External Reactive Power Compensation of Permanent Magnet Synchronous Generator

Singer, Amr

09 June 2011

This research work focuses on the reactive power compensation of the permanent magnet synchronous generator (PSG) in wind power plants. PSG feeds a fixed voltage dc grid through a rectifier bridge. In variable speed operation, the PSG will be able to build torque only in small speed range. This is due to the fixed magnet of the PSG. External reactive power compensation provides an attractive solution to overcome this problem. Different reactive power compensation configurations were examined. Statics synchronous series compensation and a shunt passive filter were chosen as a compensation method. Simulation and implementation of small wind power plant were performed. The wind power plant consists of the synchronous generator, inverter, rectifier, coupling transformers and shunt passive filter. The experimental results agree to the proposed theory and simulation results. / Der Schwerpunkt meiner Promotion ist die Blindleistungskompensation bei einem permanenterregten Synchrongenerator. Der Synchrongenerator speist das Gleichsspannungsnetz über ein Gleichrichter. In der Drehzahlvariablen Betriebsverhalten können Nachteile auftreten. Die Folge ist, dass bei konstanter Gleichspannung und fester Erregung durch die Permanenterregung nur ein sehr kleiner Drehzahlbereich mit vernünftiger Drehmomentausbeute bedienbar ist. Ein möglicher Ausweg wäre eine variable Kompensationsspannung. Verschiedene Kompensationsverfahren wurden untersucht. Ein Series Active Filter und ein Shunt Passive-Filter wurden als Blindleistungskompensation gewählt. Im Rahmen meiner Dissertation beschäftige ich mich mit dem Aufbau und der Simulation einer Windkraftanlage. Diese besteht aus einem permanenterregten Synchrongenerator, einem Wechselrichrter, einem Gleichrichter, drei Transformatoren und einem passiven Filter. Das Versuchsergebnis zeigt, dass die Theorie mit der Simulation übereinstimmt.

Windkraftanlage

Permanent Magnet Synchronous Generator

Reactive Power Compensation

Statics synchronous series compensation

passive filter

power plant

ddc:620

Blindleistungskompensation

Synchrongenerator

Implementação de um controle digital para o compensador regenerativo de potência ativa

Nascimento, Bruno Moreira [UNESP]

28 May 2009

Made available in DSpace on 2014-06-11T19:22:32Z (GMT). No. of bitstreams: 0 Previous issue date: 2009-05-28Bitstream added on 2014-06-13T20:09:45Z : No. of bitstreams: 1 nascimento_bm_me_ilha.pdf: 1604913 bytes, checksum: f565cd826c9093459f7a60aa26c658fb (MD5) / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / A tendência dos sistemas de energia elétrica é uma operação cada vez mais próxima de seus limites operacionais. A presença de equipamentos que utilizam a eletrônica de potência, no controle e condicionamento da energia, é cada vez mais freqüente. A utilização de conversores como fonte de tensão, associados a elementos armazenadores de energia como, por exemplo, a bateria de sódio-enxofre, com alta densidade de energia, alta eficiência na carga e descarga e ainda um longo ciclo de vida, é a configuração básica de um Compensador Regenerativo de Potência Ativa. Compensação regenerativa de potência é um conceito que permite o armazenamento de energia em períodos favoráveis sob o ponto de vista dos custos da energia elétrica. Este conceito de compensação baseia-se no armazenamento da energia excedente ao longo do dia, nos períodos de menor tarifação, para utilizá-la nos horários de ponta (sobre-tarifa), aproveitando-se as vantagens contratuais de consumo de energia fora de ponta e promovendo-se uma melhor equalização de consumo, permitindo uma redução no contrato de demanda. Portanto, na compensação regenerativa de potência ativa, os períodos de consumo de energia são deslocados, com o objetivo de se obter redução na tarifa. Este conceito mostra-se interessante em sistemas com tarifação do tipo horo-sazonal, como é o caso brasileiro. Com o objetivo de se verificar tal troca de potência ativa, um modelo trifásico foi implementado e simulado. Os controles da potência ativa trocada entre o compensador e o sistema e da tensão na barra na qual o mesmo está instalado são realizados independentes e por controladores do tipo PID. Os sinais de controle dos interruptores semicondutores que compõe o conversor como fonte de tensão são gerados a partir do DSP TMS320F2808 da Texas Instruments, o que está embarcado no módulo didático eZdsp F2808 da Spectrum Digital / Nowadays, electric power systems are expected to work closer to their operating limits. Power electronics based controllers, such as voltage sourced converters, are increasingly present in power systems. Electronic devices are often used to energy controlling and conditioning. The use of voltage sourced converters, associated to high-density storage elements, is the basic configuration of a Regenerative Active Power Compensator. Regenerative Active Power Compensator is a concept which proposes the energy storage as a possibility for revaluation of electrical energy cost with demand contracts. This concept is based on storing energy surplus during off peak periods, when the energy cost is cheaper, and injecting it back to the system during the overpriced peak periods. This procedure allows a better equalization of energy consumption and a reduction in electric power demand contracts. Therefore, using regenerative active power compensation, the consumption is dislocated from peak periods, resulting in a reduction of energy costs for the consumer. This concept is especially attractive for countries that use hour-seasonal fees police, as in the Brazilian case. This work proposes a three-phase model simulation with digital signal processor controller to investigate the active power flow control between the power system and the compensator, using a proportional-integral-derivative control strategy. The control signals are generate using the Texas Instruments DSP TMS320F2808, witch is embedded into the eZdsp F2808 didactic module, from Spectrum Digital

Compensação de potência ativa

Modulação vetorial espacial

Active power compensation

Space vector PWM and DSP

Análise de um mecanismo de compensação de reativos incorporado aos inversores de um sistema fotovoltaico conectado à rede elétrica / Analysis of a reactive power compensation mechanism incorporated into inverters of a grid-connected photovoltaic system

Ricardo da Silva Benedito

14 November 2014

No Brasil, quando uma unidade consumidora (UC) sob regime de microgeração ou de minigeração distribuída tem parte ou a totalidade da sua demanda por potência ativa suprida pela planta geradora, mas sua demanda por potência reativa é atendida exclusivamente pela rede elétrica, verifica-se uma aparente deterioração do fator de potência dessa UC, sob a ótica da concessionária. Esse efeito decorre do fato de que o fator de potência, de acordo com a regulamentação vigente, é determinado apenas a partir das medições dos fluxos de potência ativa e reativa trocados entre a UC e a rede elétrica e não também entre a planta geradora e UC. Para consumidores do Grupo A (tensão de fornecimento igual ou superior a 2,3 kV) nessa situação, de acordo com o perfil da carga, pode haver cobrança por excedentes de reativos, constituindo-se assim uma barreira. Especificamente no caso de sistemas fotovoltaicos conectados à rede, existe a possibilidade de se utilizar os próprios inversores c.c.-c.a para suprir a demanda de reativos da UC e, dessa forma, minimizar o problema apresentado. Com o objetivo de se avaliar essa alternativa no contexto brasileiro, tendo-se em vista condições reais de operação e os limites normativos de injeção de potência reativa para inversores de sistemas fotovoltaicos, foi realizado um estudo de caso de uma planta fotovoltaica instalada no telhado do prédio da Administração do Instituto de Energia e Ambiente da Universidade de São Paulo. O estudo mostrou que a compensação realizada por meio do inversor selecionado evitou a cobrança de excedentes de reativos sem afetar de forma significativa a produtividade do sistema fotovoltaico. Do ponto de vista elétrico, verificou-se que a injeção de reativos pelo inversor não provocou variações significativas de tensão no ponto de acoplamento ou no alimentador e, ainda, se verificou considerável liberação de capacidade do sistema supridor da concessionária. Dessa forma, a análise dos resultados indica uma tendência a se considerar a compensação de reativos proporcionada pelo próprio inversor a opção mais viável para se lidar com os excedentes de reativos, comparativamente a métodos convencionais de compensação ou à situação em que nenhuma ação compensatória seja implementada. / In Brazil, when a consumer unit (CU) under a distributed microgeneration or minigeneration scheme has part or all of its demand for active power supplied by the generating plant, but its demand for reactive power is served exclusively by the grid, the power factor of this CU appears deteriorated, from the perspective of the utility. This effect is due to the fact the power factor, according to the current regulations, is determined only from measurements of the flows of active and reactive power exchanged between the UC and the grid and not also between the generating plant and UC. Users of group A (supply voltage equal to or greater than 2.3 kV) in this situation, according to the CU load profile, may be charged due the reactive power excess, thus constituting a barrier. Specifically in the case of grid-connected photovoltaic systems, there is the possibility of using the d.c.- a.c. inverters to suply the CU reactive power demand and, thus, minimizing the presented problem. In order to evaluate this alternative in the Brazilian context, keeping in view real operating conditions and regulatory limits for the reactive power injection for photovoltaic inverters, we conducted a case study with a photovoltaic plant installed on the roof of the University of São Paulo Institute for Energy and Environment administration building. The study showed that the compensation performed by the selected inverter prevented the reactive power excess charging without affecting significantly the photovoltaic system productivity. From an electrical point of view, it was found that the injection of reactive power by the inverter did not cause significant voltage variations at the coupling point or at the transformer and, additionally, there was a significant release in the utility suply system capacity. Thus, the analysis results indicates a tendency to consider the compensation provided by the inverter itself the most viable option for dealing with the surplus of reactive power compared to conventional compensation methods or to the situation in which no compensatory action is implemented.

compensação de reativos

geração distribuída

distributed generation

grid-connected photovoltaic systems

reactive power compensation

Návrh koncepce kompenzace jalového výkonu v průmyslové síti / Design of reactive power compensation in distribution network

Popek, Jiří

January 2012

This thesis is about reactive power compensation in industrial network. Task is design reactive power compensation devices, so that the power factor, which is main indicator of power quality, was within the limits required by the distributor. This is applied to wholesale customers of electrical energy. Reactive power consumed by appliances increased the current that flows through the network, transmission losses and voltage drop. Reactive power compensation is a measure reducing load current and ohmic losses in a supply line. Given that the compensation is one of the significant cost-saving measures in electric power distribution. Distributor requires electric power consumption with a lagging power factor in the range from 0,95 to 1. Other values of power factor are penalized.

Dynamická kompenzace / Dynamic Compensation of Reactive Power

Horenský, Martin

January 2014

This master’s thesis is focusing on compensation of reactive power, especially on creating demonstrative model of static var compensation unit (SVC). Main topic of thesis is to apply this device for fast balancing dynamic conversions of recieved reactive power. In theoretical part is described suitable method for determination of instantaneous power. Next, there is basic description of all means used for compensation of reactive power and detailed description of the SVC compensator. Practical part includes design of compensation unit and control program in LabVIEW. The pq theory is implemented for detection instantaneous power. The results of validating functionality of compensator are presented in the last part of thesis.

Analysis of the Impact of Reactive Power Control on Voltage Stability in Transmission Power Grids

Cabadag, Rengin Idil

16 June 2020

Voltage stability is the ability of a power system to maintain acceptable voltages at all buses under normal and abnormal operating conditions. The scarcity of reactive power or reactive power imbalance is the main reason of voltage instabilities. The energy supply of Germany will be dominated by renewable energy sources (RES) within energy transition actions leading to a decrease in conventional power plants especially in the transmission grid. Since the conventional power plants are still main reactive power sources, key challenge in the future will be the provision of system services such as control of reactive power to maintain voltage stability in the transmission networks. A wide range of technology that is able to provide the required dynamic reactive power compensation is already available. However, in order to find the most effective implementation, it is necessary to investigate and compare these different technologies for a voltage stable grid operation. The main challenge regarding comparative studies that incorporate reactive power compensation devices is the development and the implementation of reliable comparison strategies. This thesis analyses the impact of reactive power on the voltage stability phenomena both in long-term and short-term time frames under various grid situations. Voltage stability margins in the long-term time frame are quantified by gradually increasing the reactive power injection into certain buses until the voltage collapses. Voltage stability in the short-term time frame is assessed by applying grid faults and simulating the time-domain grid response. A transient voltage severity ratio (TVSR) is developed in this thesis as the main comparison metric to evaluate and compare the performance of investigated compensation devices. Additionally, TVSR and other developed comparison metrics in this thesis are used to determine the optimal settings of the controller parameters of compensation devices. As a result, the submitted thesis shows a practical and reliable approach to analyze the performance of different compensation devices under different grid situations.

info:eu-repo/classification/ddc/621.3

ddc:621.3

Reaktiv effektkontroll i storskaliga solcellsanläggningar : Analys av växelriktarbaserade kontrollmetoder / REACTIVE POWER CONTROL INSOLAR PV FARMS : Analysis of inverter control method

Johansson, Jojje

January 2022

Rapporten redogör för en solcellsanläggnings generering av reaktiv effekt samt för de växelriktarbaserade kontrollmetoderna P(U), Konstant Q, Konstant Cosφ, Cosφ(P), Q(P) samt Q(U) för reaktiv effektkontroll. Rapporten redogör även för möjligheterna till att utnyttja solcellsanläggningen till reaktiv effektkompensation för spänningsreglering för det lokala elnätet. Rapportens syfte är att specificera en eller flera kontrollmetoder som möter både solcellsanläggningens och det lokala elnätets reglerbehov.Rapporten behandlar relevanta elektriska storheter, ger en kort introduktion till Sveriges elnät, elområden samt metoder för frekvens- och spänningsreglering. Solinstrålningens variation samt vanligt förekommande komponenter i en solcellsanläggning kartläggs och rapporten diskuterar även vilka effekter en hög andel solel kan ha på ett elnät.Utgångspunkt för rapporten är HSBs solcellsanläggning i Strängnäs samt Strängnäs lokalnät. Efter samtal med Strängnäs lokalnät konstateras att elnätet inte är i behov av ökad reglerkapacitet för spänningsreglering, dock visar insamlat data att det finns ett reglerbehov för kapacitiv reaktiv effekt. Enligt insamlat data över HSBs solcellsanläggning konstateras att så även är fallet för solcellsanläggningen.Det är därmed fördelaktigt för både HSBs solcellsanläggning och Strängnäs lokalnät med reaktiv effektkompensation med induktiv reaktiv effekt. Eftersom solcellsanläggningen inte behöver ta hänsyn till lokalnätets spänning kan anläggningen välja att styra genereringen av reaktiv effekt med kontrollmetoderna Konstant Q, Konstant Cosφ, Cosφ(P) samt Q(P). Här har kontrollmetoderna Cosφ(P) samt Q(P) fördelen att genereringen av reaktiv effekt baseras på solcellsanläggningens produktion av aktiv effekt och kan därmed implementeras utan risk för att strypa produktionen av aktiv effekt.

reactive power

reactive power compensation

solar PV farm

inverter

reaktiv effekt

reaktiv effektkompensation

solel

solcellsanläggning

växelriktarbaserade kontrollmetoder

Energy Engineering

Energiteknik

Power quality improvements in 25kV 50 Hz railway substation based on chopper controlled impedances / Amélioration de la qualité de l'energie electrique dans les sous stations ferroviaires 25kV 50Hz en utilisant des Impedances Controlees par Gradateur MLI

Raimondo, Giuliano

02 February 2012

Ce travail est le résultat d'une collaboration entre le laboratoire LAPLACE, la "Seconda Università degli Studi di Napoli" (SUN) et la Société National des Chemins de fer Français SNCF. Le sujet de recherche concerne l'utilisation de dispositifs électroniques de puissance dans les sous stations ferroviaires 25kV/50Hz afin d’améliorer la qualité de l'énergie électrique. Dans le transport ferroviaire, le système d'électrification monophasé 25kV/50Hz est largement diffusé en particulier pour les lignes ferroviaires à grande vitesse. Bien qu'aujourd'hui les systèmes d’alimentation en courant continu soient encore largement utilisés, l'adoption du courant alternatif monophasé offre des avantages économiques pour les infrastructures d'environ 30% en termes d'investissement, d'exploitation et d'entretien. Initialement, compte tenu de la simplicité du circuit, il n'y avait aucune nécessité d'intégrer de l'électronique de puissance dans les sous stations. Toutefois, au cours de la décennie passée, l'intérêt pour ces équipements est apparu car ils peuvent apporter une solution d'optimisation du réseau lorsque le trafic augmente ou lorsqu’une nouvelle sous station est envisagée. Deux principaux types de dispositifs sont installés aujourd'hui sur le réseau ferré français : les compensateurs de puissance réactive et les compensateurs de déséquilibre de tension. Cette thèse présente de nouvelles topologies de compensateurs basées sur le concept d’impédances contrôlées par gradateur MLI. Comparées aux solutions existantes, ces topologies ont des caractéristiques particulièrement intéressantes en termes de pertes dans les semi-conducteurs et de volume des composants réactifs. Le manuscrit contient trois parties principales: La première partie présente le principe de l’électrification en 25kV/50Hz et souligne l’intérêt d’installer des moyens de compensation statique dans les sous stations. Après une description des solutions actuellement utilisées, le concept d’impédance contrôlée par gradateur MLI (CCI : Chopper Controlled Impedance ) est ensuite présenté. La deuxième partie du travail concerne l'utilisation du concept de CCI pour la compensation de puissance réactive. La sous-station SNCF de Revest est considérée comme cas d’étude. Celle-ci est équipée d'un transformateur monophasé de 60MVA dont le primaire est connecté à une ligne de transport 225kV. Deux topologies de compensateur de puissance réactive, basées sur des montages abaisseur ou élévateur de tension sont présentées. Le dimensionnement des gradateurs est effectué sur la base d'une campagne de mesures réalisée à la sous station. Des simulations numériques utilisant des formes d’ondes réelles de courant et de tension sont présentées. Des résultats expérimentaux effectués à la plateforme de test de la SNCF sur un prototype de 1,2MVAR permettent de valider le concept de CCI. La dernière partie du travail concerne le problème du déséquilibre de tension en amont de la sous station. Un circuit de Steinmetz « actif », toujours basée sur des gradateurs MLI, est présenté et étudié. La sous station SNCF d'Evron est alors considérée comme cas étude. Celle-ci comporte un transformateur de 32MVA et est connectée à une ligne de transmission 90kV. Les mesures effectuées sur le site permettent le dimensionnement du compensateur ainsi que l’utilisation des formes d'onde réelles de courant et de tension dans les simulations numériques. Une comparaison avec des solutions classiques basées sur des onduleurs 2 niveaux et 3 niveaux souligne les avantages de la solution proposée. Ainsi, les résultats des calculs et des simulations montrent que l'énergie stockée dans les éléments réactifs est réduite d’un facteur six et que les pertes dans les semi-conducteurs sont réduites de 40%. Des résultats expérimentaux obtenus sur une maquette de 1.5 kVA permettent de valider le principe du circuit de Steinmetz actif. / This work is the result of collaboration between the LAPLACE laboratory, the “Seconda Università degli Studi di Napoli” (SUN) and the French national railways operator SNCF. The research topic treated herein concerns the use of power electronic devices in 25kV/50Hz railways substations to achieve power quality improvements. In railway transportation, single-phase 25kV-50Hz electrification system is widely diffused especially for high-speed railway applications. Although electrified DC systems are still widely applied, the adoption of AC single-phase system offers economical advantages for the infrastructures of about 30% in terms of investment, exploitation and maintenance. In early ages, due to its very simple diagram, there was no necessity to integrate power electronics in substations. However, for the last decade, the interest in power electronic equipments raised since they can provide the solution for network optimization when traffic increases or when a difficulty is foreseen for a substation implementation. Two types of devices are implemented today on the French Railway Network: Reactive Power compensators and Voltage Unbalance compensators. This thesis presents an investigation into new topologies based on the concept of “Chopper Controlled Impedances”(CCI). Compared to existing solutions, the new topologies show interesting features in terms of semi-conductor losses reduction and volume of reactive components. The manuscript is developed through three main parts: Firstly, the French railways system is introduced and the interest in installing power electronic compensators in substations is highlighted. After a brief description of currently used solutions, the CCI concept is presented: the use of Pulse Width Modulated AC Choppers allows achieving structures which behave as variable impedances. In the second part, the use of CCI structures in reactive power compensation is investigated. The SNCF substation of Revest is under study. It is equipped by a 60MVA single phase transformer with the primary side connected to a 225kV transmission line. Based on the step-down or step-up functioning mode of CCIs, two topologies of reactive power compensator are presented. The converter design is developed on the base of a measurement campaign carried out at the substation. Numerical simulations using real current and voltage waveforms are presented. Finally, experimental results carried out at the SNCF test platform on a 1.2MVAR prototype are shown. In the last part, the problem of voltage unbalance is treated. Using the concept of CCI, the feasibility of an active Steinmetz circuit based on AC choppers is explored. As a case study, the substation of Evron is considered. It is a 32MVA substation connected to a 90kV transmission line. Measurements carried out on the substation site allow the compensator design and the possibility to consider real waveforms for current and voltage in numerical simulations. A comparison with classical solution based on two levels VSI and three levels NPC-VSI highlights the advantages of the proposed solution. Calculation and simulation results show that the stored energy in reactive elements is reduced by a factor six whereas the semiconductor losses are 40% lower. Experimental results obtained on a scaled demonstrator (1.5 kVA) validate the principle of the active Steinmetz circuit.

Gradateur MLI

Impédance Contrôlée

Déséquilibre de tension

Circuit de Steinmetz « Actif »

Reactive Power compensation

Active Steinmetz Circuit

Voltage Unbalance Compensation

Power Quality

Railway Transportation

Voltage Source Converters with Energy Storage Capability

Xie, Hailian

January 2006

<p>This project deals with voltage source converters with energy storage capability. The main objective is to study the possible benefits of energy storage to a power system with a VSC as the interface between them.</p><p>First of all, a converter control system is proposed for a two level VSC. In the conventional converter control, the control system usually takes the voltage measured at the point where the converter is connected and calculates the reference voltage for the converter; with a modulation system the converter then produces the required 'average voltage'. In this project, a novel flux modulation scheme, combined with the deadbeat current control strategy, is proposed. The current controller is capable of controlling both positive and negative sequence current components. With flux modulation, the control system measures the bus flux and commands the converter to generate the required flux.</p><p>Based on the proposed control strategies, several application studies have been carried out.</p><p>The first application study investigates the effect of energy storage on the power quality at the point of common coupling when a system is subject to load disturbances. The voltage at PCC in a weak network is very sensitive to load changes. A sudden change in active load will cause both a phase jump and a magnitude fluctuation in the bus voltage, whereas reactive load changes mainly affect the voltage magnitude. With the addition of energy storage to a StatCom, it is possible to compensate for the active power change as well as providing reactive power support. In this thesis, some effective active power compensation schemes are proposed. Simulations and experiments have been performed to verify the compensation schemes. The results show that a StatCom with energy storage can significantly reduce phase jumps and magnitude deviations of the bus voltage.</p><p>pact of the energy storage on the performance of weak systems under fault conditions has been investigated. The investigation was done by studying an example system. The system model was established based on a real system, in which some induction motors driving pumps along a pipeline are fed from a radial transmission line. Studies show that for a weak system with induction motor loads, a StatCom with certain energy storage capacity will effectively improve the system recovery after faults. Although this incurs extra cost for the increasing dc voltage rating and size of the dc side capacitor, the overall rating of the converter can be reduced by utilization of the proposed active power compensation scheme.</p><p>The last case study investigates the possible use of a StatCom with energy storage to improve the power quality at the point of common coupling where a cyclic load is connected. Studies show that by providing both fast reactive and fast active power support to the network, not only the voltage magnitude can be well controlled, but also the voltage phase jump can be reduced significantly.</p>

Voltage source converter

StatCom

Energy storage

Active power compensation

Phase jump

Voltage dip

VSC

Weak network

Flux modulation

deadbeat control

Electric power engineering

Elkraftteknik

Elkvalitet i industrinät : Snabba spänningsvariationerns påverkan på elektrisk utrustning / Power quality in industrial networks : Voltage fluctuations effect on electrical equipment

Sköld, Joakim

January 2021

Elkvalitet beror på flera olika faktorer, exempelvis kortvarig spänningshöjning, kortvarig spänningssänkning, snabba spänningsvariationer (flimmer), spänningssprång, transienter, övertoner eller spänningsosymmetri. Den vanligaste åtgärden för att förbättra elkvaliteten i ett industrinät med ljusbågsugn och höga nivåer av snabba spänningsvariationer är att använda sig av reaktiv effektkompensering.  Denna studie undersöker snabba spänningsvariationers eventuella påverkan på elektrisk utrustning, både gällande användning och livslängd. Vidare undersöks även elkvaliteten i Sandviks industrinät där elektrisk utrustning upplevs ha blivit defekt tidigt under dess livslängd. Detta för att finna åtgärder som kan förbättra elkvaliteten för industrinätet, där en ljusbågsugn används i produktionen. I studien har mätdata gällande elkvalitet från Sandvik jämförts med mätdata från andra industrier vilket sedan analyserat utifrån gällande elkvalitetsnormer. Data om vilken typ av utrustning som kan ha påverkats och information om hur elnätsföretag upplever industriers påverkan på elkvalitet har samlats in genom intervjuer med personal på Sandvik och Vattenfall. Även tidigare forskning behandlas i denna studie. Resultatet visar att Sandviks elkvalitet påverkas av när ljusbågsugnen körs. Flimmernivån är den elkvalitetsstörning som återkommande överstiger normen vid anslutningspunkten av utrustning som tidigt blivit defekt. Tidigare forskning visar att användandet av utrustning kan påverkas av snabba spänningsvariationer till exempel i form av mindre hastighetsförändringar i motorer. I jämförelsen mellan Sandvik och de andra industriernas mätdata framkommer bland annat att höga flimmernivåer är vanligt förekommande i industrinät med ljusbågsugn. För att åtgärda Sandviks flimmernivåer och förbättra deras elkvalitet kan en reaktiv effektkompensering i form av en STATCOM installeras. Det finns inte forskning i tillräcklig stor grad för att kunna dra säkra slutsatser gällande hur snabba spänningsvariationer påverkar elektrisk utrustnings livslängd. Det finns dock forskning som indikerar att så är fallet. Denna studies insamlade data leder inte heller till några säkra slutsatser gällande detta men tydliggör att nuvarande testprocedurer om utrustnings immunitet mot snabba spänningsvariationer inte går att jämföra med de verkliga förhållandena i ett industrinät. Slutsatsen är även att fler studier i ämnet krävs. / Power quality depends on several different factors, such as voltage sags, voltage dips, voltage fluctuation (flicker), rapid voltage changes, transients, harmonics or voltage asymmetry. To improve the power quality in an industrial network one common mitigation is reactive power compensation.     This study examines the possible effects of voltage fluctuations on electronic equipment, both in terms of use and service life. Furthermore, Sandvik's power quality in their industrial network is also examined, where electronic equipment is perceived to have become defective early in its service life. To improve the power quality the goal is to find suitable mitigation for the arc furnace in the industrial network. In this study, the power quality at Sandvik was compared with the power quality from similar industries and analyzed based on current power quality standards. Through interviews with staff at Sandvik and Vattenfall data was provided regarding which type of equipment that may have been affected and information on how electricity network companies experience the impact from industries on power quality. Previous research is also covered in this study. The result shows that the power quality at Sandvik is affected when the arc furnace is active. The flicker level is the power quality disturbance that repeatedly exceeds the norm at the connection point of equipment that has become defective at an early stage. Previous research shows that the use of equipment can be affected by voltage fluctuations, for example in the form of minor speed changes in motors. The comparison between Sandvik and the similar industries reveals that industrials networks with an arc furnace often is affected by high flicker levels. By installing a reactive power compensator, in form of a STATCOM, the high flicker level of Sandvik’s industrial network can be mitigated. There is not enough research to be able to draw definite conclusions if voltage fluctuation affects the lifespan of electronic equipment. However, there is research that indicates that this is the case. The data collected in this study also do not lead to any definite conclusions regarding this but clarifies that current test procedures on equipment immunity to voltage fluctuations cannot be compared with the actual conditions in an industrial network. The conclusion is also that more studies on the subject are required.

Power quality

voltage fluctuation

flicker

reactive power compensation

industrial network

Elkvalitet

snabba spänningsvariationer

flimmer

reaktiv effektkompensering

industrinät

Annan elektroteknik och elektronik