RU2587162C1 - Method for energy-efficient dual-zone control of asynchronous motor speed in moment direct control system - Google Patents

Abstract

FIELD: electronic equipment.

SUBSTANCE: invention relates to electrical engineering and can be used in industry and transport in systems of an electric drive with direct control of asynchronous motors' moment (ad). Method of asynchronous motor speed adjustment presupposes direct control of the momentum (Direct Torque Control, DTC), at that, determination of limit momentum calculated by a speed controller, is performed by dividing the specified power of the engine rotor rotation frequency, while the value of the preset power is determined depending on the temperature of the motor stator windings, calculated by a model or measured by a temperature sensor, and can have three fixed values: 1) P_s=P_n; 2) P_s>P_n; 3) P_s<P_n, where P_s is the specified power, P_n is the nominal power of the engine; assignment for the stator flux linkage is determined in the first and second control zones on the basis of preliminary calculated value of ratio between the moment of stator flux linkage and the moment of the engine, providing the minimum value of the stator current at a set moment and having a shape of a curve with saturation.

EFFECT: provision of energy-efficient two-zone adjustment of asynchronous motor at more complete usage of engine in terms of heating and power.

1 cl, 2 dwg

Description

The invention relates to an asynchronous electric drive and can be used in industry and transport in electric drive systems with direct control of the torque of asynchronous motors (HELL).

There is a method of two-zone speed control of an asynchronous electric drive with a weakening of the rotor flow in a vector control system (Kozyaruk A.E., Rudakov V.V. Modern and perspective algorithmic support for variable-frequency electric drives. - St. Petersburg: St. Petersburg Electrotechnical Company, 2004. - Prototype). In this method, the unit for setting the flux linkage in the first regulation zone (at an engine speed below the nominal) sets the nominal flux linkage value of the engine rotor. In the second regulation zone (at an engine speed higher than the nominal one), field weakening (magnetic flux reduction with respect to the nominal value) is achieved by changing the rotor flux linkage task inversely with the increase in the rotational speed relative to the nominal one. Stator current can be minimized by maintaining the equality of the stator current components.

The disadvantages of this method are the complexity traditional for vector systems and the large amount of computation, low resistance to disturbances, the indirect effect on the rotor flux linkage through a change in stator current, the lack of regulation of motor flux linkage in the first zone, underutilization of the motor by power and heating in the second zone.

The known system of direct torque control (Direct Torque Control, - DTC) (Kozyaruk AE, Rudakov VV Systems of direct torque control in variable-frequency AC electric drives. / Ed. By A.G. Naroditsky. - St. Petersburg: St. Petersburg Electrotechnical Company, 2005), which can be used for energy-efficient two-zone control of blood pressure. The direct torque control system implements direct highly dynamic relay control of stator flux linkage and motor torque by deviation. The distinctive features of DTC (block 1 in Fig. 1, 2) include the presence in the system:

- hysteresis relay regulators of stator flux linkage (PPP) and torque (PPm) of an induction motor;

- an electronic adaptive motor model (AMD) for calculating the current controlled coordinates of an induction motor (stator flux linkage, electromagnetic torque, temperature, etc.) based on the value of phase currents, voltage in the DC link and switching function of the autonomous voltage inverter (AIN);

- a phase sector calculator (VFS) in which the current vector of the stator flux linkage is located;

- tabular (matrix) calculator of the optimal motor voltage vector, performed in the form of a block of a logical automaton (UAV) and determining the switching function of the AIN valves.

There are also two algebraic adders in the DTC block. One of them compares the task at the moment M _s coming from the control system and the engine moment calculated by AMD; the resulting mismatch is sent to PPM. The second adder compares the task for the flux link ψ _sз coming from the control system and the flux link of the engine ψ _s calculated by AMD; the resulting mismatch goes to the RRp. AMD also calculates the phase of the flux linkage vector (phase ψ _s ). If necessary, in AMD unit 1 (DTC unit), it is also possible to calculate the temperature of the stator windings of the motor t ^° (Fig. 2).

The DTC system has high speed and, at the same time, it does not require the coordinate converters necessary for the implementation of vector control, the stator current components regulators, cross-feedback compensation units for HELL, organization of pulse-width modulation (PWM). In addition, the system is more resistant to disturbances and inaccuracy of information about the state variables of the control object than the vector system. However, for DTC systems, energy-efficient methods of controlling engines are not well developed, which does not allow the cavity to fully realize all the advantages of DTC.

The objective of the invention is the implementation of energy-efficient dual-zone regulation of an induction motor in a direct torque control system with the most complete use of the engine for heating and power.

The technical result is achieved by the fact that in this method using direct control of the moment, the definition of the task constraint for the moment calculated by the speed controller is made by dividing the set power by the rotational speed of the motor rotor, and the set power is determined depending on the temperature of the stator windings calculated according to the model or measured by the temperature sensor, and can take three fixed values:

1) P _s = P _n ; 2) P _s > P _n ; 3) P _s <P _n

where P _s - set power, P _n - rated engine power;

and the task for stator flux linkage is determined in the first and second control zone by the value of the moment reference based on a previously calculated dependence of the stator flux link on the motor moment, which ensures the minimum value of the stator current at a given moment and looks like a curve with saturation.

Functional diagrams of dual-zone blood pressure control systems that implement this method are presented in FIG. 1 and 2. In the circuit of FIG. 1, the temperature of the induction motor 2 is measured by the temperature sensor of the stator windings, which is built into the AM, and in the circuit of FIG. 2 is calculated according to the model in block 1 (DTC block). The temperature measurement by the sensor is more accurate, therefore, it is preferable (Fig. 1), however, this requires the installation of the sensor in an induction motor. In the absence of a sensor, it is possible to calculate the temperature using the thermal model of the engine, which is included in this case in the adaptive model of the engine of block 1 (Fig. 2), but this reduces the accuracy of determining the temperature.

In both cases, in the presented schemes (Figs. 1, 2) there is an external circuit for regulating the engine speed (angular speed). The rate of rise of the task at the rotation frequency ω _s can be determined by the intensity adjuster (not shown in the diagrams). The actual angular velocity of the rotor HELL is measured by a speed sensor 3 (DFV). The mismatch between the given (ω _h ) and the actual angular speed of the engine (ω), determined in the adder 4, is fed to the speed controller 5, which generates a preliminary task at the moment of the traction motor (Ms _ω ). Then, in block 6, the calculation of the task of the moment taking into account the constraints (BVZM) determines the restrictions and the final task at the moment M _s entering block 1 (DTC), according to the following equations:

where M _zogr - job restriction at the time of blood pressure; M _zmax - _torque limit, usually set based on the permissible current of the valves of the static converter.

The value of the specified power P _s is determined depending on the temperature of the stator windings θ of the motor in block 7 of three fixed values according to the following equations:

where θ _add - allowable temperature of the stator winding HELL.

The stator flux linkage task ψ _sз is determined in block 8 for the first and second zone of blood pressure control according to the task found at the moment M _s using equations (1, 2) based on the previously calculated dependence of the stator flux linkage on the motor moment ψ _sз = f (M _z ) by the condition of minimum stator current, which has the form of a curve with saturation. The found flux link is sent to block 1 (DTC block). The use of DTC allows you to separately control the electromagnetic moment and flux linkage of the motor stator according to the energy-saving law with high speed. The control signals generated in block 1, are fed to the block of the static Converter 9 (block SP) to control the valves AIN.

In the first zone of speed regulation, when low speeds and low tasks are realized at the moment (in case of a reduced engine load), the stator flux linkage automatically decreases according to a given curve ψ _sз = f (M _s ) (Fig. 1, 2). When the load increases, the task at the moment increases (up to M _zmax ) and, accordingly, the task for stator flux linkage increases.

As the engine accelerates and the speed rises upwards from the nominal value, the task for the moment, taking into account the accepted restrictions (see Expressions 1), inevitably decreases with increasing ω and the task for stator flux linkage at the given design dependence ψ _sз = f (M _z ) also decreases . In this case, the engine automatically goes into the field weakening zone (into the second zone).

In this electric drive system, before starting the engine, it is necessary to set a predetermined level of flux linkage. For this, the pre-magnetization mode is used, which consists in setting the task for flux linkage at a given initial level with the task at a moment equal to zero. After magnetization of the blood pressure, the task at the moment increases with the required intensity and then the calculated dependence ψ _sз = f (M _s ) is realized.

Thus, in the first and second zones, the stator flux linkage is controlled according to the energy-saving law, and in the second zone, the maximum permissible motor power is simultaneously controlled depending on the temperature of the windings, allowing it to be dosed to change its overload capacity.

Changing the set power _Pz depending on the temperature of the windings allows to increase the motor power without reducing the service life, temporarily overloading it if necessary, for example, when overcoming lifting by a vehicle or lowering the pressure in the line when increasing the flow rate of the liquid, and also to protect the motor from exceeding temperature . At the same time, the proposed implementation of energy-saving dual-zone regulation in a direct torque control system allows to reduce losses and increase efficiency induction motor.

Claims (1)

A method of dual-zone speed control of an induction motor using direct torque control (Direct Torque Control - DTC), characterized in that in this method the definition of the task limit for the moment calculated by the speed controller is made by dividing the set power by the rotor speed of the motor, and the set value power is determined depending on the temperature of the stator windings of the motor, calculated according to the model or measured by a temperature sensor, and can take three fixed values:
1) P _s = P _n ;
2) P _s > P _n ;
3) P _s <P _n
where R _s - the given power; R _n - rated engine power,
and the task for stator flux linkage is determined in the first and second control zone by the value of the moment reference based on a previously calculated dependence of the stator flux link on the motor moment, which ensures the minimum value of the stator current at a given moment and looks like a curve with saturation.

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