DE3940569A1 - Polyphase sync. motor DC supply system - has electronic switches for winding phases controlled to one overlap when switching in and out - Google Patents

Abstract

The circuit arrangement has a switch device to connect the winding phases of the armature winding to the mains dc voltage. This device comprises a number of electronic switches each assigned to individual winding phases. Switching logic controls the switches according to the angular position of the sync-motor's rotor. Consecutive winding phases (u,v,w) are switched such that the two switching signals (S1-S6) for the switches (TT-T6) of the phases being switched overlap in time. At least one of the two switching signals in the overlap region is timed so that the average of the current (Iu etc) in the phase being switched in increases whilst in the phase being switched out it decreases. A reference is defined for the phase currents (Iu etc.) ADVANTAGE - Reduced switching loses. Less noise. Radio-frequency interference is less.

Description

State of the art

The invention relates to a circuit arrangement for Operating a multi-phase armature winding Synchronous motor on a DC network in the Preamble of claim 1 defined genus.

In a known circuit arrangement of this type for one four-phase synchronous motor (DE 30 42 819 A1) is from the as Power transistors trained switches Switching device one in series with the Winding phase of here in the stator of the synchronous motor arranged armature winding switched and lies between the a winding phase end and the zero potential. The others The winding phase ends of the armature winding are one Summarized star point, which is connected to a mains switch the plus potential of the mains DC voltage can be connected.  

The commutation logic to control the Circuit in accordance with the rotational position of the preferably permanent magnet excited rotor is through Voltage comparators, through logical links and realized by a ring counter, its parallel Count outputs with the control inputs of the transistors are connected. In the voltage comparators are each the cyclic due to blocked transistors successive winding phases induced voltages compared with each other and then an output signal issued when the in the cyclically following Winding induced voltage is greater than that in the cyclically preceding winding phase Tension. These output signals from the voltage comparators are logical with the counter output signals of the ring counter "AND" linked, in such a way that a switching signal on a monoflop occurs only when the Winding phase with the higher induced voltage cyclically following winding phase by opening the assigned Transistor is current-carrying. The one with the control input this current valve connected output of the ring counter leads here H potential. With the positive edge of the The ring counter becomes the output pulse of the monoflop counted further, so that now H potential at the next Counter output is and the currently open transistor blocked and the cyclically following transistor is opened.

In a likewise known circuit arrangement of type mentioned for a three-phase synchronous motor () shows the commutation logic Switching signal generator with a voltage-frequency converter, one upstream upstream of this and one downstream Start-up of the synchronous motor effective restart unit and a ring counter with three parallel outputs with the control inputs of those connected in star  Winding phases of the armature winding switched on Transistors are connected. The from the switching signal generator generated square pulses are counted on the Counter or clock input of the ring counter. With every count the ring counter counts one step further, successively the output potentials at the individual outputs of the Switch the ring counter from logic L to H and vice versa. Only one counting output leads to H potential.

In both circuit arrangements, the electronic Switch controlled with square-wave pulses, the positive (rising) edge of the switching pulse for the emerging switch with the negative (waste) Edge of the switching signal for the commutating switch coincides. Such a circuit arrangement causes in Synchronous motor, in connection with the circuit arrangement also called an EC motor for current commutation, d. H. at the Transition of the current flow from the one at the moment current-conducting winding phase (commutating Winding phase) to the subsequent current-conducting Winding phase (emerging winding phase) not insignificant noises and is also the cause of Radio interference.

Advantages of the invention

The circuit arrangement according to the invention with the characteristic features of claim 1 has in contrast the advantage that by the overlap of the switching signals and by clocking the switching signals in the overlap area steadily decreasing or increasing commutation edges of the Phase currents in the commutating winding phases with a predeterminable course can be achieved with little loss. Thereby becomes essential with low switching power loss Noise reduction achieved and also the radio interference significantly reduced. The noise reduction results  by the fact that during the commutation process in the emerging winding phase growing or in the commutating winding phase falling edge of the Commutation current, the average torque is not switched but is slowly steered up and that that of the slows down increasing current caused force effects not abruptly but dampened. Through this "Soft" commutation becomes commutation current peaks avoided and thus suppressed radio interference.

During the commutation process, either Switching signal for the emerging winding phase assigned switch or the switching signal for the the commutating winding phase associated switch be clocked. During the cycle of one switch the other switch involved in the commutation is full open. The timing of one switch causes both the phase current in the commutating Winding phase decreases on average as well as the phase current in the emerging phase grows on average, preferably linear or exponential.

The circuit arrangement according to the invention can be changed without modification both controlled and uncontrolled Synchronous motors or EC motors are used. The Armature winding can be in star with or without led star point be switched. In the first case the switching device has three electronic switches, each switched on in one of the three winding phases are. In the second case, the switching device has six in electronic switches combined in a bridge, each with a winding phase between two consecutive switches one of three parallel Series connections of the switches is connected.  

By the measures listed in the other claims are advantageous developments and improvements in Claim 1 specified circuit arrangement possible.

In a preferred embodiment of the invention, the Clocking the switching signal by comparing one Actual value curve of the phase current in at least one of the commutating winding phases corresponding actual value signal with a desired setpoint curve for the phase current corresponding setpoint signal obtained. This has the Advantage that the required clocking with only a small amount circuitry very simple from one also easily obtainable setpoint signal is and that a desired course of the Phase current specified during the commutation process can be.

The setpoint signal is according to a preferred one Embodiment of the invention by charging or discharging won a capacitor, the charging voltage for the The capacitor tracks the load current of the synchronous motor can be.

The actual value signal is derived from the phase currents of the commutating winding phases derived. This is done according to an expedient embodiment of the invention by means of measuring resistors in the winding phases of the Armature winding, with the measured voltage removed Represents actual value signal, so for Target-actual value comparison one of the measuring voltages from the two commutating winding phases can be used. According to a further embodiment of the invention as Actual value signal of the voltage drop at the z. B. as a MOSFET or SENSEFET trained commutating each electrical switches are used, so Setpoint-actual value comparison of the voltage drop at that of the  two commutating switches used during the Commutation process is not clocked. It depends on the actual value signal from the phase current of the up or commutating winding phase is removed, it must Setpoint signal to be adjusted accordingly and is by Charging or discharging of the capacitor realized.

The setpoint-actual value comparison is carried out according to another Embodiment of the invention by a comparator, the outputs a switching pulse when the setpoint signal Actual value signal exceeds. Will during the Commutation process that of the commutating Switch phase associated switches are clocked, so according to a further embodiment of the invention Control pulses via an OR gate to the control input of the Given switch. The other input of the OR gate is with the switch generated by the commutation logic assigned rectangular switching signal occupied. Through the Switching impulses of the comparator will then trigger the commuting switch timed over that of the Commutation logic generated switching signal extended. During this time extension, the is the emerging switching phase assigned switches the assigned switching signal of the commutation logic is full steered on.

The activation signal for the comparator is according to a Embodiment of the invention from the positive edge of the Switching signal for the commutation control of the associated electronic switch derived. In in the same way, the simultaneous negative edge of the Switching signal can be used. The same flanks of the Switch signals are also used for triggering the charging or discharging of the setpoint signal generating capacitor used because the generation of the  Setpoint signal synchronized with the commutation process must become.

drawing

The invention is based on one in the drawing illustrated embodiment in the following Description explained in more detail. Show it:

Fig. 1 is a circuit diagram of a circuit arrangement for operating a three-phase synchronous motor with electronic commutation of a DC power supply (EC motor),

Fig. 2 is a detailed illustration of the detail II in the diagram of FIG. 1,

Fig. 3 is a tabular summary of the Kommutierungsverlaufs with allocation of switching and actual value signals,

FIG. 4 shows a diagram of the switching signals generated by commutation logic in the circuit arrangement in FIG. 1.

Description of the embodiment

In the circuit diagram shown in Fig. 1, 10 denotes the three-phase armature winding of the synchronous motor, which is accommodated with its winding phases or winding phases u, v, w in the stator of the synchronous motor. The illustration of, for example, a two-pole rotor, preferably equipped with permanent magnets, which rotates in or around the stator of the synchronous motor, has been omitted. The winding phases u, v, w are combined at one winding end to form a star point and are connected at their other winding end to a switching device 11 . The switching device 11 consists of six power transistors T 1- T 6 , which are combined to form a three-phase two-way rectifier bridge circuit. Two transistors T 1 , T 4 and T 2 , T 5 and T 3 , T 6 are connected in series. The parallel connection of the three series connections of the transistors T 1- T 6 can be connected via a mains switch 12 to the DC voltage of a DC voltage network identified by "+". The free winding ends of the winding phases u, v, w are each connected to one of the parallel branches of the transistors T 1 - T 6 , specifically to the connecting lines which connect the transistors T 1 , T 4 or T 2 , T 5 or T 2 , respectively, one behind the other Connect T 3 , T 6 together.

The control inputs of the transistors T 1- T 6 are connected to the outputs of a commutation logic 13 via amplifiers V 1- V 6 . The commutation logic 13 , which can be designed, for example, as in DE 30 42 819 A1 or DE A 1 , generates switching signals S 1- S 6 at its six outputs in accordance with the rotational position of the rotor, each of which has the transistors T 1- T 6 open at their control input during the period of their queue, so that a corresponding phase current occurs in the assigned winding phase u, v, w. The time course of the switching signals S 1- S 6 at the outputs of the commutation logic 13 is shown in solid lines in FIG. 4. It can be seen that the falling edge of the switching signal for the current-carrying transistor and the rising edge of the switching signal for the immediately following current-carrying transistor coincide with one another.

In order to achieve a "smooth" commutation of the EC motor with the advantages of noise reduction and the avoidance of commutation current peaks, the switching signals S 1 - S 6 of the commutation logic 13 are changed by means of a control circuit 14 so that the two switching signals for the commutating one Transistors T 1 , T 2 and T 2 , T 3 and T 3 , T 1 assigned to the two winding phases u, v and v, w and w, u, respectively, and correspondingly T4, T 5 and T 5 , T 6 and T 6 , T 4 overlap in time and one of the two switching signals in the overlap region Δ t is clocked such that the mean value of the phase current I _u or I _v or I _w in the emerging winding phase, u, v, w and decreases in the commutating winding phase v, w, u, here in accordance with the course of an e-function. The overlap of the switching signals S 1- S 6 and the timing of the one switching signal in the temporal overlap area Δ t is shown in broken lines in FIG. 4. The overlap is achieved here by lengthening the switching signal for the transistor T 1- T 6 assigned to the commutating winding phase u, v, w. The timing of the respective switching signal is obtained in a simple manner from the comparison of an actual value signal corresponding to the actual value profile of the phase current I _u , I _v , I _w in at least one of the commutating winding phases u, v, w with a target value signal corresponding to the desired set value profile of the phase current. The end of the overlap occurs when the setpoint signal exceeds a predetermined value, hereinafter referred to as the default voltage.

In particular, the control circuit 14 has six comparators K 1- K 6 , the outputs of which are coupled via an OR gate OR 1 -OR 6 into the connecting line between the outputs of the commutation logic 13 and the inputs of the amplifiers V 1- V 6 . The one inputs of the OR gates OR 1 -OR 6 are each connected to an output of the commutation logic 13 and the other inputs of the OR gates OR 1 -OR 6 are each connected to an output of the comparators K 1 -K 6 . The outputs of the OR gates OR 1 -OR 6 are each led to the inputs of the amplifiers V 1- V 6 , the outputs of which are at the bases of the assigned transistors T 1- T 6 . In each comparator K 1- K 6 , a comparison of the actual value signal, which is obtained from the phase current I _u , I _v , I _{w of} one of the winding phases u, v, w involved in the commutation process, is carried out with the setpoint signal. If the setpoint signal exceeds the actual value signal, a switching pulse occurs at the output of the comparator K 1- K 6 , which is led via the OR gate OR 1 -OR 6 and the amplifier V 1-V6 to the corresponding transistor T 1- T 6 . These switching pulses lead to a clocked extension of the duty cycle of the respective transistor T 1- T 6 .

To obtain the actual value signals, a measuring resistor 15 is switched on in each winding phase u, v, w of the armature winding 10 , at which a measuring voltage U _u , U _v and U _w is present when the respective winding phase u, v, w is live. The measuring voltage U _u is led once to the voltage amplifier MV 1 and - inverted - to the voltage amplifier MV 4 . Accordingly, the measuring voltage U _{v is applied} to the measuring amplifiers MV 2 and MV 5 and the measuring voltage U _w to the measuring amplifiers MV 3 and MV 6 . The outputs of the measuring amplifiers MV 1 -MV 6 are correctly assigned to the one inputs of the comparators K 1- K 6 via an assignment unit 16 . The assignment unit 16 and its logical connection with the measuring amplifiers MV 1 -MV 6 and the comparators K 1- K 6 is shown in FIG. 2 in detail.

The setpoint signal for the comparators K 1- K 6 is taken from a capacitor 17 which is charged at the start of each commutation process. The charging voltage for the capacitor 17 is tracked to the load current in the armature winding 10 , that is to say the total current of the respective flowing phase currents I _u , I _v , I _w , for which purpose a resistor is connected between the outputs of the transistors T 4 -T 6 and the zero potential of the direct voltage 18 is arranged, the voltage drop is applied to an amplifier 19 . The output voltage of the amplifier 19 forms the charging voltage for the capacitor 17 , for which purpose the output of the amplifier 19 is connected to the capacitor 17 via a charging transistor 20 and a resistor 21 . A series circuit of a resistor 22 and a discharge transistor 23 which is connected in parallel with the capacitor 17, provides for the rapid discharge of the capacitor 17 after completion of the charging process. The specified voltage is tapped at a voltage divider consisting of resistors 24 and 25 , which is connected in parallel with the output of amplifier 19 . A comparator 26 compares the capacitor voltage on the capacitor 17 with the preset voltage and generates an output signal as soon as the capacitor voltage exceeds the preset voltage.

The charging and discharging process of the capacitor 17 is controlled with an RS flip-flop 27 with edge control. The Q output of the flip-flop 27 is connected to the base of the charging transistor 20 and the Q output is connected to the base of the discharging transistor 23 , while the reset input R is connected to the output of the comparator 26 . The outputs of the commutation logic 13 are connected via rectifiers 28 and capacitors 32 to a resistor 29 , which in turn is at zero potential. Resistors 33 serve to discharge the capacitors 32 . The voltage drop across resistor 29 is a switching pulse at flip-flop 27 . The flip-flop 27 is set with each positive (rising) edge of a switching signal S 1- S 6 , as a result of which its Q output logically assumes H. The flip-flop 27 is reset with each switching pulse at the output of the comparator 26 , as a result of which its Q output goes to logic high. Correspondingly, the charging transistor 20 and the discharge transistor 23 are turned on and the capacitor 17 is charged and discharged. The charging voltage of the capacitor 17 is fed to the assignment unit 16 via the input 30 and is applied by this to the comparator K 1 -K 6 to be activated in each case.

The assignment unit 16 , which makes the correct selection of one of the comparators K 1- K 6 in accordance with the respectively commutating winding phases u, v, w and which is symbolically represented in FIG. 2 by six double switches, is controlled by the switching signals S 1- S 6 . During the respectively occurring control signal S 1- S 6 , the relevant double switch is closed and the assigned comparator K 1- K 6 is assigned the setpoint and actual value signal. The assignment of the comparators K 1- K 6 to the transistors T 1- T 6 is made such that the opening duration of that transistor T 1- T 6 is extended by the switching pulses of the assigned comparator K 1- K 6 during the commutation process, which is assigned to the commutating winding phase u, v, w. The actual value signal supplied to this comparator K 1 - K 6 by the assignment unit 16 is taken from the phase current I _u , I _v , I _{w of} the other winding phase _u , _v , _w involved in the commutation process. The assignment of the switching signals S 1- S 6 to the commutating transistors T 1- T 6 and the actual value signals U _u , U _v , U _{w used} are listed in a table in FIG. 3.

For example, if the transistors T 3 and T 5 are current-carrying, so that the phase currents I _w and -I _v flow through the winding phases u, v, the transistor T 1 is turned on with the rising edge of the switching signal S 1 and the comparator K 3 with connected to the measuring voltage amplifier MV1. The measuring voltage amplifier MV 1 supplies an actual value signal derived from the measuring voltage U _u , which is a measure of the phase current I _u flowing in the winding phase u, which is assigned to the transistor T 1 . The flip-flop 27 is set with the rising edge of the switching signal S 1 , as a result of which the charging transistor 19 opens and the capacitor 17 is charged. The capacitor voltage 17 rising after a function ( 1- e ^{-t / T} ) is connected to the comparator K 3 via the closed double switch. If the setpoint signal exceeds the actual value signal, a switching pulse arrives at the transistor T 3 via the OR gate OR3, as a result of which the transistor T 3 is opened for the duration of the switching pulse despite the switching signal S 3 being eliminated. As a result of the opening of transistor T 3 , the actual value signal will exceed the set value signal again, and the switching pulse at transistor T 3 is no longer present. This process is repeated until the phase current I _u in the emerging winding phase _u has reached its end value and the phase current I _{w has} decayed to zero in the commutating winding phase _w . Since the actual value signal follows the setpoint signal, the phase current I _{u increases} in the emerging winding phase u and the phase current I _w decreases in the commutating winding phase w on average according to an e-function as specified by the charging process of the capacitor 17 . At the end of the commutation process, the winding phases u and v are now live, with the phase currents I _u and -I _{v flowing.} The commutation process is ended as soon as the capacitor voltage across capacitor 17 exceeds the preset voltage specified by voltage divider 24 , 25 . The switching pulse thereby generated by the comparator 26 resets the flip-flop 27 , as a result of which the discharge transistor 23 is turned on via the Q output of the flip-flop 27 . The capacitor 17 is completely discharged before the next switching signal S 6 occurs at the output of the commutation logic 13 .

The next commutation process takes place when the rising edge of the switching signal S 6 occurs . The transistors T 5 and T 6 and correspondingly the winding phases v and w are involved in this commutation process. When the positive edge of the switching signal S 6 occurs , the comparator K 5 is connected to the measuring amplifier MV 6 . At the same time, the charging process of the capacitor 17 is started again via the flip-flop 27 . Now through the described above in the same way at the output of the comparator K 5 switching pulses occurring the transistor T 5 is turned on 5 clocked despite discontinuation of its switching signal S, thereby the phase current -I _v in the winding phase by an exponential function falls to zero and the Phase current -I _w in the winding phase _w increases from zero to its final value after an e-function. The commutation process is ended again when the predetermined final voltage of the capacitor 17 is reached. The current-carrying winding phases are now the winding phases u and w with the phase currents I _u and -I _w . The further commutation processes can be easily understood on the basis of the tabular overview in FIG. 3.

With a controlled EC motor, the speed can be controlled by changing the load current. For this purpose, the phase current is changed by clocking the transistors T 1 , T 2 , T 3 or the transistors T 4 , T 5 and T 6 during their activation phase. For this purpose, in the circuit arrangement described here, a logical AND gate 31 is arranged between the OR gates OR 4 -OR 6 and the amplifier V 4- V 6 , which is controlled with control pulses of a predetermined frequency. The load current can be influenced by changing the relative duty cycle of this frequency signal. Alternatively, the AND gates 31 can also be arranged between the OR gates OR1 and OR3 and the amplifiers V 1- V 3 .

The invention is not restricted to the exemplary embodiment described above. Thus, in the circuit of Fig. 1, the six comparators K 1 K 6 are replaced by a single comparator, which in each case by a suitable multiplexer with the correct OR gates OR 1 -O-R 6 and with the correct measurement amplifier MV 1 and MV 6 is connected. The setpoint signal can have any profile, e.g. B. also a linear increase or decrease. If the actual value signal is detected with a measuring resistor in the winding phases u, v, w, it can also be taken in the other of the two winding phases involved in the commutation process, i.e. on the winding phase u, v, w, which corresponds to the clocked transistor T 1 - T 6 is assigned. In the example of FIGS. 1 and 2, e.g. B. on the comparator K 1 , the measurement voltage U _w , on the comparator K 2, the measurement voltage U _u and on the comparator K 3, the measurement voltage U _v , etc.

The measuring voltage can also on the voltage drop of the z. B. as bipolar transistors or as MOSFET or as SENSEFET transistors to be trained load switches T 1- T 6 . In this case, the voltage drop at that transistor is used which is not clocked during the commutation process.

Instead of generating the switching pulses by comparison a setpoint and actual value signal by means of a comparator can also use switching impulses for the overlap area fixed clock frequency and variable duty cycle specified will. This clock frequency is preferably with the Clock frequency for the speed control of the EC motor synchronized.

As an alternative to the timing of the control signal for the commutating transistor in the circuit arrangement according to FIG. 1 in the temporal overlap area Δ t of the control signals, the control signal for the commutating transistor can also be clocked. In this case, the switching signal of the commutating transistor must be extended by the overlap area Δ t. It is also possible to clock both transistors involved in the commutation.

If the star point of the armature device 10 is brought out and connected to zero potential via the resistor 18 , the transistors T 4 -T 6 can be omitted.

The control circuit for the commutation clocking can be combined with the commutation logic to form an integrable unit. The control circuit 14 operates independently of the type of generation of the switching signals by the commutation logic 13 .

The setpoint signal can also be derived from the discharge process of the capacitor 17 . In this case, the Q output of the flip-flop 27 is connected to the base of the discharge transistor 23 and the Q output is connected to the base of the charge transistor 20 . The discharge transistor 23 is then turned on with the edges of the control signals S 1- S 6 . The setpoint signal taken from the capacitor voltage then has the shape of an e ^{-t / T} function. The charging transistor 20 is blocked, and thus the charging process of the transistor is stopped when the capacitor voltage exceeds the preset voltage.

The invention can also be used in motors with a different number of phases or other phase connection, e.g. B. delta connection, be used.

Claims (19)

1. Circuit arrangement for operating a synchronous motor having a multi-phase armature winding on a DC voltage network, with a switching device for successively connecting the winding phases of the armature winding to the mains DC voltage, which has a plurality of electronic switches assigned to the individual winding phases, and with commutation logic for the consequent control of the switches with switching signals in accordance with the rotor rotational position of the synchronous motor, characterized in that for the commutation of successive current-carrying winding phases (u, v, w) the two switching signals (S 1- S 6 ) for the switches (T 1- T 6 ) assigned to the commutating winding phases overlap each other in time and that at least one of the two switching signals (S 1- S 6 ) is clocked in the overlap area (Δ t) in such a way that the mean value of the phase current (I _u , I _v , I _w ) increases and decreases in the emerging winding phase the agreement mutating winding phase decreases, preferably linearly or after an e-function. 2. Circuit arrangement according to claim 1, characterized in that the timing of the switching signal (S 1- S 6 ) from the comparison of the actual profile of the phase current (I _u , I _v , I _w ) in at least one of the commutating winding phases (u, v , w) corresponding actual value signal with a desired value signal corresponding to the desired course of the phase current (I _u , I _v , I _w ) is obtained. 3. Circuit arrangement according to claim 2, characterized characterized in that the amplitude of the setpoint signal the load current of the synchronous motor is tracked. 4. Circuit arrangement according to claim 2 or 3, characterized in that the capacitor voltage of a capacitor ( 17 ) is used as the setpoint signal during its charging or discharging process. 5. Circuit arrangement according to Claim 3 or 4, characterized in that a voltage drop tapped at a resistor ( 18 ) through which the phase total current flows determines the charging voltage of the capacitor ( 17 ). 6. A circuit arrangement according to claim 5, characterized in that the capacitor voltage is compared with a predetermined voltage in a fixed ratio to the charging voltage and that the exceeding of the predetermined voltage by the capacitor voltage is the end of the overlap area (Δ t) of the switching signals (S 1- S 6 ) specifies. 7. Circuit arrangement according to one of claims 2-6, characterized in that the actual value signal is formed by a measuring voltage (U _u , U _v , U _w ) on a measuring resistor lying in series with the winding phase (u, v, w) ( 15 ) is decreased. 8. Circuit arrangement according to one of claims 2-6, characterized in that the actual value signal is formed by the voltage drop at the non-clocked of the two commutating winding phases (u, v, w) associated electronic switch (T 1- T 6 ). 9. Circuit arrangement according to one of claims 2-8, characterized in that the actual value and the setpoint signal at the inputs of a comparator (K 1- K 6 ) can be placed, the output signals as switching signals to the control input of the switch to be clocked (T 1- T 6 ) are supplied. 10. Circuit arrangement according to claim 9, characterized in that from the rising or falling edge of each of the commutation logic ( 13 ) generated switching signal (S 1- S 6 ), a control signal for the assignment of the comparator output to the control input of the respective switch to be clocked ( T 1- T 6 ) is derived. 11. Circuit arrangement according to claim 9, characterized in that one of the number of switches (T 1- T 6 ) corresponding number of comparators (K 1- K 6 ) is provided, the outputs of which are each one of the control inputs of the switches (T 1- T 6 ) directly or indirectly connected and their inputs are each assigned the setpoint signal and one of the actual value signals derived from the phase currents (I _u , I _v , I _w ), and that from the rising or falling edge of each of the commutation logic ( 13 ) generated switching signal (S 1- S 6 ) an activation signal for the comparator (K 1- K 6 ) connected on the output side to the respective switch (T 1- T 6 ) is derived. 12. Circuit arrangement according to claim 11, characterized in that the connection of the comparator outputs to the control inputs of the switches (T 1- T 6 ) is made via an OR gate (OR 1 -OR 6 ), the other input of which output the commutation logic ( 13 ) is connected, to which the switching signal assigned to the switch (T 1- T 6 ) is generated. 13. Circuit arrangement according to one of claims 6-12, characterized in that the charging voltage of the capacitor ( 17 ) via a charging transistor ( 20 ) to the capacitor ( 17 ) and that the charging transistor ( 20 ) from the rising or falling edge of the each switching signal (S 1- S 6 ) generated by the commutation logic ( 13 ) can be driven open and can be blocked by the capacitor voltage if the preset voltage is exceeded. 14. Circuit arrangement according to claim 13, characterized in that the capacitor ( 17 ) is connected in parallel with a discharge transistor ( 23 ) which is turned on when the preset voltage is exceeded by the capacitor voltage. 15. Circuit arrangement according to claim 14, characterized in that an edge-controlled flip-flop ( 27 ) via its input with each of the switching signal outputs of the commutation logic ( 13 ), with its Q output with the base of the charging transistor ( 20 ) and with its Q- Output is connected to the base of the discharge transistor ( 23 ) and that a comparator ( 26 ) is connected on the output side to the reset input (R) of the flip-flop ( 27 ) and is occupied on the input side with the capacitor voltage and the preset voltage and generates an output signal when the capacitor voltage exceeds the default voltage. 16. Circuit arrangement according to one of claims 6-12, characterized in that the capacitor Discharge capacitor is connected in parallel by the rising or falling edge of the from the Commutation logic generated switching signal controllable is. 17. Circuit arrangement according to claim 16, characterized characterized in that the charging voltage of the capacitor led to the capacitor via a charging transistor is that when the specified voltage is exceeded by the Capacitor voltage is lockable. 18. Circuit arrangement according to claim 17, characterized characterized in that an edge-controlled flip-flop through its one entrance with each of the Switching signal outputs of the commutation logic, with its Q output with the base of the discharge transistor and with its Q output with the base of the charging transistor is connected and that a comparator on the output side the reset input of the flip-flop is connected and input side with the capacitor voltage and the Default voltage is occupied and an output signal generated when the capacitor voltage the Specified voltage exceeds.   19. Circuit arrangement according to one of claims 8-18, characterized in that the electronic switches (T 1- T 6 ) are designed as bipolar transistors, MOSFET or SENSEFET.