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ANÁLISE DA INFLUÊNCIA DE UM COMPENSADOR ESTÁTICO DE REATIVOS NA OPERAÇÃO DE SISTEMA ELÉTRICO INDUSTRIAL COM COGERAÇÃO / Analyze of the influence of a static var compensator in operation of a electrical energy industrial system with a cogenerationSilva Júnior, Gilson Soares da 15 February 2008 (has links)
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Previous issue date: 2008-02-15 / In this work is analyzed the influence of a static var compensator (SVC) on the
electromechanical stability of the electrical energy system of the industrial consumer
ALUMAR that has a cogeneration. The main considerations on cogeneration systems,
the FACTS Controllers and the systems involved in the analysis are described.
Moreover, it is discussed the modeling of electrical system of ALUMAR highlighting
the modeling updated and validated by the National Electric System Operator (ONS)
and the modeling of cogenerators. / Análise da influência de um compensador estático de reativos (SVC) na
estabilidade eletromecânica do sistema de energia elétrica do consumidor industrial
ALUMAR o qual possui cogeração. Descrevem-se as principais particularidades sobre
os sistemas de cogeração, os controladores FACTS e sobre os sistemas envolvidos na
análise. Discute-se, ainda, a modelagem do sistema elétrico da ALUMAR, destacandose
a modelagem atualizada e validada pelo Operador Nacional do Sistema (ONS) e a
modelagem dos cogeradores.
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Supervisory control scheme for FACTS and HVDC based damping of inter-area power oscillations in hybrid AC-DC power systemsHadjikypris, Melios January 2016 (has links)
Modern interconnected power systems are becoming highly complex and sophisticated, while increasing energy penetrations through congested inter-tie lines causing the operating point approaching stability margins. This as a result, exposes the overall system to potential low frequency power oscillation phenomena following disturbances. This in turn can lead to cascading events and blackouts. Recent approaches to counteract this phenomenon are based on utilization of wide area monitoring systems (WAMS) and power electronics based devices, such as flexible AC transmission systems (FACTS) and HVDC links for advanced power oscillation damping provision. The rise of hybrid AC-DC power systems is therefore sought as a viable solution in overcoming this challenge and securing wide-area stability. If multiple FACTS devices and HVDC links are integrated in a scheme with no supervising control actions considered amongst them, the overall system response might not be optimal. Each device might attempt to individually damp power oscillations ignoring the control status of the rest. This introduces an increasing chance of destabilizing interactions taking place between them, leading to under-utilized performance, increased costs and system wide-area stability deterioration. This research investigates the development of a novel supervisory control scheme that optimally coordinates a parallel operation of multiple FACTS devices and an HVDC link distributed across a power system. The control system is based on Linear Quadratic Gaussian (LQG) modern optimal control theory. The proposed new control scheme provides coordinating control signals to WAMS based FACTS devices and HVDC link, to optimally and coherently counteract inter-area modes of low frequency power oscillations inherent in the system. The thesis makes a thorough review of the existing and well-established improved stability practises a power system benefits from through the implementation of a single FACTS device or HVDC link, and compares the case –and hence raises the issue–when all active components are integrated simultaneously and uncoordinatedly. System identification approaches are also in the core of this research, serving as means of reaching a linear state space model representative of the non-linear power system, which is a pre-requisite for LQG control design methodology.
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[en] ECONOMIC VALUE OF REACTIVE POWER DEVICES / [pt] MAPEAMENTO DO VALOR ECONÔMICO DOS EQUIPAMENTOS DE COMPENSAÇÃO DE POTÊNCIA REATIVAIVO SERGIO BARAN 13 December 2002 (has links)
[pt] No novo modelo para o setor elétrico brasileiro a operação
do sistema é de responsabilidade do Operador Independente
do Sistema enquanto que a propriedade do equipamento e os
gastos com a sua manutenção são de responsabilidade do
agente prestador do serviço ancilar.Desta forma, o lucro do
agente prestador do serviço ancilar de potência reativa
será função do custo deste serviço uma vez que a sua
remuneração é previamente definida pelo agente regulador.
Dentro desta ótica os riscos operacionais dos equipamentos
de compensação de potência reativa, se não forem
convenientemente mitigados,poderão aumentar os gastos com a
manutenção e o pagamento de multa pela indisponibilidade do
equipamento.Riscos operacionais são situações de sistema
que estão fora da responsabilidade do agente mas que
poderão reduzir o seu faturamento.Esta dissertação descreve
os riscos operacionais e faz algumas sugestões para
proteger o agente da redução do seu faturamento. / [en] In the new brazilian deregulated electrical network, system
operation is under Independent System Operator
responsibility while the ancillary service agent is the
owner of the reactive power equipment and, as a
consequence, is responsible for its maintenance costs.
In the new model, the profit of the agent is a function of
the maintenance costs because his payment is previously
defined by the authorities. The operational risks of the
reactive power equipments, if not conveniently
mitigated, may increase the maintenance frequency and may
also result in the payment of a fee due to the equipment
unavailability.Operational risks are events in the
electrical transmission system that are not under the
responsibility of the agent but may reduce his profits.
This report describes these operational risks and makes
some suggestions to protect the agent against the reduction
in his profits.
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Controle de tensão e harmônicos por compensador estático de reativos com ajuste de parâmetros via redes neurais artificiaisLoureiro, Pedro da Cruz 16 April 2012 (has links)
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Previous issue date: 2012-04-16 / CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Neste trabalho é proposta a aplicação de redes neurais artificiais para ajuste de parâmetros de
um compensador estático de reativos, para controle de tensão e harmônicos. Devido à intensa
produção de correntes harmônicas e possíveis afundamentos de tensão em instalações
industriais como o forno a arco, é necessário um sistema de controle eficiente e robusto. Além
disso, os sistemas elétricos de potência se encontram em um cenário com a presença cada vez
maior de geração distribuída, cargas não-lineares e forte tendência à operação no contexto das
smartgrids e microgrids. Sendo assim, o suporte de reativos deve ser adequado a esses
sistemas, podendo atuar de forma rápida, precisa e confiável. Uma possível solução é a
utilização de um compensador estático de reativos (CER) com função adicional de filtragem
no ponto onde se deseja controlar a tensão e a distorção harmônica. Entretanto, para o correto
funcionamento, é necessário um sistema preciso para o ajuste dos parâmetros do CER, ou
seja, determinar os ângulos de disparo dos tiristores e o número de bancos de capacitores a
serem ligados. Neste trabalho é proposta uma estratégia de controle via redes neurais
artificiais, treinadas para o reconhecimento de padrões de operação em regime permanente e
definição da configuração do CER, conferindo inteligência ao equipamento.
Os desenvolvimentos propostos foram implementados no ambiente MatLab®. A validação do
método é feita através de simulações em sistemas-teste, presentes na literatura técnica,
utilizando o fluxo de potência pelo método de injeção de correntes trifásico harmônico. Os
resultados obtidos mostram as vantagens da utilização da estratégia proposta. / In this work, an artificial neural network-based static var compensator tuning is proposed for
voltage and harmonic distortion control. Due to intense harmonic current injection and
possible voltage sags produced by industrial facilities such as arc furnaces, an efficient robust
control system is needed. Besides, electrical power systems face a new scenario with high
penetration of distributed generation and non-linear loads and increased smart grid and
microgrid trends. Therefore, the available reactive power sources must be able to provide
system control in order to operate the system in a fast, accurate and reliable way. The
application of a static var compensator (SVC) with additional filtering function at the
controlled node is a possible solution. However, a precise SVC parameters tuning is needed,
in order to make the system to work properly. In this work, a control strategy based on
artificial neural networks is proposed. The neural networks are trained to recognize steadystate
operating patterns and give the SVC adjustment.
The proposed technique was implemented in the MatLab® environment. The methodology is
validated by simulations in test-systems available in technical literature, using the three-phase
harmonic current injection method power flow. Results show the advantages of the proposed
methodology.
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Voltage Stability Analysis of Unbalanced Power SystemsSantosh 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.
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