JP2019168425A - Step motor drive mechanism - Google Patents

Abstract

To provide a step motor drive mechanism with which it is possible to detect an external magnetic field by a step motor itself without using a magnetic sensor that is a separate component and supplying an appropriate drive pulse in accordance with the external magnetic field, thereby realizing stable drive with low electric power without being affected by the external magnetic field.SOLUTION: Provided is a step motor drive mechanism equipped with a step motor 20 having a rotor 21 and a coil and a drive circuit 10 for outputting a pulse to the step motor 20, characterized in that the drive circuit 10 includes a prescribed position pulse generation circuit 12 for outputting a prescribed position pulse for moving the rotor 21 to a prescribed position, and an induced current detection circuit 16 for detecting an induced current generated in the coil by the rotation of the rotor 21 after the rotor is rotationally driven by the prescribed position pulse, and there are included a determination circuit 4 for determining the presence of an external magnetic field in accordance with the induced current and a control circuit 3 for determining the state of an external magnetic field in accordance with the determination result of the determination circuit 4.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a step motor driving mechanism capable of detecting an external magnetic field.

  Conventionally, a small step motor has been widely used in an analog display type electronic timepiece or the like that displays time by a hand. This step motor has a stator that is magnetized by a coil and a rotor that is a two-pole magnetized disk-like rotating body, and for example, the rotor is driven to rotate 180 degrees every second so that the time is displayed by a pointer. is doing.

  This step motor has a feature that it can be driven with low power, but when placed in an external magnetic field, there is a problem that the stator is magnetized and the rotor cannot rotate normally. The ability to withstand this external magnetic field is referred to as anti-magnetism, but there is a problem that the anti-magnetism deteriorates when trying to improve the driving efficiency of the step motor, and in recent step motors for which further low power driving is required. It is a big issue.

  In order to solve this problem, a step motor that includes a magnetic sensor separately from the step motor and drives the step motor by outputting a drive pulse having a long pulse width when the magnetic sensor detects a strong magnetic field of a certain level or more. (See, for example, Patent Document 1).

  According to this Patent Document 1, it is shown that a magnetic resistance structure that deteriorates the efficiency of a step motor is not necessary, and a magnetic resistance mechanism of a step motor that is efficient and excellent in magnetic resistance can be realized.

Japanese Patent Publication No. 60-32145 (first page, FIG. 1)

  However, the magnetic resistance mechanism of the step motor disclosed in Patent Document 1 requires a magnetic sensor that detects an external magnetic field separately from the step motor. For this reason, since the number of parts increases, it is a disadvantageous structure for downsizing an electronic wristwatch or the like incorporating a step motor. In addition, it is uncertain how much the external magnetic field detected by the magnetic sensor, which is a separate component from the step motor, will affect the step motor itself. It is not clear how much the magnetic resistance of the step motor can be improved.

  The object of the present invention is to solve the above-mentioned problems and to detect an external magnetic field with a step motor itself without using a separate magnetic sensor and to supply an appropriate drive pulse according to the external magnetic field. It is to provide a step motor driving mechanism that realizes stable driving with low power without being affected.

  In order to solve the above problems, the step motor driving mechanism of the present invention employs the following configuration.

  A step motor driving mechanism of the present invention includes a step motor having a rotor magnetized with two or more poles in a radial direction, a coil for applying a magnetic field to the rotor, and a drive circuit for outputting a pulse to the step motor. A step motor driving mechanism comprising: a predetermined position pulse generating circuit that outputs a predetermined position pulse for moving the rotor to a predetermined position; and a rotor that rotates the rotor by the predetermined position pulse, and then the coil is rotated by the rotation of the rotor. And an induced current detection circuit for detecting an induced current generated in the circuit, and a determination circuit that determines the presence or absence of an external magnetic field according to the induced current, and a determination of an external magnetic field status according to a determination result of the determination circuit And a control circuit.

  With the step motor driving mechanism of the present invention, it is possible to determine the state of the external magnetic field by detecting the induced current generated by the rotation of the rotor of the step motor. Thereby, since the magnetic sensor as another component is unnecessary, the number of components can be reduced. Further, since the external magnetic field is detected by the step motor itself, it is possible to provide a step motor drive mechanism that reliably detects the external magnetic field that affects the step motor with high accuracy.

  The determination circuit may compare the induced current generated in the coil with a predetermined threshold and output a detection signal to the control circuit.

  Thereby, the presence or absence of an external magnetic field can be easily determined by the determination circuit comparing the induced current from the coil with a predetermined threshold value.

  The control circuit may count the output time of the detection signal of the determination circuit and determine the state of the external magnetic field.

  Thereby, the control circuit can grasp | ascertain the condition of an external magnetic field in detail by counting the output time of a detection signal. As a result, the driving of the step motor performed by the control circuit can be appropriately controlled according to the external magnetic field.

  Moreover, it is good to have two or more predetermined threshold values.

  Thereby, since the level of the strength of the external magnetic field can be determined, the driving of the step motor can be controlled according to the strength of the external magnetic field. For example, if two thresholds are provided, the strength of the external magnetic field can be determined in three stages of weak, medium, and strong, and a wide range can be handled according to the strength of the external magnetic field.

  Further, a plurality of step motors may be arranged, and the external magnetic field direction detected by at least one step motor may be different from the external magnetic field direction detected by another step motor.

  As a result, there is no blind spot in the magnetic field detection direction, and detection is possible no matter which direction the external magnetic field is applied from, so that the driving of the step motor can be controlled according to the excitation direction of the external magnetic field.

  The drive circuit may include a drive pulse generation circuit that outputs a drive pulse for driving the rotor, and the control circuit may change the drive pulse by controlling the drive pulse generation circuit according to the state of the external magnetic field.

  Thereby, the control circuit can change the drive pulse according to the state of the external magnetic field. As a result, low power driving with little energy loss is possible with respect to the step motor, and stable driving can be realized with the influence of the external magnetic field being suppressed.

  The control circuit may determine the excitation direction of the external magnetic field and change the drive pulse according to the excitation direction and the rotation direction of the rotor.

  Thereby, the control circuit can be changed to an optimum drive pulse according to the excitation direction of the external magnetic field and the rotation direction of the rotor. As a result, the step motor can be driven with low power and can be driven stably against an external magnetic field.

  The control circuit may output a drive pulse larger than the drive pulse when it is determined that there is no external magnetic field when the determined excitation direction has a polarity repelling the rotation direction of the rotor.

  As a result, a driving pulse having a large driving force that cancels the influence of the external magnetic field is output, so that the step motor can be driven stably and reliably without being affected by the external magnetic field.

  The control raw circuit may output a drive pulse smaller than the drive pulse when it is determined that there is no external magnetic field when the determined excitation direction has a polarity attracted to the rotation direction of the rotor.

  Thereby, since the drive pulse of the small drive force using an external magnetic field is output, a step motor can be driven at low electric power.

  The predetermined position pulse generation circuit may output the predetermined position pulse before the drive pulse generation circuit outputs the drive pulse.

  As a result, the state of the external magnetic field immediately before driving the step motor can be detected, so that even if the external magnetic field fluctuates with time, the step motor can be driven quickly corresponding to the external magnetic field.

  The step motor has a stator that guides the magnetic field generated in the coil to the rotor. The stator includes a first stator magnetic pole portion, a second stator magnetic pole portion, a first stator magnetic pole portion, and a second stator magnetic pole portion. A third stator magnetic pole portion provided between the stator magnetic pole portion and facing the rotor, wherein the coil magnetically couples the first stator magnetic pole portion and the third stator magnetic pole portion to each other. A second coil that magnetically couples the second stator magnetic pole part and the third stator magnetic pole part, and the predetermined position pulse generation circuit outputs the predetermined position pulse to the first coil and the second coil. The magnetic field direction of the rotor when the predetermined position pulse is output and the rotor magnetic field direction when the predetermined position pulse is not output may be parallel to each other.

  As a result, the step motor has two coils, and the induced current generated by applying the predetermined position pulse can be detected by the two coils as a pair, so the presence / absence of the external magnetic field and the excitation direction are detected with high accuracy. A step motor drive mechanism can be provided.

  The step motor has a stator that guides the magnetic field generated in the coil to the rotor. Each of the coil and the stator is configured by one, and the predetermined position pulse generation circuit outputs a predetermined position pulse to the coil. The magnetic field direction of the rotor when the predetermined position pulse is output may be different from the magnetic field direction of the rotor when the predetermined position pulse is not output.

  Thereby, the step motor is composed of only one coil, and a small and lightweight step motor driving mechanism capable of detecting an external magnetic field by applying a predetermined position pulse can be provided.

According to the step motor driving mechanism of the present invention, it is possible to provide a small step motor driving mechanism that does not require a separate magnetic sensor and has a small number of parts. Further, since the external magnetic field is detected by the step motor itself, the external magnetic field that affects the step motor can be reliably detected with high accuracy. As a result, low-power driving with little energy loss is possible, and stable driving can be realized by suppressing the influence of an external magnetic field. In addition, since the magnetic resistance is improved by driving according to the external magnetic field, the magnetic resistance of an electronic timepiece or the like incorporating the step motor driving mechanism of the present invention is improved, and an electronic device having excellent magnetic resistance can be provided.

It is a block diagram of the step motor drive mechanism concerning 1st Embodiment of this invention. 1 is a circuit diagram of a driver circuit and an induced current detection circuit according to a first embodiment of the present invention. It is a top view of the 2 coil step motor concerning the 1st and 2nd embodiment of the present invention. It is explanatory drawing which shows the motor drive pulse waveform in case the N pole of the rotor of the 2 coil step motor concerning 1st and 2nd embodiment of this invention is 0 degree | times, and rotation operation of a rotor. It is explanatory drawing which shows the motor drive pulse waveform and rotation operation of a rotor in case the N pole of the rotor of the 2 coil step motor concerning 1st and 2nd embodiment of this invention is 180 degree | times. It is explanatory drawing of the 2 coil step motor influenced by the external magnetic field concerning 1st and 2nd embodiment of this invention. It is explanatory drawing of the external magnetic field detection operation by a step motor when the external magnetic field concerning 1st Embodiment of this invention is added from the left direction. It is a timing chart explaining operation | movement of the induced current detection circuit and determination circuit concerning 1st Embodiment of this invention. It is explanatory drawing of the external magnetic field detection operation | movement by a step motor when there is no external magnetic field concerning 1st Embodiment of this invention. It is a table | surface explaining the external magnetic field detection operation conditions concerning 1st Embodiment of this invention. It is a flowchart explaining the external magnetic field detection operation | movement and step motor drive operation | movement concerning 1st Embodiment of this invention. FIG. 2 is a step motor drive pulse waveform diagram and a step motor drive operation diagram when the rotation direction of the rotor according to the first embodiment of the present invention repels an external magnetic field. FIG. 6 is a step motor driving operation diagram 2 when the rotation direction of the rotor according to the first embodiment of the present invention repels an external magnetic field. FIG. 5 is a drive pulse waveform diagram of a step motor and a step motor drive operation diagram 1 when the rotation direction of the rotor according to the first embodiment of the present invention attracts an external magnetic field. FIG. 6 is a step motor driving operation diagram 2 when the rotation direction of the rotor according to the first embodiment of the present invention attracts an external magnetic field. It is explanatory drawing which selects the magnitude of a drive pulse according to the excitation direction of an external magnetic field concerning the 1st Embodiment of this invention, the polarity of a rotor, and a rotation direction. It is a block diagram of the step motor drive mechanism concerning 2nd Embodiment of this invention. It is a layout view of a step motor drive mechanism according to a second embodiment of the present invention. It is a timing chart explaining operation | movement of the induced current detection circuit and determination circuit concerning 2nd Embodiment of this invention. It is a schematic block diagram of the step motor drive mechanism and 1 coil step motor concerning 3rd Embodiment of this invention. It is an operation | movement figure of the step motor which detects the external magnetic field from the left direction concerning 3rd Embodiment of this invention. It is a timing chart which shows operation | movement of the induced current detection circuit and determination circuit which detect the external magnetic field from the left direction concerning 3rd Embodiment of this invention, and the drive diagram of a step motor. It is an operation | movement figure of the step motor which detects the external magnetic field from the right direction concerning 3rd Embodiment of this invention. It is a timing chart which shows the operation | movement of the induced current detection circuit and determination circuit which detect the external magnetic field from the right direction concerning 3rd Embodiment of this invention, and the drive diagram of a step motor. It is an operation | movement diagram of the step motor which detects an external magnetic field when there is no external magnetic field concerning 3rd Embodiment of this invention. It is a timing chart which shows operation | movement of the induced current detection circuit and determination circuit when there is no external magnetic field concerning 3rd Embodiment of this invention, and the drive diagram of a step motor. It is a table | surface explaining the selection of the drive pulse according to the polarity of the rotor concerning 3rd Embodiment of this invention, and the number of detection signals.

  Hereinafter, preferred first to third embodiments of the present invention will be described in detail with reference to FIGS. In the description of the drawings, the same or equivalent elements will be denoted by the same reference numerals, and redundant description will be omitted. The scale and the like of the drawings are changed as appropriate for explanation, and a part of them is schematically shown so that the structure can be easily understood.

[Features of each embodiment]
The first embodiment is a basic configuration of the present invention, and is characterized in that an external magnetic field is detected by a two-coil step motor, a drive pulse is selected according to the external magnetic field, and the step motor is driven.

  The second embodiment includes a plurality of two-coil step motors, and drives the step motor by selecting a drive pulse according to an external magnetic field detected by the plurality of step motors.

  The third embodiment is characterized in that an external magnetic field is detected by a one-coil step motor, and a step pulse is driven by selecting a drive pulse in accordance with the external magnetic field.

[First Embodiment]
[Description of Step Motor Configuration Mechanism of First Embodiment: FIG. 1]
The configuration of the step motor drive mechanism of the first embodiment will be described with reference to FIG. As shown in FIG. 1, a step motor driving mechanism 1 includes an oscillation circuit 2 that outputs a reference signal P1, a control circuit 3 that inputs a reference signal P1 and outputs control signals CN1 to CN3 and the like that control each circuit, A two-coil step motor 20 having two rotors 21 and two coils A and B (hereinafter referred to as “motor 20”), a drive circuit 10 for supplying drive pulses to the motor 20, and an induced pulse signal CS from the drive circuit 10 are input. The determination circuit 4 and the like are configured.

  The drive circuit 10 has a circuit configuration surrounded by a broken line. The drive pulse generation circuit 11 receives a control signal CN1 and outputs a drive pulse SP. The drive circuit 10 receives a control signal CN2 and outputs a predetermined position pulse AP. A generation circuit 12, a pulse selection circuit 13 that inputs a drive pulse SP and a predetermined position pulse AP and outputs a motor pulse MP, a detection pulse generation circuit 14 that inputs a control signal CN3 and outputs an induced current detection pulse CP, a motor pulse The driver circuit 15 that inputs the MP and the induced current detection pulse CP and supplies the motor drive pulses O1 to O4 to the motor 20, inputs the motor drive pulses O1 to O4 and the induced current detection pulse CP, and outputs the induced pulse signal CS. The induced current detection circuit 16 is configured.

  The determination circuit 4 receives the induced pulse signal CS from the induced current detection circuit 16, compares it internally with a predetermined threshold value Vth, and outputs the comparison result to the control circuit 3 as a detection signal DS. Although not shown, the determination circuit 4 may be a C-MOS inverter circuit or the like in which about 1/2 of the power supply voltage becomes the threshold value Vth. Further, a circuit capable of adjusting the detection sensitivity for the induced pulse signal CS by making the threshold value Vth variable may be employed.

  The induced pulse signal CS and the detection signal DS are each composed of four signals (the induced pulse signals CS1 to CS4 and the detection signals DS1 to DS4), but when expressed together, the induced pulse signal CS and the detection signal DS Called.

[Description of circuit configuration of driver circuit and induced current detection circuit: FIG. 2]
Next, an example of the circuit configuration of the driver circuit 15 that drives the motor 20 and the induced current detection circuit 16 that detects the induced current due to the external magnetic field from the movement of the rotor 21 of the motor 20 will be described with reference to FIG.

  As shown in FIG. 2, the driver circuit 15 includes a total of four buffer circuits. That is, the buffer circuit formed by complementary connection of the transistor P1 which is a P-channel MOS transistor having a low ON resistance and the transistor N1 which is an N-channel MOS transistor having a low ON resistance outputs a motor driving pulse O1 to output the motor 20 It is connected to the coil terminal O1 of the coil A.

  Similarly, a buffer circuit composed of a transistor P2 and a transistor N2 having a low ON resistance outputs a motor drive pulse O2 and is connected to the coil terminal O2 of the coil A.

  Similarly, a buffer circuit composed of a transistor P3 and a transistor N3 having a low ON resistance outputs a motor drive pulse O3 and is connected to the coil terminal O3 of the coil B of the motor 20.

  Similarly, a buffer circuit composed of a transistor P4 and a transistor N4 having a low ON resistance outputs a motor drive pulse O4 and is connected to the coil terminal O4 of the coil B.

  Although not shown, the gate terminals G of the transistors P1 to P4 and N1 to N4 are ON / OFF controlled by inputting the motor pulse MP from the pulse selection circuit 13 (see FIG. 1), and the motors are applied to the coils A and B. Drive pulses O1 to O4 are supplied.

  Next, the induced current detection circuit 16 has four sets of P-channel MOS transistors TP1 to TP4 (hereinafter referred to as “transistors TP1 to TP4”) and detection resistors R1 to R4. The source terminal S of the transistor TP1 is connected to the power supply VDD, the drain terminal D of the transistor TP1 is connected to one terminal of the detection resistor R1, and the other terminal of the detection resistor R1 is connected to the coil terminal O1 of the coil A. .

  The source terminal S of the transistor TP2 is connected to the power supply VDD, the drain terminal D of the transistor TP2 is connected to one terminal of the detection resistor R2, and the other terminal of the detection resistor R2 is connected to the coil terminal O2 of the coil A. Is done.

  The source terminal S of the transistor TP3 is connected to the power supply VDD, the drain terminal D of the transistor TP3 is connected to one terminal of the detection resistor R3, and the other terminal of the detection resistor R3 is connected to the coil terminal O3 of the coil B. Is done.

The source terminal S of the transistor TP4 is connected to the power supply VDD, the drain terminal D of the transistor TP4 is connected to one terminal of the detection resistor R4, and the other terminal of the detection resistor R4 is connected to the coil terminal O4 of the coil B. Is done.
Connection points between the four detection resistors R1 to R4 and the coil terminals O1 to O4 of the motor 20 are input to the determination circuit 4 (see FIG. 1) as induced pulse signals CS1 to CS4. The details of the induced pulse signal CS will be described later.

  The four motor drive pulses O1 to O4 output from the driver circuit 15 are connected to the coil terminals O1 to O4 of the coils A and B of the motor 20, respectively. The pulse and each coil terminal have a common code.

[Schematic description of the 2-coil step motor of the first embodiment: FIG. 3]
Next, a schematic configuration of the two-coil motor 20 used in the first embodiment and the second embodiment to be described later will be described with reference to FIG. Although the configuration of the two-coil step motor is known, it is necessary for understanding the present invention, so the outline will be described below.

  As shown in FIG. 3, the motor 20 includes a rotor 21, a stator 22, two coils A and a coil B that apply a magnetic field to the rotor 21. The rotor 21 is a disk-shaped rotating body magnetized with two poles, and N and S poles are magnetized in the radial direction.

  The stator 22 has a function of guiding the magnetic field generated by the coils A and B to the rotor 21. The stator 22 is made of a soft magnetic material and is provided with a rotor hole 22d into which the rotor 21 is inserted. The rotor 21 is disposed in the rotor hole 22d.

  The stator 22 is substantially opposed to the rotor 21 and includes a first stator magnetic pole portion 22a (hereinafter referred to as “first magnetic pole portion 22a”) and a second stator magnetic pole portion 22b (hereinafter referred to as “second magnetic pole portion 22b”). Is provided. A third stator magnetic pole portion 22c (hereinafter referred to as “third magnetic pole portion 22c”) is provided at a position between the first magnetic pole portion 22a and the second magnetic pole portion 22b and facing the rotor 21.

  The coil A, which is the first coil, magnetically couples the first magnetic pole part 22a and the third magnetic pole part 22c, and the coil B, which is the second coil, is the second magnetic pole part 22b and the third magnetic pole part. The part 22c is magnetically coupled.

  The coil A has coil terminals O1 and O2 on the insulating substrate 23a, and both ends of the winding of the coil A are connected. The coil B has coil terminals O3 and O4 on the insulating substrate 23b, and both ends of the winding of the coil B are connected. Motor drive pulses O1 to O4 output from the driver circuit 15 are supplied to the coil terminals O1 to O4, respectively.

  Further, the rotor 21 shown in FIG. 3 is in a stationary state, and the upper part of the drawing is defined as 0 degree, and 90 degrees, 180 degrees, and 270 degrees are defined counterclockwise from the position. The rotor 21 is at a stationary position (static stable point) when the N pole is located at 0 degrees and when it is located at 180 degrees. Therefore, the rotor 21 shown in FIG. 3 has the N pole at a stationary position of 0 degree.

[Description of basic operation of step motor: FIGS. 4 and 5]
Next, although the driving operation of the two-coil step motor is known, it is necessary for understanding the present invention. Therefore, an example of a motor driving pulse for driving the motor 20 and an outline of the rotating operation of the motor 20 are shown in FIG. 4 and FIG. In addition, each code | symbol of the motor 20 in the following description and the stationary position of the rotor 21 are based on FIG.

First, the motor drive pulses O1 to O4 and the rotation operation of the rotor 21 when the N pole of the rotor 21 reverses (counterclockwise) from the stationary position of 0 degrees will be described with reference to FIG. FIG. 4A shows waveforms of motor drive pulses O1 to O4 for reversing the N pole of the rotor 21 of the motor 20 from the stationary position of 0 degrees, and FIG. 4B shows the N pole of the rotor 21 being stationary. FIG. 4 (c) to FIG. 4 (e) show the rotation operation of the rotor 21 by the motor drive pulses O1 to O4.

  As shown in FIG. 4A, when the N pole of the rotor 21 is at a stationary position of 0 degrees, the motor drive pulses O1 to O4 are divided into three divided drive pulses SP11 in order to reverse the rotor 21 by one step (180 degrees). , SP12, SP13. The potentials of the divided drive pulses SP11, SP12, SP13 are composed of 0V (VDD) and -V (for example, -1.5V).

  The divided drive pulses SP11 to SP13 are sequentially supplied to the coil A and the coil B of the motor 20. First, when the divided drive pulse SP11 is supplied, the coil terminal O1 of the coil A becomes −V, the coil terminal O2 becomes 0V, and the coil terminals O3 and O4 of the coil B both become 0V. As a result, a drive current flows from O2 to O1 of the coil A, and no drive current flows to the coil B.

  As a result, as shown in FIG. 4C, a magnetic flux is generated in the coil A (leftward arrow), and the first magnetic pole portion 22a is magnetized to the S pole and the third magnetic pole portion 22c is magnetized to the N pole. Further, since no magnetic flux is generated in the coil B, the second magnetic pole portion 22b has the same N pole as the third magnetic pole portion 22c. As a result, the N pole of the rotor 21 and the S pole of the first magnetic pole portion 22a attract each other, and the rotor 21 rotates about 60 degrees counterclockwise.

  Next, when the divided drive pulse SP12 is supplied to the motor 20, both the coil terminals O1 and O2 of the coil A become 0V, the coil terminal O3 of the coil B becomes -V, and O4 becomes 0V. As a result, the drive current does not flow through the coil A, and the drive current flows from O4 to O3 of the coil B.

  As a result, as shown in FIG. 4D, a magnetic flux is generated in the coil B (right arrow), and the second magnetic pole portion 22b is magnetized to the N pole and the third magnetic pole portion 22c is magnetized to the S pole. Further, since no magnetic flux is generated in the coil A, the first magnetic pole portion 22a has the same S pole as the third magnetic pole portion 22c. As a result, the N pole of the rotor 21 and the S pole of the first magnetic pole portion 22a and the third magnetic pole portion 22c attract each other, and the rotor 21 further rotates about 60 degrees counterclockwise.

  Next, when the divided drive pulse SP13 is supplied to the motor 20, the coil terminal O1 of the coil A becomes 0V, the coil terminal O2 becomes -V, the coil terminal O3 of the coil B becomes -V, and O4 becomes 0V. As a result, a drive current flows from O1 to O2 of the coil A, and a drive current flows from O4 to O3 of the coil B.

  As a result, as shown in FIG. 4 (e), magnetic fluxes in the same direction are generated in both the coil A and the coil B (both arrows pointing to the right), and the first magnetic pole part 22a and the second magnetic pole part 22b are N poles. The third magnetic pole portion 22c is magnetized to the S pole. As a result, the N pole of the rotor 21 and the S pole of the third magnetic pole portion 22c attract each other, so that the rotor 21 further rotates about 60 degrees counterclockwise, and the rotor 21 is at a stationary position of 0 degrees (see FIG. 4B). ) To 180 degrees (one step), and the N pole of the rotor 21 is at a stationary position of 180 degrees.

  Next, the motor drive pulses O1 to O4 and the rotation operation of the rotor 21 when the N pole of the rotor 21 is further reversed (counterclockwise) from the stationary position 180 degrees will be described with reference to FIG. 5A shows waveforms of motor drive pulses O1 to O4 for reversing the N pole of the rotor 21 of the motor 20 from the stationary position of 180 degrees, and FIG. 5B shows the N pole of the rotor 21 being stationary. FIG. 5C to FIG. 5E show the rotation operation of the rotor 21 by the motor drive pulses O1 to O4.

As shown in FIG. 5A, when the N pole of the rotor 21 is 180 degrees, the motor drive pulses O1 to O4 are divided into three divided drive pulses SP21 and SP22 in order to reverse the rotor 21 by one step (180 degrees). , SP23. Divided drive pulses SP21, SP22, SP
The potential of 23 is composed of 0 V (VDD) and −V (for example, −1.5 V).

  The divided drive pulses SP21 to SP23 are sequentially supplied to the coil A and the coil B of the motor 20. First, when the divided drive pulse SP21 is supplied, the coil terminal O1 of the coil A becomes 0V, the coil terminal O2 becomes -V, and the coil terminals O3 and O4 of the coil B both become 0V. As a result, a drive current flows from O1 to O2 of the coil A, and no drive current flows to the coil B.

  As a result, as shown in FIG. 5C, a magnetic flux is generated in the coil A (right arrow), and the first magnetic pole portion 22a is magnetized to the N pole and the third magnetic pole portion 22c is magnetized to the S pole. Further, since no magnetic flux is generated in the coil B, the second magnetic pole portion 22b has the same S pole as the third magnetic pole portion 22c. As a result, the S pole of the rotor 21 and the N pole of the first magnetic pole portion 22a are attracted, and the rotor 21 rotates about 60 degrees counterclockwise.

  Next, when the divided drive pulse SP22 is supplied to the motor 20, both the coil terminals O1 and O2 of the coil A become 0V, the coil terminal O3 of the coil B becomes 0V, and O4 becomes -V. As a result, the drive current does not flow through the coil A, and the drive current flows from O3 to O4 of the coil B.

  As a result, as shown in FIG. 5D, a magnetic flux is generated in the coil B (left-pointing arrow), and the second magnetic pole portion 22b is magnetized to the S pole and the third magnetic pole portion 22c is magnetized to the N pole. Further, since no magnetic flux is generated in the coil A, the first magnetic pole portion 22a has the same N pole as the third magnetic pole portion 22c. As a result, the S pole of the rotor 21 and the N pole of the first magnetic pole portion 22a and the third magnetic pole portion 22c attract each other, and the rotor 21 further rotates about 60 degrees counterclockwise.

  Next, when the divided drive pulse SP23 is supplied to the motor 20, the coil terminal O1 of the coil A becomes -V, the coil terminal O2 becomes 0V, the coil terminal O3 of the coil B becomes 0V, and O4 becomes -V. As a result, a drive current flows from O2 to O1 of the coil A, and a drive current flows from O3 to O4 of the coil B.

  As a result, as shown in FIG. 5 (e), magnetic fluxes in the same direction are generated in both the coil A and the coil B (both left arrows), and the first magnetic pole part 22a and the second magnetic pole part 22b are S poles, The third magnetic pole portion 22c is magnetized to the N pole. As a result, the S pole of the rotor 21 and the N pole of the third magnetic pole portion 22c attract each other, and the rotor 21 further rotates about 60 degrees counterclockwise. The rotor 21 is at a stationary position of 180 degrees (see FIG. 5B). ) To 180 degrees (one step), and the N pole of the rotor 21 becomes the original stationary position of 0 degrees.

  Although the forward rotation (clockwise) of the motor 20 can be realized by changing the direction of the drive current of each of the divided drive pulses of the motor drive pulses O1 to O4, the description is omitted because it is well known. As described above, the 2-coil step motor can be driven in reverse and forward by three divided drive pulses, and the reverse and forward drive have the same timing drive waveform. It has the characteristics that the speed is equal and high-speed driving is possible.

[Description of 2-coil step motor affected by external magnetic field: FIG. 6]
Next, how the stationary position of the rotor 21 is affected when a magnetic field is applied from the outside to the motor 20 described with reference to FIGS. 3 to 5 will be described with reference to FIG.

  FIG. 6A shows the rotor 21 when the N-pole external magnetic field N is applied to the motor 20 from the left direction on the drawing when the N-pole of the rotor 21 of the motor 20 is at a stationary position of 0 degrees. Indicates the position.

In this case, as shown in FIG. 6A, the N pole of the rotor 21 repels the external magnetic field N, and the S pole of the rotor 21 attracts the external magnetic field N. As described above, the N pole rotates from a stationary position of 0 degree to a position of several tens of degrees in the right direction on the drawing and stops still.

  FIG. 6B shows the position of the rotor 21 when the external magnetic field N is applied to the motor 20 from the left in the drawing when the N pole of the rotor 21 of the motor 20 is at a stationary position of 180 degrees. Is shown.

  In this case, as shown in FIG. 6B, the N pole of the rotor 21 repels the external magnetic field N, and the S pole of the rotor 21 attracts the external magnetic field N. As described above, the N pole rotates from a stationary position of 180 degrees to a position of several tens of degrees in the right direction on the drawing and stops still.

  FIG. 6C shows the position of the rotor 21 when the external magnetic field N is applied to the motor 20 from the right direction on the drawing when the N pole of the rotor 21 of the motor 20 is at a stationary position of 0 degrees. Is shown.

  In this case, since the N pole of the rotor 21 repels the external magnetic field N and the S pole of the rotor 21 attracts the external magnetic field N as shown in FIG. As described above, the N pole rotates from a stationary position of 0 degree to a position of several tens of degrees in the left direction on the drawing and stops still.

  FIG. 6D shows the position of the rotor 21 when the external magnetic field N is applied to the motor 20 from the right direction on the drawing when the N pole of the rotor 21 of the motor 20 is at a stationary position of 180 degrees. Show.

  In this case, since the N pole of the rotor 21 repels the external magnetic field N and the S pole of the rotor 21 attracts the external magnetic field N, as shown in FIG. As described above, the N pole rotates from a stationary position of 180 degrees to a position of several tens of degrees in the left direction on the drawing and stops still. Of course, the rotation angle of the rotor 21 due to the influence of the external magnetic field N changes according to the strength of the magnetic field of the external magnetic field N.

  As described above, when the external magnetic field N is applied to the motor 20, the influence on the rotor 21 due to the excitation direction of the external magnetic field N and the polarity of the rotor 21 is as shown in FIGS. 6 (a) to 6 (d). It can be understood that there are four patterns. In the first embodiment, it is not assumed that the external magnetic field N is applied from the vertical direction on the drawing.

[Description of External Magnetic Field Detection Operation of First Embodiment: FIG. 7]
Next, the detection operation of the external magnetic field N using the motor 20 will be described with reference to FIG. Of the four patterns affected by the external magnetic field N described above, the N pole of the rotor 21 shown in FIG. 6A is at a stationary position of 0 degrees, and the external magnetic field N is applied from the left in the drawing. Will be described as an example.

  FIG. 7A shows a state in which the external magnetic field N is applied from the left direction in the drawing when the N pole of the rotor 21 of the motor 20 is at a stationary position of 0 degrees. As shown in FIG. 7 (a), the rotor 21 rotates the N pole to the position of several tens of degrees in the right direction in the drawing, so that the magnetic flux Φ emitted from the N pole of the rotor 21 is close to the N pole. It passes through the second magnetic pole portion 22b. This magnetic flux Φ is indicated by a broken arrow Φ pointing downward on the second magnetic pole portion 22b (coil B side). The magnetic flux Φ that has passed through the second magnetic pole portion 22b passes through the first magnetic pole portion 22a and the third magnetic pole portion 22c and is divided approximately by half and reaches the S pole of the rotor 21.

The magnetic flux passing through the first magnetic pole portion 22a (coil A side) is shown as an upward broken arrow -Φ / 2, and the magnetic flux passing through the third magnetic pole portion 22c is also shown as an upward broken arrow -Φ / 2. When the direction of the magnetic flux is downward on the drawing, the magnetic flux is positive (not shown), and when the direction of the magnetic flux is upward on the drawing, the magnetic flux is negative (notation “−”). This notation of magnetic flux is the same in FIG. 9 described later.

  Next, FIG. 7B shows the rotation state of the rotor 21 and the magnetic poles when a predetermined position pulse AP (not shown) is supplied to both the coils A and B in order to detect the presence or absence of the external magnetic field N. The generated magnetic flux is shown. Here, when a predetermined position pulse AP is supplied to the coils A and B, both the first magnetic pole portion 22a and the second magnetic pole portion 22b generate a magnetic flux Φ / 2 indicated by a downward solid line arrow as shown in the figure. . The third magnetic pole portion 22c passes through the magnetic flux −Φ indicated by an upward solid line arrow that combines the two magnetic fluxes Φ / 2 of the first magnetic pole portion 22a and the second magnetic pole portion 22b.

  As a result, the first magnetic pole portion 22a and the second magnetic pole portion 22b are excited to the S pole, and the third magnetic pole portion 22c is excited to the N pole. As a result, the N pole of the rotor 21 was rotated to the right by several tens of degrees from the stationary position 0 degrees by the external magnetic field N (see FIG. 7A), but the N pole of the rotor 21 was turned by the predetermined position pulse AP. The S pole of both the first magnetic pole part 22a and the second magnetic pole part 22b attracts, and the S pole of the rotor 21 attracts the N pole of the third magnetic pole part 22c. The rotor 21 rotates due to the magnetic pole attracting, and the N pole of the rotor 21 returns to a stationary position of 0 degrees, which is a predetermined position, as indicated by an arrow.

  Next, FIG. 7C shows the rotation state of the rotor 21 and the magnetic flux generated in each magnetic pole after the supply of the predetermined position pulse AP is completed. Here, since the magnetic field affecting the motor 20 is only the external magnetic field N again, the rotor 21 is affected by the external magnetic field N, and the N pole is in the right direction on the drawing as in FIG. Rotate to a position of several tens of degrees as shown by the arrows.

  As a result, the magnetic flux Φ emitted from the N pole of the rotor 21 passes through the second magnetic pole portion 22b close to the N pole again. Further, the magnetic flux Φ that has passed through the second magnetic pole portion 22b passes through the first magnetic pole portion 22a and the third magnetic pole portion 22c approximately in half, and becomes the magnetic flux −Φ / 2. To.

  As described above, when the N pole of the rotor 21 is at a predetermined stationary position of 0 degrees, when the external magnetic field N is applied from the left direction, the rotor 21 is rotated to the right by several tens of degrees. By the application, the N pole of the rotor 21 returns to the stationary position 0 degree of the predetermined position, and when the predetermined position pulse AP ends, it is again rotated to the right by several tens of degrees under the influence of the external magnetic field N. It is a feature of the present invention that, after the end of the predetermined position pulse AP, the presence or absence of the external magnetic field N and the excitation direction are determined by detecting the movement of the rotor 21 whose rotation returns again due to the influence of the external magnetic field N.

  The magnetic field direction of the rotor 21 when the predetermined position pulse AP is output (see FIG. 7B) and the magnetic field direction of the rotor 21 when the predetermined position pulse AP is not output and there is no external magnetic field N (see FIG. 7B). The predetermined position pulse AP is output so that the N pole is at a stationary position of 0 degree (see FIG. 3) in the same direction (parallel).

  Although not shown, when the N pole of the rotor 21 is at a stationary position of 180 degrees, the current direction of the predetermined position pulse AP with respect to the coils A and B is reversed, and the N of the rotor 21 when the predetermined position pulse AP is output. The poles should be parallel (i.e., 180 degrees rest position). As described above, the magnetic field direction of the rotor 21 by the predetermined position pulse AP is made parallel to the magnetic field direction of the rotor 21 (N pole is 0 degree or 180 degrees), so that after the predetermined position pulse AP ends. The external magnetic field N can be detected from the rotation of the rotor 21.

[Description of detection operation of external magnetic field by induced current detection circuit and determination circuit: FIG. 8]
Next, with respect to the detection operation of the external magnetic field N by the motor 20 shown in FIG. 7 (when the N pole of the rotor 21 is at a stationary position of 0 degree and the external magnetic field N is from the left), the induced current detection circuit 16 and the determination circuit This will be described from the viewpoint of 4 with reference to the timing chart of FIG. Reference is made to the configuration diagram of FIG. 1, the circuit diagram of FIG. 2, and the operation diagram of FIG.

  As shown in FIG. 8, in order to detect the external magnetic field N, a predetermined position pulse AP is supplied to both coils A and B of the motor 20 with a predetermined pulse width. Thereby, each magnetic pole of the motor 20 is excited, and the N pole of the rotor 21 is temporarily returned to a predetermined stationary position of 0 degree (see FIG. 7B).

  When the supply of the predetermined position pulse AP is completed at the timing T1 after a predetermined time, the rotor 21 is rotated to the right again by several tens of degrees under the influence of the external magnetic field N (see FIG. 7C). When the rotor 21 rotates again under the influence of the external magnetic field N, the magnetic flux passing through the coil A changes from magnetic flux Φ / 2 (see FIG. 7B) to magnetic flux −Φ / 2 (see FIG. 7C). ). Further, the magnetic flux passing through the coil B changes from the magnetic flux Φ / 2 (see FIG. 7B) to the magnetic flux Φ (see FIG. 7C).

  The induced current IC1 shown in FIG. 8 is an induced current of the coil A induced by the magnetic flux changing from the magnetic flux Φ / 2 of the coil A to the magnetic flux −Φ / 2. Further, the induced current IC2 shown in FIG. 8 is an induced current of the coil B induced by the magnetic flux that changes from the magnetic flux Φ / 2 of the coil B to the magnetic flux Φ. Here, the induced current IC1 is generated by a large change in the magnetic flux from Φ / 2 to -Φ / 2 and the absolute value of the magnetic flux Φ. The induced current IC2 is generated by a small change of the magnetic flux from Φ / 2 to Φ and the absolute value of the magnetic flux Φ / 2. Moreover, the direction of the change of the magnetic flux of the coil A and the coil B is opposite.

  Therefore, as shown in FIG. 8, the induced current IC1 is greatly generated in the minus direction from the timing T1 immediately after the end of the predetermined position pulse AP. In addition, the induced current IC2 is small in the positive direction. In addition, Vth shown with a broken line represents the threshold value of the determination circuit 4 mentioned later.

  On the other hand, the detection pulse generation circuit 14 (see FIG. 1) outputs the induced current detection pulse CP as shown in FIG. 8 immediately after the timing T1 by the control signal CN3 from the control circuit 3. The induced current detection pulse CP is a sampling pulse having a narrow pulse width output every 0.5 mS, for example. This induced current detection pulse CP is supplied to the respective gates G of the transistors TP1 to TP4 (see FIG. 2) of the induced current detection circuit 16, and the detection resistors R1 to R4 are arranged in the coil at the timing of the induced current detection pulse CP. It operates so as to be connected to the coil terminals O1 to O4 of A and B.

  Thereby, for example, the detection resistor R2 is connected to the coil terminal O2 of the coil A shown in FIG. 8 at the timing of the induced current detection pulse CP. Similarly, the detection resistor R3 is connected to the coil terminal O3 of the coil B shown in FIG. 8 at the timing of the induced current detection pulse CP.

  By this operation, when the induced current IC1 is generated from the coil A, a current flows to the detection resistor R2 at the timing of the induced current detection pulse CP, and the coil terminal O2 has a pulsed voltage waveform corresponding to the magnitude of the induced current IC1. Occurs. Similarly, when the induced current IC2 is generated from the coil B, a current flows to the detection resistor R3 at the timing of the induced current detection pulse CP, and the coil terminal O3 has a pulsed voltage waveform corresponding to the magnitude of the induced current IC2. Arise.

This pulsed voltage waveform is referred to as an induced pulse signal CS, and voltage waveforms generated by the detection resistors R1 to R4 are referred to as induced pulse signals CS1 to CS4. That is, the induced pulse signals CS1 to CS4 are signals from the coil terminals O1 to O4 to which the detection resistors R1 to R4 are connected (see FIG. 2).

  The determination circuit 4 (see FIG. 1) receives the induced pulse signals CS1 to CS4, and if the pulsed induced pulse signals CS1 to CS4 exceed the threshold value Vth as compared with a predetermined threshold value Vth included therein, Detection signals DS1 to DS4 are output to the control circuit 3. That is, the detection signals DS1 to DS4 are signals corresponding to the four induced pulse signals CS1 to CS4.

  In the example shown in FIG. 8, as described above, since the induced current IC1 generated in the coil A is large, the induced current IC1 is determined by the threshold value Vth of the determination circuit 4 at the second and third timings of the induced current detection pulse CP. Indicates that

  As a result, the pulse-like waveform from the coil terminal O2 generated according to the magnitude of the induced current IC1, that is, the induced pulse signal CS2 is determined at the second and third timings of the induced current detection pulse CP. The signal exceeds the threshold value Vth.

  Here, the head of the induced pulse signal CS2 that exceeds the threshold value Vth of the determination circuit 4 is marked with a circle, and the head of the other induced pulse signal CS2 that does not exceed the threshold value Vth is marked with an x, for easy understanding. . As described above, when the induced pulse signal CS2 exceeding the threshold value Vth is input to the determination circuit 4, the pulsed detection signal DS2 is synchronized with the timing of the induced current detection pulse CP as shown in FIG. Output.

  Further, as shown in FIG. 8, since the induced current IC2 generated in the coil B is small and the current direction is also opposite, the induced current IC2 does not exceed the threshold value Vth of the determination circuit 4. As a result, the pulse-like waveform of the coil terminal O3 generated according to the magnitude of the induced current IC2, that is, the induced pulse signal CS3 does not exceed the threshold value Vth, and the head of the induced pulse signal CS3 is all marked with a cross. Become. Therefore, the detection signal DS3 is not output from the determination circuit 4.

  The control circuit 3 receives the detection signal DS from the determination circuit 4, determines the state of the external magnetic field N from the detection signal DS, selects the drive pulse SP, and drives and controls the motor 20. The details of the driving operation of the motor 20 will be described later.

  As described above, the detection of the external magnetic field N is performed by detecting the induced currents IC1 and IC2 generated in the two coils A and B after supplying the predetermined position pulse AP to the motor 20. The detection operations shown in FIGS. 7 and 8 are based on the condition that the N pole of the rotor 21 is at a stationary position of 0 degree and the external magnetic field N is from the left. The three patterns shown in FIG. 6D also differ in the coil in which the induced current IC is generated and the current direction of the induced current IC, but the basic detection operation is the same, and detailed description thereof is omitted.

[Description of detection operation when no external magnetic field is present: FIG. 9]
Next, an external magnetic field detection operation using the motor 20 when no external magnetic field is present will be described with reference to FIG. As a premise for explanation, it is assumed that the N pole of the rotor 21 is at a stationary position of 0 degrees.

  FIG. 9A shows the position of the rotor 21 of the motor 20 when the external magnetic field N is not present. Here, if the external magnetic field N is not present, the rotor 21 is not affected by the magnetic field, so the N pole of the rotor 21 is at a stationary position of 0 degree.

Next, FIG. 9B shows the rotation state of the rotor 21 and the magnetic flux generated in each magnetic pole when the predetermined position pulse AP is supplied to the coils A and B in order to detect the presence or absence of the external magnetic field N. Yes. Here, the magnetic flux generated in each magnetic pole is the same as that shown in FIG.

  By the predetermined position pulse AP, the first magnetic pole part 22a and the second magnetic pole part 22b are excited to the S pole, and the third magnetic pole part 22c is excited to the N pole. As a result, the north pole of the rotor 21 is attracted to the south poles of both the first magnetic pole portion 22a and the second magnetic pole portion 22b, and the south pole of the rotor 21 is attracted to the north pole of the third magnetic pole portion 22c. As described above, the N pole of the rotor 21 does not move in a state where the stationary position is 0 degrees.

  Next, FIG. 9C shows the rotation state of the rotor 21 after the supply of the predetermined position pulse AP is completed. Here, the magnetic field that affects the motor 20 is only the external magnetic field N, but since the external magnetic field N does not exist, the rotor 21 does not rotate and the N pole of the rotor 21 remains at a stationary position of 0 degrees.

  Thus, when the external magnetic field N does not exist or is not strong enough to rotate the rotor 21, the N pole of the rotor 21 remains at a stationary position of 0 degrees or 180 degrees (see FIG. 5B). Even if the predetermined position pulse AP is supplied to the rotor 20, the rotor 21 does not rotate. Accordingly, although not shown, the induced currents IC1 and IC2 from the coils A and B are not generated, the induced pulse signal CS does not exceed the threshold value Vth of the determination circuit 4, and the detection signal DS is not output.

  When the detection signal DS from the determination circuit 4 is not input, the control circuit 3 determines that the external magnetic field N does not exist, and controls the drive pulse generation circuit 11 to select the normal drive pulse SP and turn on the motor 20. To drive.

[Description of conditions for external magnetic field detection operation: FIG. 10]
Next, the summary of the detection operation of the external magnetic field N applied to the motor 20 will be described with reference to FIG. The detection of the external magnetic field N has four patterns as detection conditions as shown in FIG. 6 from the excitation direction of the external magnetic field N and the polarity of the rotor 21. However, since there is a case where the external magnetic field N does not exist, FIG. 10 is a table in which all detection conditions including the condition where the external magnetic field N does not exist are collectively described.

  As shown in FIG. 10, the external magnetic field N is applied to the motor 20 from the left direction (FIG. 6A, FIG. 6B) and from the right direction (FIG. 6C). There are three types in FIG. 6 (d)) and when the external magnetic field N does not exist (is weak).

  In addition, the polarity (magnetic field direction) of the rotor 21 is determined when the N pole is at a stationary position of 0 degree (FIG. 6A, FIG. 6C) and when the N pole is at a stationary position of 180 degrees (FIG. 6B). There are two types as shown in FIG.

  Here, when the external magnetic field N is detected by the coil A and the N pole of the rotor 21 is at a stationary position of 0 degrees, the external magnetic field N is applied from the left direction. That is, this is the case of the detection conditions shown in FIGS. Similarly, when the external magnetic field N is detected by the coil A and the north pole of the rotor 21 is at a stationary position of 180 degrees, the external magnetic field N is applied from the right direction.

  Further, when the external magnetic field N is detected by the coil B and the N pole of the rotor 21 is at a stationary position of 0 degrees, the external magnetic field N is applied from the right direction. Similarly, when the external magnetic field N is detected by the coil B and the north pole of the rotor 21 is at a stationary position of 180 degrees, the external magnetic field N is applied from the left direction. In addition, when both the coils A and B cannot be detected, the external magnetic field N does not exist regardless of the polarity of the rotor 21.

  As described above, the motor 20 of the present embodiment has two coils, and the two coils are paired to detect the induced current, so that the rotational state of the rotor 21 due to the influence of the external magnetic field N can be accurately detected. Can be detected.

  Since the control circuit 3 controls the drive of the motor 20, the control circuit 3 always knows whether the polarity of the rotor 21, that is, the N pole, is at a stationary position of 0 degrees or 180 degrees. Therefore, as shown in FIG. 10, the control circuit 3 depends on whether the induced current IC is generated in the coils A and B or the coils A and B cannot be detected by the external magnetic field detection operation. The presence or absence of the external magnetic field N and the excitation direction can be determined.

[Explanation of Flowchart of External Magnetic Field Detection Operation and Step Motor Driving Operation: FIG. 11]
Next, an outline of a detection operation flow of the external magnetic field N by the motor 20 of the first embodiment and a drive operation flow of the motor 20 performed based on the detection result of the external magnetic field N will be described with reference to the flowchart of FIG. Refer to FIG. 1 for the structure of the step motor drive mechanism 1. As a premise for explanation, the step motor drive mechanism 1 of the present embodiment is incorporated in an analog electronic timepiece having a pointer, and the pointer (not shown) displays the time by the motor 20.

  As shown in FIG. 11, in step S1, the control circuit 3 of the step motor driving mechanism 1 refers to an internal time counter (not shown) to determine whether or not it is the timing of hand movement. For example, it is determined whether or not the second advance counter for advancing the second is “00”. Here, if it is the hand movement timing (ie, the second feed counter is “00” and the determination is Y), the process proceeds to the next step S2. If it is not the hand movement timing (determination N), step S1 is repeated.

Next, in the case of determination Y in step S1, in step S2, the control circuit 3 controls the predetermined position pulse generation circuit 12 by the control signal CN2 to output the predetermined position pulse AP, and passes through the pulse selection circuit 13 and the driver circuit 15 A predetermined position pulse AP is supplied to the motor 20. As described above, the predetermined position pulse AP supplies both the coils A and B with a pulse in a current direction parallel to the magnetic field direction of the rotor 21 when the predetermined position pulse AP is not output.
Specifically, it is the state of FIG. 9B or the application state of the reverse polarity of FIG.

  Next, in step S3, immediately after the predetermined position pulse AP ends, the control circuit 3 controls the detection pulse generation circuit 14 to output the induced current detection pulse CP. The driver circuit 15 and the induced current detection circuit 16 receive the induced current detection pulse CP, detect the induced currents IC1 and IC2 from the coils A and B at the timing of the induced current detection pulse CP, and generate induced pulse signals CS1 to CS4. Output.

  Next, in step S4, the determination circuit 4 receives the induced pulse signals CS1 to CS4, compares with the predetermined threshold value Vth, and outputs detection signals DS1 to DS4. The control circuit 3 receives the detection signals DS1 to DS4 and determines whether or not the induced currents IC1 and IC2 are generated from the coils A and B, that is, the presence or absence of the detection signals DS1 to DS4. If an induced current is generated from the coils A and B (determination Y), the process proceeds to the next step S5. If no induced current is generated from coils A and B (determination N), the process proceeds to step S6.

  Next, in the case of determination Y (with induced current) in step S4, the control circuit 3 determines the excitation direction of the external magnetic field N in step S5. The determination of the excitation direction of the external magnetic field N is executed based on FIG. That is, the excitation direction of the detected external magnetic field N based on the information on whether the induced current IC is detected by the coils A and B and the information on the polarity (magnetic field direction) of the rotor 21 known by the control circuit 3. Is judged.

  Next, in step S <b> 7, the control circuit 3 determines whether the excitation direction of the external magnetic field N determined in step S <b> 5 is a direction that repels the rotation direction of the rotor 21. If the direction is repulsive (determination Y), the process proceeds to the next step S8. If the direction is not repulsive (inquiry direction: determination N), the process proceeds to step S9. (The drive pulse for the excitation direction of the external magnetic field N will be described later with reference to FIGS.

Next, in the case of determination Y (repulsion direction) in step S7, in step S8, the control circuit 3 controls the drive pulse generation circuit 11 to select a large drive pulse SP, and proceeds to the next step S10.
Further, in the case of determination N (in the attracting direction) in step S7, the control circuit 3 controls the drive pulse generation circuit 11 to select a small drive pulse SP in step S9, and proceeds to step S10.

  In the case of determination N (no induced current) in step S4 described above, in step S6, the control circuit 3 controls the drive pulse generation circuit 11 to select a normal drive pulse SP, and proceeds to step S10.

  Next, in step S <b> 10, the control circuit 3 supplies the selected drive pulse SP to the motor 20 by the driver circuit 15, and drives the motor 20 with a driving force corresponding to the external magnetic field N. Then, it returns to step S1 and determines the next hand movement timing.

  Thus, in the present embodiment, the predetermined position pulse AP is output immediately before driving the motor 20 (step S2), and the external magnetic field N is detected. It is possible to realize step motor driving that quickly responds to the magnetic field N.

[Description of Drive Operation when Rotor Rotation Direction Repels External Magnetic Field: FIGS. 12 and 13]
Next, the driving operation of the motor 20 in the case where the driving rotation direction of the rotor 21 has a polarity repelling the excitation direction of the external magnetic field N will be described with reference to FIGS. This driving operation is the operation of steps S8 and S10 in the flowchart of FIG. 11 described above. Further, as an explanation condition, it is assumed that the excitation direction of the external magnetic field N is from the left, the N pole of the rotor 21 is at a stationary position of 0 degree, and the rotation direction of the rotor 21 is reverse (counterclockwise).

  FIG. 12A shows the drive waveforms of the motor drive pulses O1 to O4 when the rotation direction of the rotor 21 repels against the external magnetic field N. FIG. 12B, FIG. FIG. 13A shows the driving state of the motor 20.

  As shown in FIG. 12A, the motor drive pulses O1 to O4 are divided into three divided drive pulses SP1, SP2, and SP3. The leading divided driving pulse SP1 has a long pulse width in order to increase the driving force. The next divided driving pulse SP2 has a normal driving force and a medium pulse width. The last divided driving pulse SP3 has a short pulse width because the driving force is small and sufficient.

  FIG. 12B shows a state where the external magnetic field N is applied from the left direction of the motor 20 when the rotor 21 of the motor 20 is at a stationary position of 0 degree. This state is the same as in FIG. 6A described above. The N pole of the rotor 21 repels the external magnetic field N, and the S pole of the rotor 21 attracts the external magnetic field N. Thus, the N pole is stationary by rotating several tens of degrees in the right direction on the drawing from the stationary position of 0 degrees.

FIG. 12C shows a rotation state of the rotor 21 when the motor 20 is supplied with the first divided drive pulse SP1 of the large drive pulse. Here, since the split drive pulse SP1 having a long pulse width is supplied to the coil A (see FIG. 12A), the first magnetic pole part 22a on the coil A side is set to the S pole, the second magnetic pole part 22b and the third magnetic pole part 22b. The magnetic pole portion 22c is excited to the N pole.

  As a result, the rotor 21 was rotated several tens of degrees from the stationary position 0 degrees to the right by the external magnetic field N (see FIG. 12B), but the N pole of the rotor 21 is moved from the position to the first magnetic pole portion. It attracts | sucks with the south pole of 22a, and the south pole of the rotor 21 attracts with the north pole of the 2nd magnetic pole part 22b and the 3rd magnetic pole part 22c. As a result, the rotor 21 rotates backward (counterclockwise) from a position of several tens of degrees in the right direction as indicated by an arrow, and rotates about 90 degrees in the left direction.

  At this time, the N pole of the rotor 21 repels the external magnetic field N from the left direction, and the S pole repels the attraction of the external magnetic field N. Therefore, a large driving force is required to reversely rotate. For this reason, the first divided drive pulse SP1 has a long pulse width.

  Next, FIG. 13A shows the rotation state of the rotor 21 when the second divided drive pulse SP2 is supplied. Here, since the split drive pulse SP2 having an intermediate pulse width is supplied to the coil B (see FIG. 12A), the second magnetic pole portion 22b on the coil B side is set to the N pole, and the first magnetic pole portion 22a and The third magnetic pole portion 22c is excited to the S pole.

  As a result, the north pole of the rotor 21 attracts the south pole of the first magnetic pole portion 22a and the third magnetic pole portion 22c, and the south pole of the rotor 21 attracts the north pole of the second magnetic pole portion 22b. As shown, the N pole of the rotor 21 is reversely rotated to a position of about 120 degrees. Since the rotating operation at this time is less influenced by the external magnetic field N, a normal pulse width is sufficient for the divided drive pulse SP2.

  Next, FIG. 13B shows a rotation state of the rotor 21 when the third divided drive pulse SP3 is supplied. Here, since the split drive pulse SP3 having a short pulse width is supplied to both the coils A and B (see FIG. 12A), the first magnetic pole portion 22a on the coil A side and the second magnetic pole on the coil B side. Both portions 22b are excited to the N pole, and the third magnetic pole portion 22c is excited to the S pole.

  As a result, the N pole of the rotor 21 attracts the S pole of the third magnetic pole portion 22c, and the S pole of the rotor 21 attracts the N pole of the first magnetic pole portion 22a and the second magnetic pole portion 22b. As a result, the N pole of the rotor 21 rotates reversely to the vicinity of 180 degrees as indicated by the arrow. Since the rotation operation of the rotor 21 at this time can also use the external magnetic field N, the divided drive pulse SP3 does not need to be output with a short pulse width with a small driving force or output.

  Next, FIG.13 (c) has shown the rotation state of the rotor 21 after the motor drive pulses O1-O4 are complete | finished. Here, the N pole of the rotor 21 repels the external magnetic field N from the left direction, and the S pole of the rotor 21 attracts the external magnetic field N. As a result, the N pole of the rotor 21 becomes a position rotated by several tens of degrees in the reverse direction from the stationary position of 180 degrees as indicated by an arrow.

  In this way, when the rotor 21 with the N pole at the stationary position of 0 degrees is rotated in the reverse direction with the external magnetic field N applied from the left direction, the first rotation operation is the excitation direction of the external magnetic field N and the rotation of the rotor 21. Since the direction is repulsive, the leading divided drive pulse SP1 requires a large driving force.

[Description of driving operation when rotor rotation direction attracts external magnetic field: FIGS. 14 and 15]
Next, the drive operation of the motor 20 in the case where the drive rotation direction of the rotor 21 has a polarity attracting the excitation direction of the external magnetic field N will be described with reference to FIGS. This driving action is
The operations in steps S9 and S10 in the flowchart of FIG. 11 described above. Further, as an explanation condition, it is assumed that the excitation direction of the external magnetic field N is from the left, the N pole of the rotor 21 is at a stationary position of 0 degree, and the rotation direction of the rotor 21 is forward rotation (clockwise).

  FIG. 14A shows drive waveforms of the motor drive pulses O1 to O4 when the rotation direction of the rotor 21 attracts the external magnetic field N. FIGS. 14B, 14C, and 15A. FIG. 15C shows the driving state of the motor 20.

  As shown in FIG. 14A, the motor drive pulses O1 to O4 are divided into three divided drive pulses SP4, SP5, and SP6. The first divided driving pulse SP4 has a short pulse width because the driving force is small and sufficient. The next divided driving pulse SP5 has a normal driving force and a medium pulse width. The last divided driving pulse SP6 has a short pulse width because the driving force is small and sufficient.

  FIG. 14B shows a state where the external magnetic field N is applied from the left direction of the motor 20 when the rotor 21 of the motor 20 is at a stationary position of 0 degrees. This state is the same as that in FIG. 12B described above, and the rotor 21 is stationary with the N pole rotating several tens of degrees in the right direction on the drawing from 0 degrees as illustrated.

  FIG. 14C shows the rotation state of the rotor 21 when the divided drive pulse SP4 at the head of the small drive pulse is supplied to the motor 20. Here, since the divided drive pulse SP4 having a short pulse width is supplied to the coil B (see FIG. 14A), the second magnetic pole portion 22b on the coil B side is set to the S pole, and the first magnetic pole portion 22a and the first magnetic pole portion 22a The three magnetic pole portions 22c are excited to the N pole.

  As a result, the rotor 21 has already been rotated to the right by several tens of degrees from the stationary position of 0 degrees due to the influence of the external magnetic field N (see FIG. 14B). The S pole of the second magnetic pole portion 22b attracts the S pole of the rotor 21 and the N pole of the first magnetic pole portion 22a and the third magnetic pole portion 22c attracts each other. Thereby, as shown by the arrow, the rotor 21 advances only slightly in the forward rotation (clockwise). Therefore, the first divided drive pulse SP4 is sufficient to have a small driving force.

  Next, FIG. 15A shows the rotation state of the rotor 21 when the second divided drive pulse SP5 is supplied. Here, since the split drive pulse SP5 having an intermediate pulse width is supplied to the coil A (see FIG. 14A), the first magnetic pole portion 22a on the coil A side is set to the N pole, and the second magnetic pole portion 22b. The third magnetic pole portion 22c is excited to the S pole.

  As a result, the N pole of the rotor 21 attracts the S pole of the second magnetic pole portion 22b and the third magnetic pole portion 22c, and the S pole of the rotor 21 attracts the N pole of the first magnetic pole portion 22a. As a result, the rotor 21 further rotates forward as indicated by the arrow, and the position of the N pole is around 240 degrees (see FIG. 3). Since the rotating operation at this time is less influenced by the external magnetic field N, a normal pulse width is sufficient for the divided drive pulse SP2.

  Next, FIG. 15B shows the rotation state of the rotor 21 when the third divided drive pulse SP6 is supplied. Here, since the split drive pulse SP6 having a short pulse width is supplied to both the coils A and B (see FIG. 14A), the first magnetic pole portion 22a on the coil A side and the second magnetic pole on the coil B side. Both portions 22b are excited to the N pole, and the third magnetic pole portion 22c is excited to the S pole.

As a result, the N pole of the rotor 21 attracts the S pole of the third magnetic pole portion 22c, and the S pole of the rotor 21 attracts the N pole of the first magnetic pole portion 22a and the second magnetic pole portion 22b. As a result, the N pole of the rotor 21 rotates positively to the vicinity of a stationary position of 180 degrees as indicated by an arrow. At this time, the rotor 21 is returned in the reverse direction by the external magnetic field N when the drive pulse SP6 is completed. Therefore, the divided drive pulse SP6 is sufficient even if it does not output a short pulse width with a small driving force.

  Next, FIG. 15C shows the rotation state of the rotor 21 after the motor drive pulses O1 to O4 are completed. Here, the N pole of the rotor 21 repels the external magnetic field N from the left direction, and the S pole of the rotor 21 attracts the external magnetic field N. As a result, the rotor 21 is slightly returned in the reverse rotation direction, and as indicated by the arrow, the north pole of the rotor 21 is a position rotated from the stationary position 180 degrees by several tens of degrees in the reverse rotation direction.

  As described above, when the rotor 21 with the N pole at the stationary position of 0 degrees is rotated in the forward direction with the external magnetic field N applied from the left direction, the first rotation operation is performed by the excitation direction of the external magnetic field N and the rotor 21. Since the rotation direction attracts the polarity, a small driving force is sufficient for the leading divided driving pulse SP4.

  From the above, the difference between the motor driving pulses O1 to O4 having a large driving force shown in FIG. 12A and the motor driving pulses O1 to O4 having a small driving force shown in FIG. Only the pulse width of the drive pulse is different. That is, the driving force (pulse width) of the second and third divided driving pulses may be the same for both the motor driving pulse having a large driving force and the motor driving pulse having a small driving force.

  When there is no external magnetic field N, the drive pulses shown in FIGS. 4 and 5 are generally used. That is, the pulse widths of the three divided drive pulses are the same, and are configured with an intermediate pulse width having a normal driving force.

  Further, the motor driving pulses O1 to O4 having a large driving force to be supplied when the rotation direction of the rotor 21 repels the external magnetic field N is more powerful than the motor driving pulses O1 to O4 selected when there is no external magnetic field N. Means big. Further, the motor driving pulses O1 to O4 having a small driving force supplied when the rotation direction of the rotor 21 attracts the external magnetic field N has a driving force higher than the motor driving pulses O1 to O4 selected when there is no external magnetic field N. It means small or no output.

  As described above, the motor driving pulses O1 to O4 having a large driving force only have a long pulse width of the first divided driving pulse PS1, and the pulse width of the third divided driving pulse SP3 may be short. The total drive power is equivalent to normal motor drive pulses O1 to O4 in the absence of the external magnetic field N.

  Further, since the motor drive pulses O1 to O4 having a small driving force have both short pulse widths of the first divided drive pulse PS4 and the third divided drive pulse SP6, the total drive power includes the external magnetic field N. This can be less than the normal motor drive pulses O1 to O4. Further, the normal motor drive pulses O1 to O4 in the absence of the external magnetic field N do not need to have a sufficient drive force on the assumption that the external magnetic field N is applied. Thereby, the pulse width of the normal motor drive pulses O1 to O4 can be shortened to reduce the power.

  Therefore, according to the present embodiment, the drive power of the motor 20 can be reduced as a whole without being affected by the external magnetic field N, and low power drive with less energy loss is possible.

[Description of selection of drive pulse by repulsion / inquiry between external magnetic field and rotor rotation: FIG. 16]
Next, a summary of motor drive pulses O1 to O4 selected depending on whether the excitation direction of the external magnetic field N applied to the motor 20 and the rotation direction of the rotor 21 are repulsive or attracting will be described with reference to FIG.

  FIG. 16A shows a case where the external magnetic field N is applied from the left direction of the motor 20, the N pole of the rotor 21 is at a stationary position of 0 degree, and the rotation direction of the rotor 21 is reverse (counterclockwise). Is shown. That is, the conditions are the same as those in FIGS. At this time, since the N pole of the rotor 21 repels the external magnetic field N and the S pole of the rotor 21 attracts the external magnetic field N, the N pole of the rotor 21 moves away from the external magnetic field N, that is, at a stationary position of 0 degree. On the other hand, it rotates several tens of degrees to the right on the drawing. In this state, if the rotor 21 is rotated in the reverse direction as shown by the arrow, the excitation direction of the external magnetic field N becomes a polarity repelling the rotation direction of the rotor 21, and as shown in FIG. Large drive pulses are required.

  FIG. 16B shows a case where the external magnetic field N is applied from the left direction of the motor 20, the N pole of the rotor 21 is at a stationary position of 0 degree, and the rotation direction of the rotor 21 is forward rotation (clockwise). Show. That is, the conditions are the same as those in FIGS. At this time, since the N pole of the rotor 21 repels the external magnetic field N and the S pole of the rotor 21 attracts the external magnetic field N, the N pole of the rotor 21 moves away from the external magnetic field N, that is, at a stationary position of 0 degree. In contrast, it rotates several tens of degrees to the right. In this state, if the rotor 21 is rotated forward as indicated by an arrow, the excitation direction of the external magnetic field N has a polarity that attracts the rotation direction of the rotor 21, so that as shown in FIG. Small drive pulses are sufficient.

  FIG. 16C shows the case where the external magnetic field N is applied from the left direction of the motor 20, the N pole of the rotor 21 is at a stationary position of 180 degrees, and the rotation direction of the rotor 21 is reverse (counterclockwise). Is shown. At this time, the N pole of the rotor 21 rotates several tens of degrees in the direction away from the external magnetic field N, that is, in the right direction with respect to the stationary position of 180 degrees. In this state, if the rotor 21 is rotated in the reverse direction as indicated by the arrow, the excitation direction of the external magnetic field N has a polarity that attracts the rotation direction of the rotor 21, so that a small drive pulse is sufficient.

  FIG. 16D shows a case where the external magnetic field N is applied from the left direction of the motor 20, the N pole of the rotor 21 is at a stationary position of 180 degrees, and the rotation direction of the rotor 21 is forward rotation (clockwise). Show. At this time, the N pole of the rotor 21 rotates several tens of degrees in the direction away from the external magnetic field N, that is, in the right direction with respect to the stationary position of 180 degrees. In this state, when the rotor 21 is rotated forward as indicated by an arrow, the excitation direction of the external magnetic field N has a polarity that repels the rotation direction of the rotor 21, and thus a large drive pulse is required.

  FIG. 16E shows the case where the external magnetic field N is applied from the right direction of the motor 20, the N pole of the rotor 21 is at a stationary position of 0 degree, and the rotation direction of the rotor 21 is reverse (counterclockwise). Is shown. At this time, the N pole of the rotor 21 rotates several tens of degrees in the direction away from the external magnetic field N, that is, leftward with respect to the stationary position of 0 degrees. In this state, if the rotor 21 is rotated in the reverse direction as indicated by the arrow, the excitation direction of the external magnetic field N has a polarity that attracts the rotation direction of the rotor 21, so that a small drive pulse is sufficient.

  FIG. 16F shows a case where the external magnetic field N is applied from the right direction of the motor 20, the N pole of the rotor 21 is at a stationary position of 0 degree, and the rotation direction of the rotor 21 is forward rotation (clockwise). Show. At this time, the N pole of the rotor 21 rotates several tens of degrees in the left direction on the drawing with respect to the direction away from the external magnetic field N, that is, the stationary position of 0 degrees. In this state, when the rotor 21 is rotated forward as indicated by an arrow, the excitation direction of the external magnetic field N has a polarity that repels the rotation direction of the rotor 21, and thus a large drive pulse is required.

FIG. 16G shows the case where the external magnetic field N is applied from the right direction of the motor 20, the N pole of the rotor 21 is at a stationary position of 180 degrees, and the rotation direction of the rotor 21 is reverse (counterclockwise). Is shown. At this time, the N pole of the rotor 21 rotates several tens of degrees in the direction away from the external magnetic field N, that is, in the left direction with respect to the stationary position of 180 degrees. In this state, if the rotor 21 is rotated in the reverse direction as indicated by the arrow, the excitation direction of the external magnetic field N has a polarity that repels the rotation direction of the rotor 21, so that a large drive pulse is required.

  FIG. 16H shows a case where the external magnetic field N is applied from the right direction of the motor 20, the N pole of the rotor 21 is at a stationary position of 180 degrees, and the rotation direction of the rotor 21 is forward rotation (clockwise). Show. At this time, the N pole of the rotor 21 rotates several tens of degrees in the direction away from the external magnetic field N, that is, in the left direction with respect to the stationary position of 180 degrees. In this state, if the rotor 21 is rotated forward as indicated by an arrow, the excitation direction of the external magnetic field N has a polarity that attracts the rotation direction of the rotor 21, so a small drive pulse is sufficient.

  Further, when the external magnetic field N does not exist, as described above, a driving pulse having a normal driving force may be supplied regardless of the polarity of the rotor 21 and the rotation direction.

  As described above, the selection of the drive pulse SP for driving the motor 20 is determined depending on whether the excitation direction of the external magnetic field N is a repulsive or attracting polarity with respect to the rotation direction of the rotor 21. That is, if the excitation direction of the external magnetic field N is a polarity that repels the rotation direction of the rotor 21, a drive pulse with a large driving force is selected, and the excitation direction of the external magnetic field N attracts the rotation direction of the rotor 21. If so, it is preferable to select a driving pulse with a small driving force.

  As described above, according to the first embodiment, the presence / absence of the external magnetic field and the excitation direction can be detected by the two-coil step motor itself, so that a separate magnetic sensor is unnecessary, and the small step with a small number of parts is required. A motor drive mechanism can be provided. In addition, since the external magnetic field is detected by the stepping motor itself, the external magnetic field that affects the stepping motor can be reliably detected with high accuracy, unlike the detection by another component. As a result, motor driving according to the external magnetic field can be realized, and low power driving with little energy loss is possible. In addition, the influence of the external magnetic field is suppressed, and stable motor driving without driving errors can be realized. Further, by realizing motor driving in accordance with an external magnetic field, the magnetic resistance is improved, and the magnetic resistance performance of an electronic timepiece or the like incorporating the step motor driving mechanism of this embodiment can be improved.

[Second Embodiment]
[Description of Configuration of Step Motor Drive Mechanism of Second Embodiment: FIG. 17]
Next, the structure of the step motor drive mechanism 50 of 2nd Embodiment is demonstrated using FIG. As shown in FIG. 17, the step motor driving mechanism 50 includes a plurality of two-coil step motors 70 and 80 (hereinafter referred to as “motors 70 and 80”). Since the motors 70 and 80 have the same configuration as the motor 20 (see FIG. 3) of the first embodiment, the description thereof is omitted.

  The step motor driving mechanism 50 includes the oscillation circuit 2 and the control circuit 3, but these circuit configurations are also the same as those in the first embodiment, and thus the description thereof is omitted with the same reference numerals. The determination circuit 66 has the same function as the determination circuit 4 of the first embodiment, but has a feature that it has a plurality of internal predetermined threshold values to be compared with the induced pulse signal CS to be input.

  Further, the step motor driving mechanism 50 has a driving circuit 60 for the motors 70 and 80. The drive circuit 60 includes two driver circuits 61 and 62 that drive the motors 70 and 80, two induced current detection circuits 63 and 64 that detect the respective induced currents of the motors 70 and 80, and a detection pulse generation circuit 65. have.

The circuit configurations of the two driver circuits 61 and 62 are the same, and the circuit configurations of the two induced current detection circuits 63 and 64 are also the same. Since these circuits are the same as each circuit configuration of the drive circuit 10 of the first embodiment, detailed description thereof is omitted. The drive circuit 60 includes a drive pulse generation circuit 11, a predetermined position pulse generation circuit 12, and a pulse selection circuit 13. Since the drive circuit 60 is similar to each circuit configuration of the drive circuit 10 of the first embodiment, the same reference numerals are used. The description will be omitted.

[Description of Arrangement of Two Motors in Second Embodiment: FIG. 18]
Next, the arrangement of the two motors 70 and 80 of the step motor driving mechanism 50 will be described with reference to FIG. As a premise of the description, it is assumed that the step motor driving mechanism 50 is incorporated in an analog electronic timepiece that displays time by hands. For example, the motor 70 is a second motor that drives a second hand, and the motor 80 functions as a minute hour motor that drives a minute hand and an hour hand.

  FIG. 18 is a schematic layout diagram of the inside of the electronic timepiece 90 in which the step motor driving mechanism 50 is incorporated. As shown in FIG. 18, the electronic timepiece 90 is covered with an exterior 91, and a crown 92 that corrects the time and the like is disposed at the end of the exterior 91. Inside the exterior 91, two motors 70 and 80 of the step motor driving mechanism 50 are arranged. Further, a control IC 93, a crystal resonator 94, a battery 95, and the like are arranged.

  The control IC 93 is configured by a control circuit of the electronic timepiece 90, but the control IC 93 may include the oscillation circuit 2, the control circuit 3, the drive circuit 50, and the like (see FIG. 17) of the step motor drive mechanism 50, Or you may comprise with another IC chip.

  As shown in the drawing, the two motors 70 and 80 are arranged with an inclination of 90 degrees. Thereby, the motor 70 can detect the external magnetic field Nx from the X-axis direction on the drawing, and the motor 80 can detect the external magnetic field Ny from the Y-axis direction on the drawing. That is, the two motors 70 and 80 of the step motor driving mechanism 50 differ in the direction of the external magnetic field that can be detected by making the arrangement angles different.

  Such an arrangement of the two motors 70 and 80 can solve the problem that only the external magnetic field N in the uniaxial direction can be detected in the first embodiment. That is, in the motor 70, it is difficult to detect the external magnetic field Ny from the Y-axis direction, but it is possible by arranging the motor 80 with a 90 degree inclination. Similarly, in the motor 80, it is difficult to detect the external magnetic field Nx in the X-axis direction, but this is possible by arranging the motor 70.

[Description of External Magnetic Field Detection Operation According to Second Embodiment: FIG. 19]
Next, the detection operation of the external magnetic field N by the induced current detection circuits 63 and 64 and the determination circuit 66 of the second embodiment will be described with reference to the timing chart of FIG.

  As shown in FIG. 19, in order to detect the external magnetic field N, a predetermined position pulse AP is supplied to the coils A and B of the motors 70 and 80. As a result, as in the first embodiment, the magnetic poles of the motors 70 and 80 are excited, and the N pole of each rotor is temporarily returned to a predetermined position.

  When the supply of the predetermined position pulse AP ends at the timing T2, the induced current detection pulse CP is output immediately after that. Since the subsequent detection operation is the same as the detection operation of the first embodiment, a detailed description of the detection operation is omitted, but in this embodiment, there are two cases where the intensity of the external magnetic field N is weak and strong. explain.

As an example, if a weak external magnetic field Nx (see FIG. 18) is applied to the motor 70 from the X-axis direction, an induced current IC is generated from the coil A of the motor 70 immediately after the timing T2.
a (shown by a solid line) is output. As described above, the determination circuit 66 has a plurality of threshold values Vth1 and Vth2, and has a relationship of Vth1 <Vth2.

  Here, the induced current ICa exceeds the threshold value Vth1 at the second and third timings of the induced current detection pulse CP. However, the induced current ICa does not exceed the threshold value Vth2. Thereby, the pulsed voltage waveform generated according to the magnitude of the induced current ICa, that is, the induced pulse signal CS2a becomes a signal exceeding the threshold value Vth1 at the second and third timings of the induced current detection pulse CP, The head of the induced pulse signal CS2a is indicated by a circle.

  Here, a region of the external magnetic field N in which the induced current ICa exceeds the threshold value Vth1 but does not exceed the threshold value Vth2 is referred to as a region Z2. A region of the external magnetic field N exceeding the threshold value Vth2 is referred to as a region Z3, and a region of the external magnetic field N not exceeding the threshold value Vth1 is referred to as a region Z1.

  When the induced current ICa is in the region Z2, it is desirable to select a motor drive pulse for driving the motors 70 and 80 according to the external magnetic field N, and the operation flow as described in the first embodiment (FIG. 11). The motor driving pulse may be appropriately selected according to (see FIG.).

  If a strong external magnetic field Nx (see FIG. 18) is applied to the motor 70 from the X-axis direction, a large induced current ICb (shown by a broken line) is output from the coil A of the motor 70 immediately after the timing T2. This is because the rotor 21 rotates greatly because the external magnetic field Nx is strong. Thereby, the induced current ICb exceeds the threshold value Vth2 at the second timing of the induced current detection pulse CP. Therefore, the external magnetic field Nx in this case is the region Z3.

  Thereby, the pulsed voltage waveform generated according to the magnitude of the induced current ICb, that is, the induced pulse signal CS2b becomes a signal exceeding the threshold value Vth2 at the second timing of the induced current detection pulse CP. The induced pulse signal CS2b is shown with a black circle at the head.

  When the external magnetic field N is in the region Z3, the external magnetic field N is strong, so there is a possibility that the motors 70 and 80 cannot be driven only by selecting the motor drive pulse. That is, when the external magnetic field N is very strong, even if a driving pulse having a large driving force is supplied, the rotor may not be able to step-feed. Therefore, when the external magnetic field N is in the region Z3, driving of both the motor 70 and the motor 80 is stopped, and when the external magnetic field N becomes the region Z2 or the region Z1, the driving is performed collectively.

  Although not shown in the figure, when the induced current IC is in the region Z1, the external magnetic field N is weak, so that a normal pulse may be selected as the drive pulse.

  As described above, according to the second embodiment, the plurality of motors 70 and 80 are provided, and the external magnetic fields in both the X direction and the Y direction are detected by changing the arrangement angle of each motor by 90 degrees. it can. As a result, the blind spot for detecting the external magnetic field is eliminated, and the detection accuracy of the external magnetic field is improved.

  Further, in consideration of the influence of the external magnetic field N detected by one motor, it can be reflected in the driving of the other motor. That is, as described above, when a strong external magnetic field N is detected by one motor, control such as temporarily stopping driving of both motors can be performed.

Note that the determination circuit 66 may have only one threshold value Vth, similar to the determination circuit 4 of the first embodiment described above. In addition, the determination circuit 4 of the first embodiment is replaced with the determination circuit 6 of the second embodiment.
Similarly to 6, the control may be performed by dividing into regions having a plurality of threshold values Vth1 and Vth2. Further, the angle difference in the direction of the external magnetic field detected by the two motors 70 and 80 is not limited to 90 degrees and may be arranged at an arbitrary angle.
Furthermore, in the second embodiment, the direction of the applied magnetic field from the outside and the applied magnetic field strength can be detected, so that it may be used as a magnetic azimuth meter.

[Third Embodiment]
[Description of Configuration of Step Motor Drive Mechanism of Third Embodiment: FIG. 20]
Next, the configuration of the step motor driving mechanism 100 according to the third embodiment and the configuration of the one-coil step motor 110 included in the driving mechanism will be described with reference to FIG. As shown in FIG. 20, the step motor drive mechanism 100 includes an oscillation circuit 2, a control circuit 3, a determination circuit 4, a drive circuit 10, and a one-coil step motor 110 (hereinafter referred to as “motor 110”). Yes.

  Here, since the configurations of the oscillation circuit 2, the control circuit 3, the determination circuit 4, and the drive circuit 10 are the same as the configuration of the step motor drive mechanism 1 of the first embodiment (see FIG. 1), the same reference numerals are given. The description is omitted. Note that the driver circuit 15 and the induced current detection circuit 16 inside the drive circuit 10 detect one induced current from one coil by driving one coil (for example, the coil A) because the motor 110 is a one-coil type. The structure to do is sufficient.

  Next, the configuration of the motor 110 will be described with reference to FIG. In addition, although the structure of 1 coil step motor is well-known, since it is required in order to understand this embodiment, an outline is demonstrated.

  As shown in FIG. 20, the motor 110 includes a rotor 111, a stator 112, a coil 113, and the like. The rotor 111 is a disc-shaped rotating body magnetized in two poles, and is magnetized in N and S poles in the radial direction. The stator 112 and the coil 113 are each constituted by one. The stator 112 is made of a soft magnetic material, and magnetic pole portions 112a and 112b surrounding the rotor 111 are divided by slits. A coil 113 is wound around a base 112e to which the magnetic poles 112a and 112b are coupled. The coil 113 has coil terminals O1 and O2.

  In addition, concave notches 112h and 112i are formed at predetermined positions on the inner peripheral surfaces of the magnetic pole portions 112a and 112b of the stator 112 that face each other. Due to the notches 112h and 112i, a static stable point (position of the magnetic pole at rest: indicated by a slanted line B) of the rotor 111 is shifted from an electromagnetic stable point (indicated by a straight line A) of the stator 112. The angle difference due to this deviation is referred to as an initial phase angle θi, and this initial phase angle θi is used to braze the rotor 111 so as to easily rotate in a predetermined direction, and is generally an angle of several tens of degrees. The method for driving the one-coil step motor is well known and will not be described.

  As described above, the step motor driving mechanism 100 according to the third embodiment is configured by a single-coil step motor having a small and simple structure. Therefore, the step motor driving mechanism 100 is smaller and lighter than the step motor driving mechanism 1 according to the first embodiment. It has characteristics.

[Description of Detection Operation when External Magnetic Field of Third Embodiment is Leftward: FIG. 21]
Next, the detection operation of the external magnetic field N when the external magnetic field N is applied from the left direction of the motor 110 will be described with reference to FIG. In the motor 110 in FIG. 21 and subsequent figures, only the rotor 111 and the stator 112 are illustrated and described. FIG. 21A is the same as FIG. 20 described above, and shows the state of the motor 110 when no external magnetic field is present. In other words, the polarity of the rotor 111 is on the static stable point B. As an example, the N pole of the rotor 111 is located at the lower left of the rotation center and the S pole is located at the upper right of the rotation center.

  Next, FIG. 21B shows a state where an external magnetic field N is applied to the motor 110 from the left direction in the drawing. Here, since the N pole of the rotor 111 repels the external magnetic field N and the S pole of the rotor 111 attracts the external magnetic field N, the rotor 111 rotates as indicated by an arrow, and the magnetic field direction of the rotor 111 is the electromagnetic stable point A. The direction is substantially orthogonal to Note that the rotation angle of the rotor 111 at this time depends on the strength of the external magnetic field N.

  Next, FIG. 21C shows the rotation state of the rotor 111 when a predetermined position pulse AP is supplied to the coil 113 (see FIG. 20) in order to detect the external magnetic field N. Here, when the predetermined position pulse AP is supplied to the coil 113, the left magnetic pole part 112a of the stator 112 is excited to the S pole, and the right magnetic pole part 112b is excited to the N pole.

  As a result, the N pole of the rotor 111 attracts the S pole of the magnetic pole part 112a, and the S pole of the rotor 111 attracts the N pole of the magnetic pole part 112b. As a result, the rotor 111 rotates in the direction of the arrow (clockwise) as shown, and the magnetic field direction of the rotor 111 is substantially parallel to the electromagnetic stable point A.

  Thus, in the motor 110 of the third embodiment, the external magnetic field N does not exist and the magnetic field direction of the rotor 111 when the predetermined position pulse AP is not supplied (on the static stable point B: FIG. 21A). And the magnetic field direction of the rotor 111 when the predetermined position pulse AP is supplied (see FIG. 21C) is different.

  Next, FIG. 21D shows the rotation state of the rotor 111 after the supply of the predetermined position pulse AP is completed. Here, since the magnetic field affecting the motor 110 is only the external magnetic field N again, the rotor 111 rotates in the direction of the arrow (counterclockwise) under the influence of the external magnetic field N, and the magnetic field direction of the rotor 111 Is again in a direction substantially perpendicular to the electromagnetic stability point A. That is, the rotor 111 returns to the same magnetic field direction as that in FIG.

  Therefore, after the supply of the predetermined position pulse AP is completed, the magnetic field direction of the rotor 111 is almost orthogonal to the electromagnetic stable point A again from a state substantially parallel to the electromagnetic stable point A (see FIG. 21C). It rotates to a position (refer FIG.21 (d)). That is, the rotor 111 rotates approximately 90 degrees.

  As described above, in the motor 110 of the third embodiment, when the external magnetic field N is applied from the left direction, the magnetic field direction of the rotor 111 is substantially orthogonal to the electromagnetic stable point A. The magnetic field direction 111 is substantially parallel to the electromagnetic stable point A. Then, by the end of the predetermined position pulse AP, it is almost orthogonal to the electromagnetic stable point A again due to the influence of the external magnetic field N. After the predetermined position pulse AP ends, the presence or absence of the external magnetic field N and the excitation direction can be detected by detecting the movement of the rotor 111 returning to rotation due to the external magnetic field N again.

[Explanation of the detection operation timing chart when the external magnetic field is from the left direction: FIG. 22 (a)]
Next, as shown in FIG. 21, the detection operation of each circuit when the external magnetic field N is applied from the left direction of the motor 110 will be described with reference to the timing chart of FIG. As shown in FIG. 22A, a predetermined position pulse AP is supplied to the coil 113 of the motor 110 in order to detect the external magnetic field N. As a result, as shown in FIG. 21C, the stator 112 of the motor 110 is excited, and the magnetic field direction of the rotor 111 is substantially parallel to the electromagnetic stable point A.

When the supply of the predetermined position pulse AP is finished at the timing T3, the rotor 111 rotates under the influence of the external magnetic field N, and the magnetic field direction of the rotor 111 becomes a direction substantially orthogonal to the electromagnetic stable point A again (FIG. 21 (d)).

  When the rotor 111 rotates again under the influence of the external magnetic field N, a magnetic flux is generated in the stator 112, and an induced current IC shown in FIG. As described above, the induced current IC has a large current value and a long generation time because the rotor 111 is largely rotated about 90 degrees at the end of the predetermined position pulse AP.

  The detection pulse generation circuit 14 (see FIG. 1) outputs the induced current detection pulse CP immediately after the timing T3. Since the subsequent detection operation is the same as the detection operation of the first embodiment, a detailed description of the detection operation is omitted. Here, the induced current is detected at the first to fourth timings of the induced current detection pulse CP. An example in which the IC exceeds the threshold value Vth of the determination circuit 4 is shown.

  As a result, the pulsed voltage waveform of the coil terminal O1 generated according to the magnitude of the induced current IC, that is, the induced pulse signal CS1 is determined at the first to fourth timings of the induced current detection pulse CP. The signal exceeds the threshold value Vth.

  Here, the head of the induced pulse signal CS1 that exceeds the threshold value Vth of the determination circuit 4 is marked with a circle, and the head of the induced pulse signal CS1 that does not exceed the threshold value Vth is marked with an x, which is easy to understand. Although not shown, the determination circuit 4 outputs the detection signal DS in synchronization with the induced pulse signal CS1 exceeding the threshold value Vth. The control circuit 3 receives the detection signal DS from the determination circuit 4 and counts the number of signals. In the example shown in FIG. 22A, the number of detection signals DS is counted as four.

  Note that counting the detection signal DS is equivalent to counting the output time during which the induced current IC generated in the coil 113 exceeds the threshold value Vth. Accordingly, in the example shown in FIG. 22A, the control circuit 3 counts and stores the output time of the detection signal DS as “4”.

  The reason why the output time of the detection signal DS is as long as “4” is that, as described above, the rotor 111 is largely rotated about 90 degrees by the end of the predetermined position pulse AP. In the present embodiment, the state of the external magnetic field N is determined according to the length of the output time during which the induced current IC exceeds the threshold value Vth (that is, the number of detection signals DS), and the drive pulse for driving the motor 110 is selected. Thus, optimum driving according to the external magnetic field N is realized.

  Note that the control circuit 3 does not count the number of detection signals DS, but from the first signal to the last signal of the detection signal DS (in the example of FIG. 22A, the first to fourth induced current detection pulses CP). (E.g.) may be measured and the value may be used as the output time of the detection signal DS.

[Description of Driving Operation of Motor According to Detected External Magnetic Field N from Left Direction: FIG. 22B]
Next, the driving operation of the motor 110 according to the detection result of the external magnetic field N shown in FIGS. 21 and 22A will be described with reference to FIG. The condition for explanation is the case where the rotor 111 is driven reversely (counterclockwise) when the external magnetic field N is applied from the left direction of the motor 110. In this case, the motor drive has such a polarity that the excitation direction of the external magnetic field N attracts the rotation direction of the rotor 111.

  Here, as described above, since the output time of the detection signal DS is counted as “4”, the control circuit 3 applies the external magnetic field N from the left direction, and the excitation direction of the external magnetic field N is the rotor 111. The drive pulse (pulse width: small) smaller than the drive pulse when the external magnetic field N is determined to be absent is determined to be supplied to the motor 110.

  By supplying this small driving pulse, the stator 112 of the motor 110 is magnetized as shown in FIG. As a result, the magnetic field direction of the rotor 111 was at the position shown in FIG. 21D, but the N pole of the rotor 111 attracts the S pole of the magnetic pole part 112b, and the S pole of the rotor 111 is N of the magnetic pole part 112a. Attract with the poles. As a result, the rotor 111 rotates reversely as indicated by an arrow, and the north pole of the rotor 111 rotates to the upper right of the static stable point B on the drawing.

  Thus, the rotor 111 rotates from the position shown in FIG. 21D (perpendicular to the electromagnetic stable point A) to the position shown in FIG. 22B, but the external magnetic field N applied from the left direction of the motor 110 is reduced. It can be understood that the excitation direction is a polarity attracting with respect to the rotation direction (reverse rotation direction) of the rotor 111. Further, since the rotation angle of the rotor 111 at this time is smaller than one step (180 degrees), it can be driven sufficiently even if the driving force of the driving pulse is small.

[Description of Detection Operation when External Magnetic Field of Third Embodiment is Rightward: FIG. 23]
Next, the detection operation of the external magnetic field N when the external magnetic field N is applied from the right direction of the motor 110 will be described with reference to FIG. FIG. 23A is the same as FIG. 20 described above, and in the case where no external magnetic field exists, the polarity of the rotor 111 is on the static stable point B, and the N pole of the rotor 111 is diagonally lower left in the drawing. The S pole is located diagonally to the upper right.

  Next, FIG. 23B shows a state where the external magnetic field N is applied to the motor 110 from the right direction in the drawing. Here, since the N pole of the rotor 111 repels the external magnetic field N and the S pole of the rotor 111 attracts the external magnetic field N, the rotor 111 rotates as indicated by an arrow, and the magnetic field direction of the rotor 111 is the electromagnetic stable point A. Almost parallel to

  Next, FIG. 23C shows the rotation state of the rotor 111 when a predetermined position pulse AP is supplied to the coil 113 in order to detect the external magnetic field N. Here, when the predetermined position pulse AP is supplied to the coil 113, the left magnetic pole part 112a of the stator 112 is excited to the S pole, and the right magnetic pole part 112b is excited to the N pole.

  As a result, the N pole of the rotor 111 attracts the S pole of the magnetic pole part 112a, and the S pole of the rotor 111 attracts the N pole of the magnetic pole part 112b. As a result, the rotor 111 does not move from the position of FIG. 23B, and the magnetic field direction of the rotor 111 is held substantially parallel to the electromagnetic stable point A.

  Thus, in the one-coil step motor, the magnetic field direction of the rotor 111 when the predetermined position pulse AP is supplied is the rotor 111 when the external magnetic field N is not present and the predetermined position pulse AP is not supplied. Is different from the magnetic field direction (on the static stable point B: see FIG. 23A).

  Next, FIG. 23D shows the rotation state of the rotor 111 after the supply of the predetermined position pulse AP is completed. Here, the magnetic field affecting the motor 110 is only the external magnetic field N again, but the rotor 111 is not rotated by the predetermined position pulse AP, and therefore does not move even when the predetermined position pulse AP ends. Therefore, the magnetic field direction of the rotor 111 is maintained substantially parallel to the electromagnetic stable point A.

  As described above, in the motor 110 of the third embodiment, when the external magnetic field N is applied from the right direction, the magnetic field direction of the rotor 111 is substantially parallel to the electromagnetic stable point A, but in this state, the predetermined position pulse AP is supplied. Even if this is done, the rotor 111 does not rotate. Therefore, even when the predetermined position pulse AP is completed, an induced current from the coil 113 is hardly generated.

[Explanation of the detection operation timing chart when the external magnetic field N is from the right direction: FIG. 24 (a)]
Next, the detection operation of each circuit when the external magnetic field N is applied from the right direction of the motor 110 as shown in FIG. 23 will be described with reference to the timing chart of FIG. As shown in FIG. 24A, a predetermined position pulse AP is supplied to the coil 113 of the motor 110 in order to detect the external magnetic field N. As a result, as shown in FIG. 23C described above, the stator 112 of the motor 110 is excited, but the rotor 111 does not rotate, and the magnetic field direction of the rotor 111 is substantially parallel to the electromagnetic stable point A. Is retained.

  When the supply of the predetermined position pulse AP is completed at timing T4, the rotor 111 is only affected by the external magnetic field N, but the rotor 111 does not rotate and the magnetic field direction does not change (see FIG. 23D). Since the rotor 111 does not rotate, the magnetic flux does not change with respect to the coil 113, and therefore the induced current IC by the coil 113 hardly occurs.

  The detection pulse generation circuit 14 (see FIG. 1) outputs the induced current detection pulse CP immediately after the timing T4. Since the subsequent detection operation is the same as the detection operation of the first embodiment, a detailed description of the detection operation is omitted. However, since the induced current IC is hardly generated, the induced pulse signal CS1 is the threshold of the determination circuit 4. Vth is not exceeded. Therefore, the detection circuit DS is not output from the determination circuit 4, and the control circuit 3 stores the number of detection signals DS as 0, that is, the output time of the detection signal DS as “0”.

  Here, the reason why the output time of the detection signal DS is “0” which is the minimum is that, as described above, under this condition, the rotor 111 hardly rotates due to the end of the predetermined position pulse AP.

[Description of Motor Drive Operation According to Detected External Magnetic Field N from Right Direction: FIG. 24B]
Next, the drive operation of the motor 110 according to the detection result of the external magnetic field N shown in FIGS. 23 and 24A will be described with reference to FIG. The condition for explanation is the case where the rotor 111 is driven in reverse rotation when the external magnetic field N is applied from the right direction of the motor 110. In this case, the motor drive has a polarity in which the excitation direction of the external magnetic field N repels the rotation direction of the rotor 111.

  Here, as described above, since the output time of the detection signal DS is counted as “0”, the control circuit 3 applies the external magnetic field N from the right direction, and the excitation direction of the external magnetic field N is the rotor 111. The motor 110 is supplied with a driving pulse (pulse width: large) larger than the driving pulse when the external magnetic field N is determined to be absent.

  By supplying the large driving pulse, the stator 112 of the motor 110 is magnetized as shown in FIG. As a result, the magnetic field direction of the rotor 111 was at the position shown in FIG. 23D, but the N pole of the rotor 111 attracts the S pole of the magnetic pole portion 112b, and the S pole of the rotor 111 is N of the magnetic pole portion 112a. Attract with the poles. As a result, the rotor 111 rotates reversely as indicated by an arrow, and the north pole of the rotor 111 rotates to the upper right of the static stable point B on the drawing.

  Thus, the rotor 111 rotates from the position of FIG. 23D (parallel to the electromagnetic stable point A) to the position of FIG. 24B, but the external magnetic field N applied from the right direction of the motor 110. It can be understood that the excitation direction is a polarity that repels the rotation direction (reverse direction) of the rotor 111. Further, since the rotation angle of the rotor 111 at this time is an angle larger than one step (180 degrees), a driving pulse having a large driving force is required.

[Description of Detection Operation in Case of No External Magnetic Field According to Third Embodiment: FIG. 25]
Next, the detection operation of the external magnetic field N when there is no external magnetic field N will be described with reference to FIG. FIG. 25A shows the state of the rotor 111 in the absence of the external magnetic field N. The magnetic field direction of the rotor 111 is on the static stable point B, and the N pole of the rotor 111 is diagonally lower left in the drawing. , S pole is located diagonally to the upper right.

  Next, FIG. 25B shows the rotation state of the rotor 111 when a predetermined position pulse AP is supplied to the coil 113 in order to detect the external magnetic field N. Here, when the predetermined position pulse AP is supplied to the coil 113, the left magnetic pole part 112a of the stator 112 is excited to the S pole, and the right magnetic pole part 112b is excited to the N pole.

  As a result, the N pole of the rotor 111 attracts the S pole of the magnetic pole part 112a, and the S pole of the rotor 111 attracts the N pole of the magnetic pole part 112b. As a result, the rotor 111 rotates in the direction of the arrow (clockwise) as shown, and the magnetic field direction of the rotor 111 is substantially parallel to the electromagnetic stable point A.

  Next, FIG. 25C shows the rotation state of the rotor 111 after the supply of the predetermined position pulse AP is completed. Here, when the supply of the predetermined position pulse AP is completed, the magnetic field affecting the motor 110 disappears, so the rotor 111 rotates in the direction of the arrow (counterclockwise) and returns to the original static stable point B, and N The pole is located diagonally in the lower left corner and the S pole is located obliquely in the upper right corner. That is, when the supply of the predetermined position pulse AP is completed, the rotor 111 rotates by an angle (several tens of degrees) corresponding to the initial phase angle θi (see FIG. 20).

  As described above, in the motor 110 of the third embodiment, when the external magnetic field N is not present, the magnetic field direction of the rotor 111 is on the static stable point B, but the magnetic field direction of the rotor 111 is applied by applying the predetermined position pulse AP. Is substantially parallel to the electromagnetic stability point A. Then, by the end of the predetermined position pulse AP, the static stable point B is again reached under the influence of the external magnetic field N. After the predetermined position pulse AP ends, the presence or absence of the external magnetic field N and the excitation direction can be detected by detecting the movement of the rotor 111 returning to rotation due to the external magnetic field N again.

[Explanation of the detection operation timing chart when there is no external magnetic field N: FIG. 26 (a)]
Next, as shown in FIG. 25, the detection operation of each circuit when the external magnetic field N does not exist will be described with reference to the timing chart of FIG. As shown in FIG. 26A, a predetermined position pulse AP is supplied to the coil 113 of the motor 110 in order to detect the external magnetic field N. As a result, as shown in FIG. 25B, the stator 112 of the motor 110 is excited, the rotor 111 rotates, and the magnetic field direction becomes substantially parallel to the electromagnetic stable point A.

  When the supply of the predetermined position pulse AP is completed at the timing T5, the rotor 111 rotates and the magnetic field direction of the rotor 111 is again on the static stable point B (see FIG. 25C). When the rotor 111 rotates again, a change in magnetic flux occurs in the coil 113, and an induced current IC shown in FIG. As described above, the induced current IC is a moderate current value because the rotation angle of the rotor 111 is relatively small, such as several tens of degrees, and the generation time is also relatively short.

  The detection pulse generation circuit 14 (see FIG. 1) outputs the induced current detection pulse CP immediately after the timing T5. Since the subsequent detection operation is the same as the detection operation of the first embodiment, detailed description of the detection operation is omitted, but here, the induced current IC is determined at the second timing of the induced current detection pulse CP. An example in which the threshold value Vth of the circuit 4 is exceeded is shown.

  As a result, the pulsed voltage waveform of the coil terminal O1 generated according to the magnitude of the induced current IC, that is, the induced pulse signal CS1 is the threshold Vth of the determination circuit 4 at the second timing of the induced current detection pulse CP. The signal exceeds.

  Here, the head of the induced pulse signal CS1 that exceeds the threshold value Vth of the determination circuit 4 is marked with a circle, and the head of the induced pulse signal CS1 that does not exceed the threshold value Vth is marked with an x, which is easy to understand. Although not shown, the determination circuit 4 outputs the detection signal DS in synchronization with the induced pulse signal CS1 exceeding the threshold value Vth.

  The control circuit 3 receives the detection signal DS from the determination circuit 4 and counts the number of signals. In the example shown in FIG. 26A, the number of detection signals DS is counted as one. As described above, the control circuit 3 stores the counted number of detection signals DS as the output time “1”.

  The reason why the output time of the detection signal DS is as short as “1” is that, as described above, the angle at which the rotor 111 is rotated by the end of the predetermined position pulse AP is small, only a few tens of degrees.

[Explanation of motor driving operation when it is determined that there is no external magnetic field N: FIG. 26B]
Next, the driving operation of the motor 110 according to the detection result of the external magnetic field N shown in FIGS. 25 and 26A will be described with reference to FIG. As an explanation condition, the external magnetic field N does not exist and the rotor 111 is driven to rotate in the reverse direction.

  Here, as described above, since the output time of the detection signal DS is counted as “1”, the control circuit 3 determines that the external magnetic field N does not exist and determines a drive pulse having a normal magnitude (pulse width: Middle) is supplied to the motor 110.

  By supplying the drive pulse having the normal magnitude, the stator 112 of the motor 110 is magnetized as shown in FIG. Thus, the magnetic field direction of the rotor 111 was at the position shown in FIG. 25C, but the N pole of the rotor 111 attracts the S pole of the magnetic pole portion 112b, and the S pole of the rotor 111 is N of the magnetic pole portion 112a. Attract with the poles. As a result, the rotor 111 rotates in the reverse direction, and the north pole of the rotor 111 rotates to the upper right of the static stable point B on the drawing.

  That is, the rotor 111 rotates 180 degrees from the position shown in FIG. 25C (static stable point B) to the position shown in FIG. Since the rotation angle of the rotor 111 at this time is the same as a normal step angle, a drive pulse with a normal driving force may be supplied.

[Summary of Motor Drive Operation According to External Magnetic Field N of Third Embodiment: FIG. 27]
Next, a summary of driving operations for the motor 110 according to the external magnetic field N of the third embodiment will be described with reference to FIG. In FIG. 27, the control circuit 3 determines the presence / absence of the external magnetic field N and the excitation direction based on the polarity (magnetic field direction) of the rotor 111 of the motor 110 and the number of detection signals DS corresponding to the induced current IC. It is the table | surface which summarized how to select the motor drive pulses O1-O4.

  As shown in FIG. 27, when the north pole of the rotor 111 is diagonally lower left on the drawing of the static stable point B (upper side of the table), the external magnetic field N is applied from the right if the number of detection signals DS is zero. ing. Therefore, since the excitation direction of the external magnetic field N has a polarity that repels the rotation direction of the rotor 111, a large drive pulse is required (see FIG. 24).

  If the number of detection signals DS is one or two, there is no external magnetic field N. Therefore, the drive pulse is a normal pulse (see FIG. 26). If the number of detection signals DS is three or more, an external magnetic field N is applied from the left. Accordingly, since the excitation direction of the external magnetic field N has a polarity attracting with respect to the rotation direction of the rotor 111, a small drive pulse is sufficient (see FIG. 22).

In addition, when the north pole of the rotor 111 is diagonally upper right on the drawing of the static stable point B (lower side of the table)
Although not described in detail, since the polarity of the rotor 111 is reversed, if the number of detection signals DS is three or more, the external magnetic field N is applied from the right direction. Accordingly, since the excitation direction of the external magnetic field N has a polarity attracting with respect to the rotation direction of the rotor 111, a small drive pulse is sufficient.

  If the number of detection signals DS is one or two, there is no external magnetic field N. Therefore, the drive pulse is a normal pulse. If the number of detection signals DS is zero, the external magnetic field N is applied from the left direction. Accordingly, since the excitation direction of the external magnetic field N has a polarity that repels the rotation direction of the rotor 111, a large drive pulse is required.

  Here, since the control circuit 3 always knows the polarity of the rotor 111, the control circuit 3 can determine the presence / absence of the external magnetic field N and the excitation direction from the information on the number of detection signals DS detected by the induced current IC. Can be understood from FIG. As a result, the control circuit 3 can determine whether the excitation direction of the external magnetic field N is repulsive or attractive with respect to the rotation direction of the rotor 111, and can supply an appropriate drive pulse to the motor 110.

  As described above, in the detection of the external magnetic field N using the one-coil step motor according to the third embodiment, the size of the induced current IC and the length of the output time differ depending on the presence / absence of the external magnetic field N and the excitation direction. Is done. Thus, the presence or absence of the external magnetic field N and the excitation direction are determined according to the time that the induced current IC exceeds the predetermined threshold Vth (the output time of the detection signal DS), and the optimum drive pulse is selected according to the external magnetic field N it can. As a result, it is possible to provide a small and lightweight step motor driving mechanism that realizes stable motor driving with low power without being affected by the external magnetic field N.

DESCRIPTION OF SYMBOLS 1, 50, 100 Step motor drive mechanism 2 Oscillation circuit 3 Control circuit 4, 66 Judgment circuit 10, 60 Drive circuit 11 Drive pulse generation circuit 12 Predetermined position pulse generation circuit 13 Pulse selection circuit 14 Detection pulse generation circuit 15, 61, 62 Driver circuit 16, 63, 64 Inductive current detection circuit 20, 70, 80 Two-coil step motor 21, 111 Rotor 22, 112 Stator 90 Electronic clock 110 One-coil step motor AP Predetermined position pulse CP Inductive current detection pulse CS1-CS4 Inductive pulse Signal DS1 to DS4 Detection signal O1 to O4 Motor drive pulse

Claims (12)

A step motor having a rotor magnetized with two or more poles in the radial direction and a coil for applying a magnetic field to the rotor;
A drive circuit for outputting a pulse to the step motor;
A step motor drive mechanism comprising:
The drive circuit is
A predetermined position pulse generating circuit for outputting a predetermined position pulse for moving the rotor to a predetermined position;
An induced current detection circuit for detecting an induced current generated in the coil by the rotation of the rotor after the rotor is rotationally driven by the predetermined position pulse;
Have
A determination circuit for determining the presence or absence of an external magnetic field according to the induced current;
A control circuit for determining the state of the external magnetic field according to the determination result of the determination circuit;
Step motor drive mechanism characterized by having. The determination circuit compares the induced current generated in the coil with a predetermined threshold value,
The step motor drive mechanism according to claim 1, wherein a detection signal is output to the control circuit. The step motor drive mechanism according to claim 2, wherein the control circuit counts an output time of the detection signal of the determination circuit and determines the state of the external magnetic field. The step motor drive mechanism according to claim 2, wherein the step motor drive mechanism has a plurality of the predetermined threshold values. A plurality of the step motors are arranged,
The step motor drive mechanism according to any one of claims 1 to 4, wherein the external magnetic field direction detected by at least one step motor is different from the external magnetic field direction detected by another step motor. . The drive circuit has a drive pulse generation circuit that outputs a drive pulse for driving the rotor,
The step motor drive mechanism according to any one of claims 1 to 5, wherein the control circuit changes the drive pulse by controlling the drive pulse generation circuit according to a state of the external magnetic field. The step motor drive mechanism according to claim 6, wherein the control circuit determines an excitation direction of the external magnetic field and changes the drive pulse according to the excitation direction and a rotation direction of the rotor. The control circuit outputs the drive pulse larger than the drive pulse when it is determined that the external magnetic field is not present when the determined excitation direction has a polarity repelling the rotation direction of the rotor. The step motor drive mechanism according to claim 7, wherein the step motor drive mechanism is output. The control circuit outputs the drive pulse smaller than the drive pulse when it is determined that there is no external magnetic field when the determined excitation direction is a polarity attracted to the rotation direction of the rotor. The step motor drive mechanism according to claim 7, wherein: 10. The device according to claim 6, wherein the predetermined position pulse generation circuit outputs the predetermined position pulse before the drive pulse generation circuit outputs the drive pulse. 11. Step motor drive mechanism. The step motor has a stator for guiding a magnetic field generated in the coil to the rotor,
The stator is provided between the first stator magnetic pole part, the second stator magnetic pole part, and the first stator magnetic pole part and the second stator magnetic pole part and facing the rotor. A magnetic pole part,
The coil magnetically couples the first stator magnetic pole portion and the third stator magnetic pole portion magnetically between the first stator magnetic pole portion and the third stator magnetic pole portion, and the second stator magnetic pole portion and the third stator magnetic pole portion. A second coil that is electrically coupled,
The predetermined position pulse generation circuit outputs the predetermined position pulse to the first coil and the second coil,
The magnetic field direction of the rotor when the predetermined position pulse is output and the magnetic field direction of the rotor when the predetermined position pulse is not output are parallel to each other. A step motor driving mechanism according to claim 1. The step motor has a stator for guiding a magnetic field generated in the coil to the rotor,
The coil and the stator are each composed of one each.
The predetermined position pulse generation circuit outputs the predetermined position pulse to the coil;
11. The magnetic field direction of the rotor when the predetermined position pulse is output and the magnetic field direction of the rotor when the predetermined position pulse is not output are different from each other. A step motor driving mechanism according to item 1.

Images