Controlled Brushless De-Excitation Structure for Synchronous Generators

Abstract: The main weakness of the brushless excitation system in a synchronous generator (SG) is the slow de-excitation response obtained during a load rejection. That is why voltage overshoots may be observed on the generator terminals. This behavior is mainly due to the exciter machine response time and the rotating diode bridge which is not able to quickly de-excite the generator by negative excitation voltages. This paper presents a new brushless de-excitation structure able to perform a quick de-excitation of the … Show more

“…Moreover, this system becomes unusable when the exciter is a permanent magnet machine or a hybrid winding‐magnet excitation machine. In 2018, Barakat [11] and Chouaba [12] took up the HSBDS with a non‐linear discharge resistor and external control from an auxiliary control loop. The combination of the main (positive) and auxiliary (negative) control loops allow the resulting system to improve the voltage regulation, in addition to de‐exciting the main generator.…”

A novel brushless de‐excitation system for synchronous generators using a buck chopper with a freewheeling discharge resistor

“…Moreover, this system becomes unusable when the exciter is a permanent magnet machine or a hybrid winding‐magnet excitation machine. In 2018, Barakat [11] and Chouaba [12] took up the HSBDS with a non‐linear discharge resistor and external control from an auxiliary control loop. The combination of the main (positive) and auxiliary (negative) control loops allow the resulting system to improve the voltage regulation, in addition to de‐exciting the main generator.…”

A novel brushless de‐excitation system for synchronous generators using a buck chopper with a freewheeling discharge resistor