AAU Student Projects - visit Aalborg University's student projects portal
A master's thesis from Aalborg University
Book cover


Impact of Wind Turbines on Power System Stability

Author

Term

4. term

Education

Energy Engineering, Master

Publication year

2019

Submitted on

Abstract

Dette speciale undersøger, om transmissionssystemet i Østdanmark kan understøtte 100% vindenergi, med særlig vægt på spændingsstabilitet og systemgrænser. For at besvare dette udvikles en iterativ, brugervenlig algoritme, der gennemfører omfattende laststrømsberegninger på tværs af et bredt spænd af belastninger for at identificere nettes svageste områder, vurdere spændingsstabilitet og afprøve forskellige scenarier for vindintegration. Algoritmen testes og valideres først på det velkendte IEEE 9-knudesystem og anvendes derefter på en model af Østdanmarks transmissionsnet. Arbejdet omfatter en introduktion til vindmølletyper og begrunder valget af dobbeltfødet asynkrongenerator (DFIG) som referenceteknologi samt inddrager krav til reaktiv effekt i den danske netkode for at gøre analysen realistisk. Samlet set giver studiet et systematisk grundlag for at finde kritiske områder og mulige implementeringsveje mod høj vindandel; specifikke kvantitative resultater fremgår ikke af det medtagne uddrag.

This thesis investigates whether the Eastern Denmark transmission system can accommodate 100% wind energy, with a focus on voltage stability and system operating limits. To address this question, an iterative, user‑friendly algorithm is developed to run extensive load flow studies across a wide range of demand levels, identify the grid’s weakest areas, assess voltage stability, and explore scenarios for wind power integration. The algorithm is first tested and validated on the benchmark IEEE 9‑bus system and then applied to a model of the Eastern Danish grid. The study introduces wind turbine concepts and motivates the choice of the doubly‑fed induction generator (DFIG) as the reference technology, while incorporating Danish grid code requirements for reactive power to enhance realism. Overall, the work provides a systematic basis for locating critical network areas and outlining feasible implementation pathways toward high wind penetration; detailed quantitative results are not included in the provided excerpt.

[This summary has been generated with the help of AI directly from the project (PDF)]

Documents

Download
View record in AAU Student Projects