DE3525421A1 - Method and circuit arrangement for reducing the torque ripple of a converter motor in the low speed range - Google Patents

Abstract

In the case of reducing the torque ripple of a converter motor (3) having two DC-isolated three-phase stator winding systems (U1, V1, W1; U2, V2, W2) which are offset by 30 DEG with respect to one another and are supplied from two converters, which each consist of a mains converter (NSR 1, NSR 2), and intermediate-circuit inductor (Ld1, Ld2) and a machine converter (MSR 1, MSR 2), with intermediate-circuit currents (Id1, Id2) whose amplitude can be influenced separately by driving the valves of the mains converter (NSR 1, NSR 2), it is intended, in the low speed range, both to suppress oscillating forks and to overcome discontinuities during the further switching of the electric loading (ratio of the total current per slot divided by the tooth pitch) of the converter motor (3). For this purpose, the valves (11... 16; 21... 26) of the mains converters (NSR 1, NSR 2) are driven in such a manner that two intermediate-circuit currents (Id1, Id2) flow, offset through 90 DEG with respect to one another, as sinusoidal half cycles which continuously follow one another in time. The valves (1A, 1F, 1C, 1D; 2A, 2B, 2D, 2E) of the machine converters (MSR 1, MSR 2) are driven in such a manner that each of the two intermediate-circuit currents (Id1, Id2) are switched on alternately in the positive and negative direction per sinusoidal half cycle via exclusively two (u1, v1 and u2, w2 respectively) of the three phase connections through windings of the two stator winding systems (U1, V1, W1; U2, V2, W2) whose electrical effect is mutually orthogonal. <IMAGE>

Description

The invention relates to a method and an arrangement for Reduction of the torque ripple of a converter motor with two galvanically isolated, three-phase staggered by 30 ° Stator winding systems made up of two, each with a mains converter, an intermediate circuit choke and a machine converter Inverters with separate control of the valves of the line converter DC link currents that can be influenced in their amplitude are fed. A Such a method and such an arrangement are described in EP 00 87 115 A1 known.

When starting one fed via a DC link converter Converter motor and for operating the same at low speeds the machine voltage is not sufficient to commutate the current from one valve branch of the machine converter to the next one out. It is therefore common for the range of low speeds, the intermediate circuit current to clock (see the article by Gölz / Grumbrecht "converter-fed Synchronous machines "in" Technical information AEG-Telefunken "63 (1973), No. 4, pages 141 to 148). The rotation of the Machine rotor (and thus the main flow of the machine) against the Pendulum torques for the machine stand, each at 60 ° which, because of their low frequencies, interfere with the operation of the  Machine. In addition, the torque curve of the converter motor discontinuous, since currentless in each case for switching on the current pad Breaks are required during which the torque disappears completely.

In DE-OS 22 34 681 a method is specified which is calculated of the torque and targeted influencing of the DC link current appropriate control of the power converter the first mentioned pendulum moments suppressed. Still remain with the forwarding of the Electricity deposits, however, exist at torque-free intervals that prevent operation to disturb.

In the EP 00 87 115 A1 already mentioned at the beginning, which, like the invention two 30 ° apart, each galvanically isolated stator winding systems powered by an intermediate circuit converter Conversely, the converter motor requires a method in which through an opposite course of the two intermediate circuit currents the disappearance of the torque is prevented while the pendulum torque however, are not influenced.

The invention has for its object a method of the beginning specified type, in which both suppresses the pendulum moments as well as the discontinuities during the continuation of the current coating be eliminated in the converter motor. In addition, a circuit arrangement be specified for performing such a method.

This object is achieved according to the invention for the method by the Characteristics characterized claim 1 solved.

Jerk-free and oscillation-free start-up of the converter motor is advantageously achieved here by a uniform torque, this via the specified control of the valves of the mains converter and the machine converter by a uniformly rotating, ie complete rotating field is generated.  

Advantageous embodiments of the method according to the invention are shown in characterized claims 2 to 7.

A circuit arrangement for performing the method according to the Invention is specified in claim 8.

The invention will now be described with reference to one in the drawing Embodiment will be explained. Show it

Fig. 1 shows the principle circuit diagram of the power of a brushless DC motor with two separate stator winding systems via two DC link inverter,

FIGS. 2a, 2b, the spatial arrangement of the stator coil systems each other brushless DC motor,

Fig. 3 shows the time course of the currents in the intermediate circuits of the converter, the currents through individual valves of the machine converter feeding the converter motor and the currents in the two stator winding systems in the range of low speeds and

Fig. 4 is a schematic diagram of a circuit arrangement for the control of both the power converter feeding the motor drive in the low speed range.

In Fig. 1, a 12-pulse arrangement is shown for supplying a power converter motor 3. From feeding networks L 11 . . . L 13 , L 21 . . . L 23 are controlled by valves 11 . . . 16 , 21 . . . 26 equipped two line converters NSR 1 NSR 2 generates two DC link currents I _{d 1} , I _{d 2} and also via DC link chokes L _{d 1} , L _{d 2} with controllable valves 1 A. . . 1 F , 2 A. . . 2 F provided machine converters MSR 1 , MSR 2 . The machine converters MSR 1 , MSR 2 in turn transform the intermediate _circuit variables I _{d 1} , I _d2 into alternating variables which are fed to the winding phases U 1 , V 1 , W 1 and U 2 , V 2 , W 2 of the converter motor 3 . The winding strands U 1 , U 2 or V 1 , V 2 or W 1 , W 2 are offset from one another by 30 ° el and electrically isolated from one another. Further, the brushless motor 3 has a field winding 4, through which a field current I _F flows. The arousal can be constant or variable. Instead of excitation winding 4 , permanent excitation is also possible.

According to the general AC theory, a complete rotating field can not only through three sine variables offset by 120 ° from each other generated in a three-phase winding system, but also by two sine variables shifted by 90 ° against each other in a two-phase Winding system.

The arrangement of the windings of the converter motor 3 is shown in FIG. 2a in their spatial assignment. u 1 , v 1 , w 1 denote the beginnings of the windings of the first stator winding system, x 1 , y 1 , z 1 , the end thereof; u 2 , v 2 , w 2 and x 2 , y 2 , z 2 are the analog names for the second stator winding system. It is easy to see that, for example, the windings u 1 - x 1 and y 1 - v 1 have a magnetic effect to a - fictitious - winding u 1 - v 1 and likewise the windings w 2 - z 2 and x 2 - u 2 a - also fictional - winding w 2 - u 2 can be summarized. This is indicated in Fig. 2b.

Since these winding strands are orthogonal to one another in their effect and also belong to two different partial winding systems, an arrangement according to FIG. 1 and corresponding modulation of the intermediate circuit currents I _{d 1} and I _{d 2} and targeted control of the valves of the machine power converters MSR 1 and MSR 2 can be achieved that a complete rotating field is formed in the machine.

Of course, this applies not only to the winding strands under consideration according to FIG. 2, but also to all combinations that result in an orthogonal winding system, that is to say also for machines in a delta connection, which are provided with two stator winding systems that are galvanically separated and offset by 30 °.

In Fig. 3 are the time profiles of the intermediate circuit currents I _{d 1} , I _{d 2} , the currents through the valves 1 A , 1 F , 1 C , 1 D and 2 A , 2 B , 2 D , 2 E and the currents in the Winding strands u 1 - v 1 ( I _{1 uv} ) and u 2 - w 2 ( I _{2 uw} ) are plotted.

It is therefore only necessary to control the valves of the two line converters NSR 1 , NSR 2 according to FIG. 1 in such a way that the two intermediate circuit currents I _{d 1} , I _{d 2} , as indicated in FIG. 3, are offset from one another by 90 ° as continuous consecutive sine half-periods flow. Furthermore, the valves 1 A , 1 F , 1 C , 1 D and 2 A , 2 B , 2 D , 2 E of the machine power converter MSR 1 , MSR 2 must be controlled such that each of the two intermediate circuit currents I _{d 1} , I _{d 2} in the positive and negative direction alternately for each half-sine cycle via only two of the three phase connections through the windings of the two stator winding systems.

The currentless pauses required for switching the intermediate circuit currents coincide with the zero crossings of the phase currents in the converter motor 3 and thus no longer appear as noticeable discontinuities in the torque of the machine.

In FIG. 4 a switching arrangement is shown, with which the intermediate-circuit currents can be produced in the desired shape and forwarded. The power section, consisting of the line converters NSR 1 , NSR 2 , the intermediate circuit chokes L _{d 1} , L _{d 2} , the machine converters MSR 1 , MSR 2 , the converter motor 3 and the excitation 4 corresponds to the arrangement shown in FIG. 1. The three-phase supply of electrical energy from the network or the feedback into the network takes place via a converter transformer 5 for generating 12-pulse network perturbations.

About a suitable measuring device 6 , for. B. an angle encoder or a resolver, the rotor position angle λ of the rotor of the converter motor 3 with respect to the axis of a strand of a stator winding system is detected and evaluated by controls 71 , 72 for the machine converter MSR 1 , MSR 2 such that ignition pulses to the correct valves the machine power converter are delivered.

Furthermore, the rotor position angle λ _is required to calculate the current setpoints w ₁₁ and w ₁₂ for the two intermediate circuit currents I _{d 1} , I _{d 2} . For this purpose, an angle δ is added to this rotor position angle λ, which angle is determined in a computing circuit 8 as a function of a predetermined torque setpoint value w _m . In the simplest case, the angle δ can also be specified constantly. With exact replication, the angle δ is a measure of the degree of loading of the machine; it describes the rotation of the river against the magnet wheel axis. The exact replica of the angle δ is e.g. B. possible via the machine equations of the converter motor.

The angle ϑ , ( ϑ = λ + δ ) obtained by adding the two angles λ and δ serves as an argument for a sine-cosine encoder 9 . The variables sin ϑ and cos ϑ output by the sine-cosine encoder 9 are multiplied by the torque setpoint w _m in multipliers 31 , 32 and the signals thus generated in absolute value formers 41 , 42 to the desired current setpoints w ₁₁ and w ₁₂ reshaped. The difference between the respective setpoint and the actual value I ' _{d 1} and I ' _{d 2 of} the respective intermediate circuit current obtained from the respective intermediate circuit via unspecified converters is supplied to current regulators 51 , 52 , the outputs of which with pulse control rates 61 , 62 for the valves of two line converters NSR 1 , NSR 2 are connected.

In each case, an evaluation logic 81 , 82 detects the change of sign of the current setpoints and, after the corresponding intermediate circuit current has become zero, the respective current controllers 51 , 52 are blocked via signals RSP 1 and RSP 2 and the pulses of the machine converter are transmitted via control sets 71 and 72 respectively Machine converter control suppressed. This process is common in direct current technology. The current-free pause of a few milliseconds practically does not affect the torque here, since the setpoint of the corresponding DC link current almost disappears. On the formation of a torque setpoint - z. B. by a superimposed speed controller - is not discussed here, since this, like the operation of the converter motor at higher speeds and load commutation, is not part of the invention.

In another embodiment of the invention, the current setpoints for the current regulators 51 , 52 can also be predetermined in a controlled manner, as a result of which the device for detecting the rotor position angle as well as the arithmetic circuit 8 of the sine-cosine encoder 9 and the multipliers 31 , 32 are omitted.

Claims (8)

1.Procedure for reducing the torque ripple of a converter motor with two galvanically separated, three-phase stator winding systems offset by 30 ° from each other, consisting of two converters, each consisting of a line converter, an intermediate circuit choke and a machine converter, by controlling the valves of the line converter in their Intermediate circuit currents that can be influenced in amplitude are fed in the range of low speeds, characterized in that the valves of the line converters are controlled in such a way that the two intermediate circuit currents are offset by 90 ° relative to one another as continuous time-sequential sine half-cycles and in that the valves of the machine converters are controlled in such a way that everyone of the two intermediate circuit currents in the positive and negative direction alternately per sinus half-period via only two of the three phase connections by windings of the two stator winding systems is switched, which are orthogonal to each other in their electrical effect. 2. The method according to claim 1, characterized,  that the setpoints for the DC link currents without recording the The rotor position of the converter can be specified in a controlled manner. 3. The method according to claim 1, characterized, that the setpoints for the intermediate circuit currents by multiplication a common current or torque setpoint with one Sine or cosine function or their amounts depending on the sum of the rotor position angle and the angle between the flux and magnet wheel axis of the converter motor are formed. 4. The method according to claim 1, characterized, that the setpoints for the DC link currents by constant specification the sine or cosine function or their amounts are formed and the desired torque by specifying the angle between Flow and magnet wheel axis of the converter motor as an argument for the Sine or cosine function or their amounts is influenced. 5. The method according to any one of claims 3 or 4, characterized, that the angle between the flux and the magnet wheel axis of the converter motor is obtained by replicating the machine equation. 6. The method according to claim 3, characterized, that the angle between the flux and the magnet wheel axis of the converter motor by multiplying a predeterminable maximum angle value by the common torque or current setpoint is obtained. 7. The method according to claim 4, characterized, that the angle between the flux and the magnet wheel axis of the converter motor by multiplying a specifiable maximum angle value by one Sin function depending on one for both DC link currents common torque or current setpoint is obtained.   8. Circuit arrangement for performing the method according to claim 1, characterized in
- That a sine-cosine encoder ( 9 ) is provided, the input as an argument, the sum of an angle encoder or resolver ( 6 ) on the rotor of the converter motor ( 3 ) output signal depending on the rotor position angle ( 2 ) of the converter motor ( 3 ) and one a signal emitted by a computing circuit ( 8 ) is fed as a function of the desired angle between the flux and the magnet wheel axis of the converter motor ( 3 ),
- That two output-side setpoints for two intermediate circuit current controllers ( 51 , 52 ) output multipliers ( 41 , 42 ) are provided, one input of which is connected to the sine or cosine output of the sine-cosine encoder ( 9 ) and the other input a common current or torque setpoint is supplied and
- That two control devices ( 71 , 72 ) for the valves of the machine power converter ( MSR 1 , MSR 2 ) are provided, the input side with the angle encoder or resolver ( 6 ) and the other with an evaluation logic ( 81 , 82 ) for becoming zero the intermediate circuit currents are connected.