Single-fault-tolerant isolation resistance determination in a photovoltaic system

The invention claimed is: 1. A method for a single-fault-tolerant determination of an isolation resistance of a photovoltaic system comprising an inverter and a solar generator connected thereto, wherein the isolation resistance is determined as a function of a test voltage drop in a resistor network, wherein the resistor network is connected to a variable voltage source by way of a first terminal, to a first pole of the solar generator by way of a second terminal and to a ground terminal of the inverter via an isolation relay by way of a third terminal, wherein a capacitor is disposed between the ground terminal and the first pole of the solar generator, the method comprising: a) applying a first Direct Current (DC) voltage value to the first terminal when the isolation relay is closed using the variable voltage source; b) applying a second DC voltage value to the first terminal when the isolation relay is closed using the variable voltage source; c) generating an Alternating Current (AC) voltage at the first terminal using the variable voltage source when the isolation relay is closed; d) generating the AC voltage at the first terminal using the variable voltage source when the isolation relay is open; and e) testing a function of the isolation relay by comparing an amplitude of the test voltage between the acts c) and d). 2. The method as claimed in claim 1 , further comprising determining the isolation resistance as a function of a difference in a determined test voltage between acts a) and b). 3. The method as claimed in claim 1 , wherein the acts are carried out while the inverter is separated from a grid. 4. The method as claimed in claim 1 , wherein the variable voltage source comprises an inverter bridge of the inverter, wherein the inverter bridge is disposed between a first pole and a second pole of the solar generator, and a mid point of the inverter bridge is connected to the first terminal via a grid filter. 5. The method as claimed in claim 4 , wherein the first DC voltage value is applied to the first terminal of the resistor network by a connection with the first pole and the second DC voltage value is applied to the first terminal of the resistor network by a connection with the second pole. 6. The method as claimed in claim 1 , wherein the AC voltage is generated with a grid frequency at the first terminal. 7. The method as claimed in claim 1 , wherein the method is carried out in the following sequence: act d), followed by act c), followed by act a), followed by act b). 8. The method as claimed in claim 1 , wherein the method is carried out again if the test of the function of the isolation relay leads to inadmissible results. 9. The method as claimed in claim 1 , further comprising generating a fault signal in the case of a negative function test or in the case of an isolation resistance that has been determined as inadmissibly below a threshold. 10. The method as claimed in claim 1 , wherein the test voltage is determined as a voltage drop across a resistor connected to the first pole of the solar generator. 11. The method as claimed in claim 1 , wherein the first terminal is connected to the third terminal via a limiting resistor. 12. An inverter for a single-fault-tolerant determination of an isolation resistance of a photovoltaic system comprising a solar generator connected to the inverter, the inverter being configured to determine the isolation resistance as a function of a test voltage drop in a resistor network of the inverter, wherein the resistor network is connected to a variable voltage source of the inverter by way of a first terminal, to a first pole of the solar generator by way of a second terminal and to a ground terminal of the inverter via an isolation relay by way of a third terminal, wherein a capacitor is disposed between the ground terminal and the second terminal, the inverter being configured to: a) apply a first Direct Current (DC) voltage value to the first terminal when the isolation relay is closed using the variable voltage source; b) apply a second DC voltage value to the first terminal when the isolation relay is closed using the variable voltage source; c) generate an Alternating Current (AC) voltage at the first terminal using the variable voltage source when the isolation relay is closed; d) generate the AC voltage at the first terminal using the variable voltage source when the isolation relay is open; and e) test a function of the isolation relay by comparing an amplitude of the test voltage between the acts c) and d).