Method and assembly for operating synchronous motors

The invention claimed is: 1. A method for operating a synchronous machine via a three-phase power controller including three semiconductor controllers connected to a three-phase power supply, the method comprising: providing a microcontroller having a processor, wherein the processor determines a phase difference between magnet-wheel voltage of the synchronous machine and voltage of the three-phase power supply; determines a rotational speed of the rotor of the synchronous machine based on a position angle of the rotor; determines a phase position of the three-phase power supply; determines at least some of stator currents of the synchronous machine; calculates a torque curve for the synchronous machine for a definable period of time in the event of activation of each of the semiconductor controllers having thyristors connected in anti-parallel while taking into account the determined values for phase difference between at least two phases controlled by the semiconductor controllers, the rotational speed, the stator current and the phase position of the three-phase power supply, and calculates another torque curve for the synchronous machine for a definable period of time in the event of activation of less than all of the semiconductor controllers while taking into account the determined values for phase difference between at least two phases controlled by the at least two semiconductor controllers, the rotational speed, the stator current and the phase position of the three-phase power supply; determines a switching time point based upon the calculation, wherein the at least two semiconductor controllers are activated at the switching time point; and triggers the at least two semiconductor controllers based on the determined switching time point. 2. The method of claim 1 , wherein the processor ascertains whether a present point in time is employed as a switching time point based on the calculation. 3. The method of claim 2 , wherein the processor determines a decision characteristic number from the calculation and comparing the decision characteristic number with a threshold value to ascertain the switching time point. 4. The method of claim 2 , wherein included in the calculation and taken into consideration is a maximum current occurring in the period of time which results on activation of the least two semiconductor controllers for the ascertained phase difference, phase position, stator current and rotational speed. 5. The method of claim 2 , wherein the processor performs an advance calculation of the torque curves both for the activation of all semiconductor controllers and for the activation of respective three pairs of thyristors in each of the semiconductor controllers, each comprising two semiconductor controllers. 6. The method of claim 2 , wherein the processor determines a maximum torque value based upon the phase difference and the rotational speed and the maximum torque value is taken into consideration such that no activation of the semiconductor controllers is carried out if the advance calculation results in an expected torque above the maximum torque value. 7. The method of claim 1 , wherein the processor determines a decision characteristic number from the calculation and comparing the decision characteristic number with a threshold value to ascertain the switching time point. 8. The method of claim 7 , wherein included in the calculation and taken into consideration is a maximum current occurring in the period of time which results on activation of the least two semiconductor controllers for the ascertained phase difference, phase position, stator current and rotational speed. 9. The method of claim 7 , wherein the processor performs an advance calculation of the torque curves both for the activation of all semiconductor controllers and for the activation of respective pairs of thysistors in each of the semiconductor controllers, each comprising two semiconductor controllers. 10. The method of claim 7 , wherein the processor determines a maximum torque value based upon the phase difference and the rotational speed and the maximum torque value is taken into consideration such that no activation of the semiconductor controllers is carried out if the advance calculation results in an expected torque above the maximum torque value. 11. The method of claim 1 , wherein included in the calculation and taken into consideration is a maximum current occurring in the period of time which results on activation of the least two semiconductor controllers for the ascertained phase difference, phase position, stator current and rotational speed. 12. The method of claim 1 , wherein the processor performs an advance calculation of the torque curves both for the activation of all semiconductor controllers and for the activation of respective pairs of thyristors in each of the semiconductor controllers, each comprising two semiconductor controllers. 13. The method of claim 1 , wherein the processor determines a maximum torque value based upon the phase difference and the rotational speed, and the maximum torque value is taken into consideration such that no activation of the semiconductor controllers is carried out if the advance calculation results in an expected torque above the maximum torque value. 14. An assembly for operating a synchronous machine, comprising: a three-phase power controller, connectable to a three-phase power supply and including three semiconductor controllers for respective phases of the three-phase power supply, each of the semiconductor controllers having two thyristors connected in anti-parallel; a microcontroller configured to determine a phase difference between magnet-wheel voltage of the synchronous machine and voltage of the three-phase power supply; determine rotational speed of the rotor of the synchronous machine; determine phase position of the three-phase power supply; and determine at least some of the stator currents wherein the microcontroller is further configured to calculate, from the determined phase difference, rotational speed, stator current and phase position, a torque curve for the synchronous machine for a definable period of time on activation of each of the semiconductor controllers and, based upon the calculation, to ascertain a switching time point at which the semiconductor controllers are activated and to calculate another torque curve for the synchronous machine for a definable period of time in the event of activation of less than all of the semiconductor controllers while taking into account the determined values for phase difference between at least two phases controlled by the at least two semiconductor controllers, the rotational speed, the stator current and the phase position of the three-phase power supply.