Method for monitoring a ground resistance of an electric installation

The invention claimed is: 1. A method for monitoring a ground resistance (R PE ) of an electric installation ( 2 ) which consists of an ungrounded stationary alternating-voltage power supply system ( 4 ) having at least one active conductor (L 1 , L 2 , L 3 ) and of a consumer ( 8 ) connected to the stationary alternating-voltage power supply system ( 4 ) via a supply line ( 6 ), the ungrounded stationary alternating-voltage power supply system ( 4 ) being supplied by a power transformer ( 12 ) and the consumer ( 8 ) comprising a leakage capacitor (C e ) connected to a protective conductor (PE), the method comprising the following steps: generating a measuring signal (U s ) having a measuring frequency by means of a measuring-signal generator ( 16 ), capacitively coupling the measuring signal (U s ) in the stationary alternating-voltage power supply system ( 4 ) between the active conductor (L 1 , L 2 , L 3 ) and ground via a coupling circuit having a coupling capacitor (C s ) and having a series resistance (R shunt ), measuring a complex-valued first measuring current (I m0 ) in the coupling circuit when the consumer ( 8 ) is switched off, detecting a complex-valued first measuring voltage (U m0 ) between the active conductor (L 1 , L 2 , L 3 ) and ground when the consumer ( 8 ) is switched off, determining a first complex-valued conductance value (Y m0 ) from the first measuring current (I m0 ) and the first measuring voltage (U m0 ), measuring a second complex-valued measuring current (I m1 ) in the coupling path when the consumer ( 8 ) is switched on, measuring a second complex-valued measuring voltage (U m1 ) between the active conductor (L 1 , L 2 , L 3 ) and ground when the consumer ( 8 ) is switched on, determining a second complex-valued conductance value (Y m1 ) from the second measuring current (I m1 ) and the second measuring voltage (U m1 ), computing a complex-valued load-side conductance value (Y v ) by forming a difference between the second conductance value (Y m1 ) and the first conductance value (Y m0 ), computing a complex-valued load-side impedance (Z v ) from the inverse of the load-side conductance value (Y v ), computing a sum ground resistance (R′ PE ) by subtracting the series resistance (R shunt ) and loss resistances (R ESR ) of the leakage capacitor (C e ) and the coupling capacitor (C a ) from the real part of the complex-valued load-side impedance (Z v ), generating an alarm signal if the sum ground resistance (R′ PE ) exceeds a ground resistance threshold (R PE1im ). 2. The method according to claim 1 , wherein the first and second measuring current (I m0 , I m1 ) are measured by tapping voltage at the series resistance (R shunt ) and at a current measuring circuit ( 50 ) which is parallel to the series resistance (R shunt ) and is realized as a high-pass filter having a current measuring capacitor (C 1 ) and a current measuring resistance (R 1 ). 3. The method according to claim 1 , wherein the first and second measuring voltage (U m0 , U m1 ) are detected by conducting a measurement by means of a capacitive voltage measuring circuit ( 30 ) which is realized as a high-pass filter having a voltage measuring capacitor (C h ) and a voltage measuring resistance (R 2 ). 4. The method according to claim 1 , wherein the first and second measuring voltage (U m0 , U m1 ) are detected by using a known measuring-signal generator voltage of the measuring-signal generator ( 16 ). 5. The method according to claim 1 , wherein the first conductance value (Y m0 ) and second conductance value (Y m1 ) are determined by computing Fourier coefficients (F{ }) of the first and second measuring current (I m0 , I m1 ) and the first and second measuring voltage (U m0 , U m1 ). 6. The method according to claim 1 , wherein, when the method is applied in a 3-phase ungrounded stationary alternating-voltage power supply system ( 4 ), the measuring signal (U s ) is coupled in such a manner by means of the coupling circuit that a coupling capacitor (C a ) is switched in the coupling circuit for each active conductor (L 1 , L 2 , L 3 ) and that the coupling circuit has the series resistance (R shunt ) as a shared coupling resistance. 7. The method according to claim 1 , wherein, when the method is applied in a 3-phase ungrounded stationary alternating-voltage power supply system ( 4 ) with a power converter ( 70 ), the sum ground resistance (R′ PE ) is computed by additionally subtracting differential diode resistances (r i ) of the power converter ( 70 ) and the loss resistances of power-converter leakage capacitors (C g ). 8. The method according to claim 1 , wherein the measuring frequency is switched between two measuring frequencies. 9. The method according to claim 1 , wherein the measuring frequency of the measuring signal (U s ) preferably ranges from 80 Hz to 150 kHz.