JP7491078B2 - Coil block, manufacturing method thereof, motor, and watch - Google Patents

Description

This invention relates to a coil block used in electronic devices such as watches, a manufacturing method thereof, a motor equipped with the same, and a watch equipped with them.

For example, in the field of wristwatches, as described in Patent Document 1, there are known structures that include a step motor for moving the hands. This type of step motor includes a coil block, a stator to which the magnetic field generated by the coil block is guided, and a rotor that is rotatably arranged in the rotor hole of the stator, and is configured so that the rotor rotates in response to the magnetic field generated by the coil block.

JP 2016-130676 A

The coil block of such a step motor includes a coil core, a coil formed by winding a wire around the coil core, and a connection board that is provided at the end of the coil core adjacent to the coil and to which the coil winding is connected. In this case, the connection board is formed in a flat plate shape and has a pair of electrode pieces on one side, the coil winding is connected to the pair of electrode pieces, and the pair of electrode pieces to which the winding is connected are sealed with sealing resin.

In such coil blocks, when a circuit board is placed on one side of a connection board on which a pair of electrodes are provided, and the pair of electrodes are brought into contact with the circuit board to connect them, the sealing resin protrudes higher than the pair of electrodes, so it is necessary to provide an escape hole in the circuit board through which the sealing resin can be inserted. This creates a problem in that high-density mounting is not possible because the wiring on the circuit board is restricted by the escape hole.

The problem that this invention aims to solve is to provide a coil block that can improve the packaging density of a circuit board without placing restrictions on the circuit board, a manufacturing method thereof, a motor equipped with the same, and a watch equipped with the same.

This invention is a coil block comprising a substrate to which a coil winding is connected, the substrate having a storage surface that is lower than one surface of the substrate, and an electrode portion that is arranged on the one surface and has at least a portion arranged on the storage surface to which the coil winding is connected , the electrode portion being an electrode piece at least a portion of which is bent one step lower, the electrode piece including a contact portion that is exposed on the one surface side of the substrate, and a connection portion that is exposed on the one surface side of the storage surface and to which the coil winding is connected.

This invention makes it possible to improve the packaging density of a circuit board without imposing any restrictions on the circuit board.

1 is an enlarged front view showing an embodiment in which the present invention is applied to a wristwatch. FIG. 2 is an enlarged rear view of the watch module of the wristwatch shown in FIG. 1 . 3 is an enlarged rear view of the watch module shown in FIG. 2 with the circuit board removed. FIG. FIG. 4 is an enlarged front view showing a first step motor of the clock module shown in FIG. 3 . FIG. 4 is an enlarged front view showing a second step motor of the clock module shown in FIG. 3 . 5 shows a coil block in the first step motor shown in FIG. 4, where (a) is an enlarged front view, (b) is an enlarged side view of the coil block in (a) seen from the bottom side, (c) is an enlarged side view of the coil block in (a) seen from the top side, and (d) is an enlarged side view of the coil block in (a) seen from the left side. 7 is an enlarged cross-sectional view of the coil block shown in FIG. 6(a) taken along the line AA. 7A and 7B show a connection board of the coil block shown in FIG. 6, in which (a) is an enlarged front view, (b) is an enlarged side view of the connection board of (a) seen from the bottom side, and (c) is an enlarged side view of the connection board of (a) seen from the right side. 7 is an enlarged plan view showing a state in which an electrode portion of a connection board is formed on a metal plate by pressing in the method for manufacturing the coil block shown in FIG. 6 . 10A is an enlarged plan view showing part A of FIG. 9, (b) is an enlarged cross-sectional view taken along the line B-B of (a), and (c) is an enlarged cross-sectional view taken along the line C-C of (a). 8A and 8B show a molding die used when insert-molding an electrode portion in the manufacturing method of the coil block shown in FIG. 6, where (a) is an enlarged cross-sectional view taken along the line D-D in FIG. 8A, and (b) is an enlarged cross-sectional view taken along the line F-F in FIG. 8A. 12 is an enlarged front view showing the connection board in a state molded by the molding die shown in FIG. 11 . FIG. 13 is an enlarged front view showing a modified example of a step motor provided with the coil block of the present invention.

An embodiment in which the present invention is applied to a wristwatch will now be described with reference to FIGS.
As shown in Fig. 1, this wristwatch has a wristwatch case 1. Inside this wristwatch case 1, a watch module 2 shown in Fig. 2 is provided.

This timepiece module 2, as shown in Figure 2, has a housing 3. The front surface of this housing 3 (the back surface in Figure 2) is provided with the dial 4 shown in Figure 1. A number of hour characters 4a are provided at equal intervals along the periphery of this dial 4. Also, as shown in Figure 2, a circuit board 5 is attached to the back surface of this housing 3 (the front surface in Figure 2). Furthermore, various parts necessary for the timepiece functions, such as an antenna 6, are mounted on this housing 3.

As shown in FIG. 1, the clock module 2 has a first display section 7 that indicates the current time, a second display section 8 that indicates world time, which is the time in a selected city among cities around the world, a third display section 9 that indicates a 24-hour time, and a fourth display section 10 that indicates the day of the week, charging status, mode, and date.

As shown in Figures 1 and 3, the first display unit 7 is provided over almost the entire area of the dial 4 and includes a second hand 7a, minute hand 7b, and hour hand 7c that move above the dial 4, and a first movement 11 that moves the second hand 7a, minute hand 7b, and hour hand 7c by rotating them on the same axis. As a result, the first display unit 7 is configured to indicate the time by having the first movement 11 move the second hand 7a, minute hand 7b, and hour hand 7c above the dial 4, and these second hand 7a, minute hand 7b, and hour hand 7c point to the hour character 4a on the dial 4.

As shown in Figures 1 and 3, the second display unit 8 is provided in a second region E1 between the 6 o'clock to 9 o'clock side of the dial 4 and the center of the dial 4. This second display unit 8 includes a world time minute hand 8a, hour hand 8b, and 24-hour hand 8c that move above the second region E1 of the dial 4, and a second movement 12 that drives the minute hand 8a, hour hand 8b, and 24-hour hand 8c.

As a result, as shown in Figures 1 and 3, the second display unit 8 is configured to move the world time minute hand 8a, hour hand 8b, and 24-hour hand 8c above the second area E1 of the dial 4 using the second movement 12 to indicate the hour, minute, and am/pm of world time, which is the time in a selected city among cities around the world.

As shown in Figures 1 and 3, the third display unit 9 is provided in a third region E2 between the area from the 9 o'clock side to the 11 o'clock side of the dial 4 and the center of the dial 4. This third display unit 9 is equipped with a first sub-hand 9a for 24 hours that moves above the third region E2 of the dial 4, and a third movement 13 that moves this first sub-hand 9a. As a result, the third display unit 9 is configured to indicate 24-hour time by moving the first sub-hand 9a above the third region E2 of the dial 4 by the third movement 13.

As shown in Figures 1 and 3, the fourth display unit 10 is provided in a fourth region E3 between the 2 o'clock to 4 o'clock side of the dial 4 and the center of the dial 4, and in a window E4 between the 4 o'clock and 5 o'clock sides of the dial 4. This fourth display unit 10 includes a second sub-hand 10a that moves above the fourth region E3 of the dial 4 to indicate functions such as the day of the week, charging status, and mode, a ring-shaped date wheel 10b that rotates below the window E4 of the dial 4 to switch between dates, and a fourth movement 14 that drives the second sub-hand 10a and the date wheel 10b.

As a result, as shown in Figures 1 and 3, the fourth display unit 10 is configured to use the fourth movement 14 to move the second sub-hand 10a above the fourth region E3 of the dial 4 to indicate functions such as the day of the week, charging status, and mode, and to rotate the ring-shaped date wheel 10b below the window portion E4 of the dial 4 to switch the date displayed on the date wheel 10b.

As shown in FIG. 3, the first movement 11 of the first display unit 7 is equipped with a first step motor 16 that drives the second hand 7a, a second step motor 17 that drives the minute hand 7b, and a third step motor 18 that drives the hour hand 7c. In this case, the first to third step motors 16 to 18 are configured to move the second hand 7a, minute hand 7b, and hour hand 7c, respectively, via a gear train mechanism (not shown).

The second movement 12 of the second display unit 8 is equipped with a fourth step motor 19 that drives the world time minute hand 8a, hour hand 8b, and 24-hour hand 8c, as shown in FIG. 3. In this case, the fourth step motor 19 is also configured to move the world time minute hand 8a, hour hand 8b, and 24-hour hand 8c via a gear train mechanism (not shown).

As shown in FIG. 3, the third movement 13 of the third display unit 9 also serves as the third step motor 18 that drives the hour hand 7c of the first movement 11, and is configured to drive the first 24-hour sub-hand 9a by this third step motor 18. In this case, the third step motor 18 is also configured to drive the first 24-hour sub-hand 9a via a gear train mechanism (not shown) separate from the first movement 11.

The fourth movement 14 of the fourth display unit 10 is equipped with a fifth step motor 20 that drives the second sub-hand 10a and the date wheel 10b, as shown in FIG. 3. In this case, the fifth step motor 20 is also configured to move the second sub-hand 10a, which indicates functions such as the day of the week, charging status, and mode, via a train wheel mechanism (not shown), and to rotate the ring-shaped date wheel 10b.

In this case, the first step motor 16 and the fifth step motor 20 are first step motors of the same type and structure as shown in FIG. 3. The second to fourth step motors 17 to 19 are second step motors of different types and structure from the first and fifth step motors 16 and 20.

That is, as shown in FIG. 4, the first and fifth step motors 16 and 20, which are the first step motors, are structured to include one coil block 21, a stator 22 with a rotor hole 22a and attached across both ends of the coil block 21, and a rotor 23 that is disposed within the rotor hole 22a of the stator 22 and rotates in response to a magnetic field generated by a coil 26 of the coil block 21, which will be described later.

In this case, as shown in FIG. 4, the stator 22 is formed in a strip shape from a magnetic material with high magnetic permeability, and each yoke 22b at both ends is attached to both ends of the coil block 21 by screws or the like. The rotor hole 22a is provided in the center of the stator 22. The rotor 23 includes a rotor body 23a, which is a cylindrical permanent magnet magnetized with two poles, a rotating shaft 23b provided on the rotor body 23a, and a rotor pinion (pinion) 23c provided on the rotating shaft 23b.

As a result, the first and fifth step motors 16 and 20, which are the first step motors, are configured so that the rotor body 23a of the rotor 23 rotates around the rotation axis 23b in response to the magnetic field generated by the coil 26, as shown in Figure 4, and the rotation is transmitted to each gear train mechanism (not shown) of the first movement 11 and the third movement 13 by the rotor pinion 23c.

On the other hand, the second to fourth step motors 17 to 19, which are the second step motors, are structured as shown in FIG. 5, with two coil blocks 21, a stator 22 with rotor holes 22a that are attached across each end of the two coil blocks 21, and a rotor 23 that is placed in the rotor hole 22a of the stator 22 and rotates in response to the magnetic field generated by each coil 26 of the two coil blocks 21.

In this case, as shown in FIG. 5, one end (the lower end in FIG. 5) of each of the two coil blocks 21 is formed to have a shape different from that of the coil blocks 21 of the first and fifth step motors 16 and 20, but otherwise has the same structure as the coil blocks 21 of the first and fifth step motors 16 and 20. These two coil blocks 21 are arranged in parallel so that they are linearly symmetrical when the one end with the different shape and the other end opposite, that is, the end to which the connection board 27 described below is attached, are brought close to each other and butted against each other.

As shown in FIG. 5, the stator 22 is formed into a plate shape with an overall shape that is roughly an inverted T, and other than this, it has the same structure as the coil blocks 21 of the first and fifth step motors 16 and 20. This stator 22 is disposed between the coil blocks 21 that are arranged in parallel.

As shown in FIG. 5, the stator 22 has a first yoke 22c at the top end of the approximately inverted T shape attached to the other ends of the two coil blocks 21 that are close to each other and correspond to each other by screws or the like. Also, the stator 22 has second yokes 22d at both ends of the lower side of the approximately inverted T shape attached to the corresponding ends of the two coil blocks 21 by screws or the like. In this case, the rotor hole 22a of the stator 22 is provided in the center of the stator 22 where the vertical bar portion and horizontal bar portion of the approximately inverted T shape intersect.

As shown in FIG. 5, the rotor 23 has the same structure as the rotor 23 of the first and fifth step motors 16 and 20. As a result, the second to fourth step motors 17 to 19, which are the second step motors, are configured so that the rotor body 23a of the rotor 23 rotates around the rotation axis 23b in response to the magnetic field generated by the two coils 26, as shown in FIG. 5, and the rotation is transmitted to each gear train mechanism (not shown) of the first, second and fourth movements 11, 12 and 14 by the rotor pinion 23c.

In this case, as shown in FIG. 5, the second to fourth step motors 17 to 19 are configured so that the magnetic field generated by the two coil blocks 21 is stronger than the magnetic field of the first and fifth step motors 16 and 20, and the rotational torque of the rotor 23 is higher than the rotational torque of the first and fifth step motors 16 and 20.

As shown in FIG. 6, each coil block 21 of the first to fifth step motors 16 to 20 includes a coil core 25, a coil 26 having a winding 26a wound around the middle of the coil core 25, and a connection board 27 that is provided at one end of the coil core 25 adjacent to the coil 26 and to which the winding 26a of the coil 26 is connected.

As shown in Figures 6(a) to 6(d), the coil core 25 is formed in a substantially plate-like shape from the same high-permeability magnetic material as the stator 22. The coil core 25 comprises a substantially rectangular core body 25a and mounting portions 25b provided at both ends of the core body 25a. In this case, the mounting portions 25b are each provided to protrude toward one side in a direction perpendicular to the longitudinal direction of the core body 25a (the lower side in Figure 6(a)). The portions of the mounting portions 25b that protrude toward one side are each provided with a mounting hole 25c.

As shown in Figures 6(a) to 6(d), the coil 26 is formed by winding wire 26a around the core body 25a of the coil core 25. As shown in Figures 6 to 8, the connection board 27 is formed in a plate shape of the same shape as the mounting part 25b of the coil core 25, from a resin such as a liquid crystal polymer. One surface of the connection board 27 is provided with a recessed portion 27a, which is a storage surface that is set lower than the first surface. This recessed portion 27a is provided adjacent to one end of the coil 16.

That is, as shown in Figs. 6 to 8, the recess 27a is open on the front surface of the connection board 27, on the side surface corresponding to one end of the coil 26, and on the side surface of the upper edge of the connection board 27. The depth of the recess 27a is approximately half the thickness of the connection board 27. In this case, the bottom surface of the recess 27a is formed as a flat surface, and the inner wall surface is formed as an inclined surface 27b with a draft angle. The connection board 27 also has a board mounting hole 27c that is coaxial with the mounting hole 25c of the coil core 25.

As shown in Figs. 6 to 8, the connection board 27 is configured such that the electrode portion 28 is exposed on the surface and the recessed portion 27a, and the winding 26a of the coil 26 is connected to the electrode portion 28. In other words, the electrode portion 28 is exposed on the surface side of the connection board 27, and a bent portion 30c of the electrode portion 28, which will be described later, is embedded in the connection board 27 by insert molding.

As shown in Figs. 6 to 8, this electrode section 28 has a pair of electrode pieces 30, a portion of which is bent down one step. Each of the pair of electrode pieces 30 has a contact section 30a that is one step higher and is embedded and exposed on the surface of the connection board 27, a connection section 30b that is one step lower and is embedded and exposed on the surface side of the connection board 27 at the bottom of the recess 27a of the connection board 27 and to which the winding 26a of the coil 26 is connected, and a bent section 30c that is embedded in the connection board 27 at the boundary between the contact section 30a and the connection section 30b.

In this case, as shown in Figures 6 to 8, the raised contact portion 30a of the pair of electrode pieces 30 is provided with a number of contact protrusions 30d that contact the pattern electrode (not shown) of the circuit board 5 that is arranged on the surface (top surface in Figure 7) of the connection board 27. In addition, the pair of electrode pieces 30 are each provided with a number of peel prevention protrusions 30e that protrude in the surface direction to prevent the pair of electrode pieces 30 from peeling off from the connection board 27. These multiple peel prevention protrusions 30e are also embedded in an exposed state on the surface side of the connection board 27.

Also, as shown in Figs. 6 and 7, sealing resin 31 is provided within recess 27a of connection board 27, which serves as a sealing portion that seals each connection portion 30b of a pair of electrode pieces 30 to which each end of winding 26a of coil 26 is connected within recess 27a. This sealing resin 31 is provided lower than the height of the surface of connection board 27 within recess 27a. As a result, sealing resin 31 is provided so as not to protrude from the surface of connection board 27.

Next, a method for manufacturing the coil block 21 will be described with reference to FIGS.
The manufacturing method of this coil block 21 includes a first step of forming electrode portion 28, a second step of forming connection board 27 having electrode portion 28 integrally formed therewith by insert molding, and a third step of attaching connection board 27 to one end of coil core 25 having coil 26 formed thereon.

In the first step, as shown in Figures 9 and 10, the metal plate 32 is punched out by press working to form an electrode section 28 in which a pair of electrode pieces 30, some of which are bent one step lower, are connected by a connecting section 33. As a result, the electrode section 28 is formed in a state in which the pair of electrode pieces 30 are formed with a contact section 30a that is one step higher, a connection section 30b that is one step lower, and a bent section 30c, and the pair of electrode pieces 30 are connected by the connecting section 33 and are also connected to the metal plate 32.

In the second step, as shown in Figures 11(a) and 11(b), the connection board 27 is formed integrally with the pair of electrode pieces 30 by insert molding. That is, in this second step, the pair of electrode pieces 30 are placed in a molding die 34, and the connecting portion 33 extending from the pair of electrode pieces 30 is sandwiched within the molding die 34, and the connection board 27 is molded in this state. In this case, the connection portion 30b of the pair of electrode pieces 30, which is bent one step lower, is placed in the recessed portion 27a of the connection board 27, and the connection board 27 is molded integrally with the pair of electrode pieces 30.

In this case, as shown in Fig. 11(a) and Fig. 11(b), the molding die 34 includes an upper die 35 and a lower die 36. When the upper die 35 and the lower die 36 are overlapped, the pair of electrode pieces 30 are placed inside the molding die 34 in advance, and when the upper die 35 and the lower die 36 are overlapped in this state, the connecting portion 33 extended from the pair of electrode pieces 30 is sandwiched between the upper die 35 and the lower die 36. As a result, the electrode portion 28 is fixed in the molding die 34 with the pair of electrode pieces 30 positioned in the molding die 34 by the connecting portion 33 and the contact protrusion 30d of the contact portion 30a.

In this state, as shown in FIG. 11(a), the contact portion 30a and the connection portion 30b of the pair of electrode pieces 30 are arranged in close contact with the inner surface of the upper die 35, and as shown in FIG. 11(b), the bent portion 30c of the pair of electrode pieces 30 and a part of each connection portion 30b are arranged in a floating state within the molding die 34. Also, in this state, as shown in FIG. 11(a) and FIG. 11(b), a hollow portion (cavity) 37 having the same shape as the connection board 27, including the recessed portion 27a and the board mounting hole 27c, is formed within the molding die 34.

In this state, resin 38 such as liquid crystal polymer is injected into cavity 37 in molding die 34. Then, bent portion 30c and part of connection portion 30b (i.e., the portion of connection portion 30b from bent portion 30c to recessed portion 27a) of the pair of electrode pieces 30 floating in cavity 37 of molding die 34 are embedded in resin 38, and contact portion 30a and connection portion 30b of the pair of electrode pieces 30 are embedded in resin 38 while being in close contact with the inner surface of upper die 35. As a result, connection board 27 is formed integrally with electrode portion 28.

In the third step, the connection board 27 is removed from the molding die 34, and this connection board 27 is attached to the mounting portion 25b on one end side of the coil core 25 on which the coil 26 is provided. In this case, when the connection board 27 is removed from the molding die 34, as shown in FIG. 12, the connecting portion 33 of the electrode portion 28 clamped by the molding die 34 protrudes from the outer periphery of the connection board 27. Therefore, the connecting portion 33 protruding from the outer periphery of the connection board 27 is cut at the cutting line S shown in FIG. 12 to separate the pair of electrode pieces 30. This results in the connection board 27 shown in FIG. 8(a).

In addition, in this third process, the ends of each winding 26a of the coil 26 are connected by solder or the like to each connection portion 30b of a pair of electrode pieces 30 arranged in a recessed portion 27a of a connection board 27 attached to an attachment portion 25b on one end side of the coil core 25. Then, each connection portion 30b to which the windings 26a are connected is sealed with sealing resin 31 within the recessed portion 27a. This forms the coil block 21 shown in Figures 6(a) to 6(d).

Next, a description will be given of the assembly of the first and fifth stepping motors 16 and 20, which are the first stepping motor shown in FIG.
4, first, the stator 22 is attached to the coil block 21. At this time, the yokes 22b at both ends of the stator 22 are attached to the mounting portions 25b at both ends of the coil core 25 of the coil block 21 by means of screws or the like.

In this state, the rotor 23 is rotatably placed in the rotor hole 22a of the stator 22. This completes the assembly of the first and fifth step motors 16, 20. The first and fifth step motors 16, 20 assembled in this manner are then attached to the housing 3 of the watch module 2 and electrically connected to the circuit board 5 attached to the housing 3.

In other words, when the circuit board 5 is placed on the back side of the housing 3 to which the first and fifth step motors 16, 20 are assembled, the multiple contact protrusions 30d provided on each contact portion 30a of a pair of electrode pieces 30 on the connection board 27 of each coil block 21 of the first and fifth step motors 16, 20 are electrically connected by point contact to the pattern electrodes (not shown) of the circuit board 5 without being obstructed by the sealing resin 31.

At this time, the lower connection portion 30b of the pair of electrode pieces 30 provided on the connection board 27 to which the winding 26a of the coil 26 in the coil block 21 is connected is disposed within the recessed portion 27a of the connection board 27. Therefore, as shown by the two-dot chain line in FIG. 7, when the circuit board 5 is disposed on the front (upper) side of the connection board 27, the multiple contact protrusions 30d provided on each contact portion 30a of the pair of electrode pieces 30 are electrically connected to the pattern electrode (not shown) of the circuit board 5 by point contact without being obstructed by the sealing resin 31.

Next, the operation of the first and fifth step motors 16, 20 assembled in this manner will be described. When current is supplied from the circuit board 5 to the coil 26 of the coil block 21 via the connection board 27, the first and fifth step motors 16, 20 generate a magnetic field in the coil 26, which is induced in the stator 22, and the rotor 23 rotates in steps in response to the induced magnetic field.

In this case, when the rotor 23 of the first step motor 16 rotates, the rotation of the rotor 23 is transmitted to the second hand 7a of the first display unit 7 via a gear train mechanism (not shown), and the second hand 7a moves above the dial 4 to indicate the second time. Also, when the rotor 23 of the fifth step motor 20 rotates, the rotation of the rotor 23 is transmitted to the second sub-hand 10a and date wheel 10b of the fourth display unit 10 via a gear train mechanism (not shown), and the second sub-hand 10a moves above the fourth region E3 of the dial 4 to indicate the day of the week, the charging state, or the mode, and the date wheel 10b of the fourth display unit 10 rotates below the window E4 of the dial 4 to change the date on the date wheel 10b.

Next, a description will be given of the case where the second to fourth stepping motors 17 to 19, which are the second stepping motor shown in FIG. 5, are assembled using the above-mentioned two coil blocks 21.
In this case, first, two coil blocks 21 are arranged in parallel as shown in Fig. 5. At this time, one end of each of both ends of the two coil blocks 21, that is, the end to which the connection board 27 is attached and which protrudes in one direction perpendicular to the longitudinal direction of the coil blocks 21, is brought close to each other and butted up against each other, and the coil blocks 21 are arranged in parallel so as to be linearly symmetrical.

In this state, the stator 22, which is approximately inverted T-shaped, is placed between the two coil blocks 21, and the first and second yokes 22c, 22d of the stator 22 are attached to each end of the two coil blocks 21 by screws. That is, the first yoke 22c at the upper end of the approximately inverted T-shape of the stator 22 is attached to the other end of the two coil blocks 21 on the corresponding connection board 27 side, and the second yokes 22d at both ends of the lower side of the approximately inverted T-shape of the stator 22 are attached to one end of each of the two coil blocks 21.

In this state, the rotor 23 is rotatably placed in the rotor hole 22a of the stator 22. This completes the assembly of the second to fourth step motors 17 to 19. The second to fourth step motors 17 to 19 assembled in this manner are attached to the housing 3 of the watch module 2, similar to the first and fifth step motors 16 and 20, and are electrically connected to the circuit board 5 attached to this housing 3.

In other words, when the circuit board 5 is placed on the back side of the housing 3 to which the second to fourth step motors 17 to 19 are assembled, similar to the first and fifth step motors 16 and 20, the multiple contact protrusions 30d provided on each contact portion 30a of the pair of electrode pieces 30 on the connection board 27 of each coil block 21 of the second to fourth step motors 17 to 19 are electrically connected by point contact to the pattern electrodes (not shown) of the circuit board 5 without being obstructed by the sealing resin 31.

Even in this case, the lower connection portion 30b of the pair of electrode pieces 30 provided on the connection board 27 to which the winding 26a of the coil 26 in the coil block 21 is connected is disposed within the recessed portion 27a of the connection board 27. Therefore, as shown by the two-dot chain line in FIG. 7, when the circuit board 5 is disposed on the front (upper) side of the connection board 27, the multiple contact protrusions 30d provided on each contact portion 30a of the pair of electrode pieces 30 are electrically connected to the pattern electrode (not shown) of the circuit board 5 by point contact without being obstructed by the sealing resin 31.

Next, the operation of the second to fourth step motors 17 to 19 assembled in this manner will be described. In the second to fourth step motors 17 to 19, like the first and fifth step motors 16 and 20, when current is supplied from the circuit board 5 to each of the coils 26 of the two coil blocks 21 via each connection board 27, a magnetic field is generated in the two coils 26, which is induced in the stator 22, and in response to this induced magnetic field, the rotor 23 rotates in steps with a stronger magnetic field and higher torque than the first and fifth step motors 16 and 20.

In this case, when the rotor 23 of the second step motor 17 rotates, the rotation of the rotor 23 is transmitted to the minute hand 7b of the first display unit 7 via a gear train mechanism (not shown), and the minute hand 7b moves above the dial 4 to indicate the minute time.

When the rotor 23 of the third step motor 18 rotates, the rotation of the rotor 23 is transmitted to the hour hand 7c of the first display unit 7 and the first 24-hour sub-hand 9a of the third display unit 9 via separate gear train mechanisms (not shown), causing the hour hand 7c of the first display unit 7 to move above the dial 4 to indicate the 12-hour time, and the first 24-hour sub-hand 9a of the third display unit 9 to move above the third area E2 of the dial 4 to indicate the 24-hour time.

Furthermore, when the rotor 23 of the fourth step motor 19 rotates, the rotation of the rotor 23 is transmitted to the minute hand 8a, hour hand 8b, and 24-hour hand 8c of the world time of the second display unit 8 via a gear train mechanism (not shown), and the minute hand 8a, hour hand 8b, and 24-hour hand 8c move above the second area E1 of the dial 4 to indicate the world time, which is the time in a selected city among the cities around the world.

Next, how to use such a wristwatch will be described.
In this wristwatch, the first to third step motors 16-18 in the first movement 11 of the first display unit 7 are normally driven, and the rotation of these driven first to third step motors 16-18 is transmitted to the second hand 7a, minute hand 7b, and hour hand 7c of the first display unit 7 via a gear train mechanism (not shown). The second hand 7a, minute hand 7b, and hour hand 7c of the first display unit 7 move above the dial 4 to point to the hour character 4a on the dial 4, thereby allowing the current time to be known.

In addition, at this time, the third step motor 18 is also used as the step motor for the third movement 13 of the third display unit 9, so that the first sub-hand 9a for 24 hours of the third display unit 9 moves in 24 hours above the third region E2 of the dial 4 via a gear train mechanism (not shown) separate from the first movement 11, indicating the 24-hour time, thereby allowing the current 24-hour time to be known.

In this state, the fourth step motor 19 in the second movement 12 of the second display unit 8 is driven, and the rotation of the driven fourth step motor 19 is transmitted to the minute hand 8a, hour hand 8b, and 24-hour hand 8c of the world time of the second display unit 8 via a gear train mechanism (not shown). The minute hand 8a, hour hand 8b, and 24-hour hand 8c of the world time move above the first area E1 of the dial 4, indicating the time of a selected city among the cities of the world, and thereby allowing the current time of the selected city to be known.

In this state, the fifth step motor 20 in the fourth movement 14 of the fourth display unit 10 is driven, and the rotation of the driven fifth step motor 20 is transmitted to the second sub-hand 10a and date wheel 10b of the fourth display unit 10 via a gear train mechanism (not shown), causing the second sub-hand 10a to move above the fourth region E3 of the dial 4 and the date wheel 10b of the fourth display unit 10 to rotate below the window portion E4 of the dial 4.

At this time, the movement of the second sub-hand 10a indicates either the day of the week, the charging state, or the mode, so the user can know either the day of the week, the charging state, or the mode, and the rotation of the date wheel 10b changes the date displayed on the date wheel 10b, so the user can know the date through the window E4.

In this way, the coil block 21 of this wristwatch comprises a coil core 25, a coil 26 formed by winding wire 26a around the coil core 25, and a connection board 27 provided at one end of the coil core 25 and to which the winding wire 26a of the coil 26 is connected. The connection board 27 comprises a recessed portion 27a which is a storage surface provided one step lower on one of its surfaces, and an electrode portion 28 which is disposed on the surface and partly disposed in the recessed portion 27a and to which the winding wire 26a of the coil 26 is connected. This makes it possible to improve the mounting density of the circuit board 5 without imposing any restrictions on the circuit board 5 which is disposed on the surface of the connection board 27.

In other words, in this coil block 21, a part of the electrode portion 28 is disposed in a recessed portion 27a that is provided one step lower on the surface of the connection board 27, and therefore the part of the electrode portion 28 disposed in this recessed portion 27a and connected to the winding 26a of the coil 26 can be sealed in the recessed portion 27a with the sealing resin 31. As a result, when the circuit board 5 is disposed on the surface (upper surface) side of the connection board 27, the circuit board 5 is not obstructed by the sealing resin 31, and the circuit board 5 can be disposed well on the surface of the connection board 27. Therefore, there is no need to provide an escape hole for the sealing resin 31 in the circuit board 5 disposed on the surface of the connection board 27, and therefore the circuit board 5 is not restricted, and the mounting density of the circuit board 5 can be improved.

In this case, the coil block 21 is provided with a sealing resin 31 that seals a part of the electrode portion 28 to which the winding 26a of the coil 26 is connected within the recess 27a, and this sealing resin 31 is provided within the recess 27a of the connection board 27 at a height lower than the surface of the connection board 27. Therefore, when placing the circuit board 5 on the surface of the connection board 27, the sealing resin 31 does not get in the way, and the circuit board 5 can be reliably and satisfactorily placed on the surface of the connection board 27.

In addition, in this coil block 21, a part of the electrode portion 28, i.e., the bent portion 30c, is embedded in the connection substrate 27 by insert molding while the electrode portion 28 is exposed on the surface of the connection substrate 27. This allows the electrode portion 28 to be reliably and firmly fixed to the connection substrate 27 even while the electrode portion 28 is exposed on the surface of the connection substrate 27.

In addition, in this coil block 21, the electrode portion 28 has a pair of electrode pieces 30 in which a portion is bent down one step, and each of the pair of electrode pieces 30 has a higher contact portion 30a that is exposed on the surface of the connection board 27, and a lower connection portion 30b that is exposed on the surface side of the connection board 27 in the recessed portion 27a of the connection board 27 and to which the winding 26a of the coil 26 is connected. This allows the winding 26a of the coil 26 to be reliably and satisfactorily connected to the lower connection portion 30b, and allows the circuit board 5 to come into contact with the higher contact portion 30a.

In this case, in this coil block 21, the higher contact portion 30a of the electrode piece 30 is provided with a plurality of contact protrusions 30d that contact the circuit board 5 placed on the surface of the connection board 27. When the circuit board 5 is placed on the surface of the connection board 27, the plurality of contact protrusions 30d provided on the higher contact portion 30a of the electrode piece 30 can be reliably and satisfactorily brought into point contact with the pattern electrode (not shown) of the circuit board 5, thereby ensuring a reliable connection between the circuit board 5 and the electrode piece 30 of the connection board 27.

Furthermore, in this coil block 21, the recessed portion 27a of the connection board 27 is provided adjacent to one end of the coil 26, so that when connecting the winding 26a of the coil 26 to a pair of electrode pieces 30, the winding 26a of the coil 26 can be easily connected to each connection portion 30b of the pair of electrode pieces 30 arranged in the recessed portion 27a of the connection board 27 adjacent to one end of the coil 26. This eliminates the need to route the winding 26a, and allows the winding 26a to be easily and satisfactorily connected to the electrode pieces 30.

In addition, the manufacturing method of the coil block 21 in this wristwatch includes a first step of manufacturing a pair of electrode pieces 30, some of which are bent down one step, connected by a connecting portion 33; a second step of molding the connection board 27 by insert molding with the pair of electrode pieces 30 placed in a molding die 34, and placing the connection portion 30b, which is a portion of the electrode portion 28 bent down one step, in the recessed portion 27a; and a third step of attaching the connection board 27 to the end of the coil core 25 on which the coil 26 is provided, and connecting the winding 26a of the coil 26 to the connection portion 30b of the pair of electrode pieces 30 placed in the recessed portion 27a of the connection board 27. This makes it possible to improve the mounting density of the circuit board 5 without restricting the circuit board 5 placed on the surface of the connection board 27.

That is, in the manufacturing method of the coil block 21, the connection board 27 is molded by insert molding in the second step, and the connection portion 30b of the pair of electrode pieces 30 bent one step lower is placed in the recessed portion 27a of the connection board 27, and in the third step, the winding 26a of the coil 26 is connected to the connection portion 30b of the pair of electrode pieces 30 placed in the recessed portion 27a of the connection board 27 attached to the end of the coil core 25, so that the connection portion 30b can be sealed with the sealing resin 31 in the recessed portion 27a. As a result, the circuit board 5 is not obstructed by the sealing resin 31, and the circuit board 5 can be well placed on the surface of the connection board 27. Therefore, there is no need to provide an escape hole for the sealing resin 31 in the circuit board 5, so the circuit board 5 is not restricted and the mounting density of the circuit board 5 can be improved.

In this case, in the manufacturing method of the coil block 21, the metal plate 32 is pressed in the first step to form a pair of electrode pieces 30 having a connection portion 30b bent one step lower and a contact portion 30a bent one step higher, which are connected by a connecting portion 33. This makes it possible to accurately and easily manufacture a pair of electrode pieces 30 having a connection portion 30b bent one step lower and a contact portion 30a bent one step higher, and since the connecting portion 33 prevents the pair of electrode pieces 30 from being separated even after the pair of electrode pieces 30 is manufactured, the pair of electrode pieces 30 can be easily handled.

In addition, in the manufacturing method of the coil block 21, in the second step, the connecting portion 33 extending from the outer periphery of the pair of electrode pieces 30 is sandwiched within the molding die 34, and the connection board 27 is formed by insert molding. This allows the pair of electrode pieces 30 connected by the connecting portion 30 to be accurately positioned within the molding die 34 and reliably and satisfactorily fixed, and thus the pair of electrode pieces 30 can be formed integrally with the connection board 27 accurately and with good precision.

Furthermore, in this manufacturing method of the coil block 21, even if the connection board 27 formed in the second step has the connecting portion 33 protruding from its outer periphery, the connection board 27 having the pair of electrode pieces 30 can be easily and satisfactorily manufactured by cutting the connecting portion 33 protruding from the outer periphery of the connection board 27 in the third step and attaching the connection board 27 to the end of the coil core 25. That is, in the second step, since the pair of electrode pieces 30 are connected by the connecting portion 33, the pair of electrode pieces 30 can be molded integrally with the connection board 27 satisfactorily, and by cutting the connecting portion 33 in the third step, the pair of electrode pieces 30 can be reliably and satisfactorily separated.

The first and fifth step motors 16 and 20, which are the first step motors of this wristwatch, are equipped with one coil block 21, a stator 22 with rotor holes 22a that are attached across both ends of the coil block 21, and a rotor 23 that is disposed in the rotor hole 22a of the stator 22 and rotates in response to the magnetic field generated by the coil 26 of the coil block 21. This allows the rotor 23, which rotates in response to the magnetic field generated by the coil 26, to rotate smoothly and reliably in steps, and does not impose any restrictions on the circuit board 5 that is disposed on the surface of the connection board 27 of the coil block 21, thereby improving the mounting density of the circuit board 5.

That is, in these first and fifth step motors 16 and 20, the connection portions 30b of the pair of electrode pieces 30, which are arranged in a recessed portion 27a provided one step lower on the surface of the connection board 27 and to which the windings 26a of the coil 26 are connected, are sealed within the recessed portion 27a by the sealing resin 31, so that the circuit board 5 can be arranged on the surface (upper surface) side of the connection board 27 without being obstructed by the sealing resin 31. Therefore, there is no need to provide an escape hole for the sealing resin 31 in the circuit board 5 arranged on the surface of the connection board 27, so the circuit board 5 is not restricted and the mounting density of the circuit board 5 can be improved.

The second to fourth step motors 17 to 19, which are the second step motors of this wristwatch, are equipped with two coil blocks 21, a stator 22 with rotor holes 22a that are attached across each end of the two coil blocks 21, and a rotor 23 that is placed in the rotor hole 22a of the stator 22 and rotates in response to the magnetic fields generated by the coils 26 of the two coil blocks 21. As a result, like the first step motor, the rotor 23 that rotates in response to the magnetic fields generated by the two coils 26 can be smoothly and reliably rotated in steps, and the mounting density of the circuit board 5 placed on the surface of the connection board 27 of the coil block 21 can be improved without imposing any restrictions.

In this case, the second to fourth step motors 17 to 19 are provided with two coil blocks 21, so the rotor 23 can be rotated with a stronger magnetic field and higher rotational torque than the first step motor in response to the magnetic field generated by the two coils 26. In addition, as with the first step motor, the circuit board 5 can be placed on the surface (upper surface) side of each connection board 27 without being obstructed by the sealing resin 31 of each of the two coil blocks 21. This eliminates the need to provide an escape hole for the sealing resin 31 in the circuit board 5 placed on the surface of the connection board 27, and the circuit board 5 is not restricted, allowing the mounting density of the circuit board 5 to be improved.

In the above embodiment, the coil blocks 21 of the first to fifth step motors 16 to 20 are configured with one coil 26 and one connection board 27 on one coil core 25. However, the present invention is not limited to this, and may be configured, for example, as in the modified example shown in FIG. 13.

That is, the step motor 40 of this modified example has two coils 26 in one coil core 42 of a coil block 41, a connection board 27 attached to each end of the coil core 42, a stator 43 attached to the middle and both ends of the coil core 42, and a rotor 23 rotatably arranged in the rotor hole 43a of the stator 43.

In this modified step motor 40, two coils 26 are provided on one coil core 42, so like the second to fourth step motors 17 to 19, the rotor 23 can be rotated with a stronger magnetic field and higher rotational torque than the first and fifth step motors 16 and 20, and the rotor 23 can be rotated in both forward and reverse directions. In addition, like the above-mentioned embodiment, the mounting density of the circuit board 5 can be improved without imposing any restrictions on the circuit board 5.

In addition, in the above-mentioned embodiment and its modified example, the coil block 21 is applied to the first to fifth step motors 16 to 20 and the modified step motor 40, but the present invention is not limited to this and can also be applied to, for example, a bar antenna.

In addition, while the above embodiment has been described as being applied to a wristwatch with a pointer, this invention does not necessarily have to be a wristwatch, and can be applied to various types of wristwatches, such as travel watches, alarm clocks, table clocks, and wall clocks. Also, this invention does not necessarily have to be applied to clocks, and can be applied to instruments such as meters, and electronic devices equipped with them.

Although one embodiment of the present invention has been described above, the present invention is not limited to this embodiment, and includes the inventions described in the claims and their equivalents.
The invention as set forth in the claims of this application is set forth below.

(Additional Note)
The invention described in claim 1 is a coil block comprising a substrate to which a coil winding is connected, the substrate having a storage surface that is lower than one surface of the substrate, and an electrode portion that is arranged on the one surface and has a portion arranged on the storage surface to which the coil winding is connected.

The invention described in claim 2 is the coil block described in claim 1, characterized in that it includes a sealing portion that seals the part of the electrode portion to which the winding of the coil is connected on the storage surface, and the sealing portion is provided on the storage surface lower than the height of the one surface of the substrate.

The invention described in claim 3 is the coil block described in claim 1 or claim 2, characterized in that the electrode portion is exposed on the one surface side of the substrate and is partially embedded in the substrate by insert molding.

The invention described in claim 4 is a coil block described in any one of claims 1 to 3, characterized in that the electrode portion has a pair of electrode pieces that are partially bent down, and each of the pair of electrode pieces has a contact portion that is one step higher and exposed on the one surface of the substrate, and a connection portion that is one step lower and exposed on the one surface side of the storage surface of the substrate and to which the winding of the coil is connected.

The invention described in claim 5 is the coil block described in claim 4, characterized in that the elevated contact portion of the electrode piece is provided with a contact protrusion that contacts a circuit board arranged on the one surface of the substrate.

The invention described in claim 6 is a coil block according to any one of claims 1 to 5, characterized in that the storage surface of the substrate is provided adjacent to one end of the coil.

The invention described in claim 7 is a method for manufacturing a coil block, characterized by comprising: a first step of manufacturing a pair of electrode pieces, some of which are bent one step lower and connected by a connecting part; a second step of forming a substrate by insert molding with the pair of electrode pieces placed in a molding die, and placing the bent one step lower portions of the pair of electrode pieces on the storage surface of the substrate; and a third step of attaching the substrate to at least one end of a coil core provided with a coil, and connecting the windings of the coil to the portions of the pair of electrode pieces placed on the storage surface of the substrate.

The invention described in claim 8 is the method for manufacturing a coil block described in claim 7, characterized in that in the third step, the part of the pair of electrode pieces is sealed with a sealing part on the storage surface, and in the first step, the metal plate is pressed to form the pair of electrode pieces having a connection part bent one step lower and a contact part one step higher by connecting them with the connecting part.

The invention described in claim 9 is the coil block manufacturing method described in claim 7, characterized in that in the second step, the substrate is formed by insert molding in a state in which the connecting portion extended from the outer periphery of the pair of electrode pieces is clamped in a molding die.

The invention described in claim 10 is the method for manufacturing a coil block described in claim 7, characterized in that in the third step, the connecting portion protruding from the outer periphery of the substrate formed in the second step is cut off, and then the substrate is attached to the one end of the coil core.

The invention described in claim 11 is a motor comprising a coil block described in any one of claims 1 to 6, a stator having a rotor hole and mounted across both ends of the coil block, and a rotor disposed in the rotor hole of the stator and rotating in response to a magnetic field generated by the coil of the coil block.

The invention described in claim 12 is a motor characterized by comprising two coil blocks described in any one of claims 1 to 6, a stator having a rotor hole and attached across each end of the two coil blocks, and a rotor disposed in the rotor hole of the stator and rotating in response to the magnetic field generated by each coil of the two coil blocks.

The invention described in claim 13 is a watch characterized by having a coil block described in any one of claims 1 to 6.

LIST OF SYMBOLS 1 Wristwatch case 2 Watch module 3 Housing 4 Dial 5 Circuit board 7 First display section 7a Second hand 7b Second hand 7c Hour hand 8 Second display section 8a Minute hand 8b Hour hand 8c 24-hour hand 9 Third display section 9a First sub-hand 10 Fourth display section 10a Second sub-hand 10b Date indicator 11-14 First to fourth movements 16-20 First to fifth step motors 21, 41 Coil block 22, 43 Stator 22a, 43a Rotor hole 23 Rotor 25, 42 Coil core 26 Coil 26a Winding 27 Connection board 27a Recessed portion 28 Electrode section 30 Electrode piece 30a Contact portion 30b Connection portion 30c Bent portion 30d Contact protrusion 31 Sealing resin 32 Metal plate 33 Connection portion 34 Molding die 35 Upper die 36 Lower die 37 Cavity portion 38 Resin 40 Step motor

Claims (13)

a substrate to which a winding of a coil is connected, the substrate having a storage surface that is lower than one surface of the substrate, and an electrode portion that is disposed on the one surface and has at least a portion disposed on the storage surface and to which the winding of the coil is connected;
The electrode portion has an electrode piece having at least a portion bent downwardly, the electrode piece including a contact portion exposed to the one surface side of the substrate, and a connection portion exposed to the one surface side of the storage surface and connected to the winding of the coil.
Coil block. a sealing portion that seals at least a portion of the electrode portion on the storage surface,
The sealing portion is provided on the storage surface lower than the height of the one surface of the substrate.
The coil block according to claim 1 . A cylindrical coil is provided.
The coil extends substantially parallel to the surface and has a diameter not exceeding the height of the surface.
The coil block according to claim 1 or 2 . the electrode portion is exposed on the one surface side of the substrate and at least a portion of the electrode portion is embedded in the substrate by insert molding;
The coil block according to any one of claims 1 to 3. The contact portion is provided with a contact protrusion that contacts a circuit board arranged on one surface of the board.
The coil block according to any one of claims 1 to 4 . The storage surface is provided adjacent to one end of the coil.
The coil block according to any one of claims 1 to 5. A first step of forming an electrode piece having a connection portion bent at least partially downward and a contact portion that is one step higher, the electrode piece being connected by a connecting portion;
a second step of forming a substrate by insert molding in a state in which the electrode piece is disposed in a molding die, and disposing at least a portion of the electrode piece bent downward on a housing surface of the substrate;
and a third step of attaching the substrate to at least one end of a coil core provided with a coil, and connecting a winding of the coil to at least a part of the electrode piece arranged on the housing surface of the substrate.
A manufacturing method for a coil block. In the third step, at least a portion of the electrode piece is sealed by a sealing portion on the housing surface,
In the first step, a metal plate is pressed to form the electrode piece having the connection portion and the contact portion by connecting the connection portion.
A method for manufacturing the coil block according to claim 7. In the second step, the substrate is formed by insert molding in a state in which the connecting portion extended from an outer periphery of the electrode piece is sandwiched within a molding die.
A method for manufacturing a coil block according to claim 7 or 8. In the third step, the connecting portion protruding from the outer periphery of the substrate formed in the second step is cut off, and then the substrate is attached to the one end of the coil core.
A method for manufacturing the coil block according to any one of claims 7 to 9. A coil block according to any one of claims 1 to 6,
a stator having a rotor hole and attached across both ends of the coil block;
a rotor disposed in the rotor hole of the stator and rotating in response to a magnetic field generated by a coil of the coil block.
motor. Two coil blocks according to any one of claims 1 to 6,
a stator having rotor holes and mounted across each end of the two coil blocks;
a rotor disposed in the rotor hole of the stator and rotating in response to magnetic fields generated by the coils of the two coil blocks.
motor. A coil block according to any one of claims 1 to 6,
clock.

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