JP2019056616A - Portable radio-wave watch - Google Patents

Abstract

To provide a portable radio-wave watch that has a high design freedom in layout and includes a movement of a high receiver sensitivity of radio wave.SOLUTION: A portable radio-wave watch includes: an exterior case; a movement 10 disposed in the exterior case; and a slot antenna 16 in which a circular-arc shaped slot 17 along the outer periphery of the movement 10 is formed in a flat conductor. In a region in which the slot 17 is not formed with respect to the center of the movement 10 in the plan view, at least, at least one of an outer-periphery operation member and an opening for display is disposed.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a portable radio timepiece.

  With regard to portable watches such as wrist watches and pocket watches, there are radio wave watches that perform time adjustment by receiving satellite radio waves such as GPS (Global Positioning System) in the wrist watch. Satellite radio waves are generally high frequency in the UHF band, and portable radio timepieces have built-in antennas that are suitable for receiving radio waves in such frequency bands. Here, the portable radio timepiece is a timepiece having a size suitable for the form, and also a so-called radio timepiece having a function of receiving an external radio wave and correcting the time.

  As an antenna used in such a portable radio timepiece, a patch antenna is practically used. However, the patch antenna occupies a large volume in the movement of the timepiece, and there are cases where the size of the timepiece is reduced and the design layout is limited.

  On the other hand, there has been proposed a ring-shaped antenna that is arranged not on the movement of the watch but on the surface or outer periphery thereof. For example, Patent Document 1 describes an electronic timepiece with a built-in antenna including an antenna body having an antenna electrode in which slots extending in the circumferential direction are formed.

  In the electronic timepiece with a built-in antenna described in this document, the exterior case functions as a side surface portion of the antenna body and the back cover functions as a bottom surface portion, and the drive mechanism is accommodated in the antenna body. Further, the C-shaped slot extends over the entire circumference and is arranged in an empty space around the dial.

JP 2012-1108045 A

  An object of the present invention is to provide a portable radio timepiece having a movement with high design freedom and high radio wave reception sensitivity.

  The present invention has various aspects, which are exemplified as follows.

  (1) an exterior case, a movement disposed in the exterior case, and a slot antenna having a flat conductor formed with an arc-shaped slot along the outer periphery of the movement. A portable radio-controlled timepiece in which at least one of the outer peripheral operation member and the display opening is disposed in an area where the slot is not formed with respect to the center of the movement.

  (2) In (1), the solar panel includes a solar panel disposed on the slot antenna, and the solar panel extends to an outer periphery of the movement in a region where the slot is not formed with respect to a center of the movement. A portable radio timepiece having a shape in which the slot is exposed in a region where the slot is formed with respect to the center of the movement.

  (3) The portable radio timepiece according to (2), wherein the solar panel has a shape overlapping with the slot at both ends of the slot.

  (4) In (1), a solar panel having a shielding region disposed on the slot antenna and having a conductive film formed on a substrate and a non-shielding region having no conductive film formed on the substrate is provided. The shielding area extends to the outer periphery of the movement in an area where the slot is not formed with respect to the center of the movement, and the non-shielding area is formed with the slot with respect to the center of the movement. A portable radio timepiece having a shape overlapping with the slot in a region.

  (5) The portable radio timepiece according to (4), wherein the shielding region has a shape overlapping with the slot at both ends of the slot.

  (6) In any one of (1) to (5), the radio-controlled wristwatch includes a winding stem to which a crown as the outer peripheral operation member is attached, and a button-type battery. A portable radio-controlled timepiece disposed at a position that is biased from a center to a region where the slot is not formed with respect to the center of the movement, and that is shifted from the center of the movement toward the winding stem. .

  (7) The portable radio timepiece according to any one of (1) to (6), wherein a metal member constituting the motor and the train wheel is disposed in a region in a circle inscribed in the slot in plan view.

  (8) In any one of (1) to (7), the flat conductor of the slot antenna is at least around the slot and is 0.3% of the wavelength of the radio wave to be received by the slot antenna. A portable radio timepiece that extends to the above range.

  (9) The portable radio timepiece according to any one of (1) to (8), wherein a shield electrode having a flat conductor formed with an opening including the slot is formed on a back surface side of the slot antenna.

  (10) In (9), the opening of the shielding electrode extends at least around the slot and extends in a range of 0.3% or more of the wavelength of the radio wave to be received by the slot antenna. Type radio clock.

  (11) The portable radio timepiece according to any one of (1) to (10), wherein the slot antenna is unbalanced.

  (12) In (11), the feeder line connected to the slot antenna is formed of a conductive thin film formed on an FPC board, and is formed on at least one first electric wire and on both sides in the transverse direction of the first electric wire. A portable radio timepiece having at least two second electric wires.

  (13) In (9) or (10), the slot antenna is unbalanced and the feed line connected to the slot antenna is formed by a conductive thin film formed on an FPC board. One electric wire and at least two second electric wires formed on both sides in the transverse direction of the first electric wire, the flat conductor of the slot antenna is formed on the surface side of the FPC, and the flat shape of the shielding electrode The conductor and the feeder are formed on the back side of the FPC, the first electric wire is connected to the flat conductor of the slot antenna on the outer peripheral side of the slot, and the second electric wire is connected to the shielding electrode, The portable radio timepiece, wherein the shield electrode is connected to the flat conductor of the slot antenna on the inner peripheral side of the slot.

  (14) The portable radio timepiece according to (10), (11), or (13), wherein the slot antenna and the shielding electrode are insulated from the outer case at an outer periphery thereof.

  According to the aspect (1) of the present invention, a portable radio timepiece having a movement with high design freedom and high radio wave reception sensitivity is provided.

  According to the aspects (2) to (5) of the present invention, the influence of the solar panel on the reception sensitivity of the slot antenna can be suppressed.

  According to the aspect (6) of the present invention, it is possible to secure a space for providing the winding stem attachment / detachment mechanism on the side of the winding stem while suppressing the influence of the button type battery on the receiving sensitivity of the slot antenna.

  According to the side of (7) of this invention, the influence on the receiving sensitivity of the slot antenna by the metal member which comprises a motor and a train wheel can be suppressed.

  According to the aspect (8) of the present invention, the current distribution around the slot of the slot antenna is stabilized, and desired reception performance is exhibited.

  According to the aspect (9) or (10) of the present invention, it is possible to suppress the influence of the shield electrode on the reception sensitivity of the slot antenna while shielding the influence of the member inside the movement on the reception sensitivity of the slot antenna.

  According to the aspects (11) to (13) of the present invention, the influence of noise on the feed line is eliminated, the wiring structure around the feed point is simplified, and the influence on the reception sensitivity of the slot antenna is reduced.

  According to the aspect (14) of the present invention, therefore, the influence from the outside of the exterior case does not directly affect the slot antenna, and the reception sensitivity is stabilized.

1 is a plan view of a portable radio timepiece according to an embodiment of the present invention. It is a top view which shows the movement accommodated in the inside of an exterior case. It is a top view of a slot antenna. It is a top view of a solar panel. It is a top view which shows the modification of a solar panel. It is a top view which shows the further modification of a solar panel. It is a figure which shows the suitable arrangement | positioning of a button type battery in planar view of a movement. It is a figure which shows the example of arrangement | positioning of a motor and a wheel train in a movement. It is a back surface top view of a slot antenna. It is sectional drawing by the XX line of FIG. It is an enlarged view of the base of the tongue part of FIG.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a plan view of a portable radio timepiece 1 according to an embodiment of the present invention. The portable radio-controlled timepiece 1 is shown here as a wristwatch, but may be other types, for example, a pocket watch. As shown in the figure, the portable radio timepiece 1 is an analog electronic timepiece, but may be provided with a digital display using a liquid crystal display or the like in part. In FIG. 1, a band for mounting the portable radio timepiece 1 on the arm is not shown.

  The portable radio timepiece 1 has a so-called movement, which is a mechanism member of a timepiece, housed inside an outer case 2. In the example of FIG. 1, a pointer 4 composed of an hour hand, a minute hand, and a second hand is provided around the center of the dial 3 of the portable radio timepiece 1 as an axis. Further, a dial ring 5 is provided on the outer peripheral edge of the dial 3 as a decorative member, but this is not necessarily an essential member. A mark indicating the time, that is, a so-called time character 6 is attached every 30 degrees indicating one hour along the outer periphery of the dial 3 (in the drawing, only the time character 6 at the 12 o'clock position is indicated for simplicity). )

  Further, a crown 7 and a push button 8 are provided on the outer peripheral side surface at 3 o'clock side of the exterior case 2 so as to sandwich the crown 7, respectively, so as to accept a user operation on the portable radio timepiece 1. . An input mechanism for accepting a user operation from the outer peripheral side surface of the exterior case 2 such as the crown 7 and the push button 8 is referred to as an outer peripheral operation member in this specification. The outer peripheral operation member includes a winding stem connected to the crown 7 and a switch mechanism to which the push button 8 is attached.

  Further, in this example, a date window 9 is provided at a position corresponding to the 3 o'clock time character of the dial plate 3 to display the date. The date window 9 is an opening that allows a user to visually recognize a predetermined position of the date plate, and a predetermined position of the date plate, which is printed as “20” in the illustrated example, is visually recognized through the date window 9. The current date is now known. An opening that allows a display member such as a date plate disposed on the back side thereof to be visible like the date window 9 is referred to as a display opening in this specification. What is displayed by the display opening is not limited to the day display shown in this example, but includes display of day of the week and time zone, and various information by a liquid crystal display.

  FIG. 2 is a plan view showing a movement 10 accommodated in the exterior case 2 by removing the exterior case 2, dial 3, pointer 4, crown 7 and push button 8 from the portable radio timepiece 1 of FIG. 1. is there.

  The movement 10 has a substantially disk shape, and a pointer shaft 11 is present at substantially the center thereof. Further, a winding stem 13 for attaching the crown 7 and a part of a switch mechanism 14 for attaching the push button 8 protrude from the outer peripheral side surface of a frame 12 (also referred to as a main plate) constituting the movement 10. A solar panel 15 and a slot antenna 16 are laminated on the upper surface of the frame 12 from the front side. In this example, no electrode is formed on the entire surface of the solar panel 15, and a part of the slot antenna 16 on the back surface and the slot 17 formed in the slot antenna 16 can be seen.

  Both the solar panel 15 and the slot antenna 16 are provided with a shaft window 18 for allowing the date window 9 and the pointer shaft 11 to pass therethrough.

  FIG. 3 is a plan view of the slot antenna 16. The slot antenna 16 has a shape in which an arc-shaped slot 17 is formed in a flat conductor 19. In this example, the slot antenna 16 has a slot 17 formed by a metal thin film pattern formed on an insulating substrate, and the flat conductor 19 is a metal thin film. Therefore, although the insulating substrate is exposed from the slot 17, the slot 17 may be formed by cutting out the insulating substrate, like the sun window 9 and the shaft opening 18.

  The length of the slot 17 may be set according to the wavelength of the radio wave to be received by the slot antenna 16, but in order to obtain circular polarization, the angle indicated by θ in FIG. 3 with respect to the center of the movement 10 The range is 180 degrees or more, more preferably 270 degrees or more. In the illustrated example, the slot 17 is provided within a range of 300 degrees with respect to the center of the movement 10.

  In addition, the outer shape of the slot antenna 16 (that is, the outer shape of the insulating substrate) is generally circular, but is slightly uneven. This unevenness is complementary to the shape of the inner periphery of the recess for receiving the solar panel 15 and the slot antenna 16 provided on the upper surface of the frame 12 shown in FIG. 2 (see FIG. 2). When 16 is placed on the frame 12, the slot antenna 16 is positioned without rotating.

  Further, in this example, the insulating substrate of the slot antenna 16 is an FPC (flexible printed circuit board), and a tongue portion 20 that protrudes from the vicinity of one end of the slot 17 toward the outer peripheral side is provided. . The tongue portion 20 has a wiring pattern formed on the back surface thereof, and functions as a feed line that connects the slot antenna 16 and a circuit board provided in the movement 10. The tongue portion 20 is flexibly bent downward when the slot antenna 16 is disposed on the frame 12.

  Further, a feeding point 21 is provided in the vicinity of either end of the slot 17. The feeding point 21 is a via hole that connects the wiring pattern provided on the back surface of the tongue 20 and the flat conductor 19. Details of the wiring pattern provided on the back surface of the tongue portion 20 and the connection portion with the flat conductor 19 will be described later.

  In the present embodiment, the slot 17 has an arc shape, and an area A in which the slot 17 is not formed is secured with respect to the center of the movement 10. In this area A, a structure that is considered to cause inconvenience due to overlapping with the slot 17 in plan view is arranged.

  A first candidate for such a structure is a conductive (usually metal) member having a size larger than a certain level that may affect the reception performance of the slot antenna 16, and the slot 17. It is a member that needs to be arranged on the outer periphery of the movement 10 to the same extent as. A typical example of such a member is the aforementioned outer peripheral operation member. As apparent from FIG. 2, in this example, the winding stem 13 and the switch mechanism 14 are arranged in a region A where the slot 17 is not formed with respect to the center of the movement 10. Of course, in the case of the portable radio-controlled timepiece 1 that does not have both the winding stem 13 and the switch mechanism 14, either one of them may be disposed in the region A. If all cannot be arranged in the area A, a part of the area A may be arranged in the area A. In that case, it is desirable to arrange a member having a metal member as small as possible and having a small influence on the reception sensitivity of the slot antenna 16 outside the region A as much as possible. Even when the outer peripheral operation member is arranged on the slot 17, it is desirable to arrange it at positions near both ends of the slot 17.

  Further, the second candidate for the structure arranged in the region A is a display opening, and in this example, the date window 9 corresponds. Normally, the display opening is arranged near the outer periphery of the watch face due to the mechanism or design layout. However, the display opening is used to make the display mechanism incorporated in the movement 10 visible to the user. The slot antenna 16 at the position corresponding to the above must be cut out or made a transparent member, and the slot 17 cannot be formed so as to straddle the display opening. Therefore, the display opening is arranged in the region A. With such a configuration, it is not necessary to dispose the display opening on the inner peripheral side of the slot 17, and the watch face can be widened, and the degree of freedom in design layout is increased.

  It should be noted that display openings are not necessarily present for all portable radio timepieces 1. Therefore, in the portable radio timepiece 1 exemplified in the present embodiment, all of the outer peripheral operation member and the display opening are arranged in the region A. In the region A, at least the outer peripheral operation member and the display opening are provided. Any one of the above may be arranged.

  In addition, a hole 35 is provided in the peripheral portion of the region A of the slot antenna 16. This is because a conductor connecting the solar panel 15 and the circuit board of the movement 10, which will be described later, passes therethrough.

  FIG. 4 is a plan view of the solar panel 15. In the solar panel 15, a solar cell is formed by laminating a conductive film and a semiconductor film on an insulating substrate. In the solar panel 15 of this example, the solar cell is not formed on the entire surface of the insulating substrate, the conductive film is formed, the shielding region 22 functioning as a solar cell, and the non-shielding region where the conductive film is not formed. 23 exists.

  In the shielding area 22, radio waves from the outside are shielded by the action of the conductive film. Therefore, if the shielding area 22 covers the slot 17 of the slot antenna 16, reception sensitivity is lowered. Therefore, the non-shielding region 23 has a shape overlapping with the slot 17 in the region B where the slot 17 is formed with respect to the center of the movement 10. Specifically, the non-shielding region 23 is also provided in a C shape at the outer peripheral edge of the solar panel 15 so as to cover the C-shaped slot 17. In FIG. 4, the position of the slot 17 is also indicated by a broken line.

  On the other hand, in the region A where the slot is not formed with respect to the center of the movement 10, the shielding region 22 extends to the outer periphery of the movement 10. This is to secure as large an effective area as possible for the solar cell.

  Further, a solar panel connection electrode 36 is provided on the back surface of the peripheral edge of the region A of the solar panel 15. When the solar panel 15 is attached to the movement 10, a conductor is disposed at a position corresponding to the solar panel connection electrode 36 of the frame 12, and the solar panel 15 and the circuit board of the movement 10 are electrically connected via the conductor. Connected. The conductor is preferably one that ensures electrical connection with the solar panel connection electrode 36, and may have a structure that elastically contacts the solar panel connection electrode 36. For example, a metal spring can be used as such a conductor. The solar panel connection electrode 36 and the hole 35 shown in FIG. 3 are provided at positions corresponding to each other, and a conductor disposed immediately below the solar panel connection electrode 36 passes through the hole 35.

  When an elastic body is used as the conductor, the solar panel connection electrode 36 needs to be provided at the periphery of the solar panel 15 in order to prevent the solar panel 15 from being lifted by the frame 12 of the movement 10. On the other hand, since no conductive film is formed in the non-shielding region 23 of the solar panel 15, the solar panel connection electrode 36 must be provided in the shielding region 22, and therefore is disposed in the region A. At the same time, by arranging the solar panel connection electrode 36 in the area A, the influence of the conductor connecting the movement 10 and the solar panel 15 on the slot antenna 16 is reduced.

  FIG. 5 is a plan view showing a modification of the solar panel 15. In this modified example, the non-shielding region 23 has a shape overlapping with the slot 17 in the region B where the slot 17 is formed with respect to the center of the movement 10, but the shielding region 22 is formed at both ends of the slot 17. The shape overlaps with the slot 17 partially. In the slot antenna 16, the vicinity of the center in the longitudinal direction (circumferential direction) of the slot 17 has a large contribution to receiving radio waves, whereas the vicinity of both ends thereof has a small contribution to receiving radio waves. The purpose is to expand the area of the solar cell and ensure the amount of power generation within the range where there is no hindrance.

  Also in this modified example, the solar panel connection electrode 36 is provided on the back surface of the peripheral edge portion of the region A of the solar panel 15. The reason for this arrangement is as described in FIG.

  FIG. 6 is a plan view showing a further modification of the solar panel 15. In this modification, a solar cell is formed on almost the entire surface of the solar panel 15, while the outer shape of the solar panel 15 is the outer shape of the movement 10 or the concave portion for receiving the solar panel 15 and the slot antenna 16 of the frame 12. It does not match the shape of the circumference. That is, in the region B where the slot 17 is formed with respect to the center of the movement 10, the shape is notched so that the slot 17 is exposed. In this figure as well, the position of the slot 17 is indicated by a broken line. As a result, a decrease in reception sensitivity of the slot antenna 17 by the solar panel 15 is suppressed.

  On the other hand, the solar panel 15 extends to the outer periphery of the movement 10 in the region A where the slot 17 is not formed with respect to the center of the movement 10. In this example, the solar panel 15 is used to receive the solar panel 15 and the slot antenna 16 of the frame 12. The outer shape is complementary to the shape of the inner periphery of the recess. In addition, the solar panel 15 is partially overlapped with the slot 17 at both ends of the slot 17.

  As in the previous modification, this is to ensure an effective area as large as a solar cell as much as possible, and by taking as long as possible the length in the circumferential direction in which the solar panel 15 extends to the outer periphery of the movement 10, This is intended to prevent displacement of the position when the solar panel 15 is arranged on the frame 12. At this time, the solar panel 15 is provided with unevenness 24 complementary to the shape of the inner periphery of the recess of the frame 12 in the vicinity of both ends of the region where the solar panel 15 extends to the outer periphery of the movement 10. Directional misalignment is prevented.

  In this modification, the solar panel 15 partially overlaps with the slot 17 at both ends of the slot 17, but the solar panel 15 may not overlap with the slot 17.

  Also in the case of this modification, the solar panel connection electrode 36 is provided on the back surface of the peripheral portion of the region A of the solar panel 15. The reason for this arrangement is also as described in FIG.

  The preferred positional relationship among the slot 17 of the slot antenna 16, the solar panel 15, the outer peripheral operation member, and the display window has been discussed above. In the following, a preferred arrangement of main members to be considered when using the slot antenna 16 will be described.

  Basically, a member to be considered when using the slot antenna 16 is a member made of a large conductor (usually metal) that can affect the reception sensitivity, and the portable radio timepiece 1 includes. There is a button type battery 25.

  FIG. 7 is a view showing a preferred arrangement of the button-type battery 25 in the plan view of the movement 10. In order to avoid complexity, the illustration of the solar panel 15 and the slot antenna 16 is omitted except for the slot 17, and the positions of the button type battery 25 and the winding stem attachment / detachment mechanism 26 are indicated by broken lines.

  The basic idea of the arrangement of the button-type battery 25 is that the button battery 25 is arranged at a position far from the center in the longitudinal direction of the slot 17 that greatly contributes to receiving radio waves. Therefore, from the center of the movement 10, A button-type battery 25 is arranged at a position biased to a region A where the slot 17 is not formed with respect to the center of the movement 10. More specifically, the button-type battery 25 is arranged so that the center O of the button-type battery 25 is positioned in the direction in which the region A exists when viewed from the center position of the movement 10, in this example, the position of the pointer shaft 11. . Furthermore, it is more preferable to arrange the button type battery 25 so that the center of the button type battery 25 is located in the region A.

  With this arrangement, as shown in FIG. 7, the button-type battery 25 is positioned on the opposite side of the center of the movement 10 from the longitudinal center of the slot 17. The area where the slot 17 overlaps is small, and even if the button-type battery 25 and the slot 17 overlap, the area will be in the vicinity of either end of the slot 17. The effect of reception sensitivity on 16 remains small.

  Further, the button-type battery 25 is disposed at a position shifted from the direction of the winding stem 13 from the center of the movement 10. Specifically, in this example, the center O of the button-type battery 25 is disposed at a position shifted by an angle φ from the 3 o'clock direction where the winding stem 13 is provided toward the 6 o'clock direction.

  This is to prevent interference between the button-type battery 25 and the winding stem attachment / detachment mechanism 26 provided on the side of the winding stem 13. Although only the outer shape of the winding stem attaching / detaching mechanism 26 is shown in FIG. 7, for example, a member that engages with a groove provided on the outer periphery of the winding stem 13 so that the winding stem 13 does not fall out of the movement. The engagement with the winding stem 13 can be arbitrarily released by an operation from the outer periphery of the movement 10, for example, pressing with a thin member such as a pin or turning a screw.

  The winding stem attachment / detachment mechanism 26 must be provided on the side of the winding stem 13 due to its nature. However, when the button-type battery 25 is provided in the direction facing the winding stem 13 with respect to the center of the movement 10, the winding core is attached / detached. There is a possibility that there is not enough room to arrange the mechanism 26. Therefore, the button-type battery 25 is disposed at a position displaced from the center of the movement 10 in the direction toward the winding stem 13, and a space sufficient to arrange the winding stem attaching / detaching mechanism 26 in the vicinity of the winding stem 13 is secured. As shown in FIG. 7, the magic prohibition attaching / detaching mechanism 26 is desirably provided on the opposite side of the center O of the button-type battery 25 with respect to the shaft of the winding stem 13 in a plan view.

  Further, as members to be considered when using the slot antenna 16, there are metal members constituting the motor 27 and the train wheel 28. Since these members are the driving mechanism of the pointer shaft 11 or the date plate, it is difficult to arrange all of them in the region A where the slot 17 is not formed with respect to the center of the movement 10.

  Therefore, in this embodiment, the metal members constituting the motor 27 and the train wheel 28 are arranged in a region C in a circle inscribed in the slot 17 in a plan view. FIG. 8 is a diagram illustrating an example of the arrangement of the motor 27 and the train wheel 28 in the movement 10. Also in this figure, in order to avoid complication, illustration of the solar panel 15 and the slot antenna 16 is omitted except for the slot 17, and the positions of the motor 27 and the train wheel 28 are indicated by solid lines. Further, a region C in a circle inscribed in the slot 17 is indicated by hatching.

  In the illustrated example, a three-motor type movement 10 is shown in which the pointer 4 is driven by two motors 27 and the date plate is driven by one motor 27. The motor has a coil and a stator surrounding the magnetized rotor, both of which are metal members, but these members are arranged in the region C and do not overlap with the slot 17, so that the slot antenna The effect on the 16 reception performance is small.

Two wheel trains 28 are shown, one for driving the pointer shaft 11 and the other for driving the date plate. In this example, all the vehicles constituting the wheel train 28 are arranged in the region C. And does not overlap with the slot 17. Therefore, even if any or all of the cars constituting the train wheel 28 are made of metal, the influence on the reception performance of the slot antenna 16 is small. When a part or all of the cars constituting the train wheel 28 are non-metallic insulators, such cars have little influence on the reception performance of the slot antenna 16 and are therefore arranged outside the region C. The slot 17 may be superimposed.
Subsequently, a preferred design of the slot antenna 16 will be described.

  FIG. 9 is a plan view of the back surface of the slot antenna 16. On the back side of the slot antenna 16, a shielding electrode 29 is formed by a flat conductor. The shield electrode 29 is formed with an opening 30 having a shape including the slot 17. In the figure, in order to show the relationship between the shielding electrode 29 and the slot 17, the position and shape of the slot 17 are indicated by broken lines.

  The shielding electrode 29 is preferably a metal thin film formed on the back surface of the insulating substrate of the slot antenna 16 and is a so-called solid electrode covering a wide area. The shield electrode 29 is provided for the purpose of shielding noise and influence on the slot antenna 16 from a metal member arranged on the back side of the slot antenna 16, the motor 27, a high-frequency circuit and other electric / electronic circuits. is there. At this time, when the slot 17 and the shielding electrode 29 are overlapped in a plan view, the reception sensitivity of the slot antenna 16 is lowered, and thus the opening 30 is provided.

  10 is a cross-sectional view taken along line XX of FIG. The slot antenna 16 is provided with a flat conductor 19 and a slot 17 on the front surface of an insulating substrate 31. On the other hand, a shield electrode 29 and an opening 30 are provided on the back surface of the insulating substrate 31. At this time, the width of the opening 30 is larger than the width of the slot 17, and the slot 17 is included in the opening 30 in plan view (in the vertical direction in FIG. 10).

  Further, at this time, it is desirable that the flat conductor 19 extends from the periphery of the slot 17 within a predetermined distance d1, and there is no other notch. As a result, the current distribution around the slot 17 when power is supplied to the slot antenna 16 is stabilized, and desired reception performance can be exhibited. In addition, it is desirable that the opening 30 extends from the periphery of the slot 17 in a range of a predetermined distance d2, and the shielding electrode 29 is not provided. Thereby, the influence on the reception sensitivity of the slot antenna 16 by the shielding electrode 29 can be reduced.

  It has been experimentally found that good reception characteristics can be obtained if the values of d1 and d2 are both 0.3% or more of the wavelength of the radio wave to be received by the slot antenna 16.

  FIG. 11 is an enlarged view of the base of the tongue portion 20 of FIG. A power supply line 34 including a first electric wire 32 and a second electric wire 33 is formed on the tongue portion 20 along the longitudinal direction. The feeder line 34 is made of a conductive thin film pattern on an insulating substrate which is an FPC substrate, and is a so-called microstrip line. A gap is provided between the first electric wire 32 and the second electric wire 33 so as not to short-circuit each other.

  And the 1st electric wire 32 is formed on the centerline of the tongue part 20 in this example, and the 2nd electric wire 33 is provided in the both sides of the 1st electric wire 32, respectively. In addition, although the 1st electric wire 32 is one in this example, it is good also as a several wire arrange | positioned in parallel. The number of the second electric wires 33 is not particularly limited, but is at least two because they are formed on both sides of the first electric wires 32, that is, both sides in the transverse direction of the first electric wires 32. The first electric wires 32 and the second electric wires 33 are preferably symmetrical with respect to all 20 longitudinal centerlines.

  The feeder line 34 is a pseudo coaxial line formed by the first electric wire 32 and the second electric wire 33 on a plane, and is advantageous in that it is not easily affected by noise from the outside.

  The first electric wire 32 is connected to the plate-like electrode 19 of the slot antenna 16 through a via hole at a feeding point 21 a on the outer peripheral side of the slot 17. Further, the two second electric wires 33 are both connected to the shielding electrode 29 and are electrically connected to each other. The shield electrode 29 is connected to the plate-like electrode 19 of the slot antenna 16 by a via hole at a feeding point 21 b on the inner peripheral side of the slot 17. With this structure, in the width direction across the slot 17, the outer peripheral side is connected to the first electric wire 32 and the inner peripheral side is connected to the shielding electrode 29.

  When radio waves are received by the slot antenna 16, power is supplied to the feeding point 21 through the feeding line 34. At this time, since the slot antenna is generally a balanced antenna, it is normal to perform balanced feeding to the feeding point 21. However, in this example, the feeding point 21b on the inner peripheral side is connected to the shielding electrode 29, and the shielding electrode 29 is kept at the ground potential in order to eliminate the influence of noise and other members. Will be.

  When considering only the power supply to the slot antenna 16, how to supply power to the first electric wire 32 and the second electric wire 33 is arbitrary, and it is possible to use balanced power supply or to set any one of them to the ground potential. It is also possible to perform balanced feeding. However, for the following reason, active feeding is performed to the first electric wire 32, the outer feeding point 21a is used as a feeding electrode, the second electric wire 33 is grounded, and the inner feeding point 21b is used as a ground electrode. desirable.

  First, in order to obtain an appropriate shielding effect, the shielding electrode 29 is desirably set to a ground potential, and the shielding electrode 29 naturally extends to the inner peripheral side of the slot 17 due to its structure.

  On the other hand, when the feeding point 21 serving as the feeding electrode is to be arranged on the inner peripheral side of the slot 17, that is, when the feeding point 21b is to be used as the feeding electrode, the first electric wire 32 is moved across the slot 17 to the feeding point 21b. Must be connected. Therefore, by connecting the feeding point 21a to the first electric wire 32 and using it as a feeding electrode, the wiring around the feeding point 21 is simplified, and the reception sensitivity of the slot antenna 16 is hardly affected.

  Further, since the feed line 34 is formed on the back side of the insulating substrate of the slot antenna 16, the tongue 20 is bent as shown in FIG. 2 to connect the feed line 34 to the substrate of the movement 10. In addition, since the power supply line 34 passes through the side surface of the movement 10 and is not exposed to the outside of the movement 10, problems such as short-circuiting with the outer case 2 are prevented.

  Further, in this example, as shown in FIG. 2, the slot antenna 16 is housed in a recess provided on the upper surface of the frame 12 of the movement 10, and is insulated from the outer periphery without contacting the outer case 2. ing. By doing so, it is possible to prevent the influence of the user or some object touching the outer case, or the user touching or operating the outer peripheral operation member on the slot antenna 16 and the reception sensitivity. In general, the movement 10 is electrically connected to the body or back cover of the exterior case 2 on the side surface or the back surface thereof by an elastic electrode to obtain a ground potential. In the slot antenna 16 of this example, the tongue portion 20 is used. The ground potential is obtained by being connected to the ground electrode on the circuit board of the movement 10 by the second electric wire 33 formed on the circuit board, and the circuit board of the movement 10 is further connected to the body or the back cover of the outer case 2. It has a structure. Therefore, it is difficult for the external case 2 to be directly affected by the slot antenna 16 and the receiving sensitivity is stabilized.

  In addition, the above description is about one Embodiment of this invention, The concrete shape, structure, number, etc. may be changed suitably by those skilled in the art as needed. Further, it is not always necessary to provide all the structures described here, and the adoption or not may be determined as appropriate within a practically necessary range.

  For example, in the described embodiment, the shielding electrode 29 of the slot antenna 16 is provided only on the back surface side of the flat conductor 19, but it may be further provided on the upper surface side. Further, the arrangement of the crown 7, the push button 8, and the date window 9 is arbitrary according to the design requirement, and a sub-needle other than the pointer 4 and a flat panel display such as a liquid crystal display may be provided. Further, the shape of the outer case 2 is not necessarily circular, and may be a square or other shapes. In the present embodiment, the material of the exterior case 2 has been described on the assumption that the metal is a conductor, but other materials such as plastic and ceramics may be used.

1 portable radio timepiece, 2 exterior case, 3 dial, 4 pointer, 5 dial ring, 6 hour, 7 crown, 8 push button, 9 day window, 10 movement, 11 pointer shaft, 12 frame, 13 winding stem, 14 switch mechanism, 15 solar panel, 16 slot antenna, 17 slot, 18 axis opening, 19 flat conductor, 20 tongue, 21, 21a, 21b feeding point, 22 shielding area, 23 non-shielding area, 24 unevenness, 25 button Type battery, 26 winding stem attaching / detaching mechanism, 27 motor, 28 train wheel, 29 shielding electrode, 30 opening, 31 insulating substrate, 32 first electric wire, 33 second electric wire, 34 feeding line, 35 hole, 36 solar panel connection electrode.

Claims (14)

An exterior case,
A movement disposed in the exterior case;
A slot antenna in which an arc-shaped slot along the outer periphery of the movement is formed in a flat conductor;
Have
A portable radio timepiece in which at least one of an outer peripheral operation member and a display opening is disposed in an area where the slot is not formed with respect to the center of the movement in a plan view. A solar panel disposed on the slot antenna;
The solar panel extends to the outer periphery of the movement in a region where the slot is not formed with respect to the center of the movement, and exposes the slot in a region where the slot is formed with respect to the center of the movement. Shape,
The portable radio timepiece according to claim 1. The portable radio timepiece according to claim 2, wherein the solar panel has a shape overlapping with the slot at both ends of the slot. A solar panel disposed on the slot antenna and having a shielding region where a conductive film is formed on a substrate and a non-shielding region where a conductive film is not formed on the substrate;
The shield region extends to the outer periphery of the movement in a region where the slot is not formed with respect to the center of the movement, and the non-shielding region is a region where the slot is formed with respect to the center of the movement. , A shape overlapping the slot,
The portable radio timepiece according to claim 1. The shielding area is shaped to overlap the slot at both ends of the slot.
The portable radio timepiece according to claim 4. The radio-controlled wristwatch has a winding stem to which a crown as the outer peripheral operation member is attached, and a button type battery.
The button-type battery is located at a position deviated from the center of the movement to a region where the slot is not formed with respect to the center of the movement, and at a position deviated from the direction of the winding stem from the center of the movement. Placed in the
The portable radio timepiece according to any one of claims 1 to 5. In a plan view, metal members constituting the motor and the train wheel are arranged in a region in a circle inscribed in the slot,
The portable radio timepiece according to claim 1. The flat conductor of the slot antenna extends at least around the slot and in a range of 0.3% or more of the wavelength of the radio wave to be received by the slot antenna.
The portable radio timepiece according to claim 1. 9. The portable radio timepiece according to claim 1, further comprising: a shielding electrode having a flat conductor formed with an opening having a shape including the slot on a back surface side of the slot antenna. The opening of the shielding electrode extends at least around the slot and in a range of 0.3% or more of the wavelength of the radio wave to be received by the slot antenna.
The portable radio timepiece according to claim 9. The portable radio timepiece according to claim 1, wherein the slot antenna is unbalanced. The feeder line connected to the slot antenna is formed of a conductive thin film formed on an FPC board, and includes at least one first electric wire and at least two second electric wires formed on both sides in the transverse direction of the first electric wire. Having electric wires,
The portable radio timepiece according to claim 11. The slot antenna is unbalanced,
The feeder line connected to the slot antenna is formed of a conductive thin film formed on an FPC board, and includes at least one first electric wire and at least two second electric wires formed on both sides in the transverse direction of the first electric wire. Have wires,
A flat conductor of the slot antenna is formed on the surface side of the FPC,
The flat conductor of the shielding electrode and the feeder line are formed on the back side of the FPC,
The first electric wire is connected to a flat conductor of the slot antenna on the outer peripheral side of the slot,
The second electric wire is connected to the shielding electrode, and the shielding electrode is connected to the flat conductor of the slot antenna on the inner peripheral side of the slot.
The portable radio timepiece according to claim 9 or 10. The portable radio timepiece according to claim 10, 11 or 13, wherein the slot antenna and the shielding electrode are insulated from the outer case at an outer periphery thereof.

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