JP2021136791A - Stator, stepper motor, and watch - Google Patents

Abstract

To provide a stator that is resistant to external stress.SOLUTION: A stator includes a stator base material that is composed of an integral magnetic material and has a through hole in which a rotor can be placed, a magnetic path that generates a magnetic pole in the stator base material around the through hole when a coil is excited, a supersaturated portion formed such that the cross-sectional area of the magnetic path is narrower than the other portion, a protrusion that is provided in the supersaturated portion so as to protrude only from the first surface of the stator base material and has a diffusion region having a different chromium weight ratio from the base material, and a groove provided in the protrusion.SELECTED DRAWING: Figure 3

Description

The present invention relates to a stator, a stepping motor, and a timepiece.

As an example of a stator used in a stepping motor for a watch, a stator formed of a permalloy material having a high magnetic permeability is known. Since the hardness of this stator is as soft as about 100 (HV), the stator formed of the permalloy material is a easily deformable component.
In this type of stator, for example, in order to easily obtain the leakage magnetic flux that drives the rotor, supersaturated portions are provided at two places (generally at 180 degree intervals) around the through holes where the rotor is installed. (Integrated stator). The supersaturated portion has an extremely thin shape (for example, a width of 100 μm) in order to facilitate the saturation magnetic flux in this portion.
Since such an integrated stator is soft and the width of the supersaturated portion is extremely narrow, it is easy to bend due to an external force generated during handling and assembly. In the integrated stator, when the supersaturated portion is deformed, the magnetic characteristics of the supersaturated portion deteriorate. As a result, the magnetic gradient between the rotor and the stator changes, so that the position where the rotor stably rests (stable rest position) shifts.

In order to solve the problem of the integrated stator, by diffusing and melting chromium in the portion corresponding to the supersaturated portion, the portion is demagnetized, and the left portion and the right portion of the demagnetized portion are magnetic. (See magnetic two-body stators, for example, Patent Documents 1 and 2).
There is almost no change in bending strength due to the local increase in the chromium weight ratio, and the change in bending strength is suppressed within the error range possessed by the material. Therefore, if the outer shape of the magnetic two-body type stator can be maintained in the same ideal shape as that of the normal one-body type stator, the difference between the bending strength of the magnetic two-body type stator and the bending strength of the one-body type stator can be tolerated.
Further, in the magnetic two-body type stator, by making the width of the supersaturated portion wider than that of the integrated stator, it is possible to make it difficult for deformation to occur with respect to an external force.

Japanese Unexamined Patent Publication No. 2019-68724 Japanese Unexamined Patent Publication No. 7-241062

However, as described in Patent Document 2, when a laser beam is irradiated from the upper surface side of the stator to penetrate the molten portion in the plate thickness direction to form a non-magnetic portion, the portion shown by line 901 in FIG. 12 is formed. As described above, the dross is formed on the upper surface side of the stator, and the recesses are formed on the upper surface side and the lower surface side of the stator, respectively, so that the plate thickness is locally reduced. Note that FIG. 12 is a diagram showing an example of dross formed when a non-magnetic portion is provided by irradiating a laser beam and penetrating the molten portion in the plate thickness direction.
The bending strength of the magnetic two-body type stator formed in this way sharply decreases according to the thickness of the thinnest portion. As a result, in the conventional magnetic two-body type stator, the stable stationary position may be significantly shifted to an unacceptable level as compared with the conventional integrated stator.

The present invention has been made in view of the above problems, and is a watch including a stator resistant to external stress, a stepping motor provided with a stator resistant to external stress, and a stepping motor having a stator resistant to external stress. The purpose is to provide.

In order to achieve the above object, the stator according to one aspect of the present invention is formed of an integral magnetic material, and has a base material of a stator having a through hole in which a rotor can be arranged inside, and the penetration when a coil is excited. A magnetic path that generates magnetic poles in the base material of the stator around the hole, a hypersaturated portion formed so that the cross-sectional area of the magnetic path is narrower than other portions, and a mother of the stator in the hypersaturated portion. It is provided so as to project from only the first surface of the material, and includes a protrusion having a diffusion region having a different chromium weight ratio from the base material, and a groove provided in the protrusion.

Further, in the stator according to one aspect of the present invention, the protrusion and the groove may be provided continuously.

Further, in the stator according to one aspect of the present invention, the groove portion may be provided symmetrically with respect to the protrusion portion.

Further, in the stator according to one aspect of the present invention, the protrusions may be provided symmetrically with respect to the groove.

Further, in the stator according to one aspect of the present invention, the height of the protrusion from the first surface may be 1/10 or less of the thickness of the base material.

Further, in the stator according to one aspect of the present invention, the depth of the groove portion from the first surface may be 2/5 or less of the thickness of the base material.

Further, in the stator according to one aspect of the present invention, the width of the groove portion may be 1/4 or less of the thickness of the base material.

Further, in the stator according to one aspect of the present invention, the depth of the groove may be larger than the width of the groove.

The stepping motor according to one aspect of the present invention includes a stator of any one of the above-mentioned modes.

The clock according to one aspect of the present invention includes the stepping motor described above.

According to the present invention, it is possible to provide a timepiece including a stator having a strong external stress, a stepping motor having a stator strong against external stress, and a stepping motor having a stator strong against external stress.

It is a block diagram which shows the clock which used the stepping motor which has the stator which concerns on embodiment. It is a perspective view which shows the schematic structure example of the stepping motor which concerns on embodiment. It is a front schematic diagram of the stator which concerns on embodiment. In the embodiment, it is a figure which shows the photograph example of the cross section AA'in FIG. 3 after melting and diffusing the chromium coated on permalloy with a laser to make the demagnetization rate about 80%. In the embodiment, it is a figure which shows the photograph example of the cross section AA'in FIG. 3 after melting and diffusing the chromium coated on permalloy with a laser to make the demagnetization rate about 95%. It is an enlarged view in the xy plane of a part of the stator of FIG. 3 which concerns on embodiment. It is a figure which shows an example of the manufacturing method of the stator which concerns on embodiment. It is a top view which shows the hoop material before the press of the stator which concerns on embodiment. It is a front schematic diagram of the stepping motor which concerns on embodiment. It is a figure for demonstrating the relationship between the arrangement of the gear around the stator, and the notch on the outside of a stator. It is a figure which shows the BH curve when the stator is returned to a flat state before and after the deformation. It is a figure which shows the example of the dross formed at the time of providing a non-magnetic part by irradiating a laser beam and penetrating a molten part in a plate thickness direction.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings used in the following description, the scale of each member is appropriately changed in order to make each member recognizable.

FIG. 1 is a block diagram showing a clock 1 using a stepping motor having a stator according to the present embodiment. In the present embodiment, an analog electronic clock will be illustrated and described as an example of the clock 1.

As shown in FIG. 1, the clock 1 includes a battery 2, an oscillation circuit 3, a frequency dividing circuit 4, a control circuit 5, a pulse drive circuit 6, a stepping motor 7, and an analog clock unit 8.
Further, the analog clock unit 8 includes a train wheel 11, an hour hand 12, a minute hand 13, a second hand 14, a calendar display unit 15, a clock case 81, and a movement 82 for the clock 1. In the present embodiment, when one of the hour hand 12, the minute hand 13, the second hand 14, and the calendar display unit 15 is not specified, it is referred to as a pointer 16.

The oscillation circuit 3, the frequency dividing circuit 4, the control circuit 5, the pulse drive circuit 6, the stepping motor 7, and the train wheel 11 are components of the movement 82. A module provided with a stepping motor 7 and a train wheel 11 is also referred to as a mechanical module.
Generally, a mechanical body of a timepiece including a device such as a time reference of the timepiece 1 is referred to as a movement. Electronic movements are sometimes called modules. In the completed state of the watch, for example, a movement to which a dial, a pointer, etc. are attached is housed in the watch case.

The battery 2 is, for example, a lithium battery, a so-called button battery. The battery 2 may be a solar cell or a storage battery that stores electric power generated by the solar cell. The battery 2 supplies electric power to the control circuit 5.

The oscillation circuit 3 is a passive element used to oscillate a predetermined frequency from its mechanical resonance, for example, by utilizing the piezoelectric phenomenon of quartz. Here, the predetermined frequency is, for example, 32 [kHz].
The frequency dividing circuit 4 divides the signal of a predetermined frequency output by the oscillation circuit 3 into a desired frequency, and outputs the divided signal to the control circuit 5.

The control circuit 5 measures the time using the divided signal output by the frequency dividing circuit 4, and generates a drive pulse based on the timed result. The control circuit 5 generates a drive pulse for forward rotation when the pointer 16 is moved in the forward rotation direction. When the pointer 16 is moved in the reverse direction, the control circuit 5 generates a drive pulse for reverse rotation. The control circuit 5 outputs the generated drive pulse to the pulse drive circuit 6. The control circuit 5 may be, for example, a CPU (Central Processing Unit), an ASIC (Application Specific Integrated Circuit), or the like.

The pulse drive circuit 6 generates a drive pulse for each pointer in response to a drive instruction output from the control circuit 5.

The stepping motor 7 moves the pointer 16 (hour hand 12, minute hand 13, second hand 14, calendar display unit 15) according to the drive pulse output by the pulse drive circuit 6. In the example shown in FIG. 1, for example, one stepping motor 7 is provided for each of the hour hand 12, the minute hand 13, the second hand 14, and the calendar display unit 15.

The hour hand 12, the minute hand 13, the second hand 14, and the calendar display unit 15 are each moved by the stepping motor 7.
The hour hand 12 makes one rotation in 12 hours when the pulse drive circuit 6 drives the stepping motor 7. The minute hand 13 makes one rotation in 60 minutes when the pulse drive circuit 6 drives the stepping motor 7. The second hand 14 makes one rotation in 60 seconds when the pulse drive circuit 6 drives the stepping motor 7. The calendar display unit 15 is, for example, a pointer for displaying a date, and the pulse drive circuit 6 drives the stepping motor 7 to make one rotation in 24 hours.

Next, a schematic configuration example of the stepping motor 7 according to the present embodiment will be described.
FIG. 2 is a perspective view showing a schematic configuration example of the stepping motor 7 according to the present embodiment. As shown in FIG. 2, the stepping motor 7 includes a stator 201, a rotor 202, a magnetic core 208, a coil 209, and a screw 220.

The stator 201 is formed with a rotor accommodating hole 203 (through hole) for providing the rotor 202, a screw hole 218a for attaching the screw 220, and a screw hole 218b. Further, the stator 201 is formed with supersaturated portions 210 and 211 having a width narrower than the other portions at two locations around the rotor accommodating hole 203.
The rotor 202 is rotatably arranged in the rotor accommodating hole 203.
The coil 209 is wound around a magnetic core.
When the stepping motor 7 is used for an analog electronic timepiece, the stator 201 and the magnetic core 208 are fixed to the main plate 51 of the movement 82 by a screw 220 and joined to each other.
The magnetic path R generates a magnetic pole around the rotor accommodating hole 203 when the coil 209 is excited.

Next, the stator 201 will be described with reference to FIG. FIG. 3 is a front schematic view of the stator 201 according to the present embodiment. In FIG. 3, the longitudinal direction of the stator 201 is the y-axis direction, and the lateral direction is the x-axis direction. The stator 201 shown in FIG. 3 is manufactured by a method for manufacturing a motor stator, which will be described later.

As shown in FIG. 3, the stator 201 has an integral structure without a joint.
The base material 240 constituting the stator 201 is formed of, for example, a magnetic plate material of Fe—Ni (iron-nickel). Further, the base material 240 has a plate shape.
The stator 201 is formed by forming a rotor accommodating hole 203, a supersaturated portion 210, a supersaturated portion 211, a screw hole 218a, and a screw hole 218b in the base material 240.
Notches (inner notches) 204 and 205 are formed in the rotor accommodating holes 203.
The supersaturated portions 210 and 211 are formed around the rotor accommodating hole 203. The supersaturated portions 210 and 211 are non-magnetic regions.
In the photograph example (reference numeral g1) of the cross section of the cross section AA', the first surface f1 is the surface irradiated with the laser, and the second surface f2 is the surface opposite to the first surface f1. Like reference numeral g1, the stator 201 includes a protrusion 251 and a left groove 252, and a right groove 253. Further, in the stator 201, the supersaturated portions 210 and 211 are provided with protrusions 251 so as to project only from the first surface f1 side of the base material 240, and the protrusions 251 are provided with grooves (left groove 252, right groove 253). Have. The protrusions 251 and the grooves (left groove 252, right groove 253) and the like will be described later with reference to FIGS. 4 and 5.

When the stepping motor 7 is used for a timepiece, an example of each size of the stator 201 will be described.
The hole diameter of the rotor accommodating hole 203 is, for example, about 1.5 to 2 mm. The width of the narrowest portion of the supersaturated portions 210 and 211 is, for example, about 0.1 mm to 0.2 mm. The thickness of the stator 201 is, for example, about 0.5 mm ± 0.1 mm. The length in the longitudinal direction is, for example, about 10 mm.

<Explanation of a photograph example of the cross section of the stator after laser irradiation>
Next, a photograph example of the cross section AA'of FIG. 3 after irradiating the chromium coated on one side of the permalloy with a laser and melting and diffusing it with a laser to make the chromium 15% by weight or more is shown in FIG. , As shown in FIG.

FIG. 4 is a diagram showing a photographic example of the cross section AA'of FIG. 3 after melting and diffusing the chromium applied to the permalloy with a laser to reduce the demagnetization rate to about 80% in the present embodiment. ..
In FIG. 4, the vertical direction (z-axis direction) is the plate thickness direction of the base material 240 of the stator 201. The laser is emitted from the first surface f1 side, which is the surface coated with chromium. The base material 240 is an integral body made of a plate-shaped magnetic material, and the thickness h1 of the base material 240 is, for example, 0.5 mm ± 0.1 mm. In FIG. 4, after the chromium was applied, the chromium was irradiated with a laser having a laser power of about 150 W for an irradiation time of 4 ms to diffuse and melt the chromium. In this case, a part of the first surface f1 where the chrome coating thickness was thin was formed to be thinner than the thickness h1 of the base material 240. Further, assuming that the demagnetization rate of the normal integrated type is 0%, the demagnetization rate of the molten portion 250, which will be described later, is about 80%.

The melting portion 250 is a melting portion melted by laser irradiation.
The protrusion 251 is a protrusion formed on the first surface f1 and the molten portion 250 of the base material 240, projecting from the first surface f1 of the base material 240 in the plate thickness direction, and formed by laser irradiation. The height of the protrusion 251 from the first surface f1 of the base material 240 is h2. Therefore, in the portion where the protrusion 251 is formed, the total thickness h5 of the thickness h1 of the base material 240 and the height h2 of the protrusion 251 is thicker than the thickness h1 of the base material 240. Further, the protrusion 251 is a dross formed by irradiation with a laser. The protrusion 251 is provided on the supersaturated portion (210, 211 (FIGS. 2 and 3)). The protrusion 251 has a diffusion region having a different chromium weight ratio from the base material 240.
The left groove portion 252 (groove portion) is a groove portion formed by laser irradiation. The depth of the left groove portion 252 from the first surface f1 of the base material 240 is h3. Therefore, the left groove portion 252 is lower than the first surface f1 of the base material 240 by h3.
The right groove portion 253 (groove portion) is a groove portion formed by laser irradiation. The depth of the right groove portion 253 from the first surface f1 of the base material 240 is h4. Therefore, the right groove portion 253 is lower than the first surface f1 of the base material 240 by h4.

As described above, the stator 201 includes a groove portion (left groove portion 252, right groove portion 253) provided in the protrusion 251.
As shown in FIG. 4, when the demagnetization rate is around 80%, the protrusion 251 and the groove (left groove 252, right groove 253) are continuously provided, and the protrusion 251 is centered on the left and right two places. Grooves (left groove 252, right groove 253) are provided.
The height h2 of the protrusion 251 from the first surface f1 of the base material 240 is, for example, 1/10 or less of the thickness h1 of the base material 240. Further, the depths h3 and h4 of the groove portions (left groove portion 252 and right groove portion 253) from the first surface f1 of the base material 240 are, for example, 1/10 or less of the thickness h1 of the base material 240.

As shown in FIG. 4, the stator 201 of the present embodiment has a protrusion 251 at a hypersaturated portion (210, 211 (FIG. 3)) having a narrow width. In the stator 201 of the present embodiment, the protrusion 251 is thicker than the first surface f1 of the base material 240. Further, the stator 201 of the present embodiment is formed without the second surface f12 being deformed.
Further, according to the present embodiment, the depths h3 and h4 of the groove portions (left groove portion 252 and right groove portion 253) from the first surface f1 of the base material 240 are, for example, 2/5 or less of the thickness h1 of the base material 240. Therefore, the thickness of the groove portion can be secured as compared with the configuration of FIG.

As a result, according to the present embodiment, deformation due to an external force generated during handling of the stepping motor 7 and assembly of the stepping motor 7 is unlikely to occur.
As a result, according to the present embodiment, deformation due to external force generated during handling of the stepping motor 7 and assembly of the stepping motor 7 is unlikely to occur. Therefore, as will be described later, the change in magnetic characteristics due to deformation of the stator 201 is reduced. Can be done.
Further, according to the present embodiment, since the height of the protrusion from the first surface f1 is 1/10 or less of the thickness of the base material, when the stepping motor 7 having the stator 201 is attached to the watch 1. , It is possible to prevent interference with parts such as gears of the watch 1.

FIG. 5 is a diagram showing a photographic example of the cross section AA'of FIG. 3 after melting and diffusing the chromium applied to the permalloy with a laser to make the demagnetization rate about 95% in the present embodiment. ..
In FIG. 5, the vertical direction (z-axis direction) is the plate thickness direction of the base material 240. The laser is emitted from the first surface f11 side, which is the surface coated with chromium. In FIG. 5, after the chromium was applied, the chromium was irradiated with a laser having a laser power of about 200 W for an irradiation time of 4 ms to diffuse and melt the chromium. In this case, the laser was passed through the base material 240 in the plate thickness direction, and the base material 240 evaporated accordingly, and the volume of the base material 240 decreased. However, as shown in FIG. 5, from the first surface f11 of the base material 240. A left protrusion 261 at a height h13 and a right protrusion 262 at a height h14 were formed. Further, assuming that the demagnetization rate of the normal integrated type is 0%, the demagnetization rate of the molten portion 260 described later was about 95%.

The melting part 260 is a melting part melted by laser irradiation.
The left protrusion 261 (protrusion) is a protrusion formed on the first surface f11 of the base material 240 and the molten portion 260, projecting in the plate thickness direction of the base material 240, and formed by laser irradiation. The height of the left protrusion 261 from the first surface f11 of the base material 240 is h13. Therefore, in the portion where the left protrusion 261 is formed, the total thickness h6 of the thickness h1 of the base material 240 and the height h13 of the left protrusion 261 is thicker than the thickness h1 of the base material 240. There is.
The right protrusion 262 (protrusion) is a protrusion formed on the first surface f11 of the base material 240 and the molten portion 260, projecting in the plate thickness direction of the base material 240, and formed by laser irradiation. The height of the right protrusion 262 from the first surface f11 of the base material 240 is h14. Therefore, in the portion where the right protrusion 262 is formed, the total thickness h7 of the thickness h1 of the base material 240 and the height h14 of the right protrusion 262 is thicker than the thickness h1 of the base material 240. There is.
Further, the left protrusion 261 (horny dross) and the right protrusion 262 (horny dross) are dross formed by laser irradiation. The protrusions (left protrusion 261 and right protrusion 262) are provided on the supersaturated portions (210, 211 (FIGS. 2 and 3)). The protrusion has a diffusion region having a different chromium weight ratio from the base material 240.
The groove portion 263 is a groove portion formed by laser irradiation. The depth of the groove portion 263 from the first surface f11 of the base material 240 is h12, and the width of the groove portion 263 in the longitudinal direction is w12. Therefore, the groove portion 263 is lower than the first surface f11 of the base material 240 by h12.

The example shown in FIG. 5 is an example in which a angular dross is formed.
As shown in FIG. 5, the stator 201 includes a groove portion 263 provided in the protrusions (left protrusion 261 and right protrusion 262).
As shown in FIG. 5, when the demagnetization rate is around 95%, the protrusions (left protrusion 261 and right protrusion 262) and the groove 263 so as to protrude only from the first surface f1 side of the base material 240. Are continuously provided, and protrusions (left protrusion 261 and right protrusion 262) are provided at two positions on the left and right, centering on the groove 263.
Further, the protrusions (left protrusion 261 and right protrusion 262) are provided on the supersaturated portions 210 and 211.
The heights h13 and h14 of the protrusions (left protrusion 261 and right protrusion 262) are, for example, 1/10 or less of the thickness h1 of the base material 240. Further, the depth h12 of the groove portion 263 is, for example, 2/5 or less of the thickness h1 of the base material 240. The depth of the groove in FIG. 5 is an example in the case where the groove is formed in the base metal 240. Further, in the example of FIG. 5, the value of the depth h12 of the groove portion 263 is larger than the value of the width w12 of the groove portion 263. To form in this way, a laser with a high discharge depth is used.

As shown in FIG. 5, the stator 201 of the present embodiment has protrusions (left protrusion 261 and right protrusion 262) in supersaturated portions (210, 211 (FIG. 3)) having a narrow width. .. In the stator 201 of the present embodiment, the protrusion is thicker than the first surface f1 of the base material 240. Further, the stator 201 of the present embodiment is formed without the second surface f12 being deformed.
Further, according to the present embodiment, the depth h12 of the groove portion 263 from the first surface f11 of the base material 240 is, for example, 2/5 or less of the thickness h1 of the base material 240.

As a result, according to the present embodiment, the thickness of the groove portion can be secured as compared with the configuration of FIG. 12, so that deformation due to an external force generated at the time of handling the stepping motor 7 and assembling the stepping motor 7 is less likely to occur.
As a result, according to the present embodiment, deformation due to external force generated during handling of the stepping motor 7 and assembly of the stepping motor 7 is unlikely to occur. Therefore, as will be described later, the change in magnetic characteristics due to deformation of the stator 201 is reduced. Can be done.
Further, according to the present embodiment, the height (h13 or h14) of the protrusions (left protrusion 261 and right protrusion 262) from the first surface f11 is 1/10 or less of the thickness of the base material. When the stepping motor 7 having the stator 201 is attached to the watch 1, it is possible to prevent the watch 1 from interfering with parts such as gears.

Next, the shape of the stator 201 of FIG. 3 when viewed in the xy plane will be described.
FIG. 6 is an enlarged view of a part of the stator 201 of FIG. 3 according to the present embodiment in the xy plane. As shown in FIG. 6, the groove portion (left groove portion 252, right groove portion 253) is formed around the protrusion 251. With this configuration, for example, even if a force is applied to the stator 201 during manufacturing, the groove portion becomes a refuge for the applied external force. Therefore, according to the configuration according to the present embodiment, as compared with the stator to which the demagnetization treatment is applied as shown in FIG. 12, it is more resistant to deformation against external force and maintains the same strength as the integrated stator. can do.

<Explanation of manufacturing method>
Next, an example of a method for manufacturing the stator 201 will be described with reference to FIGS. 7 and 8. FIG. 7 is a diagram showing an example of a method for manufacturing the stator 201 according to the present embodiment.

(1st manufacturing process 1st press (creating guide holes))
In the first manufacturing process, the manufacturing system 300 includes a press device 302. Further, the hoop material before pressing is wound in a roll shape upstream of the pressing device 302 (reference numeral 301). In FIG. 7, the longitudinal direction of the hoop material is the x-axis direction, and the lateral direction is the y-axis direction. The width of the hoop material in the lateral direction is, for example, 16.5 mm.

The press device 302 forms guide holes 312 and 313 for positioning in the lateral direction of the hoop material as shown by reference numeral 310 with respect to the magnetic material (38 permalloy or the like) in the state of the hoop material. After pressing, the manufacturing system 300 winds the pressed hoop material into a roll as shown by reference numeral 303.

(2nd manufacturing process non-magnetic region creation)
In the second manufacturing step, the manufacturing system 300 includes a paste coating device 322 for applying a paste of chromium (Cr), a drying device 323, a laser irradiation device 324, and a cleaning device 325. The hoop material after pressing in the first manufacturing step is wound in a roll shape upstream of the paste coating apparatus 322 (reference numeral 321).

The paste coating device 322 applies a paste of chromium to the hoop material at a desired position in the y-axis direction (coating step). The paste coating device 322 mixes, for example, chromium with a binder to make a paste, and dispenses it. That is, the paste application device 322 is a dispenser. The desired position in the y-axis direction is a region for creating supersaturated portions 210 and 211, which are non-magnetic regions in the stator 201 shown in FIG. The paste coating device 322 pastes and coats chromium at a desired position based on the position of the guide hole. The coating thickness of Cr is, for example, 150 to 200 [micron].
Subsequently, the drying device 323 dries the chromium paste-coated on the hoop material.

Subsequently, the laser irradiation device 324 irradiates the region (reference numeral 331) to which the chromium paste is applied with a laser (laser processing step). The laser is preferably a fiber laser having a deep discharge depth. As a result, the applied chromium dissolves in the base material (permalloy material). Then, diffusion melting occurs between the applied chromium and the chromium inside the permalloy material, and a region having a chromium weight ratio of 15% or more is formed. The region where the chromium paste is applied by laser irradiation becomes 1900 degrees or more, which is equal to or higher than the melting point of the permalloy material and Cr. The diameter of the incident side of the laser is about 0.3 to 0.5 mm. Further, the laser irradiation device 324 irradiates the laser in the x-axis direction at intervals of, for example, 25 [microns]. As a result, the heat generated by the laser irradiation applied to the base material (hoop material) can be reduced.

Subsequently, the cleaning device 325 removes unnecessary portions of the applied chromium by cleaning with a solvent. When the hoop material after laser irradiation and cleaning is viewed from the upper surface, a non-magnetic region is formed in a region (reference numeral 331) to which chromium is past-coated as in reference numeral 310A. The width of the non-magnetic region in the y-axis direction is about 0.3 to 0.5 mm. As described above, in the second manufacturing step, a non-magnetic region on a straight line continuous with respect to the hoop material in the x-axis direction is formed at a predetermined position in the y-axis direction. The time required for washing is, for example, 5 minutes.
After cleaning, the manufacturing system 300 winds the hoop material after forming the non-magnetic region into a roll shape as shown by reference numeral 326.

(Third manufacturing process 2nd press (finishing))
In the third manufacturing process, the manufacturing system 300 includes a press device 342 which is a finishing device. The hoop material after the second manufacturing step is wound in a roll shape upstream of the press device 342 (reference numeral 341).
In the press device 342, the press punching is performed so that the portions where the chromium weight ratio is, for example, 15% or more are the supersaturated portions 210 and 211 of the stator 201 as shown in FIG. 8 with reference to the positions of the guide holes 312 and 313. I do. FIG. 8 is a top view showing the hoop material of the stator 201 according to the present embodiment before pressing. The stator 201'is a stator before the fourth manufacturing process. The manufacturing system 300 (FIG. 7) presses and punches the stator 201'at the position of reference numeral 201'' in FIG. The press punching is performed by punching a part of the non-magnetic region so as to surround the rotor 202 for the stepping motor 7. That is, the rotor accommodating hole 203 is also formed at the same time by the third manufacturing process. After pressing, the manufacturing system 300 winds the hoop material after pressing and removing the stator 201 into a roll shape as shown by reference numeral 343.
As a result, the outer shape of the stator 201'in which the chrome weight ratio differs between the narrow portion and the other portion is completed.

(4th manufacturing process magnetic annealing)
In the fourth manufacturing process, the manufacturing system 300 includes an annealing furnace 351.
The annealing furnace 351 performs a high temperature annealing treatment on the stator 201'. As a result, residual stress is removed / relaxed by press working in the third manufacturing process.

The manufacturing system 300 manufactures the stator 201 shown in FIG. 3 by the first to fourth manufacturing steps described above.
The manufacturing method described with reference to FIGS. 7 and 8 is an example, and is not limited thereto.

Next, the stepping motor 7 according to the present embodiment will be described in detail with reference to FIG.
FIG. 9 is a front schematic view of the stepping motor 7 according to the present embodiment.
The stepping motor 7 shown in FIG. 9 includes a rotor accommodating hole 203, a stator 201, a rotor 202, a magnetic core 208, a coil 209, and supersaturated portions 210 and 211.

The rotor 202 is a two-pole rotor rotatably arranged in the rotor accommodating hole 203. The magnetic core 208 is joined to the stator 201. The coil 209 is wound around a magnetic core 208.

The supersaturated portions 210 and 211 are provided in portions that do not interfere with the cutout portions 204 and 205 provided in the rotor accommodating holes 203 in order to secure a stable position of the rotor 202. The coil 209 has a first terminal OUT1 and a second terminal OUT2.

The rotor accommodating hole 203 is formed in a circular hole shape in which a plurality of (two in the example of FIG. 9) half-moon-shaped notches 204 and 205 are integrally formed at a portion facing the through hole having a circular contour. .. These notch portions 204 and 205 are configured as positioning portions for determining the stop position or the stationary stable position of the rotor 202. For example, the notch 204 has an effect of stabilizing the position of the rotor by lowering the potential energy of the rotor when the rotor is in a predetermined position.

The rotor 202 is magnetized in two poles (S pole and N pole).
In the state where the coil 209 is not excited, the rotor 202 is located at a position corresponding to the positioning portion as shown in FIG. 9, in other words, the magnetic pole axis A of the rotor 202 is a line segment connecting the cutout portions 204 and 205. It is stably stopped (stationary) at a position (angle θ _{0 position) orthogonal to.}

Supersaturated portions 210 and 211 in the non-magnetic region are formed in a part of the magnetic paths R provided around the rotor accommodating hole 203 (two places in the example of FIG. 9). Here, the width of the cross section of the supersaturated portion of the stator 201 is defined as the cross-sectional width t, and the width in the direction along the magnetic path is defined as the gap width w. The supersaturated portions 210 and 211 are formed in a region defined by a cross-sectional width t and a gap width w.
In the following description, in the stator 201, the outer periphery of the supersaturated portion 211 is defined as a point a1, the inside of the supersaturated portion 211 is defined as a point b1, and the vicinity of the supersaturated portion 211 and between the outer circumference and the inner circumference of the magnetic path R are defined as a point c.

Next, the operation of the stepping motor 7 according to the present embodiment will be described with reference to FIG.
First, a drive pulse signal is supplied from the pulse drive circuit 6 between the terminals OUT1 and OUT2 of the coil 209 (for example, the first terminal OUT1 side is the positive electrode and the second terminal OUT2 side is the negative electrode), and the current i is in the direction of the arrow in FIG. A magnetic flux is generated in the stator 201 in the direction of the arrow.

In the present embodiment, supersaturated portions 210 and 211, which are non-magnetic regions, are formed, and the reluctance in the regions is increased. Therefore, it is not necessary to magnetically saturate the region corresponding to the conventional "narrow portion", and the leakage magnetic flux can be easily secured. After that, the interaction between the magnetic poles generated in the stator 201 and the magnetic poles of the rotor 202 causes the rotor 202. is rotated 180 degrees in the direction of the arrow in FIG. 9, the magnetic pole axis is stably stopped at an angle theta ₁ position (stationary).
In the present embodiment, the rotation direction (counterclockwise in FIG. 9) for rotating the stepping motor 7 to perform normal operation (hand movement operation because each embodiment of the present invention is an analog electronic clock) is performed. The direction) is the forward direction, and the opposite (clockwise direction) is the reverse direction.

Next, the pulse drive circuit 6 supplies drive pulses of opposite polarity to the terminals OUT1 and OUT2 of the coil 209 (the first terminal OUT1 side is the negative electrode and the second terminal OUT2 side so as to have the opposite polarity to the drive). When a current is passed in the direction of the counter-arrow in FIG. 9, magnetic flux is generated in the stator 201 in the direction of the counter-dashed arrow.
After that, since the supersaturated portions 210 and 211, which are non-magnetic regions, are formed as described above, the leakage magnetic flux can be easily secured, and the interaction between the magnetic poles generated in the stator 201 and the magnetic poles of the rotor 202 causes the magnetic flux to leak. The rotor 202 rotates 180 degrees in the same direction (positive direction) as described above, and the magnetic flux axis stably stops (stationary) at an _{angle θ 0 position.}

After that, by supplying signals having different polarities (alternating signals) to the coil 209 in this way, the operation is repeated, and the rotor 202 can be continuously rotated by 180 degrees in the arrow direction. ..

As described above, in the stepping motor 7 having the stator 201, since the supersaturated portions 210 and 211 which are non-magnetic regions are formed in a part of the magnetic path around the rotor accommodating hole 203, the magnetic flux consumed in the region is formed. Can be significantly reduced, and the leakage magnetic flux that drives the rotor 202 can be efficiently secured.
Further, by forming supersaturated portions 210 and 211, which are non-magnetic regions, in a portion previously regarded as a "narrow portion" to reduce the magnetic permeability, the magnetic flux generated from the rotor 202 itself can also be generated in the region. Consumption is curtailed. As a result, according to the stepping motor 7, the loss of the magnetic potential can be prevented, and the holding force for magnetically stopping (stationing) and holding the rotor 202 can be increased.

Further, after the portion that was conventionally regarded as the "narrow portion" is saturated with the magnetic flux on the OUT1 side (negative electrode) and rotated, it occurs on the OUT1 side (negative electrode) to rotate on the OUT2 side (positive electrode). It was necessary to cancel the residual magnetic flux. However, according to the present embodiment, since the residual magnetic flux in the region is significantly reduced, the time required for canceling the residual magnetic flux is not required, and the time until the rotation is converged can be shortened. Therefore, according to the present embodiment, it is possible to maintain operational stability when performing high-speed hand movement, and it is possible to increase the drive frequency.

<Relationship between the arrangement of gears around the stator and the notch on the outside of the stator>
Next, the relationship between the arrangement of the gears around the stator and the notch on the outside of the stator will be described.
FIG. 10 is a diagram for explaining the relationship between the arrangement of gears around the stator and the notch on the outside of the stator. In this example, in order to show the relationship between the stator 201 and the main plate 51, the motor 40 provided in the hour hand drive mechanism will be described.
The motor 40 is an example of a stepping motor 7, a rotor 45 is an example of a rotor 202, a stator 44 is an example of a stator 201, a rotor hole 44a is an example of a rotor accommodating hole 203, and a magnetic core 42 is a magnetic core. The 208 is an example, the coil wire 43 is an example of the coil 209, and the screw 48 is an example of the screw 220. Notches 204 and 205 of the stator 44 are provided around the rotor accommodating hole 203.

The main plate 51 constitutes the substrate of the mechanical module of the clock 1. The main plate 51 is formed in a plate shape having an axial direction as a plate thickness direction, for example, by using a resin material or the like.

The hour hand drive mechanism rotates the hour hand 12. The hour hand drive mechanism includes a motor 40 and an hour wheel train. Note that FIG. 10 shows only the first hour intermediate gear 31 that meshes with the kana 45a of the rotor 45 in the hour wheel train.

The motor 40 is a stepping motor in which the rotor 45 rotates 180 ° in one step. The motor 40 is provided in a coil block 41 including a magnetic core 42 and a coil wire 43 wound around the magnetic core 42, a stator 44 arranged so as to contact both ends of the magnetic core 42 of the coil block 41, and a rotor hole 44a of the stator 44. It has an arranged rotor 45 and.

The coil block 41 includes a magnetic core 42, a coil wire 43, and a coil lead substrate 46 fixed to one end of the magnetic core 42.

The magnetic core 42 extends along a direction orthogonal to the axial direction and the radial direction. The magnetic core 42 is fixed to the main plate 51 by screws 48 at both ends thereof. The coil lead board 46 is a printed circuit board. The coil lead substrate 46 is arranged on the front side of one end of the magnetic core 42, and is fastened together with the magnetic core 42 by screws 48. The coil lead substrate 46 extends from a fixed portion to one end of the magnetic core 42 toward the central portion of the main plate 51 when viewed from the axial direction. A pair of wirings 47 are formed on the surface of the coil lead substrate 46. The end of the coil wire 43 is welded to, for example, one end 47a of each wiring 47 on the magnetic core 42 side.

The stator 44 is arranged radially inside the magnetic core 42. The stator 44 is fastened to the main plate 51 together with the magnetic core 42 by a pair of screws 48.

The rotor 45 is arranged inside the magnetic core 42 in the radial direction. The rotor 45 is rotatably supported by a main plate 51 and a train wheel receiver (not shown) (see FIG. 9).

<Changes in stator deformation characteristics>
Next, an example of characteristic change when the stator 201 is deformed will be described.
FIG. 11 is a diagram showing a BH curve when the stator 201 is returned to a flat state before and after the deformation. In FIG. 11, the horizontal axis is the magnetic field [A / m] and the vertical axis is the magnetic flux density [T].
The deformed stator 201 is returned to flat, such as the BH curve (reference numeral g101) before bending the stator 201 and the BH curve (reference numeral g102) after the stator 201 is bent and then flattened. The characteristics are also changing. Since the amount of deformation of the characteristics is non-uniform due to errors during manufacturing and assembly and cannot be controlled, the variation in motor quality becomes extremely large when the stator is deformed.

On the other hand, in the stator 201 of the present embodiment, the protrusions formed on the supersaturated portions (210, 211 (FIG. 3)) having a narrow width are thicker than the first surface of the base material. Since the second surface is formed without being deformed, it is less likely to be deformed by an external force generated during handling of the stepping motor 7 and assembly of the stepping motor 7 as compared with the configuration of FIG.
As a result, the stator 201 of the present embodiment can reduce deformation during manufacturing and the like, so that changes in characteristics due to deformation of the stator 201 can be reduced.

As a result, according to the present embodiment, when the magnetic two-body type stator is realized, the influence of the decrease in strength on the external force is suppressed, so that the stator is compared with the stator to which the demagnetization treatment as shown in FIG. 12 is applied. Therefore, it is possible to provide a high-quality stator 201 that is strong against external force and has little change in characteristics due to deformation during manufacturing or the like. As a result, according to the present embodiment, it is possible to provide a stepping motor 7 having a stator 201 that is strong against an external force and a watch 1 having a stepping motor 7 having a stator 201 that is strong against an external force.

201 ... Stator, 202 ... Rotor, 203 ... Rotor accommodating hole, 204, 205 ... Notch, 208 ... Magnetic core, 209 ... Coil, 210, 211 ... Supersaturated part, 218a, 218b ... Screw hole, 240 ... Base material, 251 , 261,262 ... Protrusions, 252, 253, 263 ... Grooves, 7 ... Stepping motors, 1 ... Clocks, R ... Magnetic circuits, f1, f11 ... First surface, f2, f12 ... Second surface

Claims (10)

A stator base material that is composed of an integral magnetic material and has through holes in which the rotor can be placed.
A magnetic path that generates magnetic poles in the base material of the stator around the through hole when the coil is excited, and
A supersaturated portion formed so that the cross-sectional area of the magnetic path is narrower than that of other portions,
The supersaturated portion is provided with a protrusion so as to project from only the first surface of the base material of the stator, and has a diffusion region having a chromium weight ratio different from that of the base material.
Grooves provided in the protrusions and
To prepare
Stator. The protrusion and the groove are continuously provided.
The stator according to claim 1. The groove is provided symmetrically with respect to the protrusion.
The stator according to claim 1 or 2. The protrusion is provided symmetrically with respect to the groove.
The stator according to claim 1 or 2. The height of the protrusion from the first surface is 1/10 or less of the thickness of the base material.
The stator according to any one of claims 1 to 4. The depth of the groove from the first surface is 2/5 or less of the thickness of the base material.
The stator according to any one of claims 1, 2 and 4. The width of the groove is 1/4 or less of the thickness of the base material.
The stator according to any one of claims 1, 2, 4, and 6. The depth of the groove is larger than the width of the groove.
The stator according to any one of claims 1, 2, 4, 6 and 7. The stator according to any one of claims 1 to 8.
A stepper motor equipped with. A timepiece including the stepping motor according to claim 9.

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