Simulating Microgrids with OPAL-RT’s Real Time Platforms

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Simulating Microgrids with OPAL-RT’s Real Time Platforms


Contrary to classic grids that self-regulate relatively easily, microgrids integrate intermittent and unreliable renewable energy sources. This type of energy, that we do not directly control (we cannot make the sun shine brighter or the wind blow softer), therefore requires complex control systems to regulate flow of the grid’s power, voltage and frequency.

The expansion of microgrids is part of a trend that aims to:
  • Generate power using local, readily available resources.
  • Limit losses caused by too great a distance between production and consumer.
  • Reduce energy sources that pollute (nuclear or coal, for example).
Contrary to classic grids that self-regulate relatively easily, microgrids integrate intermittent and unreliable renewable energy sources. This type of energy, that we do not directly control (we cannot make the sun shine brighter or the wind blow softer), therefore requires complex control systems to regulate flow of the grid’s power, voltage and frequency. The more complex the systems, the more tests will need to be performed, and with greater accuracy. Digital real-time simulation allows researchers to study multiple scenarios in near real conditions and without risk. They can also integrate a power amplifier to introduce more realism and let them perform tests using real power flow between the simulated environment and real hardware. This is known as Power-Hardware-In-the-Loop (PHIL) simulation. Because today’s microgrids remain largely experimental, OPAL-RT supplied HIL and PHIL simulation platforms touniversity and industrial laboratories, such as the L2EP at the Ecole Centrale de Lille, EDF R&D and CEA-INES in France. These microgrids have a very promising future, especially in remote and extremely isolated areas, on islands or in countries where grids are underdeveloped or particularly unstable.