Method, circuit breaker and switching unit for switching off high-voltage DC currents

What is claimed is: 1. A method for switching off a high-voltage DC current from a voltage source delivering a nominal voltage by means of a circuit breaker including a semiconductor switching assembly and at least one mechanical switch in series, wherein the semiconductor switching assembly includes a plurality of semiconductor switches and a plurality of arresters in parallel to the semiconductor switches, the method comprising: switching off the semiconductor switching assembly to reduce current in the circuit breaker to a residual current; and switching off the residual current by means of the mechanical switch, wherein: the arresters have an added threshold voltage exceeding the nominal voltage; the mechanical switch is arranged in a resonant circuit configured to generate an oscillating current through an arc in the mechanical switch after switching off the semiconductor switching assembly and opening the mechanical switch; the oscillating current has an amplitude exceeding the residual current such that at least one current zero crossing can be generated in the arc of the mechanical switch; and the method comprises extinguishing the arc during the current zero crossing. 2. The method of claim 1 , wherein the residual current is below 20 Ampere. 3. The method of claim 2 , wherein the residual current is between 1 and 20 Ampere. 4. The method of claim 1 , wherein the circuit breaker is an AC high voltage circuit breaker. 5. The method of claim 1 , wherein the arresters have an added threshold voltage of less than 1.6 times the nominal voltage. 6. A method for switching off a high-voltage DC current from a voltage source delivering a nominal voltage by means of a circuit breaker including a semiconductor switching assembly and at least one mechanical switch in series, wherein the semiconductor switching assembly includes a plurality of semiconductor switches and a plurality of arresters in parallel to the semiconductor switches, the method comprising: switching off the semiconductor switching assembly to reduce current in the circuit breaker to a residual current; and switching off the residual current by means of the mechanical switch, wherein: the arresters have an added threshold voltage exceeding the nominal voltage; and the residual current is below 20 Ampere. 7. The method of claim 6 , wherein: the mechanical switch is arranged in a resonant circuit configured to generate an oscillating current through an arc in the mechanical switch after switching off the semiconductor switching assembly and opening the mechanical switch, the oscillating current has an amplitude exceeding the residual current such that the mechanical switch generates at least one current zero crossing in the arc of the individual switch; and the arc is extinguished during the current zero crossing. 8. The method of claim 6 , wherein the arresters have an added threshold voltage of less than 1.6 times the nominal voltage. 9. The method of claim 6 , wherein the residual current is between 1 and 20 Ampere. 10. A circuit breaker for switching off high-voltage DC currents of a nominal voltage, the circuit breaker comprising: a semiconductor switching assembly including a plurality of semiconductor switches and a plurality of arresters in parallel to the semiconductor switches, the arresters having an added threshold voltage exceeding the nominal voltage; a mechanical switch arranged in series with the semiconductor switching assembly; and a resonant circuit including a capacitor and an arc gap of the mechanical switch, the capacitor being arranged in parallel to the mechanical switch, wherein: the circuit breaker is configured to switch off the semiconductor switching assembly to reduce current in the circuit breaker to a residual current, and switch off the residual current by opening the mechanical switch; the mechanical switch is arranged in the resonant circuit which is configured to generate an oscillating current through an arc in the mechanical switch after the semiconductor switching assembly is switched off and the mechanical switch is opened; the oscillating current has an amplitude exceeding the residual current such that at least one current zero crossing can be generated in the arc of the mechanical switch; and the arc is extinguished during the current zero crossing. 11. The circuit breaker of claim 10 , wherein the resonant circuit is configured to induce current oscillations in the arc of the mechanical switch that exceed the residual current through the semiconductor switching assembly when the semiconductor switching assembly is in an off state with the nominal voltage applied to the semiconductor switching assembly. 12. The circuit breaker of 10 , wherein the capacitor has a capacitance in a range of 1 nF to 4 nF. 13. The circuit breaker of claim 10 , wherein the mechanical switch is a blast circuit breaker. 14. The circuit breaker of claim 13 , wherein the mechanical switch is a puffer circuit breaker. 15. The circuit breaker of claim 10 , wherein the mechanical switch comprises nominal current contacts, arc contacts and a driving mechanism configured to first open the nominal contacts and then the arc contacts. 16. The circuit breaker of claim 10 , comprising: a first disconnector in series with the mechanical switch. 17. The circuit breaker of claim 16 , wherein a capacitance over the mechanical switch is higher than a capacitance over the first disconnector. 18. The circuit breaker of claim 17 , wherein the first disconnector is configured to galvanically separate individual sections of the network. 19. The circuit breaker of claim 16 , wherein the first disconnector is configured to galvanically separate individual sections of the network. 20. The circuit breaker of claim 16 , comprising: a second disconnector, wherein the first disconnector and the second disconnector are configured to disconnect the semiconductor switching assembly. 21. The circuit breaker of claim 16 , wherein: the mechanical switch and the first disconnector are both blast circuit breakers; and the mechanical switch includes a gas nozzle bridging an arc gap of the mechanical switch when the mechanical switch is in an opened state. 22. The circuit breaker of claim 21 , wherein the first disconnector does not include a gas nozzle bridging an arc gap of the first disconnector when the first disconnector is in an opened state. 23. The circuit breaker of claim 21 , wherein the first disconnector also includes a gas nozzle, the gas nozzle of the first disconnector being shorter than the gas nozzle of the mechanical switch. 24. The circuit breaker of claim 21 , wherein the mechanical switch and the first disconnector are both puffer circuit breakers. 25. The circuit breaker of claim 21 , wherein the mechanical switch and the first disconnector are of identical design with the exception of the gas nozzle. 26. The circuit breaker of claim 16 , wherein the mechanical switch and the first disconnector include a common driving mechanism. 27. The circuit breaker of claim 16 , wherein the first disconnector and the mechanical switch are part of a common switching unit including an insulating support, the first disconnector and the mechanical switch both being mounted to the insulating support. 28. The circuit breaker of claim 27 , wherein the switching unit further inclu