Converter circuit

The invention claimed is: 1. A converter circuit with short-circuit protection, comprising: a plurality of phase legs having a series connection of normally-on switches, the phase legs being connected between positive and negative voltage rails of a DC voltage link; a DC link capacitor; AC voltage connection points formed of connection points between the normally-on switches; at least one phase-to-phase short-circuit protection circuit having a parallel connection of a resistive component and a controllable switch, the phase-to-phase short-circuit protection circuit including first and second terminals, the first terminal being connected to an AC voltage connection point and the second terminal forming an input or an output of the converter circuit; and a phase leg short-circuit protection circuit having a controllable switch connected in series with the DC link capacitor, the series connection of the controllable switch and the DC link capacitor being connected between the positive and negative voltage rails of the DC voltage link; wherein in case of lack of control of the normally-on switches, the converter circuit is configured so that the controllable switch of the at least one phase-to-phase short-circuit protection circuit and the controllable switch of the phase leg short-circuit protection circuit will be controlled to a non-conductive state. 2. A converter circuit according to claim 1 , wherein the converter circuit is a single phase converter circuit having two phase legs, wherein the converter circuit comprises: one phase-to-phase short-circuit protection circuit. 3. A converter circuit according to claim 1 , wherein the converter circuit is a three phase converter circuit having three phase legs wherein the converter circuit comprises: two phase-to-phase short-circuit protection circuits. 4. A converter circuit according to claim 1 , wherein the converter circuit is an AC to AC converter comprising: input phase legs forming a controllable rectifier and output phase legs forming an inverter, wherein the DC link is common to the controllable rectifier and the inverter and at least one phase-to-phase short-circuit protection circuit is arranged both in the controllable rectifier and in the inverter, and wherein the phase leg short-circuit protection circuit is arranged in the common DC link. 5. A converter circuit according to claim 1 , comprising: a charging circuit for charging the DC link capacitor, the charging circuit having a series connection of a diode and a resistive component, the charging circuit being connected between the second terminal of the phase-to-phase short-circuit protection circuit forming an input of the converter circuit and the connection point between the phase leg short-circuit protection circuit and the DC link capacitor. 6. A converter circuit according to claim 1 , comprising: one or more of the controllable switches of the short-circuit protection circuits are mechanical switches. 7. A converter circuit according to claim 1 , comprising: an auxiliary power supply and one or more gate driver circuits for driving the normally-on switches of the converter circuit, the gate driver circuits receiving voltage from the auxiliary power supply, wherein the gate driver circuits are normally-off type circuits that are provided with a capacitor for sustaining the voltage from the auxiliary power supply. 8. A converter circuit according to claim 7 , wherein the capacitor is configured to sustain voltage from the auxiliary power supply for enabling the switches of the short-circuit protection circuit to be controlled to an off-state. 9. A converter circuit according to claim 1 , wherein the normally-on switches are normally-on JFETs. 10. A converter circuit according to claim 2 , wherein the converter circuit is an AC to AC converter comprising: input phase legs forming a controllable rectifier and output phase legs forming an inverter, wherein the DC link is common to the controllable rectifier and the inverter and at least one phase-to-phase short-circuit protection circuit is arranged both in the controllable rectifier and in the inverter, and wherein the phase leg short-circuit protection circuit is arranged in the common DC link. 11. A converter circuit according to claim 3 , wherein the converter circuit is an AC to AC converter comprising: input phase legs forming a controllable rectifier and output phase legs forming an inverter, wherein the DC link is common to the controllable rectifier and the inverter and at least one phase-to-phase short-circuit protection circuit is arranged both in the controllable rectifier and in the inverter, and wherein the phase leg short-circuit protection circuit is arranged in the common DC link. 12. A converter circuit according to claim 10 , comprising: a charging circuit for charging the DC link capacitor, the charging circuit having a series connection of a diode and a resistive component, the charging circuit being connected between the second terminal of the phase-to-phase short-circuit protection circuit forming an input of the converter circuit and the connection point between the phase leg short-circuit protection circuit and the DC link capacitor. 13. A converter circuit according to claim 11 , comprising: a charging circuit for charging the DC link capacitor, the charging circuit having a series connection of a diode and a resistive component, the charging circuit being connected between the second terminal of the phase-to-phase short-circuit protection circuit forming an input of the converter circuit and the connection point between the phase leg short-circuit protection circuit and the DC link capacitor. 14. A converter circuit according to claim 12 , comprising: one or more of the controllable switches of the short-circuit protection circuits are mechanical switches. 15. A converter circuit according to claim 13 , comprising: one or more of the controllable switches of the short-circuit protection circuits are mechanical switches. 16. A converter circuit according to claim 14 , comprising: an auxiliary power supply and one or more gate driver circuits for driving the normally-on switches of the converter circuit, the gate driver circuits receiving voltage from the auxiliary power supply, wherein the gate driver circuits are normally-off type circuits that are provided with a capacitor for sustaining the voltage from the auxiliary power supply. 17. A converter circuit according to claim 15 , comprising: an auxiliary power supply and one or more gate driver circuits for driving the normally-on switches of the converter circuit, the gate driver circuits receiving voltage from the auxiliary power supply, wherein the gate driver circuits are normally-off type circuits that are provided with a capacitor for sustaining the voltage from the auxiliary power supply. 18. A converter circuit according to claim 16 , wherein the normally-on switches are normally-on JFETs. 19. A converter circuit according to claim 17 , wherein the normally-on switches are normally-on JFETs.