Research & Collaboration
What makes us unique?
SuperGrid Institute owes its success to the people who make up our various research departments. Our teams come from diverse backgrounds in industry and academia, and their wealth of experience and skills make the Institute unique. Each individual brings specific expertise to the table.
This melting pot of knowledge offers opportunities for specialists from different fields to collaborate on new and innovative solutions to technical problems.
The Institute also benefits from close collaborative relationships with industry and academic institutions. The complementary strengths of our partners provide insights and innovative approaches to technical challenges. At the same time, we retain total independence in our research. Public-private investments and collaborative projects finance our work.
SuperGrid Institute’s state-of-the-art research facilities, test platforms and laboratories at the Villeurbanne and Grenoble sites are key to the success of our five research departments.
Latest scientific publications
Liquid spray injection in the expansion volume of a CO2 high voltage circuit breaker
Most high voltage gas circuit breakers (HVCB) in operation use SF6 as the arc interruption medium because of its high dielectric strength and good arc interruption properties. However, SF6 also displays a high global warming potential which motivates the investigation of possible alternatives to this gas.
On the Black Start of Offshore Wind Power Plants with Diode Rectifier based HVDC Transmission
This paper attempts a detailed comparison of some of the solutions for black start of the Offshore Wind Power Plants with Diode Rectifier based HVDC transmission.
Power Hardware In-the-Loop validation of DC-DC power converter for offshore wind energy
he paper describes the development of a power converter small scale mock-up and a real time model of an off-shore wind farm. A Power Hardware In-the-Loop validation is proposed for a demonstration of grid architecture and control principles. The paper presents the design methodology of the PHIL test bench and underlines the contribution of PHIL in the design flow of power converter development for DC grid application. Experimental results of preliminary PHIL tests are presented.