Step-down converter and circuit arrangement therewith

What is claimed is: 1 . A step-down converter ( 1 ), comprising: a first and a second input connection ( 10 , 12 ) wherein the first input connection ( 10 ) is intended to be connected to a first DC voltage input potential, and the second input connection ( 12 ) is intended to be connected to a second DC voltage input potential that is lower than the first DC voltage input potential; a first and second output connection ( 14 , 16 ) wherein the first output connection ( 14 ) is intended to have a first DC voltage output potential and the second output connection ( 16 ) is intended to have a second DC voltage output potential that is lower than the first DC voltage output potential; a first, upper and a second, lower step-down converter element ( 2 , 3 ) wherein the first step-down converter element ( 2 ) has a first input capacitor ( 20 ), the first capacitor connection which is connected to the first input connection ( 10 ) and the second capacitor connection of which is connected to the second output connection ( 16 ); wherein a first series connection, further comprises: a first switch ( 22 ) and a first diode ( 24 ) connected in parallel with the first input capacitor ( 20 ); a first coil input of a first coil ( 26 ) is connected to the center tap between the first switch ( 22 ) and the first diode ( 24 ) the first coil output of said first coil being connected to the first output connection ( 14 ); the second step-down converter element ( 3 ) has a second input capacitor ( 30 ); and the first capacitor connection is connected to the first output connection ( 14 ) and the second capacitor connection is connected to the second input connection ( 12 ); wherein a second series connection, further comprises: a second diode ( 32 ) and a second switch ( 34 ) is connected in parallel with the second input capacitor ( 30 ); a second coil input of a second coil ( 36 ) is connected to the center tap between the second diode ( 32 ); and the second switch ( 34 ) and the second coil output of said second coil being connected to the second output connection ( 16 ). 2 . The step-down converter, according to claim 1 , wherein: the first switch ( 22 ) is in the form of a semiconductor switch; and wherein the semiconductor switch of the first switch ( 22 ) is in the form of an IGBT ( 224 ) with an antiparallel-connected diode ( 226 ) or in the form of a MOS-FET ( 228 ). 3 . The step-down converter, according to claim 2 , wherein: the second switch ( 34 ) is in the form of a semiconductor switch; and wherein the semiconductor switch of the second switch ( 34 ) is in the form of an IGBT with an antiparallel-connected diode or in the form of a MOS-FET. 4 . The step-down converter, according to claim 1 , wherein: the first switch ( 22 ) is in the form of a series connection, further comprising: at least two first semiconductor switch elements ( 220 , 222 ); and the first diode ( 24 ) is in the form of a series connection having the same number of first diode elements ( 240 , 242 ). 5 . The step-down converter, according to claim 4 , wherein: a first intermediate capacitor ( 210 ) is connected between respective center taps between adjacent first semiconductor switch elements ( 220 , 222 ) and adjacent first diode elements ( 240 , 242 ). 6 . The step-down converter, according to claim 5 , wherein: the second switch ( 34 ) is in the form of a series connection having at least two second semiconductor switch elements ( 340 , 342 ); and and the second diode ( 32 ) is in the form of a series connection having the same number of second diode elements ( 320 , 322 ). 7 . The step-down converter, according to claim 6 , wherein: a second intermediate capacitor ( 310 ) is connected between respective center taps between adjacent semiconductor switch elements ( 340 , 342 ) and adjacent diode elements ( 320 , 322 ). 8 . The step-down converter, according to claim 7 , wherein: an output capacitor ( 28 , 38 ) is connected between the first and second output connection ( 14 , 16 ). 9 . A circuit arrangement ( 6 ), comprising: a step-down converter ( 1 ) according to claim 1 , wherein: a DC voltage source ( 60 , 62 ) has a load ( 64 ); and the DC voltage source ( 60 , 62 ) is connected to the first and to the second input connection ( 10 , 12 ) and the load ( 64 ) is connected to the first and second output connection ( 14 , 16 ). 10 . The circuit arrangement, according to claim 9 , wherein: the load ( 64 ) is in the form of an electrolysis apparatus that produces gaseous hydrogen. 11 . The circuit arrangement, according to claim 10 , wherein: the DC voltage source ( 60 ) is a photovoltaic installation. 12 . The circuit arrangement, according to claim 10 , wherein: the DC voltage source ( 62 ) is in the form of a rectifier circuit. 13 . A method for operating a step-down converter ( 1 ), according to claim 7 , wherein: adjacent semiconductor switch elements are controlled out of phase with one another. 14 . A method for operating a step-down converter ( 1 ), according to claim 1 , wherein: the first switch ( 22 ) is operated half a phase length out of phase with the second switch ( 34 ). 15 . The method, according to claim 14 , wherein: an output voltage (Vo) between the output connections ( 14 , 16 ) is at most 25% of an input voltage (Vi) between the input connections ( 10 , 12 ).