Power switching device, three phase bridge inverter, and method of operating a power switching device

The invention claimed is: 1. A power switching device connected or connectable between a power supply and a load, for providing an output voltage to said load, said power switching device having at least two different operating states, each of said operating states having a different level of said output voltage associated with it, said power switching device comprising: a power terminal connected or connectable to said power supply; a load terminal connected or connectable to said load, for providing said output voltage; a power switch connected between said power terminal and said load terminal and arranged to be conductive in a first one of said operating states; a power conductor connected between said power terminal and said load terminal in at least one of said states, wherein an electrical current through said power conductor changes in response to said power switch being turned off, thereby causing self-induction in said power conductor; and a control unit arranged to control said power switch in real-time on the basis of a real-time level of a voltage across said power conductor so as to turn off said power switch in a continuous or stepwise or pulsed manner to prevent said voltage across said power conductor from exceeding a maximum allowed level. 2. The power switching device of claim 1 , wherein in said first state, said load terminal is connected to said power terminal via a conductive path comprising said power switch and said power conductor. 3. The power switching device of claim 1 , wherein in said first state said load terminal is connected to said power terminal via a conductive path comprising said power switch but not said power conductor. 4. The power switching device of claim 3 , wherein in said first state said current through said power conductor is small compared to a current through said first power switch. 5. The power switching device of claim 3 , comprising a flyback path in which a flyback current is generated in response to turning off said power switch, said flyback path comprising said power conductor. 6. The power switching device of claim 1 , wherein said power switch is a first power switch, said power switching device comprises a second power switch, said operating states comprise a second state in which said second power switch is conductive and said first power switch is nonconductive, said electrical current through said power conductor changes in response to said second power switch being turned off, thereby inducing a voltage across said power conductor; and said control unit is further arranged to control said second power switch in real-time on the basis of a real-time level of said voltage across said power conductor so as to turn off said second power switch in a continuous or stepwise or pulsed manner to prevent said voltage across said power conductor from exceeding a maximum allowed level. 7. The power switching device of claim 6 , wherein said power terminal is a first power terminal and said power switching device comprises a second power terminal connected or connectable to said power supply to provide a voltage between said first power terminal and said second power terminal, said first power switch being connected between said first power terminal and said load terminal, said second power switch being connected between said second power terminal and said load terminal. 8. The power switching device of claim 7 , wherein said power conductor is connected between said first power terminal and said first power switch. 9. The power switching device of claim 6 , comprising a protective element connected antiparallel across said first power switch. 10. The power switching device of claims 1 , comprising: a substrate carrying said power switch and a carrier carrying said power terminal, wherein said power conductor comprises a wire having a first end fixed to said substrate and a second end fixed to said carrier. 11. The power switching device of claim 1 , comprising a bridge across said power conductor for sensing said voltage across said power conductor. 12. The power switching device of claim 1 , wherein no freewheeling diode is connected in parallel to said power conductor. 13. A three-phase bridge inverter comprising a first, second, and third power switching device as set forth in claim 1 , said first, second, and third power switching device arranged to output a cyclic first, second, and third output voltage with a relative phase shift of 0°, 120° and 240°, respectively. 14. The three-phase bridge inverter of claim 13 , wherein said load is a three-phase induction motor connected to the output terminal of each of the first, second, and third power switching device. 15. A method of operating a power switching device, said power switching device being connected between a power supply and a load to provide an output voltage to said load and having at least two different operating states, each of said operating states having a different level of said output voltage associated with it, said power switching device comprising: a power terminal connected or connectable to said power supply; a load terminal connected or connectable to said load, for providing said output voltage; a power switch connected between said power terminal and said load terminal and arranged to be conductive in a first one of said operating states; and a power conductor connected between said power terminal and said load terminal in at least one of said states, wherein an electrical current through said power conductor changes in response to said power switch being turned off, thereby causing self-induction in said power conductor; wherein the method comprises: controlling said power switch in real-time on the basis of a real-time level of a voltage across said power conductor so as to turn off said power switch in a continuous or stepwise manner to prevent said voltage across said power conductor from exceeding a maximum allowed level.