JP6988971B2 - Rotation detector and electronic clock - Google Patents

Description

The present invention relates to a rotation detector and an electronic clock.

In a stepping motor, it is necessary for the rotor to rotate reliably at each step. Therefore, in the drive control of the stepping motor, it is determined whether or not the rotor has rotated (rotor rotation detection). Specifically, after applying a drive pulse for rotating the rotor, the counter electromotive force (counter electromotive voltage) generated by damping when the rotor stops at a predetermined step angle is detected. As a result, when it is determined that the rotor is not rotating, a correction pulse is further applied to rotate the rotor.

However, "damping" the rotor means converting the kinetic energy of the rotor into Joule heat, and in a sense, wasting power. Therefore, there is known a technique of reducing the speed of the rotor near the step angle to reduce the energy loss due to damping. For example, in the solution of the abstract of Patent Document 1 below, "the drive pulse supplied to the step motor is chopper-controlled, and the initial and final duty ratios of the drive pulses are set lower than the medium-term duty ratios. The distribution of effective power in the drive pulse can be set to be low at the beginning and end and high at the middle, and the step motor can generate a torque that matches the cogging torque of the step motor. Therefore, waste at the beginning and end of the drive pulse. Since the rotor can be rotated at a low speed, the power consumption for driving the step motor can be reduced. "

Japanese Unexamined Patent Publication No. 9-266697

However, the level of counter electromotive force is proportional to the rotational speed of the rotor. As described above, if the speed of the rotor near the step angle is lowered, the level of the counter electromotive force near the step angle is lowered, which causes a problem that the accuracy of rotation detection is lowered.

Further, as a method for detecting the position of a motor having a permanent magnet in a rotor, a technique using a magnetic saturation phenomenon generated in an iron core of a stator is known. That is, if the magnetic flux generated by the permanent magnet and the magnetic flux generated by the coil are in a strong relationship with each other, the influence of the magnetic saturation of the iron core becomes large, so that the inductance of the coil becomes low. On the other hand, if the magnetic flux generated by the permanent magnet and the magnetic flux generated by the coil are in a weakening relationship, the influence of magnetic saturation becomes small, so that the inductance of the coil becomes high. Thereby, the rotation angle of the rotor can be estimated by measuring the inductance of the coil.

However, in the prior art utilizing the magnetic saturation phenomenon, a high frequency voltage is applied to the coil in order to measure the inductance of the coil. Then, the power consumption becomes large because the high frequency voltage is applied, and the meaning of suppressing the rotation speed of the rotor in order to suppress the power consumption is lost.
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a rotation detection device and an electronic clock capable of realizing accurate rotation detection of a rotor while suppressing power consumption.

In order to achieve the above object, the present invention
A rotation detection device for detecting the rotation of a rotor of a motor including a rotor having a magnet and a stator including a coil for rotating the rotor.
A motor control unit for determining whether or not the rotor has rotated based on the difference between the current value flowing through the coil and the threshold value is provided.
The coil includes a first coil and a second coil.
The motor control unit determines the magnets of the case where the rotor is changed from the rotating state to the stopped state and the state where the rotor is stopped without rotating for a predetermined time or longer. of the magnetic flux density difference caused by the stop angle, and outputs the current difference detection pulse for detecting the difference between the current value and the threshold value flowing through the coil, when an input of a drive pulse for rotating the rotor, before Symbol electrostatic detecting a state before Symbol rotor by flow difference detection pulse,
The magnetic flux density of the first coil is larger than the magnetic flux density of the second coil at any of the plurality of stop angles.
It is a rotation detection device characterized by this.

According to the rotation detection device and the electronic clock of the present invention, accurate rotation detection of the rotor can be realized while suppressing power consumption.

It is a block diagram of the electronic clock according to 1st Embodiment of this invention. It is a block diagram of the microcomputer in 1st Embodiment. It is a top view of the stepping motor in 1st Embodiment. It is a circuit diagram of the drive circuit in 1st Embodiment. It is operation | movement explanatory drawing of the drive circuit in 1st Embodiment at the time of (a) pulse drive, (b) inspection pulse supply, (c) current detection, (d) current detection (reverse direction). It is a waveform diagram of (a) a coil current, (b) a waveform diagram of a coil voltage, and (c) a BH characteristic diagram at the time of successful rotation of the first embodiment. It is a waveform diagram of (a) a coil current, (b) a waveform diagram of a coil voltage, and (c) a BH characteristic diagram at the time of unsuccessful rotation of the first embodiment. It is a top view of the stepping motor in the 2nd Embodiment. It is a circuit diagram of the drive circuit in 2nd Embodiment. It is a top view of the stepping motor by the comparative example. It is a top view of the stepping motor in the 3rd Embodiment. It is a top view of the stepping motor in 4th Embodiment. It is a circuit diagram of the drive circuit in 4th Embodiment. It is operation explanatory drawing of 4th Embodiment.

[First Embodiment]
<Structure of the first embodiment>
Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to each figure.
FIG. 1 is a schematic configuration diagram showing an electronic clock 1 according to the first embodiment of the present invention.
The analog electronic clock 1 of the present embodiment can each drive four pointers 2a to 2d (display unit) by independent motors, and is not particularly limited, but for example, to be worn on an arm. It is a wristwatch-type electronic watch equipped with a band of. The electronic clock 1 has, for example, steps 2a to 2d and stepping motors 4a to 4d (motors) for rotationally driving the pointers 2a to 2d via a train wheel mechanism 3a to 3d (display unit). .. Further, the electronic clock 1 includes a drive circuit 5 for driving the stepping motors 4a to 4d, a microcomputer 6, a power supply unit 7, and an oscillator 8.

Hereinafter, when the guidelines 2a to 2d are not particularly distinguished, they are simply referred to as the pointer 2. When each train wheel mechanism 3a to 3d is not particularly distinguished, it is simply referred to as a train wheel mechanism 3. When the stepping motors 4a to 4d are not particularly distinguished, they are simply referred to as stepping motors 4.
Further, a portion including the stepping motor 4, the drive circuit 5, the microcomputer 6 (control unit), and the vibrator 8 is referred to as a "motor drive device 10". Further, since the microcomputer 6 and the drive circuit 5 also have a function of detecting whether or not the stepping motor 4 has normally rotated, the drive circuit 5 and the microcomputer 6 are referred to as a "rotation detection device 11".

The drive circuit 5 has a bridge circuit for driving the stepping motor 4, and applies a voltage to the stepping motor 4 in response to a command from the microcomputer 6. The microcomputer 6 is a large-scale integrated circuit (LSI), and includes a CPU (Central Processing Unit) 61, a peripheral circuit 62, an oscillation circuit 611, a frequency dividing circuit 612, and a timekeeping circuit 613. Consists of including.

The pointers 2a to 2d are rotatably provided with respect to the rotation axis on the dial. The train wheel mechanism 3a to 3d rotate the pointers 2a to 2d, respectively. The drive circuit 5 outputs a drive voltage signal for driving the stepping motors 4a to 4d at an appropriate timing based on the control signal input from the microcomputer 6. The drive circuit 5 can output by adjusting the drive voltage and the drive voltage pulse width of the stepping motor 4 based on the set signal from the microcomputer 6. The drive circuit 5 can output a drive voltage signal to the stepping motor 4 in the forward rotation direction or the reverse rotation direction.

The CPU 61 performs various arithmetic processes and controls the overall operation of the electronic clock 1 in an integrated manner. The CPU 61 reads out and executes a control program, continuously causes each unit to perform an operation related to time display, and requests in real time or at a set timing based on an input operation to an operation unit (not shown). Make the action performed. The CPU 61 is a control means for setting a target position where the pointer 2 moves and controlling the drive of the stepping motor 4 via the drive circuit 5.

The oscillation circuit 611 generates a unique frequency signal and outputs it to the frequency dividing circuit 612. As the oscillation circuit 611, for example, a circuit that oscillates in combination with an oscillator 8 such as a crystal is used. The frequency dividing circuit 612 divides the signal input from the oscillation circuit 611 into signals of various frequencies used by the CPU 61 and the timekeeping circuit 613, and outputs the signal. The timekeeping circuit 613 is a counter circuit that counts the number of times of a predetermined frequency signal input from the frequency dividing circuit 612 and adds the number of times to the initial time to count the current time. The current time counted by the timekeeping circuit 613 is read out by the CPU 61 and used for time display. The counting of this time may be controlled by software.

The power supply unit 7 has a configuration capable of continuously and stably operating the electronic clock 1 for a long period of time, and is, for example, a combination of a battery and a DC-DC converter. As a result, the output voltage of the power supply unit 7 during operation maintains a predetermined value.

FIG. 2 is a schematic block diagram of a microcomputer 6 which is an LSI. The microcomputer 6 includes a CPU 61, a ROM (Read Only Memory) 63, a RAM (Random Access Memory) 64, an OSC (Oscillator) 65, a peripheral 68, a VRMX 67, and a DVR 66. Various control programs and initial setting data are stored in the ROM 63, and various control programs (not shown) are read out by the CPU 61 and continuously executed when the electronic clock 1 is started.

The RAM 64 is a volatile memory such as an SRAM and a DRAM, and provides a working memory space to the CPU 61. Further, the RAM 64 can temporarily store user setting data or the like set based on an input operation to the operation unit. A part of the RAM 64 may be a non-volatile memory such as a flash memory or an EEPROM (Electrically Erasable and Programmable Read Only Memory). The OSC 65 generates a unique frequency signal and supplies it to the CPU 61, the peripheral 68, and the like, and corresponds to the combination of the oscillation circuit 611 and the oscillator 8 in FIG.

The DVR 66 is a circuit for driving a signal for driving a motor. The VRMX67 is a regulator that generates a power supply to supply the DVR66. The peripheral 68 includes a motor control unit 69, which includes a phase control circuit 691, a drive pulse generation circuit 692, a current difference detection pulse generation circuit 693, a VRMX control circuit 694, and an A / D conversion. It has a device 695 and a detection determination circuit 696. The phase control circuit 691, the drive pulse generation circuit 692, the current difference detection pulse generation circuit 693, the VRMX control circuit 694, the A / D converter 695, and the detection determination circuit 696 are motor-controlled in a single microcomputer. It may be a unit, or a motor control unit may be provided separately for each unit, and each operation may be performed by a single microcomputer or a plurality of microcomputers.

The phase control circuit 691 controls a series of phases including the output of the drive pulse and the generation of the current difference detection pulse. The drive pulse generation circuit 692 outputs a drive pulse to the motor, and the current difference detection pulse generation circuit 693 outputs a current difference detection pulse (details will be described later) to the motor. The VRMX control circuit 694 controls the VRMX 67 to generate a predetermined power supply voltage. The A / D converter 695 converts the analog voltage at a predetermined position (details will be described later) of the drive circuit 5 into a digital signal. The detection determination circuit 696 determines whether or not the stepping motor 4 has rotated based on the digital signal.

FIG. 3 is a plan view of the stepping motor 4 having a single core configuration.
The stepping motor 4 has a stator 47 and a rotor 48. The rotor 48 is formed in a disk shape and is rotatably supported in the circumferential direction, and has a magnet magnetized in two poles in the radial direction. In the rotor 48, the lightly hatched portion constitutes the S pole 48S, and the deeply hatched portion constitutes the N pole 48N. For the rotor 48, for example, a magnet such as a rare earth magnet (for example, a samarium-cobalt magnet or the like) is preferably used, but the rotor 48 is not limited thereto.

The rotor 48 is rotatably arranged around an axis (not shown) provided on the stator 47. In the present embodiment, the rotor 48 can rotate at a predetermined step angle in either the counterclockwise direction or the clockwise direction by applying a drive pulse to the coil L1 described later. When the stepping motor 4 is applied to a clock or the like, the rotor 48 is connected to, for example, a gear constituting the train wheel mechanism 3 for moving the pointer 2 of the clock, and the rotor 48 rotates. It is advisable to rotate these gears and the like.

The stator 47 has an iron core 46 formed in a substantially rectangular frame shape, and a coil L1 wound around an upper side portion thereof. A substantially circular hole 42 is formed in the central portion of the lower side of the iron core 46, and the rotor 48 is arranged so as to be concentric with the hole 42. When a current is passed through the coil L1, magnetic poles appear in the stator 47 near the regions 44 and 45. The polarities of the magnetic poles of the regions 44 and 45 are determined by the direction of the current flowing through the coil L1. The coil L1 is connected to the drive circuit 5 (see FIG. 1) via the terminal block 43.

Therefore, when the coil L1 is driven so that the magnetic poles repelling the S pole 48S and the N pole 48N appear in the regions 44 and 45, the rotor 48 rotates. Further, the stator 47 is formed with two recesses 42a on the inner peripheral surface of the hole 42 that receives the rotor 48. The two recesses 42a are formed in the directions of about 60 degrees and about 240 degrees when the upward direction is 0 degrees. These two recesses 42a allow the rotor 48 to remain stationary.

In the present embodiment, the stepping motor 4 has the largest index torque (holding torque) when the S pole 48S and the N pole 48N face the regions 44 and 45. Therefore, in the non-energized state to which the drive pulse is not applied, the rotor 48 stops magnetically stably at the stop position shown in FIG. 3 or the stop position rotated 180 degrees from this stop position.

FIG. 4 is a circuit diagram of the drive circuit 5.
The drive circuit 5 applies a drive pulse and a current difference detection pulse to the coil L1, and forms an H-bridge circuit composed of switch elements Tr1 to Tr4 composed of MOSFETs (Metal-Oxide-Semiconductor Field-Effect Transistor). Have. Further, the switch elements Tr7, Tr8 and the resistor R1 form a discharge circuit for discharging the energy stored in the coil L1. The terminal voltage of the coil L1 is called the coil voltage V1, and the current flowing through the coil L1 is called the coil current I1.

A power supply voltage Vcc is applied between the power supply terminal and the ground terminal of the drive circuit 5 by the power supply unit 7 (see FIG. 1). Then, the switch elements Tr1 and Tr2 are connected in series between the voltage terminal and the ground terminal via the connection point O2, and the switch elements Tr3 and Tr4 are connected in series via the connection point O1. One end of the resistor R1 is connected to the ground terminal, a switch element Tr7 is connected between the connection point O2 and the other end of the resistor R1, and a switch element Tr8 is connected between the connection point O1 and the other end of the resistor R1. It is connected. Further, the coil L1 of the stepping motor 4 is connected between the connection points O2 and O1.

<Operation of the first embodiment>
Next, the operation of this embodiment will be described with reference to FIG. Note that FIG. 5 is an operation explanatory diagram of the drive circuit 5 during (a) pulse drive, (b) current difference detection pulse supply, (c) current detection, and (d) current detection (reverse direction). be. The stepping motor 4 can rotate at a step angle of 180 degrees. 5 (a) to 5 (c) show the current flowing through the drive circuit 5 within a period in which the rotor 48 rotates 180 degrees from one step angle to the next step angle.

FIG. 5A shows an operation at the time of a drive pulse input for rotationally driving the rotor 48. Here, the drive pulse generation circuit 692 (see FIG. 2) turns on the switch elements Tr1 and Tr4 and turns off the other switch elements. Then, a current flows through the coil L1 along the path A1 passing through the switch elements Tr1 and Tr4, and the rotor 48 is rotationally driven by about 180 degrees in a normal state. This state is called "successful rotation". However, when vibration or impact is applied to the electronic clock 1 at the time of inputting the drive pulse, the rotor 48 may not rotate even if the drive pulse is input. This state is called "rotation failure".

Next, FIG. 5B shows an operation at the time of inputting a current difference detection pulse for detecting the position of the rotor 48. Here, the current difference detection pulse generation circuit 693 (see FIG. 2) turns on the switch elements Tr2 and Tr3 and turns off the other switch elements. Then, a current flows in the coil L1 in the direction opposite to the path A1 along the path A2 passing through the switch elements Tr2 and Tr3. Magnetic energy is stored in the coil L1 due to the current flowing through the coil L1. However, since the pulse width of the current difference detection pulse is shorter than that of the drive pulse, the rotor 48 is not rotationally driven by the current difference detection pulse.

Next, FIG. 5C shows an operation at the time of current detection in which the magnetic energy stored in the coil L1 is passed as a current and the current value is detected. Here, the current difference detection pulse generation circuit 693 turns on the switch elements Tr4 and Tr7, and turns off the other switch elements. Then, a current flows along the path A3 passing through the switch element Tr4, the coil L1, the switch element Tr7, and the resistor R1, and a terminal voltage proportional to this current appears in the resistor R1. The terminal voltage of the resistor R1 is converted into a digital signal by the A / D converter 695 shown in FIG. In the detection determination circuit 696, it is determined whether or not the rotation of the rotor 48 is successful based on the terminal voltage. If the rotation is unsuccessful, a correction pulse similar to the drive pulse is applied to rotate the rotor 48.

After the operation shown in FIGS. 5 (a) to 5 (c) is completed, the direction opposite to the direction shown in FIGS. 5 (a) to 5 (c) is used within the remaining 180-degree rotation period. A current is supplied to the coil L1. That is, at the time of inputting the drive pulse, the drive pulse is supplied along the path A2 shown in FIG. 5B under the control of the drive pulse generation circuit 692. Further, at the time of inputting the current difference detection pulse, the current difference detection pulse is supplied along the path A1 shown in FIG. 5A under the control of the current difference detection pulse generation circuit 693. At the time of current detection, the current difference detection pulse generation circuit 693 turns on the switch elements Tr2 and Tr8, and turns off the other switch elements. Then, as shown in FIG. 5D, a current flows along the path A4 passing through the switch element Tr2, the coil L1, the switch element Tr8, and the resistor R1, and the terminal voltage proportional to this current appears in the resistor R1. ..

Next, with reference to FIGS. 6A to 6C, the waveforms of each part at the time of successful rotation will be described. 6 (a) is a waveform diagram of the coil current I1, FIG. 6 (b) is a waveform diagram of the coil voltage V1 applied to the coil L1 by the switch elements Tr1 to Tr4, and FIG. 6 (c) is an iron core 46. It is a BH characteristic diagram of. The horizontal axis of FIG. 6C is the magnetic field H of the iron core 46 at the location of the coil L1, and the vertical axis is the magnetic flux density B of the iron core 46 at the location of the coil L1.

In FIG. 6 (b), the coil voltage V1 applied to the coil L1 during the period from time t1 to t2 and the period from time t3 to t4 is the drive pulse and the current shown in FIGS. 5 (a) and 5 (b), respectively. It is a difference detection pulse. Further, in FIG. 6A, the coil current I1 flowing in the period from time t4 to t5 is the current flowing in the resistor R1 in the path A3 shown in FIG. 5C. Further, the magnetic field H shown by the broken line in FIG. 6C is the magnetic field generated by the magnet of the rotor 48, and the magnetic field H shown by the alternate long and short dash line is the result of adding the magnetic field generated by the magnet and the magnetic field generated by the current difference detection pulse. be.

When the rotation of the rotor 48 is successful, the magnetic field due to the current difference detection pulse is generated in the direction of weakening the magnetic field due to the magnet. The slope of the tangent line dB / dB of is relatively large. The slope of the tangent line dB / dH has a differential magnetic permeability μ, and the inductance of the coil L1 is proportional to the differential magnetic permeability μ, so that the inductance has a relatively large value. Therefore, the coil current I1 at the time of supplying the current difference detection pulse (time t3 to t4) and at the time of current detection (time t4 to t5) becomes a relatively low value as shown in FIG. 6A. Then, if the peak value of the coil current I1 is equal to or less than the threshold value Is, the detection determination circuit 696 (see FIG. 2) determines that the rotation is successful.

Here, the width of the current difference detection pulse (time t3 to t4) is preferably in the range of 0.01 ms or more and 1 ms or less, and is 0.05 ms or more and 0.1 ms or less. It is more preferable to make it a range. Further, in relation to the width of the drive pulse (time t1 to t2), the width of the current difference detection pulse is preferably in the range of 1/3 to 1/300 of the width of the drive pulse, and is preferably 1/30 to 1/300. It is more preferable to set it in the range of 1/60. The significance of these numerical values is that if the current difference detection pulse is too short, the accuracy of rotation detection deteriorates, and if it is too long, the rotor 48 moves.

Next, with reference to FIGS. 7 (a) to 7 (c), the waveform of each part at the time of unsuccessful rotation will be described. 7 (a) to 7 (c) are waveform diagrams and characteristic diagrams at the time of unsuccessful rotation corresponding to FIGS. 6 (a) to 6 (c).
In FIG. 7B, the coil voltage V1 applied to the coil L1 during the period from time t11 to t12 and the period from time t13 to t14 is a drive pulse and a current difference detection pulse, respectively. Further, in FIG. 7A, the coil current I1 flowing in the period from time t14 to t15 is the current flowing in the resistor R1 in the path A3 shown in FIG. 5C. Further, the magnetic field H shown by the broken line in FIG. 7C is the magnetic field generated by the magnet of the rotor 48, and the magnetic field H shown by the alternate long and short dash line is the result of adding the magnetic field generated by the magnet and the magnetic field generated by the current difference detection pulse. be.

When the rotation of the rotor 48 is unsuccessful, the magnetic field due to the current difference detection pulse is generated in the direction of strengthening the magnetic field due to the magnet. Therefore, the magnetic field H obtained by adding both belongs to a region where the influence of magnetic saturation is relatively large. , The slope of the tangent line of the BH characteristic dB / dH is relatively small. As a result, the inductance of the coil L1 becomes a relatively small value, and the coil current I1 at the time of supplying the current difference detection pulse (time t13 to t14) and at the time of current detection (time t14 to t15) is shown in FIG. 7A. As shown, the value is relatively high.

As described above, the terminal voltage of the resistor R1 proportional to the coil current I1 is converted into a digital signal by the A / D converter 695 shown in FIG. 2 and supplied to the detection determination circuit 696. The detection determination circuit 696 calculates the coil current I1 based on the terminal voltage of the resistor R1 and compares the peak value of the coil current I1 with the threshold value Is. Then, if the peak value of the coil current I1 is equal to or less than the threshold value Is, it is determined that the rotation is successful, and if the peak value of the coil current I1 exceeds the threshold value Is, it is determined that the rotation is unsuccessful.

<Effect of the first embodiment>
As described above, the rotation detection device (11) of the present embodiment is
A motor control unit (69) for determining whether or not the rotor has rotated based on the difference in current flowing through the coil is provided.
The motor control unit (69)
It outputs a current difference detection pulse for detecting the difference in magnetic flux density caused by the stop angle of the magnet between the case where the rotor is rotated and the case where the rotor is not rotated by the difference in current flowing through the coil.
Here, the "current difference" is, for example, the difference between the peak value of the coil current I1 and the threshold value Is.
From another point of view, the rotation detection device (11) of the present embodiment is
The first magnetic flux density due to the magnet assuming that the rotor (48) has rotated normally is equal to or higher than the second magnetic flux density due to the magnet assuming that the rotor (48) has not rotated normally. A current difference detection pulse generation circuit (693) that supplies a current difference detection pulse to the coil to be inspected by using one coil as the coil to be inspected and generating a magnetic flux in the direction of lowering the first magnetic flux density.
A detection determination circuit (696) that determines whether or not the rotor (48) has rotated normally based on the current flowing through the coil to be inspected.
It has.

That is, in FIG. 3, the magnetic flux flowing through the coil (L1) is substantially the same regardless of the stop position of the rotor 48, and “first magnetic flux density = second magnetic flux density”. The "first magnetic flux density" is "greater than or equal to the second magnetic flux density".
The frequency of successful rotation is higher than the frequency of unsuccessful rotation, and the current difference detection pulse generation circuit (693) generates a magnetic flux in the direction of lowering the first magnetic flux density when the rotation is successful. As described above, since the current difference detection pulse is supplied to the coil to be inspected (L1), the frequency of the current flowing through the coil to be inspected (L1) becomes small (as shown at times t3 to t4 in FIG. 6A). The current becomes higher than the frequency (as shown at times t13 to t14 in FIG. 7A).
Thereby, according to the present embodiment, accurate rotation detection of the rotor (48) can be realized while suppressing power consumption.

Further, the current difference detection pulse generation circuit (693) supplies a current difference detection pulse to the coil to be inspected for a predetermined supply period (time t3 to t4, t13 to t14).
The detection determination circuit (696) determines whether or not the rotor (48) has normally rotated based on the current flowing through the coil to be inspected after the supply period ends.
Further, the rotor (48) has a plurality of stop positions that magnetically stably stop within a rotation range of one round.
The detection determination circuit (696) determines whether or not the rotor (48) is located at the stop position when the rotor (48) rotates normally.
Further, the current difference detection pulse is a square wave having a high level period of 0.01 ms or more and 1 ms or less in length.
Here, the "high level period" is, for example, a period in which a voltage having an absolute value exceeding zero is applied to the coil to be inspected by the current difference detection pulse generation circuit (693).
Due to these features, power consumption can be significantly reduced as compared with a known technique such as supplying a high frequency current to the coil (L1).

[Second Embodiment]
<Structure of the second embodiment>
Next, the electronic clock according to the second embodiment of the present invention will be described. The overall configuration of the electronic clock of this embodiment is the same as that of the first embodiment (see FIG. 1), but instead of the stepping motor 4 and the drive circuit 5 in the first embodiment, the stepping motor shown in FIG. 8 is used. The difference is that 140 and the drive circuit 150 shown in FIG. 9 are applied. In FIGS. 8 and 9, the parts corresponding to the parts of FIGS. 1 to 7 are designated by the same reference numerals, and the description thereof may be omitted.

FIG. 8 is a plan view of the stepping motor 140.
The stepping motor 140 has a stator 147 and a rotor 48. The configuration of the rotor 48 is the same as that of the first embodiment (see FIG. 3). In the present embodiment, the rotor 48 can rotate at a predetermined step angle in either the counterclockwise direction or the clockwise direction by applying a drive pulse to the coils L1 and L2 described later. In this embodiment, the step angle is 180 degrees.

The stator 147 has a substantially rectangular center yoke 145, a pair of side yokes 144 and 146 arranged below the center yoke 145, and coils L1 and L2. The side yokes 144 and 146 are provided substantially symmetrically so as to surround the rotor 48. The coils L1 (first coil) and L2 (second coil) are inserted between the upper end of the center yoke 145 and the side yokes 144 and 146, and the coils L1 and L2 are terminal blocks. It is connected to the drive circuit 150 described later via 143.

In the stator 147, a substantially circular hole 142 is formed at the intersection of the lower end of the center yoke 145 and the pair of side yokes 144 and 146, and the rotor 48 is arranged in the hole 142. In the stator 147, three magnetic poles appear along the outer circumference of the rotor 48 in the vicinity of the center yoke 145, the vicinity of the side yoke 144, and the vicinity of the side yoke 146 in the excited state. The polarities of the three magnetic poles of the stator 147 are switched by applying drive pulses to the coils L1 and L2. Further, at the connection points of the side yokes 144 and 146, an arcuate recess 147a is formed below the hole 142.

One end of the coil L1 is magnetically connected to the center yoke 145, and the other end of the coil L1 is magnetically connected to the free end of the side yoke 146. Further, one end side of the coil L2 is magnetically connected to the center yoke 145, and the other end side of the coil L2 is magnetically connected to the free end of the side yoke 144.
In the present embodiment, a drive pulse is applied to the coils L1 and L2 by the drive pulse generation circuit 692 (see FIG. 2). When magnetic flux is generated from the coils L1 and L2 as a result, the magnetic flux flows along the magnetic core of the coil L1 and the stator 147 magnetically connected to the magnetic core, and the three magnetic poles are appropriately switched.

Further, three recesses 142a are formed on the inner peripheral surface of the hole 142. These three recesses 142a are formed in two directions, one is tilted counterclockwise by about 10 degrees with respect to the direction of the center yoke 145, and the other is perpendicular to the direction. These three recesses 142a allow the rotor 48 to remain stationary. In the present embodiment, the stepping motor 140 has the most index torque in a state where the polarization directions of the rotor 48 face each other in the directions tilted clockwise by about 80 degrees and about 260 degrees with respect to the direction of the center yoke 145. (Holding torque) becomes large. Therefore, in the non-energized state to which the drive pulse is not applied, the rotor 48 stops magnetically stably at the stop position shown in FIG. 8 or the stop position rotated 180 degrees from this stop position.

FIG. 9 is a circuit diagram of the drive circuit 150.
The drive circuit 150 applies a drive pulse to the two coils L1 and L2 and also applies a current difference detection pulse to the coil L1. The drive circuit 150 comprises an H-bridge circuit composed of switch elements Tr1 to Tr6 composed of MOSFETs. Have. Further, the switch elements Tr7 to Tr9 and the resistor R1 form a discharge circuit for discharging the energy stored in the coils L1 and L2.

A power supply voltage Vcc is applied between the power supply terminal and the ground terminal of the drive circuit 150 by the power supply unit 7 (see FIG. 1). Then, the switch elements Tr1 and Tr2 are connected in series between the voltage terminal and the ground terminal via the connection point O2, the switch elements Tr3 and Tr4 are connected in series via the connection point O1, and the switch element Tr5 is connected. , Tr6 are connected in series via the connection point O3. One end of the resistor R1 is connected to the ground terminal, a switch element Tr7 is connected between the connection point O2 and the other end of the resistor R1, and a switch element Tr8 is connected between the connection point O1 and the other end of the resistor R1. It is connected, and a switch element Tr9 is connected between the connection point O3 and the other end of the resistor R1. Further, the coil L1 of the stepping motor 140 is connected between the connection points O2 and O1, and the coil L2 is connected between the connection points O3 and O1.

<Operation of the second embodiment>
In the second embodiment, the drive pulse generation circuit 692 (see FIG. 2) turns on / off the switch elements Tr1 to Tr6 shown in FIG. 9 to drive pulses (FIGS. 6B and 7) to the coils L1 and L2. (B)) is supplied, and the rotor 48 is rotationally driven. As described above, the rotor 48 stops magnetically stably at the stop position shown in FIG. 8 or the stop position rotated 180 degrees from this position. At that time, the magnetic flux densities B1 and B2 generated in the cores of the coils L1 and L2 in the non-energized state of the coils L1 and L2 are indicated by the broken line arrows in FIG.

In the present embodiment, the position of the recess 142a is tilted counterclockwise by about 10 degrees from the vertical and horizontal directions, so that the magnetic flux density B1 is larger than that of B2. At the stop position rotated 180 degrees from the stop position shown in FIG. 8, the direction of the magnetic flux is reversed, but the magnetic flux density B1 is still larger than that of B2. This means that the coil L1 is more affected by magnetic saturation than the coil L2 at the stop position.

Therefore, in the present embodiment, the current difference detection pulse generation circuit 693 supplies the current difference detection pulse (see FIGS. 6 (b) and 7 (b)) to the coil L1 and does not supply the current difference detection pulse to the coil L2. ing. Based on the current difference detection pulse, the waveform of the coil current I1 flowing through the coil L1 is the same as the waveform shown in FIG. 6A when the rotation is successful and FIG. 7B when the rotation is unsuccessful. Therefore, as in the first embodiment, if the peak value of the coil current I1 is equal to or less than the threshold value Is, the detection determination circuit 696 determines that "rotation is successful", and if the peak value of the coil current I1 exceeds the threshold value Is. Judged as "unsuccessful rotation".

<Comparison example>
Here, in order to clarify the effect of the present embodiment, the configuration of the stepping motor 160 according to the comparative example of the present embodiment will be described with reference to FIG. 10.
FIG. 10 is a plan view of the stepping motor 160. The stepping motor 160 has a stator 167 and a rotor 48. The stator 167 has a substantially rectangular center yoke 165, a pair of side yokes 164 and 166 arranged below the center yoke 165, and coils L1 and L2. The side yokes 164 and 166 are provided substantially symmetrically so as to surround the rotor 48. The center yoke 165 and the side yokes 164 and 166 have substantially the same shape as the center yoke 145 and the side yokes 144 and 146 of the second embodiment shown in FIG. Further, the shape of the recess 167a formed below the rotor 48 is also the same as the shape of the recess 147a in the second embodiment.

However, the substantially circular hole portion 162 formed at the intersection of the center yoke 165 and the side yokes 164 and 166 has a different forming position of the recess 162a as compared with the hole portion 142 of the second embodiment. That is, in the hole portion 162 of this comparative example, the recess 162a is formed on the rotor 48 and in the left-right direction. As described above, since the stator 167 of this comparative example is formed substantially symmetrically, the magnetic flux output from the rotor 48 is substantially bisected via the side yokes 164 and 166 and then rotated. Return to child 48. Therefore, the magnetic flux densities B1 and B2 generated in the cores of the coils L1 and L2 in the non-energized state of the coils L1 and L2 are substantially equal as shown by the broken line arrows in FIG.

As described above, when the magnetic flux densities B1 and B2 are substantially equal to each other, all of them are less likely to be affected by magnetic saturation. Then, the current flowing through the coils L1 and L2 due to the current difference detection pulse has a problem that the difference between successful rotation and unsuccessful rotation becomes small, and it becomes difficult to detect the rotation of the rotor 48.

<Effect of the second embodiment>
As described above, according to the electronic clock of the present embodiment, the motor (4) has a first coil (L1) and a second coil (L2) as a plurality of coils.
The magnetic flux density (B1) of the first coil (L1) is larger than the magnetic flux density (B2) of the second coil (L2) at any of the plurality of stop positions, and at any of the plurality of stop positions. Also, the first coil (L1) is selected as the coil to be inspected.

As described above, according to the comparative example (see FIG. 10) in which the magnetic flux densities B1 and B2 are substantially equal, there arises a problem that the rotation detection of the rotor 48 becomes difficult. On the other hand, according to the second embodiment (see FIG. 8), the stator 147 is configured so that the magnetic flux density B1 of the coil L1 at the stop position is larger than the magnetic flux density B2 of the coil L2. As a result, even in the dual-core type stepping motor 140, it is possible to detect the rotation of the rotor 48 with high accuracy while suppressing the power consumption.

[Third Embodiment]
Next, the electronic clock according to the third embodiment of the present invention will be described. The overall configuration of the electronic clock of this embodiment is the same as that of the first embodiment (see FIG. 1), but instead of the stepping motor 4 and the drive circuit 5 in the first embodiment, the stepping motor shown in FIG. 11 is used. The difference is that the drive circuit 150 (see FIG. 9) similar to the 170 and the second embodiment is applied. In FIG. 11, the parts corresponding to the parts of FIGS. 1 to 10 are designated by the same reference numerals, and the description thereof may be omitted.

FIG. 11 is a plan view of the stepping motor 170.
The stepping motor 170 has a stator 177 and a rotor 48. The configuration of the rotor 48 is the same as that of the first embodiment (see FIG. 3). Further, the stator 177 has a substantially rectangular center yoke 175, a pair of side yokes 174 and 176 arranged below the center yoke 175, and coils L1 and L2. The side yokes 174 and 176 are provided substantially symmetrically so as to surround the rotor 48. The center yoke 175 and the side yokes 174 and 176 have substantially the same shape as the center yoke 165 and the side yokes 164 and 166 in the comparative example of the second embodiment (see FIG. 10). Further, the shape of the hole portion 172 formed at these intersections is also the same as the shape of the hole portion 162 in the comparative example of FIG.

However, in FIG. 11, the arcuate recess 177a formed below the rotor 48 is biased to the left of the recess 167a in FIG. In the present embodiment, the magnetic flux downward from the rotor 48 is branched into the side yokes 174 and 176, but the cross-sectional area of the side yoke 174 becomes smaller in the vicinity of the recess 177a, so that the side yoke is smaller than the side yoke 174. A large magnetic flux flows by 176. The configuration other than the above is the same as that of the second embodiment.

As described above, according to the present embodiment, similarly to the second embodiment, even in the dual core type stepping motor 170, the rotation of the rotor 48 can be detected with high accuracy while suppressing the power consumption. It will be possible.

[Fourth Embodiment]
<Structure of the fourth embodiment>
Next, the electronic clock according to the fourth embodiment of the present invention will be described. The overall configuration of the electronic clock of this embodiment is the same as that of the first embodiment (see FIG. 1), but instead of the stepping motor 4 and the drive circuit 5 in the first embodiment, the stepping motor shown in FIG. 12 is used. The difference is that 240 and the drive circuit 250 shown in FIG. 13 are applied. In FIGS. 12 and 13, the parts corresponding to the parts of FIGS. 1 to 11 are designated by the same reference numerals, and the description thereof may be omitted.

FIG. 12 is a plan view of the stepping motor 240.
The stepping motor 240 has a stator 247 and a rotor 48. The configuration of the rotor 48 is the same as that of the first embodiment (see FIG. 3). In the present embodiment, the rotor 48 is counterclockwise by applying a drive pulse to the coil L1 (first coil), the coil L2 (second coil), and the coil L3 (third coil) described later. It can rotate at a predetermined step angle in either the clockwise direction or the clockwise direction. In this embodiment, the step angle is 60 degrees.

The stator 247 has a substantially E-shaped first yoke 245 and a substantially I-shaped second yoke 246. A plurality of terminal blocks 243 are mounted on the front surface of the second yoke 246. Coil L1, L2, L3 are inserted between the first and second yokes 245 and 246. The coils L1, L2, and L3 are magnetically coupled to the first and second yokes 245 and 246, and are connected to a drive circuit 250 described later via a terminal block 243.

A substantially circular hole portion 242 is formed in the central portion of the first yoke 245, and the rotor 48 is arranged in the hole portion 242. In the stator 247, three magnetic poles appear around the hole 242 in the excited state. The polarities of the three magnetic poles of the stator 247 are switched by applying drive pulses to the coils L1, L2, and L3. Further, an arc-shaped recess 247a is formed in the center of the left side surface of the first yoke 245.

A recess 242a is formed on the inner peripheral surface of the hole 242 at a position divided into six equal parts in the circumferential direction. These recesses 242a allow the rotor 48 to remain stationary. In the present embodiment, the stepping motor 240 has the largest index torque (holding torque) when the polarization direction of the rotor 48 faces the recess 242a. Therefore, in the non-energized state to which the drive pulse is not applied, the rotor 48 is at the stop position shown in FIG. 12 or at the stop position rotated by 60 degrees, 120 degrees, 180 degrees, 240 degrees, and 300 degrees from this stop position. It stops magnetically stably.

FIG. 13 is a circuit diagram of the drive circuit 250.
The drive circuit 250 applies a drive pulse and a current difference detection pulse to the three coils L1, L2, and L3, and has an H-bridge circuit composed of switch elements Tr1 to Tr6, Tr10, and Tr11 composed of MOSFETs. is doing. Further, the switch elements Tr7 to Tr9, Tr12 and the resistor R1 form a discharge circuit for discharging the energy stored in the coils L1 and L2.

A power supply voltage Vcc is applied between the power supply terminal and the ground terminal of the drive circuit 250 by the power supply unit 7 (see FIG. 1). Then, the switch elements Tr1 and Tr2 are connected in series between the voltage terminal and the ground terminal via the connection point O2, and the switch elements Tr3 and Tr4 are connected in series via the connection point O1. Similarly, the switch elements Tr5 and Tr6 are connected in series via the connection point O3, and the switch elements Tr10 and Tr11 are connected in series via the connection point O4.

Further, one end of the resistor R1 is connected to the ground terminal, a switch element Tr7 is connected between the connection point O2 and the other end of the resistor R1, and a switch element is connected between the connection point O1 and the other end of the resistor R1. Tr8 is connected. Similarly, the switch element Tr9 is connected between the connection point O3 and the other end of the resistor R1, and the switch element Tr12 is connected between the connection point O4 and the other end of the resistor R1. Further, the coil L1 of the stepping motor 240 is connected between the connection points O2 and O1, the coil L2 is connected between the connection points O3 and O1, and the coil L3 is connected between the connection points O3 and O4. ing.

<Operation of the fourth embodiment>
In the fourth embodiment, the drive pulse generation circuit 692 (see FIG. 2) turns on / off the switch elements Tr1 to Tr6, Tr10, and Tr11 shown in FIG. As a result, drive pulses (see FIGS. 6 (b) and 7 (b)) are supplied to the coils L1, L2, and L3, and the rotor 48 is rotationally driven. As described above, the rotor 48 magnetically stably stops at the stop position shown in FIG. 12 or at the stop position rotated by 60 degrees, 120 degrees, 180 degrees, 240 degrees, and 300 degrees from this position.

FIG. 14 is an operation explanatory diagram of the present embodiment. At each stop position shown in FIG. 14, the letter "N" or "S" written around the rotor 48 is a magnetic pole induced in the first yoke 245 by the rotor 48, that is, coils L1, L2. Represents a magnetic pole induced when L3 is in a non-energized state. In each of the illustrated states, if the N pole or the S pole is generated at two places, the magnetic flux divided into two flows through the coil corresponding to those places, so that the magnetic flux density becomes small. On the other hand, if the N pole or the S pole is generated at only one place, almost all the magnetic flux flows through the corresponding coil, so that the magnetic flux density becomes large. That is, the magnetic flux density of the coil is the maximum among the three coils L1, L2, and L3.

Therefore, in the present embodiment, the current difference detection pulse generation circuit 693 (see FIG. 2) sends a current difference detection pulse to the coil having the maximum magnetic flux density when the rotor 48 is assumed to rotate normally. Supply. That is, the switch elements Tr2, Tr4, Tr6, Tr7 to Tr9, Tr11, and Tr12 are controlled on / off so as to supply the current difference detection pulse in the direction of lowering the magnetic flux density of the coil. In each stepping motor 240 shown in FIG. 14, the state of the rotor 48 is shown when the rotor 48 is assumed to rotate normally. Further, the direction of the magnetic flux generated by the coil that supplies the current difference detection pulse and the current difference detection pulse is shown by a white arrow in FIG. As shown in FIG. 14, as long as the rotor 48 rotates normally, the current difference detection pulses are periodically supplied to the coils L1, L2, and L3 in a predetermined order. The rotation detection operation after supplying the current difference detection pulse is the same as that of the first to third embodiments.

As described above, according to the present embodiment,
The motor (4) has a first coil (L1), a second coil (L2), and a third coil (L3) as a plurality of coils.
The detection determination circuit (696) is predetermined for the first coil (L1), the second coil (L2), and the third coil (L3) as long as the rotor (48) rotates normally. It is characterized by supplying current difference detection pulses in order.
Further, in the coil to be inspected to which the current difference detection pulse is supplied, the first magnetic flux density by the magnet assuming that the rotor (48) rotates normally, the rotor (48) does not rotate normally. It is a coil having a higher magnetic flux density than the second magnetic flux density due to the magnet when it is assumed that the coil is used. As a result, even in the triple core type stepping motor 240, it is possible to detect the rotation of the rotor 48 with high accuracy while suppressing the power consumption.

[Modification example]
The present invention is not limited to the above-described embodiment, and various modifications are possible. The above-described embodiments are exemplified for the purpose of explaining the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the configurations described. Further, it is possible to replace a part of the configuration of one embodiment with the configuration of another embodiment, and it is also possible to add the configuration of another embodiment to the configuration of one embodiment. Further, it is possible to delete a part of the configuration of each embodiment, or add / replace another configuration. Possible modifications to the above embodiment are, for example, as follows.

(1) In each of the above embodiments, as a specific example of the "motor", an example in which a single-core, dual-core, or triple-core type stepping motor 4,140, 170, 240 is applied has been described, but more coils have been described. A stepping motor having the above may be applied. Further, the present invention may be applied to a motor other than the stepping motor.

(2) Further, although the microcomputer 6 has been described as being mounted on the electronic clock 1 in each of the above embodiments, it may be applied to motor control of various devices other than the electronic clock 1.

(3) In each of the above embodiments, an example in which the polarity of the drive pulse and the polarity of the current difference detection pulse are opposite polarities has been described, but the present invention is not limited to this. For example, the polarity of the drive pulse and the polarity of the current difference detection pulse may be the same. In this case, if the rotation of the rotor 48 is successful, the magnetic field due to the current difference detection pulse is generated in the direction of strengthening the magnetic field due to the magnet. Therefore, the magnetic field H obtained by adding both is a region where the influence of magnetic saturation is relatively large. The slope of the tangent line of the BH characteristic, dB / dH, is relatively small. As a result, the inductance of the coil L1 becomes a relatively small value. Therefore, the coil current I1 at the time of supplying the current difference detection pulse (time t3 to t4) and at the time of current detection (time t4 to t5) becomes a relatively high value. When the rotation of the rotor 48 is unsuccessful, the magnetic field due to the current difference detection pulse is generated in the direction of weakening the magnetic field due to the magnet. Therefore, the magnetic field H obtained by adding both is a region where the influence of magnetic saturation is relatively small. The slope of the tangent line of the BH characteristic, dB / dH, is relatively large. As a result, the inductance of the coil L1 becomes a relatively large value, and the coil current I1 at the time of supplying the current difference detection pulse (time t13 to t14) and at the time of current detection (time t14 to t15) becomes a relatively low value. .. Then, when the peak value of the coil current I1 exceeds the threshold value Is, it is determined as "rotation successful", and when the peak value of the coil current I1 is equal to or less than the threshold value Is, it is determined as "rotation unsuccessful".

(4) Each of the above embodiments may be applied to the detection of needle misalignment due to a drop impact, static electricity, or the like.
That is, if the same rotation detection is performed a plurality of times after the rotation detection is performed until the next drive pulse is supplied, it can be determined whether or not the needle has been displaced. When it is recognized that the needle has shifted, it is possible to correct the needle shift by detecting the needle position and returning it to the normal position. This makes it possible to mount the second hand, minute hand, and hour hand, which have a large weight and unbalanced moment, which could not be mounted in the past.

The inventions described in the claims originally attached to the application of this application are described below. The claims described in the appendix are the scope of the claims originally attached to the application for this application.
[Additional Notes]
<Claim 1>
A rotation detection device for detecting the rotation of a rotor of a motor including a rotor having a magnet and a stator including a coil for rotating the rotor.
A motor control unit for determining whether or not the rotor has rotated based on the difference in current flowing through the coil is provided.
The motor control unit
A rotation detection device characterized by outputting a current difference detection pulse for detecting the difference in magnetic flux density caused by the stop angle of the magnet between the case where the rotor is rotated and the case where the rotor is not rotated by the difference in current flowing through the coil. ..
<Claim 2>
The motor control unit
The current difference detection pulse is output to the coil for a predetermined period, and the current difference detection pulse is output.
The rotation detection device according to claim 1, wherein it is determined whether or not the rotor has rotated based on the difference in current flowing through the coil after the predetermined period has ended.
<Claim 3>
The rotor has a plurality of stop angles that magnetically stably stop within a rotation range of one round.
The rotation detection device according to claim 1 or 2, wherein the motor control unit determines whether or not the rotor rotates and stops at the stop angle.
<Claim 4>
The rotation detection device according to claim 3, wherein the current difference detection pulse is a square wave having a high level period of 0.01 ms or more and a length of 1 ms or less.
<Claim 5>
The stop angle of the rotor has two points within the rotation range of one round.
The rotor alternately stops at the two stop angles during rotation,
The rotation detection device according to claim 3 or 4, wherein the motor control unit alternately switches the polarity of the current difference detection pulse supplied to the coil when the rotor rotates.
<Claim 6>
The coil of the motor includes a first coil and a second coil.
The magnetic flux density of the first coil is larger than the magnetic flux density of the second coil at any of the plurality of stop angles, and the magnetic flux density of the first coil is increased at any of the plurality of stop angles. The rotation detection device according to claim 3 or 4, wherein it is determined whether or not the rotor has rotated based on the difference in flowing current.
<Claim 7>
As the coil of the motor, there are a first coil, a second coil, and a third coil.
The motor control unit is characterized in that, when the rotor is rotated, the current difference detection pulses are supplied to the first coil, the second coil, and the third coil in a predetermined order. The rotation detection device according to claim 3 or 4.
<Claim 8>
The rotation detection device according to any one of claims 1 to 7.
Display and
The timekeeping part that measures the time and
A control unit that displays the time measured by the timekeeping unit on the display unit,
An electronic clock characterized by being equipped with.

1 Electronic clock 2,2a-2d Pointer (display)
3,3a to 3d train wheel mechanism (display unit)
4,4a-4d, 140,170,240 Stepping motor (motor)
5 Drive circuit 6 Microcomputer (control unit)
7 Power supply unit 8 Oscillator 10 Motor drive device 11 Rotation detection device 47 Stator 48 Rotor 69 Motor control unit 613 Timekeeping circuit (timekeeping part)
692 Drive pulse generation circuit 693 Current difference detection pulse generation circuit 696 Detection judgment circuit L1 coil (first coil)
L2 coil (second coil)
L3 coil (third coil)
Tr1 to Tr12 switch element

Claims (7)

A rotation detection device for detecting the rotation of a rotor of a motor including a rotor having a magnet and a stator including a coil for rotating the rotor.
A motor control unit for determining whether or not the rotor has rotated based on the difference between the current value flowing through the coil and the threshold value is provided.
The coil includes a first coil and a second coil.
The motor control unit determines the magnets of the case where the rotor is changed from the rotating state to the stopped state and the state where the rotor is stopped without rotating for a predetermined time or longer. of the magnetic flux density difference caused by the stop angle, and outputs the current difference detection pulse for detecting the difference between the current value and the threshold value flowing through the coil, when an input of a drive pulse for rotating the rotor, before Symbol electrostatic detecting a state before Symbol rotor by flow difference detection pulse,
The magnetic flux density of the first coil is larger than the magnetic flux density of the second coil at any of the plurality of stop angles.
A rotation detection device characterized by this. The current value flowing through the coil is the current value flowing through the first coil, the current value flowing through the second coil, or the current value flowing between the first coil and the second coil connected in series. The rotation detection device according to claim 1, wherein the rotation detection device is characterized by any of the above. The motor control unit
The current difference detection pulse is output to the coil for a predetermined period, and the current difference detection pulse is output.
The rotation detection device according to claim 1 or 2, wherein it is determined whether or not the rotor has rotated based on the difference between the current value flowing through the coil and the threshold value after the predetermined period ends. .. The rotation detection device according to any one of claims 1 to 3, wherein the current difference detection pulse is a square wave having a high level period of 0.01 ms or more and a length of 1 ms or less. .. There are two stop angles of the rotor within the rotation range of one round.
The rotor alternately stops at the two stop angles during rotation,
The rotation detection device according to any one of claims 1 to 4, wherein the motor control unit alternately switches the polarity of the current difference detection pulse supplied to the coil when the rotor rotates. .. The coil includes a third coil.
The motor control unit is characterized in that, when the rotor is rotated, the current difference detection pulses are supplied to the first coil, the second coil, and the third coil in a predetermined order. The rotation detection device according to any one of claims 1 to 5. The rotation detection device according to any one of claims 1 to 6.
Display and
The timekeeping part that measures the time and
A control unit that displays the time measured by the timekeeping unit on the display unit,
An electronic clock characterized by being equipped with.

Images