Remedying saturation short circuit:

Improving the direct current supply for data processors, communication, drives, automation and industrial processes (lasers, plasma curing, electro-welding...):

  • s>1000 times the actuating speed of the primary voltage pulse durations
  • Doubling the power density:
    • Increase in efficiency: 1-15%
    • No additional components in the power circuit: approx. 50% smaller as resonance (LLC) and intermediate circuit converters
    • no costly primary current monitoring
    • enables pulse to pulse load current limitation, load short-circuit-proof without over-dimensioning
    • Outputfilter (L1, C2) up to 90% saving (data processing, communication)
    • Lower engine output, saving on transmission, and higher acceleration in the case of inverter drives (robotics, automation)

Expansion of the area of application, e.g. potential seperation for solar inverter:


  • no leakage currents
  • non-insulated solar cells

  • Banishing the risk of blackout:

    Vision for HVDC (currently, 3-phase solution):

    In the case of the transmission of higher capacities, the inverter roughly switches with the network frequency due to the high voltage, which is why no savings are to be expected regarding the transformer, however:

    • The investment volume falls by approx. 30% with a three-phase current filter;
    • Greater security of supply and non-critical switching back on:
      • The transmission lines are protected from overload.
      • In a region affected by a line failure, the grid DC voltage may decrease before intact lines would have to be switched off.
      • The danger of a chain reaction leading to a blackout is averted. The affected region is still supplied with electricity.
      • The currently high degree of crosslinking can be reduced.