
Direct method for transient stability assessment of a single wind turbine generator subject to LVRT requirements
Author(s) -
Sohn Alexandre Prodóssimo,
Abrantes Adriano Lima,
Alberto Luís Fernando Costa
Publication year - 2020
Publication title -
iet generation, transmission and distribution
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.92
H-Index - 110
eISSN - 1751-8695
pISSN - 1751-8687
DOI - 10.1049/iet-gtd.2020.1313
Subject(s) - transient (computer programming) , turbine , wind power , control theory (sociology) , rotor (electric) , generator (circuit theory) , limit (mathematics) , boundary (topology) , electric power system , stability (learning theory) , induction generator , variable speed wind turbine , computer science , engineering , voltage , permanent magnet synchronous generator , power (physics) , mathematics , control (management) , aerospace engineering , electrical engineering , physics , mathematical analysis , quantum mechanics , artificial intelligence , machine learning , operating system
The authors report on a step towards the development of direct methods for transient stability assessment of power systems with integrated wind turbine generators subject to low voltage ride‐through constraints. In this study, they propose an approach to assess transient stability of a single wind turbine generator against an infinite bus using an energy function along with an extension of the potential energy boundary surface method. The proposed approach exploits the theory of constrained dynamical systems and the concept of constrained stability region to efficiently estimate critical clearing times taking into account not only the issue of stability due to rotor acceleration but also the issue of operational limit violations, such as low‐voltage ride‐through curve violations. Very often, wind turbine generators are disconnected due to violation of operational limits, such as under‐voltage limits, instead of rotor acceleration. The proposed approach correctly estimates the critical clearing times to avoid operational limit violations, such as the low‐voltage ride‐through constraint violation, while traditional direct methods would fail to appropriately estimate such clearing times. They illustrate the effectiveness of the proposed approach by means of case studies considering two types of wind turbine generators, the fixed‐ and limited‐variable‐speed wind turbine generators.