, Nevada / Historically, aircraft power monitoring has required the use of multiple signal conditioning functions to measure various parameters including voltage, current, frequency and phase. This information was then post processed to determine the characteristics of the 3-phase power quality on the aircraft. Recent developments in embedded DSP processors within signalconditioning systems provide the instrumentation engineer with expanded capabilities for realtime on-board power quality monitoring. Advantages include reduced space and bandwidth requirements and minimal wiring intrusion. For each phase, output data may include peak positive and negative voltages and currents, peak-to-peak, average and RMS voltages and currents, phase power (real and apparent), phase power factor, phase period (frequency), phase shift measurement from phase 1 (the reference phase) to phase 2, and from phase 1 to phase 3. In addition, a Fast Fourier Transform (FFT) is performed on each phase voltage to provide Total Harmonic Distortion measurements. This paper describes the methods employed in the implementation of these functions on a single signal-conditioning card in order to provide detailed information about the power quality of a three-phase aircraft power source. Power Monitor Fast Fourier Transform Total Harmonic Distortion Three-Phase Power
2	Component Modeling and Three-phase Power-flow Analysis for Active Distribution Systems Kamh, Mohamed 19 January 2012 (has links) This thesis presents a novel, fast, and accurate 3 steady-state power-flow analysis (PFA) tool for the real-time operation of the active distribution systems, also known as the active distribution networks (ADN), in the grid-tied and islanded operating modes. Three-phase power-flow models of loads, transformers, and multi-phase power lines and laterals are provided. This thesis also presents novel steady-state, fundamental-frequency, power-flow models of voltage-sourced converter (VSC)-based distributed energy resource (DER) units. The proposed models address a wide array of DER units, i.e., (i) variable-speed wind-driven doubly-fed asynchronous generator-based and (ii) single/three-phase VSC-coupled DER units. In addition, a computationally-efficient technique is proposed and implemented to impose the operating constraints of the VSC and the host DER unit within the context of the developed PFA tool. Novel closed forms for updating the corresponding VSC power and voltage reference set-points are proposed to guarantee that the power-flow solution fully complies with the VSC constraints. All the proposed DER models represent (i) the salient VSC control strategies and objectives under balanced and unbalanced power-flow scenarios and (ii) all the operating limits and constraints of the VSC and its host DER unit. Also, the slack bus concept is revisited, associated with the PFA, where a 3 distributed slack bus (DSB) model is proposed for the PFA and operation of islanded ADNs. Distributing the real and reactive slack power among several DER units is essential to provide a realistic power-flow approach for ADNs in the absence of the utility bus. The proposed DSB model is integrated with the developed 3 PFA tool to form a complete ADN PFA package. The new PFA tool, including the proposed DER and DSB models, is tested using several benchmark networks of different sizes, topologies, and parameters. Many case studies, encompassing a wide spectrum of DER control specifications and operating modes, are conducted to demonstrate (i) the numerical accuracy of the proposed models of the DER units and their operating constraints, (ii) the effectiveness of the proposed DSB model for the islanded ADN PFA, and (iii) the computational efficiency of the integrated PFA software tool irrespective of the network topology and parameters. Smart Grids Voltage-Sourced Converter Active Distribution Networks Three-Phase Power-Flow 0544
3	Component Modeling and Three-phase Power-flow Analysis for Active Distribution Systems Kamh, Mohamed 19 January 2012 (has links) This thesis presents a novel, fast, and accurate 3 steady-state power-flow analysis (PFA) tool for the real-time operation of the active distribution systems, also known as the active distribution networks (ADN), in the grid-tied and islanded operating modes. Three-phase power-flow models of loads, transformers, and multi-phase power lines and laterals are provided. This thesis also presents novel steady-state, fundamental-frequency, power-flow models of voltage-sourced converter (VSC)-based distributed energy resource (DER) units. The proposed models address a wide array of DER units, i.e., (i) variable-speed wind-driven doubly-fed asynchronous generator-based and (ii) single/three-phase VSC-coupled DER units. In addition, a computationally-efficient technique is proposed and implemented to impose the operating constraints of the VSC and the host DER unit within the context of the developed PFA tool. Novel closed forms for updating the corresponding VSC power and voltage reference set-points are proposed to guarantee that the power-flow solution fully complies with the VSC constraints. All the proposed DER models represent (i) the salient VSC control strategies and objectives under balanced and unbalanced power-flow scenarios and (ii) all the operating limits and constraints of the VSC and its host DER unit. Also, the slack bus concept is revisited, associated with the PFA, where a 3 distributed slack bus (DSB) model is proposed for the PFA and operation of islanded ADNs. Distributing the real and reactive slack power among several DER units is essential to provide a realistic power-flow approach for ADNs in the absence of the utility bus. The proposed DSB model is integrated with the developed 3 PFA tool to form a complete ADN PFA package. The new PFA tool, including the proposed DER and DSB models, is tested using several benchmark networks of different sizes, topologies, and parameters. Many case studies, encompassing a wide spectrum of DER control specifications and operating modes, are conducted to demonstrate (i) the numerical accuracy of the proposed models of the DER units and their operating constraints, (ii) the effectiveness of the proposed DSB model for the islanded ADN PFA, and (iii) the computational efficiency of the integrated PFA software tool irrespective of the network topology and parameters. Smart Grids Voltage-Sourced Converter Active Distribution Networks Three-Phase Power-Flow 0544
4	Impact of electric vehicles in the steady state operation of distribution systems / Impacto de veÃculos elÃtricos na operaÃÃo em regime permanente de sistemas de distribuiÃÃo Erasmo Saraiva de Castro 15 June 2015 (has links) FundaÃÃo Cearense de Apoio ao Desenvolvimento Cientifico e TecnolÃgico / This work aims to quantify the impact in the steady state operation of a distribution system when electric vehicles are connected. It is worth noting that the connection of them may cause significant changes in the voltage profile, in the degree of voltage unbalance and in the electrical losses of the system. In order to make this analysis, a three-phase power flow program was developed in MATLAB language. This program is based on the Ladder Iterative Technique and it contains models of overhead distribution lines, underground distribution lines, spot loads, distributed loads connected in wye and delta, step voltage regulators, capacitor banks, three-phase transformers and the model of an electric vehicle. This model allows simulation of a real electric vehicle of model Tesla Roadster, produced by Tesla Motors. The test system used in all simulations was the IEEE 13 bus. Moreover, the methodology consisted in simulate the system with the voltage regulator and without the voltage regulator under heavy load and light load conditions. The electric vehicle was connected to a specific systemâs bus and it were considered that it could work as a load or as a distributed generator with or without positive sequence voltage control. Constants configurations of the electric vehicles were considered for the heavy load and light load cases. The results of the simulations reveal there was voltage violation due to the connection of electric vehicles acting as loads in the test system under heavy load conditions without voltage regulator. When they operate as generators, they can maintain the voltage unbalance under the allowed 2%, turning the systemâs voltages more balanced. There were significant reductions when the electric vehicles acted as a load (71.1%) and as generator (77.5%) on the total real power losses when the system operated with voltage regulator on the substation and the electric vehicles operated with positive sequence voltage control (specified at 1,0 pu). / Este trabalho tem o objetivo de quantificar o impacto da conexÃo de veÃculos elÃtricos na operaÃÃo em regime permanente de um sistema de distribuiÃÃo. Ã visto que a conexÃo dos mesmos pode causar mudanÃas significativas no perfil de tensÃes, no grau de desequilÃbrio de tensÃo e nas perdas elÃtricas do sistema. Para realizar essa anÃlise, desenvolveu-se um programa de fluxo de potÃncia trifÃsico na linguagem MATLAB. O programa Ã baseado na tÃcnica iterativa de escada. Foram implementados nesse programa modelos de linhas de distribuiÃÃo aÃreas e subterrÃneas, modelos de cargas concentradas e distribuÃdas conectadas em delta e em estrela, modelos de reguladores de tensÃo, modelos de banco de capacitores, modelo de transformadores trifÃsicos e o modelo do veÃculo elÃtrico. Esse modelo permite simular o veÃculo elÃtrico Tesla Roadster da Tesla Motors. O sistema teste utilizado em todas as simulaÃÃes foi o sistema IEEE 13 barras. A metodologia utilizada consistiu em simular o sistema sem regulador de tensÃo e com o regulador de tensÃo, em carga pesada e em carga leve. O veÃculo elÃtrico foi conectado a uma barra do sistema e considerou-se que o mesmo podia funcionar como carga ou gerador distribuÃdo sem e com controle de tensÃo de sequÃncia positiva no ponto de conexÃo. Adotou-se disposiÃÃes constantes de veÃculos elÃtricos para os casos de carga pesada e carga leve. Os resultados das simulaÃÃes revelam que houve violaÃÃo de tensÃo devido Ã inserÃÃo de veÃculos elÃtricos atuando como carga no sistema teste em carga pesada sem regulador de tensÃo. JÃ quando operam como gerador, os veÃculos elÃtricos diminuem o grau de desequilÃbrio em mÃdia, podendo mantÃ-lo abaixo do limite permitido de 2 %, tornando assim as tensÃes das barras trifÃsicas do sistema mais equilibradas. Houve reduÃÃes significativas quando os veÃculos elÃtricos atuaram como carga (71,1 %) e como gerador (77,5 %) na perda de potÃncia ativa total do sistema quando o sistema operou com regulador de tensÃo na subestaÃÃo e os veÃculos elÃtricos operaram com controle de tensÃo de sequÃncia positiva (especificada em 1,0 pu). VeÃculos elÃtricos Fluxo de potÃncia trifÃsico Electric Vehicle Three-phase power flow Voltage Regulator SISTEMAS ELETRICOS DE POTENCIA
5	Automation, Annunciation, and Emergency Safety Shutdown of a Laboratory Microgrid Using a Real-Time Automation Controller (RTAC) Vo, Do 01 May 2021 (has links) (PDF) Over the last decade, microgrid deployments throughout the world have increased. In 2019, a record number of 546 microgrids were installed in the United States [1]. This trend continues upward to combat extreme weather conditions and power shortages throughout the country. To better equip students with the necessary skillsets and knowledge to advance in the microgrid field, Cal Poly San Luis Obispo's Electrical Engineering Department and the Power Energy Institute have invested resources to develop a laboratory microgrid. This thesis sets to improve the laboratory microgrid's existing automation using the Schweitzer Engineering Laboratory SEL-3530 Real-time Automation Controller (RTAC). The improved automation features a new load-shedding scheme, LCD annunciator and meter panel, and emergency safety shutdown system. The load shedding scheme aims to enhance the grid's frequency stability when the inverter-based power output declines. The LCD annunciator and meter panels provide real-time oversight of the microgrid operating conditions via the RTAC Human Machine Interface (HMI). The emergency safety shutdown enables prompt de-energization and complete isolation of the laboratory microgrid in hazardous conditions such as earthquake, fire, arcing, and equipment malfunction and activates an audible siren to alert help. This safety system provides safety and peace of mind for students and faculties who operate the Microgrid. Lastly, this thesis provides an operating procedure for ease of operation and experiment. SEL-3530 RTAC Microgrid Safety Shutdown Annunciation Three Phase Power Protection. Power and Energy
6	Reguladores de tensão e geração distribuída em uma implementação de fluxo de potência a três e a quatro fios / Voltage regulators and distributed generation in a three and four wire power flow implementation CARVALHO, Rodrigo Mendonça de 20 April 2012 (has links) Made available in DSpace on 2014-07-29T15:08:18Z (GMT). No. of bitstreams: 1 DISSERTACAO_MESTRADO_Rodrigo M de Carvalho_2012.pdf: 3438844 bytes, checksum: 3b54078140704053b5706662ad841ff3 (MD5) Previous issue date: 2012-04-20 / As a distribution network grows, the need for voltage control and regulator devices increases, as well as the need for supplying the demands, which assists in monitoring and correction of their magnitudes. Thus, the use of voltage regulators and, more recently, distributed generation applications contribute to the improvement of the process of electric power distribution in order not only to supply the demands, but the quality of the energy supplied. This dissertation presents three three-phase step-voltage regulator models, each of Type B, and two distributed generation models, all of them implemented in a power flow application prepared according to the Backward/Forward Sweep algorithm. The three-phase voltage regulator models differ in their connection, that is, grounded-wye, closed-delta and open-delta, while models of distributed generation are identified by technology and size, being classified into PQ and PV nodes. Results are obtained from three distribution networks for different cases of use of voltage regulators and distributed generation. IEEE 13 and 34 bus systems were used for testing the evaluation algorithm and a 103 bus network, derived form one of the CELG distribution systems, were used as a real case example for the application of the implemented models of voltage regulators and distributed generation. The results were discussed and reviewed so that it is possible to identify the most efficient templates for each case or for the majority of the cases. / À medida que cresce uma rede de distribuição, aumenta a necessidade de dispositivos para a regulação e controle de tensão, assim como para suprimento das demandas, o que auxilia na monitoração e correção de suas magnitudes. Assim, a utilização de regulador de tensão e, mais recentemente, a aplicação de geração distribuída contribuem para o aperfeiçoamento do processo de distribuição da energia elétrica tendo em vista não só o atendimento da demanda, mas a qualidade da eletricidade fornecida. Esta dissertação apresenta três modelos de regulador de tensão de passo trifásico, todos do Tipo B, e dois modelos de geração distribuída, todos implementados em um aplicativo de fluxo de potência, o qual foi elaborado segundo o algoritmo Backward/Forward Sweep. Os modelos de regulador de tensão trifásicos se diferem em suas conexões, isto é, estrela aterrada, delta fechado e delta aberto, enquanto que os modelos de geração distribuída são identificados por sua tecnologia e tamanho, podendo se classificar em nós PQ e PV. São obtidos resultados a partir de três redes de distribuição para diferentes situações de utilização do regulador de tensão e da geração distribuída. Foram utilizadas os sistemas de 13 e 34 barras do IEEE para realização de testes avaliativos do algoritmo proposto e uma rede de 103 barras, derivada do sistema CELG de distribuição, como exemplo de caso real para aplicação dos modelos implementados de regulador de tensão e geração distribuída. Os resultados são comentados e analisados de forma que seja possível a identificação dos modelos mais eficientes para cada caso ou ainda para a maioria dos casos. distribuição de energia elétrica fluxo de potência trifásico geração distribuída regulador de tensão electric power distribution three-phase power flow distributed generation voltage regulator
7	Metodologia para alocação discreta e assimétrica de capacitores em sistemas elétricos de distribuição visando redução de desequilíbrio / Methodology for discret and asymmetric allocation of capacitor banks in distribution electrical systems aiming reduction of unbalance Santos, Ricardo Viol dos 27 August 2015 (has links) Submitted by Renata Lopes (renatasil82@gmail.com) on 2017-04-25T18:26:00Z No. of bitstreams: 1 ricardovioldossantos.pdf: 2585437 bytes, checksum: 897e63c2118d5c0e74581bbdb80ccb38 (MD5) / Approved for entry into archive by Adriana Oliveira (adriana.oliveira@ufjf.edu.br) on 2017-04-26T12:23:14Z (GMT) No. of bitstreams: 1 ricardovioldossantos.pdf: 2585437 bytes, checksum: 897e63c2118d5c0e74581bbdb80ccb38 (MD5) / Made available in DSpace on 2017-04-26T12:23:14Z (GMT). No. of bitstreams: 1 ricardovioldossantos.pdf: 2585437 bytes, checksum: 897e63c2118d5c0e74581bbdb80ccb38 (MD5) Previous issue date: 2015-08-27 / CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Buscando corrigir aspectos relacionados à qualidade de energia, bancos de capacitores em derivação são utilizados em alimentadores primários dos sistemas de distribuição. A busca pela melhor forma de alocação constitui um problema complexo de natureza matemática combinatória, ao incluir critérios técnicos conflitantes e restrições do sistema. Este problema não tem solução trivial, tornando-se importante a formulação de metodologias para auxiliar nessa tarefa. Neste trabalho, é proposta uma metodologia para alocação de bancos de capacitores em derivação em nós do sistema elétrico, com possibilidade de alocação desequilibrada, considerando sua natureza discreta, com objetivo de minimizar desequilíbrios de tensão e custos de alocação, baseada em aplicação de algoritmo genético. Foram consideradas também restrições tais como limites de correntes nos alimentadores, limites de tensão para a conformidade com as faixas adequadas de tensão padronizadas pelos órgãos competentes e a disponibilidade de bancos. / Seeking for correcting issues related to power quality, shunt capacitor banks are used in primary feeders of distribution systems. The search for the best allocation is a complex problem of combinatorial mathematical nature, including conflicting technical criteria and constraints of the system. This problem has nontrivial solution, making important the development of methodologies to assist in this task. In this work, it is proposed a methodology for allocation of shunt capacitor banks in electric system nodes, with the possibility of unbalanced allocation, considering its discrete nature, with the purpose of minimizing voltage imbalances and allocating costs, based on genetic algorithm application. Restrictions such as limits of current feeders, voltage limits for compliance with the appropriate standard voltage ranges and the availability of capacitor banks were considered. CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA Algoritmo genético Alocação de bancos de capacitores Correção de desequilíbrio Fluxo de potência trifásico Sistemas desequilibrados Sistemas elétricos de distribuição Genetic algorithm Capacitor banks allocation Imbalance correction Three phase power flow Unbalanced systems Electrical distribution systems
8	Modelování nesymetrického třífázového vedení / Modelling of unsymmetrical three-phase line Vápeník, René January 2009 (has links) The subject of the thesis is creation and description of mathematical model of three-phase asymmetric power line and proposal for three-phase operation calculating of the power network by variet aspects. Another component is the creation of a program in PHP, which would use this mathematical model for the calculation of the three-phase operation of the power network. Part of this work deals with derivation of matrices of elementary multipoles and their serial ordering derive complex multipoles that can be use for concentrated parameters compensation of the power lines.
9	Voltage Stability Analysis of Unbalanced Power Systems Santosh Kumar, A January 2016 (has links) (PDF) The modern day power system is witnessing a tremendous change. There has been a rapid rise in the distributed generation, along with this the deregulation has resulted in a more complex system. The power demand is on a rise, the generation and trans-mission infrastructure hasn't yet adapted to this growing demand. The economic and operational constraints have forced the system to be operated close to its design limits, making the system vulnerable to disturbances and possible grid failure. This makes the study of voltage stability of the system important more than ever. Generally, voltage stability studies are carried on a single phase equivalent system assuming that the system is perfectly balanced. However, the three phase power system is not always in balanced state. There are a number of untransposed lines, single phase and double phase lines. This thesis deals with three phase voltage stability analysis, in particular the voltage stability index known as L-Index. The equivalent single phase analysis for voltage stability fails to work in case of any unbalance in the system or in presence of asymmetrical contingency. Moreover, as the system operators are giving importance to synchrophasor measurements, PMUs are being installed throughout the system. Hence, the three phase voltages can be obtained, making three phase analysis easier. To study the effect of unbalanced system on voltage stability a three phase L-Index based on traditional L-Index has been proposed. The proposed index takes into consideration the unbalance resulting due to untransposed transmission lines and unbalanced loads in the system. This index can handle any unbalance in the system and is much more realistic. To obtain bus voltages during unbalanced operation of the system a three phase decoupled Newton Raphson load ow was used. Reactive power distribution in a system can be altered using generators voltage set-ting, transformers OLTC settings and SVC settings. All these settings are usually in balanced mode i.e. all the phases have the same setting. Based on this reactive power optimization using LP technique on an equivalent single phase system is proposed. This method takes into account generator voltage settings, OLTC settings of transformers and SVC settings. The optimal settings so obtained are applied to corresponding three phase system. The effectiveness of the optimal settings during unbalanced scenario is studied. This method ensures better voltage pro les and decrease in power loss. Case studies of the proposed methods are carried on 12 bus and 24 bus EHV systems of southern Indian grid and a modified IEEE 30 bus system. Both balanced and unbalanced systems are studied and the results are compared. Voltage Stability Reactive Power Optimization Phasor Measurement Unit (PMU) Voltage Stability Analysis L-Index Voltage Stability Index EHV System Three Phase Transmission Three Phase Power System Three Phase Load Flow Newton Raphson Method On Load Tap Changer (OLTC) Static Var Compensator (SVC) Electrical Engineering

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