Method of operating on-load tap changer

The invention claimed is: 1. A method of operating an on-load tap changer connected on an upstream side by an input line with a control transformer and a downstream side to an output line, the tap changer comprising the steps of: providing a switching module having a first load branch having an upstream semiconductor switch connected to the input line and a downstream semiconductor switch connected between the upstream semiconductor switch and the output line, a second load branch parallel to the first load branch and having an upstream semiconductor switch connected to the input line and a downstream semiconductor switch connected between the upstream semiconductor switch of the second load branch and the output line, and a sub-winding of the control transformer connected between the first branch between the respective upstream and downstream switches thereof and the second branch between the respective upstream and downstream switches thereof; whereby in a first position the upstream switch of the first branch is closed and the downstream switch of the first branch is open while the upstream switch of the second branch is open and the downstream switch of the second branch is closed for current flow from the input line to the output line in a first direction through the sub-winding; in a second position the upstream switch of the first branch is open and the downstream switch of the first branch is closed while the upstream switch of the second branch is closed and the downstream switch of the second branch is open for current flow from the input line to the output line in a second direction opposite the first direction through the sub-winding; in a third position both switches of one of the load branches are closed and there is no current flow through the sub-winding; for setting an intermediate position, switching back and forth between the third position and the first position by switching one of the switches that is open in the first position back and forth between open and closed; or switching back and forth between the third position and the second position by switching one of the switches that is open in the second position back and forth between open and closed. 2. The method defined in claim 1 , wherein each semiconductor switch consists of a respective first IGBT and second IGBT that are connected anti-serially with respect to one another, the first IGBT and the second IGBT are each provided with an inverse diode in such a way that an anode of one inverse diode is connected with an emitter terminal and a cathode of an inverse diode is connected with a collector terminal of the first IGBT and the second IGBT and the semiconductor switches of the first load branch and the second load branch are selectably switchable off. 3. The method defined in claim 1 , wherein the on-load tap changer consists of a first switching module, a second switching module and a third switching module and the sub-windings of the switching modules have different winding ratios with respect to one another. 4. The method defined in claim 3 , wherein a winding ratio of the sub-windings is 9:3:1. 5. The method according to claim 1 , further comprising the steps of: in the case of a reducing setting, windings of the sub-winding are subtracted from a control winding, in the case of an increasing setting, windings of the sub-winding are added to the control winding, and in the case of a nominal setting, the sub-winding is left out completely. 6. The method according to claim 1 , wherein the semiconductor switches are actuated on an active side of the switching module and the semiconductor switches remain in a fixed switching state on a passive side of the switching module. 7. The method defined in claim 1 , wherein each semiconductor switch consists of a respective first IGBT and second IGBT that are connected anti-serially with respect to one another, the first IGBT and the second IGBT are each provided with an inverse diode in such a way that an anode of one inverse diode is connected with an emitter terminal and a cathode of an inverse diode is connected with a collector terminal of the first IGBT and the second IGBT, the IGBTs connected with the alternately current-conducting inverse diodes of the respective active side, of the upstream semiconductor switches or downstream semiconductor switches are constantly blocking, of the two alternately current-conducting IGBTs of the active side, one is always conducting and that IGBT whose collector terminal is connected with a negative pole and the emitter terminal is connected with a positive pole of the sub-winding, of the two alternately current-conducting IGBTs of the active side, one is cycled and that IGBT whose collector terminal is connected with the positive pole and whose emitter terminal with the negative pole of the sub-winding, and at a passive side, one semiconductor switch is always blocked and the other semiconductor switch is always conducting. 8. The method defined in claim 7 , further comprising the step, in case of change in the direction of the current flow and the orientation of the positive pole and the negative pole, of: detecting at the sub-winding which IGBTs of the semiconductor switch on the active side are cycled or switched to be conducting. 9. The method defined in claim 8 , further comprising the step, in case of change in the direction of the current flow and the orientation of the positive pole and the negative pole, of: detecting at the sub-winding which IGBTs of the semiconductor switch on the passive side are switched to be conducting or non-conducting. 10. The method defined in claim 9 , further comprising the step, in case of change in direction of the current flow and the orientation of the positive pole and the negative pole, of: determining the active side and the passive side at the sub-winding.