Pulse circuit for providing a fault current in a DC voltage power supply grid

What is claimed is: 1. A DC voltage power supply grid for electrically coupling at least two electrical devices to an electrical power source connected to the DC voltage power supply grid having an electrical DC supply voltage, comprising: a protective device having a sensor unit and a switching unit which are arranged between a respective one of the at least two electrical devices and the DC voltage supply grid for protecting the respective electrical device against an unintended overcurrent, with the switching unit being designed to deactivate a device connection between the DC voltage power supply grid and the respective electrical device when an unintended overcurrent has been detected, a pulse circuit connected to an input of the protective device for discharging a predefined electrical charge stored in a capacitor of the pulse circuit when the electrical DC supply voltage dips, wherein the predefined electrical charge is determined as a function of the unintended overcurrent and a time required for discharging the predefined electrical charge, and a first semiconductor switching element connected in series with the capacitor. 2. The DC power supply grid of claim 1 , wherein the time required for discharging the predefined electrical charge is determined as a function of a characteristic property of the protective device. 3. The DC power supply grid of claim 1 , wherein the protective is configured for detecting unintended overcurrents of different magnitudes, with the electrical charge stored in the capacitor of the pulse circuit being based on a greatest of the unintended overcurrents. 4. The DC power supply grid of claim 1 , wherein the first semiconductor switching element comprises a first diode or is formed by a first diode. 5. The DC power supply grid of claim 1 , wherein the first semiconductor switching element is designed to be controllable by a control signal. 6. The DC power supply grid of claim 5 , further comprising a control unit, which is coupled to the sensor unit and provides the control signal. 7. The DC power supply grid of claim 1 , further comprising a charging unit for charging the capacitor with the predefined electrical charge. 8. The DC power supply grid of claim 1 , wherein the pulse circuit is formed integrally with the protective device. 9. The DC power supply grid of claim 1 , wherein the first semiconductor switching element comprises a parallel circuit composed of a first diode and serial circuit composed of a second diode having an inverse polarity from the first diode and being connected at a central connection point to a resistor. 10. The DC power supply grid of claim 9 , wherein the resistor is constructed as a varistor. 11. The DC power supply grid of claim 9 , wherein the switching unit comprises a second semiconductor switching element and the pulse circuit comprises a third diode connected to the second diode, with the second diode being connected anti-serially to the third diode at the central connection point, and with the anti-serially connected second and third diodes being connected in parallel with the second semiconductor switching element. 12. A method for electrically coupling at least two electrical devices to a DC power supply grid connected to an electrical power source and having a predefined electrical supply voltage, comprising: protecting the at least two electrical devices against an unintended overcurrent by arranging respective protective devices between the DC power supply grid and respective ones of the at least two electrical devices, detecting with a sensor unit disposed in a respective one of the protective devices a respective electrical current and disconnecting the respective electrical device from the DC power supply grid with a switching unit when an unintended overcurrent has been detected, discharging a predefined electrical charge from an electrical charge stored in a capacitor of a pulse circuit when a voltage detected at an input of the respective protective device dips below the supply voltage, wherein the discharged electrical charge is determined at least as a function of the unintended overcurrent and a predefined period of time required for discharging the predefined electrical charge, wherein the capacitor is connected in series with a semiconductor switching element.