Phase unbalance on low-voltage electricity networks and its mitigation using static balancers

Beharrysingh, Shiva

January 2014

Existing low-voltage networks may not accommodate high penetrations of low-carbon technologies. The topic of this thesis is unbalance, which if minimised can delay or avoid the constraining of these technologies or the replacing of still-useful network assets. Most of the discussion on unbalance, as seen in the standards and the literature, centres on the effects of voltage unbalance on consumer equipment. Its effects on the network are not equally reported. This thesis recognises fundamental differences between the consumer and network perspectives. It can inform distribution network operators on the interpretation of measurements taken on low-voltage networks and guide research on unbalance due to high penetrations of low-carbon technologies. Much of the work involved simulations of LV networks. Initially, existing 3 x 3 or 5 x 5 approaches to the forward-backward sweep method were thought suitable. After a review of these approaches however, there were doubts as to how accurately they accounted for the shared neutral-earth return path on which the out-of-balance current flows. This led to the derivation of a new 5 x 5 approach using only Kirchhoff s voltage (KVL) and current laws (KCL). Its results are validated thoroughly in the thesis. In addition to satisfying KVL and KCL, they match Matlab SimPowerSystems exactly and are in close agreement with measurements taken on a very unbalanced rural feeder. This thesis also investigates the mitigation of unbalance using the static balancer. This is a transformer with a single interconnected-star winding. It was used in 1930-1950s to correct unbalance. Contributions are made for its possible re-introduction as a retrofit option. They include a model for use in the forward-backward sweep method, validated by laboratory and field measurements, and the quantification of the static balancer s strengths and weaknesses as this can help identify when it should be used.

621.381

Photovoltaic Power Production and Energy Storage Systems in Low-Voltage Power Grids / Solcellsproduktion och energilagringssystem i lågspänningselnät

Häggblom, Johan, Jerner, Jonathan

January 2019

In recent years, photovoltaic (PV) power production have seen an increase and the PV power systems are often located in the distribution grids close to the consumers. Since the distributions grids rarely are designed for power production, investigation of its effects is needed. It is seen in this thesis that PV power production will cause voltages to rise, potentially to levels exceeding the limits that grid owners have to abide by. A model of a distribution grid is developed in MathWorks MATLAB. The model contains a transformer, cables, households, energy storage systems (ESS:s) and photovoltaic power systems. The system is simulated by implementing a numerical Forward Backward Sweep Method, solving for powers, currents and voltages in the grid. PV power systems are added in different configurations along with different configurations of ESS:s. The results are analysed, primarily concerning voltages and voltage limits. It is concluded that addition of PV power production in the distribution grid affects voltages, more or less depending on where in the grid the systems are placed and what peak power they have. It is also concluded that having energy storage systems in the grid, changing the power factor of the inverter for the PV systems or lowering the transformer secondary-side voltage can bring the voltages down. / På senare tid har det skett en ökning i antalet solcellsanläggningar som installeras i elnätet och dessa är ofta placerade i distributionsnäten nära hushållen. Eftersom distributionsnäten sällan är dimensionerade för produktion så behöver man utreda effekten av det. I det här arbetet visas det att solcellsproduktion kommer att öka spänningen i elnätet, potentiellt så mycket att de gränser elnätsägarna måste hålla nätet inom överstigs. En modell över lågspänningsnätet skapas i MathWorks MATLAB. Modellen innehåller transformator, kablar, hushåll, energilager och solcellsanläggningar. Systemet simuleras med hjälp av en numerisk Forward Backward Sweep-lösare som beräknar effekter, strömmar och spänningar i elnätet. Solcellanläggningarna placeras ut i elnätet i olika konfigurationer tillsammans med olika konfigurationer av energilager. Resultaten från simuleringarna analyseras främst med avseende på spänningen i elnätet utifrån dess gränser. De slutsatser som dras i arbetet är att solcellsproduktion kommer att påverka spänningen, mycket beroende på var i elnätet anläggningarna placeras och storleken hos dem. Det visas också att energilager, justering av effektfaktor hos solcellsanläggningarna eller en spänningssänkning på transformatorns lågspänningssida kan få ner spänningen i elnätet. / <p>LiTH-ISY-EX--19/5194--SE</p>

electric power

power flow analysis

radial distribution system

low-voltage power grid

forward backward sweep method

photovoltaic power systems

energy storage systems

power factor

elkraft

effektflödesanalys

radiella distributionsnät

lågspänningselnät

forward backward sweep-metod

solcellsanläggningar

energilagringssystem

effektfaktor

Annan elektroteknik och elektronik

Modelagem de inversores em fluxo de potência considerando suporte de potência reativa como serviço ancilar na distribuição / Modeling inverters in power flow considering reative power support as ancillary service on distribution

Sarmiento, Jonattan Emanuel

23 June 2016

Made available in DSpace on 2017-07-10T16:41:34Z (GMT). No. of bitstreams: 1 Dissert Jonattan Emanuel Sarmiento2.pdf: 1326992 bytes, checksum: eeb1918a0e5e9c45ad54043cd1ea9c5e (MD5) Previous issue date: 2016-06-23 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / In recent years there has been a great increase in the use of distributed generators. This occurred not only by advances in production technologies of small generators and frequency inverters, but also by the benefits that brings to the distribution systems and the incentive policies. In the analysis of these systems is essential to calculate the power flow and properly solve it and the modeling of the inverter should be reviewed together with its implementation in the method employed, attempting to the fact that the inverters are beginning to use advanced functions that can to provide ancillary services. In this work the modelling of inverter with advanced functions such as Basic Intelligent Volt-Var Control (BIVV) and Intelligent Volt-Var With Hysteresis (IVVH) are reviewed, therefore it is propose methods the implements this models in the method sweep. In proposal implementation it is use of elements of the sensitivity matrix of nodes PV defined in the compensation method. In the analyzed cases, the implementations were effectiveness achieving solutions in convergent values and in accordance to the control strategies. In the results of simulations there were differences in the operating points of the inverter acting on a node of the distribution system comparing the different modeling analyzed in different system load conditions and different levels of active power supply. When comparing the voltage profiles of the various modeling, in general notice that there is a greater variation when it has large reactive power capacity. If in the future of distributed generation evolve to provide reactive support as the ancillary service, it shall be careful properly modelling the inverter avoiding mistaken results that will affect the plans of the concessionaires. / Nos últimos anos verificou-se um grande aumento no uso de geradores distribuídos. Isso ocorreu não apenas pelos avanços nas tecnologias de produção de pequenos geradores e inversores de frequência, mas também pelos benefícios que estes trazem aos sistemas de distribuição e pelas políticas de incentivos. Nas análises desses sistemas é fundamental calcular o fluxo de potência e, para resolvê-lo adequadamente, deve-se revisar a modelagem do inversor e sua implementação no método empregado, atentando-se ao fato de que os inversores estão começando a utilizar funções avançadas passíveis de fornecer serviços ancilares. Neste trabalho são revisadas as modelagens dos inversores com funções avançadas, tais como o controle Basic Intelligent Volt-Var (BIVV) e Intelligent Volt-Var With Hysteresis (IVVH), além de propor métodos de implementação para o método da varredura. Nas implementações propostas se faz uso de elementos da matriz de sensibilidade dos nós PV definida no método da compensação. Nos casos analisados, as implementações tiveram eficácia, conseguindo atingir soluções em valores convergentes e em concordância às estratégias de controle. Já nos resultados das simulações, ilustram-se as diferenças dos pontos operativos do inversor atuando em um nó do sistema de distribuição comparando-se as diferentes modelagens analisadas em distintas condições de carga do sistema e diversos níveis de fornecimento de potência ativa. Ao comparar-se os perfis de tensão das diversas modelagens, em geral, nota-se que há uma variação maior quando se tem maior capacidade de potência reativa. Se no futuro a geração distribuída evoluir para prestar suporte de potência reativa como um serviço ancilar, é necessário tomar precauções para modelar adequadamente o inversor, de modo a evitar obter resultados equivocados que afetarão os planejamentos das concessionárias.

serviços ancilares

geração distribuída

fluxo de potência

método da varredura

Modeling inverters

inverters with advanced functions

ancillary services

distributed generation

power flow

forward backward sweep