Device and method for insulation monitoring in a power supply system including a high-resistance grounded neutral point

The invention claimed is: 1. A device ( 2 ) for insulation monitoring in a power supply system ( 4 ) comprising: a main system ( 14 ) including a neutral point that is high-resistance grounded via a neutral-point resistance ( 18 ), which includes the neutral point connected in series with the neutral point resistance ( 18 ) which is connected in series to ground, and at least one subsystem ( 16 ); the main system ( 14 ) and the subsystem ( 16 ) each having a differential current measuring device ( 10 , 12 ) for registering a differential current, characterized by a measuring signal generator ( 6 ) for generating an active measuring signal and for feeding an active measuring signal into the main system ( 14 ) and by an evaluating device ( 8 ) that is connected to the differential current measuring devices ( 10 , 12 ) and to the measuring signal generator ( 6 ) to evaluate differential current measuring signals; the active measuring signal is a measuring voltage (Umess) that is fed serially to the neutral-point resistance ( 18 ), configured as a low-resistance voltage source or the active measuring signal is a measuring current that is fed in parallel to the neutral-point resistance ( 18 ). 2. The device ( 2 ) for insulation monitoring according to claim 1 , characterized by an artificial neutral point ( 22 ) at the outer conductors (L 1 , L 2 , L 3 ) of the main system ( 14 ), wherein a voltage signal can be tapped against ground via said artificial neutral point. 3. The device ( 2 ) for insulation monitoring according to claim 1 , characterized in that the measuring signal generator ( 6 ) has a control unit ( 20 ) for controlling the generated active measuring signal, wherein the active measuring signal appearing in the main system ( 14 ) is fed back as the voltage signal that can be tapped via the artificial neutral point ( 22 ). 4. The device ( 2 ) for insulation monitoring according to claim 1 , characterized in that a signal shape and signal parameters of the active measuring signal can be adapted to electrical characteristics of the power supply system ( 4 ) to be monitored. 5. The device ( 2 ) for insulation monitoring according to claim 4 , characterized in that the evaluating device ( 8 ) has a data memory ( 28 ) for storing the signal shape and the signal parameters of the active measuring signal and for storing the electrical characteristics of the power supply system ( 4 ). 6. The device ( 2 ) for insulation monitoring according to claim 5 , characterized in that the evaluating device ( 8 ) has a processing unit ( 30 ) for performing digital signal processing algorithms in order to extract a fault current portion that is driven by the active measuring signal from each of the registered differential current measuring signals, the stored signal parameters and electrical characteristics. 7. The device ( 2 ) for insulation monitoring according to claim 6 , characterized in that a processing rule is implemented in the processing unit ( 30 ) of the evaluating device ( 8 ) to determine the total insulation resistance of the power supply system ( 4 ) and, if the power supply system ( 4 ) includes the main system ( 14 ) and at least one subsystem ( 16 ), to determine the partial insulation resistances of the main system ( 14 ) and of the subsystems ( 16 ) on the basis of the extracted fault current portions. 8. The device ( 2 ) for insulation monitoring according to claim 1 , characterized in that for insulation fault location, the evaluating device ( 8 ) is configured to locate an insulation fault on the basis of the registered differential currents. 9. The device ( 2 ) for insulation monitoring according to claim 1 , characterized in that the subsystem ( 16 ) has a subsystem evaluating device that is connected to the differential current measuring device ( 12 ) of said subsystem ( 16 ) to evaluate the differential current measuring signal provided by the differential current measuring device ( 12 ) of said subsystem ( 16 ). 10. The device ( 2 ) for insulation monitoring according to claim 1 , characterized in that the subsystem ( 16 ) for voltage measurement against ground (PE) has an artificial neutral point ( 22 ). 11. A method for insulation monitoring in a power supply system ( 4 ) comprising a main system ( 14 ) including a neutral point that is high-resistance grounded via a neutral-point resistance ( 18 ), which includes the neutral point connected in series with the neutral-point resistance ( 18 ) which is connected in series to ground, and at least one subsystem ( 16 ), wherein a differential current is registered in each of the main system ( 14 ) and the subsystem, ( 16 ) by a differential current measuring device ( 10 , 12 ), characterized by generation of an active measuring signal and feeding of the active measuring signal into the main system ( 14 ) by a measuring signal generator ( 6 ) and by evaluation of differential current measuring signals by an evaluating device ( 8 ) that is connected to the differential current measuring devices ( 10 , 12 ) and to the measuring signal generator ( 6 ), wherein a measuring voltage (Umess) is injected as the active measuring signal serially to the neutral-point resistance ( 18 ), configured as a low-resistance voltage source, or a measuring current is injected as the active measuring signal in parallel to the neutral-point resistance ( 18 ). 12. The method for insulation monitoring according to claim 11 , characterized in that a voltage signal is tapped against ground (PE) via an artificial neutral point ( 22 ) of outer conductors (L 1 , L 2 , L 3 ) of the main system ( 14 ). 13. The method for insulation monitoring according to claim 11 , characterized in that the generated active measuring signal is controlled, wherein the active measuring signal appearing in the main system ( 14 ) is fed back as the voltage signal that can be tapped via the artificial neutral point ( 22 ). 14. The method for insulation monitoring according to claim 11 , characterized in that signal shape and signal parameters of the active measuring signal are adapted to electrical characteristics of the power supply system ( 4 ) to be monitored. 15. The method for insulation monitoring according to claim 14 , characterized in that the signal shape and the signal parameters of the active measuring signal and the electrical characteristics of the power supply system ( 4 ) are stored in a data memory ( 28 ) of the evaluating device ( 8 ). 16. The method for insulation monitoring according to claim 15 , characterized in that in a processing unit ( 30 ) of the evaluating device ( 8 ), digital signal processing algorithms are performed that extract a fault current portion driven by the active measuring signal from each of the registered differential current measuring signals and the stored signal parameters and the electrical characteristics. 17. The method for insulation monitoring according to claim 16 , characterized in that in the processing unit ( 30 ) of the evaluating device ( 8 ), the total insulation resistance of the power supply system ( 4 ) and if the power supply system ( 4 ) includes the main system ( 14 ) and the at least one subsystem ( 16 ), the partial insulation resistances of the main system ( 14 ) and of the subsystems ( 16 ) are determined on the basis of the extracted fault current portions. 18. The method for insulation monitoring according to claim 11 , characterized in that for insulation fault location, an insulation fault is located in the evaluating device ( 8 ) on the basis of the registered differential currents.