De-exciting system for inductive circuits

What is claimed is: 1. A de-exciting system for dissipating energy from an inductive circuit that comprises at least one coil, adapted to be attached to said inductive circuit and comprising: a series connection of a discharge resistor and a unidirectional discharge switching element, said series connection being arranged such that, if the de-exciting system is attached to the inductive circuit and the discharge switching element is in a conducting state, a closed conducting path comprising the coil and the discharge resistor is formed; a unidirectional bypass switching element that is connected in parallel to the discharge resistor such that, when the de-exciting system is attached to the inductive circuit and both the discharge switching element and the bypass switching element are in a conducting state, a closed conducting path comprising the coil, the discharge switching element, and the bypass switching element is formed; and a control device configured to: in a first de-excitation phase, switch both the discharge switching element and the bypass switching element into a conducting state, and in a second de-excitation phase, switch the bypass switching element into a non-conducting state, while keeping the discharge switching element in the conducting state. 2. The de-exciting system of claim 1 , wherein the control means of the de-exciting system are coupled or integrated with control means of a circuit breaker in a powering path to the inductive circuit and configured to: in response to a request for de-excitation of the inductive circuit, begin the first de-excitation phase before the circuit breaker begins to open. 3. The de-exciting system of claim 2 , wherein the control means of the de-exciting system are further configured to: begin the second de-excitation phase after the circuit breaker has reached its full insulation capability. 4. The de-exciting system of claim 1 , further comprising a unidirectional backup switching element that is connected in parallel to the series connection of the discharge resistor and the discharge switching element. 5. The de-exciting system of claim 4 , wherein the control device of the de-exciting system are configured to: monitor a source current that is feeding the inductive circuit through the de-exciting system in the first de-excitation phase, and monitor the current through the discharge resistor in the second de-excitation phase, and the source current does not drop to zero during the first de-excitation phase, and/or the current through the discharge resistor does not reach a pre-set threshold within a pre-set time after start of the second de-excitation phase, switch the backup switching element into a conducting state. 6. The de-exciting system of claim 1 , wherein the discharge switching element, the bypass switching element, and/or the backup switching element, is a solid-state semiconductor switching element. 7. The de-exciting system of claim 1 , further comprising an induced field switching element in an anti-parallel configuration with the discharge switching element. 8. The de-exciting system of claim 1 , wherein the control means of the de-exciting system are configured to transition from the first de-excitation phase to the second de-excitation phase 100 ms after the start of the first de-excitation phase at the latest. 9. An exciting system for a synchronous machine, comprising at least one power supply, a de-exciting system according to claim 1 that is configured to be connected to a field winding of the synchronous machine as the inductive circuit, and at least one circuit breaker that controls the flow of power from the power supply to the de-exciting system. 10. The exciting system of claim 9 , wherein the power supply comprises an inverter that is configured to convert an AC supply voltage to a DC voltage for the field winding by switching the AC supply voltage onto the de-exciting system according to a time program, the control means of the de-exciting system are coupled or integrated with control means of the inverter, and the control means of the de-exciting system are configured to switch off the inverter within the first de-excitation phase.