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Use numeric methods to solve the power-flow equations in a power distribution network. Code is partially a port of the MATLAB toolbox provided by Hadi Sa'adat along with his book 'Power System Analysis', published by McGraw-Hill, along with other implementations of numeric methods and other visualization tools.

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pyPowerFlow

Python tool to solve power flow problems in power networks using numeric methods, given line and bus parameters.

Suppored Numeric Methods

  • Newton-Raphson (Port of Hadi Sa'adat's implementation)
  • Gauss-Seidel

Supported Generator Policies

  • "Tap-Changer": Play with voltages of busses that have generators on them, such that the reactive power Q_gen stays within the realm of Q_min and Q_max.
  • "Clamp": Keep the voltages of busses with generators on them constant, and clamp Q_gen to the closest of {Q_min, Q_max}.

Note

Code adapted from Hadi Sa'adat's MATLAB toolbox, published along with his book Power System Analysis, third edition, McGraw-Hill, 1999.

This code was ported and edited to solve a graded assignment in the course Techno-Economical Problems in Power Systems, in Tel-Aviv University, 2022. The changes from the original MATLAB implementation are detailed below.

Changes (from the original implementation)

  • No tap-changer support (apart from the policy described earlier), i.e can't input tap changer stops for each generator.
  • Added all line currents and losses to the outputs
  • Added a network plot, a voltage plot and convergence statistics for each mode.

Installation

  1. Create a virtual environment python -m venv venv
  2. Activate it (On unix: source venv/Scripts/activate, On windows: .\venv\Scripts\activate)
  3. Install the requirements: pip install -r requirements.txt
  4. (Modify the line and bus parameters)
  5. Run the code python main.py

Usage (main.py)

  • Input the bus and line data according to the example and headers. The format is consistent with Hadi Sa'adat's format.

  • Set the accuracy constraint and the maximum number of iterations

  • Set the mode: newton for Newton-Raphson, gauss for Gauss-Seidel.

Example initialization

my_pf =     PowerFlowNetwork(bus_params,
                             line_params,
                             base_power_reference,
                             accuracy, 
                             max_iterations,
                             mode="newton",
                             policy="tap_changer",
                             bus_csv_name="newton_bus_data.csv",
                             line_csv_name="newton_line_data.csv")

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Use numeric methods to solve the power-flow equations in a power distribution network. Code is partially a port of the MATLAB toolbox provided by Hadi Sa'adat along with his book 'Power System Analysis', published by McGraw-Hill, along with other implementations of numeric methods and other visualization tools.

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