Energy storage device having a dc voltage supply circuit and method for providing a dc voltage from an energy storage device

1 . A system ( 200 ; 300 ; 400 ) comprising an energy storage device ( 1 ) and a DC voltage supply circuit ( 8 ), wherein the energy storage device ( 1 ) has at least two energy supply branches (Z) which are coupled at a first output in each case to at least one output terminal ( 1 a , 1 b ) of the energy storage device ( 1 ) for generating an AC voltage at the output terminals ( 1 a , 1 b ) and are coupled at a second output to a common busbar ( 2 c ) wherein each of the energy supply branches (Z) has a multiplicity of series-connected energy storage modules ( 3 ) which in each case comprise: an energy storage cell module ( 5 ) having at least one energy storage cell ( 5 a , 5 k ); and a coupling device ( 7 ) having a coupling bridge circuit composed of coupling elements ( 7 a , 7 b , 7 c , 7 d ) wherein the coupling elements ( 7 a , 7 b , 7 c , 7 d ) are designed selectively to switch the energy storage cell module ( 5 ) into the respective energy supply branch (Z) or to bypass it in the energy supply branch (Z), and wherein the DC voltage supply circuit ( 8 ) has: a bridge circuit ( 9 ) having a multiplicity of first feed terminals ( 8 a , 8 b ) which are in each case coupled to one of the output terminals ( 1 a , 1 b ) of the energy storage device ( 1 ); two feed nodes ( 14 a , 14 b ), at least one of which is coupled to the bridge circuit ( 9 ); and a module tapping circuit ( 6 ), which has at least one module switching branch (A) having a commutation diode ( 16 ), wherein each of the at least one module switching branches (A) connects a coupling node (K) between two energy storage modules ( 3 ) of one of the energy supply branches (Z) to a feed node ( 14 a , 14 b ) in a switchable manner. 2 . The system ( 200 ; 300 ; 400 ) as claimed in claim 1 , characterized in that at least one of the at least one module switching branches (A) has, in addition to the commutation diode ( 16 ), a module coupling switch ( 17 ) connected in series with said commutation diode ( 16 ). 3 . The system ( 200 ; 300 ; 400 ) as claimed in claim 1 , furthermore comprising: a DC-DC converter ( 14 ) coupled between the first feed node ( 14 a ) and the second feed node ( 14 b ). 4 . The system ( 200 ; 300 ; 400 ) as claimed in claim 3 , wherein the DC-DC converter ( 14 ) has a step-up converter or a forward converter. 5 . The system ( 200 ; 300 ; 400 ) as claimed in claim 1 , wherein the DC voltage supply circuit ( 8 ) has two charging circuit terminals ( 8 j , 8 k ) and a charging circuit, wherein the charging circuit in the presence simultaneously of the DC-DC converter ( 14 ) is coupled in series with the DC-DC converter ( 14 ) via the two charging circuit terminals ( 8 j , 8 k ) and wherein the charging circuit in the absence of the DC-DC converter ( 14 ) is directly connected to the feed nodes ( 14 a ; 14 b ) by the two charging circuit terminals ( 8 j ; 8 k ) and wherein the charging circuit is designed to provide a charging DC voltage for the energy storage cell modules ( 5 ) of the energy storage device ( 1 ). 6 . The system ( 200 ; 300 ; 400 ) as claimed in claim 1 , wherein the bridge circuit ( 9 ) has a multiplicity of first bridge branches (A) having a diode ( 16 ) or the series circuit formed by a diode ( 16 ) and a bridge coupling switch ( 17 ) which are coupled in each case between the feed node ( 14 a ; 14 b ) connected to the bridge circuit and one of the multiplicity of first feed terminals ( 8 a , 8 b ). 7 . The system ( 200 ; 300 ; 400 ) as claimed in claim 1 , wherein the bridge circuit has a further first feed terminal ( 8 c ), which is connected to the output terminal ( 1 c ) of the energy storage device ( 1 ) and thus to the busbar ( 2 c ) thereof. 8 . The system ( 200 ; 300 ; 400 ) as claimed in claim 1 , wherein the bridge circuit ( 9 ) has both a multiplicity of first feed terminals ( 8 a , 8 b , 8 c ) and a multiplicity of second feed terminals ( 8 d , 8 e , 8 f ), which are coupled in each case to one of the output terminals ( 1 a , 1 b ) or the busbar ( 2 c ) of the energy storage device ( 1 ). 9 . The system ( 200 ; 300 ; 400 ) as claimed in claim 7 , wherein the bridge circuit ( 9 ) has a further bridge switching branch (A), which connects the further first feed terminal ( 8 c ) or the further second feed terminal ( 8 f ) to that one of the two feed nodes ( 14 a ; 14 b ) which is already connected via the bridge circuit ( 9 ) to the first feed terminals ( 8 a ; 8 b ) or to the second feed nodes ( 8 d , 8 e ). 10 . The system ( 200 ; 300 ; 400 ) as claimed in claim 8 , wherein the bridge circuit ( 9 ) has a multiplicity of first bridge branches (A) and a multiplicity of second bridge switching branches (A) having in each case a diode ( 16 ) or a series circuit formed by a diode ( 16 ) and a bridge coupling switch ( 17 ), wherein the first bridge switching branches (A) are connected in each case between one of the multiplicity of first feed terminals ( 8 a ; 8 b ; 8 c ) and the first feed node ( 14 a ), and wherein the second bridge switching branches (A) are connected in each case between one of the multiplicity of second feed terminals ( 8 d ; 8 e ; 8 f ) and the second feed node ( 14 b ), and wherein the direct electrically conductive connection between one of the feed nodes ( 14 a ; 14 b ) and the busbar ( 2 c ) of the energy storage device ( 1 ) is obviated. 11 . The system as claimed in claim 10 , wherein each of the at least one coupling nodes K is connected to an arbitrary feed node ( 14 a ; 14 b ) via a module switching branch (A) or is alternatively connected to each of the two feed nodes ( 14 a ; 14 b ) via a respective module switching branch (A). 12 . The system ( 200 ; 300 ; 400 ) as claimed in claim 1 , wherein each energy supply branch (Z) of the energy storage device ( 1 ) has maximally one coupling node (K), and wherein the number of energy storage modules ( 3 ) in the respective energy supply branches (Z) is identical on both sides of the respective coupling node (K). 13 . The system ( 200 ; 300 ; 400 ) as claimed in claim 1 , furthermore comprising: an n-phase electrical machine ( 2 ) having n phase terminals, coupled to the output terminals ( 1 a , 1 b ) of the energy storage device ( 1 ), wherein n≧1. 14 . The system ( 200 ; 300 ; 400 ) as claimed in claim 13 , wherein the n-phase electrical machine has a led-out winding star point, and wherein said winding star point is connected to the output terminal ( 1 c ) of the energy storage device ( 1 ) and thus to the busbar ( 2 c ) thereof. 15 . A method ( 20 ) for providing a DC voltage from a system ( 200 ; 300 ; 400 ) as claimed in claim 1 , comprising the following steps: determining ( 21 ) the output voltage of the energy supply branches (Z) at the output terminals ( 1 a , 1 b ) of the energy storage device ( 1 ); switching coupling ( 22 ) of at least one coupling node (K) between two energy storage modules ( 3 ) of one of the energy supply branches (Z) to a feed node ( 14 a ; 14 b ) that is connectable to said coupling node via a module switching branch (A) if the determined output voltage of the energy storage device ( 1 ) is lower than the maximum output voltage of an individual energy storage module ( 3 ); operating ( 24 ) the energy storage modules ( 3 ) situated between the coupling nodes (K) and a busbar ( 2 c ) of the energy storage device ( 1 ) in such a way that a potential that differs from the