Device and method for detecting a fault current in a photovoltaic installation, and photovoltaic inverter comprising the device

What is claimed is: 1. A detection device configured to detect a fault current (I fault ) at a PV generator and/or at DC lines of a PV installation assigned to the PV generator, wherein the PV generator has at least a first PV string and a second PV string, which are connected via in each case two DC lines to a PV inverter of the PV installation, wherein the detection device has at least one current transformer and an evaluation circuit connected to the at least one current transformer, wherein the current transformer comprises a current transformer jointly used by the first PV string and the second PV string, wherein a measurement signal of the jointly used current transformer represents a difference between a first summation current (I sum,1 ) flowing from the first PV string toward a ground potential (PE) and a second summation current (I sum,2 ) flowing from the second PV string toward the ground potential (PE), and wherein the fault current (I fault ), when it occurs, is a part of the first summation current (I sum,1 ) and/or a part of the second summation current (I sum,2 ). 2. The detection device according to claim 1 , wherein the jointly used current transformer comprises a jointly used toroidal current transformer through which the two DC lines of the first PV string and the two DC lines of the second PV string pass for detection of the measurement signal. 3. The detection device according to claim 2 , wherein the two DC lines of the first PV string are arranged relative to one another such that, during a normal operation of the PV installation, a DC current (I Str,1 ) flowing therein passes through the toroidal current transformer in two opposite directions, and wherein the two DC lines of the second PV string are arranged relative to one another such that, during the normal operation of the PV installation, a DC current (I Str,2 ) flowing therein passes through the toroidal current transformer in two opposite directions, and wherein a DC line connected to a positive pole of the first PV string is arranged relative to a DC line connected to a positive pole of the second PV string such that, during the normal operation of the PV installation, the DC currents (I Str,1 , I Str,2 ) in the DC lines assigned to the positive poles pass through the toroidal current transformer in opposite directions. 4. The detection device according to claim 3 , wherein the first PV string comprises a combination of two PV substrings having DC lines, the DC lines of which are arranged relative to one another such that, during the normal operation of the PV installation, the DC currents in the DC lines assigned to the positive poles of the PV substrings pass through the toroidal current transformer in a same direction. 5. The detection device according to claim 4 , wherein the first PV substring is configured such that a nominal power assigned thereto is at least 50% smaller than a nominal power of the second PV substring. 6. The detection device according to claim 1 , wherein the current transformer is configured for a maximum current value which corresponds to a value of at most 50% of the greater of the two values from among a first leakage current (I leak,1 ) and a second leakage current (I leak,2 ), wherein the first leakage current (I leak,1 ) characterizes a current flowing from the first PV string toward the ground potential (PE) in normal operation of the PV installation, and the second leakage current (I leak,2 ) characterizes a current flowing from the second PV string toward the ground potential (PE) in normal operation of the PV installation. 7. The detection device according to claim 1 , wherein the PV installation comprises a number of PV strings, wherein the number is greater than two, wherein the detection device has an equal number of toroidal current transformers as the number of PV strings connected to the evaluation circuit of the detection device, wherein for a detection of the measurement signal, each of the toroidal current transformers is passed through by the DC lines of two different PV strings, and wherein the DC lines of each PV string each pass through two different ones of the toroidal current transformers. 8. A method for detecting a fault current (I fault ) on a PV installation, wherein a PV generator of the PV installation has at least a first PV string and a second PV string, which are connected via in each case two DC lines to a PV inverter of the PV installation, with a detection device that comprises at least one current transformer and an evaluation circuit connected to the at least one current transformer, wherein the current transformer comprises a current transformer jointly used by the first PV string and the second PV string, wherein a measurement signal of the jointly used current transformer represents a difference between a first summation current (I sum,1 ) flowing from the first PV string toward the ground potential (PE) and a second summation current (I sum,2 ) flowing from the second PV string toward the ground potential (PE), and wherein the fault current (I fault ), when it occurs, is a part of the first summation current (I sum,1 ) and/or a part of the second summation current (I sum,2 ), the method comprising: detecting a measurement signal of the at least one current transformer, wherein the measurement signal represents a difference between a first summation current (I sum,1 ) flowing from the first PV string toward the ground potential (PE) and a second summation current (I sum,2 ) flowing from the second PV string toward the ground potential (PE); and signaling a fault current (I fault ) when the detected measurement signal exceeds a first threshold value (S TH,1 ). 9. The method according to claim 8 , wherein the signaling of the fault current (I fault,1 ) occurs only when the measurement signal exceeds the first threshold value (S TH,1 ) with an abrupt increase, which represents a change in a difference between the first summation current (I sum,1 ) and the second summation current (I sum,2 ) of at least 10 mA. 10. The method according to claim 8 , further comprising: determining a resistive current component of the measurement signal detected by the at least one current transformer; and signaling the fault current (I fault ) only when the measurement signal detected by the current transformer has an abrupt change in the resistive current component by at least 10 mA when the first threshold value (S TH,1 ) is exceeded. 11. The method according to claim 8 , wherein the PV generator of the PV installation has a number of PV strings, wherein the number is greater than two, and wherein the detection device has an equal number of current transformers, further comprising determining a PV string causing the fault current by two of the PV strings in each case jointly using one of the current transformers for the detection of the measurement signal, and wherein each of the PV strings uses two of the current transformers in each case. 12. The method according to claim 8 , wherein, in response to the signaling of the fault current (I fault ), isolating the PV generator or only the PV string of the PV generator causing the fault current (I fault ). 13. The method according to claim 8 , wherein DC lines of a first group of PV strings and an equally sized second group of PV strings pass through a shared toroidal current transformer such that each of the PV strings of the first group of PV strings has a first summation current (I sum,1 ) that flows toward a ground potential (PE) and is at least approximately compensated by a second summation current (I sum,2 ) of a corresponding PV string of the second group flowing toward the ground potentia