Magnetic field measuring device and method for detecting a localization current in a branched AC power supply system

The invention claimed is: 1. A magnetic field measuring device for detecting a localization current (Ip) in a branched AC power supply system, wherein a load current (IL) having a mains frequency flows through a line section to be tested of the AC power supply system and the localization current (Ip) has a fundamental frequency lower than the mains frequency, the magnetic field measuring device comprising: a current sensor arrangement mounted on the line section to be tested and comprising a first current sensor (S 1 ), a second current sensor (S 2 ) and a compensating coil (Ak), which generates a compensating magnetic field (Bk) acting in a detection range of the first current sensor (S 1 ) and serving to partially compensate a mains-frequency alternating magnetic field (BL) which is caused by the load current (IL); a first signal processing block (V 1 ); a second signal processing block (V 2 ); and a compensating block (Vk); wherein the first current sensor (S 1 ) and the second current sensor (S 2 ) are disposed such that, in addition to the compensating magnetic field (Bk), the first current sensor (S 1 ) detects the alternating magnetic field (BL) and a common-mode magnetic field (Bp) caused by the localization current (Ip) as a partially compensated magnetic field (B 1 ), and the impact of the compensating magnetic field (Bk) generated by the compensating coil (Ak) on the second current sensor (S 2 ) is negligible, the second current sensor (S 2 ) thus detecting only the alternating magnetic field (BL) and the common-mode magnetic field (Bp) caused by the localization current (Ip) as a resulting magnetic field (B 2 ); wherein the first signal processing block (V 1 ) generates a localization signal (xp) indicating the localization current (Ip) from a first sensor output signal (xs 1 ) generated by the first current sensor (S 1 ), the second signal processing block (V 2 ) generates an alternating voltage signal (xs) corresponding to the resulting magnetic field (B 2 ) from a second sensor output signal (xs 2 ) generated by the second current sensor (S 2 ) and the compensating block (Vk) connected downstream of the second signal processing block (V 2 ) generates a compensating current (Ik), which feeds the compensating coil (Ak), from the alternating voltage signal (xs); wherein the second signal processing block (V 2 ) has a signal input for receiving a synchronization signal (xsync) in order to synchronize a specified measuring period (Tm), during which the localization current (Ip) is detected, with the alternating voltage signal (xs); and wherein the current sensors (S 1 , S 2 ) are designed such that the second current sensor (S 2 ) has a lower magnetic field measuring sensitivity than the first current sensor (S 1 ) and a greater magnetic field measuring range, which is why the partial compensation occurs only to the extent that the partially compensated magnetic field (B 1 ) does not exceed the magnetic field measuring range of the first current sensor (S 1 ). 2. Magnetic field measuring device according to claim 1 , characterized in that the second signal processing block (V 2 ) is designed such that the generated alternating voltage signal (xs) is continued unchanged during the measuring period (Tm), wherein the measuring period (Tm) extends over several periods (Tp) of the localization current (Ip). 3. The magnetic field measuring device according to claim 1 , characterized in that the second signal processing block (V 2 ) has an overload detection for generating an overload signal (xov) in case of an overload of the magnetic field measuring range of the first current sensor (S 1 ). 4. The magnetic field measuring device according to claim 1 , characterized in that the compensating block (Vk) has an adjustment circuit for adjusting the compensating current (Ik) and a signal input for receiving an adjustment signal (xad) generated by the second signal processing block (V 2 ). 5. The magnetic field measuring device according to claim 1 , characterized in that the first signal processing block (V 1 ) is designed to generate a fine compensating signal (xf) which is supplied to the compensating block (Vk) for fine compensation of the alternating magnetic field (BL). 6. The magnetic field measuring device according to claim 1 , characterized in that the compensating coil (Ak) is a planar coil of which the winding is realized as a conducting path on a circuit board and which has a planar core made of ferrite. 7. The magnetic field measuring device according to claim 6 , characterized in that the planar core concentrically has an air gap in which the first current sensor (S 1 ) is disposed. 8. The magnetic field measuring device according to claim 6 , characterized by an embodiment as an independent assembly comprising the circuit board and a surrounding housing or a casting compound, wherein electronic components for signal processing are additionally disposed on the circuit board. 9. The magnetic field measuring device according to claim 6 , characterized in that the second current sensor (S 2 ) is disposed on the circuit board or realized as a separate structural unit. 10. A use of a magnetic field measuring device according to claim 3 , as a device for detecting a localization current for an insulation fault localization system (IFLS) in an AC power supply system, wherein the localization signal (xp) is transmitted to an evaluation unit of the insulation fault localization system (IFLS), the synchronization signal (xsync) is communicated by the insulation fault localization system (IFLS) and the overload signal (xov) is supplied to the insulation fault localization system (IFLS). 11. A method for detecting a localization current (Ip) in a branched AC power supply system, wherein a load current (IL) having a mains frequency flows through a line section to be tested of the AC power supply system and the localization current (Ip) has a fundamental frequency lower than the mains frequency, the method comprising the following steps: mounting a current sensor arrangement comprising a first current sensor (S 1 ), a second current sensor (S 2 ) and a compensating coil (Ak), which generates a compensating magnetic field (Bk) acting in a detection range of the first current sensor (S 1 ) and serving to partially compensate a mains-frequency alternating magnetic field (BL) which is caused by the load current (IL), on the line section to be tested in such a manner that the first current sensor (S 1 ) and the second current sensor (S 2 ) are disposed such that, in addition to the compensating magnetic field (Bk), the first current sensor (S 1 ) detects the alternating magnetic field (BL) and a common-mode magnetic field (Bp) caused by the localization current (Ip) as a partially compensated magnetic field (B 1 ), and the impact of the compensating magnetic field (Bk) generated by the compensating coil (Ak) on the second current sensor (S 2 ) is negligible, the second current sensor (S 2 ) thus detecting only the alternating magnetic field (BL) and the common-mode magnetic field (Bp) caused by the localization current (Ip) as a resulting magnetic field (B 2 ), generating a localization signal (xp) indicating the localization current (Ip) from a first sensor output signal (xs 1 ), which is generated by the first current sensor (S 1 ), by means of a first signal processing block (V 1 ), generating an alternating voltage signal (xs) from a second sensor output signal (xs 2 ), which is generated by the second current sensor (S 2 ), by means of a second signal processing block (V 2 ), generating a compensating current (Ik), which feeds the compensating coil (Ak), from the alternating voltage signal (x