Photovoltaic inverter and method for operating a photovoltaic inverter

The invention claimed is: 1. A photovoltaic inverter ( 2 ) comprising: a DC input ( 3 ) for connection to a DC source ( 4 ), a DC-DC converter ( 9 ) connected to the DC input ( 3 ), an intermediate circuit ( 10 ), a DC-AC converter ( 11 ), an AC disconnector ( 8 ), a control device ( 13 ) connected to the components of the photovoltaic inverter ( 2 ), an AC output ( 5 ) for connection to a supply network ( 6 ), a battery stage ( 16 ) formed by a bidirectional DC-DC converter and connected with the intermediate circuit ( 10 ), a battery connection ( 14 ) for connection to a buffer battery ( 15 ), and a battery switch ( 17 ) for connecting and disconnecting the buffer battery ( 15 ), wherein a switched-mode power supply ( 18 ) is provided, which switched-mode power supply ( 18 ) is connected on the input side to the AC output ( 5 ) and on the output side to the battery stage ( 16 ), wherein the control device ( 13 ) is designed to charge up the intermediate circuit ( 10 ) to a threshold value via the switched-mode power supply ( 18 ) and the battery stage ( 16 ) when the DC source ( 4 ) is deactivated and the buffer battery ( 15 ) is disconnected from the photovoltaic inverter ( 2 ), and then to actuate the AC disconnector ( 8 ) and to connect the photovoltaic inverter ( 2 ) to the supply network ( 6 ), in order to charge up the buffer battery ( 15 ) via the supply network or to compensate reactive power from the photovoltaic inverter ( 2 ) after the connection. 2. The photovoltaic inverter ( 2 ) according to claim 1 , wherein a diode ( 19 ) is arranged on the output side of the switched-mode power supply ( 18 ). 3. The photovoltaic inverter ( 2 ) according to claim 1 , wherein the battery stage ( 16 ) is formed by a boost converter with synchronous rectification with two semiconductor switches ( 21 , 22 ). 4. The photovoltaic inverter ( 2 ) according to claim 3 , wherein the battery stage ( 16 ) is connected to the control device ( 13 ), which is designed to charge the intermediate circuit ( 10 ) with essentially constant power drain from the switched-mode power supply ( 18 ) by allowing the semiconductor switches ( 21 , 22 ) of the boost converter to be activated with a predefined duty cycle (D(t)). 5. The photovoltaic inverter ( 2 ) according to claim 4 , wherein the control device ( 13 ) is connected to a programmable memory ( 20 ). 6. A method for operating a photovoltaic inverter ( 2 ), wherein the photovoltaic inverter ( 2 ) has a DC input ( 3 ) for connection to a DC source ( 4 ), a DC-DC converter ( 9 ) connected to the DC input ( 3 ), an intermediate circuit ( 10 ), a DC-AC converter ( 11 ), an AC disconnector ( 8 ), a control device ( 13 ) connected to the components of the photovoltaic inverter ( 2 ), an AC output ( 5 ) for connection to a supply network ( 6 ), a battery stage ( 16 ) formed by a bidirectional DC-DC converter and connected with the intermediate circuit ( 10 ), and a battery connection ( 14 ) for connection to a buffer battery ( 15 ) via a battery switch ( 17 ), wherein a switched-mode power supply ( 18 ) is supplied by the AC output ( 5 ) and the control device ( 13 ) is designed, when the DC source ( 4 ) is deactivated and the buffer battery ( 15 ) is disconnected from the photovoltaic inverter ( 2 ), to charge the intermediate circuit ( 10 ) via the switched-mode power supply ( 18 ) and the battery stage ( 16 ) up to a threshold value, whereupon the AC disconnector ( 8 ) is actuated and the photovoltaic inverter ( 2 ) is connected to the supply network ( 6 ) and after the connection the buffer battery ( 15 ) is charged up via the supply network or reactive power from the photovoltaic inverter ( 2 ) is compensated. 7. The method according to claim 6 , wherein the intermediate circuit ( 10 ) is charged with constant power via the switched-mode power supply ( 18 ) by the battery stage ( 16 ) being formed by a boost converter with synchronous rectification having two semiconductor switches ( 21 , 22 ), which semiconductor switches ( 21 , 22 ) are activated via a corresponding duty cycle (D(t)). 8. The method according to claim 7 , wherein before charging the intermediate circuit ( 10 ) via the switched-mode power supply ( 18 ), the voltage (U ZK ) on the intermediate circuit ( 10 ) is measured and used as a starting voltage, and the duty cycle (D(t)) is determined as a function of the starting voltage. 9. The method according to claim 6 , wherein the AC disconnector ( 8 ) is actuated when the threshold value of the voltage (U ZK ) of the intermediate circuit ( 10 ) is at least equal to the peak line voltage of the supply network ( 6 ).