JP2010200475A - Stepping motor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stepping motor that is driven by low power consumption, achieves high torque, and reduces variations in characteristics. <P>SOLUTION: The stepping motor has a rotor with a two-pole magnetized permanent magnet and a rotation axis, an exciting yoke with an exciting coil wound thereon and having first/third pole tips, and a detecting yoke with a detecting coil wound thereon and having second/fourth pole tips. The second/fourth pole tips are arranged between the first/third pole tips on the same plane. A high magnetoresistance part is provided between each of the pole tips. An angle θ1 of the rotation axis forming a part facing the rotor of the first or third pole tip is larger than an angle θ2 of the rotation axis forming a part facing the rotor of the second or fourth pole tip. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a step motor for rotationally driving a time indicator hand, a calendar, and the like of a wristwatch.

  When correcting the time of the clock or adjusting the calendar, there is a demand for a function of performing a reverse rotation operation of the step motor and a function of moving at a higher speed than during normal hand movement. When performing a reverse rotation operation of the step motor, it is necessary to grasp the initial magnetic pole position of the rotor magnet, which is a rotating body, and supply an appropriate drive pulse corresponding to the magnetic pole position. In addition, when fast-forwarding is performed by moving the step motor at high speed, it is necessary to supply fast-forwarding drive pulses that have a shorter interval (cycle) than normal drive pulses. Furthermore, in order to adjust the time, it is necessary to drive so that there is no mishandling during fast-forwarding, that is, no rotation error of the rotor, in any of forward and reverse rotations.

  And for forward / reverse rotation function at time correction and high-speed driving, the demand for stepping motor driven by low power consumption and high torque is high, and stable performance without variation. It is strongly desired that the product is a finished product. Under such circumstances, a prior art having two magnetic circuits that control the forward / reverse two directions of rotation is disclosed. Each of the two magnetic circuits includes an exciting coil and is magnetically separated from each other, the rotor is magnetized by two poles, and the rotor hole is constituted by a two-phase electromagnetic step motor having four poles. (For example, see Patent Document 1)

(Description of conventional step motor configuration: FIG. 14)
Here, the structure of this conventional step motor will be described. FIG. 14 is a diagram showing a configuration of a conventional step motor.

As shown in FIG. 14, the step motor is
A stator 101, a rotor 105 that is rotatably installed inside the stator cavity 103, and a winding 107 that is an exciting coil are provided. The stator cavity 103 is provided in the stator 101 and has an essentially circular shape. The rotation axis of the rotor 105 is perpendicular to the main surface of the stator 101. The stator 101 includes four magnetic poles 109, 113, 111, 115, and two shunts. Each magnetic pole extends outwardly by an arm to form two shunts, and each shunt has a winding. It has a line 107. Each of these arms extends at an angle of 90 degrees around the stator cavity 103 with the adjacent arm.

Japanese Patent Laid-Open No. 05-115167 (page 2-4, FIG. 1)

  However, the conventional step motor described in Patent Document 1 has the following problems.

The step motor using the prior art is either forward or reverse in both the case of performing two-coil 90-degree steps for the purpose of high torque and the case of performing one-coil 180-degree step drive for the purpose of low power consumption. It is possible to cause the same operation to be performed even in the rotational direction, and the performance is the same in both the forward and reverse rotational directions. However, in the step motor having the same performance in both the forward and reverse rotation directions, both the two-coil 90-degree step drive for high torque and the one-coil 180 degree step drive for low power consumption are used. There is a problem that it is difficult to achieve further lower power consumption in step driving.

  This will be described in more detail. When it is desired to drive the step motor with low power consumption, it is common to perform 180 degree step driving capable of performing 180 degree steps with one pulse. However, the first magnetic pole 109, the second magnetic pole 111, Since the opposing portions of the third magnetic pole 113 and the fourth magnetic pole 115 all have the same shape, the amount of magnetic flux of the rotor magnets passing through the two shunts is substantially equal, and thus the two parts are separated. The electromechanical coupling coefficient in the road is almost the same. However, since either one of the shunts is used for 180 degree step drive, it is necessary to improve the magnetic characteristics of the shunt used for further reducing power consumption. Due to the shape, it is not easy to improve the magnetic characteristics of the shunt used during 180-degree step drive by changing the shape, and to achieve further lower power consumption.

  Therefore, the present invention solves the above-mentioned problems, and can drive with low power consumption, can obtain high torque in a step motor capable of forward / reverse high-speed rotation drive, and can further reduce variations in characteristics. An object is to provide a step motor.

  In order to achieve the above object, the present invention basically employs a technical configuration as described below.

  The step motor of the present invention is arranged with a rotor (rotating body) having a permanent magnet magnetized in two poles in the radial direction and a rotating shaft, and an excitation coil wound around the rotating body. An excitation yoke having a first magnetic pole tip and a third magnetic pole tip, a second magnetic pole tip and a fourth magnetic pole tip provided around the rotation axis and having a detection coil wound therearound. And a detection motor having a detection motor, wherein the second and fourth magnetic pole tips are arranged between the first and third magnetic pole tips on the same plane, and the first to fourth magnetic pole tips. The shape of is formed so that the static stable direction in which the rotating body is stationary when no voltage is applied to the exciting coil is orthogonal to the electromagnetic stable direction generated by exciting the exciting coil. There is a space between the first and third magnetic pole tips and the second and fourth magnetic pole tips. Alternatively, a high magnetic resistance portion is provided by a nonmagnetic member, and the shape of the high magnetic resistance portion is a direction orthogonal to the electromagnetic stability direction and parallel to the static stability direction. The angle θ1 at the rotation axis that is formed so as to have a substantially symmetrical plane with respect to the axis passing through the center of the first and third magnetic pole ends and the rotating body is the second or fourth. It is characterized in that it is larger than the angle θ2 at the rotating shaft that forms the facing portion of the magnetic pole end with the rotating body.

As described above, in the step motor of the present invention,
Since the angle θ1 at the rotating shaft that forms the facing portion of the first or third magnetic pole end with the rotating body is larger than the angle θ2 at the rotating shaft that forms the facing portion of the second or fourth magnetic pole end with the rotating body, Since the magnetic flux amount φ1 of the permanent magnet in the first magnetic circuit can be increased and the electromechanical coupling coefficient n × φ1 can be increased, the driving torque “Td = n × φ1 × i × sin θ” is increased. Therefore, if the drive torque Td is maintained, low current consumption can be achieved by decreasing the current value i. If the current value i is maintained, the drive torque Td is increased. High torque characteristics can be obtained.

  Further, the angle θ1 at the rotating shaft that forms the facing portion of the first or third magnetic pole end with the rotating body is larger than the angle θ2 at the rotating shaft that forms the facing portion of the second or fourth magnetic pole end with the rotating body. Therefore, since the angle θ3 on the rotation axis that forms the facing portion between the high magnetic resistance portion having a constant width w and the rotating body can be reduced, variation in the angle θ3 can be reduced. That is, there is a variation in the angle θ1 at the rotation axis that forms the facing portion of the first or third magnetic pole end with the rotating body and the angle θ2 at the rotation shaft that forms the facing portion of the second or fourth magnetic pole end with the rotating body. The motor can be driven with high torque with a small and stable driving current. In addition, since the magnetic flux amount φ2 of the permanent magnet in the second magnetic circuit is substantially constant, the rotation detection counter electromotive voltage waveform by the detection coil can be stably obtained in the second magnetic circuit, so that accurate rotation Detection can be achieved.

It is a disassembled perspective view which shows the structure of the step motor of this invention. It is a rotary body hole part enlarged view in the step motor of this invention. It is a figure which shows the structure of the control apparatus in the step motor of this invention. It is a figure which shows the drive circuit and detection coil circuit structure in the step motor of this invention. It is a figure explaining operation | movement of the rotary body in the step motor of this invention. It is a figure which shows the rotational torque waveform with respect to the rotation angle of the rotary body in the step motor of this invention. It is a figure which shows the flow of the magnetic flux in the step motor of this invention. It is a figure which shows the flow of the magnetic flux in the step motor of this invention. It is a figure which shows the magnetic flux amount waveform with respect to the rotation angle of a rotary body which flows into the detection coil core of the step motor of this invention. It is a figure which shows the relationship between the magnetic flux amount which generate | occur | produces with an exciting coil and a detection coil, and the rotation angle of a rotary body in the step motor of this invention. It is a figure which shows the drive pulse and back electromotive force waveform in the step motor of this invention. It is a figure which shows the magnetic flux amount (phi) 1 and (phi) 2 in the step motor of this invention. It is a figure which shows (theta) 3 change in the step motor of this invention. It is drawing which shows the structure of the conventional step motor.

  Embodiments of the present invention will be described below. FIG. 1 is an exploded perspective view showing the structure of the step motor in this embodiment. FIG. 2 is an enlarged view of the rotor hole portion of the step motor in the embodiment. Hereinafter, specific examples will be described with reference to the drawings.

(Description of step motor configuration: FIGS. 1 and 2)
In FIG. 1, the step motor of the present embodiment is a permanent magnet magnetized in two radial directions, and has a rotating body 1 disposed around a rotating shaft 25 indicated by a dotted line in the figure. The rotating body 1 is rotatably inserted into the rotating body hole 7.

The step motor has an excitation yoke 17 and a detection yoke 27. As shown in FIGS. 1 and 2, the exciting yoke 17 magnetically couples both ends of the exciting coil core 5 and makes a relative distance with a certain distance from the magnetic pole end to the rotating shaft 25 around the rotating shaft 25. The first magnetic pole end 9, the third magnetic pole end 13, and the exciting coil 3 in which a conducting wire is wound around the exciting coil core 5. The detection yoke 27 magnetically couples both ends of the detection coil core 21 and is located at a position different from the first and third magnetic pole ends 9 and 13 from the magnetic pole end to the rotation shaft 25 around the rotation axis 25. A second magnetic pole tip 11 and a fourth magnetic pole tip 15 which are provided so as to be relatively spaced apart from each other, and a detection coil core 21.
And a detection coil 19 around which a conducting wire is wound.

  A notch 51 is provided inside the rotating body hole 7, and the notch 51 allows the rotating body 1 to be stationary with the magnetic pole facing the static stable direction 47.

  Here, the angle of the first magnetic pole end 9 on the rotating shaft 25 that forms the facing portion with the rotating body 1 is θ1, and the angle of the second magnetic pole end 11 on the rotating shaft 25 that forms the facing portion with the rotating body 1 is θ2. And Although not shown in FIG. 2, the third magnetic pole tip 13 has the same shape as the first magnetic pole tip 9 and is formed at a symmetrical position around the rotation axis 25. The angle of the rotating shaft 25 that forms the facing portion of the 13 rotating body 1 is also θ1, and the angle of the rotating shaft 25 that forms the facing portion of the fourth magnetic pole tip 15 facing the rotating body 1 is also θ2. . The first to fourth magnetic pole tips 9, 11, 13, and 15 are arranged around the rotating body 1 so as to satisfy the relationship that θ1 is larger than θ2.

  The angle of the rotary shaft 25 that forms the opposing portion of the high magnetoresistive portion 23 provided between the first and third magnetic pole ends and the second and fourth magnetic pole ends with the rotating body 1 is θ3. To do. In addition, the excitation coil 3 and the detection coil 19 are connected to the control device 87. Details of the control device 87 will be described later.

  The excitation yoke 17, the excitation coil core 5, the detection yoke 27, and the detection coil core 21 are made of permalloy or the like, which is a soft magnetic material that allows easy passage of magnetism. A high magnetoresistive portion 23 is provided between the first and third magnetic pole ends and the second and fourth magnetic pole ends. It is formed in a plane that is symmetric with respect to an axis that passes through the second and fourth magnetic pole ends that are orthogonal to each other and parallel to the static stable direction 47. And since the high magnetoresistive part 23 fixes between magnetic pole ends by inserting a plate-like nonmagnetic member and then welding and joining, the high magnetoresistive part 23 has a fixed width w and is substantially parallel. Are in a good positional relationship. Further, if the width w of the high magnetoresistive portion 23 is too narrow, the magnetic poles may be magnetically connected during welding, which may cause a deterioration in characteristics. If the width w is wide, the magnetic resistance of the first magnetic circuit may be increased. In this embodiment, it is assumed that about 100 μm is appropriate because resistance is increased and motor characteristics are reduced.

(Description of control device configuration: FIGS. 3 and 4)
Next, an outline of a control device that controls the step motor of this embodiment will be described. FIG. 3 is a diagram showing the configuration of the control device in the step motor of this embodiment.

  As shown in FIG. 3, the control device 87 in the step motor includes a pulse synthesizing circuit 31 that generates a reference pulse by using a reference oscillation source such as a crystal oscillator 29, and various outputs output from the pulse synthesizing circuit 31. And a drive control circuit 33 for controlling the step motor based on the pulse signal. The drive control circuit 33 is configured by a microcomputer or the like.

  The drive control circuit 33 supplies a drive pulse to the exciting coil 3 via the rotor drive circuit 35 to rotate the rotating body 1. Here, when the rotating body 1 does not rotate, a compensation pulse having a larger effective power than the drive pulse is output. The drive control circuit 33 controls the detection-side switching mechanism included in the detection coil circuit 37 and outputs a back electromotive signal from the detection coil 19. Details of specific configurations of the rotor drive circuit 35 and the detection coil circuit 37 will be described later.

The rotor rotation detection circuit 39 connected to the drive control circuit 33 is supplied with a back electromotive signal from a detection waveform that is a back electromotive voltage induced in the detection coil 19 by controlling the detection side switching mechanism. Note that the method of determining the magnetic pole position of the rotating body using this back electromotive voltage is based on the back electromotive force signal output from the detection coil 19 by controlling the switching mechanism included in the detection coil circuit 37 described above. Thus, there are a method of determining, a method of simply determining from the detection waveform of the back electromotive voltage at the peak value level, or a method of capturing a phenomenon (zero cross) in which the voltage value of the detection waveform is inverted. The rotor rotation detection circuit 39 is also connected to the excitation coil 3 and can determine the magnetic pole position of the rotating body 1 using the counter electromotive voltage generated in the excitation coil 3.

  Here, specific configurations of the rotor drive circuit 35 and the detection coil circuit 37 described above will be described. FIG. 4A is a diagram illustrating a configuration of the rotor drive circuit 35 included in the control device 87 described above, and FIG. 4B is a diagram illustrating a configuration of the detection coil circuit 37.

  The rotor driving circuit 35 included in the control device 87 includes a bridge circuit constituted by an n-channel MOS 43a and a p-channel MOS 41a connected in series, and an n-channel MOS 43b and a p-channel MOS 41b, and an n-channel MOS 43a. The control signal Pn1, the control signal Pp1 of the p-channel MOS 41a, the control signal Pn2 of the n-channel MOS 43b, and the control signal Pp2 of the p-channel MOS 41b are supplied from the power source to the excitation coil 3 (see FIG. 1) of the step motor. The direction in which the current flows can be switched by controlling the electric power.

  Further, a p-channel MOS 45a and a p-channel MOS 45b are connected in parallel at both ends of the detection coil 19 (see FIG. 1) in the detection coil circuit 37. The p-channel MOS 45a constituting the detection coil circuit 37 receives a control signal. The p-channel MOS 45b can be controlled by a control signal Pt2. The p-channel MOSs 45a and 45b are switched at regular intervals to short-circuit the detection coil 19, and the back electromotive force signal is detected when the voltage generated when the switch is switched and the back electromotive voltage waveform match. Can be done. The detection coil 19 can be opened with respect to the detection coil core 21 so as not to detect the back electromotive force.

(Description of step motor operation: FIGS. 5 and 6)
Next, the rotation operation of the rotating body 1 of the step motor and the driving torque generated here will be described. FIGS. 5A to 5D are views showing first to fourth postures, which will be described later, showing the rotation operation of the rotating body 1 of the step motor. FIG. 6 is a diagram showing the relationship between the rotational torque generated by the rotating body and the angle of the rotating body, which is generated with the rotation operation of the step motor.

  As shown in FIG. 5A, the stepping motor has the notch 51 and the first to fourth magnetic pole tips 9 such that the electromagnetic stable direction 49 is inclined by approximately 90 degrees with respect to the static stable direction 47. 11, 13, and 15 are arranged, and the angle of the rotating body used in FIG. 6 is static at the second magnetic pole tip 11 with the first magnetic pole tip 9 direction of the electromagnetic stable direction 49 as the 0-degree position. The stable direction 47 is a 90 degree position, the electromagnetic stable direction at the third magnetic pole tip 13 is a 180 degree position, and the static stable direction at the fourth magnetic pole tip 15 is a 270 degree position.

  FIG. 5A shows a first state, in which a control signal is controlled so that a drive pulse is not supplied, and no current flows through an exciting coil (not shown), which is a non-excited state. At this time, the notch 51 stops in the static stable direction 47 in which the N pole of the rotating body 1 faces the second magnetic pole end 11 and the S pole faces the fourth magnetic pole end 15. And the torque which acts on the rotary body 1 in this 1st state becomes the point a in FIG. Therefore, the rotational torque value of the rotating body 1 at this time is almost zero.

Next, the second state is shown in FIG. Control the control circuit to output drive pulses,
The first magnetic pole tip 9 is excited to the N pole, and the third magnetic pole tip 13 is excited to the S pole. In this state, the N pole of the first magnetic pole tip 9 and the N pole of the rotating body 1 repel each other, and the S pole of the third magnetic pole tip 13 and the S pole of the rotating body 1 repel each other. 1 obtains rotational torque in the counterclockwise direction. Here, the rotational torque value acting on the rotating body 1 in the second state is a point b in FIG. 6, and the rotating body 1 at this time obtains a positive rotating torque and rotates counterclockwise.

  As shown in FIG. 5B, the rotating body 1 having obtained the rotational torque rotates counterclockwise, and the first rotating body 1 as shown in the third state in FIG. 5C. The N pole of the magnetic pole tip 9 and the S pole of the rotating body 1 attract each other, and the S pole of the third magnetic pole tip 13 and the N pole of the rotating body 1 attract each other. Move in the stable direction 49. Then, the magnetic pole end of the rotator 1 is in a third state that substantially coincides with the electromagnetic stable direction 49. Here, in FIG. 6, the torque that acts while moving from the point b in the second state to the point c in the third state always rotates with a positive torque value. In the third state at this time, the rotational torque value acting on the rotating body 1 is substantially zero rotational torque, but since the rotating body 1 has rotational energy, the counterclockwise rotational motion is continued. Can do.

  Then, at the timing when the rotating body 1 takes the third state, the exciting coil is brought into a non-excited state, thereby acting between the magnetic pole end of the rotating body 1 and the first and third magnetic pole ends 9 and 13. The force is only the counterclockwise rotational torque due to the holding torque. As a result, the rotating body 1 passes through the electromagnetic stable direction 49, and the fourth state (rotating body) shown in FIG. 5D is such that the N pole of the rotating body 1 faces the fourth magnetic pole end 15 direction. 1 is stable in the stationary stable direction 47). Accordingly, in FIG. 6, from the point c which is the third state to the point d which is the fourth state, the rotation is received by the positive holding torque, and the rotational torque in the fourth state is almost zero. .

  When the N pole of the rotating body 1 is rotated clockwise from the state where the N pole is facing the second magnetic pole tip 11, the first magnetic pole tip 9 is set to the S pole and the third magnetic pole tip 13 is set to the N pole. By controlling so that the N pole of the rotating body 1 and the S pole of the first magnetic pole tip 9 are attracted, the N pole of the rotating body 1 and the N pole of the third magnetic pole tip 13 are repelled. Thus, it can be seen that the step motor of this embodiment can rotate in either the forward or reverse direction.

  Therefore, the step motor in which the first to fourth magnetic pole tips 9, 11, 13, and 15 are arranged with the above-described relationship is used for one step 180 by the drive pulse applied to the first and third magnetic pole tips 9 and 13. Rotation operation is possible, and rotation drive with low power consumption is possible, similar to a one-phase step motor having a conventional configuration.

(Explanatory diagram of magnetic flux flow accompanying step motor operation: FIGS. 7 and 8)
Next, the flow of magnetic flux accompanying the operation of the rotating body of the step motor in the first to fourth states shown in FIGS. 5 (a) to 5 (d) will be described. FIGS. 7A and 7B are diagrams showing the flow of magnetic flux in the first and second states described in FIG. FIGS. 8A and 8B are diagrams showing the flow of magnetic flux in the third and fourth states.

  In the first state shown in FIG. 7A, there is no exciting magnetic flux by the exciting coil 3, the N pole of the rotating body 1 faces the second magnetic pole tip 11, and the S pole is the fourth magnetic pole tip 15. The magnetic flux of the rotator 1 from the N pole enters the second magnetic pole end 11, passes through the detection coil core 21, passes from the fourth magnetic pole end 15 to the rotator 1. A magnetic path flowing into the S pole is formed. The magnetic circuit at this time is defined as a second magnetic circuit.

In the second state shown in FIG. 7B, the N pole of the rotator 1 is in the direction of the second magnetic pole end 11 and the S pole is in the direction of the fourth magnetic pole 15; The magnetic flux of the body 1 flows through the detection coil core 21. Here, a current is passed through the exciting coil 3 to generate a magnetic flux, and excitation is performed so that the first magnetic pole tip 9 is an N pole and the third magnetic pole tip 13 is an S pole. The magnetic flux forms a magnetic path that flows from the exciting coil core 5 to the first and third magnetic pole ends 9 and 13 and returns to the exciting coil core 5. The magnetic circuit through which the magnetic flux flows by the exciting coil 3 at this time is defined as a first magnetic circuit.

  Further, in the third state shown in FIG. 8A, the N pole of the rotating body 1 faces the direction of the third magnetic pole tip 13, and the S pole of the rotating body 1 faces the direction of the first magnetic pole tip 9. Therefore, the magnetic flux generated by the rotating body 1 flows from the third magnetic pole tip 13 to the exciting coil core 5 and then to the first magnetic pole tip 9. At this time, the magnetic flux generated by the exciting coil 3 also flows from the exciting coil core 5 to the first magnetic pole end 9 and the third magnetic pole end 13 and returns to the exciting coil core 5. Both the magnetic fluxes generated by the exciting coil 3 have the same path. Therefore, the magnetic flux flowing through the detection coil core 21 becomes zero, and the change in the amount of magnetic flux flowing through the detection coil core 21 occurs when the rotating body 1 changes from the second state to the third state.

  In the fourth state shown in FIG. 8B, no current is passed through the exciting coil 3, so there is no exciting magnetic flux, and the north pole of the rotating body 1 faces the fourth magnetic pole end 15 and the south pole. Faces the 11 direction of the second magnetic pole tip. Therefore, a magnetic circuit is configured such that the magnetic flux of the rotating body 1 flows from the fourth magnetic pole tip 15 to the detection coil core 21 and then to the second magnetic pole tip 11. And the magnetic flux which flows into the detection coil core 21 becomes a reverse direction with the direction of the magnetic flux which flows in a 1st state. Therefore, the direction of the magnetic flux flowing through the detection coil core 21 changes while the rotating body 1 changes from the first state to the fourth state.

  Thus, in the non-excited state, the N pole and the S pole of the rotating body 1 take a stable state in the static stable direction 47 in which the second and fourth magnetic pole ends 11 and 15 are directed. The form in which the rotating body 1 is stabilized in this static stable direction is the first form in which the N pole faces the second magnetic pole end 11 direction and the S pole faces the fourth magnetic pole end 15 direction. May be in two directions, a second form in which the direction of the fourth magnetic pole tip 15 is directed and the S pole is directed to the direction of the second magnetic pole tip 11.

(Explanation of change in magnetic flux flowing through detection coil core: FIG. 9)
Next, a change in the amount of magnetic flux flowing through the detection coil core 21 that occurs with the rotation of the rotating body 1 shown in FIGS. 7 and 8 will be described. FIG. 9 is a diagram showing the relationship between the rotation angle of the rotator and the amount of magnetic flux generated at that time. The abscissa indicates the rotation angle in the direction in which the magnetic pole of the rotator is facing, and the ordinate indicates the detection coil core. The amount of magnetic flux passing through 21 is shown. In this figure, when the direction of the magnetic flux flowing through the detection coil core 21 flows from the fourth magnetic pole tip 15 to the second magnetic pole tip 11 is positive, the second magnetic pole tip 11 extends to the fourth magnetic pole. The time when it flows to the extreme 15 is negative.

  When the rotating body 1 is in the first and second states shown in FIGS. 5A, 5B and 7A, 7B, the N pole of the rotating body 1 is in the direction of the second magnetic pole end 11. As shown in FIG. 9, the amount of magnetic flux flowing through the detection coil core 21 at this time is −φ shown at point a.

  The magnetic flux amount of the detection coil core 21 in the third state shown in FIG. 5C and FIG. 8A in which the rotating body 1 is rotated is a point b shown in FIG. The amount of magnetic flux becomes almost zero. 5 (d) and FIG. 8 (b), the magnetic flux amount of the detection coil core 21 when the rotating body 1 is in the fourth state is φ at the point c shown in FIG. Take the maximum value.

  Further, the counter electromotive voltage value V obtained by the change of the magnetic flux amount can be obtained by V = N × dφ / dt (N is the number of detection coil turns), and V = N × (dφ / dθ) when the equation is modified. Xdθ / dt. Dφ / dθ in this equation is a term corresponding to the slope of the waveform in FIG.

(Explanation of change in magnetic flux of excitation coil core and detection coil core: Fig. 10)
Next, the change in the amount of magnetic flux in the detection coil core when the amount of magnetic flux passing through the first magnetic circuit is changed by the exciting coil will be described. FIG. 10 is a diagram showing the relationship between the amount of magnetic flux generated in the excitation coil and the detection coil and the rotation angle of the rotating body.

  In the curve A (solid line) showing the calculated magnetic flux amount waveform when the rotating body is rotated without flowing the magnetic flux through the exciting coil, the magnetic flux amount by the exciting coil is always 0. It can be seen that the amount of magnetic flux has a waveform that changes from −φ to φ.

  In a curve B (dotted line) showing a calculated magnetic flux amount waveform when the rotating body is rotated with a magnetic flux flowing through the exciting coil, the magnetic flux amount φ by the exciting coil is added to the data of the curve A, and the magnetic flux The waveform changes from 0 to 2φ. By exciting the exciting coil in this way, it can be seen that the magnetic flux passing through the first magnetic circuit is shifted with respect to the curve A by the amount of exciting magnetic flux.

  On the other hand, according to the curve C showing the change in the amount of magnetic flux passing through the detection coil core as the second magnetic circuit, even when the excitation coil is excited (curve B), it is not excited ( Even for curve A), curve C has the same value as a result. This is because the magnetic flux of the exciting coil does not flow through the detection coil core, and it is possible to detect a change in the amount of magnetic flux of the rotating body 1 without being affected at all by the excitation of the exciting coil.

  The amount of magnetic flux generated by the exciting coil is likely to change. For example, the amount of magnetic flux generated in the exciting coil can be obtained by changing the pulse duty to reduce the power consumption or load compensation. Will fluctuate. In addition, the amount of magnetic flux of the exciting coil changes due to fluctuations in the power supply voltage value or the like. In any case, the amount of magnetic flux passing through the detection coil core is not affected by them, and only the rotating body 1 is affected. Magnetic flux can be acquired. Therefore, according to this embodiment, an accurate magnetic flux position can be grasped by using a detection waveform that is a counter electromotive voltage waveform.

(Description of relationship between drive pulse and detection waveform: FIG. 11)
Next, the relationship between the drive pulse and the detection waveform will be described. FIG. 11 is a diagram showing the relationship between the drive pulse and the detected waveform, where the horizontal axis indicates time and the vertical axis indicates the voltage value. The upper part of the figure shows the drive pulse supplied to the excitation coil, the lower part shows the detection waveform (counterelectromotive voltage waveform) generated in the detection coil, and the drive pulse 55 is supplied to the excitation coil. Is a period during which rotation is detected using the detection waveform 59 generated in the detection coil. Further, after the excitation period 57, a period in which the drive pulse 55 is not supplied to the excitation coil is set as a pause period 63.

  As shown in FIG. 11, the step motor of this embodiment is provided with the excitation period 57 and the rest period 63 alternately, so that it can rotate at an arbitrary rotation speed. This is the same as the conventional configuration.

  In the step motor of this embodiment, the drive waveform 55 is supplied to the excitation coil, and the detection waveform 59 is detected from the change in magnetic flux caused by the rotation of the rotating body in the excitation period 57 in which the rotating torque is applied to the rotating body. Can be obtained at Therefore, it is possible to set the detection period 61 for performing rotation detection using the detection waveform 59 so as to overlap the excitation period 57. At this time, the detection waveform 59 is a waveform that falls below the zero value (zero crossing) after the detection period 61 ends.

Then, the drive control circuit 33 (see FIG. 3) described above switches the detection-side switching mechanism of the detection coil circuit 37 (see FIG. 3) at an arbitrary interval during the detection period 61, so that the detection coil is used. If a certain number of detection signals (back electromotive signals) are detected during the detection period 61, it is determined that the rotating body is operating. In this manner, by providing the detection period 61 so as to overlap the excitation period 57, it is possible to determine the rotation of the rotating body at an early timing when detected.

  Further, in the case of detecting the position of the rotating body based on the peak value of the detection waveform 59, which is a detection method different from that described above, even immediately before the excitation period 57 shown in FIG. Since the peak value can be detected, the rotation of the rotating body can be confirmed within the excitation period 57. Even in such a case, the position of the rotating body can be reliably grasped at an early timing. And if rotation operation of a rotary body can be confirmed, since control which interrupts supply of a drive pulse can be performed, the reduction in power consumption of the drive power of a motor can be expected.

  In addition, even when the rotation of the rotating body is determined by the detection waveform 59 being zero-crossed, which is another detection method, the rotational position of the rotating body can be grasped at an early timing as described above.

(FIG. 12 is a diagram for explaining the magnetic flux amounts φ1 and φ2 with respect to the magnetic pole tip facing angle difference θ1-θ2).
The angle at the rotation axis that forms the first or third magnetic pole end facing the rotating body is the angle at the magnetic pole end facing angle θ1, and the angle at the rotation axis that forms the second or fourth magnetic pole end facing the rotating body. The magnetic flux φ1 flowing in the first magnetic circuit and the magnetic flux φ2 flowing in the second magnetic circuit with respect to θ1-θ2 when the magnetic pole end facing angle θ2 is set will be described with reference to FIG.

  The horizontal axis of FIG. 12 indicates θ1−θ2 (deg) at the first or third magnetic pole end facing angle θ1 and the second or fourth magnetic pole end facing angle θ2, and the vertical axis indicates the amount of magnetic flux (Wb). When the magnetic flux φ1 flowing through the first magnetic circuit and the magnetic flux amount φ2 flowing through the second magnetic circuit are shown, the magnetic flux amount φ1 flowing through the first magnetic circuit has a relationship of increasing with respect to θ1-θ2. The amount of magnetic flux φ2 flowing through the second magnetic circuit has a decreasing relationship with respect to θ1−θ2. And it turns out that (theta) 1- (theta) 2 becomes (phi) 1> (phi) 2 on the boundary of substantially 0. FIG. Therefore, since θ1 = θ2 in the conventional example, the amount of magnetic flux is point a. However, at point b in the range of θ1−θ2> 0, the amount of magnetic flux φ1 that can be passed through the first magnetic circuit is increased. The amount of magnetic flux can be increased by about 25% at the point b. As a result, the electromechanical coupling coefficient n × φ1 of the first magnetic circuit can be increased, and therefore, the one-step 180 degree rotation operation can be rotated with lower power consumption than the conventional example. Further, if the power consumption is assumed to be the same, rotation driving with high torque becomes possible.

  The change in the magnetic flux amount φ2 flowing through the detection coil core 21 is not affected at all by the excitation magnetic flux generated by the excitation coil, so that dφ / dθ can be accurately obtained even if the magnetic flux amount φ2 of the detection coil core is reduced. Since the back electromotive voltage value generated in the motor can be obtained, the rotation of the rotating body can be determined.

(Drawings explaining the change of the high magnetic resistance portion facing angle θ3: FIGS. 13 and 2)
Next, the relationship between the first magnetic pole end facing angle θ1 and the high magnetic resistance portion facing angle θ3 with respect to θ1−θ2 at the second magnetic pole end facing angle θ2 will be described with reference to FIGS. 13 and 2. In FIG. 13, the horizontal axis represents θ1−θ2 (deg), and the vertical axis represents the angle at the rotation axis that forms the facing portion between the high magnetic resistance portion 23 having a constant width w and the rotating body, and the high magnetic resistance portion facing angle θ3 (deg). It is a graph. From this graph, it can be seen that if θ1-θ2 is increased, θ3 can be reduced. Therefore, by increasing the first magnetic pole end facing angle θ1 and decreasing the second magnetic pole end facing angle θ2, even if a processing error occurs in the high magnetoresistive portion width w, the larger θ1-θ2 is higher. Since the error in the magnetoresistive portion facing angle θ3 can be reduced, the errors can also be reduced in the pole end facing angles θ1 and θ2, and the variation in the amount of magnetic flux φ1 flowing in the first magnetic circuit can be reduced. Thus, stable characteristics can be obtained, and variations in the amount of magnetic flux Φ2 flowing through the second magnetic circuit can be reduced.

  This will be explained with specific numerical values. At the point c in the range of θ1-θ2 <0, when the width w of the high magnetoresistive portion is 100 μm, the facing angle θ3 is 13.43 degrees, and the high magnetoresistive portion When the width w becomes 105 μm due to a processing error, the facing angle θ3 = 14.22 degrees, and the error of θ3 becomes 0.79 degrees. On the other hand, at the point d in the range of θ1−θ2> 0, the opposing angle θ3 = 8.77 degrees can be narrowed with respect to the high magnetoresistive portion width of 100 μm, and the opposing angle θ3 width when the high magnetoresistive portion width is 105 μm. It becomes 9.23 degrees, and the error of θ3 becomes 0.46 degrees. Therefore, even when the processing error of the high magnetic resistance portion is the same, the error of the resistance angle θ3 can be reduced.

  This can be understood qualitatively by the following explanation. Here, it is assumed that there is a straight line having a certain width w for dividing the circle. Considering the case where this straight line passes near the center of the circle and the case where it passes away from the center and touches the circumference, the length of the arc where the straight line and the circle overlap is greater than the former. You can imagine that it is longer. In particular, it can be seen that the length of the overlapping arcs increases exponentially as the straight line approaches the circumference. The length of the arc uniquely corresponds to the angle from the center of the circle, and corresponds to the facing angle θ3 of the high magnetic resistance portion.

  In addition, when looking at the shape of the graph of FIG. 13, the slope of the graph changes greatly around the vicinity where θ1−θ2 = 0, and in the region of θ1−θ2> 0, the region of θ1−θ2 <0. It can be seen that the slope of the graph is gentle. In particular, the tendency becomes even stronger when θ1−θ2 exceeds 50 degrees, and θ3 becomes substantially constant above 100 degrees, and the influence on the opposing angle θ3 due to the processing error of the width w of the high magnetoresistive portion is affected. The smallest. That is, the larger θ1−θ2 can reduce the error of the high magnetoresistive portion facing angle θ3, but the degree of reduction of the error is small at θ1−θ2 = 0, and conversely, θ1−θ2 is small. The increase in the error of θ3 is more remarkable.

In this way, the step motor of this embodiment is
Since the angle θ1 at the rotating shaft that forms the facing portion of the first or third magnetic pole end with the rotating body is larger than the angle θ2 at the rotating shaft that forms the facing portion of the second or fourth magnetic pole end with the rotating body, Since the magnetic flux amount φ1 of the permanent magnet in the first magnetic circuit can be increased and the electromechanical coupling coefficient n × φ1 can be increased, the driving torque “Td = n × φ1 × i × sin θ” is increased. Therefore, if the drive torque Td is maintained, a low current consumption value can be achieved by decreasing the current value i. If the current value i is maintained, the drive torque Td is increased. Thus, high torque characteristics can be obtained.

  Further, the angle θ1 at the rotating shaft that forms the facing portion of the first or third magnetic pole end with the rotating body is larger than the angle θ2 at the rotating shaft that forms the facing portion of the second or fourth magnetic pole end with the rotating body. Therefore, since the angle θ3 in the rotation axis that forms the opposed portion of the high magnetic resistance portion having a constant width w and the rotating body can be reduced, the variation in the angle θ3 can be reduced, that is, the first or first It is possible to reduce variations in the angle θ1 at the rotating shaft that forms the facing portion of the magnetic pole end 3 with the rotating body and the angle θ2 at the rotating shaft that forms the facing portion of the second or fourth magnetic pole end with the rotating body. Thus, the motor can be driven with a stable low current consumption value and high torque, and the magnetic flux amount φ2 of the permanent magnet in the second magnetic circuit can be stabilized. It is possible to stably obtain a rotation detecting counter electromotive voltage waveform due to the detection coil in the circuit, it is possible to achieve accurate rotation detection.

1 Rotating body (rotor)
DESCRIPTION OF SYMBOLS 3 Excitation coil 5 Excitation coil core 7 Rotating body hole 9 1st magnetic pole end 11 2nd magnetic pole end 13 3rd magnetic pole end 15 4th magnetic pole end 17 Excitation yoke 19 Detection coil 21 Detection coil core 23 High magnetic resistance part 25 Rotating shaft 27 Detection yoke 29 Quartz crystal oscillator 31 Pulse synthesis circuit 33 Drive control circuit 35 Rotor drive circuit 37 Detection coil circuit 39 Rotor rotation detection circuit 41a, 41b p-channel MOS
43a, 43b n-channel MOS
45a p-channel MOS
45b p-channel MOS
47 Static stable direction 49 Electromagnetic stable direction 51 Notch 55 Drive pulse 57 Excitation period 59 Detection waveform 61 Detection period 63 Rest period 87 Controller

Claims (1)

A rotating body having a permanent magnet magnetized into two poles in the radial direction and a rotating shaft;
An excitation yoke having a first magnetic pole end and a third magnetic pole end wound around an excitation coil and disposed relative to the rotation axis;
A detection yoke having a second magnetic pole end and a fourth magnetic pole end wound around a detection coil and provided so as to face each other about the rotation axis;
A step motor comprising:
The second and fourth magnetic pole tips are disposed between the first and third magnetic pole tips on the same plane;
The shape of the first to fourth magnetic pole ends is such that the static stable direction in which the rotating body is stationary when no excitation is applied to the exciting coil is compared with the electromagnetic stable direction generated by exciting the exciting coil. , Formed to be orthogonal directions,
Between the first and third magnetic pole ends and the second and fourth magnetic pole ends, a high magnetoresistive portion is provided by a gap or a nonmagnetic member,
The shape of the high magnetoresistive portion is a direction orthogonal to the electromagnetic stability direction, and is substantially with respect to an axis passing through the centers of the second and fourth magnetic pole ends parallel to the static stability direction. It is formed to be a symmetrical plane,
The angle θ1 of the rotating shaft that forms the facing portion of the first or third magnetic pole end with the rotating body is the angle θ1 of the rotating shaft that forms the facing portion of the second or fourth magnetic pole end with the rotating body. Greater than the angle θ2,
Step motor characterized by that.

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