JP5500040B2 - Clock with solar battery - Google Patents

Description

  The present invention relates to a solar cell timepiece.

Conventionally, a circuit board is arranged on the back side of the main plate, a rotating plate such as a date wheel is arranged on the front side of the main plate, a solar cell is arranged on the front side of the rotating plate, and the solar cell and the circuit board are connected by a conductive member. A solar cell timepiece that uses a solar cell as a power source by conducting is known (see, for example, Patent Document 1).
In the timepiece described in Patent Document 1, a coil spring (solar cell connection spring) is used as a conducting member. And this coil spring is arrange | positioned in the position outside the outer periphery of a rotation board (day plate) by planar view, and both ends of this coil spring are press-contacted to a solar cell and a circuit board, respectively, and a solar cell and a circuit It is electrically connected to the board.

JP 2002-90475 A

However, in the timepiece described in Patent Document 1, when the rotating plate is enlarged, the coil spring and the rotating plate interfere with each other. In order to prevent this interference, it is necessary to make the circuit board larger than the rotating plate so that the coil spring can be arranged at a position outside the outer peripheral edge of the rotating plate in plan view.
Therefore, when designing a plurality of types of timepieces having different sizes of the rotating plate, there is a problem in that the size of the circuit board must be changed in accordance with the size of the rotating plate, which increases the manufacturing cost of the timepiece.

  The objective of this invention is providing the timepiece with a solar cell which can conduct | electrically_connect a circuit board and a solar cell even when a circuit board is smaller than a rotary plate.

  The solar cell timepiece of the present invention includes a ground plate, a circuit board disposed on the back side of the ground plate, a rotating plate disposed on the front side of the ground plate, and a solar cell disposed on the front side of the rotating plate, A timepiece with a solar cell comprising a conductive member for conducting the circuit board and the solar cell, wherein the circuit board includes a terminal portion at a position overlapping the rotating plate in plan view, An electrode portion is provided at a position outside the outer peripheral edge of the rotating plate in plan view, and the conductive member has a first coil spring whose one end is pressed against the terminal portion of the circuit board, and the electrode portion of the solar cell. And a second coil spring whose one end is pressure-contacted with the first coil spring and a connecting portion for connecting the other end of the second coil spring to each other. And

  According to the present invention, one end side of the first coil spring is pressed into contact with the terminal portion of the circuit board, and one end side of the second coil spring is pressed into contact with the electrode portion of the solar cell. The conducting member includes the first coil spring, the second coil spring, and the connecting portion, and is integrally formed. The connecting portion includes the first coil spring and the second coil spring. The other ends are connected to each other. For this reason, a 1st coil spring and a 2nd coil spring can be arrange | positioned in a plane different position by a connection part. Therefore, even if the terminal part of the circuit board is in a position where it overlaps the rotating plate in plan view, and the electrode part of the solar cell is in a position outside the outer peripheral edge of the rotating plate in plan view, the conductive member and the rotating plate are The circuit board and the solar cell can be conducted by the conducting member without interference. In addition, it is not necessary to newly design the circuit board so that the terminal portion of the circuit board is positioned outside the outer peripheral edge of the rotating plate in plan view in order to conduct the circuit board and the solar battery. It is possible to prevent an increase in the manufacturing cost of the timepiece.

In the solar cell timepiece of the present invention, the conducting member has a direction from one end side of the first coil spring to the other end side and a direction from one end side of the second coil spring to the other end side. It is preferable that the first coil spring and the second coil spring have the same length in the axial direction of the coil.
According to the present invention, the direction from the one end side to the other end side of the first coil spring and the direction from the one end side to the other end side of the second coil spring are configured to be opposite to each other. The lengths of the coils in the axial direction are the same. For this reason, one end side of either one of the coil springs is brought into pressure contact with the electrode part of the solar cell, and one end side of the other coil spring is brought into pressure contact with the terminal part of the circuit board, thereby electrically connecting the circuit board and the solar cell. be able to. Thereby, when attaching a conduction | electrical_connection member to a ground plane, it becomes unnecessary to care about the direction of each coil spring, and the assembly property of a timepiece with a solar cell can be improved.

In the solar cell timepiece of the present invention, the ground plate has an attachment portion for attaching the conducting member, the attachment portion has an opening on a side surface, and opens on the back surface of the ground plate, so that the first A fitting portion into which a coil spring is fitted, a guide portion that leads from the surface of the ground plate to an opening on a side surface of the fitting portion, a cutout on the side surface, and an opening on the surface of the ground plate, It is preferable that the guide portion has an inclined surface that is inclined so that the distance to the opening portion decreases from the front side to the back side.
According to the present invention, when the conductive member is attached to the attachment portion, the first coil spring is fitted into the fitting portion from the front side of the main plate via the guide portion and the opening portion. Moreover, a 2nd coil spring is installed in an installation part from the front side of a ground plane. In addition, a connection part is arrange | positioned through the opening part of a fitting part, and the notch of an installation part. Then, when the first coil spring is fitted into the fitting portion, the first coil spring is guided to the fitting portion by the inclined surface of the guide portion. For this reason, the first coil spring can be easily fitted into the fitting portion, and the conducting member can be easily attached to the ground plane.

In the solar cell timepiece of the present invention, the opening is provided on the outer peripheral edge side of the ground plate in the fitting portion, and the ground plate has a protrusion positioned on the outer peripheral edge side of the ground plate from the connecting portion. It is preferable to provide.
According to this invention, the opening part is provided in the outer periphery side of the said ground plate in a fitting part, and a 1st coil spring is fitted by the fitting part toward the center side from the outer periphery side of a ground plate. For this reason, the first coil spring may come off toward the outer peripheral edge of the main plate due to an impact such as dropping. However, since the base plate is provided with a protrusion at a position on the outer peripheral side of the connecting portion, the connecting portion is pressed by the protruding portion even when the first coil spring is likely to come off from the fitting portion. The first coil spring can be prevented from coming off from the fitting portion, and as a result, the conducting member can be prevented from coming off from the ground plane.

In the timepiece with solar cell according to the present invention, the connecting portion is on the outer peripheral edge side of the main plate in a plan view among two common outer tangent lines of the first coil spring and the second coil spring. It is preferable that it has the shape connected with the common outer tangent located.
According to the present invention, since the connecting portion has a shape that is connected by a common outer tangent line that is located on the outer peripheral edge side of the main plate, the connecting portion is a shape that is connected by a common outer tangent line that is located on the center side of the main plate. As compared with the above, it is possible to reduce the portion of the conductive member that overlaps the rotating plate in plan view. From this, even if it is a case where a conduction member remove | deviates from a ground plane by impacts, such as dropping, it can prevent that a conduction member interferes with a rotating plate.

The disassembled perspective view which shows schematic structure of the timepiece with a solar cell in one Embodiment of this invention. The back view which shows the structure of the circuit board in the said embodiment, a solar cell, and a conduction member. Sectional drawing which shows the structure of the conduction | electrical_connection member in the said embodiment. The top view which shows the structure of the main plate in the said embodiment, a date dial, and a conduction member. Sectional drawing which shows the structure of the fitting part and guide part in the said embodiment. The perspective view which shows the state which attached the conduction | electrical_connection member in the said embodiment. The perspective view which shows the state which attached the date dial in the said embodiment.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
[Configuration of the watch with solar battery]
The solar cell timepiece 1 in the present embodiment is a wristwatch that a user wears on his / her arm.
As shown in FIG. 1, the solar cell timepiece 1 includes a main plate 2, a circuit board 3, a date wheel 4 as a rotating plate, a solar cell 5, and a conduction member 6. In addition, although illustration is abbreviate | omitted here, each member 2-6 is accommodated in the exterior case to which the band for a user to mount | wear to an arm was attached.

[Configuration of the main plate]
The base plate 2 is formed in a disc shape by injection molding a non-conductive plastic material. The base plate 2 has an attachment portion 2A for attaching the conducting member 6 in the vicinity of the outer peripheral edge. The conductive member 6 and the attachment portion 2A will be described later. The circuit board 3, the date wheel 4, and the solar cell 5 are incorporated in the base plate 2 and the exterior case, etc., because they are general structures, and thus the description thereof is omitted here.

[Configuration of circuit board]
FIG. 2 is a view of the circuit board 3, the solar cell 5, and the conducting member 6 after being assembled as viewed from the back side of the solar cell timepiece 1.
The circuit board 3 is composed of electricity, electronic components, a printed circuit board, and the like that constitute a control circuit that controls the operation of the solar cell timepiece 1. The circuit board 3 is attached to the back side of the ground plane 2.

The circuit board 3 includes a terminal portion 31 in the vicinity of the edge on the front side (side facing the ground plane 2). As shown in FIG. 1, the circuit board 3 is attached to the ground plane 2 so that the terminal portion 31 overlaps a position slightly inside the outer peripheral edge of the ground plane 2 in a plan view. Moreover, this terminal part 31 is provided in the position which overlaps with the date indicator 4 mentioned later by planar view (refer FIG. 3).
The terminal portion 31 is for supplying power to the circuit board 3 from the outside. Specifically, the terminal portion 31 includes two terminals, a positive terminal connected to the positive electrode and a negative terminal connected to the negative electrode.

[Composition of date wheel]
The date wheel 4 is for displaying the date, and as shown in FIG. 1, is formed in a disk shape having an opening for attachment at the center. Specifically, the date wheel 4 is made of a non-conductive plastic material.
On this date indicator 4, numbers 1 to 31 as date indications are printed. As described above, the date wheel 4 needs to be printed for 31 days. Therefore, if the diameter is small, one character becomes small and the date becomes difficult to visually recognize. Therefore, the diameter of the date dial 4 is configured to be slightly larger than the diameter of the main plate 2.
The date dial 4 is attached to the front side of the main plate 2 by a stepping motor (not shown) so as to rotate around the central portion. Since the movement for driving the date dial 4 and the like is a general configuration of a wristwatch, a detailed description thereof will be omitted.

[Configuration of solar cell]
The solar cell 5 is a driving power source that drives the electrical and electronic circuits of the circuit board 3. As shown in FIG. 1, the solar cell 5 is formed in a disk shape and includes a window portion 51 for visually recognizing numbers (dates) printed on the date wheel 4 and a solar cell 52. . The diameter of the solar cell 5 is configured to be substantially the same as the diameter of the ground plane 2 or slightly larger than the diameter of the ground plane 2. The solar cell 5 is arranged on the front side of the date wheel 4.

  As shown in FIG. 2, the solar cell 5 includes an electrode portion 53 in the vicinity of the edge on the back side (side facing the ground plane 2). This electrode part 53 is comprised by two, a positive electrode and a negative electrode. The electrode portion 53 extends so as to connect a position inside the solar cell 5 that overlaps the terminal portion 31 of the circuit board 3 and a position outside the solar cell 5 that does not overlap the terminal portion 31 of the circuit board 3 in plan view. Has been. Further, the electrode portion 53 is formed to extend from a position overlapping the date indicator 4 in plan view to a position outside the outer peripheral edge of the date indicator 4 (a position not overlapping the date indicator 4).

[Configuration of conductive member]
3 and 4 are diagrams showing the configuration of the conductive member 6 after incorporation. Specifically, FIG. 3 is a cross-sectional view of the vicinity of the conductive member 6 as viewed from the side, and FIG. 4 is a plan view of the main plate 2, the date wheel 4 and the conductive member 6 as viewed from the front side.
The conducting member 6 is a member for conducting the circuit board 3 and the solar cell 5.
The conductive member 6 is made of a conductive material such as metal, and includes a first coil spring 61, a second coil spring 62, and a connecting portion 63, as shown in FIGS. The structure is formed integrally.

  The 1st coil spring 61, the 2nd coil spring 62, and the connection part 63 are comprised with one wire with the same diameter. The first coil spring 61 and the second coil spring 62 are composed of compression coil springs whose spring axes are linear. Moreover, the 1st coil spring 61 and the 2nd coil spring 62 are comprised by the same spring shape. Specifically, the first coil spring 61 and the second coil spring 62 all have the same structure in terms of coil diameter, number of turns, coil height (axial length), and the like.

The connecting portion 63 is for preventing the conducting member 6 from interfering with the date wheel 4. The connecting portion 63 connects the end portion 61B on the other end side of the first coil spring 61 and the end portion 62B on the other end side of the second coil spring 62 to each other.
As shown in FIG. 4, the connecting portion 63 is configured such that the first coil spring 61 and the second coil spring 62 are shared by two coils of the first coil spring 61 and the second coil spring 62. It has the shape connected with the common outer tangent located in the outer-periphery side of the ground plane 2 in planar view among outer tangents. Further, as shown in FIG. 3, the connecting portion 63 is provided so as to be orthogonal to the axis of each of the coil springs 61 and 62.

In addition, even if the conduction member 6 rotates so that the positions of the first coil spring 61 and the second coil spring 62 are switched, the shape of the same position before and after the rotation has the same structure. Specifically, the conducting member 6 is configured such that the spring shaft of the first coil spring 61 and the spring shaft of the second coil spring 62 are parallel to each other. The conducting member 6 includes a direction from the end portion 61A of the first coil spring 61 toward the end portion 61B, and an end portion 62B of the second coil spring 62 on the spring axis of the second coil spring 62. The directions toward are opposite to each other. In other words, the conducting member 6 is configured at a central position in the longitudinal direction of the connecting portion 63 and has a 180-degree rotationally symmetric shape around the center line orthogonal to the axis of the connecting portion 63 and the coil springs 61 and 62. Yes.
The conducting member 6 configured in this way is attached to the attaching portion 2A of the ground plate 2 described above.

[Configuration of mounting part of conductive member]
Hereinafter, the configuration of the mounting portion 2A of the main plate 2 will be described.
2A of attachment parts are formed by providing an unevenness | corrugation in the surface and the back surface of the ground plane 2. FIG. As shown in FIG. 1, the mounting portion 2 </ b> A includes a fitting portion 21, a guide portion 22, a protruding portion 23, and an installation portion 24.

FIG. 5 is a cross-sectional view showing the configuration of the fitting portion 21 and the guide portion 22.
The fitting portion 21 is a portion into which the first coil spring 61 is fitted. The fitting portion 21 is formed in a concave shape on the back surface of the main plate 2. If it explains in full detail, as for the insertion part 21, the back side of the baseplate 2 will open and the front side will be obstruct | occluded. In addition, the height of the inner wall of the fitting portion 21 is configured to be smaller than the height of the coil of the first coil spring 61 (the height in an uncompressed state). An opening portion 21 </ b> A for fitting the first coil spring 61 into the fitting portion 21 and passing the connecting portion 63 is provided on the side surface of the fitting portion 21 located on the outer peripheral edge side of the base plate 2.

The guide 22 is a part that allows the opening 21 </ b> A to communicate with the surface of the main plate 2. The guide portion 22 is provided on the outer peripheral edge side of the base plate 2 in which the opening portion 21 </ b> A in the fitting portion 21 is provided. The guide portion 22 has an inclined surface 22A.
As shown in FIG. 5, the inclined surface 22 </ b> A is for guiding the first coil spring 61 to the opening 21 </ b> A of the fitting portion 21 when the conductive member 6 is attached to the base plate 2. In addition, the conduction member 6 shown by the solid line in FIG. 5 shows the first coil spring 61 during attachment, and the two-dot chain line shows the first coil spring 61 after attachment.
The inclined surface 22A is inclined so that the distance L to the opening 21A decreases from the front side to the back side. The minimum opening dimension L1 between the inclined surface 22A and the ground plane 2 is a dimension that allows the first coil spring 61 in a compressed state to be inserted.

  The protrusion 23 is for preventing the conducting member 6 from being detached from the main plate 2. As shown in FIG. 1, the protruding portion 23 is provided on the surface of the ground plane 2 between the fitting portion 21 and the guide portion 22 and an installation portion 24 described later. As shown in FIG. 4, the protrusion 23 is provided at a position closer to the outer peripheral edge side of the base plate 2 than the connecting portion 63 after the conduction member 6 is attached to the attachment portion 2 </ b> A. Specifically, the projecting portion 23 is formed at substantially the same height as the diameter of the connecting portion 63 along the connecting portion 63 after attachment.

  The installation portion 24 is a portion where the second coil spring 62 is installed. The installation portion 24 is formed in a concave shape on the surface of the ground plane 2. More specifically, the installation part 24 is open on the front side of the main plate 2 and closed on the back side. In addition, the height of the inner wall of the installation portion 24 is configured to be smaller than the height of the coil of the second coil spring 62 (the height in an uncompressed state). Further, as shown in FIG. 1, a cutout 24 </ b> A through which the connecting portion 63 passes when the conductive member 6 is attached is formed on the side surface of the installation portion 24.

The notch 24A is configured such that the width dimension is smaller than the diameter of the second coil spring 62, and the second coil spring 62 installed in the installation part 24 does not come off the installation part 24 through the notch 24A. . Further, the notch 24 </ b> A has the conductive member 6 in a state where the second coil spring 62 is installed in the installation portion 24, and the first coil spring 61 side from the guide portion 22 to the fitting portion 21 around the second coil spring 62. It is comprised in the width dimension which can be rotated in the range.
In addition, when the first coil spring 61 tries to rotate from the fitting portion 21 toward the guide portion 22 around the second coil spring 62, the connecting portion 63 protrudes from the conductive member 6 attached to the attachment portion 2A. It contacts the part 23. Therefore, in this case, the rotation of the conductive member 6 is restricted, and the first coil spring 61 is prevented from being detached from the fitting portion 21.

[Assembly timepiece with solar battery]
6 and 7 are diagrams for explaining the assembly of the solar cell timepiece 1.
As shown in FIG. 6, first, the conduction member 6 is attached to the attachment portion 2 </ b> A of the base plate 2. At this time, the second coil spring 62 is installed in the installation unit 24 before the first coil spring 61. That is, as shown in FIG. 1, the second coil spring 62 is installed on the installation unit 24 from the front side of the base plate 2 with the end 62 </ b> B coming into contact with the installation unit 24.

Next, as shown in FIG. 5, the first coil spring 61 is pushed inward from the outside of the main plate 2 along the inclined surface 22A of the guide portion 22, and the first coil spring 61 is inserted into the fitting portion. Fit into 21. At this time, the connecting portion 63 gets over the protruding portion 23 so that the protruding portion 23 is arranged at a position closer to the outer peripheral end of the base plate 2 than the connecting portion 63 in plan view.
Thereby, the conduction member 6 is attached to the attachment portion 2A so that the end portion 61A of the first coil spring 61 faces the back side of the base plate 2 and the end portion 62A of the second coil spring 62 faces the front side. Note that the first coil spring 61 protrudes from the back surface of the main plate 2 in the end portion 61 </ b> A in an uncompressed state. Similarly, in the state where the second coil spring 62 is not compressed, the end portion 62 </ b> A protrudes from the surface of the main plate 2.

After attaching the conducting member 6 to the main plate 2, as shown in FIG. 7, the date wheel 4 is attached to the front side of the main plate 2, and the solar cell 5 is stacked on the front side of the date indicator 4. Install so as not to interfere with the cross section. Further, the circuit board 3 is attached to the back side of the ground plane 2.
And the timepiece 1 with a solar cell is assembled by accommodating each member 2-6 in the exterior case of the timepiece 1 with a solar cell.

As shown in FIG. 3, the assembled conductive member 6 has a first coil spring 61 overlapping the terminal portion 31 of the circuit board 3 in a plan view, and a second coil spring 62 in the plan view. It is attached to a position that overlaps with the electrode portion 53. In addition, the conductive member 6 includes a first coil spring 61 that overlaps the date indicator 4 in plan view, and a second coil spring 62 that is outside the outer periphery of the date indicator 4 in plan view (in the plan view with the date indicator 4). It is attached so that it will be in a position that does not overlap).
The conducting member 6 is configured such that the end 61A of the first coil spring 61 is in pressure contact with the terminal portion 31 of the circuit board 3, and the end 62A of the second coil spring 62 is in pressure contact with the electrode portion 53 of the solar cell 5. The Thereby, the circuit board 3 and the solar cell 5 are conducted through the conducting member 6.

According to such this invention, there exist the following effects.
The end portion 61A of the first coil spring 61 is pressed into contact with the terminal portion 31 of the circuit board 3, and the end portion 62A of the second coil spring 62 is pressed into contact with the electrode portion 53 of the solar cell 5. The conducting member 6 includes the first coil spring 61 and the second coil spring 62, and a connecting portion 63, and is integrally formed. The connecting portion 63 includes the first coil spring 61 and the connecting portion 63. The other end sides of the second coil springs 62 are connected to each other. For this reason, the 1st coil spring 61 and the 2nd coil spring 62 can be arrange | positioned in a plane different position by the connection part 63. FIG. Therefore, even if the terminal part 31 of the circuit board 3 is in a position overlapping the date indicator 4 in plan view, and the electrode part 53 of the solar cell 5 is in a position outside the outer peripheral edge of the date indicator 4 in plan view, it is conductive. The circuit board 3 and the solar cell 5 can be conducted by the conducting member 6 without the member 6 and the date wheel 4 interfering with each other. Further, in order to make the circuit board 3 and the solar cell 5 conductive, it is necessary to newly design the circuit board 3 so that the terminal portion 31 of the circuit board 3 is located outside the outer peripheral edge of the date wheel 4 in plan view. Therefore, the manufacturing cost of the solar cell timepiece 1 can be prevented from increasing.

  The conducting member 6 is configured so that the direction from the end 61A of the first coil spring 61 toward the end 61B and the direction from the end 62A of the second coil spring 62 toward the end 62B are opposite to each other. The lengths in the axial direction of the coils of the coil springs 61 and 62 are the same. For this reason, one of the end portion 61A of the first coil spring 61 and the end portion 62A of the second coil spring 62 is brought into pressure contact with the electrode portion 53 of the solar cell 5, and the other is brought into contact with the terminal portion 31 of the circuit board 3. The circuit board 3 and the solar cell 5 can be electrically connected by press-contacting. Thereby, when attaching the conduction | electrical_connection member 6 to the ground plane 2, it becomes unnecessary to care about the direction of each coil spring 61 and 62, and the assembly property of the solar cell timepiece 1 can be improved. Further, since the first coil spring 61 and the second coil spring 62 have the same structure in coil diameter, number of turns, coil height, and the like, the stress generated by each of the coil springs 61 and 62 is also the conductive member 6. It can be the same regardless of the mounting direction.

When attaching the conducting member 6 to the attachment portion 2A, the first coil spring 61 is fitted into the fitting portion 21 from the front side of the main plate 2 via the guide portion 22 and the opening portion 21A. The second coil spring 62 is installed on the installation unit 24 from the front side of the main plate 2. The connecting portion 63 is disposed through the opening 21A of the fitting portion 21 and the notch 24A of the installation portion 24. Then, when the first coil spring 61 is fitted into the fitting part 21, the first coil spring 61 is guided to the fitting part 21 by the inclined surface 22 </ b> A of the guide part 22. For this reason, the first coil spring 61 can be easily fitted into the fitting portion 21, and the conducting member 6 can be easily attached to the ground plane 2.
The circuit board 3 is attached to the back side of the base plate 2, and the conductive member 6 is attached to the attachment portion 2 </ b> A from the front side of the base plate 2. For this reason, even after the circuit board 3 is attached to the ground plane 2, the conductive member 6 can be easily incorporated.

  An opening 21A is provided on the outer peripheral edge side of the base plate 2 in the insertion portion 21, and the first coil spring 61 is inserted into the insertion portion 21 from the outer peripheral edge side to the center side of the base plate 2 in plan view. . For this reason, the first coil spring 61 may come off toward the outer peripheral edge of the main plate 2 due to an impact such as dropping. However, since the base plate 2 is provided with the protruding portion 23 at a position on the outer peripheral edge side with respect to the connecting portion 63, even when the first coil spring 61 is likely to be detached from the fitting portion 21, Since the connecting portion 63 is pressed, it is possible to prevent the first coil spring 61 from being detached from the fitting portion 21, and as a result, it is possible to prevent the conducting member 6 from being detached from the ground plane 2.

  Since the connecting portion 63 has a shape that is connected by a common outer tangent line that is located on the outer peripheral edge side of the ground plane 2, it is compared with a case where the connecting portion 63 is connected by a common outer tangent line that is located on the center side of the ground plane 2. And the part which overlaps with the date wheel 4 in planar view of the conduction | electrical_connection member 6 can be decreased. Therefore, even when the conducting member 6 is detached from the main plate 2 due to an impact such as dropping, the conducting member 6 can be prevented from interfering with the date wheel 4.

Since the end portion 61B of the first coil spring 61 abuts on the fitting portion 21 and the end portion 62B of the second coil spring 62 abuts on the installation portion 24, the circuit board 3 and the solar cell 5 are electrically connected. Sufficient stress can be ensured for press-contact through the member 6.
The solar cell 5 includes an electrode portion 53 that is formed to extend from a position overlapping the date wheel 4 in plan view to a position outside the outer peripheral edge of the date wheel 4. For this reason, the solar cell 5 can also be used as a solar cell of a solar cell timepiece that employs another small date wheel and that has a linear spring shaft that connects the circuit board and the solar cell. .

It should be noted that the present invention is not limited to the above-described embodiments, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the present invention.
For example, in the embodiment, the date wheel 4 is exemplified as the rotating plate, but the rotating plate is not limited to this, and may be a day wheel for displaying the day of the week. The rotating plate may be composed of a plurality of components such as a date indicator and a day indicator. In the said embodiment, although the electrode part illustrated what was formed in the back surface of the solar cell 5, the solar cell 5 is not restricted to this structure, A flexible substrate is connected to the electrode part formed in the surface of the solar cell 5. The flexible substrate may be disposed on the back surface of the solar cell 5 to form the back electrode portion of the solar cell 5.
In the above embodiment, a wristwatch type timepiece has been described as an example of the timepiece according to the present invention. However, the present invention is not limited to this, and other types of timepieces such as a wall clock may be used.

  DESCRIPTION OF SYMBOLS 1 ... Clock with solar cell, 2 ... Ground plate, 2A ... Mounting part, 3 ... Circuit board, 4 ... Date wheel (rotary plate), 5 ... Solar cell, 6 ... Conductive member, 21 ... Insertion part, 21A ... Opening part , 22 ... guide part, 22A ... inclined surface, 23 ... projection part, 24 ... installation part, 24A ... notch, 31 ... terminal part, 53 ... electrode part, 61 ... first coil spring, 62 ... second coil spring , 63 ... connecting part.

Claims (5)

A ground plate, a circuit board disposed on the back side of the ground plate, a rotating plate disposed on the front side of the ground plate, a solar cell disposed on the front side of the rotating plate, and the circuit board and the solar cell. A solar cell timepiece comprising a conducting member that conducts,
The circuit board includes a terminal portion at a position overlapping the rotating plate in plan view,
The solar cell includes an electrode portion at a position outside the outer peripheral edge of the rotating plate in plan view,
The conducting member is
A first coil spring whose one end is pressed against the terminal portion of the circuit board;
A second coil spring whose one end is pressed against the electrode portion of the solar cell;
A timepiece with a solar cell, comprising: a connecting portion that connects the other end sides of the first coil spring and the second coil spring to each other. The solar cell timepiece according to claim 1, wherein
The conducting member is configured such that a direction from one end side to the other end side of the first coil spring and a direction from one end side to the other end side of the second coil spring are opposite to each other.
The first coil spring and the second coil spring have the same length in the axial direction of the coil. In the timepiece with solar cell according to claim 1 or 2,
The ground plate has an attachment portion for attaching the conductive member,
The mounting portion is
A fitting portion which has an opening on a side surface and which is opened on the back surface of the base plate to fit the first coil spring;
A guide portion that leads from the surface of the base plate to the opening on the side surface of the fitting portion;
An installation portion that has a notch on a side surface and that opens to the surface of the main plate and installs the second coil spring;
The solar cell timepiece, wherein the guide portion has an inclined surface that is inclined so that a distance to the opening portion decreases from the front side toward the back side. The timepiece with solar battery according to claim 3,
The opening is provided on the outer peripheral edge side of the ground plane in the fitting portion,
The said ground plate is provided with the projection part located in the outer periphery side of the said ground plate rather than the said connection part. Timepiece with a solar cell characterized by the above-mentioned. The solar cell timepiece according to any one of claims 1 to 4,
The connecting portion has a shape that is connected by a common circumscribing line located on the outer peripheral edge side of the ground plane in a plan view among two common circumscribing lines of the two circles by the respective coils of the first coil spring and the second coil spring. A solar cell timepiece characterized by comprising:

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