Commutating circuit

The invention claimed is: 1. A commutating circuit for a power converter, the commutating circuit comprising: a first switching device having a first terminal and a second terminal; a second switching device; and a circuit part for limiting a size of a time-related variation of a voltage which occurs across said first switching device, said circuit part having an energy store connected in parallel with said first switching device, said energy store having a first terminal connected directly to said first terminal of said first switching device and a second terminal connected directly to said second terminal of said first switching device; said first switching device and said circuit part together forming a parallel electric circuit; said second switching device being electrically connected in series with said parallel electric circuit to form an electrical series circuit disposed to bridge the power converter. 2. The commutating circuit according to claim 1 , wherein said circuit part has a surge voltage protector for protecting said energy store against a voltage surge. 3. The commutating circuit according to claim 1 , wherein the power converter is a rectifier. 4. The commutating circuit according to claim 1 , wherein said first switching device is connected to a first DC voltage connection and, via said second switching device, to a second DC voltage connection on the power converter. 5. The commutating circuit according to claim 1 , wherein at least one of said first switching device or said second switching device has a mechanical switch. 6. The commutating circuit according to claim 1 , wherein said second switching device is a series circuit containing a plurality of mechanical switches. 7. The commutating circuit according to claim 1 , wherein said first switching device is connected to a first DC voltage connection on the power converter and said second switching device is connected to a second DC voltage connection on the power converter. 8. The commutating circuit according to claim 1 , wherein said energy store is a capacitor. 9. The commutating circuit according to claim 5 , wherein said mechanical switch is a vacuum switch. 10. A power converter, comprising: a commutating circuit containing a switching device and a circuit part for limiting a size of a time-related variation of a voltage which occurs across said switching device, said circuit part having an energy store connected in parallel with said switching device, said energy store having a first terminal connected directly to a first terminal of said switching device and a second terminal connected directly to a second terminal of said switching device; said first switching device and said circuit part forming a parallel electric circuit; and a second switching device electrically connected in series with said parallel electric circuit to form an electrical series circuit disposed to bridge the power converter. 11. An arrangement, comprising: a plurality of power converters electrically connected in series, each of said power converters containing a commutating circuit having a switching device by which a respective one of said power converters is electrically bridged and a circuit part for limiting a size of a time-related variation of a voltage which occurs across said switching device, each said circuit part having an energy store connected in parallel with said switching device, said energy store having a first terminal connected directly to a first terminal of said switching device and a second terminal connected directly to a second terminal of said switching device said first switching device and said circuit part forming a parallel electric circuit; and a second switching device electrically connected in series with said parallel electric circuit to form an electrical series circuit disposed to bridge the power converter. 12. A method for commutation of an electric current by a first switching device of a commutating circuit in a power converter, the power converter being bridgeable by means of the first switching device and a second switching device connected in series with the first switching device, which comprises the steps of: flowing the electric current initially through a closed first switching device and a closed second switching device connected in series with the first switching device; opening the first switching device; and providing a circuit part with an energy store connected in parallel with said first switching device, the circuit part being a part of the commutating circuit and the energy store having a first terminal connected directly to a first terminal of the first switching device and a second terminal connected directly to a second terminal of the first switching device; commutating the electric current by the first switching device to the circuit part of the commutating circuit, using the circuit part to limit a size of a time-related variation of a voltage which occurs across the first switching device upon the opening of the first switching device, and as a result of a limitation of the time-related variation of the voltage, achieving a current zero-crossing in the first switching device; and charging the energy store with the current commutated to the circuit part and, as a result of a time-related increase in the voltage on the energy store, commutating the electric current from the circuit part to the power converter; and after commutation of the electric current to the power converter, opening the second switching device. 13. The method according to claim 12 , wherein the energy store includes a capacitor and, as a result of the time-related increase in a capacitor voltage of the capacitor, the electric current is commutated from the circuit part to the power converter. 14. The method according to claim 13 , which further comprises limiting a magnitude of the capacitor voltage to a maximum voltage value.