JPH0552970A - Timepiece - Google Patents

Abstract

PURPOSE:To obtain a miniaturized timepiece enhanced in the quality and capacity of the peripheral part of a battery circuit by providing the engaging part engaged with a base frame to a press plate so that said engaging part is engaged with or fixed to the part to be engaged of the base frame by the elastomer fixed from the side surface of a battery in a pressure contact state. CONSTITUTION:A battery 2 is held from the side surfaces thereof by the pressure springs 28c, 28d on the side of the battery of the positive terminal 28 thereof to be set to a positive continuity state. A battery pressing plate 33 has the bar ring part 33a guided by the tip part on the battery side of the screw pin 81 driven in and fixed to a base plate 1 and is grasped and fixed by clamping the outer peripheral part of the opening part 1c of the base plate escaping the outer periphery of the bar ring part 33a and a screw 91. The battery pressing plate 33 is positioned by the bar ring part 33a and also positioned in its rotary direction by the engaging part 33b engaged with the positioning hole part 28g of the positive terminal 28 of the battery. When the battery pressing plate 33 is fixed, said plate 33 can be positioned by the bar ring part 33a to be clamped and fixed by the screw 91 and, therefore, various members can be fixed in extremely small space.

Description

Detailed Description of the Invention

The present invention relates to improvement of a battery / circuit peripheral structure of a timepiece.

[0002]

2. Description of the Related Art Conventionally, as a fixing means of a battery plus terminal which is a holding plate for holding and fixing the constituent members of a timepiece, it is fixed by a plurality of screw pins and screws which are press-fitted into a base frame. Alternatively, a method has been known in which a plurality of dowels provided on a synthetic resin base frame are thermally or mechanically deformed and fixed.

Further, a method of engaging an elastic beam portion extending from the battery positive terminal to the side surface of the base frame and a convex portion on the side surface of the base frame has come to be seen.

In addition to the above-mentioned means for guiding and fixing the battery positive terminal, which is a holding plate for holding and fixing the constituent members of the timepiece, the inner diameter of the guide hole of the battery positive terminal is burred on the dowel outer diameter of the base frame. Is a guide means by press-fitting, and means for fixing and guiding the battery plus terminal by combining two means such as fixing the battery plus terminal with a screw pin and a screw press-fitted into a base frame at a position different from the burring shape of the battery plus terminal. Is also common.

Conventionally, as a measure against disengagement of the battery negative terminal, which is a conduction spring member, from the base frame, it is held by a screw pin and a screw press-fitted into the base frame. Alternatively, a means is known in which the base frame dowel is raised to prevent disengagement even if the battery negative terminal is tilted.

Conventionally, even when the output side of the booster coil, which is an electric element mounted on the circuit block of the timepiece, is not electrically connected to the piezoelectric element, the booster coil boosts at the time of buzzer output.

Conventionally, the switch spring of the battery plus terminal, which is a holding plate for holding and fixing the constituent members of the timepiece, has been assembled into the base frame in a bent shape without engaging with other parts. The spring had no initial deflection.

Conventionally, the switch spring of the battery positive terminal is
Even when the contact portion between the circuit block and the button is at the same position or at different positions, the two points were rigid.

Conventionally, as a method of resetting an IC system, all of a plurality of buttons are pressed at the same time. Alternatively, it is common to pull out the crown to the second stage and simultaneously press two buttons.

[0010]

However, in the conventional means for fixing the battery positive terminal, in the case of fixing with the screw pin and the screw, it takes time to loosen the screw at the time of disassembling, and if the screw is damaged, the appearance will be damaged and the screw will be damaged. Had to replace. Further, when the dowel of the base plate, which is the base frame, is deformed thermally or mechanically, it cannot be disassembled and lacks after-sales serviceability such as parts replacement. Further, even when the elastic beam portion is used, there is a problem that the elastic beam portion is damaged when the disassembly and assembly are repeated.

Further, if the dowel of the base plate which guides the battery negative terminal is raised, the timepiece body becomes thicker. Further, when tightening and fixing with a screw pin and a screw, the cost increases due to an increase in the number of parts.

Further, when the battery positive terminal is guided by the burring shape and the main plate guide dowel, it is necessary to fix the battery positive terminal with a screw pin and a screw at a position different from the burring shape, which is a big limitation in a planar layout. It was

Further, since the buzzer output signal is boosted even when the output side of the booster coil mounted on the circuit block is not electrically connected to the piezoelectric element, the CMOS-IC is used.
However, there is a problem that a malfunction such as a system lit occurs due to the influence of noise due to the buzzer output.

Further, since the switch spring of the battery plus terminal is assembled in the bent shape without engaging with the base plate and the like, the variation of the bent shape in the machining of the parts causes the positional deviation of the switch spring in the initial state. , Switching failure occurred when pushing the button. If the contact point between the switch spring circuit block and the button is at the same position or at a different position and the two points are rigid, pressing the button too much applies excessive stress to the switch spring and breaks it. There was a problem that it became a cause.

In addition, when resetting the IC system, an operation method that is not possible with a normal button operation when carrying is carried out. However, when the crown is pulled out to the second stage, if the crown is dropped, the winding stem is broken. However, in the case of pressing all the buttons at the same time, there is a possibility that the system will be reset when the clock is held by hand.

As described above, the conventional technique has many problems, and the present invention solves such problems.
The object of the present invention is to provide a timepiece in which the quality and performance of the battery / circuit peripheral portion of an analog electronic timepiece are improved and the size is reduced.

[0017]

[Means for Solving the Problems] 1). In a structure of a timepiece including a base frame of a timepiece, a battery serving as a power source of the timepiece, and a holding plate that holds and fixes the constituent members of the timepiece, the holding plate has an engaging portion that engages with the base frame. The engaging portion is an elastic body that is pressed and fixed from the side surface of the battery, and at the same time, is engaged and fixed to the engaged portion of the base frame.

2). In the timepiece, the engagement part of the pressing plate is not engaged and fixed to the engaged part of the base frame in a state where the battery is not incorporated in the timepiece.

3). A base frame of a timepiece, a holding plate for holding and fixing the constituent members of the timepiece, a screw pin press-fitted into the base frame,
In a structure of a timepiece including a screw that engages with the screw pin, the pressing plate has a burring-shaped guide hole, and guide-engages the burring-shaped guide hole with the screw pin of the base frame, and the base frame. The pressing plate is fixed by the screw.

4). In the structure of a timepiece, which includes a base frame of a timepiece, a conduction spring member on the negative electrode side of a battery of the timepiece, electric elements that planarly overlap the conduction spring member, and a circuit block for mounting the electric elements, the conduction spring is provided. The member is guided by at least one or more protrusions of the base frame at a position different from the electric element in a plane, and the conduction spring member and the electric elements mounted on the circuit block overlap in a plane. In addition, the lower surface of the electric element is positioned below the upper surface of the protrusion of the base frame in cross section.

5). In the structure of a timepiece including a holding plate that holds and fixes the components of the timepiece, a circuit block that mounts electric elements, and a back lid that is an exterior member, pressure contact with the conducting portion of the circuit block is performed only when the back lid is closed. The holding plate is provided with a conduction spring that operates.

6). A base frame of a timepiece, a holding plate for holding and fixing the constituent members of the timepiece, a circuit block for mounting electric elements, and an exterior member, which is integral with the holding plate in the structure of the timepiece including buttons attached to the case. The switch elastic spring has a conductive portion with the circuit block at the tip, and a contact portion with the button at a position different from the conductive portion in cross section in the central portion of the switch elastic spring. Then, the protrusion that is the engaged portion provided on the outer peripheral portion of the base frame is engaged with the back surface of the conducting portion at the tip end portion of the switch elastic spring of the pressing plate, and the switch elastic spring is given an initial deflection. It is characterized by having it.

7). In a timepiece including a button that is an external operation member, a crown that is an external operation member, and a MOS-IC, the system reset of the MOS-IC is performed by rotating at least one button and the crown. ..

8). In a timepiece including a button that is an external operation member, a crown that is an external operation member, and a MOS-IC, the system reset of the MOS-IC is performed by simultaneously pressing at least two buttons and rotating the crown. And

[0025]

EXAMPLES The present invention will be described in detail below based on examples. FIG. 1 is a front plan view showing an embodiment of a multifunctional electronic timepiece according to the present invention. In this embodiment, two stepping motors are used to realize multiple functions.

Reference numeral 1 is a base plate formed by plastic resin molding, and 2 is a battery. Reference numeral 3 denotes a step motor A for driving a train wheel for indicating the time of the hour and minute hands, a magnetic core 3a made of a high-permeability material, a coil wound around the magnetic core 3a and a coil whose terminals are electrically connected to each other. Lead board 3
It comprises a coil block 3d composed of b and a coil frame 3c, a stator 4 composed of a high magnetic permeability material, a rotor 5 composed of a rotor magnet 5a and a pinion 5b. Also, 6, 7,
8 is a fifth wheel, a third wheel and a second wheel, respectively, 9 is a back wheel of the day, and 10 is a hour wheel. The center wheel & pinion 8 with the minute hand and the hour wheel with the hour hand are arranged at the center position of the timepiece body. With these motors and wheel trains, the time and minutes are displayed at the center of the timepiece according to their respective functions. For example, in the current time display function state, normal hour and minute display,
In the stopwatch function state, the stopwatch measurement hour / minute display is displayed, and in the alarm set function state, the alarm set time hour / minute display is displayed. FIG. 2 is a sectional view showing the engaged state of the train wheel for displaying the time and minutes. As shown in the figure,
The rotor pinion 5b meshes with the gear 6a of the fifth wheel & pinion 6, and the fifth pinion 6b meshes with the gear 7a of the third wheel & pinion 7. The pinion 7b of the third wheel & pinion 7 meshes with the gear 8a of the second wheel & pinion 8. The reduction gear ratio from the rotor pinion 5b to the second gear 8a is 1/120, and when the rotor makes a half rotation (180 °) in 15 seconds, the second wheel is 3600.
One rotation is made every second, that is, every 60 minutes, and the minute display of the time becomes possible.
Reference numeral 11 denotes a minute hand fitted to the tip of the center wheel & pinion 8 for displaying the minute. The second kana 8b is the gear 9a of the back wheel 9 of the day.
The back pinion 9b meshes with the hour wheel 10. The reduction ratio from the second pinion 8b to the hour wheel 10 is 1/12
And the time can be displayed at the time. 12
Is an hour hand fitted to the tip of the hour wheel 10 for displaying the hour.

In FIG. 1, reference numeral 13 is a step motor B for displaying a stopwatch seconds and date, and a magnetic core 13a made of a high magnetic permeability material, a coil wound around the magnetic core 13a, and both ends thereof are terminal-treated so as to be conductive. Coil block 13 including coil lead board 13b and coil frame 13c
d, a stator 14 and a rotor magnet 15 made of a high magnetic permeability material
The rotor 15 is composed of an a pinion 15b. Further, 16, 17, 18, and 19 are second CG first intermediate wheel, second CG second intermediate wheel, second CG third intermediate wheel, and second C, respectively.
It is a G car, and the second CG car 19 is arranged at the center position of the timepiece body. With these train wheel configurations, the seconds and days of the stopwatch are displayed coaxially with the hour and minute hands at the center position of the timepiece. FIG. 3 is a cross-sectional view showing the wheel train engagement state for displaying the stopwatch seconds and date. As shown in the figure, the rotor pinion 15b meshes with the gear 16a of the second CG first intermediate wheel 16 and the second CG first intermediate pinion 16d meshes with the gear 17a of the second CG second intermediate wheel 17. The second CG second intermediate pinion 17b meshes with the gear 18a of the second CG third intermediate pinion 18, and the second CG third intermediate pinion 18b meshes with the gear 19a of the second CG wheel 19. The reduction ratio from the rotor pinion 15b to the second CG gear 19a is 1/900. Reference numeral 20 is a center hand engaged with the tip of the second CG wheel 19 for displaying the seconds and the day. The center hand has a function of displaying seconds at one end and a function of calendar display at the other end, depending on the respective functional states. Further, in FIG. 1, reference numeral 21 denotes a 1/10 second CG wheel arranged on the axis of the watch body in the 12 o'clock direction, and a wheel train configuration including a rotor 15, a second CG first intermediate wheel 16, and a 1/10 CG wheel 21. Displays the stopwatch for 1/10 seconds. FIG. 4 is a cross-sectional view showing an engaged state of the train wheel for displaying the stopwatch 1/10 second. As shown in the figure, the second intermediate CG first intermediate kana 16b is the second CG wheel 21.
It meshes with the gear of. Rotor kana 15b to second CG
The reduction ratio up to the gear 21a is 1/15.

In the stopwatch function state, CM
The rotor 15 is set to 1 by the electric signal from the OS-IC 32.
Rotate 180 ° × 3 every / 10 seconds. This gives the second C
The G car 19 is 0.6 ° every 1/10 second, that is, 0.
It is possible to display seconds by rotating 6 ° x 10 steps and rotating once every 60 seconds. In addition, 1/10 second CG car 21 is 1/10
It rotates 36 ° every second, that is, 36 ° × 10 steps per second, and 1/10 second display is possible in conjunction with the second CG vehicle.
In the current time display function state, the CMOS-IC
The electrical signal from 32 causes the rotor 15 to rotate 180 ° × 3
Rotate 0 times or 180 ° x 60 times. As a result, the second CG wheel 19 rotates 6 ° or 12 °, and the center hand 2
0 can display the day at one end. As an example of displaying the day, when the second CG wheel 19 is displayed in increments of 6 °, for example, a half-round calendar display of 1 to 31 is possible from the 3 o'clock position to the 9 o'clock position. In the case of 12 ° increments,
If the distance between 29-30 and 30-31 is set at 6 ° intervals, full-circle calendar display is possible. An external view of an embodiment described later shows an embodiment in which a full-circle calendar is displayed.

In FIG. 1, reference numeral 22 denotes an external operating member, which is a winding stem with a crown. Reference numeral 23 is a temple that engages with the winding stem 22. The temple 23 engages with the hook 24 to determine the pull-out position of the winding stem 22, and at the same time, engages with the switch lever 25 and the lower surface dowel 23C to interlock the switch lever 25. The hook 24 determines the position of the hand wheel 26 in the axial direction of the winding stem 22 by engaging with the lever 23. With these switching structures, the circuit-like switching state of the timepiece is set. FIG. 5 is a sectional view showing an engaged state of this switching structure. As shown in the figure, the lever 23 is pivotally supported by the lever shaft 27 incorporated in the main plate 1, engages with the bolt 24 at the stepped side surface 23a, and the switch lever is provided with the dowel 23c integrally formed on the lower surface thereof. Engage with 25. Further, it is engaged with the winding stem at the lower surface portion 23b which is raised one step. The lever 23 is pressed and fixed by the rod presser spring 28a of the battery plus terminal 28, and is stable, and at the same time, it has three steps up and down with respect to the surface of the rod 23 received by the rod shaft 27. The moment of the force received from 24 can be minimized, and the temple 23 can be stabilized without being lifted up. The boot 24 and the switch lever 25, which is a switch member, are sandwiched between the train wheel bridge 29 and the main plate 1 and guided with a certain clearance. Switch lever 25
Is rotatable about the dowel 19 of the main plate 1, and by interlocking with the lever 23, the contact spring portion 25a with the circuit of the switch lever 25 is pressed against the circuit block 30. Further, the switch lever 25 is in pressure contact with the circuit block 30, and at the same time, has a structure in which it is in pressure contact with the mode correction jumper 31 by its reaction force. The mode correction jumper 31 is positively conducted by the positive conduction spring 28b of the battery positive terminal 28 and is electrically conducted to the switch lever 25.

In FIG. 1, a battery plus terminal 28 is made of an elastic conductive member. The battery 2 is held and conducted by the battery side pressure springs 28c and 28d of the battery plus terminal 28, and the upper surface is fixed by the battery pressing plate 33.
The battery positive terminal 28 has switch spring portions 28e and 28f substantially symmetrically with respect to the winding stem 22 located at 3 o'clock. In addition, the battery plus terminal is a spring 28g, 28g for preventing looseness of the anti-magnetic plate located between the timepiece body and the back lid which is an exterior member.
h, 28i, spring 28 for preventing play in the cross section of the watch body
k, 28l, 28m, crystal unit holding spring 28n,
It has a positive conduction spring 28p to the boost coil. With these elastic spring configurations, conduction as a watch body, holding and fixing of parts, holding of the watch body, etc. are performed.

FIG. 6 is a sectional view showing the fixing portion of the battery 2 held by the battery plus terminal 28. As shown in the figure, the battery 2 is held from the side by the battery side pressure springs 28c and 28d of the battery plus terminal 28, and at the same time, the battery 2 is positively conducted. The state of the battery side pressure spring 28d before the battery is installed is at the position 28d 'as shown by the chain double-dashed line, and at the same time as the battery 2 is installed, the engaged portion 1b of the ground plate 1 is engaged.
By engaging the engaging portion 28d-1 of the battery plus terminal 28 with the above, the battery 2 is held by the lateral pressure of the spring, and the battery plus terminal 28 can be prevented from rising above the cross section. Further, the battery pressing plate 33 has a burring portion 33a guided by the battery side tip of the screw pin 81 fixed to the main plate 1 and the outer peripheral portion of the main plate opening 1c which escapes the outer periphery of the burring portion 33a. It is clamped and fixed by tightening the screw 91. The battery pressing plate 33 is positioned by the burring portion 33a, and at the same time, the battery pressing plate 33 is rotationally positioned by the engaging portion 33b that engages with the positioning hole 28q of the battery plus terminal 28. Battery retainer plate 3
When assembling and fixing 3, the burring portion 33a can be positioned and the screw 91 can be tightened and fixed at the same position, so that the member can be fixed in a very small space. In addition, as described above, the battery positive terminal 28
The battery side pressure spring 28d of 28
Since it returns to the position of d ', it has a structure that does not require a process such as removing screws.

FIG. 7 is a sectional view showing the switch portion of the switch spring portion 28f constituted by the battery plus terminal 28. 8 and 9 are a sectional view showing a contact portion between the circuit board 30a and the switch conducting portion 28f-1 of the battery plus terminal 28, and a sectional view showing a button pressing portion 28f-2. As shown in the figure, the switch conducting portion 28f-1 located at the tip of the switch spring portion 28f of the battery positive terminal 28 is at the position of 28f-1 'shown by the chain double-dashed line in the state before the spring is assembled. At the same time, it engages with the spring hooking portion 1d of the base plate 1 to give the spring an initial deflection. By giving the switch spring an initial deflection, it is possible to suppress variations in the planar spring positions of the switch conducting portion and the button pressing portion, and at the same time, it is possible to have a reaction force for returning the button.
In this embodiment, the switch conducting portion 28f-1 at the tip of the spring is hooked on the main plate 1d, so that the planar position of the button pressing portion located in the middle of the spring is stable without variation. Next, the button pressing will be described in detail.
The switch spring portion 28f is pressed against the spring base portion 28f-3 and the switch conducting portion 28f-1 by a button pressing portion 28f-.
2 is formed in a T shape. When the button 34 is pressed, the switch conducting portion 28f-1 is contacted and a switch input is made. Further, even if the button 34 is pushed, the button pressing portion 28f-2 of the switch spring portion is twisted,
Even if the button 34 is pushed too much, the switch spring portion 28f does not generate more stress than necessary, and there is no breakage or settling.

Next, the circuit configuration of the circuit block 30 will be described. In FIG. 1, 35 is a battery negative terminal, 3
Reference numeral 6 is a buzzer lead terminal that is pressed against the piezoelectric element. As electric elements mounted on the circuit block 30, 37 is a step-up coil, 38 is a buzzer transistor, 39 is a battery protection capacitor, 40 is a rate regulation capacitor, 4
Reference numeral 1 is a crystal unit containing a crystal oscillator, and 32 is a CMOS-IC for transmitting electric signals. Reference numeral 42 is a circuit spacer for press-connecting the circuit block 30 and the coil lead substrates 3b and 13b with each other in a sectional manner. The electric circuit configuration will be described later, and the circuit structure will be described in detail here. The CMOS-IC 32 is wire-bonded to the circuit board 30a and then fixed by the mold 30b. The other elements are mounted by soldering and fixed.

FIG. 10 is a sectional view showing the conducting structure of the battery negative terminal 35. The battery negative terminal 35 is the main plate 1
It is guided by the guide dowels 1e and 1f, and has a structure in which one end is in contact with the (−) side of the battery 2 and the other end is in contact with the circuit board 30a with the shoulder portion 1g of the main plate as a fulcrum. The battery negative terminal 35 and the buzzer transistor 38 are arranged so as to overlap each other in plan view. The transistor 38 has an outer periphery covered with a resin material, and does not short-circuit even if it comes into contact. Further, in the same figure, the spring 28k for preventing backlash of the battery positive terminal 28 is provided with a spring 28p for conducting a positive potential to the boosting coil 37 in the vicinity thereof. The backlash prevention spring 28k is bent with the spring 28p by incorporating the back cover 71 which is an exterior member.
p comes into pressure contact with the circuit board 30c. That is, the booster coil 37 has a structure in which an exterior is incorporated and a positive potential is obtained only in a complete state. This is because if there is a buzzer output while the piezoelectric element is not connected, the output noise may reset the CMOS-IC.

As described above, the guide dowel 1 of the main plate 1 for positioning the battery negative terminal 35 in FIG.
A transistor 38 is arranged in the middle between e and 1f so as to overlap in a plane. Since the mounting position of the normal transistor 38 is arranged so as not to overlap with other components due to the planar overlapping, it is possible to reduce the space and allow a margin for the arrangement of other components. Further, by ensuring a certain amount of cross-sectional overlap H1 between the guide dowels 1e and 1f of the main plate 1 and the transistor 38, the battery negative terminal 35 does not disengage from the guides 1e and 1f when a shock is applied. Can be

FIG. 11 is a back plan view showing an embodiment of the multi-function electronic timepiece of the invention shown in FIG. In addition to FIG. 1, the electronic timepiece of the present invention is a hand type in which a stopwatch function, an alarm function, a timer function, a dual time display function, etc., in addition to the basic timepiece function, are arranged at the center of the timepiece and at the 3 o'clock, 9 o'clock and 12 o'clock positions. This means that the display is to be performed.
A mode display structure for displaying each function by a window arranged at the 6 o'clock position on the dial will be described below.

FIG. 12 is a plan view of a main portion showing the switching portion and the mode correction contact portion of FIG. 1, and FIGS. 13, 14 and 15 are sectional views showing the mode correction structure. In FIGS. 11 to 14, the clutch wheel 26 meshes with the mode correction transmission wheel 101 at the 0th stage of the winding stem so that the mode can be switched by rotating the winding stem 22 in the normal carrying state. When the winding stem 22 is turned, the hand wheel 26 rotates, and further the rotation is transmitted to the mode correction axle 104 via the mode correction transmission wheel 101, the first mode correction intermediate wheel 102, and the second mode correction intermediate wheel 103. As shown in FIG. 13, the mode correcting axle 104 penetrates from the front side to the back side (the dial 72 side) of the timepiece body, and is guided and held in guide holes provided in the main plate 1 and the train wheel bridge 29, respectively. The main plate engaging portion 104a of the mode correcting axle 104 has a circular cross section, and the engaging portion 104b of the mode contact spring 105 which is a rotary switch and the engaging portion 104c of the second mode correcting intermediate wheel 103 are shown in FIG. D as shown
It has a shape, and is configured to engage with the D-shaped holes provided in each of the mode contact spring 105 and the second mode correction intermediate wheel 103 so that the three parts rotate integrally.
Contact portions 105a and 105 of the mode contact spring 105
b is the substrate 3 of the circuit block 30 on which electric elements are mounted
0a patterns 30d, 30e, 30f, 30g, 3
It comes into contact with 0h. With the above-described structure, the mode contact spring 105 rotates in association with the winding stem operation, and the contact portions 105a and 105b and the patterns 30d to 30h.
By changing the combination of contacts, the modes can be electrically switched. That is, the contact portion 105b of the mode contact spring 105 always has a positive potential of 30
It is possible to create max2 ³ states depending on whether the contact point 105a at the other end is open (non-contact state) or is connected to 30e, 30f, or 30g by being connected to d and being connected to 30d. Further, in the winding stem normal state, by simultaneously pressing the A and B switches while rotating the winding stem, the contact portion 105a of the mode contact spring 105 is brought into conduction with the pattern 30h on the circuit board, and the circuit board 30a. It is possible to reset the system of the CMOS-IC.

The mode correction axle shaft 104 is rotationally positioned by engaging the jump control portion 31a of the mode correction jumper 31 with a jump control gear 104e formed integrally with the mode correction axle shaft 104. Mode correction jumper 31 is main plate 1
The jump control portion 31a is incorporated and guided by the dowels 1h and 1i and is positioned by being hooked on the main plate 1j. In this state, the jump control gear 104e of the mode correction axle 104 and the jump control portion 31a of the mode correction jumper 31 have a constant clearance H ₂ . When the clearance is not provided, the rotational positioning of the mode correcting axle 104 can be performed without rattling, but when the force is applied by the mode correcting jumper 31 when the guide of the mode correcting axle 104 is only the main plate in the assembly process, the mode correcting axle 104 tilts and the wheel train to be incorporated later. The receiver is very difficult to incorporate. Therefore, by providing the above-mentioned clearance H ₂ , the assembling property is improved. However, if the clearance H ₂ is too large, the positioning becomes impossible, so it is set to about 2/100 mm.

By rotating the winding stem 22, the winding stem rotates with a load torque until the jump control gear 104e of the mode correction axle 104 crosses the top of the jump control portion 31a of the mode correction jumper 31. And the jump control section 31a
The structure is such that the mode correction jumper 31 rotates from the top to the rest position by the jump control force. Therefore, in the transmission system related to the mode correction from the mode correction axle 104 to the second mode correction intermediate wheel 103, the first mode correction intermediate wheel 102, the mode correction transmission wheel 101, and the winding stem 22 via the clutch wheel 26, Modified axle 104
However, it is necessary to consider so that it can be surely rotated by the jump control of the mode correction jumper 31. In the present embodiment, in the D-shaped shape of the engaging portion 104c of the mode-correcting axle 104 and the D-shaped center hole shape of the second mode-correcting intermediate wheel 103, the rotation direction of more than half the gear pitch of the jump control gear 104e of the mode-correcting axle 104 is used. The hole width of the D-shaped center hole shape of the second mode correction intermediate wheel 103 is widened so that a play can be obtained. Therefore, the movement of the mode correction axle 104 becomes smooth, and the movement of the mode display wheel 106 described below can also be made smooth. In FIG. 11, the mode display wheel 106 is made of a synthetic resin material, and has “Time”, “Reset”, and “→ 0”.
The mode display unit 10 on which character strings, marks, etc. indicating the functional states such as “←”, “Chrono”, and “Timer” are printed.
6b and internal teeth provided inside the display unit,
Is guided by the inner tooth portion in a guide portion 1k provided in the center of the center of the clock having an arc shape. In the present embodiment, the display located in the 6 o'clock direction is made visible through a window hole 72a provided in the dial 72 in the 6 o'clock direction to selectively display the mode state. Reference numeral 107 denotes a mode-correcting wheel, which engages with the mode-correcting wheel engaging portion 104d of the mode-correcting axle 104 by a D-shaped hole provided at the center and rotates integrally with the mode-correcting axle 104. The mode correction wheel 107 meshes with the internal teeth of the mode display wheel 106, and the rotation of the mode correction wheel 104 is controlled by the mode display wheel 1.
Tell 06. Therefore, the mode display wheel 106 can rotate around the center of the clock. According to the above-described structure, the mode display portion 106b of the mode display wheel 106 can be arranged closer to the outer periphery with respect to the center of the clock, and as a result, the display area for one mode in the mode display portion 106b becomes wider, and a large and easy-to-see mode display is provided. It will be possible. The mode display wheel 106 is plane-positioned by the mode display jumper 108, and the mode display wheel is clamped by the mode display wheel holding plate 109 with a certain clearance. Since the jump control force of the mode display wheel 106 by this mode display jumper 108 is transmitted as a load to the mode correction axle 104 via the mode correction wheel 107, the jump control force of this mode display jumper 108 is the jump of the mode correction jumper 31 described above. It is set to be as weak as possible. Mode display jumper 108
Since the variation in the mode display position can be reduced by using, the gap between the window hole of the dial and the character string indicating the mode, the mark, etc. can be reduced, and the character size can be increased accordingly.

As described above, the mode correcting axle 104 is rotated by the rotating operation of the winding stem 22, and the electric mode can be switched on the front side of the timepiece, and at the same time, the mode can be changed on the back side of the timepiece via the mode correcting wheel 107. The display wheel 106 rotates to switch the mode display. In this embodiment, the number of teeth of the jump control gear 104e of the mode correction axle 104 is six, and the number of teeth of the mode correction wheel 107 capable of performing six functional states is 12 per revolution of the mode correction axle 104.
The number of teeth of the mode display wheel 106 is 24, and the mode display wheel 106 is set to make a half turn for one rotation of the mode correction axle 104. Further, in order to match the phases of the functional states of the mode correction wheel 107 and the mode display wheel 106, a positioning hole 107a is formed on the mode correction wheel 107 and 106a is printed on the mode display wheel 106 by printing, and they are incorporated at positions matched with each other. Is being carried out. As a result, it is possible to display the mode that matches the electrical mode setting state.

Reference numerals 109 and 110 denote a mode display wheel holding plate and a hour wheel holding plate, respectively, which are holding members for the vehicles related to the auxiliary needle display and the vehicles related to the mode display. Similar to the dial 72, the mode display holding plate 109 is a window hole 1 for mode display.
09a. In the present embodiment, the mode display section is set to the 6 o'clock direction, but according to the mode display structure of the present invention, the display section is set at any position within the range in which the mode display section of the mode display wheel 106 can rotate. Since it can be set, the degree of freedom in design increases. Also, the mode display car holding plate 1
No. 09 has a step 109b in the vicinity of the root positions of the inner teeth of the mode indicating wheel 106 so as not to rub the mode printing surface of the mode indicating wheel 106. The mode display wheel holding plate 109 may have a structure in which the tooth portion of the mode display wheel 106 is held with a constant gap in cross section and a step is provided on the outer peripheral portion to protect the printing surface. Further, the hour wheel holding plate 110 positions the cross section of the hour wheel 10 arranged at the center of the timepiece. The hour wheel presser 110 has bending up portions 110a and 110b at the upper portion of the hour wheel 10 and is located between the hour wheel retainer 110 and the mode display wheel retainer plate 109. This is to prevent the hour wheel 12 from being lifted up via the dial 72 and the mode display wheel retainer 109 when the hour hand 12 engaging with the distal end portion of the hour wheel 10 is pulled out, and the date when the hour wheel 12 meshes with the hour wheel 10 is prevented. This has the effect of eliminating tooth crushing of the back pinion 9b and the 24-hour intermediate wheel 111.

In FIG. 12, the switch lever 25, which is a switch member, rotates around the rotary shaft 1h formed on the main plate through the temple 23 with the withdrawal of the winding stem 22 and the winding stem 1 with the contact portion 25a. It is electrically connected to the pattern 30i formed on the circuit board at the second stage and electrically connected to the pattern 30j at the second stage of the winding stem. Thereby, the correction state of the hour and minute hands and the date is created by the combination with the contact state with the circuit pattern of the mode contact spring 105 described above.

In FIG. 11, reference numeral 10 denotes an hour wheel, which indicates the hour by the above-described front train wheel configuration. Reference numeral 111 is a 24-hour intermediate wheel that meshes with the hour wheel, and 112 is a 24-hour vehicle that meshes with the 24-hour intermediate wheel. Reference numeral 113 is a DT24 intermediate wheel which also meshes with the hour wheel, and 114 is the DT24.
It is a DT24 hour car that meshes with the intermediate hour wheel. 24 o'clock car 11
2 and DT24 hour wheel 114, 1/10 CG mentioned above
The wheel 21 is a pointer wheel for the auxiliary hand arranged at an equal distance from the center of the timepiece body. With these back train arrangements, 24
The hour and dual time 24:00 are displayed. Figure 1
4 and 16 are cross-sectional views showing the gear train meshing state for the 24:00 and dual time 24:00 display. As shown in the figure, the 24-hour wheel 112 and the DT 24-hour wheel 114 are the hour wheel 10
From each 24 hour intermediate car, DT 24 hour intermediate car 1 /
It will be decelerated to 2, and it will function as a secondary hand wheel indicating 24 hours. The DT24 hour wheel 114 has a structure in which the dual time can be independently corrected by pulling out the winding stem 22 one step. By pulling out the winding stem 22 one step, the clutch wheel 26 is operated by the operation of the lever 23 and the bolt 24 described above.
Moves and meshes with the correction wheel 115 at DT 24 o'clock. By rotating the winding stem 22 in this state, the DT24 hour correction wheel 115 rotates, and the DT24 wheel 114 that meshes with the DT24 hour correction wheel 115 rotates. DT24 o'clock car is the hour wheel 1
0 and the DT24H intermediate car 113 are interlocked,
Since the gear 113a and the pinion 113b of the intermediate wheel 113 at DT24 o'clock have a structure capable of slip rotation,
By operating the winding stem 22, the DT24 hour wheel 114 can be independently corrected, and the dual time display can be performed.

Next, the circuit configuration of the multi-function electronic timepiece of the invention will be described.

FIG. 17 shows a circuit connection diagram of the CMOS-IC 32 and other electric elements. In FIG. 17, 2 is a silver oxide battery, 3b is a step motor A coil block, 1
3b is a coil block of the step motor B, 37 and 3
8 is an element for driving the buzzer, 37 is a booster coil, 3
8 is a mini-molded transistor with protection diode, 39
Is a 0, 1 NF chip capacitor for suppressing the voltage fluctuation of the constant voltage circuit built in the CMOS-IC 32, and 41 is an ultra-small tuning fork type crystal oscillator which is a source oscillation of the oscillation circuit built in the CMOS-IC 32. Reference numeral 40 is a rate adjusting capacitor for rate adjustment, and 53 is a piezoelectric buzzer. Four
Reference numeral 5 is an A switch, and 46 is a B switch, which is input only when the push button switch is pushed. Reference numeral 47 is a C switch, and 48 is a D switch, which serves as a switch with the above-mentioned switch lever 25 and electrically determines the pull-out position of the winding stem 22. When the switch C47 is closed, the winding stem 22 is in the second stage, when the switch D48 is closed, the winding stem 22 is in the first stage, and the switch C47 and the switch D4.
When 8 is open, it is determined that the winding stem 22 is in the normal position. 49 is RA1 switch, 50 is RA2 switch,
Reference numeral 51 is an RB1 switch, which electrically switches the modes corresponding to the switch patterns 30e, 30g, 30f of the mode switching unit described above. Reference numeral 52 is an RB2 switch, which enables the system reset of the CMOS-IC by simultaneous input of the A switch 45 and the B switch 46. 28P is a battery positive terminal spring for applying a positive potential to the boosting coil 37 described above.

FIG. 18 shows the CMOS-I used in this embodiment.
The block diagram of C20 is shown. As shown in FIG. 18, CM
The OS-IC 32 includes a program memory, a data memory, four motor drivers, a motor hand movement control circuit, a sound generator, on one chip centering on a core CPU.
It is a one-chip microcomputer for an analog electronic timepiece that integrates an interrupt control circuit and the like. Below, Figure 1
8 will be described.

Reference numeral 201 denotes a core CPU, which is composed of an ALU, a calculation register, an address control register, a stack pointer instruction register, an instruction decoder, etc., and an address bus (adbus) by a memory mapped I / O system with peripheral circuits. ) And a data bus (dbus).

Reference numeral 202 denotes a program memory composed of a mask ROM having a structure of 2048 words × 12 bits.
It stores software for operating C.

Reference numeral 203 is an address decoder of the program memory 202.

Reference numeral 204 is a data memory consisting of a RAM of 112 words × 4 bits, and is used as a timer for various clocks, a counter for storing the needle position of each pointer, and the like.

Reference numeral 205 is an address decoder of the data memory 204.

Reference numeral 206 denotes an oscillator circuit, which has Xin and Xo.
A tuning fork type crystal unit connected to the ut terminal
It oscillates at 68 Hz.

Reference numeral 207 denotes an oscillation stop detection circuit, which detects when the oscillation of the oscillation circuit 206 is stopped and resets the system.

Reference numeral 208 denotes a first frequency dividing circuit, which is an oscillation circuit 2
The 32768 Hz signal φ _32K output from the H.06 is sequentially divided to output a ₁₆ Hz signal φ ₁₆ .

Reference numeral 209 denotes a second frequency dividing circuit, which divides the 16 Hz signal φ ₁₆ output from the first frequency dividing circuit 208 into a 1 Hz signal φ ₁ . The state of each frequency dividing stage from 8 Hz to 1 Hz can be read into the core CPU 201 by software.

Further, in the IC of this embodiment, 16 Hz signal φ ₁₆ , 8 Hz signal φ ₈ and 1 Hz signal φ are used as the time interrupt Tint for processing such as clock timing.
₁ is used. The time interrupt Tint is generated at the falling edge of each signal, and reading, resetting and masking of each interrupt factor are all performed by software, and resetting and masking can be individually performed for each factor.

A sound generator 210 forms a buzzer drive signal and outputs it to the AL terminal. The drive frequency, ON / OFF, and ringing pattern of the buzzer drive signal can be controlled by software.

Reference numeral 211 denotes a stopwatch circuit, which is 1
/ 100 seconds 1/10 when configuring a stopwatch
It is possible to significantly reduce the load on the software by controlling the movement of the 0 second hand by hardware.

Reference numeral 212 denotes a motor hand movement control circuit, which is specifically configured as shown in FIG. 19 and outputs a motor drive pulse to each motor driver based on a command from software. Hereinafter, FIG. 19 will be described.

Reference numeral 219 is a motor hand movement type control circuit,
The hand movement method of each motor is stored according to a command from the software, and Sa for selecting the forward rotation drive I, Sb for selecting the forward rotation drive II, Sc for selecting the reverse rotation drive I, Sd for selecting the reverse rotation drive II, and S to select the rotation correction drive
It forms and outputs each control signal of e.

Reference numeral 220 denotes a hand movement reference signal forming circuit, which is specifically constructed as shown in FIG. 20 and forms and outputs a hand movement reference clock Cdrv according to a command from software.

In FIG. 20, reference numeral 2201 denotes a 3-bit register, which stores data for determining the frequency of the hand movement reference clock Cdrv in response to a command from software (output signal of the address decoder 2202). Reference numeral 2203 denotes a 3-bit register, which captures and stores the data stored in the register 2201 at the trailing edge of the hand movement reference clock Cdrv output from the programmable division period 2205. 2204 is a decoder, which corresponds to the data stored in the register 2203,
The numbers 2, 3, 4, 5, 6, 8, 10, 16 are output in binary form. 2205 is a programmable frequency divider,
256 Hz signal φ output from the first frequency dividing circuit 208
_{When 256} is n, the numerical value output from the decoder 2204 is n, and the frequency is divided into 1 / n and output. Therefore, the hand movement reference signal forming circuit 220 receives the instruction from the software,
The frequency of the reference clock Cdrv for hand movement is 128 Hz, 8
5.3Hz, 64Hz, 51.2Hz, 42.7Hz,
It is possible to select from 8 types of 32 Hz, 25.6 Hz, and 16 Hz. Further, the frequency of the reference clock Cdrv for hand movement is changed at the time when data is taken into the register 2203, and the data is taken into the register 2203 in synchronization with the clock Cdrv for hand movement reference. When switching to the next frequency fb, an interval of 1 / fa is always ensured.

When the forward rotation drive I and the reverse rotation drive are continuously performed, the frequency of the hand movement reference clock Cdrv is limited to 64 Hz or less.

Reference numeral 221 denotes a first drive pulse forming circuit, which forms and outputs the drive pulse Pa for the normal rotation drive I shown in FIG.

Reference numeral 222 denotes a second drive pulse forming circuit, which forms and outputs the drive pulse Pb for the forward drive II shown in FIG.

Reference numeral 223 denotes a third drive pulse forming circuit, which forms and outputs the drive pulse Pc for the reverse drive I shown in FIG.

Reference numeral 224 denotes a fourth drive pulse forming circuit, which forms and outputs the drive pulse Pd for the reverse drive II shown in FIG.

225 is a fifth drive pulse forming circuit, which is a pulse group Pe for correction drive (Japanese Patent Laid-Open No. 60-2608).
The normal drive pulse P ₁ , the correction drive pulse P ₂ , the AC magnetic field detection pulse P ₃ , the AC magnetic field detection pulse SP ₁ , and the rotation detection pulse SP ₂ ) disclosed in 83 are formed and output.

Reference numerals 226, 227, 228, and 229 denote motor clock control circuits, which are specifically configured as shown in FIG. 25, and each control the number of hand movement pulses of the step motor by a command from software.

In FIG. 25, 2261 is a 4-bit register, which stores the number of hand movement pulses instructed by software. Reference numeral 2262 is a 4-bit amplifier counter, which counts the reference clock Cdrv for hand movement passing through the AND gate 2274, and is reset by the control signal Reset. 2263 is a coincidence detection circuit,
The contents of the register 2261 and the up counter 2262 are compared, and when they match, a match signal Dy is output. Reference numeral 2264 denotes an all-1 detection circuit, which outputs an all-1 detection signal D ₁₅ when the content of the register 2261 is all-1. 226
Reference numeral 5 is a motor drive pulse forming trigger signal generation circuit, which is composed of NOT gates 2266 and 2267, a 3-input AND gate 2268, a 2-input AND gate 2269, and a 2-input OR gate 2270, and all 1 (15) is set in the register 2261. When it is turned on, the motor pulse is repeatedly output until other data is set,
When data other than all 1's is set, the motor pulse is output by that amount, and the motor pulse output is stopped until the next data is set. Reference numeral 2271 denotes a bidirectional switch, which has a control signal Sre
Turns on when ad is output, and up counter 226
Put the data of 2 on the data bus. Reference numeral 2272 denotes a control signal forming circuit, which is a signal Ss for setting the number of hand movement pulses in the register 2261 according to a command from software.
et, a signal Sread for reading the data of the up counter 2262, and a signal Sreset for resetting the register 2261 and the up counter 2262 are formed and output. When the signal Sread is output, the NOT gate 2273 and the AND gate 2274 prohibit passage of the hand movement reference clock Cdrv. In this case, after reading, it is necessary to generate the signal Reset and reset the register 2261 and the up counter 2262. When the match detection circuit 2263 detects a match (when output of the set number of pulses is completed), each motor has a motor control interrupt (Mint).
To occur. When a motor control interrupt occurs, the software can read which interrupt occurred and can reset it after reading.

Reference numerals 230, 231, 232, and 233 are trigger forming circuits, and the hand movement system control signals Sa, Sb, Sc, Sd output from the motor hand movement system control circuit 219.
The trigger signal Tr output from the motor clock control circuit corresponding to Se is 221, 222, 223, 224,
Each drive pulse control circuit 225 has a motor drive pulse P
The trigger signals Sat, Sbt, Sct, Sdt, and Set for forming a, Pb, Pc, Pd, and Pe are passed.

Reference numerals 234, 235, 236 and 237 denote motor drive pulse selection circuits, which are the hand movement system control signals Sa and S.
Motor drive pulses Pa, Pb, Pc output from the drive pulse forming circuits corresponding to b, Sc, Sd, and Se.
The drive pulse required for each step motor is selected from Pd and Pe and output. This is the end of the description of FIG.

Reference numerals 213, 214, 215, and 216 denote motor drivers, which alternately output the motor drive pulses output from the motor drive pulse selection circuit to the two output terminals of each motor drive circuit, respectively. To drive.

Reference numeral 217 is an input control and reset circuit, which is A, B, C, D, RA1, RA2, RB1, RB2.
Processing of each switch input and processing of K, T, and R input terminals. Any one of A, B, C, D or any one of RA1, RA2, RB1, RB2
Switch interrupt SWi when two switches input
nt is generated. At this time, reading and resetting of the interrupt factor are performed by software. In addition, each input terminal is _pulled down to V _SS , and becomes data 1 when connected to data φ and V _DD in the open state.

The K terminal and the D1, D2, D3 and D4 terminals are specification switching terminals, and several kinds of specifications can be selected according to the data of these terminals. The data of these terminals is read by software.

The R terminal is a system reset terminal, and R
When the terminal is connected to V _DD , the core C
The PU, frequency dividing circuit and other peripheral circuits are forcibly set to the initial state.

The T terminal is a test mode conversion terminal, and R
By inputting a clock to the T terminal with the A2 terminal connected to V _DD , 16 test modes for testing peripheral circuits can be switched. The main test modes include a forward rotation I confirmation mode, a forward rotation II confirmation mode, a reverse rotation I confirmation mode, a reverse rotation II confirmation mode, a correction drive confirmation mode, and a chronograph 1/100 second confirmation mode. In the confirmation mode, the motor drive pulse is automatically output to each motor drive pulse output terminal.

System reset can be performed by simultaneous input of switches in addition to the method of connecting the R terminal to V _DD ,
This IC is configured such that when there are simultaneous inputs of A, B and RB2, the system is forcibly reset by hardware.

Further, as reset functions that can be processed by software, there are a frequency divider circuit reset and a peripheral circuit reset. When the peripheral circuit reset is performed, the frequency divider circuit is also reset.

Reference numeral 236 is an interrupt control circuit, which prioritizes the interrupts, stores before the reading, and performs reset processing after the reading regarding the switch interrupt, the chronograph interrupt, and the motor control interrupt.

Reference numeral 200 denotes a constant voltage circuit, which is from the battery voltage (about 1.58V) applied between V _{DD and} V _SS to about 1.2V.
Form a low constant voltage and output it to the V _SS terminal.

This is the end of the description of FIG.

As described in detail above, the CMOS-
The IC 32 has the following features for driving a step motor, and is a multi-hand type multifunctional analog electronic timepiece I.
Very good as C.

Motor drivers 213, 214, 21
5 and 216, four step motors can be driven simultaneously.

It has a hand movement control system control circuit 219, drive pulse forming circuits 221 to 225, and motor drive pulse selecting circuits 234 to 237.
Each of the step motors can be made to perform three types of forward drive and two types of reverse drive.

The hand movement reference signal forming circuit 220 is provided, and the hand movement speed of each step motor can be freely changed by software.

The motor clock forming circuits 226 to 229 corresponding to the four step motors are provided, and the number of hand movement pulses of each step motor can be freely set by software.

FIG. 26 is an external view of a completed body of the multifunctional electronic timepiece of this embodiment. Reference numeral 60 is an outer case, and 72 is a dial. Crown 61 interlocking with winding true at 3 o'clock position, 2 o'clock,
Buttons 45a and 46a are arranged at the 4 o'clock position. At the center of the watch body, the hour hand 12, minute hand 11, and center hand 20 described above are provided.
It has an hour display, a minute display, a stopwatch second display, and a day display. The sub hands arranged equidistantly from the center of the timepiece are the 1/10 second chronograph hand 64 at the 12 o'clock position, the dual time 24-hour hand at the 3 o'clock position, and the 24-hour hand at the 9 o'clock position. A mode display window 72a for displaying the function at the 6 o'clock position is provided on the dial, and a function display is displayed below the mode display wheel 106a. In this embodiment, the following six mode displays are provided, and the function corresponding to each mode display is provided. The six modes are "TIME",

[Outer 1] “→ 0 ←”, “TIMER”, and “CHRONO”.

Of the six modes, in the 0 position setting mode indicated by the display "→ 0 ←", the hour hand 12 and the minute hand 1
1, center hand 20, 1/10 second chronograph hand 64,
The reference position of the 24-hour hand 65 is set. Crown 6
1 to rotate the switch RA13 for mode switching
0e, RA230g, and RB130f, RB130
When only the switch 51 of f is turned on, the zero position set mode is set. When the crown 61 is in the first stage (when D48 is on), when the A switch 45 is turned on, the 1/10 second chronograph hand 64 is turned clockwise by one step (hereinafter referred to as forward direction). The hands are moved, and the center needle 20 is also moved in conjunction with this. When the B switch 46 is input, the 1/10 second chronograph hand 64 is moved counterclockwise (hereinafter referred to as the reverse direction), and the center hand 20 is also moved in conjunction with this. A or B switch 4
By continuing to press 5 and 46, the fast-forwarding hand movement can be performed and the 0 position can be quickly set. At this time, the reference clock Cdrv for hand movement is 128 Hz in the forward rotation direction and 51.2 Hz in the reverse rotation direction. Similarly, crown 61 is 2
At the stage (when C47 is on), by pressing the A or B button 45a, 46a, the hour hand 12, minute hand 1
The reference position of the 1 and 24 hour hand 65 can be set. Number of hand movement steps, direction of hand movement, reference clock for hand movement Cdrv
Is the same as the setting of the center hand 20 and the 1/10 second chronograph hand 64. The reference clock for hand movement is 128 Hz in the normal rotation direction and 51.2 Hz in the reverse rotation direction in all the other modes. In each mode, the position of each needle is always stored in the needle position counter formed in a part of the data memory 204 with reference to the position set in the 0 position setting mode.

27 and 28 are flowcharts of the normal time mode indicated by the display of "Time". When none of the mode switching switches are turned on, the normal time mode is set. When using the multifunctional electronic timepiece of the present invention, it is expected that the time used in the normal time mode is the longest. Therefore, in this mode, all the mode switching switches are turned off, so that the average current consumption is reduced. It can be expected to reduce the battery life and extend the service life of the battery. 27 and 28
As shown in, when a 1 Hz interrupt is input, 1 is added to the 15-second counter formed in a part of the data memory 204, and when the value of the 15-second counter is 15, the motor hand movement method control circuit 219 Step motor A
Motor rotation control circuit A22
Set the number of hands to 1 to 6.

The correction of the current time is performed with the crown 61 in the second stage. When the crown 61 is in the second stage, the hour / minute hands 12 and 11 are moved in the forward direction to the position of the minute. Each time the button 45a (A switch 45) is pressed, the hour / minute hands 12 and 11 are moved in the forward direction in units of 1 minute. Every time the button 46a (B switch 46) is pressed, the hour and minute hands 12, 11
Is moved in the reverse direction in units of 1 minute. By continuing to press button 45a or 46a, the needle will be moved fast forward,
Correction is possible in a short time.

The date is corrected with the crown 61 in the first stage. By pressing the button 45a with the crown 61 in the first stage, the center needle 20 is moved in the forward direction every day. Each time the button 46a is pressed, the center needle 20 is moved in the reverse direction every day. Each time the button 46a is pressed, the center needle 20 is moved in the reverse direction every day. Same as the correction of the current time, button 45a or 4
Correction by fast-forwarding is also possible by pressing and holding 6a. The center hand 20 indicating this date has a current time of 2
At 4 o'clock, the 1 / 10-second chronograph hands are instantaneously rotated simultaneously to advance the date by one day, so that the date can be clearly confirmed even at around 24:00 midnight unlike the conventional analog clock.

29 and 30 show flowcharts of the stopwatch function. Incidentally, "CG" used in FIGS. 29 and 30 means a stopwatch. Also,
“CG start” indicates that the stopwatch is being measured and the split display is released. RA13 by rotating the crown
When the 0e switch 49 is on and the crown is in the 0th stage (the C and D switches are off), the display of the stopwatch and the measurement operation can be performed. Each time the button 45a (A switch 45) is pressed, the start and stop of stopwatch measurement are repeated. When the stopwatch measurement is started, the CG 1/10 second counter formed in a part of the data memory 204 by the CG interrupt becomes +.
When the 1/10 second chronograph hand 64 is moved every 3 steps in 1/10 second increments and the 1/10 second counter counts 15 seconds, the data memory 20
The CG 15-second counter formed on part of 4 is incremented by 1 and the minute hand 11 is moved every 15 seconds. Further, when the button 46a (B switch 46) is input during "CG start", the split display state is set, and when the button 46a (B switch 46) is input in the split display state, "CG start" is set and 1/10 second The chronograph hand 64, the center hand 20 indicating the second of the measurement time, and the hour hand 12 and the minute hand 11, which are linked with the chronograph hand 64, are fast-forwarded until the measurement time is displayed. Also, press the button 4 when the stopwatch is stopped.
When 6a (B switch 46) is input, the stopwatch measurement is reset and each of the hands other than the dual time 24 hand 66 is fast-forwarded until the 0 position is displayed. When there is no crown or button operation for 10 minutes in the stopwatch measurement state, the 1/10 second chronograph hand performs a fan-shaped hand movement as shown in FIG. Normally, 30 motor pulses are generated per second during stopwatch measurement, but if the hand movement as shown in Fig. 31 is performed, only 3 motor pulses are generated per second, so extend the battery life. You can also see at a glance that the stopwatch is being measured.

32, 33 and 34 show flowcharts of the timer function. The timer setting time is indicated by the minute hand 11. When the switches 49 and 51 of the RA 130e and the RB 130f are turned on by the rotation of the crown, the timer mode is set, and the set time can be changed by setting the second stage of the crown (the C switch 47 is turned on). Button 4
Each time 6a (A switch 46) is input, the set time can be increased by one minute (4 steps). Each time the button 46a (B switch 46) is pressed, the set time can be reduced by one minute. You can set fast-forward by pressing and holding either button. The maximum setting is 60 minutes. Crown 61
When is set to the 0th step, the timer measurement operation becomes possible. Immediately after switching from another mode to the timer mode, the timer setting time is preset by pressing the button 46a (B switch 46), and the minute hand 11 is fast-forwarded to the setting time. The start / stop of the timer is performed with the button 45a (A switch 45). When the timer operation starts, the center hand 64 moves counterclockwise every 30 seconds.
Step by step, the minute hand 11 moves counterclockwise for 15 seconds,
Displays the remaining time of the timer. However, when the remaining time of the timer is 5 minutes or more, the 1/10 second chronograph hand 64 performs the same fan-shaped hand movement as in the case of the stopwatch measurement of 10 minutes or more, and only the minute hand 11 displays the remaining time. The warning sound is sounded from 3 seconds before the remaining time, and when 0 seconds is reached, the time-up sound is sounded and the timer operation is ended.

FIG. 35 shows a flowchart of the alarm setting function. RA 230g and R by crown rotation
When the switches 50 and 51 of B130f are turned on, the alarm set mode is set, and the hour hand 12, minute hand 11 and 24 hour hand 6
5. The dual time 24 hour hand 66 is fast-forwarded until the alarm set time is displayed. To correct the alarm set time, use the second crown (C switch 47
Is turned on), each time the button 45a (A switch 45) is input, 1 minute in the forward rotation direction, and each time the button 46a (B switch 46) is input, 1 minute in the reverse rotation direction.
Can be moved to correct the alarm set time. Similar to the other correction modes, the button 45a or the button 46a
By continuing to press, the minute hand moves forward or reversely in fast forward, so correction can be done in a short time. When the crown is set to the second stage, the hour hand 12, minute hand 11 and 2 are still
While the 4 hour hand 65 and the dual time 24 hour hand 66 are self-propelled to the alarm set time, by pushing the button 45a or 46a, the self-propelled movement can be stopped and the stopped position can be set as the alarm set time.

When only the switch 50 of RA 230g is turned on by the rotation of the crown, the hour hand 12, the minute hand 11 and the 24-hour hand 65 are in the mode indicating the normal time. In this state, the alarm set time and the current time set in the alarm set mode are set. When and match, the alarm sounds.

FIG. 36 shows a flow chart of a method of rotating the crown to determine the fast-forwarding direction of each needle when the mode is switched. When the mode is switched from one mode to another mode, the displayed contents of each mode are different, so the hand moves to the display indication position of the current mode by fast-forwarding. I try to keep it short. This is the same not only when switching between modes, but also when each hand runs in stopwatch mode or timer mode.

FIG. 37 and FIG. 38 show flow charts of the hand moving method of each motor. FIG. 37 shows a motor movement method when the number of movements is 14 or less, and FIGS. 38 (a) and 38 (b)
Is a fast-forwarding method of 15 or more shots. The "motor pulse register" in the figure is the register 2261 in FIG.
That is.

Immediately after the system is reset when the crown is set to the second stage, the rotor hands of the step motor A3 and the step motor B13 are magnetized by performing the demonstration hand movements of one reverse rotation and one forward rotation for each motor. It is possible to unambiguously determine the direction in which it is being performed. That is, the rotor can be adjusted to a position that always matches the hand movement pulse signal after system reset. Further, by attaching the 1/10 second chronograph hand or the center second hand to the 0 position at this position, even if the system is reset after the 0 position adjustment, the 0 position will not be displaced and the normal hand operation will be performed.

In addition to the above functions, the multi-function electronic timepiece of the invention is provided with a time alarm function, a 12-hour alarm function, etc., and the K terminal can be used to switch these specifications and also to have a date display function. And whether the D1, D2, D3 terminals are connected to V _DD or not. Therefore, it is possible to construct a timepiece having several kinds of specifications with this IC.

[0101]

The present invention is as described above, but according to the present invention, many effects can be obtained as described below. 1). The battery pressure measuring spring of the battery positive terminal according to the present invention,
Since the engagement with the ground plate is released as the battery is removed, a special operation for releasing the engagement is not required, and the battery plus terminal can be prevented from floating above the cross section. 2). By making the guide hole of the battery holding plate a burring shape and guiding and engaging with the screw pin of the main plate, positioning and fixing can be done at the same position, and it is possible to guide and fix the member in a very small space. By engaging the position determining hole with the engaging portion of the battery pressing plate, the battery pressing plate can be positioned in the rotation direction. 3). By arranging the battery negative terminal and the buzzer transistor so as to overlap each other in a plane, a plane layout can be configured in a very small space, and a margin can be given to the arrangement of other components. Further, by overlapping the transistor and the guide dowel of the main plate in a cross-sectional view, it is possible to prevent the battery negative terminal from being disengaged from the main plate guide dowel. 4). By providing a conduction spring on the battery positive terminal,
In the state where the booster coil is not electrically connected to the piezoelectric element, a positive potential is not supplied to the booster coil, so that the output signal of the buzzer is not boosted. Therefore, noise due to the output signal of the buzzer does not occur, and malfunctions such as system reset of the CMOS-IC can be prevented. Further, when the piezoelectric element is electrically connected to the booster coil, a positive potential is supplied to the booster coil, so that the boosted buzzer output signal is transmitted to the piezoelectric element and a buzzer sound can be generated. In this state, noise is not generated because the boosted voltage is reduced by connecting the piezoelectric element. 5). By engaging the switch spring of the battery positive terminal with the engaging part of the main plate to give it an initial deflection, it is possible to suppress the variation in the planar spring position of the switch conducting part and the button pressing part, and at the same time The button can be returned by the reaction force. 6). Since the contact part of the battery positive terminal switch spring with the circuit block and the contact part of the button are set to different positions, the contact part of the switch spring with the button will be twisted and the switch spring will require it even if the button is pushed too far. It is possible to prevent the above stress from being applied, and it is possible to prevent the switch spring from being broken or set. 7). As a CMOS-IC system reset method,
Since the operation of rotating the crown while pressing two buttons at the same time is performed with both hands, it is an operation that cannot be normally carried and the system is not reset accidentally. In addition, since the crown is in the normal position, it is possible to prevent winding winding from being broken.

[Brief description of drawings]

FIG. 1 is a front plan view showing an embodiment of a multi-function electronic timepiece of the invention.

FIG. 2 is a cross-sectional view showing a time / hour / minute display train wheel.

FIG. 3 is a cross-sectional view showing a chronograph seconds and date display train wheel.

FIG. 4 is a cross-sectional view showing a 1 / 10-second chronograph display train wheel.

FIG. 5 is a cross-sectional view showing a switching structure.

FIG. 6 is a cross-sectional view showing a battery fixing structure.

FIG. 7 is a sectional view showing a switch spring structure.

FIG. 8 is a sectional view showing a switch structure.

FIG. 9 is a sectional view showing a button switch structure.

FIG. 10 is a cross-sectional view showing a battery negative conduction structure.

FIG. 11 is a back plan view showing one embodiment of the multi-function electronic timepiece of the invention.

FIG. 12 is a cross-sectional view showing a mode train wheel and a back train wheel.

FIG. 13 is a sectional view showing a mode correction structure.

FIG. 14 is a sectional view showing a mode correction structure.

FIG. 15 is a sectional view showing a mode correction structure.

FIG. 16 is a sectional view showing a back train wheel.

FIG. 17 is a circuit connection diagram of the embodiment of FIG.

FIG. 18 is a block diagram of the CMOS-IC 32 shown in FIG. 1.

FIG. 19 is a block diagram showing a specific configuration example of a hand movement reference signal forming circuit 220.

FIG. 20 is a block diagram showing a specific configuration example of a motor hand movement control circuit 212.

FIG. 21 is a timing chart of a motor drive pulse Pa output from a first drive pulse forming circuit 221.

FIG. 22 is a timing chart of a motor drive pulse Pb output from a second drive pulse forming circuit 222.

FIG. 23 is a timing chart of a motor drive pulse Pc output from a third drive pulse forming circuit 223.

FIG. 24 is a timing chart of a motor drive pulse Pd output from a fourth drive pulse forming circuit 224.

FIG. 25: Motor clock control circuits 226, 227, 2
The block diagram which shows the concrete structure of 28,229.

FIG. 26 is an external view of a completed body of the multifunction electronic timepiece according to the present embodiment.

FIG. 27 is a flowchart of a normal time mode.

FIG. 28 is a flowchart of a normal time mode.

FIG. 29 is a flowchart of a stopwatch function.

FIG. 30 is a flowchart of a stopwatch function.

FIG. 31 is a chart showing a fan-shaped hand movement state.

FIG. 32 is a flowchart of a timer function.

FIG. 33 is a flowchart of a timer function.

FIG. 34 is a flowchart of a timer function.

FIG. 35 is a flowchart of an alarm set function.

FIG. 36 is a flowchart of a method of determining a fast-forwarding needle movement direction of each needle when the mode is switched.

FIG. 37 is a flowchart of a hand movement method of each motor.

FIG. 38 is a flowchart of a method of moving a hand of each motor.

[Explanation of symbols]

 1 main plate 2 battery 28 battery positive terminal 29 wheel train support 30 circuit block 104 mode correction axle 105 mode contact spring 106 mode display wheel 109 mode display wheel holding plate

Claims (8)

[Claims] 1. A base frame of a timepiece, a battery as a power source of the timepiece,
In the structure of a timepiece including a holding plate that holds and fixes the constituent members of the timepiece, the holding plate has an engaging portion that engages with the base frame, and the engaging portion is fixed by pressure from the side surface of the battery. A timepiece characterized by being an elastic body which is engaged with and fixed to the engaged portion of the base frame. 2. The timepiece according to claim 1, wherein the timepiece does not incorporate the battery, and the engaging portion of the pressing plate is not engaged and fixed to the engaged portion of the base frame. The watch described in 1. 3. A timepiece base frame, which holds the timepiece components.
In a structure of a timepiece including a holding plate to be fixed, a screw pin press-fitted into the base frame, and a screw engaging with the screw pin, the holding plate has a burring guide hole and the burring guide hole and the base frame. A timepiece characterized in that the screw pin is guided and engaged, and the pressing plate is sandwiched and fixed by the base frame and the screw pin. 4. A timepiece comprising a base frame of the timepiece, a conduction spring member on the negative electrode side of the battery of the timepiece, electric elements that planarly overlap the conduction spring member, and a circuit block on which the electric elements are mounted on the lower surface. In the above structure, the conduction spring member is guided by at least one projection of the base frame at a position overlapping the electric element in plan view, and the conduction element is mounted on the conduction spring member and the circuit block. A timepiece characterized in that the parts overlap each other in a plane and the lower surface of the electric element is located below the upper surface of the protrusion of the base frame in cross section. 5. A holding plate for holding and fixing constituent members of a timepiece,
In a structure of a timepiece including a circuit block for mounting electric elements and a back cover which is an exterior member, a holding spring is provided on the holding plate for contacting a conduction portion of the circuit block only when the back cover is closed. Characteristic clock. 6. A timepiece structure comprising a base frame of a timepiece, a holding plate for holding and fixing the constituent members of the timepiece, a circuit block for mounting electric elements, and an exterior member, the button structure mounted on a case, A switch elastic spring integrally formed with the holding plate has a conduction portion with the circuit block at a tip end thereof, and a button at a position different from the conduction portion in a cross section in a central portion of the switch elastic spring. Of the switch elastic spring of the pressing plate is engaged with a protrusion that is an engaged portion provided on the outer peripheral portion of the base frame at the back surface of the conducting portion of the switch elastic spring, and the switch elastic A watch characterized by having a spring with an initial deflection. 7. A timepiece comprising a button which is an external operating member, a crown which is an external operating member, and a MOS-IC,
A timepiece characterized by performing system reset of the MOS-IC by rotating at least one button and the crown. 8. A timepiece comprising a button which is an external operation member, a crown which is an external operation member, and a MOS-IC,
A timepiece characterized by performing a system reset of the MOS-IC by simultaneously pressing at least two buttons and rotating the crown.