Method for extending a voltage range of a rectifier, rectifier for carrying out the method, and electrolysis system

What is claimed is: 1 . A method for extending a DC voltage range of a rectifier circuit for the supply, from an AC grid, of a DC load which is connected to a DC rectifier output of the rectifier circuit, wherein an AC rectifier input of the rectifier circuit is connected via a grid connection point to the AC grid, wherein the rectifier circuit comprises an AC/DC converter having an AC input and a DC output, wherein the AC/DC converter comprises a converter circuit having semiconductor switches and freewheeling diodes connected in an antiparallel arrangement thereto, wherein an inductance is connected between the AC input of the AC/DC converter and the grid connection point, the method comprising: setting a desired DC operating voltage U DC,Soll on the DC output of the AC/DC converter or on the DC rectifier output, or both, by an actuation of semiconductor switches of the AC/DC converter, wherein, when the desired DC operating voltage U DC,Soll lies below a value of an amplitude Û 4 of an alternating (AC) voltage on the AC input of the AC/DC converter, the semiconductor switches of the AC/DC converter are actuated for an exchange of reactive power Q 1 (t) with the AC grid, which has a voltage-lowering effect upon the amplitude Û 4 of the AC voltage at the AC input of the AC/DC converter, such that the amplitude Û 4 approaches the desired DC operating voltage U DC,Soll , and wherein the exchange of the reactive power Q 1 (t) with the AC grid is executed during or shortly before an electrical connection and/or an electrical isolation of the DC load to or from the rectifier circuit. 2 . The method as claimed in claim 1 , wherein the reactive power Q 1 (t) which is exchanged between the AC/DC converter and the AC grid, to a predominant proportion, is displacement reactive power. 3 . The method as claimed in claim 1 , wherein the inductance comprises a filter reactor arranged between the AC/DC converter and the AC rectifier input, or a transformer winding on a secondary side of a transformer that is operably coupled to the rectifier circuit, or both, the filter reactor and the transformer winding on the secondary side of the transformer. 4 . The method as claimed in claim 1 , wherein, if the desired DC operating voltage U DC,Soll achieves or exceeds a voltage threshold value U TH , the semiconductor switches of the AC/DC converter are actuated for an exchange of a further reactive power Q 2 (t) with the AC grid, such that the exchange of the further reactive power Q 2 (t) has a voltage-increasing effect upon the amplitude Û 4 at the AC input of the AC/DC converter, such that the amplitude Û 4 approaches the desired DC operating voltage U DC,soll . 5 . The method as claimed in claim 4 , wherein the exchange of the further reactive power Q 2 (t) comprises determining a reactive power target value, based upon a known voltage variation characteristic u(Q) as a function of a reactive power Q exchanged between the AC input of the AC/DC converter and the grid connection point of the AC grid. 6 . The method as claimed in claim 1 , wherein the exchange of the reactive power Q 1 (t) comprises determining a reactive power target value, based upon a known voltage variation characteristic u(Q) as a function of a reactive power Q exchanged between the AC input of the AC/DC converter and the grid connection point of the AC grid. 7 . The method as claimed in claim 4 , further comprising: detecting an actual value of a DC voltage U DC,4 present on the DC output of the AC/DC converter; comparing the detected actual value with the desired DC operating voltage U DC,soll ; and regulating an exchange of the further reactive power Q 2 (t) using a regulating circuit which is connected to a control circuit, such that the actual value of the DC voltage U DC,4 present on the DC output of the AC/DC converter approaches the desired DC operating voltage U DC,Soll . 8 . The method as claimed in claim 1 , further comprising: detecting an actual value of a DC voltage U DC,4 present on the DC output of the AC/DC converter; comparing the detected actual value with the desired DC operating voltage U DC,Soll ; and regulating an exchange of the reactive power Q 1 (t) using a regulating circuit which is connected to the control circuit, such that the actual value of the DC voltage U DC,4 present on the DC output of the AC/DC converter approaches the desired DC operating voltage U DC,Soll . 9 . The method as claimed in claim 4 , wherein the exchange of the reactive power Q 1 (t) or the exchange of the further reactive power Q 2 (t), or both, generates a variation in the amplitude Û 4 on the AC input of the AC/DC converter of at least 10% in relation to a nominal value of the amplitude Û 4 . 10 . The method as claimed in claim 1 wherein, under specified marginal conditions, and during a state of the AC grid in which an amplitude Û 7 of the alternating voltage on the AC rectifier input deviates from its nominal value, executing an exchange of a third reactive power Q 3 (t) between the AC/DC converter and the AC grid, such that a resulting effect on the amplitude Û 7 of the alternating voltage on the AC rectifier input counteracts a deviation thereof from its nominal value. 11 . The method as claimed in claim 1 , wherein the exchange of the reactive power Q 1 (t) between the AC/DC converter and the AC grid is only executed when the desired DC operating voltage U DC,soll , in addition to the value of the amplitude Û 4 , also undershoots an average rectified value of an alternating voltage at the amplitude Û 4 . 12 . An actively-controlled rectifier circuit configured to supply a DC load from an AC grid having an AC voltage, comprising: an AC rectifier input comprising a plurality of input terminals configured to connect to the AC grid, and a DC rectifier output comprising two output terminals configured to connect to the DC load, an AC/DC converter comprising an AC-side AC input that is connected to the AC rectifier input, a DC-side DC output that is connected to the DC rectifier output, and a converter circuit arranged between the AC-side AC input and the DC-side DC output, wherein the converter circuit of the AC/DC converter comprises actively controllable semiconductor switches and freewheeling diodes connected in an antiparallel arrangement thereto, and wherein the AC/DC converter is configured for an exchange of reactive power Q 1,2 (t) with the AC grid, and wherein the rectifier circuit further comprises a control circuit configured to control the semiconductor switches of the AC/DC converter, wherein the rectifier circuit is configured to: set a desired DC operating voltage U DC,Soll on the DC-side DC output of the AC/DC converter or on the DC rectifier output, or both, by an actuation of semiconductor switches of the AC/DC converter, wherein, when the desired DC operating voltage U DC,Soll lies below a value of an amplitude Û 4 of an alternating voltage on the AC-side AC input of the AC/DC converter, the semiconductor switches of the AC/DC converter are actuated for an exchange of reactive power Q 1 (t) with the AC grid, which has a voltage-lowering effect upon the amplitude Û 4 of the AC voltage at the AC input of the AC/DC converter, such that the amplitude Û 4 approaches the desired DC operating voltage U DC,Soll , and wherein the exchange of the reactive power Q 1 (t) with the AC grid is executed during or shortly before an electrical connection or an electrical isolation of the DC load to or from the rectifier circuit. 13 . The rectifier circuit as claimed in claim 12 , wherein the rectifier circuit comprises a regulating circuit con