KR20120031463A - Motor - Google Patents

Abstract

PURPOSE: A motor is provided to suppress complexity of a circuit structure by preventing an excessive load of a gate voltage even through a driving voltage is deteriorated. CONSTITUTION: A rotor is supported to freely rotate. A driving device(4) supplies a driving current to a coil. A plurality of power devices includes an upper power device(21a,21b,21c) and a lower power device(22a,22b,22c). A voltage dividing circuit(47) includes a voltage dividing path and a first potential output path. The voltage dividing path has a first resistor and a second resistor connected in series. A low voltage sub circuit(50) highly changes a control voltage if the control voltage is lower than a preset value.

Description

Motor {MOTOR}

The present invention relates to a motor of a pulse amplitude modulation (PAM) control method.

In order to variably control the rotational speed of the motor, the driving voltage applied is largely changed. Therefore, a performance that can stably rotate and drive in a wide range from a high voltage region having a high driving voltage to a low voltage region having a low driving voltage is desired.

When rotating the motor, it is necessary to supply a predetermined pattern of current to the coil. The control is generally performed by turning on and off a power element (MOSFET: Metal Oxide Semiconductor Field Effect Transistor).

MOSFETs include N-channel MOSFETs and P-channel MOSFETs. In the case of the N-channel MOSFET, a current flows between the source electrode and the drain electrode by applying a potential on the anode side to the gate electrode (on state). In the case of the P-channel MOSFET, a current flows between the source electrode and the drain electrode by applying a potential on the cathode side to the gate electrode (on state). In the vicinity of the threshold voltage, the amount of current flowing between the source electrode and the drain electrode is affected by the magnitude of the potential applied to the gate electrode.

For example, Japanese Patent Laid-Open No. 2008-259340 discloses a motor drive circuit using an N-channel MOSFET for a power element.

In this motor drive circuit, a charge pump circuit for boosting the drive voltage is provided. The boosted voltage boosted by the charge pump circuit is converted into a regulated voltage regulated by the regulated circuit. The converted regulated voltage is output to the gate of the power element.

DESCRIPTION OF RELATED ART Conventionally, a motor drive circuit reduces a drive voltage by fixed partial pressure ratio. And the motor drive circuit outputs a control voltage to a power element using the reduced voltage. However, when the driving voltage is lowered, the control voltage output to the power element also decreases as the driving voltage decreases. Therefore, when the driving voltage is greatly reduced, the on / off operation of the power element becomes unstable. Then, there is a problem that required motor performance is not obtained, such as a decrease in rotation speed or torque.

1, the outline of the drive circuit of the power element 100 is shown. 1 illustrates a case where a P-channel MOSFET is used for the power element 100. In the case of the power element 100, two P-type regions (the source electrode 102 and the drain electrode 103) are formed apart on the N-type semiconductor 101. The gate electrode 105 is laminated through the oxide film 104 in the channel region between the source electrode 102 and the drain electrode 103.

The power element 100 is connected in the middle of a current supply line 106 that supplies a current to the coil. The power supply side (high potential side) is connected to the source electrode 102. The coil side (low potential side) is connected to the drain electrode 103. The driving voltage Vm is applied to the current supply line 106.

The voltage dividing circuit 110 has a first resistor 111 and a second resistor 112. The voltage dividing circuit 110 applies a control voltage to the power element 100. The first resistor 111 and the second resistor 112 are connected in series. The driving voltage Vm is also applied to the voltage dividing circuit 110. The gate electrode 105 is electrically connected between the first resistor 111 and the second resistor 112. The potential of the gate electrode 105 becomes the potential and coincidence between the first resistor 111 and the second resistor 112.

When the voltage dividing circuit 110 is not energized, no potential is output to the gate electrode 105. Therefore, the channel region does not conduct (off state). However, as shown in FIG. 1, when the voltage dividing circuit 110 is energized, the potential of the cathode side is output to the gate electrode 105. Then, a control voltage generated by the voltage drop is applied to the gate electrode 105 (gate voltage Vg). The channel region then conducts. Then, a current flows from the source electrode 102 to the drain electrode 103 (on state).

By the way, when driving voltage Vm is reduced, as shown in FIG. 2, gate voltage Vg will also fall accordingly. The power element 100 has a lower limit VgL of the gate voltage Vg which functions stably. If the lower limit is lower than the lower limit, the gate voltage Vg is not turned on even when the gate voltage Vg is applied. Therefore, the on-off operation of the power element 100 becomes unstable. Moreover, even if it is turned on, the electric resistance of a channel part is large. Therefore, an appropriate amount of current cannot be obtained. And the required motor performances, such as rotation speed and a torque fall, are not acquired. In this regard, the motor driving circuit of Patent Document 1 boosts the driving voltage in the charge pump circuit. Therefore, even if the driving voltage is lowered, excessive drop of the gate voltage is prevented. However, since the circuit structure is complicated, it is disadvantageous in terms of member cost and reliability.

The motor 1 of the PAM control system in which the drive voltage Vm changes is provided with the drive apparatus 4. The drive device 4 includes an upstream power element 21, a downstream power element 22, a control circuit 31, and a control voltage forming circuit 41. Then, the drive device 4 supplies a drive current to the coil 6 through the plurality of current entry / exit lines 7. The upstream power element 21 and the downstream power element 22 switch the current in / out wiring 7. The control circuit 31 applies the control voltage Vg to the upstream power element 21 and the downstream power element 22. The control voltage forming circuit 41 is provided between the control circuit 31 and the upstream power element 21. The control voltage forming circuit 41 divides the driving voltage Vm to form the control voltage Vg. As the upstream power element 21, a P-channel MOSFET is used. The control voltage forming circuit 41 is provided with a low voltage auxiliary circuit 50. And the low voltage auxiliary circuit 50 changes the control voltage Vg high, when the control voltage Vg falls below a predetermined value.

1 is a schematic view showing a preferred example of a drive circuit of a power element.
2 is a graph showing the relationship between the drive voltage Vm and the control voltage Vg.
3 is a schematic view showing a motor of a first preferred embodiment of the present invention.
4 is a schematic view showing a circuit configuration of a preferred drive device of the present invention.
5 is a schematic view showing a preferred control voltage forming circuit of the present invention.
6A and 6B are diagrams for explaining the operation of the preferred control voltage forming circuit of the present invention.
7 is a schematic diagram showing a relationship between a driving voltage and a control voltage.
8 is a schematic diagram showing a circuit configuration of a drive device in a motor according to a second preferred embodiment of the present invention.
9 is a schematic diagram showing a circuit configuration of a preferred minimum potential output circuit of the present invention.
10 is a schematic diagram showing a circuit configuration of a preferred comparison circuit of the present invention.
11 is a schematic diagram showing a circuit configuration of a drive device in a motor of a preferred modification of the present invention.
12 is a schematic diagram showing the main parts of a low voltage auxiliary circuit in a motor of a preferred modification of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described concretely based on drawing. However, the following description is merely an illustration in nature and does not limit the present invention, its application or its use.

(First Embodiment)

3 is a preferable example of an outline of the motor 1 of the present embodiment to which the present invention is applied. The motor 1 is used for a fan of a blower, for example, and is a three-phase brushless DC motor of a PAM control system. The motor 1 is provided with the rotor 2, the motor main body 3, and the drive device 4. As shown in FIG.

The rotor 2 is rotatably supported by the motor case 5 via a shaft. The motor main body 3 for rotating the rotor 2 is housed in the motor case 5. The structure of the motor main body 3 is the same as that of a conventional motor. For example, if it is an inner rotor type, the rotor 2 is formed in the circumference shape which has several magnet in the outer periphery. And the circular stator which has some coil 6 (refer FIG. 4) is arrange | positioned at the outer side of the rotor 2 between them.

The coil 6 consists of three-phase coils 6u, 6v, 6w of U, V, and W, for example. The coils 6u, 6v, 6w are connected by Y connection or delta connection according to the specification of a motor. In this embodiment, Y connection is carried out. The motor main body 3 is provided with a current entry / exit wiring 7 (current entry / exit path). The drive current is supplied from the drive device 4 to these coils 6u, 6v, 6w in a predetermined order through the current intake path.

By doing so, torque is generated by the action of each of the coils 6u, 6v, 6w sequentially excited and the permanent magnet. Then, the rotor 2 rotates. In order to change the rotational speed, the drive voltage Vm changes large and small by the PAM control system.

The drive device 4 is a circuit board made of, for example, an IC or the like. The drive device 4 is provided inside the motor case 5. The drive device 4 is connected to an external device 8 in order to receive a supply of power or the like. In the vicinity of the motor main body 3, position sensors 9, such as a hall element, are arrange | positioned. The position sensor 9 detects the position (rotation angle) of the rotor 2. The position data of the rotor 2 detected by the position sensor 9 is output to the drive device 4.

4 is a preferred example of a schematic diagram illustrating a circuit configuration of the drive device 4. As shown in the figure, the drive device 4 includes the current supply wiring 11 (current supply path), the power elements 21 and 22, the control circuit 31 (control device), and the control voltage forming circuit 41. ) (Control voltage forming device). The control voltage forming circuit 41 includes a voltage dividing circuit 47 and a low voltage auxiliary circuit 50. The low voltage auxiliary circuit 50 is provided with a voltage-division ratio variable circuit 51.

The current supply wiring 11 has a high potential side wiring 12, three switching wirings 13a, 13b, 13c (switching path), and a low potential side wiring 14.

One end of the high potential side wiring 12 is connected to the driving power supply side. Switching wirings 13a, 13b, and 13c (switching paths) are branched from the other end of the high potential side wiring 12 and arranged in parallel. One end of the low potential side wiring 14 is connected to the low potential side of the switching wirings 13a, 13b, and 13c.

The other end of the low potential side wiring 14 is grounded through the lower resistor 15. At the time of driving of the motor 1, the driving voltage Vm is applied to the current supply wiring 11.

The power elements 21 and 22 are switch elements which can be controlled on and off. The power elements 21 and 22 are connected in series with each of three switching wirings 13a, 13b, and 13c. The power elements 21 and 22 include the power element 21 (upstream power elements 21a, 21b, 21c) disposed on the high potential side, and the power element 22 (downstream power) disposed on the low potential side. Elements 22a, 22b, 22c). The upstream power element 21 is a P-channel MOSFET. The downstream power element 22 uses an N-channel MOSFET.

The current input / output wiring 7 is composed of three current input / output wirings 7a, 7b, and 7c. The current input / output wirings 7a, 7b, and 7c are respectively connected to the portion between the upstream power element 21 and the downstream power element 22 in each of the switching wirings 13a, 13b, and 13c. Then, any one of the upstream power elements 21a, 21b, 21c is controlled on. In addition, any one of the downstream power elements 22a, 22b, 22c is controlled on. By doing so, one closed circuit to which the driving voltage Vm is applied is formed.

That is, the drive current of a predetermined | prescribed flow is supplied to the predetermined | prescribed coil 6 through predetermined | prescribed order through the two current ingress / outlines 7 and 7 of the three current ingress / out wirings 7a, 7b, and 7c. For example, the upstream power element 21a is turned on, and the downstream power element 22c is turned on. At that time, the drive current flows in the order of the switching wiring 13a, the current input / output wiring 7a, the coil 6w, the coil 6v, the current input / output wiring 7c, and the switching wiring 13c.

The control circuit 31 outputs an energization signal (control signal) at a predetermined timing to control the power elements 21 and 22 on and off. The control circuit 31 is provided with the position detection input part 32, the timing control part 33, the energization signal formation part 34, the upper arm drive circuit part 35, and the lower arm drive circuit part 36. As shown in FIG. In addition, the circuit voltage Vcc lower than the drive voltage Vm is used for driving the control circuit 31.

The position detection input part 32 inputs the position data which the position sensor 9 outputs. The position detection input unit 32 converts the position data into a position signal. The position detection input unit 32 then outputs the position signal to the timing control unit 33. The timing control part 33 produces | generates the on-off signal of each power element 21 and 22 based on the position signal and the timing chart memorize | stored previously. The on-off signal turns on and off the respective power elements 21 and 22. The timing controller 33 outputs the on / off signal to the energization signal forming unit 34. The energization signal forming unit 34 generates an energization signal (specifically, a potential based on the circuit voltage Vcc) based on the on-off signal. The energization signal turns on and off the respective power elements 21 and 22 at a predetermined timing. The energization signal forming unit 34 cooperates with each of the upper arm driving circuit section 35 and the lower arm driving circuit section 36 to output the energization signal to the current supply wiring 11 side.

The energization signal is output from the lower arm drive circuit portion 36 to the gate electrode of the predetermined downstream power element 22. On the other hand, an energization signal is output from the upper arm drive circuit part 35 to the control voltage formation circuit 41. The control voltage forming circuit 41 is provided between the control circuit 31 and the upstream power element 21.

5 is a preferable example of the circuit configuration of the control voltage forming circuit 41. The control voltage forming circuit 41 forms a control voltage (also referred to as the first control voltage Vg) for controlling the upstream power element 21. The control voltage forming circuit 41 is provided for each upstream power element 21a, 21b, 21c. 5 shows one configuration of a preferred example. The drive power supply is connected upstream of the control voltage forming circuit 41. The driving voltage Vm is applied to the control voltage forming circuit 41. The control voltage forming circuit 41 divides the driving voltage Vm at a predetermined voltage division ratio. And the control voltage formation circuit 41 forms the 1st control voltage Vg.

In particular, the control voltage forming circuit 41 has a low voltage auxiliary circuit 50. For example, as the driving voltage Vm decreases, the first control voltage Vg falls below a predetermined value. In that case, the low voltage auxiliary circuit 50 changes the first control voltage Vg high. In this embodiment, the divided voltage ratio variable circuit 51 is provided as the low voltage auxiliary circuit 50. The divided voltage ratio variable circuit 51 can be changed to the first divided voltage ratio for a normal voltage and the second divided voltage ratio for a low voltage at which the first control voltage Vg becomes higher than the first divided voltage ratio.

First, the control voltage forming circuit 41 has a voltage dividing circuit 47. The voltage dividing circuit 47 has a voltage dividing line 45 (dividing path) and a potential output wiring 46 (first potential output path). The divided wiring 45 has a first resistor 43 and a second resistor 44 which are sequentially connected in series from the high potential side. The potential output wiring 46 has a potential between the first resistor 43 and the second resistor 44 in order to apply the first control voltage Vg to the upstream power element 21. 21).

The portion at the lower potential side than the second resistor 44 is grounded through a switch element (also called the first switch element 48). The first switch element 48 is an N channel MOSFET. The gate electrode of the first switch element 48 is connected to the upper arm drive circuit portion 35 through the control wiring 49. The first switch element 48 is turned on and off by the energization signal output from the upper arm drive circuit section 35.

The voltage-division ratio variable circuit 51 is composed of a voltage dividing circuit 47, a third resistor 52, a fourth resistor 53, and a switch element (also referred to as a second switch element 54). The third resistor 52 is connected in series to the portion on the higher potential side than the first resistor 43 in the divided wiring 45. The partial pressure wiring 55 (partial pressure path) is connected in parallel with a portion (also referred to as a divided resistor) provided with the third resistor 52 and the first resistor 43. The fourth resistor 53 and the second switch element 54 are connected in series to the partial pressure wiring 55 in order from the high potential side.

The second switch element 54 of the present embodiment is also an N channel MOSFET. A control voltage (also called a second control voltage) is applied to the second switch element 54. Therefore, the part between the 3rd resistance 52 and the 1st resistor 43 in the voltage division wiring 45, and the gate electrode of the 2nd switch element 54 are the potential output wiring 56 (2nd). (Potential output path). The potential between the third resistor 52 and the first resistor 43 is output to the gate electrode of the second switch element 54. In this way, when the second control voltage is applied to the second switch element 54, the second switch element 54 is turned on. The partial pressure wiring 55 is in a energized state.

Resistance values such as the third resistor 52 and the first resistor 43 are appropriately set in accordance with the performance of the gate electrode of the second switch element 54 or the upstream power element 21.

In addition, a zener diode 57 (overvoltage prevention device) is provided in parallel with the divided resistor portion and the partial pressure wiring 55. This restricts the voltage above the predetermined value to be applied to the gate electrode of the second switch element 54 or the upstream power element 21.

6, the operation | movement of a preferable example of the control voltage formation circuit 41 of such a structure is demonstrated. The motor 1 may be driven under normal drive voltage Vm by PAM control. In that case, resistance values, such as the 3rd resistance 52, are set so that the 2nd switch element 54 may be set to the stable ON state. Therefore, the partial pressure wiring 55 is in an energized state. The control voltage forming circuit 41 has a circuit configuration shown in Fig. 6A for generating a first voltage division ratio for a normal voltage.

In addition, the second switch element 54 may be turned off as the drive voltage Vm decreases. In that case, the partial pressure wiring 55 is cut off. The control voltage forming circuit 41 has a circuit configuration shown in Fig. 6B for generating a second voltage division ratio for low voltage.

In this case, the total resistance of the divided resistor portion and the portion of the partial pressure wiring 55 increases from the first divided voltage ratio. Therefore, the voltage drop amount becomes large, and the potential between the first resistor 43 and the second resistor 44 is further lowered. Therefore, in the second voltage division ratio, the first control voltage Vg applied to the gate electrode of the upstream power element 21 becomes higher than in the case of the first voltage division ratio.

And when it returns to the normal drive voltage Vm again, the 2nd switch element 54 will turn ON. And the control voltage formation circuit 41 is switched to the circuit structure which generate | occur | produces a 1st voltage division ratio.

7 shows the relationship between these drive voltages Vm and the first control voltage Vg. In FIG. 7, the case where a broken line is the 1st partial pressure ratio for normal voltage has shown the case where a solid line is the 2nd partial pressure ratio for low voltage. In the low voltage region, the second partial pressure ratio is applied. Therefore, the value of the 1st control voltage Vg with respect to the drive voltage Vm becomes relatively high. Therefore, even if the driving voltage Vm is greatly reduced, the first control voltage Vg can be kept high. Therefore, the on-off operation of the upstream power element 21 is stable. In addition, the motor performance is stable.

(Second Embodiment)

In the present embodiment, the comparison circuit 61 and the minimum potential output circuit 71 are used as the low voltage auxiliary circuit 50 instead of the voltage ratio variable circuit 51. The low voltage auxiliary circuit 50 switches the first control voltage Vg to the minimum potential in the low voltage region. In addition, the basic structure of this embodiment is the same as that of 1st embodiment. Therefore, the same structure is abbreviate | omitted using the same code | symbol, and a different point is demonstrated in detail.

8 is a preferred example of a schematic diagram showing a circuit configuration of the drive device 4 in the motor 1 of the present embodiment. As shown in the figure, the control voltage forming circuit 41 of the drive device 4 is provided with a comparison circuit 61 and a minimum potential output circuit 71. The control voltage forming circuit 41 is applied not only to the driving voltage Vm but also the circuit voltage Vcc.

9 is a preferable example of the circuit configuration of the minimum potential output circuit 71. The first control voltage Vg may be lowered below a predetermined value (also referred to as a threshold value) in which the on state of the upstream power element 21 may become unstable. In that case, the minimum potential output circuit 71 outputs 0 V (the minimum potential set by this motor 1) to the upstream power element 21.

Specifically, the minimum potential output circuit 71 has a minimum potential output wiring 72 (minimum potential output path) and a switch element (also referred to as a third switch element 73).

The minimum potential output wiring 72 has one end connected to the ground on the potential lower side than the second resistor 44 in the voltage dividing wiring 45 and the portion of the coin potential. The other end of the minimum potential output wiring 72 is connected to a portion between the first resistor 43 and the second resistor 44 in the voltage divider wiring 45. In detail, this part is connected to the gate electrode of the upstream power element 21. The third switch element 73 is provided in the middle of the minimum potential output wiring 72. The third switch element 73 is in parallel with the second resistor 44. As the third switch element 73, an N-channel MOSFET is used. One end of the potential output wiring 74 (third potential output path) is connected to the third switch element 73. The potential output wiring 74 applies a control voltage (also called a third control voltage) to the gate electrode of the third switch element 73. 10, the preferable example of the circuit structure of the comparison circuit 61 is shown. The comparison circuit 61 compares whether the first control voltage Vg has fallen below a predetermined value. The comparison circuit 61 is composed of the first divided wiring 62, the second divided wiring 63, and the comparator 64.

In the first divided wiring 62, the fifth resistor 65 and the sixth resistor 66 are connected in series from the high potential side. In the second divided wiring 63, the seventh resistor 67 and the eighth resistor 68 are connected in series from the high potential side. The circuit voltage Vcc is applied to the first divided wiring 62. The driving voltage Vm is applied to the second divided wiring 63. In addition, the resistance value of the fifth resistor 65 or the like is appropriately set according to the performance of the gate electrode of the upstream power element 21 and the comparator 64.

The portion between the fifth resistor 65 and the sixth resistor 66 in the first divided wiring 62 is connected to the terminal 64a on the high potential side of the comparator 64. The portion between the seventh resistor 67 and the eighth resistor 68 in the second divided wiring 63 is connected to the terminal 64b on the low potential side of the comparator 64. The other end of the potential output wiring 74 is connected to the output terminal 64c (potential output terminal) of the comparator 64.

The comparator 64 compares the potential of the terminal 64a on the high potential side with the potential of the terminal 64b on the low potential side. It is compared whether or not the first control voltage Vg has fallen below the threshold. And when the 1st control voltage Vg falls below a threshold value, the comparator 64 supplies H which applies a 3rd control voltage to the gate electrode of the 3rd switch element 73 via the potential output wiring 74. FIG. Output the potential of the level. Then, the third switch element 73 is turned on.

If so, the minimum potential output wiring 72 is in an energized state. Therefore, a potential of 0 V is output to the gate electrode of the upstream power element 21. The first control voltage Vg is further higher. Therefore, when the drive voltage Vm falls significantly, the motor 1 can stabilize the on-off operation of the upstream power element 21. Moreover, the motor 1 can also exhibit the motor performance stably.

On the other hand, when the first control voltage Vg exceeds the threshold, the comparator 64 supplies the L-level potential (for example, 0 V) to the gate electrode of the third switch element 73 through the potential output wiring 74. Outputs Then, the third switch element 73 is turned off. In this case, therefore, the minimum potential output wiring 72 is cut off. Therefore, the upstream power element 21 is applied with the first control voltage Vg generated under the ordinary voltage dividing circuit 47.

(Variation)

The motor 1 of this modification has the low voltage auxiliary circuit 50. The low voltage auxiliary circuit 50 includes a voltage-division ratio variable circuit 51 of the motor 1 of the first embodiment, a comparison circuit 61 and a minimum potential output circuit 71 of the motor 1 of the second embodiment. ) In combination.

11, the circuit structure of the drive device 4 in the motor 1 of this modification is shown. Since each structure of the voltage-division ratio variable circuit 51 etc. in the motor 1 is the same as that of each embodiment mentioned above, the description is abbreviate | omitted using the same code | symbol.

12, the part except the comparison circuit 61 in the low voltage auxiliary circuit 50 of this modification is shown (comparative circuit 61 is the same as 2nd Embodiment). The motor 1 of the present modification can switch the first control voltage Vg in the low voltage region in two stages.

For example, the first reference voltage and the second reference voltage lower than the first reference voltage are set. The voltage-division ratio variable circuit 51 is controlled based on the first reference voltage. The comparison circuit 61 and the minimum potential output circuit are controlled based on the second reference voltage. By doing so, the on-off operation of the upstream power element 21 in the low voltage region can be controlled more precisely and precisely. Therefore, the on-off operation of the upstream power element 21 is more stable. Motor 1 performance is also exhibited more stably.

In addition, the motor of this invention is not limited to embodiment mentioned above, It also includes various other structures. For example, the motor 1 may be an outer rotor type. The switch element (second switch 54) is not limited to the MOSFET, but may be another transistor.

Claims (6)

As a motor of the PAM control method in which the driving voltage changes,
With the rotor,
A plurality of coils,
With the motor body,
With a driving device,
The rotor is rotatably supported,
The motor main body has three or more current input / output paths,
The current in and out path is connected to the coil,
The drive device,
A current supply path, a plurality of power elements, a control device, and a control voltage forming device,
Supplying a driving current to the coil through at least two of the current in and out paths,
Drive the rotor in rotation,
The current supply path is
Includes a plurality of conversion paths arranged in parallel,
Supplying the drive current to the motor body,
The plurality of power elements,
An upstream power element and a downstream power element,
Switch the current in and out path,
The upstream power element,
P channel MOSFET,
Connected to the high potential side of the switching path,
The downstream power elements are respectively disposed on the low potential side of the switching path,
The control device outputs a control signal at a predetermined timing in order to control on / off of each of the upstream power element and the downstream power element,
The control voltage forming device,
A voltage divider circuit and a low voltage auxiliary circuit;
It is provided between the said control apparatus and the upstream power element,
A control voltage of the upstream power element is formed from the driving voltage,
The voltage dividing circuit has a voltage dividing path and a first potential output path,
The partial pressure path is,
The driving voltage is applied,
Has a first resistor and a second resistor connected in series from the high potential side,
The first potential output path outputs a potential between the first resistor and the second resistor to the upstream power element,
The low voltage auxiliary circuit causes the control voltage to change high when the control voltage falls below a predetermined value.
motor.
The method of claim 1,
The low voltage auxiliary circuit has a voltage ratio variable circuit,
The voltage dividing ratio variable circuit can be switched to a first voltage dividing ratio and a second voltage dividing ratio for a low voltage at which the control voltage becomes higher than the first voltage dividing ratio.
motor.
The method of claim 2,
The divided voltage ratio variable circuit includes the divided voltage circuit, a third resistor, and a negative divided voltage path,
The third resistor is connected in series to a portion on the side of a higher potential than the first resistor in the voltage dividing path,
The partial pressure path,
Has a fourth resistor and a switch element,
Connected in parallel with a portion provided with the third resistor and the first resistor in the divided path,
The fourth resistor and the switch element are sequentially connected in series from the high potential side,
The switch element is an N-channel MOSFET,
The second potential output path is
It is provided between the partial pressure path and the partial pressure path,
Outputting a potential between the third resistor and the first resistor to the switch element
motor.
The method of claim 1,
The low voltage auxiliary circuit has a comparison circuit and a minimum potential output circuit,
The comparison circuit compares whether or not the control voltage has fallen below a predetermined value,
The minimum potential output circuit outputs a minimum potential to the upstream power element based on an instruction from the comparison circuit when the control voltage drops below a predetermined value.
motor.

The method of claim 4, wherein
The comparison circuit has a comparator,
The comparator outputs a predetermined potential from the potential output terminal according to the comparison result,
The minimum potential output circuit has a minimum potential output path and a switch element,
One end of the minimum potential output path is connected to a potential lower than the second resistance in the voltage dividing path,
The other end of the minimum potential output path is connected to the upstream power element,
The switch element is provided in the middle of the minimum potential output path,
The switch element is an N-channel MOSFET,
The third potential output path is
Is provided between the comparison circuit and the minimum potential output path,
Outputting the potential of the potential output terminal to the switch element
motor.
The method of claim 2,
Further having the comparison circuit and the minimum potential output circuit according to claim 4
motor.

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