JPS6346871Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to an electrically conductive structure of a circuit block in a battery-powered watch. In particular, when aiming to downsize a watch, the electrically conductive structure can be easily assembled with a small number of parts, and can be realized with high reliability.

By miniaturizing watch movements, it is extremely meaningful to have more flexibility in exterior design and to provide the market with superior models with higher fashionability.This invention allows for further miniaturization of watches. It is possible.

FIG. 1 shows a cross-sectional view of a conventional embodiment. 1 is a battery, 8 is a crystal resonator, and 2 is a battery positive terminal which also serves to hold down the crystal resonator 8. 4 is a circuit board made of insulating tape and a copper foil pattern, 5 is a battery negative terminal, 9 is a ground plate, 3 is a fixing screw for the battery positive terminal, 6 is a battery positive fixing screw pin driven into the ground plate 9, and 7 is a battery Phillips fixing screw pin 6
It is a circuit seat that is positioned on the ground plane and serves to insulate the battery negative terminal 5 and to receive the crystal resonator 8. Conductivity from the positive electrode of the battery 1 to the positive conduction pattern 4a of the circuit board 4 is established by fixing the crystal resonator 8 and connecting the circuit board 8 to the positive conduction pattern 4a.
Connect it to the battery positive terminal fixing screw 3 through the battery positive terminal 2, which also has the role of holding down, and from the shoulder part of the battery positive terminal fixing screw pin 6 to the positive conduction pattern 4a of the circuit board 4 that rests on it. conducts with. In order to ensure that the positive terminal of the battery is conductive to the circuit board in this way, it is necessary to use a screw to sandwich and fix the battery positive terminal and the circuit board in between.
Screw pins are required, and the space required for them is large, which hinders the miniaturization of watches. Also, the negative electrode of the battery
Since conduction is conducted through the battery negative terminal 5 to the negative conduction pattern 4b of the circuit board 4, it is necessary to leave a large gap between the patterns on the circuit board to prevent the positive and negative electrodes from shorting, which reduces the size of the watch. making it difficult. For this reason, in conventional ultra-compact watches, the battery positive terminal,
Continuity is established by connecting the negative terminal of the battery and the circuit board by soldering a lead wire or by linear soldering. However, in this case, disassembly and reassembly are extremely difficult, making repair services at watch shops and the like difficult.

The present invention solves these problems and provides an electrically conductive structure that achieves reliable electrical conduction with a small number of parts and a small area, and realizes an ultra-compact watch that is easier to assemble.

FIGS. 2 and 3 are a plan view and a sectional view showing an embodiment of the present invention. 1 is a battery, 8 is a crystal oscillator,
2 is the positive terminal of the battery, which also serves to hold down the crystal resonator 8. 4 is a circuit board made of insulating tape and a copper foil pattern. 5 is the battery negative terminal, 9
is the main plate, 7 is on the main plate 9 and the battery negative terminal 5
It is a circuit seat that serves to insulate the crystal oscillator 8 and to receive the crystal oscillator 8. Here, the conduction structure between the battery positive terminal 2 and the positive conduction pattern 4a of the circuit board 4 will be explained. As shown in FIG. 2, the positive conduction pattern 4a overhangs the insulating tape of the circuit board 4, and the overhang portion rests on the crystal oscillator 8 and is pressed together by the battery positive terminal 2. There is.

Normally, a crystal oscillator is fixed with sufficient force so that it will not move due to the impact of the drop even if the watch is dropped, and an electrically conductive structure that utilizes this force is highly reliable. In addition, there is no need for screws or pins for conduction, and the area used to hold the crystal oscillator can be used as the area for the conduction structure, so even if the entire watch is made smaller, there is plenty of copper on the circuit board. This realizes foil pattern design and conductive structure.

FIGS. 4 and 5 are a plan view and a sectional view of another embodiment. 1 is a battery, 8 is a crystal resonator, and 2 is a battery positive terminal which also serves to hold down the crystal resonator 8. 4 is a circuit board made of insulating tape and a copper foil pattern. 5 is the battery negative terminal, 9 is the ground plate,
Reference numeral 7 denotes a circuit seat that rests on the ground plate 9 and serves to insulate the battery negative terminal 5 and to receive the crystal oscillator 8. Here, the conduction structure between the battery positive terminal 2 and the positive conduction pattern 4a of the circuit board 4 will be explained. Since the outer periphery of the crystal resonator 8 is made of metal, it is electrically conductive. Therefore, as shown in FIGS. 4 and 5, the crystal oscillator 8 is held down by two parts of the battery positive terminal 2, one part directly holding the crystal oscillator 8 and the other part holding the circuit board 4 in between. The sandwiched portion of the circuit board is held down so that a positive conduction pattern 4a is present on the sandwiched portion of the circuit board. As a result, the positive electrode of the battery is electrically connected from the battery positive terminal 2 through the crystal oscillator 8 to the positive conduction pattern 4a of the circuit board 4. The structure as described above also has high reliability with a small number of parts as in the above-mentioned embodiments, and realizes a copper foil pattern design and a conductive structure of the circuit board that have sufficient margin even when the watch is miniaturized. Further, in this embodiment, the crystal holding part and the holding force for positive conduction use the elasticity caused by the twisting of the battery positive terminal 2.

Further, an embodiment of the entire movement that effectively utilizes the present invention is shown in FIGS. 6 to 8. This structure will be explained below. FIG. 6, FIG. 7, and FIG. 8 are sectional views thereof. This watch is a small watch for women.
The movement is also very small, so its structure is
It is divided into tiers to make effective use of the narrow space.
In FIG. 6, the upper left is the circuit section, the lower left is the switching section, the upper right is the battery section, and the lower right is the train wheel section.
Note that 128 is a battery, 129 is a clock, 130 is a minute hand, and 131 is a dial.

In Figure 7, the battery positive terminal 125 is connected to the crystal oscillator 1.
24, so in order to prevent this, the T-shaped spring part 121b is bent up from the hold down holder 121 and is hooked onto the battery positive terminal 125. As can be seen from FIG. 11, the hook portion of the battery positive terminal 125 is a U-shaped groove. Conventionally, it was common sense to use screws to hold down such parts, but in ultra-compact watches with a two-layer structure like this one, there is no area to attach screws, and moreover, the lower layer is Since the screw pin cannot be set up because it is a separate part, this hook-based presser structure allows a reliable presser mechanism to be constructed in a small area, and is very effective for small watches.

FIG. 8 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 the ninth
It is fixed to the main plate by dowels 114a and 114b shown in the figure, and the battery negative terminal is positioned by 114a ₂ and 114c. 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 a dowel presser 121, and the dowel presser is pushed down by the fixing force of the crystal oscillator 124 by the battery positive terminal 125, and the dowel presser 11
8 from malfunctioning. As can be seen from Figure 9, the battery negative terminal overlaps the third wheel & pinion 109 in plan view.
In cross section, it passes over the third wheel. 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. Further, a portion 113b having spring properties is in contact with the circuit pattern and provides a negative input to the MOSIC. 113b part is contact 1
It is located almost on a straight line connecting the positioning dowel 114a ₂ with the positioning dowel 13a, and is located near the outer periphery of the main plate 101. Fig. 9 is a plan view of the gear train and its surrounding area, Fig. 10 is a plan view of the switching section and its surrounding area, and Fig. 11 is a plan view of the battery section and circuit section provided above the gear train section and switching section. It is a diagram. 101 is a base plate which is the base frame of the watch body, 102 is a rotor magnet 102a having two poles of N and S in the outer diameter direction, and a rotor pinion 10.
2b and a seat 102c. 103
is a stator made of ferromagnetic material with an inner hole, inner notches and outer notches. Reference numeral 104 designates a coil block in which a base frame 106 is integrated, in which a coil is wound around the shaft of a magnetic core 105 made of a ferromagnetic material, and both ends of the coil are connected by sandwiching them between electrode patterns. The rotor, stator, and coil block constitute a motor. This motor is MOSIC10
The current flowing through the coil due to the output pulse applied by 7 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 gear train are connected to the rotor pinion, and transmit rotation to known hour and minute hands. These gear trains are supported by stones and bushes on the main plate and the gear train bridge 112, and screws 132 and 13
The gear train bridge is fixed to the pin set on the main plate in step 3. The winding stem 115, which is an external operating member, is connected to the shaft portion 1.
15a and a tenon portion 115b at the tip thereof, it is supported 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. Further, the dowel 116a engages with the click portion 118a of the bolt 118 and is positioned at two locations in this case according to the recesses of the click portion. The bolt 118 is always crimped to the oshidori by the force of the spring portion 118b, and the tip of the bolt 118 is pressed against the chamfered portion 1 of the winding stem.
It guides the wheel 119 that is engaged with the wheel 15d. Then, the wheel is moved to the normal position and the reset position depending on the position of the shifter. Although not shown, when the winding stem is pulled out and placed in a reset state, the tips of the teeth 119a of the hexagonal 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 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 springy portion 121a, is guided by two pins set up on the base plate, and is fixed with screws. The circuit board 122 has a copper foil pattern 123 formed on polyimide resin, which is an insulating material, and the pattern, MOSIC 107, and crystal resonator 12
4th grade is connected. 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. circuit board 122,
The battery positive terminal is fixed to a pin erected on the base plate by screws 134 and 135. One of the screws c also fixes the speed/speed switch lever 126 above the battery positive terminal. The speed/speed switch lever 126 has an L-shaped tip positioning part, and when this is inserted into the battery positive terminal or the speed/speed hole 127a or 127b of the circuit board and fixed, the logical speed/speed pattern 123c or 123d of the circuit board is set.
It is configured to be crimped with spring properties. Furthermore, when the speed/speed switch lever is assembled into the speed/speed hole 127c of the battery positive terminal (the state shown in the figure), it does not come into contact with the circuit pattern because the circuit board is a notch. If the adjustment switch lever is inserted into any adjustment hole 127a, 127b, or 127c and fixed with a screw, the logical adjustment pattern 1 is achieved.
23c and 123d, the same pattern is grounded, and the speed is adjusted. Since there is no pattern when installed in 127c, pattern 123c is +0.264 seconds/day and 123d is -0.264 based on this position.
If the circuit is configured so that it can be controlled in seconds/day, it can be controlled in three steps in total. 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 against the 125b portion of the battery positive terminal for conduction, and at the same time the crystal resonator 124 is held down by the crystal resonator fixing portion 125a, the overhanging circuit positive conduction pattern 1
23b is sandwiched between the crystal oscillator, conduction is established, and the signal is input to the MOSIC. As is clear from the circuit positive conduction pattern 123b and circuit negative conduction pattern 123a in FIG.
In such a micro-sized watch, the space between the crystal oscillator 124 and the battery 128 is narrow, so only one pattern can pass through. Therefore, it is impossible to establish positive conduction using the screw 135. Therefore, if the present invention is not used, the battery or crystal oscillator must be moved outside and two patterns must be passed through. In other words, unless the size is increased, it will no longer be viable as a watch. Therefore, by fixing the crystal oscillator and providing positive conduction to the battery at the same time as in the present invention, it becomes possible to realize a reliable electrically conductive structure in a limited space without increasing the size of the watch.

As explained above, in small watches where the space provided for the circuit pattern is narrow and it is not possible to establish electrical continuity with screws or pins, the fixed parts of the parts that make up the watch and the electrically conductive parts of the circuit blocks are commonly used. By doing so, planar space can be effectively utilized and the arrangement of each component in the movement can be facilitated. It can also be used to create smaller watches.

Although a crystal resonator has been described as an example of a fixed component in the embodiments and application examples of the present invention, any component constituting a circuit block may be used. It is also possible to use other parts. Although the positive terminal of a battery was used as an example of a holding plate, any plate that has a structure to hold down parts may be used. In particular, when the part to be fixed is a gear train bridge or base plate that is electrically conductive to a battery, the holding plate may be made of plastic, ceramic, or the like that does not have electrical conductivity.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing a conventional example. FIG. 2 is a plan view showing an embodiment of the present invention. Figure 3 is a cross-sectional view.
FIG. 4 is a plan view showing another embodiment of the present invention. Fifth
The figure is a sectional view of FIG. 4. FIG. 6, FIG. 7, and FIG. 8 are sectional views showing an example of application of the present invention. Figures 9 and 10
11 are plan views of FIGS. 6, 7, and 8. 101...Main plate, 109...Third wheel, 112...
... Gear train bridge, 113 ... Battery negative terminal, 114
...Battery terminal insulator, 115... Winding stem, 116...
...Oshidori, 118...Kanuki, 119...Tsuzumi wheel, 120...Oshidori presser seat, 121...
Oshidori presser, 122... Circuit board, 123...
Copper foil pattern, 124...Crystal resonator, 125...
...battery positive terminal, 126...speed/speed switch lever, 128...battery.

Claims (1)

[Scope of utility model registration request] Consisting of a base frame, a battery and circuit block held in the base frame, and a holding plate for the circuit block,
The presser plate includes a connection portion that contacts at least one electrode of the battery, and a fixing portion that elastically fixes and holds the metal components of the battery watch to the base frame, and By interposing an electrically conductive part consisting of a part of the conductive pattern of the circuit block between the fixed part and the metal component, the elasticity of the fixed part allows contact for electrical continuity between the presser plate and the electrically conductive part. A structure for an electrically conductive part of a battery-powered watch, characterized in that the metal component and the presser plate are brought to the same potential by removing pressure.