Open AccessPower System Stability Improvement through the Coordination of TCPS-based Damping Controller and Power System Stabilizer
Author(s) -
Muhammad Arif Sharafat Ali,
Khawaja Khalid Mehmood,
ChulHwan Kim
Publication year - 2017
Publication title -
advances in electrical and computer engineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.254
H-Index - 23
eISSN - 1844-7600
pISSN - 1582-7445
DOI - 10.4316/aece.2017.04004
Subject(s) - stabilizer (aeronautics) , control theory (sociology) , electric power system , power (physics) , damping torque , controller (irrigation) , stability (learning theory) , damp , computer science , control engineering , engineering , control (management) , physics , voltage , electrical engineering , mechanical engineering , agronomy , quantum mechanics , artificial intelligence , machine learning , biology , direct torque control , meteorology , induction motor
To guarantee the secure and reliable operations of power systems through the rapid damping of low-frequency electromechanical oscillations (LFEOs) is the ultimate objective of this study. This paper presents a coordination of a flexible AC transmission system (FACTS) device and power system stabilizer (PSS) to meet this objective, and deals with the design of a damping controller based on a thyristor-controlled phase shifter (TCPS) and a PSS. The proposed design is incorporated in the framework of a single-machine infinite-bus (SMIB) power system. The effectiveness of the proposed design in damping power system oscillations is explored through eigenvalue analysis, time-domain simulations and damping torque contribution. A comparative study on different control schemes, such as with an SMIB including a PSS and an SMIB including a TCPS-based damping controller is also carried out. The obtained results prove the superior performance of the proposed design in improving the stability of the given power system. All the digital simulations are performed using MATLAB/ SIMULINK