JP2016004021A - Circuit module, movement for clock, electronic clock, and method for interconnecting circuit module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a circuit module, movement for clock, an electronic clock, and a method for interconnecting a circuit module that can reduce the cost for designing and manufacturing.SOLUTION: The circuit module has an interconnection board and a control IC 590, the interconnection board having first and second loop-shaped interconnection paths 530 and 540, respectively, and connecting terminals 511 to 514, the control IC 590 having output terminals A1, A2, B1, and B2, the output terminals A1 and A2 being located between the output terminals B1 and B2, the first interconnection path 530 being connected to the output terminal A1, connecting terminal 511, output terminal B1, and connecting terminal 513 in that order, and the second interconnection path 540 being connected to the output terminal A2, connecting terminal 512, output terminal B2, and connecting terminal 514 in that order.

Description

  The present invention relates to a circuit module, a timepiece movement, an electronic timepiece, and a circuit module wiring method.

  An analog electronic timepiece having a chronograph function includes a basic timepiece motor that drives a hand for displaying a basic timepiece, and a chronograph motor that drives a hand for displaying a chronograph (for example, a patent) Reference 1).

JP 2010-256337 A

By the way, in an analog electronic timepiece with a chronograph function, the position of the pointer may change due to the design. In this case, the motor for the basic timepiece depends on the positional relationship between the pointer and the motor that drives the pointer. May function as a motor for a chronograph, and a motor for a chronograph may function as a motor for a basic clock.
However, in this case, it is usually necessary to change the wiring of the control IC that controls the driving of the motor and the wiring of the wiring board on which the control IC is mounted. For this reason, it is necessary to prepare a control IC and a wiring board separately, and there is a problem that the cost for design and manufacturing increases.

  An object of the present invention is to provide a circuit module, a timepiece movement, an electronic timepiece, and a circuit module wiring method that can reduce the cost of design and manufacturing.

  The circuit module of the present invention has a wiring board and a control IC mounted on the wiring board, and the wiring board is connected to the loop-shaped first wiring path and the second wiring path, and the first motor. A first connection terminal and a second connection terminal, and a third connection terminal and a fourth connection terminal connected to the second motor, and the control IC is one of the first motor and the second motor. A first output terminal and a second output terminal for outputting a drive signal to one of them; a third output terminal and a fourth output terminal for outputting a drive signal to either one of the first motor and the second motor; And the first output terminal and the second output terminal are disposed between the third output terminal and the fourth output terminal, and the first wiring path includes the first output terminal and the first output terminal. 1 connection terminal and the third output A child and the third connection terminal are connected in this order, and the second wiring path includes the second output terminal, the second connection terminal, the fourth output terminal, and the fourth connection terminal. Are connected in this order.

According to the present invention, the first output terminal and the first connection terminal can be selectively connected by cutting between the first output terminal and the third connection terminal in the first wiring path. The third output terminal and the third connection terminal can be selectively connected by cutting between the third output terminal and the first connection terminal. Further, by disconnecting the second output terminal and the fourth connection terminal in the second wiring path, the second output terminal and the second connection terminal can be selectively connected, and the fourth output in the second wiring path. By disconnecting the terminal and the second connection terminal, the fourth output terminal and the fourth connection terminal can be selectively connected. As a result, signals output from the first and second output terminals can be input to the first motor, and signals output from the third and fourth output terminals can be input to the second motor.
In addition, by disconnecting the first output terminal and the first connection terminal in the first wiring path, the first output terminal and the third connection terminal can be selectively connected, and the third output in the first wiring path. By disconnecting the terminal and the third connection terminal, the third output terminal and the first connection terminal can be selectively connected. Further, by disconnecting the second output terminal and the second connection terminal in the second wiring path, the second output terminal and the fourth connection terminal can be selectively connected, and the fourth output in the second wiring path. By disconnecting the terminal and the fourth connection terminal, the fourth output terminal and the second connection terminal can be selectively connected. As a result, signals output from the first and second output terminals can be input to the second motor, and signals output from the third and fourth output terminals can be input to the first motor.
Thus, according to the present invention, the cutting positions in the first wiring path and the second wiring path are changed, so that the input to the first motor and the second motor can be performed without changing the wiring of the control IC and the wiring board. The drive signals to be used can be interchanged, and the functions of the first motor and the second motor can be interchanged. Thereby, the cost concerning design and manufacture of a circuit module can be reduced.
Further, according to the present invention, in the control IC, the first output terminal and the second output terminal are disposed between the third output terminal and the fourth output terminal. Wirings connecting the two wiring paths can be arranged without crossing each other, and the wiring structure can be simplified as compared with the case of crossing.

In the circuit module of the present invention, it is preferable that the first motor is a display motor for a basic timepiece, and the second motor is a display motor different from the basic timepiece.
Alternatively, in the circuit module of the present invention, it is preferable that the first motor is a display motor different from the basic timepiece, and the second motor is a display motor for the basic timepiece.

A display motor different from the basic clock is, for example, a chronograph display motor.
According to the present invention, if the cutting position on the wiring board is changed, for example, a motor that drives the hands of the chronograph can function as a motor that drives the hands of the basic timepiece. According to this, the position of the hands of the basic timepiece can be easily replaced with the position of the hands of the chronograph, and the design of the electronic timepiece can be easily changed.

The circuit module of the present invention includes a wiring board and a control IC mounted on the wiring board, and the control IC outputs a first driving signal to one of the first motor and the second motor. An output terminal and a second output terminal; and a third output terminal and a fourth output terminal for outputting a drive signal to either one of the first motor and the second motor. A first wiring path and a second wiring path; a first connection terminal and a second connection terminal connected to the first motor; a third connection terminal and a fourth connection terminal connected to the second motor; A first output wiring connecting the first output terminal and the first wiring path; a second output wiring connecting the second output terminal and the second wiring path; and the third output terminal and the first wiring path. Connect A third output wiring; a fourth output wiring connecting the fourth output terminal and the second wiring path; a first connection wiring connecting the first connection terminal and the first wiring path; and the second connection. A second connection wiring that connects the terminal and the second wiring path, a third connection wiring that connects the third connection terminal and the first wiring path, and a connection between the fourth connection terminal and the second wiring path. A first connection wiring portion for connecting the first output wiring and the first connection wiring; the first connection wiring and the third output wiring; A second connection wiring portion connecting between the third output wiring and the third connection wiring, and a fourth connection connecting between the third connection wiring and the first output wiring. A connecting wiring portion, and formed in a loop shape, The second wiring path includes a fifth connection wiring portion that connects the second output wiring and the second connection wiring, and a sixth connection wiring portion that connects the second connection wiring and the fourth output wiring. A seventh connection wiring portion that connects the fourth output wiring and the fourth connection wiring, and an eighth connection wiring portion that connects the fourth connection wiring and the second output wiring. The first output wiring and the second output wiring are arranged between the third output wiring and the fourth output wiring.
According to the present invention, the same effect as the circuit module can be obtained.

A timepiece movement according to the present invention includes the above circuit module, wherein two portions of the first wiring path and two portions of the second wiring path are cut, and the first output terminal and the second output terminal are The first connection terminal and the second connection terminal are connected to any one of the third connection terminal and the fourth connection terminal, and the third output terminal and the fourth output terminal are connected to the first connection terminal and The second connection terminal, the third connection terminal, and the fourth connection terminal are connected to the other.
According to the circuit module, since the cost for design and manufacture can be reduced, the cost for designing and manufacturing a timepiece movement on which the circuit module is mounted can also be reduced.

The movement for a timepiece of the present invention is preferably a movement for a chronograph timepiece.
Since the chronograph timepiece has chronograph hands in addition to the hands of the basic timepiece (hour hand, minute hand, second hand, etc.), the number of hands increases. For this reason, it is possible to effectively increase design variations by changing the position of the pointer by changing the function of the motor.

An electronic timepiece according to the present invention includes the timepiece movement described above.
According to the timepiece movement, since the cost for design and manufacture can be reduced, the cost for design and manufacture of the electronic timepiece on which the timepiece movement is mounted can also be reduced.

  In the circuit module wiring method of the present invention, the first output terminal and the second output are cut by cutting the two positions of the first wiring path and the two positions of the second wiring path with respect to the circuit module. A terminal is connected to any one of the first connection terminal, the second connection terminal, the third connection terminal, and the fourth connection terminal, and the third output terminal and the fourth output terminal are connected to the first connection terminal. One connection terminal, the second connection terminal, the third connection terminal, and the fourth connection terminal are connected to the other.

  According to the present invention, by changing the cutting position in the first wiring path and the second wiring path, the functions of the first motor and the second motor are interchanged without changing the wiring of the control IC and the wiring board. The cost for designing and manufacturing the circuit module can be reduced.

It is a figure which shows the electronic timepiece concerning embodiment of this invention. It is the top view which looked at the movement of the electronic timepiece from the back cover side. It is the perspective view which looked at the principal part of the movement from the back cover side. It is a circuit diagram which shows the motor drive circuit of the said electronic timepiece. It is the fragmentary top view which looked at the said circuit module from the back cover side. It is the figure which compared the position of the hand of the electronic timepiece and the electronic timepiece whose design was changed. It is the top view which looked at the movement of the electronic timepiece by which the design was changed from the back cover side. It is a circuit diagram which shows the motor drive circuit of the electronic timepiece which changed the design. It is a figure which shows the electronic timepiece of a modification. It is a figure explaining the change of the position of the hand of the electronic timepiece of a modification. It is a figure which shows the control IC of a modification.

An electronic timepiece according to an embodiment of the present invention will be described with reference to the drawings.
[Configuration of electronic timepiece 1]
FIG. 1 is a diagram showing an electronic timepiece 1 of the present embodiment.
The electronic timepiece (chronograph timepiece) 1 has a 24-hour display, a date display, a second CG (chronograph) display for performing a stopwatch function, and a minute CG display in addition to a normal 12-hour display with each hour, minute, and second hands. It has multiple display functions.
As shown in FIG. 1, the electronic timepiece 1 includes an hour hand 2, a minute hand 3, a second hand 4 that displays time for 12 hours, a 24-hour hand 5 that displays time for 24 hours, a second CG hand 6, and a minute CG hand 7. And a date wheel 8 for displaying the date.

As shown in FIG. 1, the hour hand 2, the minute hand 3, and the second hand 4 are provided coaxially and rotatably at the approximate center of the dial 13 of the electronic timepiece 1.
The 24-hour hand 5 is rotatably provided on an axis independent of the hour hand 2, the minute hand 3 and the second hand 4 at 3 o'clock side from the center of the dial 13.
The second CG hand 6 is rotatably provided on an axis independent of the hour hand 2, the minute hand 3, and the second hand 4 on the 6 o'clock side from the center of the dial 13.
The minute CG hand 7 is rotatably provided on an axis independent of the hour hand 2, the minute hand 3, the second hand 4, and the second CG hand 6 on the 9 o'clock side from the center of the dial 13.

[Composition of movement]
FIG. 2 is a plan view of the movement 10 mounted on the electronic timepiece 1 as viewed from the back cover side.
The movement (timepiece movement) 10 includes a first motor 100, a second motor 200, a basic timepiece wheel train 300, a chronograph wheel train 400, a circuit module 500, and a conductive substrate 600.
FIG. 3 is a perspective view of the main part of the movement 10 as seen from the back cover side. In FIG. 3, the basic timepiece train wheel 300 and the chronograph train wheel 400 are not shown.
As shown in FIG. 3, the first motor 100 and the second motor 200 are located at the same height in the thickness direction of the electronic timepiece 1. The circuit module 500 is located on the back cover side with respect to the second motor 200, and the conductive substrate 600 is located on the back cover side with respect to the circuit module 500 and the first motor 100.

[First motor]
As shown in FIG. 2, the first motor 100 includes a magnetic core 101, a coil 102 wound around the magnetic core 101, a stator 103, a rotor 104 disposed in a hole provided in the stator 103, and a coil 102. An electrode MA1 (FIGS. 2 and 3) connected to one end and an electrode MA2 (FIGS. 2 and 3) connected to the other end of the coil 102 are provided.
The rotor 104 is disposed at a substantially central position PC of the dial 13 via the basic clock train 300, and drives a pointer shaft to which the hour hand 2, the minute hand 3, and the second hand 4 are respectively attached.
That is, in the electronic timepiece 1, the first motor 100 functions as a motor that drives the hands 2, 3, and 4 for the basic timepiece.

  Here, the basic timepiece wheel train 300 is engaged with the gear 21 that meshes with the rotor 104, the gear 22 that meshes with the gear 21, the second hand 4 is attached, the gear 23 that meshes with the gear 22, the gear 23, and the minute hand. 3, a gear 25 that meshes with the gear 24, and a gear 26 that meshes with the gear 25 and to which the hour hand 2 is attached.

[Second motor]
The second motor 200 includes a magnetic core 201, a coil 202 wound around the magnetic core 201, a stator 203, a rotor 204 disposed in a hole provided in the stator 203, and an electrode MB1 connected to one end of the coil 202. (FIGS. 2 and 3) and an electrode MB2 (FIGS. 2 and 3) connected to the other end of the coil 202.
The rotor 204 is disposed at a position P6 on the 6 o'clock side from the center of the dial 13 via the chronograph wheel train 400, and a pointer shaft to which the second CG hand 6 is attached and 9 o'clock from the center of the dial 13 The pointer shaft, which is disposed at the position P9 on the side and to which the minute CG hand 7 is attached, is driven.
That is, in the electronic timepiece 1, the second motor 200 functions as a motor that drives the hands 6 and 7 for the chronograph.

Here, the chronograph wheel train 400 meshes with the gear 27 that meshes with the rotor 204, the gear 28 that meshes with the gear 27, the second CG hand 6 is attached to, the gear 29 that meshes with the gear 27, and the gear 29. A gear 30, a gear 31 that meshes with the gear 30, a gear 32 that meshes with the gear 31, and a gear 33 that meshes with the gear 32 and to which the minute CG needle 7 is attached.
Note that the number of steps of the second motor 200 that rotates the gears 28 and 33 of the chronograph train wheel 400 one time is the same as the number of steps of the first motor 100 that rotates the gears 22 and 24 of the basic timepiece train wheel 300 one time. Is set to a value.

[Circuit module]
The circuit module 500 includes a wiring board 510 provided with a wiring pattern on the dial side (the side opposite to the back cover side), and a control IC 590 mounted on the dial side with respect to the wiring board 510.
FIG. 4 is a circuit diagram showing a motor drive circuit configured by the circuit module 500. FIG. 5 is a partial plan view of the circuit module 500 as viewed from the back cover side.
As shown in FIGS. 4 and 5, the control IC 590 includes an output terminal A1 (first output terminal), an output terminal A2 (second output terminal), an output terminal B1 (third output terminal), and an output terminal B2 (fourth output). Terminal). The output terminal A1 is disposed adjacent to the output terminal B1 between the output terminal B1 and the output terminal B2. The output terminal A2 is disposed adjacent to the output terminal B2 between the output terminal B1 and the output terminal B2.
In the electronic timepiece 1, the output terminals A1 and A2 are terminals for outputting a driving signal for a motor for a basic timepiece, and the output terminals B1 and B2 are terminals for outputting a driving signal for a motor for a chronograph.

As shown in FIGS. 2, 4, and 5, the connection terminal 511 connected to the electrode MA <b> 1 of the first motor 100 is provided on the front surface side (dial plate side) of the wiring substrate 510 via a conductive substrate 600 (FIG. 2) described later. (First connection terminal), a connection terminal 512 (second connection terminal) connected to the electrode MA2 of the first motor 100 via the conductive substrate 600, and a connection terminal 513 (first connection) connected to the electrode MB1 of the second motor 200. 3 connection terminals) and a connection terminal 514 (fourth connection terminal) connected to the electrode MB2 of the second motor 200 are provided.
As shown in FIG. 5, the wiring board 510 is provided with two through holes 521 and 522, and the connection terminals 511 and 512 are bent and the wiring board 510 is connected to the wiring board 510 via the through holes 521 and 522. It protrudes to the back cover side.
One end of a conductive substrate 600 described later is disposed on the back cover side of the wiring substrate 510. The connection terminals 511 and 512 protruding to the back cover side of the wiring substrate 510 are connected to the conductive substrate 600 and connected to the electrodes MA1 and MA2 of the first motor 100 via the conductive substrate 600.
Further, the wiring board 510 is provided with a screw fixing hole 523, and the wiring board 510 has a ground plane with the second motor 200 interposed therebetween by a screw N1 (FIGS. 2 and 3) inserted through the hole 523. (Not shown). Here, the connection terminals 513 and 514 are arranged to face the electrodes MB1 and MB2 of the second motor, and are connected in contact with the electrodes MB1 and MB2.

Further, the wiring substrate 510 is provided with a loop-shaped first wiring path 530 and a second wiring path 540 as shown in FIGS.
The first wiring path 530 is connected to the output wiring 551 (first output wiring) connected to the output terminal A1, the connection wiring 561 (first connection wiring) connected to the connection terminal 511, and the output terminal B1. The output wiring 553 (third output wiring) and the connection wiring 563 (third connection wiring) connected to the connection terminal 513 are connected counterclockwise in this order.
That is, the first wiring path 530 includes a connection wiring portion 531 (first connection wiring portion) that connects the output wiring 551 and the connection wiring 561, and a connection wiring portion 532 (first connection) that connects the connection wiring 561 and the output wiring 553. 2 connection wiring portions), a connection wiring portion 533 (third connection wiring portion) for connecting the output wiring 553 and the connection wiring 563, and a connection wiring portion 534 (fourth connection) for connecting the connection wiring 563 and the output wiring 551. Wiring section).
The second wiring path 540 is connected to the output wiring 552 (second output wiring) connected to the output terminal A2, the connection wiring 562 (second connection wiring) connected to the connection terminal 512, and the output terminal B2. The output wiring 554 (fourth output wiring) and the connection wiring 564 (fourth connection wiring) connected to the connection terminal 514 are connected clockwise in this order.
That is, the second wiring path 540 includes a connection wiring portion 541 (fifth connection wiring portion) that connects the output wiring 552 and the connection wiring 562, and a connection wiring portion 542 (first connection) that connects the connection wiring 562 and the output wiring 554. 6 connection wiring portions), a connection wiring portion 543 (seventh connection wiring portion) for connecting the output wiring 554 and the connection wiring 564, and a connection wiring portion 544 (8th connection) for connecting the connection wiring 564 and the output wiring 552. Wiring section).

Here, as shown in FIG. 5, the output wirings 551 and 552 are disposed between the output wiring 553 and the output wiring 554, and are further disposed so as to pass between the connection terminal 511 and the connection terminal 512.
The connection terminal 511 is disposed in a region S <b> 1 surrounded by the output wiring 551, the connection wiring portions 531 and 532 constituting the first wiring path 530, and the output wiring 553.
Further, the connection terminal 512 is disposed in a region S <b> 2 surrounded by the output wiring 552, the connection wiring portions 541 and 542 constituting the second wiring path 540, and the output wiring 554.
The connection terminals 513 and 514 are disposed outside the first wiring path 530 and the second wiring path 540 and outside the regions S1 and S2.

In the electronic timepiece 1, the connecting wiring portions 532 and 534 in the first wiring path 530 are provided with holes P by punching, and the connecting wiring portions 532 and 534 are cut halfway. Accordingly, the output terminal A1 is selectively connected to the connection terminal 511 via the output wiring 551, the connection wiring portion 531 and the connection wiring 561, and the output terminal B1 is output to the output wiring 553, the connection wiring portion 533, and the connection wiring 563. Is selectively connected to the connection terminal 513.
Further, in the electronic timepiece 1, the connecting wiring portions 542 and 544 in the second wiring path 540 are provided with holes P by punching, and the connecting wiring portions 542 and 544 are cut off halfway. Accordingly, the output terminal A2 is selectively connected to the connection terminal 512 via the output wiring 552, the connection wiring portion 541, and the connection wiring 562, and the output terminal B2 is output to the output wiring 554, the connection wiring portion 543, and the connection wiring 564. Is selectively connected to the connection terminal 514.
That is, in the electronic timepiece 1, the output terminals A1 and A2 are connected to the electrodes MA1 and MA2 of the first motor 100, and the output terminals B1 and B2 are connected to the electrodes MB1 and MB2 of the second motor 200.

As shown in FIG. 5, the connection wiring portions 531, 533, 541, and 543 are provided with punching areas PA. In the electronic timepiece 1, the punching area PA is not punched. However, in the electronic timepiece 1 </ b> A, which will be described later, in which the design of the electronic timepiece 1 is changed, the hole P is not provided, and the punching area PA is punched out. Is provided.
Here, the holes P are arranged such that the punching area PA is located therebetween, and the punching areas PA are arranged adjacent to each other. According to this, when punching out the hole P or when punching out the punching area PA in the electronic timepiece 1A, it is possible to easily distinguish the punching portion.
In other words, the first wiring path 530 and the second wiring path 540 are routed so that the position of the hole P and the position of the punching area PA can be easily distinguished.

[Conductive substrate]
As shown in FIG. 2, the conductive substrate 600 has a longitudinal shape, and has two wiring patterns 610 and 620 extending from one end 601 to the other end 602 on the dial side. . The end portion 601 of the conductive substrate 600 is provided with a screw-fastening hole 603. The screw N2 (FIGS. 2 and 3) inserted through the hole 603 is interposed between the first motor 100 and a ground plate (not shown). Fixed.
Here, the end portion 601 is located on the back cover side of the first motor 100, and the wiring patterns 610 and 620 are opposed to and connected to the electrodes MA1 and MA2 of the first motor 100.
On the other hand, the end portion 602 is located on the back cover side of the wiring board 510, and the wiring patterns 610 and 620 are in contact with and connected to the connection terminals 511 and 512 protruding to the back cover side of the wiring board 510.
Thus, the connection terminals 511 and 512 of the wiring board 510 are connected to the electrodes MA1 and MA2 of the first motor 100 via the wiring patterns 610 and 620 provided on the conductive board 600.

[Description of Electronic Timepiece 1A with Changed Pointer Position]
Next, the position of the hands is changed with respect to the electronic timepiece 1, and accordingly, contrary to the electronic timepiece 1, the hands for the chronograph are driven by the first motor 100 and the basic timepiece is driven by the second motor 200. An electronic timepiece 1A that drives a hand for use will be described.

FIG. 6 is a diagram comparing the positions of the hands of the electronic timepiece 1 and the electronic timepiece 1A.
As shown in FIG. 6, in the electronic timepiece 1, the second hand 4 is provided coaxially with the hour hand 2 and the minute hand 3 at the approximate center of the dial 13, but in the electronic timepiece 1A, the second hand (small second hand) 4 is The dial 13 is provided on an axis at 6 o'clock with respect to the center of the dial 13.
Further, in the electronic timepiece 1, the second CG hand 6 is provided on the axis at 6 o'clock side from the center of the dial 13, but in the electronic timepiece 1 A, the second CG hand 6 is substantially at the center of the dial 13. (Center) is provided coaxially with the hour hand 2 and the minute hand 3.
The positions of the other hour hand 2, minute hand 3, 24 hour hand 5, and minute CG hand 7 of the electronic timepiece 1A are the same as those of the electronic timepiece 1.

[Composition of movement]
FIG. 7 is a plan view of the movement 10A mounted on the electronic timepiece 1A as viewed from the back cover side.
The movement 10A includes a first motor 100, a second motor 200, a basic clock train wheel 300A, a chronograph train wheel 400A, a circuit module 500A, and a conductive substrate 600.
The first motor 100 has the same configuration as the first motor 100 of the electronic timepiece 1. Here, in the electronic timepiece 1 </ b> A, the rotor 104 is disposed at a position PC substantially at the center of the dial 13 via the chronograph wheel train 400 </ b> A, and a pointer shaft to which the second CG hand 6 is attached and a center of the dial 13. It is arranged at a position P9 on the 9 o'clock side and drives the pointer shaft to which the minute CG hand 7 is attached.
That is, in the electronic timepiece 1A, the first motor 100 functions as a motor that drives the chronograph hands.
The second motor 200 has the same configuration as the second motor 200 of the electronic timepiece 1. Here, in the electronic timepiece 1 </ b> A, the rotor 204 is disposed at a substantially central position PC of the dial 13 via the basic clock train wheel 300 </ b> A, and a pointer shaft to which the hour hand 2 and the minute hand 3 are respectively attached, and the dial 13 It is arranged at a position P6 on the 6 o'clock side of the center of the needle and drives a pointer shaft to which the second hand 4 is attached.
That is, in the electronic timepiece 1A, the second motor 200 functions as a motor that drives a pointer for a basic timepiece.
The conductive substrate 600 has the same configuration as the conductive substrate 600 of the electronic timepiece 1.

Here, the basic timepiece train wheel 300 </ b> A includes the gears 24, 25, and 26 that constitute the basic timepiece train wheel 300 of the electronic timepiece 1 and the gears 27 and 28 that constitute the chronograph train wheel 400 of the electronic timepiece 1. , 29 and newly added gears 34, 35, 36.
In the electronic timepiece 1 </ b> A, the second hand 4 is attached not to the gear 22 but to the gear 28. The gear 34 meshes with the gear 29, the gear 35 meshes with the gear 34, and the gear 36 meshes with the gear 35. Further, the gear 24 is meshed with the gear 36.
The number of steps of the second motor 200 that rotates the gears 28, 24, and 26 of the basic timepiece train wheel 300A each time is the first number of steps that causes the gears 22, 24, and 26 of the basic timepiece wheel train 300 of the electronic timepiece 1 to rotate once. It is set to the same value as the number of steps of one motor 100.

The chronograph train wheel 400A includes gears 31, 32, and 33 constituting the chronograph train wheel 400 of the electronic timepiece 1, gears 21 and 22 constituting the basic watch train wheel 300 of the electronic timepiece 1, and a new The gear 37 added to is provided.
In the electronic timepiece 1A, the second CG hand 6 is attached not to the gear 28 but to the gear 22. The gear 37 meshes with the gear 22. The gear 31 is meshed with the gear 37.
Note that the number of steps of the first motor 100 that rotates the gears 22 and 33 of the chronograph train wheel 400 </ b> A one time is the same as that of the second motor 200 that rotates the gears 28 and 33 of the chronograph wheel train 400 of the electronic timepiece 1 one time. It is set to the same value as the number of steps.
In the electronic timepiece 1A, the gears 23 and 30 in the electronic timepiece 1 are excluded from the configuration.

[Circuit module]
The circuit module 500A of the electronic timepiece 1A is different from the circuit module 500 of the electronic timepiece 1 in terms of punching in the wiring board 510A. Other configurations are the same as those of the circuit module 500 of the electronic timepiece 1.
FIG. 8 is a circuit diagram showing a motor drive circuit configured by the circuit module 500A.
In the circuit module 500A, the connection wiring parts 531 and 533 in the first wiring path 530 and the connection wiring parts 541 and 543 in the second wiring path 540 are cut by punching.
That is, the wiring board 510A of the circuit module 500A has a configuration in which the hole P is not provided but the punching area PA is punched and a hole is provided in the wiring board 510 shown in FIG. .
Accordingly, the output terminal A1 is selectively connected to the connection terminal 513 via the output wiring 551, the connection wiring portion 534, and the connection wiring 563, and the output terminal B1 is output to the output wiring 553, the connection wiring portion 532, and the connection wiring 561. Is selectively connected to the connection terminal 511 through the connector. The output terminal A2 is selectively connected to the connection terminal 514 via the output wiring 552, the connection wiring portion 544, and the connection wiring 564, and the output terminal B2 is connected to the output wiring 554, the connection wiring portion 542, and the connection wiring 562. Through the connection terminal 512.
That is, in the electronic timepiece 1A, the output terminals A1 and A2 are connected to the electrodes MB1 and MB2 of the second motor 200, and the output terminals B1 and B2 are connected to the electrodes MA1 and MA2 of the first motor 100.

[Effects of Embodiment]
The function of the first motor 100 and the second motor 200 can be changed without changing the wiring of the control IC 590 and the wiring board 510 by changing the cutting position of the wiring board 510 in the first wiring path 530 and the second wiring path 540. Can be used interchangeably. Thereby, the cost concerning the design and manufacture of the circuit module 500 can be reduced.

  In the control IC 590, since the output terminals A1 and A2 are disposed between the output terminal B1 and the output terminal B2, the output wiring 551 connecting each output terminal to the first and second wiring paths 530 and 540. 552, 553, and 554 can be arranged without crossing each other, and the wiring structure can be simplified as compared with the case of crossing.

Since the position of the hands of the basic timepiece can be easily replaced with the position of the hands of the chronograph, the design of the electronic timepiece can be easily changed.
In addition, since the number of hands is increased in the chronograph timepiece, the position of the hands can be changed, so that variations in design can be effectively increased.

[Other Embodiments]
In addition, this invention is not limited to the structure of the said embodiment, A various deformation | transformation implementation is possible within the range of the summary of this invention.
In the embodiment, the output terminals A1 and A2 are terminals for outputting a driving signal for a motor for a basic timepiece, and the output terminals B1 and B2 are terminals for outputting a driving signal for a motor for a chronograph. However, the present invention is not limited to this. That is, the output terminals A1 and A2 may be terminals that output a drive signal for a chronograph motor, and the output terminals B1 and B2 may be terminals that output a drive signal for a motor for a basic timepiece.

In the embodiment, the position of the hands for the basic timepiece and the position of the hands for the chronograph are interchanged, but the present invention is not limited to this.
For example, as shown in FIG. 9, in addition to the hands for the basic clock (hour hand 2, minute hand 3, second hand 4), the mode hand 9, the second CG hand 6, and the hour / minute CG hand or alarm clock for indicating the mode. In the timepiece having the hands 11 functioning as the hour / minute hands, the present invention is applied when the position of the mode hand 9 (12 o'clock direction) and the position of the hands 11 (6 o'clock direction) are switched as shown in FIG. May be.
In addition, examples of the pointer that can change the position of the pointer include a day indicator, an indicator hand, a month indicator, a world time indicator, and the like.

In the said embodiment, although the connection terminals 511 and 512 are arrange | positioned in area | region S1, S2, this invention is not limited to this.
For example, the connection terminals 511 and 512 may be disposed in the first and second wiring paths 530 and 540. Also in this case, the connection terminals 511 and 512 can be pulled out to the back cover side of the wiring board 510 through the through holes provided in the wiring board 510.

In the embodiment, in the control IC 590, the output terminals A1, A2, B1, and B2 are arranged along one side of the outer periphery of the control IC 590 as shown in FIG. 4, but the present invention is not limited to this. .
For example, as illustrated in FIG. 11, the output terminal B1, the output terminals A1 and A2, and the output terminal B2 may be arranged along different sides.
Also in this case, the output terminals A1 and A2 only need to be arranged between the output terminal B1 and the output terminal B2. In other words, the output terminals A1 and A2 are arranged between the output terminal B1 and the output terminal B2 in the arrangement order along the outer periphery of the control IC.

In the embodiment, the connection terminals 511 and 512 of the wiring board 510 are connected to the electrodes MA1 and MA2 of the first motor 100 via the conductive substrate 600, but the present invention is not limited to this.
For example, the connection terminals 511 and 512 of the wiring board 510 are changed to the electrodes MA1 and MA2 of the first motor 100 by changing the shape and wiring layout of the conductive board 600 or changing the arrangement location of the first motor 100. Direct connection may be made without using the conductive substrate 600.

  In the above-described embodiment, the number of steps of the second motor 200 that rotates the gears 28 and 33 of the chronograph train wheel 400 once each is the number of steps of the first motor 100 that rotates the gears 22 and 24 of the basic watch train wheel 300 one time. Although it is set to the same value as the number, the present invention is not limited to this, and may be set to a different value.

  DESCRIPTION OF SYMBOLS 1,1A ... Electronic timepiece, 10, 10A ... Movement, 100 ... 1st motor, 200 ... 2nd motor, 500, 500A ... Circuit module, 510 ... Wiring board, 511-514 ... Connection terminal, 530 ... 1st wiring route , 531 to 534, 541 to 544..., Connecting wiring part, 540... Second wiring path, 551 to 554... Output wiring, 561 to 564. B2 ... output terminal, S1, S2 ... area.

Claims (8)

A wiring board;
A control IC mounted on the wiring board,
The wiring board includes a loop-shaped first wiring path and a second wiring path, a first connection terminal and a second connection terminal connected to the first motor, a third connection terminal and a second connection terminal connected to the second motor. 4 connection terminals,
The control IC drives a first output terminal and a second output terminal for outputting a drive signal to one of the first motor and the second motor, and a drive to the other of the first motor and the second motor. A third output terminal for outputting a signal and a fourth output terminal;
The first output terminal and the second output terminal are disposed between the third output terminal and the fourth output terminal,
The first output terminal, the first connection terminal, the third output terminal, and the third connection terminal are connected to the first wiring path in this order,
The circuit module, wherein the second output terminal, the second connection terminal, the fourth output terminal, and the fourth connection terminal are connected to the second wiring path in this order. . The circuit module according to claim 1,
The first motor is a motor for displaying a basic clock,
The circuit module, wherein the second motor is a display motor different from the basic timepiece. The circuit module according to claim 1,
The first motor is a display motor different from the basic clock,
The circuit module, wherein the second motor is a motor for displaying a basic timepiece. A wiring board and a control IC mounted on the wiring board;
The control IC outputs a driving signal to one of the first motor and the second motor, and outputs a driving signal to one of the first motor and the second motor. A third output terminal and a fourth output terminal for outputting,
The wiring board is
A loop-shaped first wiring path and a second wiring path;
A first connection terminal and a second connection terminal connected to the first motor;
A third connection terminal and a fourth connection terminal connected to the second motor;
A first output wiring connecting the first output terminal and the first wiring path;
A second output wiring connecting the second output terminal and the second wiring path;
A third output wiring connecting the third output terminal and the first wiring path;
A fourth output wiring connecting the fourth output terminal and the second wiring path;
A first connection wiring connecting the first connection terminal and the first wiring path;
A second connection wiring connecting the second connection terminal and the second wiring path;
A third connection wiring connecting the third connection terminal and the first wiring path;
A fourth connection wiring connecting the fourth connection terminal and the second wiring path,
The first wiring path includes a first connection wiring portion that connects the first output wiring and the first connection wiring, and a second connection wiring portion that connects the first connection wiring and the third output wiring. A third connection wiring portion that connects the third output wiring and the third connection wiring, and a fourth connection wiring portion that connects the third connection wiring and the first output wiring. Formed into
The second wiring path includes a fifth connection wiring portion that connects the second output wiring and the second connection wiring, and a sixth connection wiring portion that connects the second connection wiring and the fourth output wiring. A seventh connection wiring portion that connects the fourth output wiring and the fourth connection wiring, and an eighth connection wiring portion that connects the fourth connection wiring and the second output wiring. Formed into
The circuit module, wherein the first output wiring and the second output wiring are arranged between the third output wiring and the fourth output wiring. A circuit module according to any one of claims 1 to 4, comprising:
Two locations of the first wiring path and two locations of the second wiring path are cut, and the first output terminal and the second output terminal are connected to the first connection terminal, the second connection terminal, and the third, respectively. The third output terminal and the fourth output terminal are connected to either one of the connection terminal and the fourth connection terminal, and the third output terminal and the fourth output terminal are connected to the first connection terminal, the second connection terminal, the third connection terminal and the first connection terminal. A watch movement characterized by being connected to either one of the four connection terminals. The timepiece movement according to claim 5 is:
A watch movement characterized by being a movement for a chronograph watch. An electronic timepiece comprising the timepiece movement according to claim 5. The circuit module according to any one of claims 1 to 4,
By cutting the two locations of the first wiring path and the two locations of the second wiring path, the first output terminal and the second output terminal are connected to the first connection terminal, the second connection terminal, and the second Three connection terminals and the fourth connection terminal, the third output terminal and the fourth output terminal are connected to the first connection terminal, the second connection terminal, the third connection terminal, and the A circuit module wiring method comprising connecting to the other of the fourth connection terminal.

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