JP6481715B2 - Stepping motor - Google Patents

Description

  The present invention relates to a stepping motor.

2. Description of the Related Art Conventionally, a stepping motor that includes two coils and is configured to be capable of forward and reverse rotation by appropriately applying drive pulses to the coils is known.
For example, Patent Document 1 discloses a stepping motor including a rotor having two poles and a stator having two main magnetic poles and one sub magnetic pole.

Japanese Patent No. 5-006440

  However, a stepping motor having such a two-pole magnetized rotor generally rotates the rotor in 180 degree steps, so that, for example, the stepping motor is used as a drive source for a hand movement mechanism that moves a clock pointer. Cannot reduce the needle movement angle of the pointer unless it is greatly decelerated using a reduction gear (gear). That is, for example, when the rotor rotates in 180 degree steps, a 1/180 speed reduction is required to move the pointer in 1 degree steps.

However, when decelerating greatly in this way, it is necessary to provide a large number of gears (gears) for adjusting (decelerating) in a functional unit driven by a stepping motor such as a hand movement mechanism.
For this reason, there are problems that the cost of a device in which a stepping motor is incorporated increases due to an increase in the number of gears, and that the product size increases in order to secure a space for incorporating many gears.
Further, when the number of gears is increased, backlash is accumulated accordingly, and there is a problem that the accuracy of the functional unit driven by the stepping motor is deteriorated, for example, the accuracy of the hand movement angle is lowered.

  Therefore, it is desirable to rotate the rotor at a small rotation angle, such as 60 degrees, but for that purpose, the rotor is accurately stopped at a predetermined rotation angle within an arbitrary voltage range, or the rotor does not rotate due to an impact. In order to achieve this, it is necessary to generate an index torque (holding torque) of an appropriate magnitude.

In this regard, a method of reducing the rotation angle by using a multi-pole magnetized rotor is also conceivable.
With such a configuration, it is possible to accurately achieve rotation at a small rotation angle. For this reason, even when a stepping motor is used to move the hands of a watch that requires fine movement, it is not necessary to decelerate using many gears in order to reduce the rotation angle.

However, in order to form a multipolar magnetized rotor, there is a problem that a complicated and expensive mold and magnetizer are required as compared with dipolar magnetisation.
Further, when a stepping motor is used as a power source of a small device such as a wristwatch, it is necessary to make the rotor extremely small, but it is very difficult to form a small multipolar magnetized rotor.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a stepping motor capable of accurately maintaining a step every 60 degrees by a configuration that can be easily formed. is there.

In order to solve the above-described problem, a stepping motor according to the present invention includes:
A circular rotor magnetized in two radial directions and having a stationary part ;
A stator body having a first magnetic pole, a second magnetic pole, and a third magnetic pole, a symmetrical position across the vertices of the first magnetic pole, the second magnetic pole, and the third magnetic pole, and with the rotation of the rotor A stationary part disposed at a position facing the stationary part of the rotor, and a stator,
Equipped with a,
The stationary portion of the rotor is disposed at a target position sandwiching the apex of each magnetic pole of the rotor, and has a shape recessed inward from the outer peripheral shape of the rotor,
The stationary portion of the stator has a shape recessed inward from the outer peripheral shape of the stator adjacent to the rotor .

  According to the present invention, a rotor with two poles can be rotated by 60 degrees, and the stationary state of the rotor is reliably maintained for every 60 degrees of rotation by providing a stator side stationary part and a rotor side stationary part. Can be made. For this reason, there exists an effect that the step of every 60 degrees can be correctly maintained by the structure which can be formed easily.

It is a top view of the stepping motor in a 1st embodiment. It is a top view of the stator main body of the stepping motor shown in FIG. FIG. 3 is a plan view of a first coil block and a second coil block of the stepping motor shown in FIG. 1. It is a principal part block diagram which shows the mechanism which applies a drive pulse to the 1st coil and 2nd coil of the stepping motor shown in FIG. It is a graph which shows the index torque at the time of providing a recessed part in a rotor magnet, and when not providing a recessed part. It is the figure which showed typically the flow of the magnetic flux in the case of rotating forward the stepping motor shown in FIG. 1, (a) shows the state in which a rotor exists in an initial position, (b) shows the rotor rotating 60 degree | times. (C) shows a state where the rotor has rotated 120 degrees, and (d) shows a state where the rotor has rotated 180 degrees. It is the figure which showed typically the flow of the magnetic flux in the case of reversing the stepping motor shown in FIG. 1, (a) shows the state in which a rotor exists in an initial position, (b) shows a rotor rotating -60 degree | times. (C) shows a state where the rotor has rotated -120 degrees, and (d) shows a state where the rotor has rotated -180 degrees. It is a top view of the stepping motor in a 2nd embodiment. It is the figure which showed typically the flow of the magnetic flux in the case of making the stepping motor shown in FIG. 8 forward, (a) shows the state in which a rotor is in an initial position, (b) shows the rotor rotating 60 degree | times. (C) shows a state where the rotor has rotated 120 degrees, and (d) shows a state where the rotor has rotated 180 degrees. FIG. 9 is a diagram schematically showing the flow of magnetic flux when the stepping motor shown in FIG. 8 is reversed, where (a) shows a state in which the rotor is in an initial position, and (b) shows that the rotor is rotated by −60 degrees. (C) shows a state where the rotor has rotated -120 degrees, and (d) shows a state where the rotor has rotated -180 degrees. It is a top view of the stepping motor in a 3rd embodiment. FIG. 12 is a diagram schematically illustrating the flow of magnetic flux when the stepping motor illustrated in FIG. 11 is rotated forward, in which (a) illustrates a state in which the rotor is in an initial position, and (b) illustrates rotation of the rotor by 60 degrees. (C) shows a state where the rotor has rotated 120 degrees, and (d) shows a state where the rotor has rotated 180 degrees. FIG. 12 is a diagram schematically showing the flow of magnetic flux when the stepping motor shown in FIG. 11 is reversed, where (a) shows a state where the rotor is at an initial position, and (b) shows that the rotor rotates by −60 degrees. (C) shows a state where the rotor has rotated -120 degrees, and (d) shows a state where the rotor has rotated -180 degrees. It is a top view which shows the modification of the stepping motor from which the shape of a rotor magnet differs.

[First Embodiment]
Hereinafter, a first embodiment of a stepping motor according to the present invention will be described with reference to FIGS. The stepping motor according to the present embodiment is a small motor that is applied to drive a hand movement mechanism, a date mechanism, or the like that operates a wristwatch of a wristwatch, for example, but an embodiment to which the stepping motor according to the present invention can be applied is It is not limited to this.

FIG. 1 is a plan view of a stepping motor in the present embodiment.
As shown in FIG. 1, the stepping motor 100 includes a stator (Stator) 1 and a rotor (Rotor) 5.

In the present embodiment, the stator 1 includes a stator body 10 and two coil blocks 20 (a first coil block 20a and a second coil block 20b). In the following description, the simple term “coil block 20” includes the first coil block 20a and the second coil block 20b.
As will be described later, one end of the first coil block 20a is magnetically coupled to a center yoke 11 (described later) of the stator body 10, and the other end is magnetically connected to a side yoke 12a (described later) of the stator body 10. It is connected to.
Similarly, the second coil block 20b has one end side magnetically coupled to a center yoke 11 (described later) of the stator body 10, and the other end side magnetically coupled to a side yoke 12b (described later) of the stator body 10. Has been.

FIG. 2 is a plan view of the stator body 10 of the stepping motor 100 shown in FIG.
In the present embodiment, the stator body 10 is formed of a high magnetic permeability material such as permalloy, for example.
The stator main body 10 includes a center yoke 11 having a straight portion 11a and a projecting portion 11b projecting substantially symmetrically on one end side of the straight portion 11a. The center yoke 11 is substantially T-shaped. It consists of a pair of side yokes 12 (12a, 12b) provided substantially symmetrically on the other end side of the shaped part, and the outer shape is substantially bowl-shaped.

A stator side connecting portion 13 (13a) for connecting with the coil block 20 (first coil block 20a, second coil block 20b) on the free end side of the overhanging portion 11b of the center yoke 11 and the side yokes 12a, 12b. , 13b, 13c, 13d).
In the present embodiment, the stator body 10 and the coil block 20 are connected by being screwed and fixed, and the stator side connecting portion 13 (13a, 13b, 13c, 13d) is connected to the stator body 10 and the coil. It is a screw hole for screwing the block 20.
In addition, the connection method of the stator main body 10, the first coil block 20a, and the second coil block 20b may be any as long as the stator main body 10, the first coil block 20a, and the second coil block 20b can be magnetically connected. It is not limited to screwing. For example, the stator side connecting portion 13 (stator side connecting portions 13a, 13b, 13c, 13d) and a coil side connecting portion 23 (coil side connecting portions 23a, 23b, 23c, 23d) to be described later may be fixed by welding. May be.

  The stator body 10 is formed with a rotor receiving portion 14 which is a substantially circular hole portion and receives the rotor 5 at the intersection of the center yoke 11 and the side yokes 12a and 12b.

In addition, the stator body 10 has a first magnetic pole 15a, a second magnetic pole 15b, and a second magnetic pole 15b at positions where the outer periphery is divided into three along the outer periphery of the rotor magnet 50 of the rotor 5 received by the rotor receiving portion 14 in the excited state. Three magnetic poles 15 of the third magnetic pole 15c are respectively arranged. In the present embodiment, the first magnetic pole 15 a, the second magnetic pole 15 b, and the third magnetic pole 15 c appear uniformly every 120 degrees along the outer periphery of the rotor magnet 50, and around the rotor receiving portion 14. The magnetic pole 15 appearing on the center yoke 11 side is the first magnetic pole 15a, and the magnetic pole 15 appearing on the side yoke 12a side around the rotor receiving portion 14 is the second magnetic pole 15b, around the rotor receiving portion 14 and side yoke. The magnetic pole 15 appearing on the 12b side is referred to as a third magnetic pole 15c.
As described above, in the present embodiment, the three magnetic poles 15 of the first magnetic pole 15a, the second magnetic pole 15b, and the third magnetic pole 15c are arranged uniformly every 120 degrees along the outer periphery of the rotor magnet 50. A position where the magnetic flux generated from the rotor magnet 50 stably turns around the magnetic pole 15 in a non-energized state where the coil 22 is not energized (that is, either the S pole or the N pole of the rotor magnet 50 is one of the stator main body 10). (Position facing the magnetic pole 15) uniformly appears every 60 degrees. For this reason, the detent torque (static torque) of the rotor 5 becomes large at each 60 degrees.

As described above, one end side of the first coil block 20 a is magnetically connected to the center yoke 11 of the stator body 10, and the other end side is magnetically connected to the side yoke 12 a of the stator body 10. The second coil block 20 b is magnetically connected at one end side to the center yoke 11 of the stator body 10 and magnetically connected at the other end side to the side yoke 12 b of the stator body 10.
Accordingly, in the present embodiment, a magnetic pulse is generated from the coil 22 by applying a driving pulse from the driving pulse supply circuit 31 described later to the coils 22 (the first coil 22a and the second coil 22b) of the two coil blocks 20. When this occurs, the magnetic flux flows along the magnetic core 21 of the coil block 20 and the stator body 10 that is magnetically coupled thereto, and the three magnetic poles 15 (first magnetic pole 15a, second magnetic pole 15b, and third magnetic pole 15c). The polarity (S pole / N pole) is appropriately switched.

Further, the stator 1 is formed with a first recess (that is, notch) 16. The first concave portion 16 is a stator side stationary portion that maintains the stationary state of the rotor 5.
The stator side stationary portion is in each of the magnetic poles 15 (first magnetic pole 15a, second magnetic pole 15b, and third magnetic pole 15c) appearing on the three yokes of the stator body 10 (that is, the center yoke 11, the side yoke 12a, and the side yoke 12b). A second position which is at least one of the vertices of the magnetic poles on the side facing the rotor magnet 50 and symmetrical positions across the vertices of the respective magnetic poles and which is the rotor-side stationary portion of the rotor 5 as the rotor 5 rotates. Is disposed at a position facing the recess 52 (52a, 52b).
In the present embodiment, the three magnetic poles 15 (the first magnetic pole 15a, the second magnetic pole 15b, and the third magnetic pole 15c) are provided on the inner peripheral surface of the rotor receiving portion 14 at intervals of approximately 120 degrees periodically at three intervals. The 1st recessed part 16 (1st recessed part 16a, 16b, 16c) is provided.

FIG. 3 is a plan view of the first coil block 20a and the second coil block 20b of the stepping motor 100 shown in FIG.
Each of the two coil blocks 20 (first coil block 20a and second coil block 20b) is formed by winding a magnetic core 21 using a high magnetic permeability material such as permalloy and a conductive wire around the magnetic core 21. Coil 22 (first coil 22a, second coil 22b). In the present embodiment, the first coil 22a and the second coil 22b have the same wire diameter, number of windings, and winding direction. In the following description, the simple term “coil 22” includes the first coil 22a and the second coil 22b.

At one end of the magnetic core 21 of the first coil block 20a, a coil side connecting portion 23 (23a) for connecting to the stator side connecting portion 13 (13a) of the center yoke 11 of the stator body 10 is provided. The other end of the magnetic core 21 of the first coil block 20a is provided with a coil side connecting portion 23 (23b) for connecting to the stator side connecting portion 13 (13b) of the side yoke 12a of the stator body 10. ing.
Similarly, a coil side coupling portion 23 (23c) for coupling to the stator side coupling portion 13 (13c) of the center yoke 11 of the stator body 10 is provided at one end of the magnetic core 21 of the second coil block 20b. ing. Further, the other end portion of the magnetic core 21 of the second coil block 20b is provided with a coil side connecting portion 23 (23d) for connecting to the stator side connecting portion 13 (13d) of the side yoke 12b of the stator body 10. ing.
As described above, in the present embodiment, the stator body 10 and the coil block 20 are connected by being screwed and fixed, and the coil side connecting portion 23 (23a, 23b, 23c, 23d) It is a screw hole for screwing the stator body 10 and the coil block 20 together.
The stator side connecting portion 13 (13a) and the coil side connecting portion 23 (23a) are connected to form a fixed portion 30a, and the stator side connecting portion 13 (13b) and the coil side connecting portion 23 (23b) are connected. The fixed portion 30b is configured, the stator side connecting portion 13 (13c) and the coil side connecting portion 23 (23c) are connected to form the fixed portion 30c, and the stator side connecting portion 13 (13d) and the coil side connecting portion 23 ( 23d) is connected to form a fixed portion 30d.
The stepping motor 100 is illustrated by a screw (not shown) that connects the coil side connecting portion 23 (23a, 23b, 23c, 23d) and the stator side connecting portion 13 (13a, 13b, 13c, 13d). It may be fixed in the apparatus or on the substrate.

A pair of substrates 17 and 18 are superimposed on the overhanging portion 11b of the center yoke 11 to which the coil side connecting portions 23a and 23c are connected. The substrates 17 and 18 are fixed on the stator 1 by screws that fix the stator body 10 and the two coil blocks 20. Note that the substrate may be connected to one another without being divided into two.
On the substrate 17, the first coil terminal 171 and the second coil terminal 172 of the first coil block 20a are mounted. The conducting wire end 24 of the first coil 22a is connected to the first coil terminal 171 and the second coil terminal 172 on the substrate 17, respectively. The first coil 22a is connected to the first coil terminal 171 and the first coil terminal 171. As shown in FIG. 4, it is connected to the drive pulse supply circuit 31 via two coil terminals 172.
Similarly, the first coil terminal 181 and the second coil terminal 182 of the second coil block 20 b are mounted on the substrate 18. The conducting wire end 24 of the first coil 22b is connected to the first coil terminal 181 and the second coil terminal 182 on the substrate 18, respectively. The second coil 22b is connected to the first coil terminal 181 and the second coil terminal 182. As shown in FIG. 4, it is connected to the drive pulse supply circuit 31 via two coil terminals 182.

The drive pulse supply circuit 31 applies drive pulses individually to the first coil 22a and the second coil 22b to rotate the rotor 5 by 60 degrees.
In the present embodiment, three first concave portions 16 (first concave portions 16a, 16b, 16c; stator side stationary portions) are provided on the inner peripheral surface of the rotor receiving portion 14 of the stator 1 approximately every 120 degrees, and the rotor 5 stops at a position where one of the two second recesses 52 (52a, 52b; rotor-side stationary portion) provided on the outer peripheral surface of the rotor magnet 50 faces one of the first recesses 16. By doing so, a step of 60 degrees can be engraved.
Specifically, the drive pulse supply circuit 31 has a position where any one of the second recesses 52 (52a, 52b) faces any one of the first recesses 16 (first recesses 16a, 16b, 16c). A driving pulse is appropriately applied to the coil 22 (the first coil 22a and the second coil 22b) so that the rotor 5 is stationary.

In the present embodiment, the drive pulse supply circuit 31 includes three magnetic poles 15 (first magnetic pole 15a, second magnetic pole 15b, and third magnetic pole 15) alternately for each step. A drive pulse is applied to the coil 22 (the first coil 22a and the second coil 22b) so as to face one of the magnetic poles 15c), and the polarities of the first magnetic pole 15a, the second magnetic pole 15b, and the third magnetic pole 15c are changed. It is supposed to switch.
That is, for example, when the rotor 5 is rotated in the forward rotation direction (that is, clockwise), the first magnetic pole 15a facing the S pole of the rotor magnet 50 becomes the N pole, and the second magnetic pole 15b and the third magnetic pole 15c. Is the S pole (the state shown in FIG. 6A), the drive pulse supply circuit 31 applies a drive pulse to the coil 22 so that the second magnetic pole 15b becomes the N pole. . When the second magnetic pole 15b becomes an N pole, the N pole of the rotor magnet 50 repels the second magnetic pole 15b and is attracted to the third magnetic pole 15c. As a result, the rotor 5 rotates 60 degrees, and the S pole of the third magnetic pole 15c and the N pole of the rotor magnet 50 are opposed to each other (the state shown in FIG. 6B). Further, the drive pulse supply circuit 31 applies a drive pulse to the coil 22 so that the first magnetic pole 15a becomes the S pole. When the first magnetic pole 15a becomes the S pole, the S pole of the rotor magnet 50 repels the first magnetic pole 15a and is attracted to the second magnetic pole 15b. As a result, the rotor 5 further rotates 60 degrees, and the N pole of the second magnetic pole 15b and the S pole of the rotor magnet 50 are opposed to each other (the state shown in FIG. 6C). Thus, the drive pulse supply circuit 31 causes the N pole and the S pole of the rotor magnet 50 to alternately oppose any one of the magnetic poles 15 (the first magnetic pole 15a, the second magnetic pole 15b, and the third magnetic pole 15c). The polarity of the magnetic pole 15 is switched.
The rotor 5 rotates by 60 degrees. However, it is possible to rotate the rotor 5 by 120 degrees, 180 degrees, 240 degrees, 300 degrees, and 360 degrees by continuously applying driving pulses. is there.

  The substrates 17 and 18 include, for example, a drive pulse supply circuit 31 that applies a drive pulse to each coil block 20 (the first coil block 20a and the second coil block 20b), a circuit related to the control of the stepping motor 100, and the like. May be mounted, or a circuit board on which the drive pulse supply circuit 31 and the like are mounted may be provided separately from the boards 17 and 18.

The rotor 5 is obtained by attaching a rotor magnet 50 magnetized in two radial directions to a rotating spindle 51. In the present embodiment, the rotor magnet 50 is formed in a disk shape, and the rotation support shaft 51 is attached to the center of the circle of the rotor magnet 50.
As the rotor magnet 50, for example, a permanent magnet such as a rare earth magnet (for example, a samarium cobalt magnet) is preferably used, but the type of magnet applicable as the rotor magnet 50 is not limited thereto.
The rotor 5 is received by the rotor receiving portion 14 of the stator body 10 and is disposed so as to be rotatable about the rotation support shaft 51. In the present embodiment, the rotor 5 switches the drive pulse applied by the drive pulse supply circuit 31 to change the forward direction (that is, clockwise direction) and the reverse direction (that is, counterclockwise direction) within the rotor receiving portion 14. The direction can be rotated in either direction.
For example, a gear or the like (not shown) constituting a train wheel mechanism for moving the hands of a watch is connected to the rotation support shaft 51, and this gear is rotated when the rotor 5 rotates. ing.

In the present embodiment, the rotor magnet 50 has a first outer peripheral surface and each magnetic pole (S pole and N pole) at substantially the center in the circumferential direction of the rotor magnet 50 (that is, the apex of each magnetic pole). Two recesses (that is, notches) 52 (second recesses 52a and 52b) are formed.
The second recess 52 is a rotor-side stationary portion that maintains the stationary state of the rotor 5.
In the present embodiment, any one of the second recesses 52 (second recesses 52a, 52b) is opposed to any one of the first recesses 16 (first recesses 16a, 16b, 16c) on the stator 1 side. When the rotor 5 is disposed at the position, a large index torque (holding torque) is applied, and the rotor 5 is maintained in a stopped state at the position.

  That is, the opening part of the second recess 52 in the rotor magnet 50 and the opening part of the first recess 16 on the stator 1 side are areas where the magnetic attractive force is weak, and the second recess 52 (second 2 recesses 52a, 52b) and the position of the first recess 16 (first recesses 16a, 16b, 16c) on the stator 1 side do not match the opening of the second recess 52 Since the magnetic attractive force is weakened in each of the opening portions of the first recess 16, the region where the magnetic attractive force is weak becomes wider, and the loss of the magnetic attractive force is increased accordingly. In contrast, the position of the second recess 52 (second recesses 52a, 52b) of the rotor magnet 50 and the position of the first recess 16 (first recesses 16a, 16b, 16c) on the stator 1 side are determined. When they are coincident (opposed), the loss of magnetic attraction is small, and the strength of the magnetic attraction is increased around the rotation angle at which the second recess 52 and the first recess 16 coincide. Since it changes greatly, the peak of index torque (holding torque) becomes large.

FIG. 5 shows the index torque (holding torque) when the first recess 16 (notch) is provided on the stator 1 side and the second recess 52 (notch) is provided on the rotor magnet 50, and the recess ( It is a graph which shows the index torque (holding torque) in the case of the conventional structure which provided the notch and the recessed part (notch) was not provided in the rotor magnet.
In FIG. 5, the index torque (holding torque) in the case of the configuration of the present embodiment in which the rotor magnet 50 is provided with the second recess 52 is indicated by a solid line and a black square, and the rotor magnet is not provided with a recess. The index torque (holding torque) in the case of this configuration is indicated by a solid line and white square points.
As shown in FIG. 5, when the rotor magnet is not provided with a recess (notch), the index torque value fluctuates, but only a weak index torque that is insufficient to make the rotor 5 stationary is generated. Absent. On the other hand, when the rotor magnet 50 is provided with the second recess (notch) 52, the peak of the index torque (holding torque) appears greatly. Thereby, when any of the second recesses 52 (second recesses 52a, 52b) is disposed at a position facing any of the first recesses 16 (first recesses 16a, 16b, 16c), The rotor 5 can be stably stopped at the position and maintained in a stationary state.

Next, the operation of the stepping motor 100 in this embodiment will be described with reference to FIGS.
6 and 7, solid arrows indicate the direction of magnetic flux generated from the coil 22, and broken arrows indicate the flow of magnetic flux flowing through the stator 1.

First, the case where the rotor 5 is normally rotated (that is, rotated in the clockwise direction) will be described with reference to FIGS. 6 (a) to 6 (d).
FIG. 6A shows a case where the position where the S pole of the rotor magnet 50 is closest to the first magnetic pole 15a is the initial position. In a non-energized state in which no coil 22 is energized, the first magnetic pole 15a facing the south pole of the rotor magnet 50 becomes the north pole, and the second magnetic pole 15b and the third magnetic pole facing the north pole of the rotor magnet 50 15c becomes the south pole. At this time, the magnetic flux flows from the rotor magnet 50 into the center yoke 11 of the stator body 10 along the magnetic cores 21 of the first coil block 20a and the second coil block 20b, as indicated by broken line arrows in FIG. It flows toward the rotor magnet 50.

Here, first, a drive pulse is applied from the drive pulse supply circuit 31 to the second coil 22b so that the second magnetic pole 15b becomes N pole. Thereby, as shown in FIG. 6B, a magnetic flux in the direction of the solid line arrow is generated from the second coil 22b, and from the magnetic core 21 of the second coil block 20b to the center yoke 11 of the stator body 10 as shown by the broken line arrow. The magnetic flux that flows is divided into the magnetic flux that flows from the magnetic core 21 of the second coil block 20 b to the magnetic core 21 of the first coil block 20 a and flows toward the rotor magnet 50. As a result, the third magnetic pole 15c becomes the S pole, the other two magnetic poles (the first magnetic pole 15a and the second magnetic pole 15b) become the N pole, and the N pole of the rotor magnet 50 is attracted in the direction of the third magnetic pole 15c. The rotor magnet 50 rotates 60 degrees clockwise.
The position rotated by 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably rotates around the magnetic pole 15 (that is, the position where the N pole of the rotor magnet 50 faces the third magnetic pole 15c). In this embodiment, since the second recess 52b provided at the apex of the N pole of the rotor magnet 50 faces the first recess 16c provided at the apex of the third magnetic pole 15c of the stator 1 at this position, the index torque Even after the (holding torque) is increased and the application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 is stably stopped at the position while maintaining the rotation angle.

Next, a drive pulse is applied from the drive pulse supply circuit 31 to the first coil 22a so that the first magnetic pole 15a becomes the S pole. Thereby, as shown in FIG.6 (c), the magnetic flux of a solid line arrow direction generate | occur | produces from the 1st coil 22a, and the magnetic flux which flows along the magnetic core 21 of the 2nd coil block 20b from the rotor magnet 50 as shown by a broken line arrow. And the flow of magnetic flux flowing along the center yoke 11 of the stator body 10 are generated. As a result, the second magnetic pole 15b becomes the N pole, the other two magnetic poles (the first magnetic pole 15a and the third magnetic pole 15c) become the S pole, and the S pole of the rotor magnet 50 is attracted in the direction of the second magnetic pole 15b. Then, the rotor 5 further rotates 60 degrees clockwise (that is, 120 degrees from the initial position).
The position rotated 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably turns around the magnetic pole 15 (that is, the position where the S pole of the rotor magnet 50 faces the second magnetic pole 15b). In this embodiment, since the second recess 52a provided at the apex of the S pole of the rotor magnet 50 is opposed to the first recess 16b provided at the apex of the second magnetic pole 15b of the stator 1 at this position, the index torque Even after the (holding torque) is increased and the application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 is stably stopped at the position while maintaining the rotation angle.

Further, a drive pulse is applied from the drive pulse supply circuit 31 to the first coil 22a and the second coil 22b so that the third magnetic pole 15c becomes N pole. As a result, as shown in FIG. 6D, a magnetic flux in the direction of the solid line arrow is generated from the first coil 22a and the second coil 22b, and from the rotor magnet 50 to the center yoke 11 of the stator body 10 as shown by the broken line arrow. A flow of magnetic flux flowing along is generated. As a result, the first magnetic pole 15a becomes the S pole, the other two magnetic poles (the second magnetic pole 15b and the third magnetic pole 15c) become the N pole, and the N pole of the rotor magnet 50 is attracted in the direction of the first magnetic pole 15a. The rotor 5 is further rotated 60 degrees clockwise (that is, 180 degrees from the initial position).
The position rotated by 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably rotates around the magnetic pole 15 (that is, the position where the N pole of the rotor magnet 50 faces the first magnetic pole 15a). In this embodiment, since the second recess 52b provided at the apex of the N pole of the rotor magnet 50 faces the first recess 16a provided at the apex of the first magnetic pole 15a of the stator 1 at this position, the index torque Even after the (holding torque) is increased and the application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 is stably stopped at the position while maintaining the rotation angle.

  Through the above three steps, the rotor 5 rotates clockwise by 60 degrees three times, and is in a state rotated 180 degrees from the initial position. By further rotating 180 degrees by the same method, the rotor 5 rotates 360 degrees and returns to the initial position again.

Next, the case where the rotor 5 is reversely rotated (that is, rotated in the counterclockwise direction) will be described with reference to FIGS. 7 (a) to 7 (d).
FIG. 7A shows a case where the position where the S pole of the rotor magnet 50 is closest to the first magnetic pole 15a is the initial position. In a non-energized state in which no coil 22 is energized, the first magnetic pole 15a facing the south pole of the rotor magnet 50 becomes the north pole, and the second magnetic pole 15b and the third magnetic pole facing the north pole of the rotor magnet 50 15c becomes the south pole. At this time, the magnetic flux flows from the rotor magnet 50 into the center yoke 11 of the stator body 10 along the magnetic cores 21 of the first coil block 20a and the second coil block 20b, as indicated by broken line arrows in FIG. It flows toward the rotor magnet 50.

Here, first, a drive pulse is applied from the drive pulse supply circuit 31 to the first coil 22a so that the third magnetic pole 15c becomes N pole. Thereby, as shown in FIG. 7B, a magnetic flux in the direction of the solid line arrow is generated from the first coil 22a, and from the magnetic core 21 of the first coil block 20a to the center yoke 11 of the stator body 10 as shown by the broken line arrow. The magnetic flux that flows is divided into the magnetic flux that flows from the magnetic core 21 of the first coil block 20 a to the magnetic core 21 of the second coil block 20 b and flows toward the rotor magnet 50. As a result, the second magnetic pole 15b becomes the S pole, the other two magnetic poles (the first magnetic pole 15a and the third magnetic pole 15c) become the N pole, and the N pole of the rotor magnet 50 is attracted in the direction of the second magnetic pole 15b. The rotor 5 rotates 60 degrees (−60 degrees) counterclockwise.
The position rotated 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably turns around the magnetic pole 15 (that is, a position where the N pole of the rotor magnet 50 faces the second magnetic pole 15b). In this embodiment, since the second recess 52b provided at the apex of the N pole of the rotor magnet 50 faces the first recess 16b provided at the apex of the second magnetic pole 15b of the stator 1 at this position, the index torque Even after the (holding torque) is increased and the application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 is stably stopped at the position while maintaining the rotation angle.

Next, a drive pulse is applied from the drive pulse supply circuit 31 to the second coil 22b so that the first magnetic pole 15a becomes the S pole. Thereby, as shown in FIG.7 (c), the magnetic flux of a solid line arrow direction generate | occur | produces from the 2nd coil 22b, and the magnetic flux which flows along the magnetic core 21 of the 1st coil block 20a from the rotor magnet 50 as shown by a broken line arrow. And the flow of magnetic flux flowing along the center yoke 11 of the stator body 10 are generated. As a result, the third magnetic pole 15c becomes the N pole, the other two magnetic poles (the first magnetic pole 15a and the second magnetic pole 15b) become the S pole, and the S pole of the rotor magnet 50 is attracted in the direction of the third magnetic pole 15c. Then, the rotor 5 further rotates 60 degrees counterclockwise (−60 degrees, that is, −120 degrees from the initial position).
The position rotated 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably moves around the magnetic pole 15 (that is, the position where the S pole of the rotor magnet 50 faces the third magnetic pole 15c). In this embodiment, since the second recess 52a provided at the apex of the S pole of the rotor magnet 50 faces the first recess 16c provided at the apex of the third magnetic pole 15c of the stator 1 at this position, the index torque Even after the (holding torque) is increased and the application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 is stably stopped at the position while maintaining the rotation angle.

Further, a drive pulse is applied from the drive pulse supply circuit 31 to the first coil 22a and the second coil 22b so that the second magnetic pole 15b becomes the N pole. As a result, as shown in FIG. 7D, a magnetic flux in the direction of the solid arrow is generated from the first coil 22a and the second coil 22b, and from the rotor magnet 50 to the center yoke 11 of the stator body 10 as shown by the broken arrow. A flow of magnetic flux flowing along is generated. As a result, the first magnetic pole 15a becomes the S pole, the other two magnetic poles (the second magnetic pole 15b and the third magnetic pole 15c) become the N pole, and the N pole of the rotor magnet 50 is attracted in the direction of the first magnetic pole 15a. Then, the rotor 5 further rotates 60 degrees counterclockwise (−60 degrees, that is, −180 degrees from the initial position).
The position rotated by 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably rotates around the magnetic pole 15 (that is, the position where the N pole of the rotor magnet 50 faces the first magnetic pole 15a). In this embodiment, since the second recess 52b provided at the apex of the N pole of the rotor magnet 50 faces the first recess 16a provided at the apex of the first magnetic pole 15a of the stator 1 at this position, the index torque Even after the (holding torque) is increased and the application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 is stably stopped at the position while maintaining the rotation angle.

  Through the above three steps, the rotor 5 rotates counterclockwise three times by -60 degrees and is rotated by -180 degrees from the initial position. By further rotating −180 degrees by the same method, the rotor 5 rotates 360 degrees and returns to the initial position again.

As described above, according to the present embodiment, the three magnetic poles of the first magnetic pole 15 a, the second magnetic pole 15 b, and the third magnetic pole 15 c are disposed around the rotor receiving portion 14 that receives the rotor 5 along the outer periphery of the rotor 5. The first magnetic pole 15a, the second magnetic pole 15b, and the third magnetic pole are arranged uniformly at intervals of approximately 120 degrees, and second concave portions 52a and 52b are formed as rotor-side stationary portions at the apexes of the magnetic poles of the rotor magnet 50. The first stator-side stationary portion is located at the apex of the magnetic pole on the side facing the rotor magnet 50 in 15c and facing either of the second recesses 52a, 52b of the rotor magnet 50 as the rotor 5 rotates. Recesses 16a, 16b, and 16c are formed. And with respect to the first coil 22a and the second coil 22b, the rotor 5 is stopped at a position where any of the second recesses 52a, 52b faces any of the first recesses 16a, 16b, 16c. The drive pulse is individually applied from the drive pulse supply circuit 31 to rotate the rotor 5.
As a result, a position where the magnetic flux generated from the rotor magnet 50 stably turns around the magnetic pole 15 in a state where the coil 22 is not energized (that is, either the S pole or the N pole of the rotor magnet 50 is the position of the stator body 10). The position facing the magnetic pole 15 appears uniformly every 60 degrees. For this reason, the detent torque (static torque) of the rotor 5 becomes large at each 60 degrees.
In addition, when the first recesses 16a, 16b, and 16c as the stator side stationary portions and the second recesses 52a and 52b as the rotor side stationary portions face each other, the index torque (holding torque) becomes large. At the time of de-energization to 22, the rotor 5 is surely stopped at the position of every 60 degrees. Thus, since the rotor 5 can be accurately rotated with 60 degrees as one unit (one step), it is possible to finely control the rotation angle.
For example, when the stepping motor 100 is used as a driving source of a hand movement mechanism for moving the hands of a timepiece or the like, and the rotor 5 rotates in 180 degree steps, the hands of the hands need to be decelerated without using a gear (gear). The angle cannot be reduced. That is, for example, when the rotor 5 rotates in 180 degree steps, a 1/180 speed reduction is required to move the pointer in one degree steps. On the other hand, when the rotor 5 can be rotated by 60 degrees as a unit as in the present embodiment, for example, it is sufficient to perform 1/60 deceleration in order to move the pointer in one step. It is possible to realize a fine hand movement angle or the like without using a large number of gears (gears) to decelerate greatly. In general, in order to move a second hand moving in a step of 6 degrees in a step of 2 degrees, a gear (gear) for decelerating 3 times is required, but if the stepping motor 100 in the present embodiment is used, Since it is possible to convert to a step twice without providing a gear (gear) for speed control, it is difficult for the hands to move, and the hands can be moved smoothly.
Thus, in this embodiment, since the number of parts, such as a gear (gear) for decelerating, can be reduced, the apparatus cost can be suppressed. Further, since the number of parts such as gears (gears) can be reduced, the space in the apparatus in which the stepping motor 100 is incorporated can be used efficiently, and the apparatus in which the stepping motor 100 is incorporated can be reduced in size and thickness. it can. Further, since the number of mechanical parts such as gears (gears) constituting the speed control mechanism connected to the stepping motor 100 can be reduced as described above, the accumulation of backlash can be reduced, and the stepping motor 100 is driven. The accuracy of the hand movement mechanism and the like can be improved.
In a stepping motor capable of forward and reverse rotation, when the rotor 5 is rotated 180 degrees by one set of driving pulses, for example, three stages of driving pulses are applied according to the rotation angle of the rotor 5. In this case, since the rotation angle of the rotor 5 is not necessarily stabilized at each stage, it is difficult to synchronize the rotation angle of the rotor 5 and the drive pulse, and it is difficult to efficiently rotate the rotor 5. In this regard, in the present embodiment, the rotor 5 can be efficiently rotated by the magnetic flux emitted from the magnetic pole 15 where the rotor 5 stably stops at a position of every 60 degrees.
In addition, after the rotor 5 is rotated by applying a drive pulse to the coil 22, when the rotor 5 is stationary at each step of 60 degrees, the rotor 5 is stably stationary at the position in the non-energized state. For this reason, it is possible to shift to the next step in a short time, and the rotor 5 can be stably rotated at a high speed.
Further, since the stator side stationary part and the rotor side stationary part that maintain the stationary state for each unit rotation of the rotor 5 that can rotate every 60 degrees are provided, the stationary state of the rotor 5 in the non-energized state is more reliably maintained. can do.
Further, in the present embodiment, the stator side stationary portion is the first recess 16 provided on the inner peripheral surface of the rotor receiving portion 14, and the rotor side stationary portion is the outer peripheral surface of the rotor magnet 50 and the apex of each magnetic pole. Since the second concave portion 52 is provided in the first and second recesses, it is possible to provide means for reliably stopping the rotor by relatively easy processing.
In addition, in order to manufacture a multi-pole magnetized rotor, a complicated and expensive mold or magnetizer is required. In this embodiment, a rotor magnet 50 magnetized in two poles is used. For this reason, the stepping motor 100 capable of realizing rotation with 60 degrees as a unit can be manufactured with a simple configuration and relatively easily and inexpensively.
In addition, when the rotor magnet has a simple disk shape, the magnet pole direction cannot be easily determined from the outer shape, and when the rotor gear teeth are molded or assembled, the direction of the gear teeth and the magnet pole The direction of cannot be adjusted. For this reason, countless combinations of the rotor magnet's pole direction and the gear tip direction occur, and the size of the hole for detecting the needle position of the gear interlocking with the rotor must be expanded to a size that assumes every rotor. In other words, extra gears are required to prevent the positions of the holes from overlapping and erroneously detecting in the preceding and following steps, and the size of the gears need to be increased unnecessarily. In this regard, when the concave portion is provided at the apex of the magnetic pole of the rotor magnet 50 as in this embodiment, the pole direction of the magnet can be easily determined from the outer shape, and the type of the rotor is narrowed down to one type. Is possible. As a result, it is possible to reduce the hole of the gear for detecting the needle position, eliminate the need for a gear to prevent erroneous detection, and to reduce the size of the gear. The product can be downsized.

[Second Embodiment]
Next, a second embodiment of the stepping motor according to the present invention will be described with reference to FIGS. Note that the present embodiment is different from the first embodiment only in the configuration of the stator side stationary portion and the rotor side stationary portion, and therefore, in the following, differences from the first embodiment will be particularly described.

FIG. 8 is a plan view of the stepping motor of the present embodiment.
As shown in FIG. 8, in the present embodiment, the stepping motor includes stator bodies 10 and 2 each having three yokes (that is, a center yoke 11, a side yoke 12a, and a side yoke 12b), as in the first embodiment. The stator 1 includes two coil blocks 20 (a first coil block 20a and a second coil block 20b), a rotor 5 that is rotatably received by a rotor receiving portion 14 of the stator body 10, and the like.

In the present embodiment, corresponding to the three magnetic poles 15 (the first magnetic pole 15a, the second magnetic pole 15b, and the third magnetic pole 15c) of the stator body 10, the period is substantially every 120 degrees on the inner peripheral surface of the rotor receiving portion 14. In particular, a stator side stationary part is provided. In the present embodiment, each stator-side stationary part is composed of two concave parts.
That is, the rotor magnet 50 in each magnetic pole 15 (the first magnetic pole 15a, the second magnetic pole 15b, and the third magnetic pole 15c) appearing in the three yokes of the stator body 10 (that is, the center yoke 11, the side yoke 12a, and the side yoke 12b). A second recess 55 (second recess 55a, 55b) which is a symmetrical position across the top of each magnetic pole on the opposite side and which is a rotor-side stationary portion of the rotor 5 to be described later as the rotor 5 rotates. Two first recesses 6 (first recesses 6a, 6b, 6c) are formed at positions opposite to each other.
In the present embodiment, the two first recesses 6 are symmetrical positions sandwiching the apexes of the magnetic poles of the stator body 10 and the center of the circle of the rotor receiving portion 14 (ie, the rotor received by the rotor receiving portion 14). It is arranged at a position that is at an angle of approximately 60 degrees with respect to the circle center of the magnet 50.

In addition, the rotor magnet 50 is provided with a rotor-side stationary portion at a symmetrical position across the apex of each magnetic pole of the rotor magnet 50. In this embodiment, each rotor side stationary part is comprised by two recessed parts, respectively.
That is, two second recesses 55 (second recesses 55a and 55b) are formed at symmetrical positions across the top of each magnetic pole of the rotor magnet 50, respectively.
In the present embodiment, the two second recesses 55 are symmetrical positions sandwiching the apexes of the magnetic poles of the rotor magnet 50 and are disposed at positions that are at an angle of approximately 60 degrees with respect to the circle center of the rotor magnet 50. Has been.

  In addition, since the other structure is the same as that of 1st Embodiment, the same code | symbol is attached | subjected to the same member and the description is abbreviate | omitted.

  Next, the operation of the stepping motor in this embodiment will be described with reference to FIGS. 9 and 10, the solid arrow indicates the direction of the magnetic flux generated from the coil 22, and the broken arrow indicates the flow of the magnetic flux flowing through the stator 1.

FIG. 9A to FIG. 9D are explanatory diagrams when the rotor 5 is rotated forward (that is, rotated in the clockwise direction). FIG. 9A shows that the S pole of the rotor magnet 50 is the first. The case where the position closest to one magnetic pole 15a is the initial position is shown.
When the rotor 5 is rotated forward, first, a drive pulse is applied from the drive pulse supply circuit 31 to the second coil 22b so that the second magnetic pole 15b becomes N pole. As a result, as shown in FIG. 9B, a magnetic flux in the direction of the solid line arrow is generated from the second coil 22b, and the magnetic flux flows toward the rotor magnet 50 as shown by the broken line arrow. And the rotor 5 rotates 60 degrees clockwise.
The position rotated by 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably moves around the magnetic pole 15. In this embodiment, the position is symmetrical with respect to the top of the N pole of the rotor magnet 50. Since the second recesses 55b and 55b provided at the positions are opposed to the first recesses 6c and 6c provided at symmetrical positions with the apex of the third magnetic pole 15c of the stator 1 therebetween, index torque (holding torque) is generated. Even after the application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 is stably stopped at the position while maintaining the rotation angle.

Next, a drive pulse is applied from the drive pulse supply circuit 31 to the first coil 22a so that the first magnetic pole 15a becomes the S pole. As a result, as shown in FIG. 9C, a magnetic flux in the direction of the solid line arrow is generated from the first coil 22a, the magnetic flux flows as shown by the broken line arrow, and the magnetic pole 15 of the stator 1 is switched. Is further rotated 60 degrees clockwise (i.e. 120 degrees from the initial position).
The position rotated by 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably moves around the magnetic pole 15. In this embodiment, the position is symmetrical with the apex of the S pole of the rotor magnet 50 interposed therebetween. Since the second recesses 55a and 55a provided at the positions are opposed to the first recesses 6b and 6b provided at the symmetrical positions across the vertex of the second magnetic pole 15b of the stator 1, index torque (holding torque) is generated. Even after the application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 is stably stopped at the position while maintaining the rotation angle.

Further, a drive pulse is applied from the drive pulse supply circuit 31 to the first coil 22a and the second coil 22b so that the third magnetic pole 15c becomes N pole. As a result, as shown in FIG. 9 (d), magnetic flux in the direction of the solid line arrow is generated from the first coil 22a and the second coil 22b, and the magnetic flux flows as shown by the broken line arrow, and the magnetic pole 15 of the stator 1 is switched. As a result, the rotor 5 further rotates 60 degrees clockwise (that is, 180 degrees from the initial position).
The position rotated by 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably moves around the magnetic pole 15. In this embodiment, the position is symmetrical with respect to the top of the N pole of the rotor magnet 50. Since the second recesses 55b and 55b provided at the position face the first recesses 6a and 6a provided at symmetrical positions with the apex of the first magnetic pole 15a of the stator 1 being opposed, index torque (holding torque) is generated. Even after the application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 is stably stopped at the position while maintaining the rotation angle.

  Through the above three steps, the rotor 5 rotates clockwise by 60 degrees three times, and is in a state rotated 180 degrees from the initial position. By further rotating 180 degrees by the same method, the rotor 5 rotates 360 degrees and returns to the initial position again.

Next, FIG. 10A to FIG. 10D are explanatory views when the rotor 5 is reversely rotated (that is, rotated counterclockwise), and FIG. 10A is the S pole of the rotor 5. Shows the case where the position closest to the first magnetic pole 15a is the initial position.
Since the method of applying the drive pulse and the flow of magnetic flux in the case of rotating the rotor 5 in the reverse direction are the same as those shown in the first embodiment, description thereof is omitted.
When the rotor 5 is rotated 60 degrees (−60 degrees) counterclockwise from the initial state shown in FIG. 10A to the state shown in FIG. 10B, the N pole apex of the rotor magnet 50 is sandwiched. Since the second concave portions 55b and 55b provided at the symmetrical position face the first concave portions 6b and 6b provided at the symmetrical position across the vertex of the second magnetic pole 15b of the stator 1, the index torque (holding torque). Even after application of the drive pulse from the drive pulse supply circuit 31 is stopped, the rotor 5 stably stops at the position while maintaining the rotation angle.
Next, by applying a drive pulse from the drive pulse supply circuit 31 to the second coil 22b so that the first magnetic pole 15a becomes the S pole, the rotor 5 is further rotated 60 degrees counterclockwise (−60 degrees, ie, initial 10C, the second recesses 55a and 55a provided at symmetrical positions across the vertex of the south pole of the rotor magnet 50 are the third of the stator 1. Even after the application of the drive pulse from the drive pulse supply circuit 31 stops, the index torque (holding torque) increases because it faces the first recesses 6c, 6c provided at symmetrical positions across the apex of the magnetic pole 15c. The rotor 5 stably stops at the position while maintaining the rotation angle.
Further, by applying a drive pulse from the drive pulse supply circuit 31 to the first coil 22a and the second coil 22b so that the second magnetic pole 15b becomes an N pole, the rotor 5 is further rotated 60 degrees counterclockwise (−60 10 degrees, i.e., -180 degrees from the initial position), when the state shown in FIG. 10D is reached, the second recesses 55b and 55b provided at symmetrical positions with the N pole apex of the rotor magnet 50 sandwiched by the stator The index torque (holding torque) increases because it faces the first recesses 6a, 6a provided at symmetrical positions across the apex of the first magnetic pole 15a, and the drive pulse supply circuit 31 applies the drive pulse. Even after stopping, the rotor 5 stably stops at the position while maintaining the rotation angle.

  Through the above three steps, the rotor 5 rotates counterclockwise three times by -60 degrees and is rotated by -180 degrees from the initial position. By further rotating −180 degrees by the same method, the rotor 5 rotates 360 degrees and returns to the initial position again.

  Since other points are the same as those in the first embodiment, description thereof is omitted.

As described above, according to the present embodiment, the following effects can be obtained as in the first embodiment.
That is, in the configuration of the present embodiment, the position where the magnetic flux generated from the rotor magnet 50 stably turns around the magnetic pole 15 in a state where the coil 22 is not energized (that is, either the S pole or the N pole of the rotor magnet 50). (Positions facing each magnetic pole 15 of the stator body 10) appear uniformly every 60 degrees. For this reason, the detent torque (static torque) of the rotor 5 becomes large at each 60 degrees.
In addition, when the first recesses 6a, 6b, 6c as the stator side stationary portions and the second recesses 55a, 55b as the rotor side stationary portions face each other, the index torque (holding torque) increases, so the coil At the time of de-energization to 22, the rotor 5 is surely stopped at the position of every 60 degrees. Thus, since the rotor 5 can be accurately rotated with 60 degrees as one unit, the rotation angle can be finely controlled.
Thereby, a fine hand movement angle or the like can be realized without using a large number of gears (gears) to decelerate greatly. In addition, since it is possible to convert to a step twice without providing a gear (gear) for speed control, it is difficult for the hands to move, and the hands can be moved smoothly.
Thus, in this embodiment, since the number of parts, such as a gear (gear) for decelerating, can be reduced, the apparatus cost can be suppressed. Further, since the number of parts such as gears (gears) can be reduced, the space in the apparatus incorporating the stepping motor can be used efficiently, and the apparatus incorporating the stepping motor can be reduced in size and thickness. Further, since the number of mechanical parts such as gears (gears) constituting the speed control mechanism connected to the stepping motor can be reduced in this way, accumulation of backlash and the like can be reduced and driven by the stepping motor. The accuracy of the hand movement mechanism and the like can be improved.
In a stepping motor capable of forward and reverse rotation, when the rotor 5 is rotated 180 degrees by one set of drive pulses, for example, three stages of drive pulses are applied according to the rotation angle of the rotor 5. However, according to the present embodiment, the rotor 5 can be stably stopped at positions of every 60 degrees, and the rotor 5 can be efficiently rotated by the magnetic flux emitted from the magnetic pole 15.
Further, since the stator side stationary part and the rotor side stationary part that maintain the stationary state for each unit rotation of the rotor 5 that can rotate every 60 degrees are provided, the stationary state of the rotor 5 in the non-energized state is more reliably maintained. can do. For this reason, it is possible to shift to the next step in a short time, and the rotor 5 can be stably rotated at a high speed.
Further, in the present embodiment, the stator side stationary portion is the first concave portion 6 provided periodically every 120 degrees on the inner circumferential surface of the rotor receiving portion 14, and the rotor side stationary portion is the outer circumferential surface of the rotor magnet 50. And since it is the 2nd recessed part 55 provided in the vertex of each magnetic pole, the means for making a rotor stand still reliably by a comparatively easy process can be provided.
In addition, since the rotor magnet 50 magnetized with two poles is used in the present embodiment, a stepping motor capable of realizing rotation with 60 degrees as a unit is manufactured with a simple configuration and relatively easily and inexpensively. be able to.

[Third Embodiment]
Next, a third embodiment of the stepping motor according to the present invention will be described with reference to FIGS. Note that this embodiment is different from the first embodiment only in the configuration of the stator side stationary part and the rotor side stationary part, and in the following, differences from the first embodiment and the like will be particularly described.

FIG. 11 is a plan view of the stepping motor of the present embodiment.
As shown in FIG. 11, in this embodiment, the stepping motor includes a stator body 10 including three yokes (that is, a center yoke 11, a side yoke 12a, and a side yoke 12b), as in the first embodiment. The stator 1 includes two coil blocks 20 (a first coil block 20a and a second coil block 20b), a rotor 5 that is rotatably received by a rotor receiving portion 14 of the stator body 10, and the like. .

In the present embodiment, corresponding to the three magnetic poles 15 (the first magnetic pole 15a, the second magnetic pole 15b, and the third magnetic pole 15c) of the stator body 10, the period is substantially every 120 degrees on the inner peripheral surface of the rotor receiving portion 14. In particular, a stator side stationary part is provided. In this embodiment, each stator side stationary part is comprised by three recessed parts, respectively.
That is, the rotor magnet 50 in each magnetic pole 15 (the first magnetic pole 15a, the second magnetic pole 15b, and the third magnetic pole 15c) appearing in the three yokes of the stator body 10 (that is, the center yoke 11, the side yoke 12a, and the side yoke 12b). A second concave portion 57 (second portion) that is a symmetrical position across the apex of each magnetic pole on the opposite side and the apex of each magnetic pole and that is a rotor-side stationary portion of a rotor magnet 50 described later as the rotor 5 rotates. The first recesses 7 (first recesses 7a, 7b, 7c) are formed in three each at positions facing the recesses 57a, 57b).

Further, the rotor magnet 50 is provided with a rotor-side stationary portion at a symmetrical position across the top of each magnetic pole of the rotor magnet 50 and the top of each magnetic pole. In this embodiment, each rotor side stationary part is comprised by the three recessed parts, respectively.
That is, three second recesses 55 (second recesses 55a and 55b) are formed at symmetrical positions sandwiching the apex of each magnetic pole of the rotor magnet 50 and the apex of each magnetic pole.

  In addition, since the other structure is the same as that of 1st Embodiment etc., the same code | symbol is attached | subjected to the same member and the description is abbreviate | omitted.

  Next, the operation of the stepping motor in this embodiment will be described with reference to FIGS. 12 and 13, solid arrows indicate the direction of magnetic flux generated from the coil 22, and broken arrows indicate the flow of magnetic flux flowing through the stator 1.

FIGS. 12A to 12D are explanatory diagrams when the rotor 5 is rotated forward (that is, rotated in the clockwise direction), and FIG. The case where the position closest to one magnetic pole 15a is the initial position is shown.
When the rotor 5 is rotated forward, first, a drive pulse is applied from the drive pulse supply circuit 31 to the second coil 22b so that the second magnetic pole 15b becomes N pole. As a result, as shown in FIG. 12B, a magnetic flux in the direction of the solid line arrow is generated from the second coil 22b, and the magnetic flux flows toward the rotor magnet 50 as shown by the broken line arrow. And the rotor 5 rotates 60 degrees clockwise.
The position rotated by 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably moves around the magnetic pole 15. In this embodiment, the apex and apex of the N pole of the rotor magnet 50 are sandwiched at this position. The second recesses 57b, 57b, 57b provided at the symmetrical positions are opposed to the first recesses 7c, 7c, 7c provided at the symmetrical positions across the apex of the third magnetic pole 15c of the stator 1 and the apex. Thus, the index torque (holding torque) is increased and the rotor 5 is stably stopped at the position while maintaining the rotation angle even after the application of the drive pulse from the drive pulse supply circuit 31 is stopped.

Next, a drive pulse is applied from the drive pulse supply circuit 31 to the first coil 22a so that the first magnetic pole 15a becomes the S pole. As a result, as shown in FIG. 12C, a magnetic flux in the direction of the solid line arrow is generated from the first coil 22a, and the magnetic flux flows as shown by the broken line arrow, so that the magnetic pole 15 of the stator 1 is switched. Is further rotated 60 degrees clockwise (i.e. 120 degrees from the initial position).
The position rotated 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably moves around the magnetic pole 15. In this embodiment, the apex and apex of the S pole of the rotor magnet 50 are sandwiched at this position. The second recesses 57a, 57a, 57a provided at the symmetrical positions are opposed to the first recesses 7b, 7b, 7b provided at the symmetrical positions across the apex of the second magnetic pole 15b of the stator 1 and the apex. Thus, the index torque (holding torque) is increased and the rotor 5 is stably stopped at the position while maintaining the rotation angle even after the application of the drive pulse from the drive pulse supply circuit 31 is stopped.

Further, a drive pulse is applied from the drive pulse supply circuit 31 to the first coil 22a and the second coil 22b so that the third magnetic pole 15c becomes N pole. As a result, as shown in FIG. 12D, a magnetic flux in the direction of the solid arrow is generated from the first coil 22a and the second coil 22b, and the magnetic flux flows as shown by the dashed arrow, and the magnetic pole 15 of the stator 1 is switched. As a result, the rotor 5 further rotates 60 degrees clockwise (that is, 180 degrees from the initial position).
The position rotated by 60 degrees is a position where the magnetic flux generated from the rotor magnet 50 stably moves around the magnetic pole 15. In this embodiment, the apex and apex of the N pole of the rotor magnet 50 are sandwiched at this position. The second recesses 57b, 57b, 57b provided at the symmetrical positions are opposed to the first recesses 7a, 7a, 7a provided at the symmetrical positions across the apex of the first magnetic pole 15a of the stator 1 and the apex. Thus, the index torque (holding torque) is increased and the rotor 5 is stably stopped at the position while maintaining the rotation angle even after the application of the drive pulse from the drive pulse supply circuit 31 is stopped.

  Through the above three steps, the rotor 5 rotates clockwise by 60 degrees three times, and is in a state rotated 180 degrees from the initial position. By further rotating 180 degrees by the same method, the rotor 5 rotates 360 degrees and returns to the initial position again.

Next, FIGS. 13A to 13D are explanatory diagrams when the rotor 5 is rotated in the reverse direction (that is, rotated counterclockwise), and FIG. 13A is the S pole of the rotor 5. Shows the case where the position closest to the first magnetic pole 15a is the initial position.
Since the method of applying the drive pulse and the flow of magnetic flux in the case of rotating the rotor 5 in the reverse direction are the same as those shown in the first embodiment, description thereof is omitted.
When the rotor 5 is rotated 60 degrees (−60 degrees) counterclockwise from the initial state shown in FIG. 13A to the state shown in FIG. 13B, the vertices and vertices of the N pole of the rotor magnet 50 are set. The second recesses 57b, 57b, 57b provided at the sandwiched symmetrical positions are opposed to the apex of the second magnetic pole 15b of the stator 1 and the first recesses 7b, 7b, 7b provided at the symmetrical positions sandwiching the apex. As a result, the index torque (holding torque) is increased, and the rotor 5 is stably stopped at the position while maintaining the rotation angle even after the application of the drive pulse from the drive pulse supply circuit 31 is stopped.
Next, by applying a drive pulse from the drive pulse supply circuit 31 to the second coil 22b so that the first magnetic pole 15a becomes the S pole, the rotor 5 is further rotated 60 degrees counterclockwise (−60 degrees, ie, initial (120 degrees from the position), and when the state shown in FIG. 13C is reached, the second recesses 57a, 57a, 57a provided at symmetrical positions across the apex of the S pole and the apex of the rotor magnet 50 are stators. The first torque of the third magnetic pole 15c and the first recesses 7c, 7c, 7c provided at symmetrical positions across the apex increase the index torque (holding torque) and drive from the drive pulse supply circuit 31. Even after the application of the pulse is stopped, the rotor 5 stably stops at the position while maintaining the rotation angle.
Further, by applying a drive pulse from the drive pulse supply circuit 31 to the first coil 22a and the second coil 22b so that the second magnetic pole 15b becomes an N pole, the rotor 5 is further rotated 60 degrees counterclockwise (−60 (Ie, 180 degrees from the initial position) and the state shown in FIG. 13D is reached, the second poles 57b and 57b provided at symmetrical positions with the N pole apex of the rotor magnet 50 sandwiched between the apexes. , 57b are opposed to the first recesses 7a, 7a, 7a provided at symmetrical positions across the apex of the first magnetic pole 15a of the stator 1, and the index torque (holding torque) is increased, and the drive pulse supply circuit Even after the application of the drive pulse from 31 stops, the rotor 5 stably stops at that position while maintaining the rotation angle.

  Through the above three steps, the rotor 5 rotates counterclockwise three times by -60 degrees and is rotated by -180 degrees from the initial position. By further rotating −180 degrees by the same method, the rotor 5 rotates 360 degrees and returns to the initial position again.

  Since other points are the same as those in the first embodiment, the description thereof will be omitted.

As described above, according to the present embodiment, the following effects can be obtained as in the first embodiment.
That is, in the configuration of the present embodiment, the position where the magnetic flux generated from the rotor magnet 50 stably turns around the magnetic pole 15 in a state where the coil 22 is not energized (that is, either the S pole or the N pole of the rotor magnet 50). (Positions facing each magnetic pole 15 of the stator body 10) appear uniformly every 60 degrees. For this reason, the detent torque (static torque) of the rotor 5 becomes large at each 60 degrees.
In addition, when the first concave portions 7a, 7b, 7c as the stator side stationary portions and the second concave portions 57a, 57b as the rotor side stationary portions face each other, the index torque (holding torque) becomes large. At the time of de-energization to 22, the rotor 5 is surely stopped at the position of every 60 degrees. Thus, since the rotor 5 can be accurately rotated with 60 degrees as one unit, the rotation angle can be finely controlled.
Thereby, a fine hand movement angle or the like can be realized without using a large number of gears (gears) to decelerate greatly. In addition, since it is possible to convert to a step twice without providing a gear (gear) for speed control, it is difficult for the hands to move, and the hands can be moved smoothly.
Thus, in this embodiment, since the number of parts, such as a gear (gear) for decelerating, can be reduced, the apparatus cost can be suppressed. Further, since the number of parts such as gears (gears) can be reduced, the space in the apparatus incorporating the stepping motor can be used efficiently, and the apparatus incorporating the stepping motor can be reduced in size and thickness. Further, since the number of mechanical parts such as gears (gears) constituting the speed control mechanism connected to the stepping motor can be reduced in this way, accumulation of backlash and the like can be reduced and driven by the stepping motor. The accuracy of the hand movement mechanism and the like can be improved.
In a stepping motor capable of forward and reverse rotation, when the rotor 5 is rotated 180 degrees by one set of drive pulses, for example, three stages of drive pulses are applied according to the rotation angle of the rotor 5. However, according to the present embodiment, the rotor 5 can be efficiently rotated by the magnetic flux emitted from the magnetic pole 15 where the rotor 5 is stably stationary at positions of every 60 degrees.
Further, since the stator side stationary part and the rotor side stationary part that maintain the stationary state for each unit rotation of the rotor 5 that can rotate every 60 degrees are provided, the stationary state of the rotor 5 in the non-energized state is more reliably maintained. can do. For this reason, it is possible to shift to the next step in a short time, and the rotor 5 can be stably rotated at a high speed.
Further, in the present embodiment, the stator side stationary portion is the first concave portion 7 periodically provided on the inner circumferential surface of the rotor receiving portion 14 every 120 degrees, and the rotor side stationary portion is the outer circumferential surface of the rotor magnet 50. And since it is the 2nd recessed part 57 provided in the vertex of each magnetic pole, the means for making a rotor stand still reliably by a comparatively easy process can be provided.
In addition, since the rotor magnet 50 magnetized with two poles is used in the present embodiment, a stepping motor capable of realizing rotation with 60 degrees as a unit is manufactured with a simple configuration and relatively easily and inexpensively. be able to.

  Although the embodiments of the present invention have been described above, the present invention is not limited to such embodiments, and various modifications can be made without departing from the scope of the present invention.

For example, in each of the above embodiments, the stator body 10, the first coil block 20a, and the second coil block 20b are formed as separate bodies, and these are magnetically coupled to each other to constitute the stator 1. As described above, the shape and configuration of the stator 1 and the stator body 10, the first coil block 20a, and the second coil block 20b constituting the stator 1 are not limited to those shown in the above embodiments, and can be modified as appropriate. It is.
For example, the stator may be composed of a stator body and one coil block having a continuous long magnetic core.
In this case, when the stator body includes a center yoke and a pair of side yokes as in the present embodiment, for example, the substantially central portion of the magnetic core of the coil block is magnetically coupled to the center yoke of the stator body. A first coil and a second coil are provided on both sides of the coupling portion, and one end of the magnetic core is magnetically connected to one end of one side yoke, and the other end of the magnetic core is magnetically connected to one end of the other side yoke. To do.
When the stator has such a configuration, the number of parts can be reduced as compared with the case where the coil block is configured as a pair.

  Furthermore, the stator main body, the first coil block, and the second coil block may all be integrally formed as a stator. In this case, for example, the stator body and the magnetic cores of the first coil block and the second coil block are formed as an integral member.

Further, in each of the above embodiments, the case where the stator side stationary portion is the first recess provided on the inner peripheral surface of the rotor receiving portion 14 has been described as an example. Any one can be used as long as it can stably maintain the stationary state of the rotor when the coil is de-energized by increasing the detent torque and holding torque, and is not limited to those exemplified here.
For example, the stator side stationary portion may be a convex portion provided on the inner peripheral surface of the rotor receiving portion 14. In addition, it is not essential that the stator-side stationary portion is provided on the inner peripheral surface of the rotor receiving portion 14. The rotor receiving portion 14 itself has an eccentric shape, or an eccentric pin or the like is provided outside the rotor receiving portion 14. It is good also as a structure which provides and enlarges the index torque of a rotor.
The shape or the like of the rotor-side stationary portion changes as appropriate according to the stator-side stationary portion. For example, when the stator-side stationary portion is a convex portion provided on the inner peripheral surface of the rotor receiving portion 14. The rotor-side stationary portion is also a convex portion formed on the outer peripheral surface of the rotor magnet 50.

Moreover, in 1st Embodiment, the 2nd recessed part as a rotor side stationary part shows the example provided one each in the vertex of each magnetic pole of a rotor magnet, In 2nd Embodiment, 2nd recessed part is shown. An example is shown in which a pair of recesses are provided at symmetrical positions sandwiching the apex of each magnetic pole of the rotor magnet (two in each magnetic pole in the second embodiment). In the third embodiment, the second recess In the example shown in FIG. 5, the symmetric positions (three in each magnetic pole in the third embodiment) sandwiching the apex of each magnetic pole of the rotor magnet and the apex of each magnetic pole are shown. The number and arrangement of the recesses are not limited to those illustrated here. For example, four or more second recesses may be provided in each magnetic pole. In this case, the same number of first concave portions as the stator side stationary portions are provided at positions opposite to the second concave portions corresponding to the second concave portions.
Since the rotor magnet can obtain a larger rotational torque as it is closer to a circle, it is preferable that the number of locations where the concave portion is provided by scraping the outer peripheral surface of the rotor magnet is preferable from the viewpoint of securing a large rotational torque.

In each of the above embodiments, the case where the rotor-side stationary portion is the second recess provided on the outer peripheral surface of the rotor magnet 50 has been described as an example. However, the rotor-side stationary portion is the index torque (detent torque) of the rotor. , Holding torque) can be increased so long as it can stably maintain the stationary state of the rotor when the coil is not energized, and is not limited to those exemplified here.
For example, as shown in FIG. 14, notches 58 (58a, 58b) may be provided at the apexes of the magnetic poles of the rotor magnet 50 as the rotor-side stationary portion. Also in this case, a peak of index torque (holding torque) that is as large as that obtained when a concave portion is provided at the apex of each magnetic pole of the rotor magnet 50 can be obtained.

  Further, in each of the above embodiments, the case where the stator side stationary portion is provided on the inner peripheral surface of the rotor receiving portion 14 at approximately every 120 degrees has been described as an example. It is not limited to.

  Further, in each of the above embodiments, the case where the stepping motor 100 drives the hand movement mechanism of the timepiece pointer has been described as an example. However, the stepping motor 100 is not limited to the one that drives the hand movement mechanism, It can be applied as a drive source.

  In addition, it cannot be overemphasized that this invention is not limited to said each embodiment, and can be changed suitably.

Although several embodiments of the present invention have been described above, the scope of the present invention is not limited to the above-described embodiments, but includes the scope of the invention described in the claims and equivalents thereof. .
The invention described in the scope of claims attached to the application of this application will be added below. The item numbers of the claims described in the appendix are as set forth in the claims attached to the application of this application.
[Appendix]
<Claim 1>
A rotor comprising a rotor magnet magnetized in two radial directions;
A rotor receiving portion for receiving the rotor is formed, and a first magnetic pole, a second magnetic pole, and a third magnetic pole are arranged around the rotor receiving portion at positions obtained by dividing the outer periphery into three along the outer periphery of the rotor magnet. A stator comprising a stator body having magnetic poles, and a coil magnetically coupled to the stator body;
A drive pulse supply circuit for applying a drive pulse for rotating the rotor to the coil;
With
The rotor magnet is formed with a rotor side stationary part,
The stator is formed with a stator side stationary part,
The rotor-side stationary portion is disposed at at least one of symmetrical positions sandwiching the top of each magnetic pole and the top of each magnetic pole of the rotor magnet,
The stator-side stationary portion is at least one of a symmetrical position across the top of each of the first magnetic pole, the second magnetic pole, and the third magnetic pole facing the rotor magnet, and the top of each magnetic pole. And is disposed at a position facing the rotor-side stationary portion of the rotor magnet as the rotor rotates.
The driving pulse supply circuit applies a driving pulse to the coil such that any one of the rotor side stationary portions faces one of the stator side stationary portions so that the rotor is stationary. motor.
<Claim 2>
The stepping motor according to claim 1, wherein the rotor-side stationary portion is a recess formed in an outer peripheral surface of the rotor magnet.
<Claim 3>
3. The stepping motor according to claim 1, wherein the stator-side stationary portion is a recess formed in an inner peripheral surface of the rotor receiving portion.
<Claim 4>
In the drive pulse supply circuit, the N pole and the S pole that are the magnetic poles of the rotor magnet are alternately opposed to any one of the first magnetic pole, the second magnetic pole, and the third magnetic pole at each step. Furthermore, the polarity of the said 1st magnetic pole, the said 2nd magnetic pole, and the said 3rd magnetic pole is switched by applying the said drive pulse to the said coil, The Claim 1 characterized by the above-mentioned. Stepping motor.

DESCRIPTION OF SYMBOLS 1 Stator 5 Rotor 10 Stator main body 11 Center yoke 12a Side yoke 12b Side yoke 14 Rotor receiving part 15a 1st magnetic pole 15b 2nd magnetic pole 15c 3rd magnetic pole 16 1st recessed part 20a 1st coil block 20b 2nd coil block 21 Magnetic core 22a 1st coil 22b 2nd coil 24 Conductor end part 31 Drive pulse supply circuit 50 Rotor magnet 52 2nd recessed part 100 Stepping motor

Claims (3)

A circular rotor magnetized in two radial directions and having a stationary part ;
A stator body having a first magnetic pole, a second magnetic pole, and a third magnetic pole, a symmetrical position across the vertices of the first magnetic pole, the second magnetic pole, and the third magnetic pole, and with the rotation of the rotor A stationary part disposed at a position facing the stationary part of the rotor, and a stator,
Equipped with a,
The stationary portion of the rotor is disposed at a target position sandwiching the apex of each magnetic pole of the rotor, and has a shape recessed inward from the outer peripheral shape of the rotor,
The stepping motor according to claim 1, wherein the stationary portion of the stator has a shape recessed inward from an outer peripheral shape of the stator adjacent to the rotor . The rotor main body is formed with a rotor receiving portion for receiving the rotor, and the first magnetic pole, the second magnetic pole, and the third magnetic pole are disposed around the rotor receiving portion. The stepping motor according to 1 . A drive pulse supply circuit for supplying a drive pulse for rotating the rotor;
The drive pulse supply circuit supplies a drive pulse so that any one of the stationary portions of the rotor is stationary at a position facing any one of the stationary portions of the stator. Or the stepping motor of 2 .

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