Line Impedance Estimation Based on Synchrophasor Measurements for Power Distribution Systems

Effective monitoring and management applications on modern distribution networks (DNs) require a sound network model and the knowledge of line parameters. Network line impedances are used, among other things, for state estimation and protection relay setting. Phasor measurement units (PMUs) give synchronized voltage and current phasor measurements, referred to a common time reference (coordinated universal time). All synchrophasor measurements can thus be temporally aligned and coordinated across the network. This feature, along with high accuracy and reporting rates, could make PMUs useful for the evaluation of network parameters. However, instrument transformer behavior strongly affects the parameter estimation accuracy. In this paper, a new PMU-based iterative line parameter estimation algorithm for DNs, which includes in the estimation model systematic measurement errors, is presented. This method exploits the simultaneous measurements given by PMUs on different nodes and branches of the network. A complete analysis of uncertainty sources is also performed, allowing the evaluation of estimation uncertainty. Issues related to operating conditions, topology, and measurement uncertainty are thoroughly discussed and referenced to a realistic model of a DN to show how a full network estimator is possible

Viiveiden vaikutus sähkömekaanisten heilahtelujen laajan alueen vaimennussäätöön

In this thesis the effects of delays on the wide-area damping control of electromechanical oscillations were studied. The research goals were two fold: to identify and define the delay sources in phasor measurement based (PMU) wide-area measurement systems for power systems, and to study the effects of delays on wide-area damping control using power system simulations as a research tool. The implementation the delays into a pre-existing power system simulation program as also a part of this work. The thesis shows and identifies the delays components and their properties in the wide-area measurement systems. It gives a survey on the reports of real delays observed in wide-area measurement systems worldwide. The simulation results show that delay has an impact on the damping control. Power system have a delay margin they are able to tolerate before turning unstable. Additionally, latency changes the properties of the electromechanical oscillations.Tässä diplomityössä tutkittiin viiveiden vaikutusta sähkömekaanisten heilahtelujen vaimennussäätöön. Työ oli karkeasti jaettavissa kahteen erilliseen osaan. Ensimmäinen osa oli voimajärjestelmien PMU-pohjaisten laajan alueen mittaus- ja ohjausjärjestelmien viivelähteiden löytäminen, tunnistaminen ja luokittelu. Toinen osa oli viiveiden vaikutusten tutkiminen laajan alueen heilahtelusäätöön käyttäen voimajärjestelmäsimulointia tutkimuksen työkaluna. Työn toteutus sisälsi viiveellistenmittauksien ja ohjauksien toteuttamisen valmiina olevaan simulaatio-ohjelmaan. Työ näyttää laajan alueen mittaus- ja ohjausjärjestelmien viivekomponentittien ominaisuudet ja vaikutuksen viiveketjuun sekä millaisia lukemia on raportoitu käytössä olevista järjestelmistä ympäri maailman. Työn viivesimulaatiot osoittavat, että viiveillä on merkitys sähkömekaanisten heilahtelujen vaimennussäätöön. Viiveellinen säätö muuttaa sähkömekaanisten heilahtelujen ominaisuuksia ja osoittaa, että voimajärjestelmillä on niille ominainen viiveen sietokyky

Online System for Power Quality Operational Data Management in Frequency Monitoring Using Python and Grafana

This article proposes a measurement solution designed to monitor the instantaneous frequency in power systems. It uses a data acquisition module and a GPS receiver for time stamping and traceability. A Python-based module receives data, computes the frequency, and finally transfers the measurement results to a database. The frequency is calculated with two different methods, which are compared in the article. The stored data is visualized using the Grafana platform, thus demonstrating its potential for comparing scientific data. The system as a whole constitutes an efficient, low-cost solution as a data acquisition system.This research is funded by the Spanish Ministry of Science and Education through the project PID2019-108953RB-C21; has been co-financed by the European Union under the 2014-2020 ERDF Operational Program. Additionally, funding for frequency monitoring comes from the Andalusian-FEDER project FEDER-UCA18-108516 (Intelligent Techniques for visualization and data compression of PQ data in the smart grid)