KR0132390B1 - Choppingless converter for switched reluctance motor drive - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a choppingless motor for driving a switched reluctance motor, and simultaneously performs input phase voltage and current UPF control at the same time regardless of load fluctuations. The sine wave form, the high voltage of the boost converter allows for efficient control without a separate control device at high speed operation, and improves the system efficiency due to the reduction of switching loss compared to the conventional converter, Speed and torque control can be easily controlled through voltage control of the buck converter, and cost reduction is expected due to the use of a low speed switching device.

Description

Choppingless Converter for Switched Reluctance Motors

1 is a circuit diagram of a chopping league converter for driving a switched reluctance motor of the present invention.

2 is a circuit diagram of FIG. 1 and a combined circuit diagram of a control circuit for controlling the circuit diagram.

FIG. 3 is a diagram of current waveforms flowing in the upper winding of the input voltage, current, and switched reluctance motor of FIG.

4 is an additional circuit diagram for EPROM control when the switches S1 and S2 of FIG. 1 are replaced with diodes.

* Explanation of symbols for main parts of the drawings

1: Boost Converter (Boster Converter) 2: Buck Converter

3: Switched Reluctance Motor (SRM) Converter

4: PI controller 5: triangle wave generator

6: Comparator 7: F / V Converter

8: EPROM 9: Encoder

10: gate drive circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a converter for driving a switched reluctance motor, and in particular, a choppingless converter for driving a switched reluctance motor incorporating a booster-buck converter. It relates to a Choppingless Converter.

The conventional converter for driving a switched reluctance motor is simply composed of a part of a full bridge diode for rectifying the voltage on the input side and a large capacity capacitor for smoothing the voltage rectified by the full bridge diode. have.

However, in the converter for driving the switched reluctance motor configured as described above, the current of the input side cannot be controlled sine wave or the UPF (Utility Power Factor) characteristic cannot be realized due to the drive characteristics of the switched reluctance motor.

Therefore, the converter performs a high-speed switching operation for limiting the current value at a low speed in accordance with the change of the speed of the motor, or a separate complicated control device is required to increase the current value at the high speed. As a result, such a speed control method has a problem of high switching loss at low speed and difficulty in control at high speed.

The present invention has been made to solve the above problems, and by using a boost converter on the input side, the input power factor is always 1 and the input current is sinusoidal regardless of the load influence. The purpose is to provide to be.

Another object of the present invention is to use a high voltage of the boost converter to obtain a fast current rise rate required for high-speed operation, so that complicated control such as advance the time of voltage application to obtain a current of the magnitude required for the phase winding It can be reduced.

In addition, another object of the present invention is to apply a voltage proportional to the speed of the switched reluctance motor by using a voltage converter (Pre-Voltage Reluctance) method by a buck converter (Converter on the switched reluctance motor side) Since the adapter does not need to choke for current control, switching losses can be reduced.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 shows an overall circuit diagram of a choppingless converter for driving a switched reluctance motor according to the present invention.

As shown in FIG. 1, a boost converter 1 having an UPF characteristic of always having an input power factor of 1 and an input current of a sine wave regardless of the influence of a load on an input terminal, and a voltage control method for speed A buck converter 2 for applying a proportional voltage to the switched reluctance motor, and a switched reluctance motor (SRM) converter 3 for driving the switched reluctance motor directly with the output voltage of the buck converter. .

The function and characteristic of the said circuit are demonstrated.

Boost converter (1) has an inductance (L1) for energy storage on the input side, a capacitance (C1) for outputting voltage, a diode (D5) (D6) and a switch (S1) for controlling the output voltage. It consists of S2.

In other words, the switch S1 and S2 operate so that the input voltage and the current are in phase so that the UPF characteristic and the sinusoidal input current can be realized.

The switch S1 switches only during a period in which the polarity of the input voltage is positive (+). When the switch S1 is turned on, the switch S1 of the inductance L1-switch S1-switch S2 Energy is stored in the inductance L1 along the path, and when turned off, outputs a voltage to the capacitance C1 via the path of the inductance L1-diode D5-capacitance C1-switch S2. do.

The switch S2 switches only in a section in which the input voltage is negative.

The switching frequency of the switches S1 and S2 is about 20 kHz, and the control method adopts a sinusoidal pulse width modulation (SPWM).

The input power factor of the converter is always 1 regardless of the load variation at the input stage, so that a large part of the high frequency component on the input side can be removed.

In addition, in the conventional control method of the switched reluctance motor, complicated control such as advancement of the voltage application point is required to secure sufficient rise time of the current according to the increase of the speed, but this topology has a boost converter. The high output voltage can be obtained through (1), so that the sufficient speed of insulation of the switched reluctance motor can be secured, and the rising speed of current can be naturally increased at high speed operation, and the buck converter can be used during low speed operation (2). By controlling in a voltage control scheme of, there is no need for chopping control through high speed switching.

Therefore, like the conventional converter, a complicated angle control method according to the speed change is not necessary.

The buck converter 2 consists of a switch T, a diode D and an inductance L2 and a capacitance C2 for energy storage.

In the conventional converter, in order to suppress the increase in the current value during low speed operation, the current is limited by the chopping of the current by the fast switching operation, but the switching duty of the buck converter 2 according to the present invention, that is, the switch By controlling the turn-on time of (T), the voltage control of the converter for driving the switched reluctance motor is executed.

Therefore, the control method is simple since the loss due to the reduction of the switching frequency can be greatly reduced.

When the buck converter 2 turns on the switch T, a voltage is charged to the capacitance C2 through the flow of the switch T-inductance L2-capacitance C2, and the switch T When is turned off, the voltage charged in the capacitance (C2) is transferred to the load side.

In addition, the switched reluctance motor (SRM) converter 3 has the easiest control method, and has fewer elements than the Asymmetric Bridge converter, which is known to be various, and can realize various and easy control. It is.

Reverse current blocking diode (D ₁ ) (D ₂ ) on a loop for exciting a phase winding in consideration of the influence of a diode present in the switching element of the switched reluctance motor (SRM) converter 3. By inserting (D ₃ ) and (D ₄ ), the reverse current flow at the time of forced demagnetization of the wound can be suppressed.

In addition, it reduces the potato time by creating a diode (Dac, Dbd) current flow that regenerates the forced potato current to the input side with high voltage.

The winding of the switched reluctance motor (SRM) is ABCD, which is wound by one independent switch (T _a ) (T _b ) (T _c ) (T _d ) and a common switch (T _ac ) (T _bd ) It is in the form of a connection.

Therefore, when the A phase is excited, the switch (T _a ) and the common switch (T _ac ) are turned on to be excited, and when the B phase is excited, the switch (T _b ) and the common switch (T _bd ) are turned on. Come and be a woman.

Therefore, when the switched reluctance motor SRM controls the switches sequentially so as to obtain a continuous rotational force, the rotational force of the motor SRM is obtained by exciting the upper winding.

Diodes (D _a , D _b , D _c , D _d , D _ac , D _bd ) are used to create a path for the current flowing in the phase winding when the switch that excites the phase winding is turned off. When the excitation is completed, the current flow is forced by the diode (D _a ) -winding A-diode (D ₁ ) -diode (D _ac ).

FIG. 2 shows the overall circuit diagram of FIG. 1 and a coupling diagram with the control circuit diagram for controlling the circuit diagram.

The control signal of the switched reluctance motor (SRM) converter 3 is based on the parallel processing of the information values stored in the EPROM 8, and as the switched reluctance motor SRM rotates, the encoder The position information of the rotor is received from (9), and this information value serves to designate the address of the information value to be output from the EPROM 8.

The information value inside the EPROM 8 whose address is the value output from the encoder 9 is output in parallel from the output end of the EPROM 8, and these values are converted into respective switched reluctance motor (SRM) converters ( It becomes a control signal for turning on and off the switches (T _a , T _b , T _c , T _d , T _ac , T _bd ) of 3).

The control signal of the buck converter 2 is performed by receiving from the encoder 9 a direct current value W, which is proportional to the rotational speed of the switched reluctance motor SRM, via the F / V converter 7.

The direct current value (W) is compared with the command value (W *), and the difference (e *) is amplified by the PI controller (4), and this value is the triangular wave and the comparator (outputted from the triangular wave generator 5). 6), the final PWM (Pulse Width Modulation) output is obtained.

The PWM output thus obtained becomes a control signal for turning on and off the switch of the buck converter 2 via the gate drive circuit 10.

3 shows waveforms of the input voltage 30, the current 31 and the phase current 32 applied to both ends of the choppingless converter for driving a switched reluctance motor of the present invention.

FIG. 4 is a circuit added for controlling the EPROM 8 when the switches S1 and S2 of the boost converter 1 are replaced by a diode, and is referred to as an automatic EPROM page changer 40. It is located as shown in FIG.

If the switches S1 and S2 are replaced with diodes, the converter's converter function of boost is lost and a high voltage cannot be obtained.

Therefore, the automatic EPROM page converter 40 can be used to variably select a table inside the EPROM 8 whose turn-on timing is appropriately adjusted as the speed of the switched reluctance motor SRM increases.

That is, the output value of the F / V converter 7 is compared by the comparator 33 with the values divided by considering the influence of speed and load from the reference voltage Vcc, and the output through the comparator 33 is 8 It is converted into a signal for selecting a table inside the EPROM 8 by the / 3 encoder 34, and these values are connected to an address pin of the EPROM 8.

Therefore, if the output value of the F / V converter 7 changes according to the speed change, the output values of D ₀ , D ₁ , and D ₂ become high or low, and accordingly, the 8/3 encoder ( The output values Out ₀ and Out ₁ of the 34 are also high or low. Accordingly, the output values Out ₀ and Out ₁ of the 8/3 encoder 34 are also high or low. low) to specify different addresses of EPROM (8).

As described above, according to the present invention, the input side current has the sine wave form while the input side voltage and the current are always in phase regardless of the load variation, and the input side current has the sine wave form, and the high speed operation is performed by using the high voltage of the boost converter. Efficient control is possible without a separate control device at the time, improves the efficiency of the system due to the reduction of switching loss compared to the conventional converter, and can easily control the speed and torque through the voltage control of the buck converter As a result, the use of a low speed switching device is expected to reduce the cost.

Claims (7)

Regardless of the load effect on the input side, the power factor always has a UPF characteristic of 1, while the input side current has a sinusoidal wave characteristic, and the high current output rate can be used to obtain a fast current rising rate required for high speed operation. A boost converter (1) capable of reducing complicated control, such as advancement of a voltage application time point to obtain a current of a required magnitude in the line; A buck converter 2 for applying a voltage proportional to the speed to the switched reluctance motor SRM using a voltage control scheme; Switched reluctance motor, characterized in that it consists of a switched reluctance motor (SRM) converter (3) which drives the switched reluctance motor (SRM) directly from the output voltage of the buck converter (2). Choppingless Converter for Driving. 2. The switching element of the switched reluctance motor (SRM) converter 3 according to claim 1, wherein the switching element of the switched reluctance motor is characterized by using an element having a low-speed switching (hundreds of Hz) function. Choppingless Converter. The reverse current blocking diodes (D1, D2, D3) of the switched reluctance motor (SRM) converter (3) when the switching elements (Ta, Tb, Tc, Td) with internal diodes are used. Choppingless converter for driving a switched reluctance motor, characterized in that the connection D4). 4. A choppingless converter for driving a switched reluctance motor according to claim 3, wherein no reverse current blocking diodes (D1, D2, D3, D4) are inserted. 2. The switched reluctance motor according to claim 1, wherein the switches S1 and S2 of the boost converter 1 are controlled by a diode to control the switched reluctance motor SRM. 3. ) Choppingless Converter for Driving. 7. The switch S1 and S2 of the boost converter 1, when replaced with a diode, control the speed and torque of the switched reluctance motor SRM through coupling with the EPROM 8. Choppingless converter for driving a switched reluctance motor, characterized in that it uses an automatic EPROM page switcher (40). 8. A table according to claim 7, wherein a table having different switch turn-on and turn-off positions in the EPROM 8 can be selected according to the speed change in the speed and torque control in driving the switched reluctance motor SRM. Choppingless converter for driving a switched reluctance motor, characterized in that.