JP2010093889A - Device for controlling switched reluctance motor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inverter device of an SR motor to obtain torque even in high-speed rotation. <P>SOLUTION: A control device of an SR motor selectively energizes multiple coils, provided in an SR motor 2, one ends of which are star-connected. In the control device, an inverter circuit 4 includes multiple half bridges each composed of two switching elements connected in series. The half bridges are connected in correspondence with the neutral point of the star connection and the other ends of the coils. An inverter control device 5 sequentially energizes the coils based on the SR rotor position, the value of current passing through the coils, and a current command value. When coils to be energized are changed, the inverter control device once turns off the switching elements of a half bridge connected to the neutral point and turns on the switching elements of those not connected to the neutral point of the half bridges. At least two of the coils are energized, to drive the SR motor 2. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a control device for a switched reluctance motor.

  There is a technique for driving an SR motor using an inverter circuit including eight switching elements for driving a conventional SR (switched reluctance) motor (Patent Document 1 and Patent Document 2).

  FIG. 17 is a schematic block diagram showing a configuration of an SR (Switched reluctance) motor device 9 in a conventional example. The SR motor device 9 includes an SR motor 92 having coils Lu, Lv, and Lw, an inverter circuit 94, and a DC power source 95. One end of each of the coils Lu, Lv, and Lw is coupled at a neutral point 93 and star-connected. The inverter circuit 94 includes half bridges 94a, 94b, 94c, and 94d in which two switching elements are connected in series. One switching element has a drain connected to the high potential side of the DC power supply 95 and a source connected to the drain of the other switching element. The other switching element has a source connected to the low potential side of the DC power supply 95.

  The half bridges 94 a to 94 d include two switching elements connected in series as described above, and are connected in parallel to the DC power supply 95. In the half bridge 94a, the connection point between the switching element NH and the switching element NL is connected to a neutral point 93. In the half bridge 94b, the connection point between the switching element UH and the switching element UL is connected to the other end of the coil Lu. In the half bridge 94c, the connection point between the switching element VH and the switching element VL is connected to the other end of the coil Lv. In the half bridge 94d, the connection point between the switching element WH and the switching element WL is connected to the other end of the coil Lw.

  FIG. 18 is an energization timing chart of the switching element of the inverter circuit 94 when the energization angle is 120 degrees in the conventional example. As illustrated, the inverter circuit 94 switches on / off of the switching elements NH, NL, UH, UL, VH, VL, WH, and WL included in the inverter circuit 94 as follows. The switch is switched by energizing the coils Lu, Lv, and Lw in this order while sequentially switching the six stages # 1 to # 6 to rotate the rotor.

  In stage # 1, the switching elements NH and UL are turned on. As a result, a circuit that energizes the DC power supply 95, the switching element NH, the coil Lu, the switching element UL, and the DC power supply 95 in this order is formed. In stage # 2, switching elements VH and NL are turned on. As a result, a circuit that energizes the DC power supply 95, the switching element VH, the coil Lv, the switching element NL, and the DC power supply 95 in this order is formed. In stage # 3, the switching elements NH and WL are turned on. As a result, a circuit that energizes the DC power supply 95, the switching element NH, the coil Lw, the switching element WL, and the DC power supply 95 in this order is formed.

In stage # 4, switching elements UH and NL are turned on. As a result, a circuit that energizes the DC power supply 95, the switching element UH, the coil Lu, the switching element NL, and the DC power supply 95 in this order is formed. In stage # 5, the switching elements NH and VL are turned on. As a result, a circuit that energizes the DC power supply 95, the switching element NH, the coil Lv, the switching element VL, and the DC power supply 95 in this order is formed. In stage # 6, the switching elements WH and NL are turned on. As a result, a circuit that energizes the DC power supply 95, the switching element WH, the coil Lw, the switching element NL, and the DC power supply 95 in this order is formed.
Note that the switching element is in an energized state when it is on, and is in a non-energized state when it is off.
JP 2007-28866 A JP 2008-125321 A

  When the switching element of the inverter circuit is controlled as described above, if the rotational speed of the SR motor increases, the rotor rotates sufficiently before the current starts flowing through the U, V, and W phases. It was difficult to obtain a proper torque. In addition, the switching elements NH and NL connected to the neutral point 93 have a longer time for current to flow than the other switching elements, and further, the amount of current increases at the time of high rotation, which is caused by energization compared to the other switching elements. High temperature due to heat generation. Accordingly, there is a problem in that the temperature characteristic of the switching element limits the amount of current flowing through the switching element and prevents the SR motor from obtaining torque.

  The present invention has been made to solve the above problems, and an object of the present invention is to provide an SR motor device capable of obtaining sufficient torque even when the SR motor is rotating at a high speed.

In order to solve the above problems, the present invention is a control device for a switched reluctance motor that selectively energizes a plurality of coils, one end of which is star-connected, each of which includes two switching diodes connected in parallel to each other. A plurality of half bridges in which elements are connected in series are provided, and the neutral point of the star connection and the other ends of the plurality of coils are respectively connected to connection points of the two switching elements provided in the corresponding half bridges. The inverter circuit, the position of the rotor of the switched reluctance motor, the current value flowing through each of the plurality of coils, and the current of the current flowing through each of the plurality of coils determined according to the target output of the switched reluctance motor And energizing the plurality of coils in order based on the current command value indicating the value. An inverter control device that drives a reluctance motor, and the inverter control device sequentially energizes the plurality of coils adjacent in the circumferential direction around the rotation axis of the rotor, and switches the energized coils. The switching element that is energized by the half bridge connected to the neutral point is turned off, and the half corresponding to the coil that is energized next that is not connected to the neutral point among the plurality of half bridges. When the switching element of the bridge is turned on, an overlap period is provided in which the coil that is energized among the plurality of coils and the coil that is energized next are energized simultaneously, and the drive signal of the switching element is also the overlap period Is a control device for a switched reluctance motor.
When switching a coil to be energized, this switched reluctance motor control device provides a period in which no current flows through the half bridge to which the neutral point is connected, and energizes the next energized coil in that period. Advance.

Further, according to the present invention, in the above-described invention, the inverter control device includes an advance angle / energization angle signal indicating an advance angle and an energization angle in accordance with the rotational speed of the switched reluctance motor and the current command value. The overlap period is determined based on the advance angle / energization angle calculation unit that outputs, the advance angle / energization angle signal, the rotor position, the current value flowing through the plurality of coils, and the current command value. And an energization timing output unit for switching on and off of the switching elements provided in the plurality of half bridges.
The timing for switching on and off the switching elements of the inverter circuit is changed according to the rotational speed of the rotor and the current command value. Further, the overlap period is changed according to the rotational speed of the rotor and the current command value.

  According to the present invention, when switching the coil to be energized, the current is passed through the switching element of the other half bridge without passing the current through the switching element of the half bridge connected to the neutral point. Heat generation of the half-bridge switching element connected to the point can be suppressed, and the amount of current limited by the temperature characteristics of the switching element can be increased (reason 1).

In addition, when switching the coil to be energized, by providing an overlap period for energizing the energized coil and the coil adjacent to the rotation direction of the rotor of the coil, the energization time of the next energized coil is lengthened. (Reason 2).
For the reasons 1 and 2 described above, it is possible to increase the output torque of the SR motor even at high speeds by increasing the period during which a current that contributes to torque generation flows.

Hereinafter, a motor device and its operation according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic block diagram showing the configuration of the motor device 1 according to the present embodiment.
The motor device 1 includes an SR motor 2, a DC power supply 31, a smoothing capacitor 32, an inverter circuit 4, and an inverter control device 5 that drives the inverter circuit 4.

The SR motor 2 includes a substantially cylindrical stator 21 and a rotor 22 that is rotatably disposed inside the stator 21. The stator 21 includes three-phase U, V, and W coils Lu, Lv, and Lw wound around the stator salient poles 24 of the stator core 23. Each of the coils Lu, Lv, and Lw is formed by winding a winding around each pair of stator salient poles 24 that are opposed in the radial direction.
The rotor 22 includes an output shaft 25 and a rotor salient pole 26 protruding in the radial direction. The output shaft 25 is provided with a resolver 17 that is a rotation detection device that detects the rotation angle of the rotor 22.
Each coil Lu, Lv, Lw is star-connected so that one end of the coil is coupled at a neutral point 47 and has the same potential. Further, the neutral point 47 and each of the other ends of the coils Lu, Lv, and Lw are electrically connected to the inverter control device 5. Further, current sensors 27 for detecting currents (winding currents) of the respective phases supplied to the SR motor 2 are provided at the other ends of Lu, Lv, and Lw of each coil.

The inverter circuit 4 includes half bridges 41 to 44 in which two switching elements are connected in series. Each of the half bridges 41 to 44 is connected to the DC power supply 31 and the smoothing capacitor 32 in parallel.
The switching elements NH, NL, UH, UL, VH, VL, WH, and WL included in the half bridges 41 to 44 are configured using FETs (Field Effective Transistors). Each FET has a gate connected to the inverter controller 5 and is controlled to be turned on / off. Each FET is formed with free-wheeling diodes D1 to D8.
In the half bridge 41 (first half bridge), the switching element NH has a drain connected to the high potential side of the DC power supply 31 and a source connected to the drain of the switching element NL via the connection point J1. The source of the switching element NL is connected to the low potential side of the DC power supply 31. The connection point J1 is connected to one end of each of the coils Lu, Lv, and Lw via a neutral point 47. In the half bridge 42 (second half bridge), the switching element UH has a drain connected to the high potential side of the DC power supply 31 and a source connected to the drain of the switching element UL via the connection point J2. The source of the switching element UL is connected to the low potential side of the DC power supply 31. The connection point J2 is connected to the other end of the U-phase coil Lu.

In the half bridge 43 (third half bridge), the switching element VH has a drain connected to the high potential side of the DC power supply 31 and a source connected to the drain of the switching element VL via the connection point J3. The source of the switching element VL is connected to the low potential side of the DC power supply 31. The connection point J3 is connected to the other end of the V-phase coil Lv. In the half bridge 44 (fourth half bridge), the switching element WH has a drain connected to the high potential side of the DC power supply 31 and a source connected to the drain of the switching element WL via the connection point J4. The source of the switching element VL is connected to the low potential side of the DC power supply 31. The connection point J4 is connected to the other end of the W-phase coil Lw.
The switching elements NH, UH, VH, and WH connected to the high potential side of the DC power supply 31 are high potential side switching elements, and the switching elements NL, UL, and VL connected to the low potential side of the DC power supply 31. , WL are low potential side switching elements.

The inverter control device 5 includes a current command value determination unit 51, a current detection unit 52, a current control unit 53, a position detection unit 54, a rotation speed calculation unit 55, an advance / energization angle calculation unit 56, And a timing output unit 57.
The current command value determination unit 51 sets a current command value based on a signal indicating the target output that is an output required for the SR motor 2 based on a signal input from the outside, for example, the degree of depression of the accelerator pedal. . For example, the current command value determination unit 51 sets the target output of the SR motor 2 from the accelerator operation signal corresponding to the detection result of an accelerator pedal opening sensor or the like that detects the accelerator opening related to the driver's accelerator operation. Set the current command value according to the target output. The current command value is a current value required for the SR motor 2 to obtain a target output. In addition, the current command value determination unit 51 outputs the calculated current command value to the current control unit 53 and the advance / energization angle calculation unit 56.
The current detection unit 52 detects a winding current value energized in the SR motor 2 based on, for example, a detection signal of each phase current (winding current) output from each current sensor 27, and controls the current control unit 53. Output to.

Based on the current command value output from the current command value determination unit 51 and the winding current value output from the current detection unit 52, the current control unit 53 determines the winding current supplied to the SR motor 2. Performs PWM (Pulse Width Modulation) control. The current control unit 53 includes a PWM duty calculation unit 53a and a current feedback processing unit 53b. The current feedback processing unit 53b compares the current command value output from the current detection unit 52 with the winding current value output from the current detection unit 52, and sends the comparison result (for example, deviation) to the PWM duty calculation unit 53a. Output.
The PWM duty calculation unit 53a is based on the comparison result output from the current feedback processing unit 53b, and the ratio of ON to OFF per unit time for each of the switching elements UH to WL provided in the half bridges 42 to 44 of the inverter circuit 4 The duty ratio is calculated, and the calculated duty ratio is output to the energization timing output unit 57. For example, the PWM duty calculation unit 53a uses a duty ratio used for pulse width modulation based on a current command value and a rectangular wave carrier signal from a voltage value obtained by PI control using an input comparison result, that is, each switching The duty ratio between ON and OFF of the elements UH, UL, VH, VL, WH, WL is calculated and output to the energization timing output unit 57.

The position detection unit 54 detects the rotation position of the rotor 22 based on a signal output from the resolver 17 that is a rotation angle sensor, and outputs the rotation position to the rotation speed calculation unit 55 and the energization timing output unit 57. Here, the rotation position is a rotation angle from the position of the rotor 22 serving as a predetermined reference, and is a position indicated by a value in the range of 0 degrees to 359 degrees.
The rotation speed calculation unit 55 calculates the rotation speed (rotation speed) of the rotor 22 from the amount of change per unit time of the rotation position output from the position detection unit 54 and outputs the rotation speed (rotation speed) to the advance / energization angle calculation unit 56.

The advance angle / energization angle calculation unit 56 outputs an advance angle and an energization angle according to the current command value output from the current command value determination unit 51 and the rotation speed output from the rotation speed calculation unit 55. To the unit 57. The advance / energization angle calculation unit 56 includes an advance angle map unit 56a and an energization angle map unit 56b.
The advance angle map unit 56 a outputs an advance angle to the energization timing output unit 57 based on the current command value output from the current command value determination unit 51 and the rotation speed output from the rotation speed calculation unit 55. The advance angle map unit 56a is a map in which an advance value is associated with each combination of the current command value corresponding to the target output and the rotation speed of the rotor 22. Here, the advance angle is a predetermined position (for example, an increase start phase and a decrease of the inductance) according to the inductance change of each phase, with respect to each of the coils Lu, Lv, and Lw of each phase of the SR motor 2. This represents the angle at which the energization angle is changed to the advance side from the start phase. Note that the advance angle tends to increase with increasing current command value and rotation speed. The advance angle map unit 56a is determined from a simulation, a measurement result by an actual machine, or the like.

  The energization angle map unit 56 b outputs the energization angle to the energization timing output unit 57 based on the current command value output from the current command value determination unit 51 and the rotation speed output from the rotation speed calculation unit 55. The energization angle map unit 56 b is a map in which energization angle values are associated with each combination of the current command value and the rotation speed of the rotor 22. Here, the energization angle is associated with each of the coils Lu, Lv, Lw of each phase of the SR motor 2. The conduction angle map unit 56b is determined from a simulation, a measurement result by an actual machine, or the like.

The energization timing output unit 57 is based on the rotation position output from the position detection unit 54 and the advance angle and energization angle output from the advance angle / energization angle calculation unit 56. A pulse signal is applied to the gate of WL to switch on / off. The energization timing output unit 57 includes a timer unit 57a, a commutation signal generation unit 57b, and a PWM signal output unit 57c.
Based on the rotational position output from the position detection unit 54 and the advance angle and energization angle output from the advance / energization angle calculation unit 56, the timer unit 57a makes the current energized coil and the energized state next. A period (overlap period) in which both the coil and the coil are energized is calculated. Further, the timer unit 57a counts the calculated overlap period, and outputs a timing signal indicating the overlap period to the commutation signal generation unit 57b and the PWM signal output unit 57c. For example, the calculation of the overlap period by the timer unit 57a is performed using the rotation speed and the conduction angle map.
The commutation signal generation unit 57b is based on the rotational position output from the position detection unit 54, the advance angle and energization angle output from the advance / energization angle calculation unit 56, and the timing signal output from the timer unit 57a. Thus, a pulse signal for switching on and off the switching elements NH and NL of the half bridge 41 of the inverter circuit 4 is generated, and the generated pulse signal is output to the switching elements NH and NL.

The PWM signal output unit 57c includes a PWM duty signal output from the current control unit 53, a rotational position output from the position detection unit 54, and an advance angle and an energization angle output from the advance angle / energization angle calculation unit 56. Based on the timing signal output from the timer unit 57a, a signal for switching on / off of each switching element UH, UL, VH, VL, WH, WL is applied to the gate.
Here, the signals of the switching elements NH and NL output from the commutation signal generation unit 57b are turned off at a timing earlier than 120 degrees based on the overlap period output from the timer unit 57a. The signal applied to the gates of the switching elements UH to WL output from the PWM signal output unit 57c is turned on at a timing earlier than 120 degrees based on the overlap period.

  Next, FIG. 2 associates the position of the rotor 22, the on / off states (energization patterns) of the switching elements NH to WL included in the inverter circuit 4, and the inductance values of the U, V, and W phases. It is the schematic shown. 3-14 is a figure which shows the path | route through which the electric current in each energization pattern by the inverter control apparatus 5 flows. Hereinafter, the operation of the motor device 1 will be described with reference to FIGS. In the following description, the rotor 22 of the SR motor 2 rotates counterclockwise.

  First, at time t1, the inverter control device 5 switches the switching element WL off and switches the switching element NH on. In the stage S1 from time t1 to time t2, the inverter control device 5 turns on the switching elements NH and UL. In the stage S1, as shown in FIG. 3, the current A1 flows from the DC power supply 31 in the order of the switching element NH, the coil Lu, the switching element UL, and the DC power supply 31. During this period, the value of the inductance of the coil Lu increases, and the rotor 22 rotates while being attracted to the stator salient pole 24 around which the coil Lu is wound.

  At time t2, the inverter control device 5 switches the switching element NH off and switches the switching element VH on. In stage S2 from time t2 to time t3, inverter control device 5 turns on switching elements UL, VH. In the stage S2, as shown in FIG. 4, the current A2 flows from the DC power supply 31 in the order of the switching element VH, the coil Lv, the coil Lu, the switching element UL, and the DC power supply 31. Further, at time t3, the U-phase stator salient pole 24 and the rotor salient pole 26 face each other, and the inductance value of the coil Lu becomes the maximum value.

  At time t3, the inverter control device 5 switches the switching element UL off and switches the switching element NL on. In stage S3 from time t3 to time t4, inverter control device 5 turns on switching elements VH and NL. In the stage S3, as shown in FIG. 5, the current A3 flows from the DC power supply 31 in the order of the switching element VH, the coil Lv, the switching element NL, and the DC power supply 31. During this period, the inductance value of the coil Lv increases, and the rotor salient pole 26 is attracted to the stator salient pole 24 around which the coil Lv is wound and rotates. Further, the inductance value of the coil Lu becomes small.

  At time t4, the inverter control device 5 switches the switching element NL off and switches the switching element WL on. In stage S4 from time t4 to time t5, inverter control device 5 turns on switching elements VH and WL. In stage S4, as shown in FIG. 6, current A4 flows from DC power supply 31 in the order of switching element VH, coil Lv, coil Lw, switching element WL, and DC power supply 31. Further, at time t5, the stator salient pole 24 and the rotor salient pole 26 around which the coil Lv is wound face each other, and the inductance value of the coil Lv becomes the maximum value. Further, the inductance value of the coil Lu is 0 or a value close to 0.

  At time t5, the inverter control device 5 switches the switching element VH off and switches the switching element NH on. In stage S5 from time t5 to time t6, inverter control device 5 turns on switching elements NH and WL. In the stage S5, as shown in FIG. 7, the current A5 flows from the DC power source 31 in the order of the switching element NH, the coil Lw, the switching element WL, and the DC power source 31. During this period, the inductance value of the coil Lw increases, and the rotor salient pole 26 is attracted to the stator salient pole 24 around which the coil Lw is wound to rotate. Further, the inductance value of the coil Lv decreases.

  At time t6, the inverter control device 5 switches the switching element NH off and switches the switching element UH on. In stage S7 from time t6 to time t7, inverter control device 5 turns on switching elements UH and WL. In stage S6, as shown in FIG. 8, current A6 flows from DC power supply 31 in the order of switching element UH, coil Lu, coil Lv, switching element WL, and DC power supply 31. Further, at time t7, the stator salient pole 24 and the rotor salient pole 26 around which the coil Lw is wound face each other, and the inductance value of the coil Lw becomes the maximum value. The inductance value of the coil Lv is 0 or a value close to 0.

  At time t7, the inverter control device 5 switches the switching element WL off and switches the switching element NL on. In stage S7 from time t7 to time t8, inverter control device 5 turns on switching elements UH and NL. In the stage S7, as shown in FIG. 9, the current A7 flows from the DC power source 31 to the switching element UH, the coil Lu, the switching element NL, and the DC power source 31 in this order. During this period, the inductance value of the coil Lu increases, and the rotor salient pole 26 is attracted to and rotated by the stator salient pole 24 around which the coil Lu is wound. Further, the inductance value of the coil Lw decreases.

  At time t8, the inverter control device 5 switches the switching element NL off and switches the switching element VL on. In stage S8 from time t8 to time t9, inverter control device 5 turns on switching elements UH and VL. In stage S8, as shown in FIG. 10, current A8 flows from DC power supply 31 in the order of switching element UH, coil Lu, coil Lv, switching element VL, and DC power supply 31. Further, at time t9, the stator salient pole 24 and the rotor salient pole 26 around which the coil Lu is wound face each other, and the inductance value of the coil Lu becomes the maximum value. The inductance value of the coil Lw is 0 or a value close to 0.

  At time t9, the inverter control device 5 switches the switching element UH off and switches the switching element NH on. In stage S9 from time t9 to time t10, inverter control device 5 turns on switching elements NH and VL. In the stage S9, as shown in FIG. 11, the current A9 flows from the DC power source 31 to the switching element NH, the coil Lv, the switching element VL, and the DC power supply 31 in this order. During this period, the inductance value of the coil Lv increases, and the rotor salient pole 26 is attracted to the stator salient pole 24 around which the coil Lv is wound and rotates. Further, the inductance value of the coil Lu decreases.

  At time t10, the inverter control device 5 switches the switching element NH off and switches the switching element WH on. In stage S10 from time t10 to time t11, inverter control device 5 turns on switching elements WH and VL. In the stage S10, as shown in FIG. 12, the current A10 flows from the DC power supply 31 in the order of the switching element WH, the coil Lw, the coil Lv, the switching element VL, and the DC power supply 31. At time t11, the inductance value of the coil Lv becomes the maximum value. Further, the inductance value of the coil Lu is 0 or a value close to 0.

  At time t11, the inverter control device 5 switches the switching element VL off and switches the switching element NL on. In stage S11 from time t11 to time t12, inverter control device 5 turns on switching elements WH and NL. In the stage S11, as shown in FIG. 13, the current A11 flows from the DC power source 31 in the order of the switching element WH, the coil Lw, the switching element NL, and the DC power source 31. During this period, the inductance value of the coil Lw increases, and the rotor salient pole 26 is attracted to the stator salient pole 24 around which the coil Lw is wound and rotates. Further, the inductance value of the coil Lv decreases.

At time t12, the inverter control device 5 switches the switching element NL off and switches the switching element UL on. In stage S12 from time t12 to time t13, inverter control device 5 turns on switching elements WH and UL. In the stage S10, as shown in FIG. 14, the current A12 flows from the DC power source 31 in the order of the switching element WH, the coil Lw, the coil Lu, the switching element UL, and the DC power source 31. At time t13, the inductance value of the coil Lw becomes the maximum value. The inductance value of the coil Lv is 0 or a value close to 0.
Hereinafter, the inverter control device 5 sequentially repeats the operations of the stages S1 to S12 to rotate the rotor 22 of the SR motor 2.

As described above, the inverter control device 5 switches the energization pattern of the inverter circuit 4 and rotates the rotor 22 of the SR motor 2. Moreover, the inverter control apparatus 5 performs control not to energize the switching elements NH and NL of the half bridge 41 to which the neutral point 47 is connected in stages S2, S4, S6, S8, S10, and S12. As a result, it is possible to reduce the time for energizing the switching elements NH and NL of the half bridge 41 to which the neutral point 47 is connected as compared with the prior art, and to make the heat generation amount with the other switching elements UH to WL uniform. it can. As a result, the amount of heat generated by the switching elements NH and NL can be reduced, and the amount of current flowing through the SR motor 2 when the SR motor 2 is rotated at a high speed can be increased.
In addition, since the current starts to flow through each coil before the period in which the torque of the SR motor 2 is generated (period in which the inductance value of each phase increases), the current can be efficiently changed to the torque of the SR motor 2. It becomes possible.

FIG. 15 is a schematic diagram illustrating changes in the current values of the U phase and the V phase in the present embodiment and the conventional example, respectively. The horizontal axis direction indicates time, and the vertical axis direction indicates current values of the U phase and the V phase. The current values in the motor device 1 of the present embodiment are indicated by L1 and L3, and the current values of the conventional example are indicated by L2 and L4. The period from time t2 to time t5 is a period in which torque is obtained by passing a current through the U phase. Further, the period from time t5 to time t8 is a period in which torque is obtained by flowing a current in the V phase.
Here, in the energization pattern of the inverter circuit 4 of the present embodiment, the period from the time t0 to the time t1 corresponds to the stage S6 or the stage S12 in FIG. 2, and the period from the time t1 to the time t3 in FIG. The period from time t3 to time t4 corresponds to stage S1 or stage S7, corresponds to stage S2 or stage S8 in FIG. 2, and the period from time t4 to time t6 corresponds to stage S3 or stage S9 in FIG. Correspondingly, the period from time t6 to time t7 corresponds to stage S4 or stage S10 in FIG.
The period in which the U-phase and V-phase torques are generated is shifted from the timing of energizing the U-phase and V-phase in FIG. 2 because the advance angle obtained by the advance angle map unit 56a This is because the timing is advanced.

  In the motor device 1 of the present embodiment, the motor device 9 of the conventional example starts to flow current to the U-phase coil Lu from time t1, whereas it starts to flow current to the U-phase coil Lu from time t0. The phase current can be raised quickly. As a result, the motor device 1 of the present embodiment can increase the torque obtained for the region indicated by a1 in the period from time t2 to time t3, compared to the U-phase current value of the conventional example. Further, in the motor device 1 of the present embodiment, the motor device 9 of the conventional example starts to flow current to the V-phase coil Lv from time t4, whereas it starts to flow current to the V-phase coil Lv from time t3. The V-phase current can be raised quickly. As a result, the motor device 1 of the present embodiment can pass a larger amount of current that contributes to the generation of torque in the engine from time t5 to time t6 than the conventional V-phase current value, and is indicated by a3. It is possible to increase the torque that can be obtained in the region to be applied (the time product of the difference between the current values).

  On the other hand, the motor device 1 of the present embodiment increases the inductance value by connecting the U-phase coil Lu and the V-phase coil Lv in series during the period from the time t3 to the time t4. As a result, during the period from time t3 to time t4, the current value of the U phase in the present embodiment becomes lower than the current value of the U phase in the conventional example as the value of the inductance increases. Thereby, compared with the motor apparatus 9 of a prior art example, the torque obtained for the area | region illustrated by a2 decreases. Further, in the motor device 1 of the present embodiment, the inductance value increases by connecting the V-phase coil Lv and the W-phase coil Lw in series during the period from the time t6 to the time t7. As a result, during the period from time t6 to time t7, the V-phase current value of the present embodiment becomes lower than the V-phase current value of the conventional example as the inductance value increases. Thereby, compared with the motor apparatus 9 of a prior art example, the torque obtained by the area | region (the time product of the difference of an electric current value) illustrated by a4 decreases.

  As described above, by providing an overlap period in which a plurality of U-phase, V-phase, and W-phase are energized at the same time, the obtained torque increases, but the obtained torque decreases. For this reason, the length of the overlap period and the timing for starting the overlap period are determined so that the increasing torque exceeds the decreasing torque based on simulation, measurement by an actual machine, or the like. Further, based on the determined length and timing of the overlap period, the association of the advance angle with the rotation speed and the current command value in the advance angle map unit 56a is determined. Further, the association of the energization angle with the rotation speed and the current command value in the energization angle map unit 56b is determined. Further, the overlap period counted by the timer unit 57a is determined.

  If the overlap period is too long, the period in which the coils are connected in series becomes longer, the amount of decrease is greater than the increase in the flowing current value, and the total amount of torque obtained is reduced. On the other hand, if the overlap period is too short, the current flowing through the switching elements NH and NL connected to the neutral point 47 cannot be reduced, and the amount of current that can be flowed is limited due to the temperature characteristics of the switching elements. The difference from the control method of the conventional inverter circuit 4 is almost eliminated.

  Next, FIG. 16 is a graph showing current values of the U-phase coil Lu and the V-phase coil Lv in the actual machines of the motor device 1 of the present embodiment and the motor device 9 of the conventional example. Here, in the motor device 1, the conduction angle of the conventional motor device 9 is 120 degrees, whereas the conduction angle is 140 degrees. That is, 20 degrees corresponds to the overlap period. The current value of the motor device 1 is indicated by L6 and L8, and the current value of the motor device 9 is indicated by L7 and L8.

  As shown in the figure, since the U-phase current of the motor device 1 starts to flow from time t0, it can be confirmed that the maximum value is higher than the U-phase current of the motor device 9. In addition, from time t3 to time t4, since the motor apparatus 1 energizes both the U-phase coil Lu and the V-phase coil Lv, it can also be confirmed that the current value is lower than that of the motor apparatus 9. In addition, since the area | region (the time product of the difference of an electric current value) shown by a5 is wider than the area | region shown by a6, the torque which the motor apparatus 1 obtains has increased rather than the torque which the motor apparatus 9 obtains. I can confirm that.

  As described above, it is possible to increase the torque obtained by overlapping the energizing periods of the coils Lu, Lv, and Lw of the U-phase, V-phase, and W-phase so that the energization angle is 120 degrees or more. become. Further, in the overlap period, by providing a period during which no current is supplied to any of the switching elements NH and NL of the half bridge 41 connected to the neutral point 47, heat generation due to the current supply is suppressed, and the switching element Heat generation can be made uniform, and the restriction on the value of the current flowing through the switching element due to the temperature characteristics of the switching element can be relaxed. Further, since the inverter circuit 4 can increase the amount of current flowing through the SR motor 2 without changing from the conventional configuration, it can be easily applied to an existing motor device.

  In the present embodiment, the SR motor 2 having three-phase coils has been described. However, the present invention can also be applied to SR motors having different numbers of coils. In that case, the number of half bridges of the inverter circuit is changed according to the number of coils.

  The inverter control device 5 described above may have a computer system inside. In that case, the process of switching on and off the switching elements NH to WL included in the inverter circuit 4 is stored in a computer-readable recording medium in the form of a program, and the computer reads and executes the program. Thus, the above processing is performed. Here, the computer-readable recording medium means a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like. Alternatively, the computer program may be distributed to the computer via a communication line, and the computer that has received the distribution may execute the program.

It is a schematic block diagram which shows the structure of the motor apparatus 1 by this embodiment. FIG. 4 is a schematic diagram showing the position of the rotor 22 in the same embodiment, the on / off state (energization pattern) of the switching element included in the inverter circuit 4, and the inductance values of the U, V, and W phases in association with each other. is there. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is a figure which shows the path | route through which the electric current with respect to the electricity supply pattern of the embodiment flows. It is the schematic which showed the change of the electric current value of the U phase and V phase in this embodiment and a prior art example, respectively. It is the graph which showed the electric current measured value of each of the U phase coil Lu and the V phase coil Lv in the actual machine of the motor apparatus 1 of this embodiment, and the motor apparatus 9 of a prior art example. It is a schematic block diagram which shows the structure of SR motor apparatus 9 in a prior art example. It is an electricity supply timing chart of the switching element of the inverter circuit 94 in the electricity supply angle 120 degree | times in a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Motor apparatus 2 ... SR motor, 21 ... Stator, 22 ... Rotor, 23 ... Stator core 24 ... Stator salient pole, 25 ... Output shaft, 26 ... Rotor salient pole, 27 ... Current sensor 31 ... DC power supply, 32 ... Smoothing Capacitor 4 ... Inverter circuit, 47 ... Neutral point 41, 42, 43, 44 ... Half bridge NH, NL, UH, UL, VH, VL, WH, WL ... Switching element 5 ... Inverter controller 51 ... Current command value determination , 52 ... Current detection unit, 53 ... Current control unit 53a ... PWM duty calculation unit, 53b ... Current feedback processing unit 54 ... Position detection unit, 55 ... Rotational speed calculation unit, 56 ... Advance angle / energization angle calculation unit 56a ... Advance angle map section, 56b ... conduction angle map section, 57 ... conduction timing output section 57a ... timer section, 57b ... commutation signal generation section, 57c ... PWM signal Power unit 9 ... motor device 92 ... SR motor, 93 ... neutral point, 94 ... inverter circuit 94a, 94b, 94c, 94d ... half-bridge 95 ... DC power source

Claims (3)

A control device for a switched reluctance motor that selectively energizes a plurality of coils that are star-connected at one end,
A plurality of half bridges each having two switching elements each connected in parallel with a free-wheeling diode are connected in series, and the neutral point of the star connection and the other ends of the plurality of coils are provided in the corresponding half bridges. An inverter circuit connected to a connection point of the two switching elements,
A current command indicating a position of a rotor of the switched reluctance motor, a current value flowing through each of the plurality of coils, and a current value of a current flowing through each of the plurality of coils determined according to a target output of the switched reluctance motor And an inverter controller that drives the switched reluctance motor by sequentially energizing the plurality of coils based on the value,
The inverter control device
The coils adjacent to each other in the circumferential direction around the rotation axis of the rotor are sequentially energized, and when switching the energized coils, the switching elements that are energized by the half bridge connected to the neutral point are turned off. And turning on the switching element of the half bridge corresponding to the next coil to be energized that is not connected to the neutral point among the plurality of half bridges, and energizing among the plurality of coils. An apparatus for controlling a switched reluctance motor, wherein an overlap period is provided in which a coil and a coil to be energized next are energized at the same time, and the drive signal of the switching element is also provided with an overlap period. The inverter control device
An advance angle / energization angle calculator that outputs an advance angle / energization angle signal indicating an advance angle and an energization angle according to the rotational speed of the switched reluctance motor and the current command value;
The overlap period is determined based on the advance angle / conduction angle signal, the position of the rotor, the current value flowing through the plurality of coils, and the current command value, and the plurality of half bridges are provided with the overlap period. A switching reluctance motor control device according to claim 1, further comprising: an energization timing output unit that switches on and off of the switching element. The plurality of coils of the switched reluctance motor are:
It consists of three coils: a U-phase coil, a V-phase coil, and a W-phase coil.
The plurality of half bridges provided in the inverter circuit,
A first half bridge connected to the neutral point; a second half bridge connected to the other end of the U-phase coil; and a third half connected to the other end of the V-phase coil. The control device for the switched reluctance motor according to claim 1 or 2, comprising a bridge and a fourth half bridge connected to the other end of the W-phase coil.

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