Patent Grant
10691078
This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2017-034287 filed on Feb. 27, 2017 the entire contents of which are incorporated herein by reference.
The present invention relates to electronic devices and timepieces.
A traditional electronic device such as a timepiece is equipped with a motor, such as a stepping motor, and an antenna device to receive radio waves.
To enhance the antimagnetic performance of the timepiece and maintain the operating accuracy of the motor, an antimagnetic plate should be installed to magnetically shield the motor from an external magnetic field, which adversely affects the operation of the motor.
Unfortunately, the antimagnetic plate, which causes distortion of the magnetic field, also leads to distortion of radio waves (a magnetic field) entering the antenna device. The antimagnetic plate placed in the vicinity of the antenna device attenuates the radio waves entering the antenna device, resulting in a reduction in radio wave receiving sensitivity of the antenna device.
To cope with this problem, Japanese Unexamined Patent Application Publication No. 2011-075541 discloses a timepiece that includes a microstrip antenna accommodated in and separated from a metallic case. This configuration can successfully prevent a reduction in receiving sensitivity, regardless of the metallic case reducing the receiving sensitivity.
Similarly, in providing an antimagnetic plate, it is possible to consider separating the antenna device from the antimagnetic plate.
Unfortunately, if a small device, such as a wristwatch, is equipped with an electronic device, all the components should be accommodated in limited spaces in a case, which indicates that a motor and an antenna device are inevitably installed in close proximity.
Recently, there has been an increasing demand for implementing multiple antenna devices to process various radio waves and multiple motors to achieve various functions.
Such a trend makes it more difficult to implement antenna devices separate from metal members, as described in Japanese Unexamined Patent Application Publication No 2011-075541, since a required implementation space cannot be provided.
Implementation of a largest possible antimagnetic plate is preferred to enhance antimagnetic performance and thereby maintain the operating accuracy of the motors. However, implementation of multiple antenna devices precludes securement of a space for implementing a large antimagnetic plate without close proximity between the motors and the antenna devices.
For an electronic device, which receives radio waves to correct the time and determine the position, a reduction in receiving sensitivity of antenna devices leads to a reduction in performance of the electronic device.
Because of this, the electronic device has been forced to sacrifice the antimagnetic performance of the motors to some extent to maintain the radio wave receiving performance of the antenna devices.
The present invention provides an electronic device and timepiece provided with a plurality of motors and a plurality of antenna devices which are able to maintain accuracy of operation of the motor by enhancing antimagnetic performance and able to maintain radio wave receiving performance of the antenna devices.
According to an aspect of the present invention, an electronic device includes: a plurality of antenna devices; a plurality of motors; and antimagnetic plates, each fully or partially covering the motors and having cutouts at positions overlapping with the antenna devices.
With reference to
Although the embodiments described below have various preferred technical restrictions to implement the present invention, these embodiments and drawings, however, should not be construed to limit the scope of the invention.
As shown in
The timepiece case 1 according to this embodiment is a short hollow column and provided with a wind shield 11 composed of transparent glass on the front (viewer side) of the timepiece 100.
The timepiece 100 has a rear lid 12 on its rear face.
The timepiece case 1 includes band mounts 13 for mounting a timepiece band (not shown) at its upper and lower ends, i.e., at the 12 o'clock and 6 o'clock positions of an analog timepiece, as shown in
The timepiece 100 includes an operational button 14 on a side of the timepiece case 1.
The operational button 14 is connected to a module 2 (described below), which has its insertion end located inside the timepiece case 1. The operational button 14 according to this embodiment is, for example, a winder that allows various operations to be performed by pressing or rotating the operational button 14.
The timepiece case 1 accommodates the electronic device including module 2 and a display 15. The display 15 is driven by motors 28 provided in the module 2 to operate and display the time.
The timepiece 100 according to this embodiment includes a functional wheel 52 (see
As shown in
The display 15 according to this embodiment is an analog display which includes a dial plate 16 and pointers 17 thereabove, as shown in
Hourmarks 161 are disposed on the surface of the dial plate 16 around its perimeter to show the time indicated by the pointers 17 (the hour, minute, and second hands).
The timepiece 100 according to this embodiment includes a calendar wheel 51 and a functional wheel 52, as described below. The calendar wheel 51 is a rotor with date numbers disposed around its periphery, while the functional wheel 52 is a rotor with worldwide city names disposed around its periphery (see
Besides the main display that displays the time with the pointers 17 of the hour, minute, and second hands, a small display 18 equipped with the pointer 17 of the functional hand is provided in the display 15.
The small display 18 displays the time at a city or region (for example, the current time in New York) which is different from that displayed with the hour, minute, and second hands (for example, the current time in Tokyo if the timepiece 100 is used there).
Alternatively, the display 15 need not be equipped with the small display 18. Alternatively, the display 15 may be a digital display that includes a liquid crystal panel or may include both of an analog display with the pointers 17 and a digital display that includes a liquid crystal panel.
The module 2 includes, for example, several antenna devices for receiving radio waves (in this embodiment, a BLE antenna 25, a GPS antenna 26, and a standard radio wave antenna 27, described below, see
Coaxial pointer shafts 19 extend from the module 2 through the dial plate 16 and protrudes from the dial plate 16.
The pointer shafts 19 according to this embodiment are pointer shafts for the hour, minute, and second hands and a pointer shaft for the functional hand. These pointer shafts for the hour, minute, and second hands are coaxially disposed and the pointers 17 of the hour, minute, and second hands are connected to their respective pointer shafts 19.
The pointer shafts 19 rotating in accordance with the timepiece movement causes their respective pointers 17 mounted thereon to separately pivot about their respective pointer shafts 19 above the upper face of the dial plate 16.
The number of the pointer shafts 19 and the number of the pointers 17, which are mounted on and pivot about their respective pointer shafts 19, are not limited to those shown in the drawing. Besides the hour, minute, and second hands, pointers 17 of functional hands which display function-related information may be provided, like this embodiment. Alternatively, a pointer shaft 19 may be provided to support only, for example, the hour hand and a single pointer 17 may be mounted on the pointer shaft 19.
With reference to
With reference to
The housing 21 is composed of, for example, resin and includes a base plate 211 and a side wall 212 disposed around its periphery.
The housing 21 provides upper and lower spaces above and below the base plate 211, the height of upper and lower spaces being equal to the raised length of the side wall 212, and accommodates the timepiece movement, various electronic components, and the substrates in the spaces.
The substrate according to this embodiment has a double-layer structure of the upper substrate 22 and the lower substrate 23. The upper substrate 22 and the lower substrate 23 are disposed on the rear side of the base plate 211 in the housing 21 (the opposite (lower) side of the viewer of the timepiece 100).
In detail, the upper substrate (a first substrate) 22 is disposed on the viewer side and the lower substrate (a second substrate) 23 is disposed below the upper substrate 22 (on the opposite side of the viewer of the timepiece 100) such that the upper substrate 22 and the lower substrate 23 are partially superimposed in the thickness direction of the module 2.
The lower substrate 23 according to this embodiment has a battery space 231, which is disposed at the 6 o'clock position of an analog timepiece.
The battery space 231 is a cutout conforming with the outer shape of the battery 24 (a button battery in this embodiment, as shown in
The BLE antenna 25 as a first antenna device is disposed on the viewer face of the lower substrate 23, i.e., the face opposing the upper substrate 22, in the vicinity of the battery space 231.
The BLE antenna 25 is a Bluetooth (registered trademark) Low Energy compliant antenna for relatively short-distance radio communication.
The timepiece 100 according to this embodiment sends and receives signals, shares information and performs synchronization with other devices located at a relatively short distance via the BLE antenna 25.
The Global Positioning System (GPS) antenna 26 as a second antenna device is disposed on the viewer (upper) face of the lower substrate 23 (i.e., the face opposing the upper substrate 22) at the opposite position of the battery space 231 and the BLE antenna 25 along the plane direction (i.e., at the 12 o'clock position of an analog timepiece).
The GPS antenna 26 receives signals sent from GPS satellites, for example, positioning codes, such as Coarse and Acquisition (C/A) codes and precise positioning (P) code, and navigation messages, such as Almanac information (summary orbit information) and Ephemeris information (detailed orbit information). The GPS antenna 26 can receive relatively high-frequency signals, for example, in the L1 (1575.42 MHz) and L2 (1227.6 MHz) bands. For example, a microstrip antenna can be suitably used as the GPS antenna 26. To achieve a compact implementation by downsizing the module 2, the GPS antenna 26 should be preferably smallest possible.
The timepiece 100 according to this embodiment determines the three-dimensional geographical position (latitude, longitude, and altitude) of, for example, the timepiece 100 based on the signals received by the GPS antenna 26.
The housing 21, which has the lower substrate 23 mounted on the rear (lower) side of the housing 21 (i.e., the opposite side of the viewer of the timepiece 100), includes a GPS antenna space 213 for accommodating the GPS antenna 26 at a position corresponding to the GPS antenna 26.
The upper substrate 22 has a cutout 221 conforming with the outer shape of the GPS antenna 26 at a position corresponding to the GPS antenna space 213 on the upper substrate 22 mounted on the housing 21.
The GPS antenna space 213 has a thickness substantially identical to that of the GPS antenna 26 (the thickness of the GPS antenna 26 minus the thickness of the upper substrate 22). The GPS antenna 26 is accommodated in the cutout 221 and the GPS antenna space 213 such that the GPS antenna 26 is substantially flush with the rear face of the upper substrate 22 where the lower substrate 23, which has the GPS antenna 26 mounted thereon, is disposed in rear of the housing 21 to oppose the upper substrate 22.
In this embodiment, the battery 24 and the GPS antenna 26 are disposed on the same plane side by side, the GPS antenna 26 is accommodated in the GPS antenna space 213 of the housing 21, and the battery 24 is accommodated in the battery space 231, being a cutout on the lower substrate 23, as shown in
An antenna retainer 214 is provided on the rear (lower) side of the base plate 211 of the housing 21 (i.e., the opposite side of the viewer of the timepiece 100) at a position that fully or partially overlaps with the BLE antenna 25 disposed on the mounted lower substrate 23. The antenna retainer 214 accommodates the standard radio wave antenna 27 as a third antenna device.
The standard radio wave antenna 27 can receive date and time information sent from an atomic timepiece in a standard radio station in the form of digital signals and is, for example, a coil-wound core composed of amorphous magnetic metal or ferrite.
The timepiece 100 corrects the time based on the digital signals containing date and time information received by the standard radio wave antenna 27.
The upper substrate 22 according to this embodiment has a cutout at a position corresponding to the antenna retainer 214 such that the antenna retainer 214 and the standard radio wave antenna 27 are disposed at a lower level than the upper substrate 22. This configuration, which allows the standard radio wave antenna 27 to be disposed on the rear side of the base plate 211, minimizes the irregularity.
The BLE communication using the BLE antenna 25 is a short-distance radio communication on a 2.4 GHz frequency band and does not interfere with the standard radio wave antenna 27, which is an antenna device to receive standard radio waves with a frequency of 40 kHz and/or 60 kHz.
Because of this nature, the BLE antenna 25 and the standard radio wave antenna 27 among the several antenna devices according to this embodiment are superimposed in the thickness direction of the module 2, i.e., the direction perpendicular to the antimagnetic plates. The BLE antenna 25 and the standard radio wave antenna 27 may be partially superimposed but need not be fully superimposed. The BLE antenna 25 and the standard radio wave antenna 27 may be disposed in any manner other than that shown in the drawing.
The antenna devices superimposed with each other enables compact and efficient implementation of the antenna devices (the BLE antenna 25 and the standard radio wave antenna 27 according to this embodiment) and can reduce the implementation area.
In this embodiment, antimagnetic plates (the front antimagnetic plate 31 shown in
The multiple motors 28 (six motors 28a to 28f in this embodiment, see
Each motor 28 is a stepping motor. The stepping motor includes, for example, a stator 281, a coil block 284, and a rotor 285 which is accommodated in a receptor of the stator 281. The coil block 284 includes a core 282 and a coil 283 wound therearound and is magnetically connected to the stator 281. Driving pulses applied, as appropriate, to the coil block 284 magnetically connected to the stator 281 cause the rotor 285 to rotate at a predetermined step angle.
In this embodiment, four motors 28b, 28c, 28e, and 28f in
The motors 28 operate each functional unit of the timepiece 100 and constitute a timepiece movement together with the train wheel mechanism 29 including a gear.
Each motor 28 is preferably disposed separately from the three antenna devices of the BLE antenna 25, the GPS antenna 26, and the standard radio wave antenna 27 according to this embodiment to the maximum extent possible.
The number or allocation of the motors 28 shown in
With reference to
In detail, the front antimagnetic plate 31 is disposed above the base plate 211 on the viewer (front) side of the timepiece 100, as shown in
Each antimagnetic plate fully or partially covers multiple motors 28 and provides a cutout 315 to avoid overlap with the three antenna devices of the BLE antenna 25, the GPS antenna 26, and the standard radio wave antenna 27 according to this embodiment.
In detail, the front antimagnetic plate 31 is disposed above the base plate 211 on the viewer (front) side of the timepiece 100 so as to avoid overlap with the three antenna devices of the BLE antenna 25, the GPS antenna 26, and the standard radio wave antenna 27 according to this embodiment.
With reference to
The antimagnetic plates distort an external magnetic field to prevent it from reaching the motors 28 and have a magnetically shielding effect.
Each antimagnetic plate (the front antimagnetic plate 31 and the rear antimagnetic plate 32) is composed of, for example, cold-reduced carbon steel sheets and strips (SPCC) or permalloy.
Any antimagnetic plate may be used which can effectively prevent a magnetic field, which adversely affects the motors 28, from reaching the motors 28. The antimagnetic plates may be composed of any material other than those described here.
With reference to
The front antimagnetic plate 31 according to this embodiment includes an antimagnetic plate body 311 and a side cover 312. The antimagnetic plate body 311 covers the viewer sides of the motors 28. The side cover 312 is connected to the antimagnetic plate body 311 to cover the sides of the motors 28.
Of the six motors 28a to 28f according to this embodiment, three motors 28a, 28b, and 28d disposed near the periphery of the module 2 have their sides covered with the side cover 312. The motors 28 having sides covered with the side cover 312 need not be limited to those shown in the drawing. The side cover 312 that can cover, for example, the sides of all the motors 28 may be provided to cover all the sides.
The front antimagnetic plate 31 according to this embodiment is a single sheet fabricated by stamping a material plate into a predetermined shape and bending the stamped plate. In detail, the side cover 312 is connected to the antimagnetic plate body 311 via a bridge 313, as shown in
The antimagnetic plate body 311, which covers the viewer sides of the motors 28, is formed integrally with the side cover 312 covering the sides of the motors 28. This configuration allows the front antimagnetic plate 31 to seamlessly cover a larger area than the antimagnetic plate body 311 formed separately from the side cover 312 and disposed around the motors 28, which can achieve a higher antimagnetic effect.
The side cover 312 should be preferably bent near its two ends so as to be disposed along the side faces of each coil block 284.
The bent portions of the side cover 312 should preferably be long enough to at least cover the areas defined by extending the core 282 wound by the coil 283 in the lateral direction.
The side covers 312 in
As described above, the timepiece 100 accommodating the electronic device according to the present invention include the calendar wheel 51 for displaying a date and the functional wheel 52 for displaying function-related information, such as a city name.
The calendar wheel 51 and the functional wheel 52 are each a plate-like toroidal rotor composed of a non-metallic material and rotate along the plane direction when driven by the motors 28.
The non-metallic material of the calendar wheel 51 and the functional wheel 52 is a synthetic resin, for example, acrylic or polycarbonate resin. The calendar wheel 51 and the functional wheel 52 may be composed of any other non-metallic material.
The calendar wheel 51 and the functional wheel 52 may be composed of an identical material or different materials. The calendar wheel 51 and the functional wheel 52 may have any thickness, color and size, which may be determined as appropriate based on the design of the timepiece 100.
The calendar wheel 51 and the functional wheel 52, which are rotors, are disposed on the opposite (lower) side of the viewer of the dial plate 16, a decorative board partially equipped with the windows 162 and 163 (see
Since only the functional wheel 52 according to this embodiment is a rotor having a characteristic configuration, the calendar wheel 51 is not shown in
With reference to
With reference to
As shown in
The gear 522 of the functional wheel 52 engages with the train wheel mechanism 29 and is connected to the motors 28 via the train wheel mechanism 29. When driven by the motors 28, the gear 522, which engages with the train wheel mechanism 29, rotates to cause the entire functional wheel 52 to rotate along the plane direction.
The functional wheel 52, being a rotor, has a metallic portion 523 on the upper face (viewer side) of the wheel body 521.
The metallic portion 523 according to this embodiment is an evaporated- or sputtered metallic film.
The metallic portion 523 may be composed of various metals, for example, Au, Cr, Al, Pt, Ni, Pd and Rh.
The metallic portion 523 may be formed by any method capable of forming a metallic film other than those shown here. Ion plating may be used, for example.
The metallic portion 523 has a minimum film thickness required to express a metallic appearance to minimize the impact of metal components on the antenna devices. The film thickness is, for example, about 500 angstroms to 5000 angstroms, although it depends on the type of metal or a method of forming the metallic portion 523.
The metallic film, which is composed of metal, may cause a reduction in receiving sensitivity of the BLE antenna 25, the GPS antenna 26, and the standard radio wave antenna 27 according to this embodiment, if these are disposed in the vicinity of the antenna devices. The metallic portion 523 should be preferably smallest possible.
Accordingly, the metallic portion 523 is not provided on the lower (rear) side of the wheel body 521 (i.e., the opposite side of the viewer), which does not affect appearance.
If the gear 522 had a metal surface produced by evaporation, metallic flakes could fall into the timepiece case 1 due to friction during engagement of the gears. The gear 522 is not exposed to the outside. Accordingly, no metallic portion 523 is provided on the upper and lower faces of the gear 522.
The metallic portion 523 need not cover the entire wheel body 521 and should be provided on a portion exposed through the window 163 in the dial plate 16, which functions as a decorative board shown in
The operations of the electronic devices according to this embodiment and the timepiece 100 will now be explained.
The timepiece 100 is assembled as follows: A predetermined number of motors 28 and the train wheel mechanism 29 connected thereto are mounted on the viewer side of the base plate 211 of the housing 21. The front antimagnetic plate 31, which fully or partially covers multiple motors 28 and is provided with cutouts at positions overlapping with the several antenna devices, is mounted to cover the front faces of the motors 28. The motors 28a, 28b, and 28d according to this embodiment are provided with the side covers 312 to cover the coil blocks 284; the bridges 313 are bent at about 90° to the opposite side of the viewer; and the side covers 312 are bent along the side faces of the coil blocks 284 of the motors 28a, 28b, and 28d so as to cover the side faces of the coil blocks 284.
The rear antimagnetic plate 32 is mounted on the opposite side of the viewer of the base plate 211 to fully or partially cover these motors 28 while avoiding overlap with several antenna devices.
The standard radio wave antenna 27 is mounted in the antenna retainer 214 on the opposite side of the viewer of the base plate 211.
The upper substrate 22 is mounted on the opposite side of the viewer of the base plate 211 such that the GPS antenna space 213 is aligned with the cutout 221.
The BLE antenna 25 and the GPS antenna 26 are mounted on a side, facing the opposite side of the viewer of the upper substrate 22, of the lower substrate 23. The mounted BLE antenna 25 substantially overlaps with the standard radio wave antenna 27. The GPS antenna 26 is mounted so as to be fit into the GPS antenna space 213 of the housing 21 and the cutout 221 of the upper substrate 22.
The lower substrate 23 is superimposed on the upper substrate 22, the GPS antenna 26 is fit into the GPS antenna space 213, and the battery 24 is placed in the battery space 231 of the lower substrate 23. The module 2 according to this embodiment is finished.
The calendar wheel 51 and the functional wheel 52 are mounted on the viewer side of the module 2 to finish the electronic device according to this embodiment.
The electronic device is mounted in the timepiece case 1, the rear lid 12 is closed to block the opening on the opposite side of the viewer of the timepiece case 1, and the display 15 including the dial plate 16 and the pointers 17 is placed on the calendar wheel 51 and the functional wheel 52 in the electronic device.
The wind shield 11 is mounted on the opening on the viewer side of the timepiece case 1.
The assembly of the timepiece 100 according to this embodiment is finished.
An external magnetic field enters the timepiece 100 and adversely affects the motors 28 to reduce their operating accuracy.
In this embodiment, the antimagnetic plates are provided to fully or partially cover the motors 28 on the upper (viewer) sides and the lower sides (i.e., the opposite side of the viewer) of the motors 28. In other words, the motors 28 are disposed between the front antimagnetic plate 31, which is disposed on the upper sides of the motors 28, and the rear antimagnetic plate 32, which is disposed on the lower sides of the motors 28. This configuration allows the antimagnetic plates 31 and 32 to distort an external magnetic field to magnetically shield the motors 28 so that the magnetic field does not adversely affect the motors 28. For three motors 28a, 28b and 28d according to this embodiment, the side covers 312 connected to the antimagnetic plate body 311 also magnetically shield the side faces of the coil blocks 284. This configuration can achieve a higher antimagnetic effect.
In this embodiment, the substrate has a double-layer structure of the upper substrate 22 and the lower substrate 23, each of which has electronic components disposed thereon. This configuration enhances implementation efficiency.
The timepiece 100 according to this embodiment includes the functional wheel or rotor 52, which allows function-related information, such as city name, to appear through the window 163 provided on the dial plate 16.
The functional wheel or rotor 52 is disposed at a position fully or partially covering the BLE antenna 25, the GPS antenna 26, and the standard radio wave antenna 27 according to this embodiment. If the functional wheel 52 is disposed in a small timepiece case 1, like, for example, a wrist timepiece, the distance is short between the functional wheel 52 and the antenna devices.
However, the functional wheel 52, which is composed of a non-metallic material such as resin according to this embodiment, does not reduce the receiving sensitivity of the antenna devices.
The functional wheel 52 would lack a premium feel if it had a resin-like appearance since its top is partially exposed through the window 163. In this embodiment, the functional wheel 52 is provided with the metallic portion 523 of a metallic film on its upper face. This configuration provides the functional wheel 52 with a metal-look appearance when its top surface is partially exposed through the window 163.
As described above, the electronic device according to this embodiment and the timepiece 100 includes the BLE antenna 25, the GPS antenna 26, and the standard radio wave antenna 27, the motors 28a to 29f, and antimagnetic plates. The antimagnetic plates are disposed to fully or partially cover the multiple motors 28 and provided with the cutout 315 at positions overlapping with the BLE antenna 25, the GPS antenna 26, the standard radio wave antenna 27 according to this embodiment.
This configuration magnetically shields the motors 28 from an external magnetic field, which adversely affects the operation of the motors 28. With this, the external magnetic field does not reach the motors 28. This prevents malfunction of the motors 28, enhances their operating accuracy, and meet stringent antimagnetic requirements as set forth, for example, in Japanese industrial Standard (JIS) for antimagnetic timepieces.
In particular, the antimagnetic plate according to this embodiment includes the antimagnetic plate body 311 covering the viewer side of the motors 28 or opposite the viewer side. The antimagnetic plate may also include a side cover 312 connected to the antimagnetic plate body 311 to cover the side faces of the motors 28. This configuration also allows the antimagnetic plate to effectively shield the side faces of the motors 28.
This configuration can significantly reduce the impact of an external magnetic field on the motors 28 to the maximum extent possible and enhance antimagnetic performance.
An antimagnetic plate disposed in the vicinity of an antenna device may reduce the receiving sensitivity of the antenna device. However, the antimagnetic plates according to this embodiment are disposed to avoid the antenna devices. This configuration can retain the receiving sensitivity of the BLE antenna 25, the GPS antenna 26, and the standard radio wave antenna 27 according to this embodiment, while maintaining their antimagnetic performance.
The BLE antenna 25 and the standard radio wave antenna 27 according to this embodiment are at least partially superimposed in the thickness direction which is perpendicular to the plane direction of the antimagnetic plates. This configuration can reduce the implementation area of the antenna devices, downsize the entire timepiece, and save the space. This, in turn, decreases the range where the antimagnetic plates cannot be provided, increases a space for larger antimagnetic plates and further enhances the antimagnetic characteristics.
The antimagnetic plates according to this embodiment consist of the front antimagnetic plate 31 disposed on the viewer side of the timepiece 100 and the rear antimagnetic plate 32 disposed on the opposite side of the viewer. The motors 28 are disposed between the front antimagnetic plate 31 and the rear antimagnetic plate 32.
This configuration can efficiently eliminate the impact of an external magnetic field on the motors 28 to further enhance antimagnetic performance.
The timepiece 100 according to this embodiment includes the functional wheel 52 which displays function-related information, such as a city name. This expands the functionality of the timepiece 100.
The functional wheel 52, which is composed of a non-metallic material, such as resin, does not adversely affect the receiving sensitivity of the antenna devices.
The functional wheel 52 has the metallic portion 523, which has a metal-like appearance on its top. This provides a high-class appearance as if it could be achieved by a functional wheel 52 made of metal, while maintaining the receiving sensitivity of the antenna devices.
Although the embodiment of the present invention has been described above, it should be understood that the embodiment described above is not construed to limit the present invention and can be appropriately modified without departing from the scope of the present invention.
In the above embodiment, the exemplary multiple antenna devices, for example, include the BLE antenna 25, the GPS antenna 26, and the standard radio wave antenna 27. Alternatively, the electronic device and the timepiece 100 may have any type of antenna devices.
For example, the antennas may be magnetic sensors, such as azimuth sensors, or other sensors.
The number of antennas is not limited to three. In other words, a plurality of antennas (e.g., two, four, or more antennas) may be provided.
In the above embodiment, the exemplary metallic portion 523 of the functional wheel or rotor 52 is composed of an evaporated metallic film. Alternatively, the metallic portion 523 need not be a metallic film.
For example, if the functional wheel or rotor 52 is fabricated with a die, the metallic portion 523 may be formed on the viewer side of the rotor using a die with a surface pattern of streaks or rays from the rising sun formed by metal working.
This method can also provide a functional wheel or rotor 52 with a metal-like appearance and a high-class finish.
The rotor may be patterned using a die with a surface pattern formed by surface machining and then subject to the surface treatment for forming a metallic film as described above.
This can further enhance metallic feeling.
In the above embodiment, only the functional wheel 52 is provided with the metallic portion 523. Alternatively, for example, the calendar wheel 51 may be provided with a metallic portion.
The unexposed portions viewed through the windows 162 and 163 of the functional wheel 52 and the calendar wheel 51 does not need the metallic portion 523. In this case, the functional wheel 52 and the calendar wheel 51 should be rotated such that the portions without the metallic portion 523 overlap with the antenna devices while the antenna devices are receiving radio waves. This can maintain high receiving sensitivity of the antenna devices and further reduce the impact on the antenna devices.
In the above embodiment, the exemplary functional wheel or rotor 52 is substantially toroidal. Alternatively, the rotor may have any other shape that can rotate along the plane and are disposed to fully or partially cover the antenna devices in planar view. For example, the rotor may be a disk.
In the above embodiment, the electronic device is applied to the timepiece 100. The electronic device can also be applied to any apparatuses other than the timepiece 100. For example, the electronic device may be applied to a variety of apparatuses provided with antenna devices, such as GPS antennas, and motors.
For example, the electronic device according to the present invention may be applied to passometers, heart rate meters, altimeters, barometers, and terminals, such as mobile phones.
Although several embodiments of the present invention have been described above, the present invention should not be construed to limit the scope of these embodiments and includes the scope of the claims below or the equivalent thereto.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2017-034287 | Feb 2017 | JP | national |
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| Number | Date | Country |
|---|---|---|
| 101405665 | Apr 2009 | CN |
| 104932246 | Sep 2015 | CN |
| 2005084037 | Mar 2005 | JP |
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| Entry |
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| Japanese Office Action (and English language translation thereof) dated Jan. 15, 2019 issued in counterpart Japanese Application No. 2017-034287. |
| Chinese Office Action dated Sep. 26, 2019 (and English translation thereof) issued in Chinese Application No. 201810159503.1. |
| Number | Date | Country | |
|---|---|---|---|
| 20180246476 A1 | Aug 2018 | US |
