CN201937536U - Single regulating loop indirect torque control device of three-phase induction motor - Google Patents

Single regulating loop indirect torque control device of three-phase induction motor Download PDF

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Publication number
CN201937536U
CN201937536U CN2011200055398U CN201120005539U CN201937536U CN 201937536 U CN201937536 U CN 201937536U CN 2011200055398 U CN2011200055398 U CN 2011200055398U CN 201120005539 U CN201120005539 U CN 201120005539U CN 201937536 U CN201937536 U CN 201937536U
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torque
phase
motor
stator
vector
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王和平
阮浩
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WUHAN LINGDIAN AUTOMOBILE ELECTRONIC CONTROL SYSTEMCO., LTD.
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WUHAN LINGDIAN AUTOMOBILE ELECTRONICS CO Ltd
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Abstract

The utility model discloses a single regulating loop indirect torque control device of a three-phase induction motor, which relates to the technical field of motor driving and AC speed regulation. The single regulating loop indirect torque control device is provided with a indirect torque controller, takes a 32-bit digital signal processor as a core which is provided with a corresponding peripheral circuit; and software of the single regulating loop indirect torque control device comprises a flux linkage observation and torque calculation unit, a steady state slip frequency calculation unit, a rotation speed sampling period integral unit, a torque regulator unit, a stator flux linkage vector amplitude and phase calculation unit and a space voltage vector calculation output unit. The method mainly utilizes the effective value formula of each phase electromotive force of a motor stator U>>E=4.44kfNF, i.e., the ratio of the voltage vector amplitude to the phase increment is kept to be be in constant relationship when the movement trajectory of the stator flux linkage vector is a flux linkage circle, so that the space voltage vector of the next period for controlling the motor is obtained. The device only needs a torque single PI regulating loop, so that the structure of a system is simple, the dynamic performance of the system is improved, and the high performance control of a three-phase induction motor drive system is achieved.

Description

The indirect torque control unit in a kind of three phase induction motor dull joint loop
Technical field
The utility model relates to motor-driven and ac speed control technology field, relates in particular to the indirect torque control unit in a kind of three phase induction motor dull joint loop.
Background technology
Alternating current machine with respect to direct current machine simple in structure, safeguard easily, aspects such as environmental requirement is low and energy-conservation and increase productivity had enough advantages, make AC speed regulating extensively apply among industrial and agricultural production, communications and transportation, national defence and the daily life.Along with the high speed development of power electronic technology, microelectric technique, control theory, ac speed control technology has also obtained significant progress.
Mainly contain two kinds of vector control and direct torque control at present in high performance AC speed regulating field:
1, doctor Hasse of the nineteen sixty-eight Darmstader college of engineering has tentatively proposed field orientation control (Field Orientation) theory, this theory is summed up and realized at the F.Blaschke by Siemens Company in 1971 afterwards, and deliver with the form of patent, progressively improve and formed present various vector control methods.
2, for direct torque control, general document is thought what it was proposed at first respectively in 1985 by the I.Takahashi of the M.Depenbrock professor of German Rule university and Japan.Direct torque control for the magnetic linkage circle, its basic thought be the locus and the size of accurate observation stator magnetic linkage and keep its amplitude substantially constant and the condition of accurately computational load torque under, control the instantaneous rotary speed of motor stator magnetic linkage by the instantaneous input voltage of control motor, change its instantaneous revolutional slip, reach the purpose of direct control motor output rotor.Different with vector control inwardly in control is that direct torque control is come indirect Control current by direct controlling torque and magnetic linkage, does not need complicated coordinate transform, therefore have simple in structure, torque response fast and to advantages such as the parameter robustness are good.
In order to reduce or torque pulsation when eliminating low speed, improve the rotating speed control precision, and then enlarge the speed adjustable range of direct Torque Control, in recent years, be applicable to that indirect torque (ISC) control technology of moving has been subjected to various countries scholars' extensive attention under low speed.ISC is the set-point that decides the stator voltage space vector of motor by the magnetic linkage increment of the adjacent control cycle of accurate Calculation, realizes electromagnetic torque is controlled and regulated, and the running orbit that has guaranteed stator magnetic linkage simultaneously is for circular.But the needed feedback quantity of this control technology all is the forecast model by motor to be calculated, and needs the accurate motor forecast model of design, and exists magnetic linkage and two regulating loops of torque, design and use complicated.
Summary of the invention
The purpose of this utility model just is to overcome the shortcoming and defect that prior art exists, and provides a kind of three phase induction motor dull joint loop indirect torque control unit.
The purpose of this utility model is achieved in that
One, the dull joint of the three phase induction motor indirect torque control unit in loop (abbreviation device)
This device comprises power supply, three phase induction motor, power inverter, electric current and voltage detecting unit, motor speed detecting unit;
Be provided with indirect torque controller;
Power supply, power inverter and three phase induction motor connect to form major loop successively, and three phase induction motor is rotated;
Power supply is connected with the electric current and voltage detecting unit respectively with power inverter, and three phase induction motor is connected with the motor speed detecting unit, detects voltage, electric current and rotating speed respectively;
The electric current and voltage detecting unit is connected with indirect torque controller respectively with the motor speed detecting unit, and torque controller and power inverter connect to form control loop indirectly, realizes indirect torque control.
Two, the dull joint of the three phase induction motor indirect method for controlling torque in loop (abbreviation method)
This method comprises the following steps:
1. according to stator voltage vector equation ψ s=∫ (u s-R si s) dt calculates stator magnetic linkage,
ψ sBe stator magnetic linkage, u sBe stator voltage, R sBe stator resistance, i sBe stator current;
2. according to electromagnetic torque equation T enψ s* i sCalculate electromagnetic torque,
T eBe electromagnetic torque, Ρ nBe motor progression;
3. the command value and the actual value of electromagnetic torque are done PI calculating, draw the integration dynamic increment Δ Xd of the dynamic slippage of torque a sampling period;
4. the phase place stable state increment Delta X0 addition in one-period can get magnetic linkage at a total phase increment Δ X of sampling period with integration dynamic increment Δ Xd and magnetic linkage;
5. utilize the effective value formula U E=4.44 k f N F of the every emf phase of motor stator, promptly voltage vector amplitude and phase increment ratio are the space voltage vector that the constant relation can obtain next periodic Control motor,
U is a motor stator voltage, and E is the stator-induced electromagnetic kinetic potential, and f is a stator frequency, and K is a fundamental wave winding coefficient, and N is a stator winding circle, and F is the air-gap flux amount, but the NF Approximate Equivalent is the motor stator magnetic linkage;
6. drive three-phase inverter by the drive signal (SVPWM) that the space voltage vector method is calculated and output pulse width can be regulated;
7. detect coherent signal in real time and feed back to digital signal processor by voltage, electric current and motor speed detecting unit and carry out calculation process.
In the above-mentioned steps, except that step 5., other step is general procedure.
The utlity model has following advantage and good effect:
1, only needs the single PI regulating loop of torque, make system configuration simple, improve the dynamic property of system, realize the high performance control of three phase induction motor drive system;
2, can realize Speedless sensor control three phase induction motor;
3, can be widely used in various three phase induction motors, as threephase asynchronous, three-phase synchronous motor and permanent magnet synchronous motor etc.
Description of drawings
Fig. 1 is the structured flowchart of existing apparatus (two regulating loop);
Fig. 2 is the block diagram in this device (dull joint loop);
Fig. 3 is that three phase induction motor MT axle is rotor field-oriented equivalent circuit diagram;
Fig. 4 is the stator magnetic linkage trajectory diagram of indirect torque control mode;
Fig. 5 is the space vector of voltage and the flux linkage space polar plot of three phase induction motor;
Fig. 6 is the structured flowchart of indirect torque controller;
Fig. 7 is a software Real-time Interrupt Processing module flow chart.
Among the figure:
000-power supply;
100-three phase induction motor;
200-power inverter;
300-indirectly torque controllers,
301-flux observation and torque calculation unit,
302-stable state slippage computing unit,
303-rotating speed sampling period integral unit,
304-torque controller unit,
305-stator magnetic linkage vector magnitude and phase calculation unit,
306-space voltage vector calculates output unit,
307-magnetic linkage adjuster,
308-stator magnetic linkage incremental computations unit;
400-electric current and voltage detecting unit;
500-motor speed detecting unit.
English to Chinese
PI: the abbreviation that is ratio and integration.In a single day deviation has appearred in system, and ratio is regulated and produced regulating action immediately in order to reduce deviation.Proportional action is big, can accelerate to regulate, and reduces error, but excessive ratio makes the stability decreases of system, even causes the instability of system.Because error is arranged, integration is regulated and is just carried out, and until indifference, integration is regulated and stopped, and integration is regulated output one value often.The power of integral action depends on and integration time constant Ti that Ti is more little, and integral action is just strong more.Otherwise Ti is greatly then a little less than the integral action, adds integration and regulates the stability of a system is descended, and dynamic response is slack-off.Integral action is regulated with ratio and is combined, and forms pi regulator.
SVPWM: the abbreviation that is space vector pulse width modulation (Space Vector Pulse Width Modulation).The desirable magnetic linkage circle of three-phase symmetrical motor stator is a normative reference when powering with three-phase symmetrical sine wave voltage, does suitable switching with the different switching modes of three-phase inverter, thereby forms the PWM ripple, follows the trail of its accurate magnetic linkage circle with formed actual flux linkage vector.Traditional SPWM method is from the angle of power supply, and generating the sine-wave power of a Frequency Adjustable pressure regulation, and the SVPWM method regards inversion system and asynchronous machine as an integral body and consider that model is fairly simple, also is convenient to the real-time control of microprocessor.
Embodiment
Describe in detail below in conjunction with drawings and Examples:
One, existing apparatus (two regulating loop)
As Fig. 1, existing system is drawn together power supply 000, three phase induction motor 100, power inverter 200, indirect torque controller 300; Electric current and voltage detecting unit 400, motor speed detecting unit 500;
Described indirect torque controller 300 its softwares comprise that flux observation and torque calculation unit 301, stable state slippage computing unit 302, rotating speed sampling period integral unit 303, torque controller unit 304, space voltage vector calculate output unit 306, magnetic linkage adjuster 307 and stator magnetic linkage incremental computations unit 308;
Its operation principle is:
Three phase induction motor stator magnetic linkage vector adopts the stator voltage vector equation to try to achieve, electromagnetic torque adopts stator magnetic linkage vector and stator current vector to draw, adopt two PI regulating loops of stator magnetic linkage and torque then and in conjunction with the mechanical angle speed of motor, calculate stator magnetic linkage respectively at the amplitude increment and the phase increment in a sampling period, thereby draw the stator magnetic linkage increment in this sampling period; Calculate the space vector of control output voltage again by space vector, realize the magnetic linkage and the torque control of asynchronous motor.
Two, this device (dull joint loop)
1, overall
This device is on the basis of existing apparatus (two regulating loop), having removed magnetic linkage adjuster 307 and stator magnetic linkage incremental computations unit 308 in the torque controller 300 indirectly, is provided with stator magnetic linkage vector magnitude and phase calculation unit 305.Utilizing the effective value formula U E=4.44 k f N F of the every emf phase of motor stator, the movement locus that promptly keeps the stator magnetic linkage vector according to the phase increment of input is that magnetic linkage bowlder stator voltage vector magnitude and phase increment ratio are that constant concerns the space voltage vector that can obtain next periodic Control motor.
As Fig. 2, this device comprises power supply 000, three phase induction motor 100, power inverter 200, electric current and voltage detecting unit 400, motor speed detecting unit 500;
Be provided with indirect torque controller 300;
Power supply 000, power inverter 200 and three phase induction motor 100 connect to form major loop successively, make three phase induction motor 100 motions;
Power supply 000 is connected with electric current and voltage detecting unit 400 respectively with power inverter 200, and three phase induction motor 100 is connected with motor speed detecting unit 500, records voltage, electric current and rotating speed respectively;
Electric current and voltage detecting unit 400 is connected with indirect torque controller 300 respectively with motor speed detecting unit 500, and torque controller 300 and power inverter 200 connect to form control loop indirectly, realizes indirect torque control.
Described indirect torque controller 300 is core with the 32-bit number signal processor and disposes correspondent peripheral circuit that its software comprises that flux observation and torque calculation unit 301, stable state slippage computing unit 302, rotating speed sampling period integral unit 303, torque controller unit 304, voltage vector amplitude and phase calculation unit 305 and space voltage vector calculate output unit 306;
Described flux observation and torque calculation unit 301 are: according to electric moter voltage and the current signal gathered, utilize electric moter voltage equation and electromagnetic torque Equation for Calculating to go out actual flux linkage vector and motor torque;
Described stable state slippage computing unit 302 is: constant when stator magnetic linkage, the electromagnetic torque value is during less than maximum electromagnetic torque, according to electromagnetic torque and the proportional slip angular frequency that calculates of slip angular frequency;
Described rotating speed sampling period integral unit 303 is: the static phase increment of stator magnetic linkage can be drawn the Calais with the mechanical rotor angular frequency mutually by the slip angular frequency in the sampling period;
Described torque controller unit 304 is: the actual torque according to given torque and feedback carries out proportional integral calculating, draws the dynamic phasing increment of stator magnetic linkage;
Described flux linkage vector amplitude and phase calculation unit 305 are: according to the phase increment of stator magnetic linkage of input, i.e. the phase increment of stator voltage vector utilizes the effective value formula of the every emf phase of motor stator U E=4.44 k F N F,Be stator magnetic linkage when constant stator voltage vector magnitude and phase increment ratio be the stator magnetic linkage vector of the following one-period that the constant relation can controlled motor;
Described space voltage vector calculates output unit 306: for the movement locus that guarantees the stator magnetic linkage vector forms circular space rotating magnetic field, utilize the on off state and the adjustment of sequential combination and switching time of inverter power switching tube, overlap with the magnetic linkage circle with the running orbit that guarantees space vector of voltage, the stator magnetic linkage vector control is equivalent to the stator voltage vector control, produce less harmonic wave like this, and the higher output of DC power supply voltage utilization.
Flux observation and torque calculation unit (301) are divided into two-way:
One the tunnel is that flux observation and torque calculation unit (301) and torque controller unit (304) are mutual;
Another road is flux observation and torque calculation unit (301), and stable state slippage computing unit (302) and rotating speed sampling period integral unit (303) are mutual successively;
Mutual after rotating speed sampling period integral unit (303) and torque controller unit (304) addition with voltage vector amplitude and phase calculation unit (305), and then calculate output unit (306) alternately with space voltage vector again.
2, functional block
1) main power circuit
(1) power supply 000
Main circuit adopts three-phase not control rectification and strengthens capacitor filtering, produces too high pump when excessive transient current and motor braking occurring when avoiding powering on and gives birth to voltage, the energy bleed-off circuit when being provided with soft starting circuit and dynamic braking.Drive circuit adopts the negative and positive dual power power supply, provides 4 road or 6 tunnel power supplies of isolating mutually 000 by Switching Power Supply.
(2) inverter 200
Inverter 200 adopts 6 IGBT of Infineon to form the three phase full bridge inverter circuits, and it is little, in light weight, simple in structure to have a volume, and Installation and Debugging are convenient.And design has fault secure circuits such as overvoltage, overcurrent, overheated and under voltage.Its peripheral circuit mainly comprises 6 road PWM drive signals and rapid light coupling isolation, drives simple and reliable.
2) control loop
(1) indirect torque controller 300
As Fig. 6, torque controller adopts 32 fixed-point dsp TMS320F28035 of the up-to-date release of American TI Company as control chip indirectly, this DSP has 32 kernels, have monocycle 32 * 32 hardware multipliers and monocycle atomic instructions executive capability, can realize complicated control algolithm.The various integration modules that also comprise oscillator, analog comparator, electrification reset and power down protection etc. on powerful ADC analog to digital converter, special-purpose high resolution PWM, the high-precision sheet simultaneously.Floating-point control law accelerator (CLA) can be independent of kernel operation control loop.Use the task manager control inverter, by the position and the rate signal of orthogonal coding circuit interface detection motor, and AD unit sensed current signal, make control system have control precision height, simple, the reliability advantages of higher of hardware.
(2) electric current and voltage detecting unit 400 is selected closed loop current type Hall element sampled voltage and current signal for use, and by 12 built-in ADC of DSP sampled signal is carried out analog-to-digital conversion.
(3) motor speed detecting unit 500 is selected high-resolution rotation photoelectric encoder for use.
The operation principle of this device is:;
As Fig. 3 (three phase induction motor MT axle is rotor field-oriented equivalent circuit diagram), in torque is controlled indirectly, stator magnetic linkage vector ψ sThe variation of amplitude or phase place is to rely on to change applied voltage vector u sRealize.When the applied voltage flip-flop, in the starting stage of this transient process, because the equivalent magnetizing inductance of field excitation branch line is bigger, i MHave little time to change, can think that rotor flux is constant; For the variation of stator current, field excitation branch line is equivalent to open circuit, and applied voltage has just changed torque component, and the speed that stator current changes depends primarily on stator transient inductance L S, owing to the equivalent magnetizing inductance of stator and rotor leakage inductance much smaller than field excitation branch line, so the variation of stator current is far faster than i MVariation, make ψ sVariation faster than rotor flux vector ψ rChange ψ fast by the applied voltage vector s, make stator magnetic linkage vector ψ sWhen amplitude remains unchanged, change ψ sWith respect to ψ rSpace phase δ Sr, make its leading or hysteresis, just by changing δ SrCome the controlling torque current i TBecause rotor flux vector ψ rItself rotates, and changes δ at any time SrSize, be a kind of continual dynamic control mode, whole control process is in " transition " state always, is to rely on stator magnetic linkage vector ψ sRegulate δ with respect to loitering of ψ Sr.Result's (torque deviation) of this dependence torque control judges stator magnetic linkage vector ψ sTrend, just the control mode of indirect torque is taked in torque to three phase induction motor.
As Fig. 2 (this apparatus structure block diagram), three phase induction motor stator magnetic linkage vector adopts the stator voltage vector equation to try to achieve, electromagnetic torque adopts stator magnetic linkage vector and stator current vector to draw, and torque controller output is the phase integral dynamic increment of dynamic slippage a sampling period then.And the stable state slippage is come out by magnetic linkage and torque calculation, stable state slippage and electromechanics angular speed sum obtain synchronous angular velocity, it is carried out integration a sampling period just can obtain the phase place stable state increment of magnetic linkage in one-period, make it to get magnetic linkage at a total phase increment of sampling period with the dynamic increment addition.For guaranteeing that the stator magnetic linkage space vector moves along circular path, utilizes the effective value formula of the every emf phase of motor stator:
U E=4.44 k f N F, stator voltage vector magnitude and phase increment ratio were the space voltage vector that constant relation can controlled motor when promptly stator magnetic linkage was constant.Decide space voltage vector by the phase increment that calculates magnetic linkage, can guarantee that not only magnetic linkage track is circular, but also stable state and dynamic the adjusting have been carried out in torque.Can also resemble the vector control by increasing the sampling period and reduce switching frequency and can not produce extra torque pulsation, this mainly is because the phase increment of magnetic linkage can accurately calculate in a sampling period.Therefore torque control has good stable state and dynamic property indirectly, can reduce low-speed torque ripple greatly in jumbo speed governing, increases speed adjustable range.
Two, method
1, the relevant course of work of this method:
At first digital signal processor detects and gathers coherent signal, calculate stator current vector, adopt the stator voltage vector equation to try to achieve the stator magnetic linkage vector then, draw the actual electromagnetic torque with stator magnetic linkage vector and stator current vector, export the phase integral dynamic increment of dynamic slippage by torque controller a sampling period according to the difference of actual torque and target torque.And the stable state slippage is come out by magnetic linkage and torque calculation, stable state slippage and electromechanics angular speed sum obtain synchronous angular velocity, it is carried out integration a sampling period just can obtain the phase place stable state increment of magnetic linkage in one-period, make it to get magnetic linkage at a total phase increment of sampling period with the dynamic increment addition.For guaranteeing that the stator magnetic linkage space vector moves along circular path, utilize electric moter voltage vector magnitude and phase increment ratio to concern and space voltage vector that voltage equation can controlled motor for constant.Decide space voltage vector by the phase increment that calculates magnetic linkage, can guarantee that not only magnetic linkage track is circular, but also stable state and dynamic the adjusting have been carried out in torque.Can also resemble the vector control by increasing the sampling period and reduce switching frequency and can not produce extra torque pulsation, this mainly is because the phase increment of magnetic linkage can accurately calculate in a sampling period.Therefore torque control has good stable state and dynamic property indirectly, can reduce low-speed torque ripple greatly in jumbo speed governing, increases speed adjustable range.
What Fig. 4 represented is the stator magnetic linkage trajectory diagram of indirect torque control mode, magnetic linkage ψ s ( k) and ψ s ( k1) represents respectively kWith k(both differ a control cycle to the stator magnetic linkage space vector in 1 moment TS), Δ δ Sr( k) expression stator magnetic linkage space vector is from the k1 to kParallactic angle increment constantly, Δ ψ s ( k) increment of an expression stator magnetic linkage space vector control cycle be ψ s ( k) and ψ s ( k1) difference.And native system directly adopts the stator magnetic linkage vector to represent the magnetic linkage increment, and the stator magnetic linkage vector is to move along circumference.
Can be by the synthetic required voltage vector of the method for space vector of voltage pulse-width modulation (SVPWM).Space vector of voltage as shown in Figure 5.Because the restriction of power electronic device switching frequency can only produce certain polygon and approach desirable circle.Under the situation of Fig. 5, suppose that the reference voltage vector is at a computing cycle Tz (Tc/2, Tc is a switch periods) in remain unchanged, and the mean value of inverter output voltage is identical with the reference voltage vector in the computing cycle, can determine that so just the time value of adjacent with the reference voltage vector two effective voltage vectors and no-voltage vector solves the time of effective voltage vector and the effect of no-voltage vector thus.
In torque was controlled indirectly, if adopt voltage integration to calculate the stator magnetic linkage vector, unique parameter of electric machine of using was stator resistance R in whole control process S, when stator frequency is low, R SVariation very big to the estimated result deviation of magnetic linkage, also directly have influence on the accuracy that torque is estimated, the design adopts and implements to dynamic observe and revise stator resistance R based on the fuzzy neural network Adaptable System of stator current deviation S
When the asynchronous machine rotating speed reaches rated speed, because the stator voltage of motor can't continue to increase torque more near the size of back-emf.Must reduce the size of back-emf this moment, just can make in the range of speeds of motor more than rated speed and move.Can effectively limit the size of back-emf by the amplitude that reduces stator magnetic linkage, just can realize weak magnetic function, thus expanding governing.Before rated speed, be that basic fast scope is permanent torque adjustment, in weak magnetic scope is by electric moter voltage vector magnitude and DC bus-bar voltage normalized ratio are determined the stator flux linkage set value, variation by the flux linkage set value, realize dynamic adjustments on the one hand, realize the permanent power adjustments of weak magnetic speed-up on the other hand average torque.
2, software design
Software design of the present utility model can be divided into initialization module, major cycle control module and Real-time Interrupt Processing module.
Because what the utility model adopted is indirect torque control strategy, its groundwork is to be finished by the Real-time Interrupt Processing module, the Real-time Interrupt Processing module as shown in Figure 7, because digital signal processor will be born the burdensome task of management, coordination, each link of supervisory control system, and moment controlling system belongs to the higher motion control category of rapidity requirement indirectly, the variation of system controlled quantity of state is very fast, and this just requires the sampling processing cycle of system short as much as possible.In view of native system is very high to the requirement of real-time, structure and their sequential each other that must rationally arrange each program module when software design properly cooperate.
Wherein initialization module and major cycle control module are module commonly used.
As Fig. 7, software Real-time Interrupt Processing module flow process is:
1st, interrupt inlet A;
2nd, the B that keeps the scene intact;
3rd, electric current and voltage sampling and rotating speed detect C; (the corresponding method step 7.)
4th, CLARKE transformation calculations current phasor D;
5th,, calculate stator magnetic linkage E according to the electric moter voltage equation; (the corresponding method step 1.)
6th,, calculate motor torque F according to the electromagnetic torque equation; (the corresponding method step 2.)
7th, motor torque PI regulates G; (the corresponding method step 3.)
8th, the dynamic increment of the stator magnetic linkage phase place of torque PI adjusting output adds that the stable state increment of stator magnetic linkage phase place draws the reference stator voltage vector phase increment H of output; (the corresponding method step 4.)
9th, be that constant draws reference voltage vector I by voltage vector amplitude and phase increment ratio; (the corresponding method step 5.)
10th, calculate and export SVPWM value J by means of space vector representation; (corresponding step 6.)
11st, recover on-the-spot K;
12nd, interrupt returning L.
Three, test result
Test waveform and actual test result show, adopt indirect torque control, and the stator magnetic linkage vector moves with circular trace, and the stator current sine is good, and torque step response is fast, only is 10ms; Theoretical and test proof, torque control can be avoided the unfavorable result of direct torque control when low-speed region work indirectly, i.e. the minimum ON time restriction of switching device and the bigger torque pulsation that causes, and the magnetic linkage track that stator resistance causes distorts.The indirect clear physics conception of torque control mode, simple in structure, torque responsing speed fast, the parameter robustness is good, and need not complicated coordinate transform and calculating, will be widely used in three phase induction motor speed governing field.

Claims (4)

1. the indirect torque control unit in a three phase induction motor dull joint loop, comprise power supply (000),
Three phase induction motor (100), power inverter (200), electric current and voltage detecting unit (400), motor speed detecting unit (500);
It is characterized in that:
Be provided with indirect torque controller (300);
Power supply (000), power inverter (200) and three phase induction motor (100) connect to form major loop successively;
Power supply (000) is connected with electric current and voltage detecting unit (400) respectively with power inverter (200), and three phase induction motor (100) is connected with motor speed detecting unit (500);
Electric current and voltage detecting unit (400) is connected with indirect torque controller (300) respectively with motor speed detecting unit (500), and torque controller (300) and power inverter (200) connect to form control loop indirectly;
Described indirect torque controller (300) is core with the 32-bit number signal processor and disposes correspondent peripheral circuit.
2. by the described device of claim 1, it is characterized in that:
Inverter (200) selects for use 6 IGBT of Infineon to form the three phase full bridge inverter circuit.
3. by the described device of claim 1, it is characterized in that:
Electric current and voltage detecting unit (400) is selected closed loop current type Hall element for use.
4. by the described device of claim 1, it is characterized in that:
Motor speed detecting unit (500) is selected high-resolution rotation photoelectric encoder for use.
CN2011200055398U 2011-01-10 2011-01-10 Single regulating loop indirect torque control device of three-phase induction motor Expired - Lifetime CN201937536U (en)

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Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102364871A (en) * 2011-10-24 2012-02-29 洛阳理工学院 Method for directly controlling torque of induction motor and control device
CN102427326A (en) * 2011-12-20 2012-04-25 中国东方电气集团有限公司 Preestimate control method for electromobile asynchronous motor
CN103326651A (en) * 2013-04-18 2013-09-25 江苏华骋科技有限公司 Alternating current motor control system based on vector control
CN104009693A (en) * 2014-04-09 2014-08-27 南京航空航天大学 Control method for brushless direct current motors
CN108270203A (en) * 2017-12-14 2018-07-10 北京卫星制造厂 A kind of high-voltage high-power motor driving protection system and method
CN109818540A (en) * 2017-11-21 2019-05-28 杭州三花研究院有限公司 The field weakening control method and motor of motor
CN115356921A (en) * 2022-10-19 2022-11-18 上海泛腾电子科技有限公司 Voltage closed-loop control system for linear driver
CN116995981A (en) * 2023-09-26 2023-11-03 天津德星智能科技有限公司 Current-voltage vector amplitude angle control method

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102364871A (en) * 2011-10-24 2012-02-29 洛阳理工学院 Method for directly controlling torque of induction motor and control device
CN102427326A (en) * 2011-12-20 2012-04-25 中国东方电气集团有限公司 Preestimate control method for electromobile asynchronous motor
CN102427326B (en) * 2011-12-20 2014-04-09 中国东方电气集团有限公司 Preestimate control method for electromobile asynchronous motor
CN103326651A (en) * 2013-04-18 2013-09-25 江苏华骋科技有限公司 Alternating current motor control system based on vector control
CN104009693A (en) * 2014-04-09 2014-08-27 南京航空航天大学 Control method for brushless direct current motors
CN104009693B (en) * 2014-04-09 2016-06-15 南京航空航天大学 A kind of control method for brushless direct current motor
CN109818540A (en) * 2017-11-21 2019-05-28 杭州三花研究院有限公司 The field weakening control method and motor of motor
CN108270203A (en) * 2017-12-14 2018-07-10 北京卫星制造厂 A kind of high-voltage high-power motor driving protection system and method
CN115356921A (en) * 2022-10-19 2022-11-18 上海泛腾电子科技有限公司 Voltage closed-loop control system for linear driver
CN116995981A (en) * 2023-09-26 2023-11-03 天津德星智能科技有限公司 Current-voltage vector amplitude angle control method
CN116995981B (en) * 2023-09-26 2023-12-12 天津德星智能科技有限公司 Current-voltage vector amplitude angle control method

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