CN113659914A

CN113659914A - Drive circuit for high-speed switched reluctance motor and control method thereof

Info

Publication number: CN113659914A
Application number: CN202110978825.0A
Authority: CN
Inventors: 洪伟泷; 张桂东
Original assignee: Guangdong University of Technology
Current assignee: Guangdong University of Technology
Priority date: 2021-08-25
Filing date: 2021-08-25
Publication date: 2021-11-16
Anticipated expiration: 2041-08-25
Also published as: CN113659914B

Abstract

The invention discloses a drive circuit for a high-speed switched reluctance motor and a control method thereof, wherein the drive circuit comprises the following steps: the direct current power supply and the N-phase winding of the switched reluctance motor, wherein N is a natural number and is more than or equal to 3, and the switch converter consists of an inductor, two capacitors, N +3 switch tubes and N +3 diodes and a control method thereof; when the motor runs at a low speed or a high speed, the capacitor energy stored in the instantaneous power module is released, the low-voltage or high-voltage demagnetization modes are respectively switched, the average demagnetization voltage is adjusted, the rotating speed range is widened, the torque ripple is reduced, and the capacity and the volume of the power capacitor are greatly reduced. Meanwhile, the invention combines PI control to form a multivariable coupling control method for output current, input power and motor rotating speed, compensates instantaneous power ripples of a direct current power supply generated by equal nonlinear factors of output power and motor switching, widens the voltage selection range of the direct current power supply and obviously improves the performance of a switched reluctance motor driving system.

Description

Drive circuit for high-speed switched reluctance motor and control method thereof

Technical Field

The invention relates to a power conversion device for excitation and demagnetization of a switched reluctance motor and a control method thereof, in particular to a small-capacitance multi-level power conversion device based on a multiplexing technology and a control method thereof.

Background

In a new energy automobile system, a switched reluctance motor becomes an important member in the development industry of an electric automobile driving system by virtue of the advantages of simple and reliable motor structure, low manufacturing cost, large starting torque, high fault tolerance, flexible control and the like.

The power converter plays a role in transmitting and distributing power supply energy in a switched reluctance motor driving system, and the driving performance of a motor driving topology influences the running performance of the whole motor. As shown in fig. 1, the asymmetric half-bridge inverter is a typical example applied to a conventional switched reluctance motor driving system because of its simple and reliable structure and control method, and it satisfies that the switched reluctance motors are independent of each other between different phases in the control process, and its control method is simple and reliable, so it is widely used. However, the number of semiconductor devices required by each phase winding of the asymmetric half-bridge converter applied to the switched reluctance motor is large, and a large-capacity electrolytic capacitor needs to be connected in parallel to an input end to absorb power ripples generated by the motor, so that the cost and the volume of the system are increased. Furthermore, the direct current bus voltage on the asymmetric half-bridge converter structure cannot be adjusted, and the rotating speed and torque range of the switched reluctance motor are limited. Therefore, how to provide a solution to the above technical problems is a problem that researchers in this field need to solve. Researchers continuously optimize and improve the power converter on the basis of the asymmetric half-bridge converter, and at present, the power converter topology is mainly researched in the aspects of reducing cost, reducing volume, improving performance and the like.

Aiming at the problems of an asymmetric half-bridge converter, the invention provides a power converter with small capacitance and multiple levels and a control method thereof on the basis of the asymmetric half-bridge converter, and the power converter adjusts average demagnetizing voltage by changing a working mode or duty ratio, thereby widening the rotating speed range and reducing torque ripple; the selection range of the direct-current power supply voltage is widened through a power flow control method, the multiplexing technology is structurally combined, the number of semiconductor devices required by the converter is reduced, and the performance of a switched reluctance motor driving system is remarkably improved.

Disclosure of Invention

The invention aims to increase the output level of a motor driving topology, widen the rotating speed range of a switched reluctance motor, reduce the torque ripple generated by the operation of the motor, structurally reduce the capacitance value and the volume of an electrolytic capacitor required by the topology, reduce the number of semiconductor devices required in the application scene of a multi-phase motor and improve the performance of a switched reluctance motor driving system. The other purpose of the invention is to provide a control method of the power converter, which compensates the output power of the direct current power supply, and performs multivariable coupling control on the output current and the input power while converting the instantaneous power ripple generated by equal nonlinear factors of the motor.

The technical scheme of the device provided by the invention is as follows:

a small capacitance multilevel power converter for high speed switched reluctance motor drives. It is characterized by comprising: the circuit comprises a direct-current power supply, a filter inductor, an instantaneous power module 101, a shared bridge arm 102, a first bridge arm 103, a second bridge arm 104, a third bridge arm 105, an Nth bridge arm 10X and a switched reluctance motor N-phase winding, wherein N is a natural number and is more than or equal to 3; x is N + 2.

The DC power supply V_inThe positive pole of the filter inductor L is connected with the positive pole of the filter inductor L, and the direct current power supply V_inAnd the switching tube S of the common bridge arm 102₂Is connected to the source of (a); negative pole of filter inductor L and switching tube S sharing bridge arm 102₁Source electrode, S₂Is connected to the drain of (1). The filter inductor has the functions of keeping the input current of the direct current power supply continuous and reducing current ripple.

The instantaneous power module 101 comprises a switch tube, three diodes and two capacitors, wherein the switch tube S₃Is connected to the second capacitor C₂Positive electrode of (2) and switching tube S in common bridge arm 102₁Of the drain electrode, the switching tube S₃Is connected with the first capacitor C₁Positive electrode of (2), first diode D₁And a second diode D₂A cathode of (a); a first capacitor C₁The negative electrode of the DC power supply is simultaneously connected with the voltage V of the DC power supply_inAnd a third diode D₃The anode of (1); second capacitor C₂Is simultaneously connected with a second diode D₂And a third diode D₃A cathode of (a); first diode D₁Anode and common bridge arm 102 switching tube S₁Source electrode, S₂Is connected to the drain of (1).

The common bridge arm 102 is composed of a switch tube S₁And a switching tube S₂Series connection of switching tubes S₁Source electrode and switch tube S₂Is connected to the drain of (1).

The first bridge arm 103 is composed of a diode D₄And a switching tube S₄Are connected in series, wherein the diode D₄And a switching tube S in the common bridge arm 102₁Is connected to the drain of diode D₄Anode and switch tube S₄Is connected to the drain of the switching tube S₄Source of and switching tube S in common bridge arm 102₂Is connected to the source of (a).

The second leg 104 is formed by a diode D₅And a switching tube S₅Are connected in series, wherein the diode D₅And a switching tube S in the common bridge arm 102₁Is connected to the drain of diode D₅Anode and switch tube S₅Is connected to the drain of the switching tube S₅Source of and switching tube S in common bridge arm 102₂Is connected to the source of (a).

Third leg 105 is formed by diode D₆And a switching tube S₆Are connected in series, wherein the diode D₆And a switching tube S in the common bridge arm 102₁Is connected to the drain of diode D₆Anode and switch tube S₆Is connected to the drain of the switching tube S₆Source of and switching tube S in common bridge arm 102₂Is connected to the source of (a).

The Nth bridge arm 10X is composed of a diode D_N+3And a switching tube S_N+3Are connected in series, wherein the diode D_N+3And a switching tube S in the common bridge arm 102₁Is connected to the drain electrode ofPolar tube D_N+3Anode and switch tube S_N+3Is connected to the drain of the switching tube S_N+3Source of and switching tube S in common bridge arm 102₂Is connected to the source of (a).

The N-phase winding of the switched reluctance motor is at least a three-phase winding, and the positive pole of each phase of motor winding is connected with the switching tube S of the common bridge arm 102₁Source electrode, S₂Is connected with the drain electrode of the transistor; negative pole A of A phase motor winding^-And a switch tube S in the first bridge arm 103₄Drain electrode connection point of (1), diode D₄The anode connecting points are connected; negative pole B of B-phase motor winding^-And a switch tube S in the second bridge arm 104₅Drain electrode connection point of (1), diode D₅The anode connecting points are connected; negative pole C of C-phase motor winding^-And a switch tube S in the third bridge arm 105₆Drain electrode connection point of (1), diode D₆Is connected to the negative pole N of the … … N-phase motor winding^-And a switching tube S in the Nth bridge arm 10X_N+3Drain electrode connection point of (1), diode D_N+3Are connected, and the asymmetric half-bridge circuit formed by each motor winding is arranged in parallel at both ends of the common bridge arm 102.

The technical scheme of the control method of the invention is as follows:

a power flow control method for a small-capacitance multi-level power converter driven by a high-speed switched reluctance motor specifically comprises the following steps: a topological state variable control loop 201, a motor position variable control loop 202 and a motor speed variable control loop 203.

The topology state variable control loop 201 comprises a capacitance voltage control loop and an inductance current control loop, wherein the capacitance voltage control loop is used as an external control loop, and firstly, a voltage sensor is selected from a first capacitor C in the instantaneous power module 101₁Detected capacitor voltage v_capAnd a capacitor voltage set reference value V_{cap_ref}Comparing, transmitting the obtained comparison result to a PI controller, and taking the output value of the PI controller as an inductive current reference value i_{L_ref}Transmitted to the input end of the current control loop; in the internal inductive current control loop, firstly, the inductive current reference value i_{L_ref}And electricityInductance current value i detected by flow sensor from filter inductance L_LComparing, using the obtained comparison result as the input value of PI regulator, using the output of PI regulator as the input of PWM signal generator, and using the comparison result with sawtooth wave as the switch tube S₁、S₂The PWM signal generator takes the value of the duty ratio D to the switching tube S₁，S₂The driving signals are output to control their turn-on and turn-off.

The motor position variable control loop 202 is characterized by: the external control loop is a rotating speed control loop, and a rotating speed set value n is firstly set_{_ref1}Comparing with the actual rotating speed value n detected by the motor position sensor, and using the comparison result as the input of the PI regulator, and using the output of the PI regulator as the reference value i of the motor phase current_{Y_ref}The internal control loop is a phase current control loop, and the current hysteresis comparator obtains phase current detection values i from each phase winding of the switched reluctance motor by the current sensor_YWith reference value of motor phase current i_{Y_ref}Comparing the signals and using the processed signal as the switch tube S of the power converter₄、S₅、S₆…S_N+3Turn on and off the driving signal; wherein Y is a, B, C, …, N.

The motor speed variable control loop 203 is characterized in that: firstly, a rotating speed set value n is set_{_ref2}And the actual rotating speed value n detected by the motor rotating speed sensor is used as the input of a rotating speed comparator, and the signal processed by the rotating speed comparator is used as a power converter switch tube S₃Turn on and off the driving signal; when the actual rotating speed value n of the switched reluctance motor is lower than the rotating speed set value n_{_ref2}The rotation speed comparator outputs a signal to enable the switch tube S₃The power converter is in and keeps in a conducting state, and the power converter works in a low-voltage demagnetization mode; if the motor running speed n exceeds the set value n of the rotating speed_{_ref2}Then the rotation speed comparator outputs a signal to make the switch tube S₃In and remains in an off state with the power converter operating in a high voltage demagnetization mode.

Compared with the technical scheme of the traditional asymmetric half-bridge converter, the technical scheme of the invention has the following advantages:

(1) the instantaneous power module 101 absorbing and supplying power and the power supply are separated from each other, so the power supply end is not affected by the voltage ripple of the capacitor;

(2) for the capacitors in the instantaneous power module 101, higher than the supply voltage and larger ripple voltage can be allowed, in which case capacitors with smaller capacity and volume can be chosen;

(3) the filter inductor L can filter the direct current power supply current, so that electrolytic capacitors do not need to be connected in parallel at two ends of a power supply, and in addition, the selection range of the direct current power supply voltage is wider and is allowed to be lower than the rated voltage of the switched reluctance motor;

(4) the DC bus voltage has adjustability. The higher demagnetization voltage is applied to the winding, so that the phase current reduction time is shortened, the generation of negative torque is inhibited, the rotating speed range of constant torque is widened, and the application of the switched reluctance motor in high-speed operation is facilitated;

(5) when the phase number of the driven switched reluctance motor is N, the traditional asymmetric half-bridge converter needs 2N switching tubes and 2N diodes, and the power converter provided by the invention only needs N +3 switching tubes, N +3 diodes, 2 capacitors and 1 inductor, so that the cost and the volume can be effectively reduced, the power density is improved, and the reliability of the power converter is further improved.

Drawings

In order to more clearly illustrate the technical solution in the embodiments of the present invention, the drawings used in the prior art and the embodiments will be briefly described below.

Fig. 1 is an operation schematic diagram of an N-phase switched reluctance motor of a conventional asymmetric half-bridge converter.

Fig. 2 is a topological diagram of a small-capacitance multi-level N-phase power converter and a power flow control method thereof according to the present invention.

Fig. 3 is a topological diagram of a small-capacitance multi-level three-phase power converter and a power flow control method thereof according to the present invention.

Fig. 4 is a mode 1 equivalent circuit diagram of a low-voltage demagnetization mode of the small-capacitance multi-level three-phase power converter provided by the invention.

Fig. 5 is a mode 2 equivalent circuit diagram of a low-voltage demagnetization mode of the small-capacitance multi-level three-phase power converter provided by the invention.

Fig. 6 is a mode 3 equivalent circuit diagram of a low-voltage demagnetization mode of the small-capacitance multi-level three-phase power converter provided by the invention.

Fig. 7 is a mode 4 equivalent circuit diagram of a low-voltage demagnetization mode of the small-capacitance multi-level three-phase power converter provided by the invention.

Fig. 8 is a mode 5 equivalent circuit diagram of a low-voltage demagnetization mode of the small-capacitance multi-level three-phase power converter provided by the invention.

Fig. 9 is a mode 6 equivalent circuit diagram of a low-voltage demagnetization mode of the small-capacitance multi-level three-phase power converter provided by the invention.

Fig. 10 is a modal 6 equivalent circuit diagram of the high-voltage demagnetization mode of the small-capacitance multi-level three-phase power converter provided by the invention.

Fig. 11 is a voltage waveform diagram of a phase winding of a small-capacitance multi-level three-phase power converter provided by the invention in two working modes.

Fig. 12 is a phase current waveform diagram of a conventional asymmetric half-bridge inverter when the switched reluctance motor is operating at a low speed.

Fig. 13 is a phase current waveform diagram of a small-capacitance multi-level three-phase power converter in a high-voltage demagnetization mode according to the present invention.

Fig. 14 is a diagram of dynamic phase current waveforms of a small-capacitance multi-level three-phase power converter provided by the invention when a switched reluctance motor operates at a low speed.

Fig. 15 is a dynamic rotation speed waveform diagram of the small-capacitance multi-level three-phase power converter provided by the invention when the switched reluctance motor operates at a low speed.

Fig. 16 is a phase current waveform diagram of the small-capacitance multi-level three-phase power converter and the asymmetric half-bridge converter provided by the invention when the switched reluctance motor runs at a low speed respectively.

Fig. 17 is a waveform diagram of the low-capacitance multi-level three-phase power converter provided by the invention in a low-voltage demagnetization mode when the switched reluctance motor operates at a high speed.

Fig. 18 is a waveform diagram of the small-capacitance multi-level three-phase power converter provided by the invention in a high-voltage demagnetization mode when the switched reluctance motor operates at a high speed.

Fig. 19 is a phase current waveform diagram of an asymmetric half-bridge inverter during high speed operation of a switched reluctance motor.

Detailed Description

The invention will be further described with reference to examples in the drawings.

The small-capacitance multi-level power converter of the present invention is shown in fig. 2, and includes: the direct-current power supply, the filter inductor, the shared bridge arm 102, the first bridge arm 103, the second bridge arm 104, the third bridge arm 105, the N-phase winding of the switched reluctance motor and the instantaneous power module 101.

In fig. 2 to 19, reference symbols respectively represent: v_inIs a direct current power supply and is a main power supply for the work of the motor; l is a filter inductor; s₁、S₂、S₃、S₄、S₅、S₆…S_N+3Showing a switching tube with an anti-parallel diode; d₁、D₂、D₃、D₄、D₅、D₆…D_N+3Represents a diode; c₁、C₂Respectively representing a first capacitance and a second capacitance in the instantaneous power module 101; a. the⁺、B⁺、C⁺…N⁺Respectively, A, B, C … N phase winding positive pole of the switched reluctance motor, and correspondingly, A^-、B^-、C^-…N^-Respectively representing A, B, C … N phase winding cathodes of the switched reluctance motor; d represents the duty cycle of the converter; v. of_capRepresenting a first capacitance C₁The detection voltage of (1); v_{cap_ref}Representing a first capacitance C₁Setting a reference value for the capacitor voltage; i.e. i_LAn inductance current detection value representing the filter inductance L; i.e. i_{L_ref}An inductor current reference value representing the filter inductance L; n represents the dynamic rotation speed of the motor; n is_{_ref1}、n_{_ref2}Representing a set value of the rotating speed of the motor; Δ t_on、Δt_offRespectively, the rise of each phase currentTime and fall time; i.e. i_A、i_B、i_CRespectively representing the working currents of the three-phase windings; i.e. i_inRepresenting an input current of the converter; f_A、F_B、F_CRepresenting the magnetic flux of the three-phase winding when the switched reluctance motor operates; t represents an instantaneous torque; Δ T represents the torque ripple peak to peak value.

The instantaneous power module 101 can provide demagnetizing voltages with different levels according to the rotating speed of the motor so as to meet the requirement; when the switched reluctance motor operates at a low speed, the instantaneous power module 101 provides a demagnetization voltage with a lower level, so that the switching loss of a semiconductor device can be reduced; when the switched reluctance motor operates at a high speed, the instantaneous power module 101 can provide a high level demagnetization voltage to rapidly reduce the phase current, so as to prevent the tail current from appearing in a winding inductance reduction area to generate negative torque and reduce effective torque.

The common bridge arm 102 is composed of a switch tube S₁And a switching tube S₂Are connected in series. Switch tube S₁Source electrode and switch tube S₂Is connected to the drain of (1).

The Nth bridge arm 10X is composed of a diode D_N+3And a switching tube S_N+3Are connected in series, wherein the diode D_N+3And a switching tube S in the common bridge arm 102₁Is connected to the drain of diode D_N+3Anode and switch tube S_N+3Is connected to the drain of the switching tube S_N+3Source of and switching tube S in common bridge arm 102₂Is connected to the source of (a).

As shown in fig. 2, the power flow control method specifically includes: a topological state variable control loop 201, a motor position variable control loop 202 and a motor speed variable control loop 203.

The topology state variable control loop 201 comprises a capacitance voltage control loop and an inductance current control loop, wherein the capacitance voltage control loop is used as an external control loop, and firstly, a voltage sensor is selected from a first capacitor C in the instantaneous power module 101₁Detected capacitor voltage v_capAnd a capacitor voltage set reference value V_{cap_ref}Comparing, transmitting the obtained comparison result to a PI controller, and taking the output value of the PI controller as an inductive current reference value i_{L_ref}Transmitted to the input end of the current control loop; in the internal inductive current control loop, firstly, the inductive current reference value i_{L_ref}And the inductance current value i detected by the current sensor from the filter inductance L_LComparing, using the obtained comparison result as the input value of PI regulator, using the output of PI regulator as the input of PWM signal generator, and using the comparison result with sawtooth wave as the switch tube S₁、S₂The PWM signal generator takes the value of the duty ratio D to the switching tube S₁，S₂The driving signals are output to control their turn-on and turn-off.

It should be noted here that the switching tube S is ideally switched on and off₁And S₂Are complementary, and in fact both the switching tube conduction and the switching tube conduction are requiredFor a certain time, although the time is short, when switching the tube S₁And S₂When the driving signals are completely complementary, there is still a risk that one of the switching tubes is in a state of not completely turning off and the other switching tube is in a state of turning on, which may cause the first capacitor C₁And a second capacitor C₂Is short-circuited and the switching tube S₁And S₂The switching tube is damaged by the transient current which flows through a large peak value, so that a certain dead time is required to avoid the occurrence of the through condition.

It should be noted that, unlike the conventional asymmetric half-bridge converter, the small-capacitance multilevel power converter in the embodiment of the present application may be divided into two operation modes, i.e., a low-voltage demagnetization mode and a high-voltage demagnetization mode, according to the operating speed of the switched reluctance motor.

In particular, in the present specification, a small-capacitance multi-level three-phase power converter is taken as an example for explanation, and is specifically shown in fig. 3.

Considering that the operating states of each phase winding in one operating cycle are the same, taking phase a as an example, the following is to analyze one operating cycle in two operating modes, specifically refer to fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9 and fig. 10, where fig. 4 to fig. 9 are equivalent circuit diagrams of the circuit when the switched reluctance motor operates at a low speed, and fig. 10 is an equivalent circuit diagram of the circuit when the switched reluctance motor operates at a high speed; the dotted line portion in the figure is a non-working portion, and may be regarded as not present. The operation of the small capacitance multilevel power converter is described below with reference to the structure of the converter provided in this application:

when the power converter provided by the invention works in a low-voltage demagnetization mode, the switch tube S₃It is necessary to maintain the on state. When working in high-voltage demagnetizing mode, the switch tube S₃The off state needs to be maintained.

1) Specifically, when the circuit operates in mode 1 of the low voltage demagnetization mode, as shown in fig. 4, the switching tube S is now on₂，S₄Conducting, switching tube S₁And (6) turning off. The voltage drop of the two ends of the filter inductor L is the input power voltage V_inCurrent i of inductor L_LGradually rising. Meanwhile, the external voltage at two ends of the A-phase winding of the switched reluctance motor is zero and passes through a switching tube S₂，S₄Freewheeling is performed but the winding current continues to decrease during this process due to the presence of back emf.

2) When the circuit operates in mode 2 of the low voltage demagnetization mode, as shown in fig. 5, the switching tube S is now on₁，S₄Conducting, switching tube S₂And (6) turning off. In this case, the filter inductor L current i is satisfied at the same time_LGreater than phase winding current i_AVoltage V across the phase winding_AEqual to the capacitor voltage

The A-phase winding current is gradually increased, and the A-phase winding is in an excitation state. DC power supply pass diode D₁For the first capacitor C₁Charging is carried out, and the rest energy of the power supply is charged by the first capacitor C₁Absorption, so that the voltage drop across the filter inductance L is equal to

The inductor current continues to decrease.

3) When the circuit operates in mode 3 of the low voltage demagnetization mode, as shown in fig. 6, the switching tube S is now on₁，S₄Conducting, switching tube S₂Is turned off and satisfies the L current i of the filter inductor_LLess than phase winding current i_AIn the case of a condition where the power supply is unable to supply sufficient energy to the phase winding, the power supply and the instantaneous power module are required to supply energy to the phase winding simultaneously, which can be classified as

And

two states are considered. When in use

Then, the equivalent circuit is as shown in FIG. 6, and only the first capacitor C is used₁And a power supply for supplying the current required by phase A, a first capacitor C₁The voltage at both ends passes through a switch tube S₁、S₃，S₄Is applied to the A-phase winding, so that the voltage V is applied across the A-phase winding_AEqual to the capacitor voltage

The voltage across the filter inductance L remains equal to

So that the inductor current i_LThe decrease continues.

4) When the circuit operates in mode 4 of the low voltage demagnetization mode, as shown in fig. 7, the switching tube S is now on₁，S₄Conducting, switching tube S₂And the on and off states of the switching tube are the same as the working state III. But different from the working state III, the first capacitor C is arranged at the moment₁And a second capacitor C₂The voltages at both ends being equal, i.e.

At this time, the first capacitor C₁、C₂Providing instantaneous power required by A phase winding with power supply, voltage V across A phase winding_AIs equal to

The voltage across the filter inductance L remains equal to

So that the inductor current i_LThe decrease continues.

5) When the circuit operates in mode 5 of the low voltage demagnetization mode, as shown in fig. 8, the switching tube S is now on₁Conducting, switching tube S₂，S₄And (6) turning off. The power supply passes through the diode D only₄For the first capacitor C₁And charging is carried out. The voltage across the filter inductor is

So that the inductor current i_LGradually decreases. At the same time, the A phase winding passes through the switch tube S₁And a diode D₄Freewheeling is performed so that the external voltage drop across the winding is zero, but the phase winding current i is zero due to the presence of back emf_AGradually decreases.

6) When the circuit operates in mode 6 of the low voltage demagnetization mode, as shown in fig. 9, the switching tube S is now on₂Conducting, switching tube S₁，S₄And (6) turning off. The voltage drop at both ends of the filter inductor is input power voltage V_inThus the inductor current i_LGradually increasing. Due to the switchPipe S₃In the conducting state, the A-phase winding passes through a loop diode D₄And a switching tube S₂、S₃And a first capacitor C₁Follow current when the voltage across the winding is

So that the winding current i_ARapidly reducing the first capacitance C entering a demagnetization mode₁The voltage across the terminals increases slightly.

7) When the circuit is operating in mode 6 of the high voltage demagnetization mode, as shown in fig. 10, the switching tube S is now on and off₂Conducting, switching tube S₁，S₃，S₄The turn-off phase winding is in the high-voltage demagnetization period, which is the same as mode 6 of the low-voltage demagnetization mode, and the voltage drop across the filter inductor is the input supply voltage V_inSo that the inductor current i_LGradually increasing. Different from the above, the switch tube S₃Can be turned off only by the diode D₂，D₄Switch tube S₂And a first capacitor C₁A second capacitor C₂Follow current is carried out, in which the phase winding is subjected to a voltage drop of

So that the phase winding current i_ARapidly reducing the first capacitor C entering a high voltage demagnetization mode₁A second capacitor C₂The pressure drop across increases slightly. It should be noted that, in the high-voltage demagnetization mode, only the operating state six is different from the low-voltage demagnetization mode, and the rest of the operating states are the same as the low-voltage demagnetization mode, so the details are not described here.

Taking phase a as an example, the equivalent circuits during excitation and demagnetization when the proposed converter operates in the low-voltage demagnetization mode are shown in fig. 4, 5 and 8, 9, respectively. During excitation, the filter inductance L and the winding inductance L can be derived from fig. 4 and 5_minThe equation of state of (c):

wherein i_L、i_ACurrent of L and A phase windings of filter inductor, D is switch S₂Duty ratio, V_C1Is a first capacitor C₁The voltage across the terminals. The expression of the A-phase winding current in the excitation stage can be derived through the formula:

obviously, it can be found by comparison that the phase current rise value of the power converter proposed by the present invention is the same with the asymmetric half-bridge converter under the condition of the same excitation time. The demagnetization equivalent model in the low-voltage demagnetization mode is shown in fig. 8 and 9, and the state equation of the filter inductance and the winding inductance can be expressed as follows:

also, the phase current expression during this period can be derived from the above equation:

according to the formula, the power converter provided by the invention works in a low-voltage demagnetization mode, and the demagnetization time of the winding is shorter than that of the asymmetric half-bridge converter only when the duty ratio D is larger than 0.5.

In combination with the above analysis it has been shown that under the same conditions the rise time required for the phase current to reach the set value when the proposed converter is operated in the low voltage demagnetization mode is the same compared to an asymmetric half bridge converter. The fall time of the phase current depends on the magnitude of the duty cycle D, which in the first case is<0.5, the demagnetization time of the proposed converter will be larger than for an asymmetric half-bridge converter; in the second case the duty cycle D is 0.5, the demagnetization time of the proposed converter will be the same as for an asymmetric half bridge converter; the third caseThe space ratio D > 0.5, the demagnetization time of the proposed converter will be smaller than for an asymmetric half-bridge converter. And when the switched reluctance motor is in a high-voltage demagnetization mode, the working state and the rising time of phase current during excitation are the same as those in a low-voltage demagnetization mode. During demagnetization of the winding, its corresponding simplified circuit model is shown in fig. 10. Similarly, the filter inductance L and the winding inductance L can be derived_minThe equation of state of (a) is:

after simplification, the expression of the phase A winding current in the high-voltage demagnetization mode can be obtained as follows:

when the duty ratio D of the switching tubes is the same, the reduction rate of the current of the phase winding in the high-voltage demagnetization mode is twice that in the low-voltage demagnetization mode, so that the time required for reducing the current to zero in the high-voltage demagnetization mode is only half that in the low-voltage demagnetization mode, which is very favorable for reducing tail current, widening the constant-torque rotating speed range and improving the running efficiency of the motor. The winding voltages in the two modes of operation are shown in fig. 11, and comparison shows that the excitation voltages in the two modes of operation are the same, while the demagnetization voltage in the high-voltage demagnetization mode is twice that in the low-voltage demagnetization mode. On the other hand, compared with the asymmetric half-bridge converter, in the high-voltage demagnetization mode, the demagnetization time of the winding is smaller than that of the asymmetric half-bridge converter only when the duty ratio D is larger than 0.33.

The average exciting voltage and average demagnetizing voltage provided by the asymmetric half-bridge converter are fixed and equal to the input power voltage V_in. The average excitation voltage provided by the power converter is the same as that of the asymmetric half-bridge converter, but the average demagnetization voltage can be regulated, and when a certain condition is met (when the power converter works in a low-voltage demagnetization mode, the duty ratio D is required to be more than 0.5, and when the power converter works in a high-voltage demagnetization modeThe duty cycle D > 0.33 is satisfied for the mode), the average demagnetizing voltage is larger than that of the asymmetric half-bridge converter.

For verification, a simulation circuit of the circuit shown in fig. 3 may be built, where the simulation parameters are specifically set as follows:

under the low-speed running condition that the rotating speed of the switched reluctance motor is 1000r/min and the load torque is 80 N.m, a power flow control method is adopted. A simulation of the asymmetric half-bridge converter in this operating condition is shown in fig. 12, and a simulation of waveforms of the proposed power converter operating in the high-voltage demagnetization mode is shown in fig. 13: the phase current fall time in the high voltage demagnetization mode is 289.3 mus, and the phase current fall time when an asymmetric half bridge converter is applied is 892.7 mus. The fall time of the winding phase current in the high voltage demagnetization mode is significantly less than when using an asymmetric half bridge converter.

Fig. 14 shows simulation results of the proposed power converter under dynamic performance tests. The motor starting running speed is set to 1000r/min and the load torque is set to 40N · m. The motor reaches the rated rotation speed and is in steady-state operation in a period of time before the time t is 3s, the load torque of the motor is instantaneously increased from 40N · m to 80N · m when the time t is 3s, and the phase current and the rotation speed of the motor are changed, wherein the phase current is gradually increased from 29A to 45A, and the corresponding change process is shown in fig. 14. Fig. 15 shows a motor speed change process, and it can be seen that the speed starts to drop at time t 2s, and after 236ms has elapsed, the speed reaches 1000r/min again.

Fig. 16(a) and (b) show the input current waveforms of the asymmetric half-bridge converter and the power converter proposed by the present invention, respectively, and it can be seen that the asymmetric half-bridge converter has a large low-frequency current ripple and the peak-to-peak value thereof reaches 56A. In contrast, since the power converter proposed by the present invention has a filter inductance and adopts a power flow control method, the amplitude of the low-order harmonic of the input current is smaller, and the peak-to-peak value is only 14A. In the aspect of current harmonic amplitude of higher frequency, the values of the proposed power converter are all lower than those of an asymmetric half-bridge converter, and the effects of effectively prolonging the service life of a power supply, filtering and the like can be realized.

Fig. 17 to 19 are simulation results of the power converter and the asymmetric half-bridge converter proposed by the present invention under high-speed operation of the switched reluctance motor, respectively. At high motor speeds, the winding current waveforms of the asymmetric half-bridge converter and the proposed power converter operating in the low voltage demagnetization mode are severely distorted with large tail currents, as shown in fig. 17 and 19. The increase in average torque and rotational speed is severely affected. Compared with the prior art, the average demagnetization voltage of the power converter provided by the invention is obviously improved when the power converter works in a high-voltage demagnetization mode, the phase current can be quickly established and reduced, and the simulation result is shown in fig. 18, so that the rotating speed range is widened and the torque ripple is reduced under the condition of no change of load torque. Under the same conditions, the maximum rotating speed of the asymmetric half-bridge converter can only reach 6700r/min, while the rotating speed of the converter provided by the invention can reach 7200r/min when the converter works in a high-voltage demagnetization mode. In addition, when the motor runs at high speed, the peak-to-peak torque ripple values of the asymmetric half-bridge converter and the power converter provided by the invention are respectively 20.6N-m and 21.8N-m when the power converter works in the low-voltage demagnetization mode, and the peak-to-peak torque ripple value of the power converter works in the high-voltage demagnetization mode is only 17.8N-m, which is reduced by 15% compared with the asymmetric half-bridge converter. The proposed power converter is applied to electric vehicles and other equipment, and is smoother when running at high speed compared with the traditional power converter.

As a preferred embodiment, the switching tube S₁、S₂、S₃、S₄、S₅、S₆Are all NMOS tubes.

As a preferred embodiment, the switching tube S₁、S₂、S₃、S₄、S₅、S₆Are all IGBT tubes.

In addition, the switching tube S here₁、S₂、S₃、S₄、S₅、S₆Other types of switch tubes can be selected, and the application is not particularly limited and is determined according to the actual situation.

It is to be noted that, in the present specification, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and all simple modifications, changes and equivalent structural changes made to the above embodiment according to the technical spirit of the present invention still fall within the protection scope of the technical solution of the present invention.

Claims

1. A drive circuit for a high speed switched reluctance motor comprising: a small capacitance multi-level power conversion circuit and a control method thereof.

2. The small capacitance multi-level power conversion circuit according to claim 1, comprising: the system comprises a direct-current power supply, a filter inductor, an instantaneous power module 101, a shared bridge arm 102, a first bridge arm 103, a second bridge arm 104, a third bridge arm 105, an Nth bridge arm 10X and a switched reluctance motor N-phase winding; wherein N is a natural number and is more than or equal to 3; x is N + 2;

the DC power supply V_inThe positive pole of the filter inductor L is connected with the positive pole of the filter inductor L, and the direct current power supply V_inAnd a negative electrode and a common electrodeSwitching tube S of bridge arm 102₂Is connected to the source of (a); negative pole of filter inductor L and switching tube S sharing bridge arm 102₁Source electrode, S₂Is connected with the drain electrode of the transistor;

the instantaneous power module 101 comprises a switch tube, three diodes and two capacitors, wherein the switch tube S₃Is connected to the second capacitor C₂Positive electrode of (2) and switching tube S in common bridge arm 102₁Of the drain electrode, the switching tube S₃Is connected with the first capacitor C₁Positive electrode of (2), first diode D₁And a second diode D₂A cathode of (a); a first capacitor C₁The negative electrode of the DC power supply is simultaneously connected with the voltage V of the DC power supply_inAnd a third diode D₃The anode of (1); second capacitor C₂Is simultaneously connected with a second diode D₂And a third diode D₃A cathode of (a); first diode D₁Anode and common bridge arm 102 switching tube S₁Source electrode, S₂Is connected with the drain electrode of the transistor;

the common bridge arm 102 is composed of a switch tube S₁And a switching tube S₂Series connection of switching tubes S₁Source electrode and switch tube S₂Is connected with the drain electrode of the transistor;

the first bridge arm 103 is composed of a diode D₄And a switching tube S₄Are connected in series, wherein the diode D₄And a switching tube S in the common bridge arm 102₁Is connected to the drain of diode D₄Anode and switch tube S₄Is connected to the drain of the switching tube S₄Source of and switching tube S in common bridge arm 102₂Is connected to the source of (a);

the second leg 104 is formed by a diode D₅And a switching tube S₅Are connected in series, wherein the diode D₅And a switching tube S in the common bridge arm 102₁Is connected to the drain of diode D₅Anode and switch tube S₅Is connected to the drain of the switching tube S₅Source of and switching tube S in common bridge arm 102₂Is connected to the source of (a);

third leg 105 is formed by diode D₆And a switching tube S₆Are connected in series, wherein the diode D₆And a switching tube S in the common bridge arm 102₁Is connected to the drain of diode D₆Anode and switch tube S₆Is connected to the drain of the switching tube S₆Source of and switching tube S in common bridge arm 102₂Is connected to the source of (a);

the Nth bridge arm 10X is composed of a diode D_N+3And a switching tube S_N+3Are connected in series, wherein the diode D_N+3And a switching tube S in the common bridge arm 102₁Is connected to the drain of diode D_N+3Anode and switch tube S_N+3Is connected to the drain of the switching tube S_N+3Source of and switching tube S in common bridge arm 102₂Is connected to the source of (a);

3. The method for controlling the small-capacitance multi-level power conversion circuit driven by the high-speed switched reluctance motor according to claim 1 specifically comprises: a topological state variable control loop 201, a motor position variable control loop 202 and a motor rotating speed variable control loop 203;

the topology state variable control loop 201 comprises a capacitor voltage control loop and an inductor current control loop, wherein the capacitor voltage control loop is used as an external control loop, firstlyFirstly, a voltage sensor is connected with a first capacitor C in the instantaneous power module 101₁Detected capacitor voltage v_capAnd a capacitor voltage set reference value V_{cap_ref}Comparing, transmitting the obtained comparison result to a PI controller, and taking the output value of the PI controller as an inductive current reference value i_{L_ref}Transmitted to the input end of the current control loop; in the internal inductive current control loop, firstly, the inductive current reference value i_{L_ref}And the inductance current value i detected by the current sensor from the filter inductance L_LComparing, using the obtained comparison result as the input value of PI regulator, using the output of PI regulator as the input of PWM signal generator, and using the comparison result with sawtooth wave as the switch tube S₁、S₂The PWM signal generator takes the value of the duty ratio D to the switching tube S₁，S₂Outputting driving signals to control the on and off of the driving signals;

the motor position variable control loop 202 is characterized by: the external control loop is a rotating speed control loop, and a rotating speed set value n is firstly set_{_ref1}Comparing with the actual rotating speed value n detected by the motor position sensor, and using the comparison result as the input of the PI regulator, and using the output of the PI regulator as the reference value i of the motor phase current_{Y_ref}The internal control loop is a phase current control loop, and the current hysteresis comparator obtains phase current detection values i from each phase winding of the switched reluctance motor by the current sensor_YWith reference value of motor phase current i_{Y_ref}Comparing the signals and using the processed signal as the switch tube S of the power converter₄、S₅、S₆…S_N+3Turn on and off the driving signal; wherein Y is a, B, C, …, N;

the motor speed variable control loop 203 is characterized in that: firstly, a rotating speed set value n is set_{_ref2}And the actual rotating speed value n detected by the motor rotating speed sensor is used as the input of a rotating speed comparator, and the signal processed by the rotating speed comparator is used as a power converter switch tube S₃Turn on and off the driving signal; when the actual rotating speed value n of the switched reluctance motor is lower than the rotating speed set value n_{_ref2}When the temperature of the water is higher than the set temperature,the output signal of the rotation speed comparator makes the switch tube S₃The power converter is in and keeps in a conducting state, and the power converter works in a low-voltage demagnetization mode; if the motor running speed n exceeds the set value n of the rotating speed_{_ref2}Then the rotation speed comparator outputs a signal to make the switch tube S₃In and remains in an off state with the power converter operating in a high voltage demagnetization mode.

4. The power electronic switching device is provided with a diode in parallel; the power electronic switching device is an IGBT tube; or the power electronic switching device is an NMOS tube.

5. Small-capacitance multilevel power converter according to claim 1, characterized in that the switching tubes S in the common bridge leg 102₁And a switching tube S₂Are complementary, are not on simultaneously, and require dead time to be set.