- #POWERGUI MATLAB SIMULINK HOW TO#
- #POWERGUI MATLAB SIMULINK GENERATOR#
- #POWERGUI MATLAB SIMULINK SERIES#
![powergui matlab simulink powergui matlab simulink](https://i.stack.imgur.com/CI6t0.png)
#POWERGUI MATLAB SIMULINK SERIES#
From that menu select R to convert the series RLC branch to a resistor branch as shown in the figure below, There will be a menu to select which combination of all the three components you want to place on your simulink window.
#POWERGUI MATLAB SIMULINK HOW TO#
Now the question here is, how to convert these branches to individual components? Double click on the first RLC branch and a parameters window will appear.R, L, and C so we will place three such Series RLC branch on the simulink window as shown in the figure below, In our case we need three components i.e. This branch can be converted to any of the three components or any combinations of the three components i.e.
![powergui matlab simulink powergui matlab simulink](https://es.mathworks.com/help/examples/sps_product/win64/power_active_filter_01.png)
The series RLC branch when placed is shown in the figure below,
![powergui matlab simulink powergui matlab simulink](https://i.ytimg.com/vi/L0HLoQSF1h8/maxresdefault.jpg)
Note that the Load flow Bus block displays the bus voltage magnitude and phase angle as block annotations. Press the 'Apply' button to apply the load flow solution to the model in order to start the simulation in steady-state. The Load flow parameters are defined in the Load Flow tab of the Synchronous and Asynchronous machine blocks, Three-Phase Source block, Three-Phase Dynamic Load block, and the Three-Phase RLC Load blocks. The five Load Flow Bus blocks are used to specify the bus base voltages and to specify the voltage at PV bus and the voltage and angle of the swing bus.
#POWERGUI MATLAB SIMULINK GENERATOR#
A 150 MW power plant using a 13.8 kV synchronous generator is connected at the 120 kV bus through a 13.8 kV/ 120 kV transformer. The 120 kV network is modeled by a simple inductive voltage source (short circuit power of 1200 MVA) using the Three-Phase Source block. The model shows a 9 MW wind farm using asynchronous generators and exporting power to a 120 kV network through a 25-kV distribution feeder.