JPH0110631Y2 - - Google Patents

Description

[Detailed explanation of the idea] The present invention relates to a small crystal watch.

The purpose of the present invention is to provide an ultra-small crystal watch. Furthermore, the aim is to stably provide ultra-small crystal watches at low prices and in large quantities. Currently, analog crystal watches are required to be thinner and smaller, and women's crystal watches are particularly required to be smaller.

Women's watches are required to come in a variety of sizes due to their fashion role. In order to meet this demand, a small movement size is a necessary condition. Furthermore, this type of watch has traditionally been a special, expensive watch, and in recent years, providing such watches at low prices has become a major theme.

The purpose of the present invention is to provide an ultra-compact crystal watch to meet such demands.

The structure of the electrically conductive part of the battery watch according to the present invention includes a switching part that positions an external operating member attached to the main plate at a plurality of positions, and a part of the outer periphery that is placed close to the outer periphery of the main plate and eccentrically arranged with respect to the main plate. a circuit block formed by disposing electronic elements on a circuit board formed in an arc shape in a space formed by the eccentricity of the battery; one end facing one electrode of the battery; The battery has the other end facing the connection pattern of the circuit board and a fulcrum part for rotating the battery lead plate so that the other end part is pressed against the connection pattern by the pressing force when the battery is installed. A battery lead plate electrically connected to the circuit block and an insulating member for positioning and holding the battery lead plate are disposed on the base plate, and the insulating member includes a fixing portion fixed to the base plate. A holding part for the battery lead plate is formed, and the insulating member is fixed to the main plate at an outer circumferential side of the main plate and at a position overlapping the circuit block, and a member of the switching part is formed on the distal end surface of the holding part. and holding the battery lead plate while positioning a cross-sectional direction of a part of the battery, and further, the battery lead plate is disposed between the insulating member and the switching part and is overlapped with the switching member. It is characterized by

The present invention will be explained using figures.

FIG. 1 is a plan view of a conventional battery section. 3 is a battery, 4 is a circuit block, and 4a is a negative pattern of the circuit block. The battery negative terminal 5 is in contact with the negative pole of the battery at the spring part 5a, and 5b
Connects to the circuit negative pattern. The battery negative terminal 5b also has spring properties and is fixed with a screw 6. The negative pattern 4a of the circuit block 4 and the conductive part 5a of the battery negative terminal 5 are as follows.
They are in contact within the range indicated by diagonal lines 11.

FIG. 2 is a sectional view of a conventional example.

A screw pin 8 is driven into the base plate 7, and the battery negative terminal 5 is arranged around the pin 8 via an insulating frame 9 made of plastic. 4 is a circuit block, and 4a is a negative pattern. Although not shown, the circuit block 4 includes a crystal oscillator as a time standard and a MOSIC for oscillating the crystal oscillator and frequency-dividing the signal.
A circuit holding plate 10 is made of metal and has the role of holding down the circuit block 4. The side surface 3b of the battery 3 is received by the side surface of the circuit holding plate 10, and the battery is positioned in a plane.

In the conventional example represented by FIGS. 1 and 2, the battery negative terminal 5 and the negative pattern 4a of the circuit block 4 are connected by screws 6 through a circuit holding plate 10. In this conventional example, the effective spring length and overall length of the battery negative terminal were limited to a setting slightly longer than half the diameter of the battery.
For this reason, in order to make the movement more compact and use a smaller battery, the spring length could not be secured sufficiently, making it difficult to secure stable contact points.

In addition, it is difficult to insert any other element other than the conduction into the planar space included in the battery negative terminal, and this also makes the overall movement space inefficient, which is a major hindrance to miniaturization.

The present invention attempts to solve these conventional drawbacks, provide a very space-efficient structure of the battery section, and make it possible to downsize the movement.

An embodiment in which the present invention is effectively utilized is shown in FIGS. 3 to 7. This structure will be explained below. This watch is a small women's watch with a very small movement, so the structure is divided into two stages to make effective use of the narrow space. In FIG. 3, the upper left is the battery positive terminal 125, the crystal unit 124,
The circuit part consists of a circuit board 122, the lower left is the oshidori presser foot 121, the oshidori presser seat 120, and the oshidori 1
16, bolt 118, winding stem 115, wheel 1
The upper right part is a battery part of a battery 128, and the lower right part is a gear train part consisting of a second wheel & pinion 110, a third wheel & pinion 109, a fourth wheel & pinion 108, a rotor, and a train wheel bridge 112. Further, 101 is a main plate, 131 is a dial plate, 129 is an hour hand, and 130 is a minute hand. Fig. 4 is a plan view of the gear train and its surrounding area, Fig. 5 is a plan view of the switching section and its surrounding area, and Fig. 6 is a plan view of the battery section and circuit section provided above the gear train section and switching section. It is a diagram. Next, we will mainly talk about FIG. 4. Reference numeral 101 is the main plate which is the base frame of the watch body, 102 is the rotor magnet 102a and the rotor pinion 102b, which have two poles of N and S in the outer diameter direction.
This is a rotor consisting of a seat 102c. A stator 103 is made of a ferromagnetic material and has an inner hole, an inner notch, and an outer notch. Reference numeral 104 denotes a substrate 106 in which a coil is wound around the pole of a magnetic core 105 made of ferromagnetic material and both ends of the coil are connected to electrode patterns by soldering or the like.
This is a coil block that integrates the The rotor, stator, and coil block constitute a motor. This motor is shown in Figure 6.
The current flowing through the coil due to the output pulse applied by the MOSIC 107 generates a magnetomotive force, and the resulting magnetic flux saturates the smallest part formed by the outer notch and inner hole of the stator, generating N and S poles. This is a step motor that performs magnetic rotation by attracting and repelling a rotor magnet. A fourth wheel & pinion 108, a third wheel & pinion 109, a second wheel & pinion 110, and a sun wheel & pinion 111 of the reduction wheel train are connected to the rotor pinion to transmit rotation to the well-known hour and minute hands. These gear trains are supported by stones and bushes on the base plate and the gear train bridge 112, and the gear train bridge is fixed to pins set on the base plate with screws 132 and 133. The winding stem 115, which is an external operating member described with reference to FIG. 5, is supported by a shaft portion 115a and a tenon portion 115b at the tip thereof in a horizontal hole in the main plate. The shifter 116 is rotatably supported around a shifter shaft 117 erected on the main plate, and is engaged with a concave portion 115c of the winding stem. Also, the dowel 116a is the click part 118a of the bolt 118.
In this case, it is positioned at two locations according to the recessed portion of the click portion. Kannuki 118
is always pressed against the bottom by the force of the spring portion 118b, and its tip guides the wheel 119 which is engaged with the chamfered portion 115d of the winding stem. Then, the wheel is moved to the normal position and the reset position depending on the position of the shifter. Although not shown, when you pull out the winding stem and reset it,
The tooth tips 119a of the helical wheel mesh with the second gear, and the time can be adjusted by turning the winding stem. In the case of this movement, due to its miniaturization, there is no regulating lever, so as is clear from FIG. 3, the movement of the wheel is transmitted to the rotor through the second, third, and fourth wheels. These switching parts are covered with a pusher presser 121 via a pusher presser seat 120. The oshidori holder holds the oshidori with a spring 121a, is guided by two pins set up on the base plate, and is fixed with screws. Next, FIG. 6 will be described. The circuit board 122 has a copper foil pattern 123 formed on polyimide resin, which is an insulating material, and the MOSIC 107, crystal resonator 124, etc. are connected to the pattern. Although not shown, the output lead pattern from the MOSIC is connected to the coil 104 of the step motor and outputs a predetermined pulse signal to drive the motor. The circuit board 122 and battery positive terminal are fixed to pins erected on the base plate by screws 134 and 135. One screw 134
is the speed/speed switch lever 12 above the battery positive terminal.
6 are also fixed together. Speed/speed switch lever 1
26 has an L-shaped tip positioning part, which is connected to the battery positive terminal and the adjustment hole 1 of the circuit board.
When it is inserted and fixed in 27a or 127b, it is configured to be compressed with spring property to the logical adjustment pattern 123c or 123d of the circuit board. Also, when the adjustment switch lever is assembled into the adjustment hole 127c of the battery positive terminal (the state shown in the figure),
Since the circuit board has a notch, it does not come into contact with the circuit pattern. If the adjustment switch lever is inserted into any adjustment hole 127a, 127b, or 127c and fixed with a screw, the logical adjustment pattern 123c,
123d, the same pattern is grounded, and the speed is adjusted. Since there is no pattern when it is installed in 127c, pattern 123 is created using this position as a reference.
If you configure the circuit so that c can be adjusted to +0.264 seconds/day and 123d can be adjusted to -0.264 seconds/day, the total will be 3.
You can speed up or down in one step. The negative electrode of the battery is press-contacted to the battery negative terminal 113a section for electrical conduction, and from the 113b section to the circuit negative conduction pattern 123a section for electrical connection and input to the MOSIC.
The positive electrode of the battery is pressed into contact with the battery positive terminal 125b for electrical conduction, and the crystal resonator fixing part 125a
At the same time, the overhanging circuit plus conductive pattern 123b is sandwiched between the crystal resonator 124 and the crystal resonator to establish conduction and input to the MOSIC. FIG. 3 is a schematic sectional view of the plan view of FIGS. 4, 5, and 6 described above, and the numbers of each component are commonly used.

FIG. 7 shows the part of the battery positive terminal 125 that conducts from the crystal oscillator fixing part 125a to the positive conduction pattern 123b of the circuit board 122, and the battery that conducts electricity from the negative electrode of the battery 124 to the negative conduction pattern 123a of the circuit board 122. 3 is a cross-sectional view mainly showing the negative terminal 113. FIG. 114 is a battery terminal insulator. The battery terminal insulator is fixed to the main plate by dowels 114a and 114b, and
4a ₂ , 114c positions the battery negative terminal. This serves the dual role of fixing the battery negative terminal and insulating it from the ground plane. In addition, the dowel 114a ₂ receives an Oshidori presser 121, and this prevents the Oshidori presser from being pushed down by the fixing force of the crystal oscillator 124 by the battery positive terminal 125, and thereby preventing the cannula 118 from malfunctioning. The purpose is The battery negative terminal overlaps the third wheel 109 in plan view, and passes over the third wheel in cross section. The contact 113a, which has a spring property, presses against the negative electrode of the battery 124 to establish electrical conduction, and this spring hits the battery terminal insulator while the battery is being pushed in and bent, thereby reducing the bending stress at the base of the spring. In addition to relaxing the force, it also serves to increase the spring force of the contact point 113a with the battery electrode. In addition, the part 113b having spring properties is in contact with the circuit pattern,
Negative input is being made to MOSIC. 113
Part b is the contact 113a part and the positioning dowel 114a ₂
It is located almost on a straight line connecting the two, and is located near the outer periphery of the main plate 01.

As described above, according to the present invention, the insulating member in which the fixing part fixed to the main plate and the holding part for positioning and holding the battery lead plate are formed is placed on the outer circumferential side of the main plate and at a position overlapping the circuit block. By fixing it to the main plate and arranging the battery lead plate between the insulating member and the switching part, the effective length of the electrical conduction path between the battery and the circuit block can be reduced despite the small planar size of the movement. Since it can be formed to be longer than the radius of the ground plate, electrical continuity can be ensured with appropriate spring force. Furthermore, since the battery lead plate is provided with a fulcrum portion, the battery can be reliably connected to the connection pattern of the circuit board by the pressing force of the battery.

In addition, by positioning the cross-sectional direction of a part of the switching member by the front end surface of the battery lead holding portion of the insulating member, the holding of the battery lead plate and the cross-sectional direction of the switching member are positioned. Since there is no need for any special member to position the watch, space can be saved and the watch can be made smaller.

Furthermore, the advantage of being able to set the overall length of the battery negative terminal longer with this invention is not only in the stability of the spring properties, but also in the ease of parts processing and handling, which leads to a large reduction in battery life.
The effectiveness of this invention is significant.

Further, in this embodiment, the battery negative terminal is arranged below the switching section, but it goes without saying that the same effect can be obtained even if it is arranged between the circuit block and the switching section in cross section.

Furthermore, in this embodiment, a crystal is placed between the negative terminal of the battery, the contact between the battery and the circuit block, but this is not a crystal, but rather an element that constitutes the circuit block, such as a MOSIC or a trimmer capacitor. , chip capacitors, and other elements such as resistors.

Further, the structure of the contact portion between the battery negative terminal and the circuit block is not limited to this embodiment, and the effectiveness of the present invention is not impaired even if the structure is screwed as in the conventional case.

[Brief explanation of the drawing]

Figure 1: Plan view of the conventional example, Figure 2: Cross-sectional view of the conventional example, Figure 3: Cross-sectional view of an embodiment of the present invention, Figure 4.
Figure: Plan view of the gear train section of an embodiment of the present invention, No. 5
Figure: Plan view of the switching section of an embodiment of the present invention, No. 6
Figure: A plan view of the battery and circuit section of one embodiment of the present invention.
FIG. 7: A sectional view of a conductive part of an embodiment of the present invention. 101...Main plate, 113...Battery negative terminal, 118...Cannula, 124...Crystal, 12
8...Battery.

Claims (1)

[Scope of utility model registration request] A switching unit for positioning an external operating member attached to a main plate at a plurality of positions, a battery having a part of its outer periphery close to the outer periphery of the main plate and eccentrically arranged with respect to the main plate, and a circuit block formed by disposing electronic elements on a circuit board formed in an arc shape in the formed space; one end facing one electrode of the battery; the other end facing the connection pattern of the circuit board; A battery having a fulcrum part that rotates a battery lead plate so that the other end part is pressed against a connection pattern by a pressing force when the battery is installed, thereby establishing electrical continuity between the battery and the circuit block. A lead plate and an insulating member for positioning and holding the battery lead plate are arranged on the base plate, and the insulating member has a fixing part fixed to the base plate and a holding part for the battery lead plate. The insulating member is fixed to the main plate at an outer peripheral side of the main plate and at a position overlapping with the circuit block, and the distal end surface of the holding portion positions the cross-sectional direction of a part of the member of the switching portion. An electrically conductive part of a battery-powered watch, characterized in that it holds a battery lead plate, and the battery lead plate is arranged between the insulating member and the switching part and overlaps with the switching member. structure.