Fault current injection from Inverter Based Generation in the distribution grid : A case study of distribution grid on the Swedish island of Gotland

Mansori, Farsad

January 2022

This work proposes recommendations for new guidelines for fault current injection on a distribution grid. These guidelines will help improve the transition towards renewable electrical energy generation. The grid-integration of inverter-based distributed generations (IBDGs) into the distribution grid changes the topology of a conventional grid with one-way power flow to a grid with multi-way power flow. This thesis investigates the impact of fault current injection on a distribution grid, if the limitations in the fault current injection of IBDGs affect the reliable function of the protection system and if there is a preferable type of current control to be prioritised. This investigation was carried out through a literature review and transient state simulations on a model grid in PSCAD. The grid is based on a real radial distribution grid on the Swedish island of Gotland, where a Type III wind turbine generator (WTG) is connected. The limitation on fault current injection by the wind turbine, the location and type of fault in the grid, can affect the reliable function of the protection system. The control system inside a type III WTG affects its fault current injection that impacts fault detection by the protection system. This thesis emphasizes the need for a guideline and requirement on the WTG control system for fault current injection. Prioritising reactive current control (q-axis) seems to be preferable and should become the standard for fault current injection in type III wind turbine generators in this distribution grid, according to this study. Furthermore, the need for more investigation for different types of IBDGs with different control strategies is highlighted in this work. / Detta arbete föreslår rekommendationer för nya riktlinjer för felströmsinjektering i ett distributionsnät. Dessa rekommendationer kommer bidra till att förbättra omställningen till förnyelsebar elgenerering. Integreringen av omriktarbaserade distributionsgeneratorer (IBDG) i distributionsnätet förändrar topologin i ett konventionellt nät med ett enkelriktat effektflöde till ett flervägsriktat effektflöde. Detta examensarbete undersöker påverkan av felströmsinjektering i ett distributionsnät, om begränsningarna i felströmsinjekteringen hos IBDG:er påverkar reläskydds pålitliga funktionalitet och om det finns en typ av kontrollström som föredras och bör prioriteras. Denna undersökning genomfördes genom en litteraturstudie och transienta simuleringar i ett exempelnät i PSCAD. Nätet är baserat på ett verkligt radialdistributionsnät från Gotland, där ett Typ III vindkraftverk (WTG) är anslutet. Begränsningen i felströmsinjektering hos vindkraftverket, platsen för och typen av fel i nätet kan påverka den pålitliga funktionaliteten hos reläskydd. Kontrollsystemet inuti ett Typ III WTG påverkar dess felströmsinjektering som påverkar feldetekteringen i reläskyddet. Detta examensarbete betonar vikten av riktlinjer och krav på WTG kontollsystem för felströmsinjektering. Prioritering av reaktiv kontrollström (q-axis) verkar vara fördelaktigt och bör bli standard för felströminjektering i Typ III WTG i detta distributionsnät, enligt detta arbete. Dessutom påtalas behovet av att ytterligare undersöka olika typer av IBDG:er med olika kontrollstrategier i detta arbete.

Distribution generator

Inverter-Based Distributed Generation

Inverter Based Generation

DFIG

PSCAD

Distribution grid

Overcurrent protection

Elektroteknik och elektronik

Transient And Distributed Algorithms To Improve Islanding Detection Capability Of Inverter Based Distributed Generation

Al Hosani, Mohamed

01 January 2013

Recently, a lot of research work has been dedicated toward enhancing performance, reliability and integrity of distributed energy resources that are integrated into distribution networks. The problem of islanding detection and islanding prevention (i.e. anti-islanding) has stimulated a lot of research due to its role in severely compromising the safety of working personnel and resulting in equipment damages. Various Islanding Detection Methods (IDMs) have been developed within the last ten years in anticipation of the tremendous increase in the penetration of Distributed Generation (DG) in distribution system. This work proposes new IDMs that rely on transient and distributed behaviors to improve integrity and performance of DGs while maintaining multi-DG islanding detection capability. In this thesis, the following questions have been addressed: How to utilize the transient behavior arising from an islanding condition to improve detectability and robust performance of IDMs in a distributive manner? How to reduce the negative stability impact of the well-known Sandia Frequency Shift (SFS) IDM while maintaining its islanding detection capability? How to incorporate the perturbations provided by each of DGs in such a way that the negative interference of different IDMs is minimized without the need of any type of communication among the different DGs? It is shown that the proposed techniques are local, scalable and robust against different loading conditions and topology changes. Also, the proposed techniques can successfully distinguish an islanding condition from other disturbances that may occur in power system networks. This work improves the efficiency, reliability and safety of integrated DGs, which presents a necessary advance toward making electric power grids a smart grid.

Algorithms

amplitude estimation

distributed algorithm

distributed energy resources

distributed generation

dynamic estimator

inverter based distributed generation

islanding

islanding detection methods

non detection zone

non linear observer

over/under frequency protection

over/under voltage protection

point of common coupling

quality factor

sandia frequency shift

scheduled perturbation

stiffness

transient response

Electrical and Computer Engineering

Electrical and Electronics

Engineering