DE1563228C - Method for controlling the torque delivered by an asynchronous machine - Google Patents

Description

Rotor current I ₂ must remain approximately constant. Like F i g. 1 shows, a phase rotation of the main flux by the value Αφ is necessary to achieve the new equilibrium position. This means that the rotating field would have to suddenly change its spatial position in relation to the rotor. Since such a sudden change, as already explained, is not possible, the torque cannot be changed suddenly or at high speed with the known control.

The present invention is based on the task of applying the known control method to this end improve the fact that a quick change in torque is possible, thus avoiding the difficulty explained will.

To solve this problem it is proposed according to the invention that when changing the predetermined Torque also a change in the angle between stator current and main flow without a sudden change in the spatial position of the rotating field relative to the rotor is caused.

Fig. 3 shows an embodiment of the invention. A three-phase squirrel cage motor 3 is fed from a DC voltage source U ₉ via an inverter 1 which can be controlled in terms of frequency and amplitude of the output voltage. The current in the three motor leads is measured with the aid of the transducers 2a, 2b, 2c, and the actual current value h is formed by the summing element 2, which is compared in point 6 with the current setpoint I _s. The difference AI is entered into the controller 4 for the inverter 1. At the same time, a digital encoder 5 coupled to the machine 3 maps the rotational frequency / ". At point 7, the desired slip frequency / _{s is} added to this circulation frequency f _n. The sum frequency / is also entered into the controller 4.

The torque can be set by specifying the slip frequency f _s and the stator current / _s. In order to couple the two variables with one another in such a way that the main flow of the machine remains constant during an adjustment, corresponding function generators 11 and 12 are provided. A change in the voltage at point α thus results in a change in the torque with a constant main flow. In Fig. 3 also shows a superimposed speed control in which the machine's torque is used as the manipulated variable. With the aid of the converter 8, the analog speed actual value ni is formed from the frequency f _n , which is compared in point 9 with the nominal value n _s. The difference is amplified in the control amplifier 10. It is given at point α to the “actuator” of the superimposed speed control arrangement.

According to the invention, the elements 13 and 14 are additionally provided in the arrangement. The function generator 13 maps the associated angle φ as an analog value depending on the slip frequency, and the converter 14 generates a corresponding number of pulses N ₉ for each change in φ , which are introduced into the control loop at point 15 and

ίο a corresponding change in the angle of the stator current effect opposite the main river. The angle between the stator current and the main flow in the machine as a function of the rotor frequency can either be calculated or measured. The characteristic of the Function generator 13 is set according to the determined results.

If the speed of a squirrel-cage machine fed by an inverter or converter is increased, so one reaches a point, the so-called

Ao th type point, where the maximum possible output voltage of the inverter or converter is just about sufficient to generate the nominal flow in the machine. At higher speeds the machine can can only be operated with reduced flow. Since you are above the type point by intervening in the current control loop the current in the machine cannot be sustained in this area in general the maximum inverter voltage and the slip frequency are specified. To also in this speed range to improve the dynamic behavior of the squirrel cage machine above the type point, special means are provided in a further embodiment of the invention, which are dependent cause a correction of the angular rotation of the speed of the squirrel cage machine. F i g. 3 shows an embodiment of this additional measure. The actual speed value obtained from the converter is sent to the amplifier 16, the output of which is corrected to the function generator 13 acts. The correction function can also be determined here by calculation or measurement and are set in the function generator 13. The invention not only relates to squirrel cage machines, which are fed via power converters. The specified control method can always be used if for the squirrel cage machine a power supply of some kind is available, its output voltage or output current can be changed in frequency and amplitude.

1 sheet of drawings

Claims (3)

1 2 claims: remains constant. The output variable of the control follows the setpoint more precisely, the shorter the 1. The method for controlling the rise time of the control loop is. Asynchronous machine output torque, such a compensatory capacity achieved z. B. in which the asynchronous machine is fed by a voltage source with an adjustable frequency, which is largely similar to the one fed and regulated, the asynchronous motor is regulated according to the French patent, the stator current is regulated and the slip frequency font 1 381 246 is specified as less than one percent speed and as a manipulated variable for the rotation - Deviation when torque is applied to the target value of the stator current and the 0 to the maximum torque.
Serve slip frequency, the predeterminable values of which io apart from the fact that at. The above are coupled with each other that the main known arrangements the problem of the control flow of the machine remains approximately constant, the rotation output by an asynchronous machine, characterized in that at the moment, especially when there is a rapid change in the specified torque, the torque also changes , neither recognized nor treated as a result of a change in the angle between stator current 15, the invention and main flow differs without a sudden change thereby advantageously from the arrangements of the Entder spatial position of the rotating field relative to counter-holdings that is caused by rapid change of the rotor. Torque occurring compensation processes not 2. The method according to claim 1, characterized in that they are managed in such a way that they are countersigned, that by a function generator of the 20 stand a regulation can be made, but they Angles between stator current and main flow in are avoided from the outset. It is still Dependence of the predetermined slip frequency to determine that with the arrangement of said shown analogously and this value on a French patent specification with specification of the downstream tolerance Converter is given, the limit for the speed no teaching is given to the effect proportional to the change in its input voltage, in which way the torque tion emits a number of impulses that change the. cause required angular rotation. The known arrangements and theirs 3. The method according to claim 1, characterized in that the methods used are not suitable to operate shows that the angular rotation as a function of rapid changes in the torque of the machine from the speed of the asynchronous machine to generate correct 30, since when changing the specified is yawed. Sizes of stator current and slip frequency output processes occur in the machine, which are themselves - Resist a quick change. This is used to explain these processes in more detail 35 the F i g. 1, which shows the phasor diagram from the stator The invention relates to a method for the current I ₁ , the rotor current I ₂ and the magneti-control of the ab- sierungsstrom (no-load current) I _m from an asynchronous machine. The time phase given torque at which the asynchronous of the main flux Φ coincides with the magnetizing machine from a voltage source adjustable current I _m . The vector diagram is fed at a frequency, the stator current is regulated and shown 40 times. In the illustration and the further the slip frequency is given and as a manipulated variable explanation it is assumed that the slip for the torque of the target value of the stator current is relatively small, so that the leakage resistance of the. and the slip frequency are used, the specifiable rotor values of which are coupled to one another with respect to the effective resistance of the rotor in such a way that it is negligibly small. The angle φ is the main time flow of the machine, which remains approximately constant. 45 phase angle between the stator current and the Due to the modern converter technology - especially the main flow of the machine. It corresponds to the special angle between the stator current coating created by the stator current coating - it has become possible to build up the stator rotating field excitation voltage generated by the inverter and the converter and its output voltage. rotating field. · If frequency and amplitude are varied within wide limits in the known Anin 5 ° order, the stator current can be varied by the amount Al _1. Enlarges with the help of such power converter, the inductor current has the value J ₂ 'ananordnungen to squirrel cage machines can take to ensure that the resulting excitation run I _m and among others in such a way that the order of the river remain constant. A fast stator current of the machine is regulated and the electrical change of the rotor frequency (slip frequency) of the machine, which determines the torque, is only possible if the rotating field, which is linked to a given value with the rotor winding, is not maintained, neither its amplitude nor its. spatial position to the runner suddenly changes. In In this context, a procedure is used for both cases would otherwise equalizing currents in the Control of the rotor winding induced by an asynchronous machine, which is a fast specified torque (special print SSW 60 oppose change. As already stated, 426/329 from "Siemens-Zeitschrift" 39, year 1965, are in the familiar arrangement of the stator current S. 199 to 205), in which the asynchronous machine of and changed the frequency together in such a way that a voltage source of adjustable frequency, the amplitude of the rotating field remains constant. the the stator current is regulated and the slip frequency change in the stator current by the value ZlZ ₁ leads are specified. As a manipulated variable for the torque 65 to a new equilibrium position, which is shown in FIG. 1 then serve the setpoint of the stator current and which is shown in dashed lines. The one shown in dashed lines Slip frequency, the predefinable values of which must be set in such a vector diagram because of the are coupled that the main flux of the machine angle between the rotor voltage E ₂ and the