[en] MINIMUM SYNCHRONOUS INERTIA MONITORING AND CALCULATION SYSTEM FOR REAL-TIME DECISION MAKING / [pt] SISTEMA DE MONITORAÇÃO E CÁLCULO DE INÉRCIA MÍNIMA SINCRONIZADA PARA A TOMADA DE DECISÃO EM TEMPO REAL

RAPHAEL BOTTINO ARCOS

27 October 2022

[pt] Centros de operação ao redor do mundo têm verificado o aumento da complexidade ao longo dos anos, principalmente pela grande quantidade de novas informações que devem ser consideradas. No sistema elétrico brasileiro não é diferente, impactado pela participação cada vez mais ativa de fontes renováveis, como eólicas e fotovoltaicas, além de elos de corrente contínua. Seguindo uma tendência global, a consideração de valores de inércia sincronizada para a avaliação do desempenho da frequência e de fluxos sistêmicos se faz necessária, configurando-se como uma nova informação a ser exposta à operação em tempo real. Visando garantir mais segurança e confiabilidade ao ambiente de tempo real, o presente trabalho tem como objetivo traduzir os estudos realizados pela equipe de planejamento do ONS para a operação, através de um sistema capaz de monitorar parâmetros como a inércia sincronizada, reserva de potência operativa e outras informações associadas, ampliando a consciência situacional dos usuários. Além disso, o sistema deve promover simulações de contingências severas que possam provocar atuações de esquemas de corte de carga e indicar ações que possam ser realizadas para mitigar o problema. / [en] Operation centers around the world have verified an increase of the complexity throughout the years, mostly due to huge amounts of new information that must be considered. The Brazilian electric system is no different, impacted by the increasingly active participation of renewable sources, such as wind and photovoltaic, as well as direct current links. Following a global trend, the consideration of values of synchronous inertia for the evaluation of the performance of the frequency is necessary, configuring as a new information to be exposed to real-time operation. With the purpose of guaranteeing more safety and reliability to the real-time environment, this work has the goal of translating the studies carried out by the ONS planning team to the operation, through a system capable of monitoring parameters such as synchronous inertia, operating reserve and other associated informations, increasing users situational awareness. Besides that, the system must promote simulations of severe contingencies that may trigger load shedding schemes and indicate actions that can be taken to soften the problem.

[pt] RESERVA DE POTENCIA OPERATIVA

[pt] SIMULACAO DINAMICA DE CONTINGENCIAS

[pt] INERCIA SINCRONIZADA

[pt] OPERACAO EM TEMPO REAL

[pt] CONTROLE DE FREQUENCIA

[en] OPERATING POWER RESERVE

[en] DYNAMIC SIMULATION OF CONTINGENCIES

[en] REAL-TIME OPERATION

[en] FREQUENCY CONTROL

Frequency Stability of Power Electronic Based Power System with 100% Renewable Energy.

Albalali, Abdullah

January 2022

The modern power system is aiming to progress away from conventional synchronous machine  based power generation towards converter dominated system that leads to extensively high penetration of renewable energy such as wind and PV. This transition of modern power system toward converter based renewable energy comes with new challenges as the conventional synchronous generation is being replaced by converter based power system (CBPS). The converter is commonly interfaced to the power system with Phase Locked Loop (PLL) technique to synchronize the converter with the grid voltage angle and inject the current at the right angle. Therefore, this approach is called grid- ­following converter; this type of configuration of converters may lead to some power system instabilities (e.g., voltage instability, frequency instability, synchronous and sub­synchronous instabilities). In order to overcome the limitation of the grid-­following converters, another converter control concept become present in the literature as a grid-­forming converter where the synchronizing method to the grid eliminates the need for PLL .In this thesis, a grid- ­forming controlled power converter is implemented with an energy storage system to emulate the inertia of the synchronous generator through the VSM control concept. An electromagnetic transient (EMT) simulation has been modeled in the PSCAD simulation environment. The model is the well­known four-­machine two-­area power system. The model has been tested by incrementally replacing the synchronous machines with wind farms connected through power converters; this weakens the grid and may lead to frequency instability during a disturbing event. An Energy Storage System (ESS) has been implemented and added to the system to mitigate the loss of the kinetic energy of the rotating masses of the synchronous generators. The ESS is integrated with a grid-­forming converter that is controlled to mimic the dynamic behavior of a synchronous generator. Thus, the ESS is synchronized to the system based on the swing equation of the synchronous generator. The results show significant improvements in the frequency stability of the system under study. / Det moderna energisystemet har som mål att bortgå från den konventionella synkronmaskinbaserade energiförsörjning mot ett konverteringsdominerat system som leder till  en mycket hög penetration av förnybar energi, som tillexempel vind och solenergi. Den här övergången av modernt energisystem mot konverteringsbaserad förnybar energi medför nya utmaningar i och med att konventionell synkrongenerering byts ut mot konverterarbaserat energisystem (Converter Based Power System, CBPS) . Konverteraren är ofta integrerad i energisystemet via Phase Locked Loop ­teknik (PLL) för att synkronisera konverteraren med kraftnätets spänningsvinkel och injicera strömmen i rätt vinkel. Det här tillvägagångssättet kallas därför för nätföljande konvertering; denna typ av konfiguration av konverterare kan leda till instabilitet i energisystemet (t.ex. instabil elektrisk spänning, frekvensinstabilitet, synkron och sub- ­synkron instabilitet). För att hantera begränsningarna som nätföljande konverterare träder ett koncept om ytterligare en konverteringskontroll fram i litteratur, i form av en nätformande konverterare där synkroniseringsmetoden i nätet eliminerar behovet av PLL.I denna avhandling implementeras en nätformande konverterare med ett energiförvaringssystem för att emulera trögheten i synkrongeneratorn genom VSM-­styrkonceptet. En elektromagnetisk transientsimulering (EMT) har modellerats i simuleringsmiljön PSCAD. Modellen är det välkända energisystemet med fyra maskiner och två områden. Modellen har testats genom att stegvis byta ut synkronmaskinerna med vindkraftverk anslutna genom energikonverterare; detta gör nätet svagare och kan leda till frekvensinstabilitet vid en störande händelse. Ett energiförvaringssystem (Energy Storage System, ESS) har implementerats och kopplats till systemet för att mildra förlusten av kinetisk energi i de roterande massorna hos synkrongeneratorerna. Energiförvaringssystemet ESS är integrerat med en nätformande konverterare som styrs för att härma det dynamiska uppförandet av en synkrongenerator. Således är ESS synkroniserat med systemet baserat påsynkrongeneratorns svängekvation. Resultaten visar betydelsefulla förbättringar av frekvensstabiliteten i systemet under studien.

energy storage

frequency control

synchronous generators

distributed power generation

virtual synchronous machine (VSM)

PSCAD.

energilagringssystem

frekvenskontroll

synkrona generatorer

distribuerad kraftproduktion

virtuell synkron maskin

PSCAD.

Elektroteknik och elektronik

Anpassning av småskaliga vattenkraftverk för ö-drift av lokalt elnät / Adapting small hydropower plants for frequency control of power grids in island mode

Fredriksson, Jonatan

January 2019

This master thesis examines technical requirements for small hydro power plants (HPP) to operate proximate parts of the power grid in island mode. The work examines how small hydropower can be modified and complemented with additional technologies to achieve sufficient frequency control capabilities. A case study was performed within the concession area of power grid operator Ålem Energy. One of the HPPs, located in Skälleryd, is owned by Ålem Energy and became the focal point of the study. Relevant parts of the concession area were surveyed for properties such as system inertia, electric load and available power. Furthermore, a model of Kaplan turbine 1 in Skälleryd HPP was created with the purpose of studying the benefits of bypassing regulation control from the wicket gates directly to the runner. The method was tested in an off-grid islanding test. Frequency control of the turbine was tested powering electric heaters and, using a new method, controlling a virtual power grid. Finally, a theory was developed to estimate the transient disturbance resilience (TDR) of a power grid. The theory was applied to the HPP in Skälleryd to suggest modifications for the plant to achieve sufficient islanding capabilities. The survey of the power system revealed a promising potential for the HPPs to operate in island mode, especially at later stages when the grid spans several HPPs for more system inertia. The available power from the HPPs was however strongly seasonal which imposes flexibility on a future plan of action for engaging the grid in island mode. The method of controlling the turbine power from the runner proved to have several difficulties. Firstly, the current hydraulics system was not able to freely control the runner as the hydrodynamic forces on the runner blades were too large. Secondly, the method was found to be unstable due to inherent amplification of speed deviations. Furthermore, the low inertia at Skälleryd is likely detrimental to the lone frequency control of the turbine. Therefore other methods for improving frequency control were suggested. The developed theory for TDR was used to create charts describing the TDR for various combinations of system inertia and regulation speed. By studying the proprieties of Skälleryd HPP in the charts the necessary modifications could be rationally chosen. A frequency regulating dummy load was found to be the simplest option. A control scheme was suggested with the dummy load performing primary frequency control and the turbines at Skälleryd performing secondary control, restoring the dummy load to its nominal state.

small hydropower

hydropower

Kaplan

turbine

transient

disturbance

resilliance

power grid

island

islanding

adapting

island mode

frequency control

dummy load

Kaplan

Kaplanturbin

elnät

ö-nät

ö-drift

vattenkraft

småskaliga vattenkraftverk

transient störningstålighet

indexprov

kombineringsprov

lokalt elnät

Energy Systems

Energisystem

Energy Engineering

Energiteknik

Wind Power

Makhalas, Kharsan Al, Alsehlli, Faisal

January 2015

This Bachelor thesis has been written at the Blekinge Institute of Technology. This thesis concentrates on the wind power and their components, also the large wind farm is studied. The electrical power is generated by using the power in wind to drive a wind turbine to produce mechanical power. This mechanical power can be converted into electrical power by using electrical induction generators. There are two types of the wind turbines, the horizontal axis and vertical axis wind turbine, where the horizontal axis wind turbine is mostly used and was studied in this thesis. The rotor can be placed in two directions: an upwind rotor where the blade of turbine faces to the wind, so it operates more smoothly and transmit more power. The other type is a downwind rotor which orients itself with respect for the wind direction. Moreover, the tower shadow makes the blade to flex, consequently resulting in fatigue, noise, and reduces output of the power. The modern wind turbine has been built with an odd number of blades which is important for the stability of the turbine. The rotor with an odd number of blades can be considered to be similar to a disc when calculating the dynamic properties of the machine. The main idea of this thesis is to study the wind power in general and large wind parks specifically. The Horns Rev wind park was taken as an example of a wind park in Denmark and the Gotland wind park as an example of a wind park in Sweden too. Into account, the distance between wind turbine in the wind direction cannot be too small. If the wind turbines are located to close to each other, the wind will be more and more turbulent after it passes through each single wind turbine. This would lead to that wind turbines downstream in the wind park, and it might even have to shut down due to that mechanical loading gets to high during strong conditions. This is due to the fact that when wind passes through the rotor of the wind turbine it gets very turbulent and the wind speed is decreased. The minimum length of the rotor should be approximately 5-7 rotor diameters to avoid that issue. Gotland Energy AB (GEAB) considered, that high voltage direct current light would be the only realistic way to solve the technical problems for the high amount of wind power in-feed. One result is that The stability of voltage during transient events, has become much better by using the high voltage direct current light so that the output current stability from the asynchronous generators have been improved, which reduces the stresses on the AC grid and on the mechanical construction of the windmills. / In general the wind turbines with three blades accommodated a thicker root are used. It is obvious that, the less number of blades on the wind turbine, the cost of material and manufacturing will be lower. It is worthy to mentioned that, the modern wind turbine has been built with an odd number of blades. When the length of the blade increases the deflection of blade tip due to axial wind force also increase as well. So without consider the increase in length of blade may lead to dangerous situation of collision of tower and blade. Moreover, by increasing the number of blades cost of the system would increased as well. The limit of transfer for the AC transmission system depends on the distance from shore and is therefore physically limited by this. AC large wind parks that are placed at a long distance from the shore, which means AC long transmission line, and more drop voltage A solution to AC long transmission line, it could be to decrease the offshore frequency and use a low frequency AC networks. There is a suggestion by for instance (Schütte, Gustavsson and Ström 2011). The usages of a low frequency system are in electrified railway systems, where the frequency ranges from 16.67 Hz to 25 Hz. However, the network of a low frequency would allow a simpler design of the offshore WTs and The aerodynamic rotor of a large WT operates at maximum revolutions at 15-20 rpm. The lower frequency would then allow a smaller gear ratio for turbines with a gearbox, or decrease the poles number for WTs with direct driven generators. This would lead to lighter and cheaper turbines. One of the disadvantages by using a low frequency system is the size of transformer would be increased, and hence, the costs of transformer will increased too. The operator of the grid, Gotland Energy AB (GEAB) considered, that HVDC light would be the only realistic way to solve the technical problems for the high amount of wind power in-feed. The experiences have supported expected improvements in the characteristics for example: - Stability in the system arose. - Reactive demands, power flows, as well as voltage level in the harmonic and system were reduced. - Flicker problems were eliminated with the installation of HVDC light and transient phenomena disappeared. Moreover, Overall experiences of Gotland Energy AB (GEAB) are that the control of power flow from the converters makes the AC grid easier to observe than a conventional AC network and the power variations do not stress the AC grid as much as in normal network. Voltage quality has been better with the increased wind power production. A topic to study in the future is the consequences of blackouts in power supply with many wind power farm. / 004676396018

wind energy

history of wind energy

types of wind energy

statisticas

wind power development in sweden

wind turbines generators

ac synchronous generators

electric power transmission

transmission lines

ac wind park

frequency control

Horns Rev wind park

Gotland wind park

Social Sciences Interdisciplinary

Mechanical Engineering

Maskinteknik

Elektroteknik och elektronik