Germany
The ACS laboratory hosts a state-of-the-art pilot site designed to simulate, emulate, and investigate a wide range of modern power system scenarios. This facility supports cutting-edge research and development for real-world power systems, distributed systems, and multi-physics systems.
Our infrastructure includes high-performance real-time simulators such as the Real-Time Digital Simulator (RTDS), OPAL-RT, and DSP/PC-Cluster, as well as advanced power system equipment like Phasor Measurement Units (PMUs), protection devices, and power converters. Additionally, the pilot site is equipped with an Imperix PEB8038 converter and a Chroma 61830 grid emulator, enabling precise emulation of microgrids connected to the main grid.
This comprehensive experimental environment supports real-time simulation with Hardware in the Loop (HIL) and Power Hardware in the Loop (PHIL) techniques. These capabilities bridge the gap between numerical simulations and field tests, allowing for detailed and accurate analysis of power and communication network interactions, as well as the behavior of complex energy systems under various scenarios.
Germany
The ACS laboratory hosts a state-of-the-art pilot site designed to simulate, emulate, and investigate a wide range of modern power system scenarios. This facility supports cutting-edge research and development for real-world power systems, distributed systems, and multi-physics systems.
Our infrastructure includes high-performance real-time simulators such as the Real-Time Digital Simulator (RTDS), OPAL-RT, and DSP/PC-Cluster, as well as advanced power system equipment like Phasor Measurement Units (PMUs), protection devices, and power converters. Additionally, the pilot site is equipped with an Imperix PEB8038 converter and a Chroma 61830 grid emulator, enabling precise emulation of microgrids connected to the main grid.
This comprehensive experimental environment supports real-time simulation with Hardware in the Loop (HIL) and Power Hardware in the Loop (PHIL) techniques. These capabilities bridge the gap between numerical simulations and field tests, allowing for detailed and accurate analysis of power and communication network interactions, as well as the behavior of complex energy systems under various scenarios.
