5 Results for the search "Power Electronics":
HVDC models
Description:
These models contain a 3-phase rectifier (AC/DC) and a 3-phase inverter (DC/AC).
The average model (AM) just contains a control circuit that is connected to several controlled sources.
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The detailled model (DML) contains complete inverter and rectifier models and represents the semi-conductors.
Tag(s): Power electronics, inverter, rectifier, average, detailled
Electrical Vehicle charger
Description:
These example provide model of EV chargers and documentation
Tag(s): EV, charger, charging, station, power electronics
Pwm_inv_3ph
Description:
This case shows a three-phase full-bridge DC/AC inverter with PWM switching.
Reference: Power Electronics, Mohan, Undeland, Robbins - Ed Wiley - Chapter 8.
Tag(s): Power Electronics
SVC_Simple
Description:
This is a simple SVC model with a TCR branch and fixed capacitors.
This case is taken from the book of T.E. Miller entitled 'Reactive Power Control in Electric System.
Tag(s): Power Electronics
TCR1
Description:
Example of single phase Thyristor Controlled reactor using TACS control devices. This circuit reproduces the TCR case presented in the EMTP Workbook volume 4 chapter 6.
Example of single ph... see morease Thyristor Controlled reactor using TACS control devices. This circuit reproduces the TCR case presented in the EMTP Workbook volume 4 chapter 6.
The basic static Var system consists of a static switch in series with an inductor. This is normally called a phase controlled reactor, or Thyristor Controlled Reactor (TCR). The TCR is in parallel with a fixed capacitor. Together they interface with the power system at some interconnection point. The control circuit of the TCR can be divided into three parts. There is the gate pulse generator (GPG), the heart of the control system, a voltage regulator and an interface to the power systems which could be simply a RMS voltage meter.
The purpose of the gate pulse generator is to provide firing pulses to the thyristors. The regulator calculates the conduction angle, ?, which is passed to the gate pulse generator as a control signal. It is the function of the gate pulse generator to generate the correct firing pulses to achieve the requested conduction angle, ?. In this example the gate pulse generator is modeled using TACS control devices.
Tag(s): Power Electronics