WO2013189609A2 - Synchronous machine and method for operating a synchronous machine - Google Patents

Abstract

The invention relates to a method for operating a synchronous motor (15) comprising a stator and comprising phase windings (U, V, W) with a drive device (16) for the phase windings, a measuring device (33) and a closed-loop control device (17) for the closed-loop control of the drive device (16), wherein for complexity- and effect-optimized closed-loop control, the measuring device (33) detects exclusively electrical variables at the phase windings of the synchronous motor (15) and/or in the drive device (16), the value of a variable which is representative of the load angle between the stator field and the rotor or the value of the load angle is determined from this, and a manipulated variable of the closed-loop control device (17, 37) is determined exclusively from the discrepancy between the determined values and a setpoint value, for bringing the load angle close to the setpoint value for the load angle.

Description

 description

 Synchronous machine and method for operating a synchronous machine

The invention is in the field of electrical engineering and relates in particular to synchronous machines.

Such synchronous machines can be operated as rotating electrical machines both as a motor and as a generator. Corresponding synchronous drives are widely used in industry as machine drives, but also as actuators. Such a synchronous machine basically has a stator with stator windings, so-called phase windings, which generate a magnetic rotating field in the region of the rotor. A corresponding activation of the phase windings causes the magnetic field to rotate. A rotor located in the rotating field with magnetic poles, which may be formed either as permanent magnets or electrically excited magnets, rotates synchronously with the rotational speed of the rotating field generated by the stator.

The control of the phase windings of the stator is usually carried out by electronically controlled converter circuits, which are designed with power semiconductors. Depending on the load of a drive, the rotor lags the stator rotary field more or less by an angle a, which is referred to as Polradwinkel or load angle. If the load is too large, the load angle increases beyond a tilt angle, at which the drive stops.

Conventional controls for synchronous drives provide that the absolute position of the rotor (angular position) by separate sensors (for example

Hall sensors or other magnetic sensors) or by evaluating the voltage induced in the stator winding (EMF) is determined. A control of the machine then adjusts, for example, voltages or current intensities at the phase windings in such a way that a desired behavior, in particular a time-dependent desired position, of the synchronous machine is achieved. On the one hand, a disadvantage of such methods is that the determination of the absolute position of the rotor requires corresponding sensors and hardware expenditure as well as a certain amount of computing power in the control device. The indirect determination of the absolute position of the rotor via electrical variables also requires computing power. On the other hand, the determination of the absolute rotor position is also time-consuming, so that a reaction of the control can not often take place at the desired speed when changing the load. In addition, especially in the determination of the rotor position via electrical variables often a corresponding design of the commutation in the control of the phase windings is necessary, so that further boundary conditions for the control arise, which complicate the scheme.

Typical problems that arise with such control methods are acoustic suggestions and slow reaction of the control under load changes and possibly also vibration behavior of the controlled variable, for example, the rotor speed, which, for example, vibrations of the load angle can be caused up to reaching the tilt angle.

The present invention is based on the background of the prior art, the object to provide a stable method for operating a synchronous machine, which allows the simplest and most effective control even with load changes, and manages with the least expensive control device. Furthermore, a synchronous machine operating thereafter, in particular a synchronous motor operating thereafter, should be specified.

With regard to the method, the object is achieved according to the invention by the features of claim 1. Advantageous Weitebildungen are the subject of the dependent thereupon dependent claims. With regard to the synchronous machine, the stated object is achieved according to the invention by the features of patent claim 12. Advantageous embodiments are the subject matter of the subclaims referenced hereto. It is assumed that the synchronous machine, in particular the synchronous motor, a stator with phase windings and a drive means for the phase windings, a measuring device and a control device for controlling the control device has.

According to the invention, it is additionally provided that the measuring device detects only electrical variables on the phase windings of the synchronous motor and / or in the control device, that the value of a variable representative of the load angle between the stator field and the rotor or the value of the load angle is determined therefrom, and is determined exclusively from the deviation of the determined values of a target value, a manipulated variable of the control device for approximating the load angle to the target value of the load angle.

In this case, usually at least two or three phase windings are provided for generating the rotary field, which are supplied via the drive means with power. For example, the control device generates time-dependent voltages in the form of pulse-width-modulated signals from electronic control signals for the individual phase windings. For this purpose, appropriate voltages are applied to the phase windings. The voltages are usually supplied to the pulse width modulation by an electrical intermediate circuit, which is part of a semiconductor bridge circuit with controllable semiconductor switches, for example transistors, field-effect transistors or IGBTs. The desired voltage and the current intensity at the phase windings are then set via the pulse width modulation.

The measuring device can measure, for example, the voltage drop across the phase windings and, for example, also detect the induced voltage generated by the rotor in the stator winding, which can be set in relation to the drive voltages of the phase windings. As a result, a load angle can already be determined without directly determining a rotor position. It can also be a variable representative of the load angle between the stator field and the rotor at a specific time, which is determined by the stator field periodicity, which is reached when the optimum load factor is reached. Angle at this time expected induced voltage compared with the actually induced voltage at this time and the difference value of the further control are used as a basis, until this difference value has been adjusted down to zero. When the difference disappears, the optimized load angle is reached.

However, the measured values of the measured variable (s) can also be converted into a rotor position additionally and independently of the control mechanism and thus also provide information about the load angle. This calculation process can be carried out at low speed and with little computation because it does not provide any size needed for the control. The measuring device can also detect the current intensity and thus the load of the drive or a combination of current and voltage at the individual phase windings.

By comparing the values detected by the measuring device with the signals fed in by the control device, the reaction of the synchronous machine to the control device and, therefrom, the load angle and possibly the absolute load can be determined therefrom. This feedback serves as the basis for determining the control deviation, i. the difference between an actual size and a desired size and the determination of the manipulated variable of the control device in order to bring about an approximation to the desired value of the reference variable (the optimal load angle).

For example, the control can control or influence the voltage, for example the voltage amplitude, at the phase windings and / or the current, for example the current amplitude of the current, by the phase windings to achieve the desired value, with an increase in the stator field strength usually resulting in a reduction of the load angle leads. The optimum load angle determines the optimum efficiency of the synchronous machine and depends, for example, on the reluctance torque of the machine. In any case, a direct measurement of the position of the rotor with the corresponding hardware and computational effort can be avoided in the cases described, and the control device makes do with determining the load angle or an electrical variable representative of this for optimizing the efficiency. It can be advantageously provided that a speed and / or a time-dependent desired position of the rotor of the synchronous machine is predetermined.

In the concept of the invention, it is generally assumed that the speed of the synchronous machine is predetermined as a desired value and that this is advantageously not primarily influenced by the control device, but rather that the control device influences only phase voltages and phase voltage amplitudes. Only one cooperating with the control device damping device, which will be explained in more detail below, can be provided to affect the speed or the frequency of the stator field, at least temporarily and temporarily.

The rotor basically follows the stator field and also keeps its speed, as long as the critical tilt angle between the stator and rotor position is not reached, so that the control can be concentrated or limited to the optimization of the load angle. The actual rotor position or speed need neither be determined nor regulated.

Advantageously, in the control, the manipulated variable of the control device, the voltage amplitude and / or a current amplitude in at least one phase winding or in two or three phase windings. By the voltage amplitude is meant the maximum value of the voltage, which is modulated by sine and cosine functions or also concretely by a pulse width modulation for the control of a phase winding. Thus, only one size must be adjusted for control, which is basically constant in time during operation of the control device. The current intensity or voltage amplitude are used in the control device as a constant value of the modulation by a periodic function, for example, a sine function or a pulse width modulation basis. As a manipulated variable can also be advantageous for a specific time behavior of the drive voltage of a phase winding (U, V, W), for example, a duty cycle of a pulse width modulation, serve for a limited time of action. For example, may be provided during a load change on the synchronous machine, an extension of the period in the control of one or more phase windings for half or whole period or a few periods of the three-phase field of the synchronous machine, for example, a sudden increase in load angle by a time offset of the three-phase field permanently or temporarily reduce.

In principle, it can also be provided that the manipulated variable is a frequency of the control of the phase windings, ie of the three-phase current field. This can lead to the rotational speed of the rotating field being temporarily adapted to the changed load during a load change. For example, with an increased load, the frequency during the control of the phase windings can be temporarily reduced and thus the rotational speed of the rotating field and of the rotor can be lowered. This can be realized for such a short action time that in fact only one or a few oscillation periods of the rotating field are prolonged.

A further advantageous embodiment of the method according to the invention provides that the temporal behavior of the control deviation is determined and the rate of change of the manipulated variable is deliberately reduced by a damping device in order to dampen the change in the control deviation.

It is fundamentally known that an overly strong and / or too fast intervention in the event of a control deviation can cause the control deviation to oscillate. If, for example, the load angle is correspondingly increased in the case of a suddenly increased load, the control can bring about an equally abrupt reduction of the load angle by increasing the voltage and / or the current in the phase windings, so that the load angle can swing strongly around the setpoint value. Such oscillations can be achieved, for example, by mass-spring models of the Polradwin- known in the literature. kels / load angle described and in extreme cases lead to the reaching of the tilt angle at which the synchronous machine stops working. For this reason, an attenuation of the control by the control device can be provided according to the invention, which is realized in an electronic manner.

Basically, alternatively or in addition to the electronic damping, the realization of such a damping by a so-called damper cage in the rotor possible, the damper cage generated by induced currents in the rotor magnetic fields that dampen oscillations and stabilize the system against rapid changes.

However, electronic damping can react in a more targeted and optimized way. It is therefore considered advantageous according to the present invention, at least in addition to realize such attenuation in an electronic manner, for example by the control variable of the control device is not abruptly, but gradually and temporally delayed adjusted. Alternatively, the rate of change of the control deviation can be detected by the measuring system and the manipulated variable can be changed in such a way that the rate of change of the control deviation is limited. The damping device can also superimpose its own signals to the electrical signals generated by the control device at the phase windings and thus to modulate the effect of the control device.

Advantageously, the invention can be configured by measuring voltage values on the phase windings and / or phase currents of the synchronous machine for controlling a damping device and determining oscillations therefrom. Since oscillations of the rotor due to the effect on the stator field also act on the currents in the stator windings and the voltages on the stator windings, a concrete oscillation state can be determined by analyzing the phase currents and / or the voltages.

A further advantageous embodiment of the invention can provide that for controlling a damping device in the phase windings through the rotor movement induced voltage is detected and from this oscillations are determined. Since an additional oscillation superimposed on the desired rotor movement influences the relative movement of the rotor and stator field, the voltages induced in the stator and determined by the relative velocity are also influenced by this. Therefore, the vibration state can be determined by analyzing the induced voltages.

It can also be advantageously provided that the amplitude and / or the phase position of the drive voltage is influenced by a damping device for damping a rotor pendulum.

In addition, it can be provided in the invention that for damping a rotor oscillation by a damping device, a time-dependent voltage at the converter of the commutation voltage generated by the control device is superimposed.

The invention relates not only to a method for operating a synchronous machine on the design of a synchronous machine / a synchronous motor. Εέ is a synchronous machine is provided, which has a stator with phase windings and a rotor and a drive means for the phase windings and a measuring device and a control device for controlling the drive means. The invention provides that the measuring device only electrical measurements on at least one Pha senwicklung and / or detected at the control device and processes that the control device a representative of the load angle between the stator and rotor tive size or the load angle and a manipulated variable, in particular one Voltage amplitude for driving the phase windings to approximate the load angle to the setpoint of the load angle determined.

The control device is thus supplied with no measured values, for example, from a further measuring device which measures the position of the rotor directly via hardware sensors. As a reference variable for the control device thus serve only sizes that are representative of the load angle or directly express the size of the load angle, and which are determined from electrical measurements on one, two, three or more phase windings and / or on the drive direction.

By way of example, the measuring device can determine the load on the synchronous machine and the voltages induced by the rotor movement by determining the voltage drops at one, two or three phase windings or the maximum current or current intensity profiles and one, two or three phase windings, and from this determine the load angle. It can thus be determined from the relationship between the voltage applied to the individual phases and the load currents or from the temporal behavior of currents and voltages of the load angle. As a reference variable for the control device can then serve either a voltage at a phase winding, an amperage amplitude or a point at a certain time of the Ansteuerperiode reached voltage or current characteristic of the load angle / Polradwinkel. Thus, the synchronous machine can be controlled in a particularly simple and inexpensive manner, which can be responded particularly quickly even with low computing power of the control device efficiently to load changes.

By way of example, the measuring device can also have a device for measuring the current intensity or a voltage at a current source of the drive device and / or at an electrical intermediate circuit.

The actual behavior of the synchronous machine also has an effect on these variables, so that the load or the load angle of the synchronous machine and, therefrom, a manipulated variable for the control device can also be determined from their behavior.

An advantageous embodiment of the invention also provides that an electrical damping device for the manipulated variable of the controller either integrated into the control device or this is connected downstream. This means, for example, that when the damping device is integrated into the control device, tion, the damping device influences the control behavior of the control device in order to prevent a rocking of a pendulum behavior. However, the damping device can also influence the control variables generated and output by the control variables or superimpose their own signals, such as a modulation at the input of the control device or the inverter or its own voltage signals directly to one or more phase windings.

Embodiments of the invention will be explained in more detail with reference to a drawing. Show:

1 shows schematically the phase windings of a star-connected electric drive,

 2 shows a bridge circuit for driving in each case a phase winding of a drive,

3 is an equivalent circuit diagram for a voltage supply of a phase, FIG. 4 is a schematic equivalent circuit diagram for an electric drive in triangular circuit,

 5 shows a device for carrying out the operating method according to the invention,

 6 shows a further device for carrying out the inventive

 Operating method in which the damping device directly modulates the output signals of the control device, and

 Fig. 7 shows a device for carrying out the operating method according to the invention, in which the damping device acts only on the phase position and the control device only to the amplitudes of the drive voltages of the phase windings.

Fig. 1 shows schematically a star connection of three phase windings U, V, W, wherein the neutral point 1 forms the connection terminal between each two phase windings U, V, W. The individual phase windings are shown in the form of an equivalent circuit diagram, each having an inductance 2, an ohmic resistance 3 and a voltage drop, the one by the movement of the rotor induced voltage (EMF, EMF) is generated and represented by the circle 4. If one of the three phase windings is assumed to be de-energized, the result is a series connection of the two remaining phase windings, which are each connected to star point 1.

The respective voltage drop across a phase winding U, V, W is represented by the arrows 20, 21, 22 and results in each case as the sum of the voltage drops via inductance and ohmic resistance and induced voltage.

The control of such a star-connected brushless electric drive can be done for example via a so-called B6 circuit in which either a higher DC level or a lower DC voltage level of an intermediate circuit 5 to 11, in particular ground potential, can be applied to each of the phase windings. Thus, such an electric drive with respect to the speed, the power and the direction of rotation can be controlled.

By way of example, an arrangement of two switches for the phase W is shown in FIG. 1, wherein 5 denotes the ground potential connection and 6 denotes a higher DC potential of the intermediate circuit 5 to 11. About the switches 7, 8, the first terminal 9 of the phase winding W can be connected to either the higher DC potential or ground potential. If the switch 7 is closed and the switch 8 is opened, the terminal 9 is connected to the higher voltage potential. If the terminal 7 is opened and the terminal 8 is closed, the first terminal 9 of the phase winding W is connected to the ground potential. Depending on the switching position of the individual switches, the phase winding can thus be subjected to two different voltage levels.

Fig. 2 shows comparatively detailed the possible construction of a circuit with a constellation of two semiconductor switches, over which two different voltage potentials can be selectively connected to a phase winding. The phase winding connection is 9 and a first switch is 7 and a second switch 8 - analogous to the designations of FIG. records. A low voltage level, for example, of the ground potential is indicated by the ground potential terminal 5, while the higher DC potential is applied to the terminal 6. The switches 7, 8 are implemented as MOSFETs, which can each switch through or lock, and which are controllable by a control voltage with respect. Their switching state. The control voltage inputs are designated 10, 11 in FIG. By appropriate control of the control voltage inputs 10, 11 can thus be transmitted to a phase winding of a circuit, such as a star connection, an electric drive either a DC voltage pulse of a higher voltage level or a lower voltage level or ground potential.

FIG. 3 shows an equivalent circuit diagram for a voltage source which, for example, can supply the higher voltage level at terminal 6 in FIG. 2 with respect to ground potential. In this case, 23 designates the internal resistance of the voltage source, 24 the self-inductance, 25 the capacitance, 26 the ground potential connection, 27 the shunt resistor, at which the useful voltage drops, and 28 the supplied useful voltage and 29 the delivered current. Power and voltage are supplied on the left side of the circuit by way of example by a battery.

Usually, a star connection, as shown in FIG. 1, respectively has semiconductor switch bridges for each phase winding, as illustrated, for example, in FIG.

The same applies to a triangular circuit shown schematically in Fig. 4, which can also serve as a typical circuit of an electric drive, with correspondingly in a known manner to a star connection of different drive characteristics. For the individual phase windings of the phases U, V, W, the above applies in connection with FIG. 1.

FIG. 5 shows by way of example a synchronous machine 15 in the form of a synchronous motor, which is fed by a converter 16. The inverter 16 constitutes a drive device for the phase windings U, V, W of the motor and contains the typical components for a voltage supply of the phase windings, optionally including a device for the pulse width modulation.

A corresponding control device for the drive device 6 is designated 17, 37 in FIG. 5. For the voltage vector which is converted into the supply voltage of the phase windings in the control device 16, the control device 17 has, on the one hand, a direction specification module 18 which determines the orientation of the voltage vector, that is to say the relative phase position of the individual phase voltages, taking into account the setpoint frequency, as well as a time-dependent one Vector length module 19, which serves to determine the amplitude of the individual phase voltages. The information / specifications of the directional specification module 18 and of the vector length module 19 are passed to a vector module 31, which converts the specifications into a vector tuple, in particular a vector triple, ie ultimately an absolute specification for the individual components of the voltage vector. This information is then passed to the inverter where it is converted into supply voltage quantities for the individual phases.

As a voltage curve, for example, the following can be selected in the usual form for the phases U, V and W:

 Uu = sin (a)

U _v = sin (+120 °)

U _w = sin (a -120 °)

The vector length is determined by the voltage amplitude UAmp. From the direction specification and the vector length, the control device 17, 37 builds up the control variables for the control device 16:

UuAnst ~ U Offset ⁺ U Amp * Uy

UvAnst ~ U Offset ⁺ U Amp * Uv

UwAnst - U Offset ⁺ U Amp * Uw

The value for Ucmset is usually half the DC link voltage. Uoffset can also be chosen with advantage over time: U Offset (t) - - min (U _Amp (t) * Uu (t), U _Amp (t) * U _v (t), U _Amp (t) * U _w (t)).

This leads to one phase each having the value 0. These voltage variables can then process the control device for generating time-dependent voltage values. The profile of the individual phase voltages can be converted, for example, by a pulse width modulation in the control device.

On the input side of the control device 17, 37 except, for example, the target frequency of the control, ie the target speed of the machine, on the one hand via a setpoint input 32, a setpoint for the load angle or one or more for these representative sizes. Such representative quantities can be, for example, specific values of induced voltages on the phase windings at specific times in relation to the period of the phase winding drive, that is, with respect to the orientation of the phase vector.

A measuring system 33 determines from actual variables measured on the motor, such as the phase voltage and / or the phase current and, for example, the induced voltages and their time behavior, the actual load angle and passes this input side as an actual value to the control device 17, 37 via the actual value input 34th and the phase controller 37. The controller can zoom in on the phase controller 37 for targeted change in the load angle, for example, the phase voltages (corresponding to the vector length) (at too large load angle) or reduce (at too low load angle). Thus, depending on the choice of the setpoint value at the setpoint input 32, an optimized phase angle can be set, which depends, inter alia, on the reluctance torque of the motor, for example.

Current measured values of the load angle or of the variable (s) representative of it are / are also fed to the damping device 36 in the example shown in FIG. The damping device can act on both the vector length and the vector direction, ie both the phase voltage amplitudes and the speed change in the short term. The measuring device 33 can also be connected directly to the control device 16 to determine the reaction of the motor to the drive, which is represented by a dashed connection in FIG. 5. The corresponding variables can also be obtained by the measuring device 33 exclusively from the control device 16, for example in the form of values of the phase currents, phase voltages, the DC link current or the battery current.

From the variables processed in the measuring device 33, the absolute position of the rotor of the motor 15 can also be indirectly determined in a position-determining module 35. This can also be transmitted on the input side of the control device 17. It is important that the position determination, which leads to the disclosure of information to the controller 17, is not necessary for the control process.

It may optionally or additionally be provided a further position detection module that works by means of directly on the engine 15 sensors, however, the information thus obtained on the rotor position also within the scope of the invention is not required as an input to the control device 7 and represent at best advantageously usable additional information ,

In order to dampen the operation of the control device 17, 37, for example, the measuring system 33 can also determine a rate of change of the respective actual variable in addition to the actual values of the load angle or a measured variable determined for this representative and feed them to the damping device 36. The damping device 36 is connected to the directional specification module 18 and the vector length module 19 and acts on the input side to the control device 17, 37 in order to dampen an adjustment of the desired value such that, if necessary, vibrations of the system are minimized and decay rapidly. It can be used for damping a slow controller. The damping device can also determine the specific vibration behavior of the rotor from measured values and superimpose signals on the control behavior which lead to a damping of the vibrations. The damping device 36 can evaluate, for example, measured motor currents / phase currents. By a pendulum motion due to a vibration of the rotor, for example, voltages are induced, which overlap the supply voltages from the control device. Also, the variation of the load angle affects the phase currents. For example, the induced voltages at the zero crossing of the currents can be measured in order to detect corresponding oscillating movements. The damping can be done either by influencing the currently controlled load angle (for example over a time ramp) or by influencing the vector length of the voltage vector.

Fig. 6 shows a constellation in which the damping device modulates the output variables of the control device and does not act directly on the control device. The phase controller of the control device can act both on the vector length and on the vector direction specification, ie the phase position of the voltage vector.

In an exemplary implementation of the invention, a setpoint speed and thus an angular position for each defined point of time are initially predefined for the control device. If a deviation of the load angle from the setpoint is detected, the speed specified by the control follows the actual setpoint via a ramp, whereby boundary conditions such as the maximum current to be observed are observed.

The measuring system detects the phase currents in the estimated zero crossing of the induced voltage of one or more phases and optionally also, for example, the battery current. These quantities are the input variables for the control device 17, 37 and the damping device 36.

The controller then operates as follows: The set point of the phase currents at the zero crossing of the induced voltage is zero. Since the voltage at the time of measurement drops only at the inductance, can from the known Inductance, the measured current and the speed of the target voltage can be determined. The determined values for current intensity and voltage are fed to the control device 17, 37 and regulated to zero by variation of the amplitude and phase position (vector orientation) of the voltage vector.

Instead of a variation of the phase position and amplitude of the voltage vector, as shown in FIG. 7, two independent aspects of the amplitude (a sine component and a cosine component) may also be controlled separately. In this case, the phase controller 37 is connected only to the vector length module and not to the vector direction module.

In the example described according to FIG. 7, the damping device acts, for example, as follows: The battery current is measured continuously. When a pendulum oscillation of the rotor and the current strength of the battery current oscillates accordingly. From this, a damping can be derived. A time variable variable is modulated onto the desired speed, where n neu = n _a it ⁺ f (1 Bat) with f (1 _B at) equal to an attenuation factor multiplied by an instantaneous deviation of the battery current magnitude from a current average. The signs are chosen such that at a momentary exceeding of the average battery current strength of the target value of the speed is slightly reduced, and that this target value of the speed is slightly increased when the average battery power is below.

This oscillation-dependent modulation of the solid core / nominal frequency / nominal phase position achieves effective damping of the battery current and of the overall system. Optionally, the amplitude of the phase voltages can be modulated for damping or a combination of the amplitude and the phase position, as indicated in Figure 5. The damping device 36 acts in the manner described against exceeding of a tilt angle and for minimizing rotor vibrations with the known corresponding side effects. As a result, the implementation of the invention achieves the operation of a synchronous machine with optimized regulation, whereby an ideal phase position is established between the stator field / rotating field and the rotor field after a reasonable time. Advantageously, superimposed vibrations by a damper, in particular an electronic damper, can be quickly brought to a subsidence. The method of operation may respond very quickly to load transients and other changes before comparable measurements of actual positions of the rotor, obtained according to the prior art from previously used separate sensors, could signal such changes. The measuring system used can operate with little effort and relatively low accuracy and sampling rate, since phase control and attenuation are generally not time critical.

The invention is not limited to the embodiment described above. Rather, other variants of the invention can be derived therefrom by the person skilled in the art without departing from the subject matter of the invention. In particular, all the individual features described in connection with the exemplary embodiment can also be combined with one another in other ways, without departing from the subject matter of the invention.

LIST OF REFERENCE NUMBERS

1 star point U, V, W phase windings

2 inductance

 3 ohmic resistance

 4 induced voltage

 5 earth potential connection

 6 higher DC potential

7, 8 switches

 9 first connection of the phase winding W

 10, 11 control voltage inputs

 12, 13, 14 phase connections in delta connection

 15 synchronous motor

 16 control device

17, 37 control device

 18 directional specification module

 19 vector length module

 20, 21, 22 via phase winding sloping voltages

 23 Internal resistance of the voltage source

 24 Self-inductance of the voltage source

 25 Capacity of the voltage source

 26 Earth potential connection of the voltage source

 27 Shunt resistance of the voltage source

 28 useful voltage of the voltage source

 29 Current of the voltage source

 30 second terminal of the phase winding V

 31 vector module

 32 setpoint input

 33 measuring equipment

 34 Actual value input

 35 position determination module

 36 damping device

 37 phase controller (part of the control device)

Claims

June 2013 claims

1. A method for operating a synchronous machine, in particular a synchronous motor (15), with a stator with phase windings (U, V, W), with a drive means (16) for the phase windings, with a measuring device (33) and with a control device (17 , 37) for controlling the drive device (16),

 characterized,

 - That the measuring device (33) detects only electrical variables at the phase windings of the synchronous motor (15) and / or in the control device (16), from which the value of a representative of the load angle between the stator and rotor size or the value of the load angle is determined , and

 - That only from the deviation of the determined values of a target value, a manipulated variable of the control device (7, 37) is determined to approximate the load angle to the target value of the load angle.

2. The method according to claim 1,

 characterized,

 that a speed and / or a time-dependent desired position of the rotor of the synchronous machine is predetermined.

3. The method according to claim 1 or 2,

 characterized,

 in that the manipulated variable is a voltage amplitude and / or amplitude on at least one phase winding (U, V, W).

4. The method according to any one of claims 1 to 3, characterized,

 the manipulated variable is a variable time response of the drive voltage of a phase winding (U, V, W), in particular a duty cycle of a pulse width modulation for a limited action time.

5. The method according to claim 4,

 characterized,

 that the manipulated variable is the frequency of driving at least one phase winding (U, V, W).

6. The method according to any one of claims 1 to 5,

 characterized,

 that the temporal behavior of the control deviation is determined and the rate of change of the manipulated variable under the action of the control device is deliberately reduced by a damping device in order to dampen the change in the control deviation.

7. The method according to any one of claims 1 to 6,

 characterized,

 in that voltage values are measured on the phase windings and / or phase currents of the synchronous machine for controlling a damping device and oscillations are determined therefrom.

8. The method according to any one of claims 1 to 7,

 characterized,

 in that a voltage induced in the phase windings by the rotor movement is detected to trigger a damping device and oscillations are determined therefrom.

9. The method according to any one of claims 1 to 8,

characterized, that for damping a rotor oscillation by a damping device, the phase position of the drive voltage influenced, in particular modulated.

10. The method according to any one of claims 1 to 9,

 characterized,

 that for damping a rotor oscillation by a damping device, the amplitude of the drive voltage is influenced, in particular modulated.

11. The method according to any one of claims 1 to 9,

 characterized,

 in that a time-dependent voltage on the converter is superimposed on the commutation voltage generated by the control device for damping a rotor oscillation by means of a damping device (36).

12. Synchronous machine, in particular synchronous motor (15), with a stator with phase windings (U, V, W) and with a rotor, with a drive device (16) for the phase windings (U, V, W) and with a measuring device ( 33) and with a control device (17, 37) for controlling the drive device (16),

 characterized,

 - that the measuring device (33) exclusively detects and processes electrical measured quantities on at least one phase winding (U, V, W) and / or on the drive device (16),

 - That the measuring device (33) detects only electrical variables at the phase windings (U, V, W) of the synchronous machine (15) and / or in the drive means (16), wherein the control device (17, 37) on the input side for supplying the reference variable exclusively connected to the measuring device (33),

- That the control device is a representative of the load angle between the stator and rotor size or the load angle and a manipulated variable, in particular a voltage amplitude, for controlling the phase senwindlungen (U, V, W) determined to approximate the load angle to the target value of the load angle.

13. Synchronous machine according to claim 12,

 characterized,

 in that the measuring device (33) has a device for measuring the current intensity and / or voltage at at least one phase winding (U, V, W).

14. Synchronous machine according to claim 12 or 13,

 characterized,

 in that the measuring device (33) has a device for measuring the current intensity and / or the voltage at a current source (23, 24, 25, 26, 27, 28, 29) of the drive device (16) and / or at an electrical intermediate circuit (5, 6, 7, 8, 9, 10, 11).

15. Synchronous machine according to claim 12, 13 or 14,

 characterized,

 in that an electronic damping device (36) is provided for the manipulated variable of the control device (17), which is integrated into or connected downstream of the control device (17).