The present application is based on, and claims priority from JP Application Serial Number 2020-212195, filed Dec. 22, 2020, the disclosure of which is hereby incorporated by reference herein in its entirety.
The present disclosure relates to an electronic watch.
An electronic watch with a battery has been widely used. As indicated in JP-A-2018-163166, a battery having a button shape has been generally used for an electronic watch. A movement is provided with a motor, a torque transmission mechanism by a toothed gear, a mechanism for rotating a hand by rotation of a setting stem, a printed wired board that drives the motor, and an area for housing a battery.
As disclosed in JP-A-2018-163166, when the battery is disposed in the movement, a thickness and a size of the battery are great constraints, and thus a reduction in thickness and size of the movement is limited.
An electronic watch includes a hand configured to indicate time, a dial having a through hole through which a hand shaft configured to rotate the hand passes, a movement including a motor configured to rotate the hand shaft, and a circuit electrically coupled to the motor, a battery electrically coupled to the circuit and configured to supply power to the motor, and a solar panel configured to supply power to the battery, wherein the movement, the battery, the solar panel, and the dial are disposed in this order, the battery has a first opening through which the hand shaft passes, and the solar panel has a second opening through which the hand shaft passes.
As illustrated in
As illustrated in
A dial 7 is disposed on a back surface side of the cover glass 5. The dial 7 is optically transparent.
A hand shaft 8 is disposed at the center of the dial 7 in plan view of the dial 7. A seconds hand 9, a minute hand 11, and an hour hand 12 indicating time are attached to the hand shaft 8. Hereinafter, the seconds hand 9, the minute hand 11, and the hour hand 12 are referred to as a hand 13. The hand shaft 8 is formed of three rotary shafts to which the seconds hand 9, the minute hand 11, and the hour hand 12 are attached. The hand 13 rotates about the hand shaft 8. The cover glass 5 is transparent, and the dial 7 and the hand 13 are visible through the cover glass 5.
A first through hole 7a is formed at the center of the dial 7. The hand shaft 8 passes through the first through hole 7a. The dial 7 is provided with a mark 14. The mark 14 is disposed concentrically about the first through hole 7a. The mark 14 is disposed every 30 degrees. The hand 13 indicates time with the mark 14 as a graduation.
A solar panel 15 is disposed on a back surface side of the dial 7. Light passing through the dial 7 is applied to the solar panel 15. The solar panel 15 receives light and generates power. A battery 16 is disposed on a back surface side of the solar panel 15. A movement 17 is disposed on a back surface side of the battery 16. The movement 17, the battery 16, the solar panel 15, and the dial 7 are disposed in order of the movement 17, the battery 16, the solar panel 15, and the dial 7 from the movement 17 toward the dial 7.
The movement 17 includes a main plate 18, a train wheel bridge 19, a motor 21, a circuit portion 24 as a circuit, a train wheel mechanism 22, the hand shaft 8, and the like. The circuit portion 24 is disposed on a back surface side of the main plate 18. The circuit portion 24 outputs a drive current that drives the motor 21. The motor 21 and the train wheel mechanism 22 are disposed between the main plate 18 and the train wheel bridge 19. The train wheel mechanism 22 transmits torque of the motor 21 to the hand shaft 8. The hand shaft 8 is a part of the movement 17. The motor 21 and the train wheel mechanism 22 rotate the hand shaft 8. A guide frame 23 is disposed between the dial 7, the solar panel 15, the battery 16, and the movement 17, and the outer case 4. A position of the dial 7, the solar panel 15, the battery 16, and the movement 17 in a thickness direction of the watch body 2 is determined by the guide frame 23.
The solar panel 15 is disposed between the dial 7 and the battery 16. The solar panel 15 has a second opening 15a through which the hand shaft 8 passes. The second opening 15a is a through hole. The second opening 15a and the first through hole 7a are disposed so as to overlap each other, and the hand shaft 8 passes through both of the second opening 15a and the first through hole 7a. The solar panel 15 provides power to the battery 16.
The battery 16 is disposed between the solar panel 15 and the movement 17. The battery 16 has a first opening 16a through which the hand shaft 8 passes. The first opening 16a is a through hole. The first opening 16a, the second opening 15a, and the first through hole 7a are disposed so as to overlap each other, and the hand shaft 8 passes through all of the first opening 16a, the second opening 15a, and the first through hole 7a. The circuit portion 24 is electrically coupled to the battery 16. The battery 16 supplies power to the motor 21 via the circuit portion 24.
According to this configuration, the battery 16 and the solar panel 15 are disposed between the dial 7 and the movement 17. The hand shaft 8 passes through the first opening 16a of the battery 16 and the second opening 15a of the solar panel 15. The hand shaft 8 rotates the hand 13 disposed on the dial 7 side.
Therefore, the movement 17 does not have an area where the battery 16 is disposed, and thus the movement 17 can be made thinner and smaller. Since the battery 16 is disposed close to the solar panel 15, electrical coupling can be easily established between the solar panel 15 and the battery 16.
According to this configuration, since the first through hole 7a, the first opening 16a, and the second opening 15a are through holes, the hand shaft 8 can pass through the first through hole 7a, the first opening 16a, and the second opening 15a.
In the electronic watch 1, the solar panel 15 and the battery 16 are in contact with each other. According to this configuration, since the solar panel 15 and the battery 16 are in contact with each other, the solar panel 15 is reinforced. Therefore, damage to the solar panel 15 during a manufacturing step can be suppressed. Further, since the solar panel 15 and the battery 16 are located close to each other, electrical coupling can be easily established between the solar panel 15 and the battery 16. Since the solar panel 15 and the battery 16 are integrated together, the solar panel 15 and the battery 16 can be easily incorporated into the watch body 2.
The battery 16 includes a first surface 16b on the dial 7 side and a second surface 16c on the main plate 18 side. A first wiring substrate 25 is disposed on the battery 16 from the first surface 16b to the second surface 16c along a side surface. The first wiring substrate 25 includes a first electrode 25a and a second electrode 25b at a surface facing the movement 17. The first electrode 25a and the second electrode 25b are electrically coupled to an electrode of the battery 16. The circuit portion 24 includes a third electrode 24a and a fourth electrode 24b at a surface facing the battery 16. A first spring 26 is disposed between the first electrode 25a and the third electrode 24a. The first spring 26 electrically couples the first electrode 25a and the third electrode 24a. A second spring 27 is disposed between the second electrode 25b and the fourth electrode 24b. The second spring 27 electrically couples the second electrode 25b and the fourth electrode 24b. A through hole is formed in the main plate 18 at a place where the first spring 26 and the second spring 27 are disposed. Thus, even with the main plate 18 between the battery 16 and the circuit portion 24, the first spring 26 and the second spring 27 can be electrically coupled to the circuit portion 24. Note that, when the battery 16 is adhesively fixed to the movement 17, stability of electrical coupling between the battery 16 and the movement 17 can be improved.
In this way, the movement 17 includes, on an upper surface 17a side facing the battery 16, the third electrode 24a and the fourth electrode 24b that are electrically coupled to the battery 16. The third electrode 24a and the fourth electrode 24b are disposed on the surface on the battery 16 side, thereby facilitating electrical coupling to the battery 16.
In plan view viewed from an axial direction of the hand shaft 8, the size of the battery 16 is the same as that of the dial 7. According to this configuration, by adopting the battery 15 as a battery having the same size as that of the dial 7 in the plan view viewed from the axial direction of the hand shaft 8, a larger battery can be adopted than when the battery 16 is included in the movement 17, and thus capacity of the battery 16 can be increased. Note that “the same” also includes “substantially the same”.
The battery 16 is an all-solid battery. Specifically, the battery 16 is an all-solid lithium secondary battery.
According to this configuration, since the battery 16 is an all-solid battery, a leak does not need to be taken into consideration, and thus safety can be ensured. The battery 16 is an electrically chargeable all-solid secondary battery, but may also be used as a primary battery.
Next, the solar panel 15 and the battery 16 will be described according to
The solar circuit portion 28 includes a fifth electrode 28a as an electrode and a sixth electrode 28b as an electrode. Power generated by the solar panel 15 is output to the fifth electrode 28a and the sixth electrode 28b. Note that the arrangement of the electrodes included in the solar circuit portion 28 is not limited to the arrangement illustrated in
A through hole is disposed in the solar circuit portion 28 so as to overlap the second opening 15a. The hand shaft 8 passes through the through hole of the solar circuit portion 28. A notch portion 28c is formed in the solar circuit portion 28 at a place facing the first wiring substrate 25. The notch portion 28c is larger than the first wiring substrate 25. When the solar panel 15 and the battery 16 overlap each other, the solar circuit portion 28 does not overlap the first wiring substrate 25.
The battery 16 includes a positive electrode 16d and a negative electrode 16e. The first wiring substrate 25 includes a seventh electrode 25c and an eighth electrode 25d. The seventh electrode 25c is electrically coupled to the positive electrode 16d and the first electrode 25a. The eighth electrode 25d is electrically coupled to the negative electrode 16e and the second electrode 25b.
A positive electrode pad 16f as an electrode is disposed on the positive electrode 16d at a place facing the sixth electrode 28b. A negative electrode pad 16g as an electrode is disposed on the negative electrode 16e at a place facing the fifth electrode 28a. The solar panel 15 includes the fifth electrode 28a and the sixth electrode 28b at a surface facing the battery 16. The battery 16 includes the negative electrode pad 16g and the positive electrode pad 16f at a surface facing the solar panel 15. The solar panel 15 and the battery 16 are joined by an anisotropic conductive film 29.
In the anisotropic conductive film 29, conductive particles are dispersed in a thermosetting resin. When the solar panel 15 and the battery 16 are thermally crimped with the anisotropic conductive film 29 sandwiched therebetween, the thermosetting resin contracts to bond the solar panel 15 and the battery 16. Since the density of the conductive particles increases between the positive electrode pad 16f and the sixth electrode 28b, the positive electrode pad 16f and the sixth electrode 28b are electrically coupled to each other. Since the density of the conductive particles increases between the negative electrode pad 16g and the fifth electrode 28a, the negative electrode pad 16f and the fifth electrode 28a are electrically coupled to each other. Since the density of the conductive particles is low between the positive electrode pad 16f and the negative electrode pad 16g, the positive electrode pad 16f and the negative electrode pad 16g are in an electrically isolated state.
According to this configuration, since the solar panel 15 and the battery 16 are joined by the anisotropic conductive film 29, electrical coupling can be easily established between the solar panel 15 and the battery 16. An energy loss on energization between the solar panel 15 and the battery 16 can be suppressed. Since the solar panel 15 and the battery 16 are integrated together, the solar panel 15 and the battery 16 can be easily incorporated into the watch body 2.
As illustrated in
A cylindrical first insulating portion 32 is installed on an outer circumference of the overlapped battery units 31, and a second insulating portion 33 is installed on an inner circumference. The circular negative electrode 16e is installed on an upper side of the battery units 31, the first insulating portion 32, and the second insulating portion 33 in the diagram, and a third insulating portion 34 is installed on an outer circumferential side of the negative electrode 16e and on a side surface side of the first insulating portion 32. The third insulating portion 34 is disposed between the positive electrode 16d and the negative electrode 16e, and is also disposed between the positive electrode 16d and the second insulating portion 33. Furthermore, the third insulating portion 34 is installed on an inner circumferential side of the negative electrode 16e and on a side surface side of the second insulating portion 33. Also on the inner circumferential side of the negative electrode 16e, the third insulating portion 34 is disposed between the negative electrode 16e and the positive electrode 16d, and is also disposed between the positive electrode 16d and the second insulating portion 33.
The first insulating portion 32 and the second insulating portion 33 fix the battery units 31 such that the battery units 31 do not move in a left-and-right direction in the diagram. Furthermore, the first insulating portion 32 and the second insulating portion 33 perform insulation such that the side surface of the battery units 31 does not conduct with the positive electrode 16d. The third insulating portion 34 insulates the positive electrode 16d and the negative electrode 16e. A material of the positive electrode 16d and the negative electrode 16e is stainless steel. A material of the first insulating portion 32, the second insulating portion 33, and the third insulating portion 34 is insulating acrylic resin.
As illustrated in
The lower electrode 35 is an electrode that serves as a positive electrode, and functions as a substrate that maintains a structure. A material of the lower electrode 35 is copper. The carbon sheet 36 is a carbon film that efficiently flows a current between the lower electrode 35 and the electrode composite 37.
The separation film 38 is a film that prevents a short circuit between the electrode composite 37 and the upper electrode 39, and is a film formed of LBO (lithium triborate), LCBO (lithium carbon borate), and the like. In the present exemplary embodiment, for example, LCBO is adopted for the separation film 38. Further, the upper electrode 39 is an electrode that serves as a negative electrode, and is a lithium film.
As illustrated in
The communication hole 43 is filled with a non-crystalline solid electrolyte 44. Since the communication hole 43 is installed in a mesh pattern, the active material forming body 41 and the solid electrolyte 44 are in contact with each other over a wide area. Thus, lithium ions easily move between the active material forming body 41 and the solid electrolyte 44.
Further, the solid electrolyte 44 fills the communication hole 43 between the active material forming bodies 41. Therefore, the solid electrolyte 44 is a continuous structure having a mesh pattern. The lithium ions move within the solid electrolyte 44. Then, since the solid electrolyte 44 in a mesh pattern fills the communication hole 43, a path in which lithium ions can move to every corner of the active material forming body 41 is secured. The solid electrolyte 44 is in a non-crystalline form, has low resistance of a grain boundary, and can thus make the lithium ions easy to move. As a result, the battery 16 can stably perform a charging-discharging cycle.
When the battery 16 is charged, the lithium ions in the solid electrolyte 44 move from the active material forming body 41 of the electrode composite 37 to the upper electrode 39. The upper electrode 39 is a negative electrode of a lithium film. Then, when the battery 16 is discharged, the lithium ions in the solid electrolyte 44 move from the upper electrode 39 to the active material forming body 41 of the electrode composite 37.
A lithium double oxide is used as a material for forming the active material particles 42. Note that the lithium double oxide is an oxide that always contains lithium, contains two or more kinds of metal ions, and does not contain oxoacid ions. Examples of the lithium double oxide include LiCoO2, LiNiO2, LiMn2O4, Li2Mn2O3, LiFePO4, Li2FeP2O7, LiMnPO4, LiFeBO3, Li3V2(PO4)3, Li2CuO2, LiFeF3, Li2FeSiO4, and Li2MnSiO4.
In addition, solid solutions in which a part of atoms of these lithium double oxide is substituted with other transition metal, a typical metal, an alkali metal, an alkali rare earth, lanthanoid, chalcogenide, halogen, and the like may also be included in the lithium double oxide, and these solid solutions can also be used as positive electrode active materials. In the present exemplary embodiment, for example, LiCoO2 is used for the active material particles 42.
Li2+XC1—XBXO3 is used for a material of the solid electrolyte 44. X is a substitution rate of boron B and represents a real number greater than 0 and less than or equal to 1. Therefore, Li2CO3 when X is 0 is not included in the solid of the solid electrolyte 44, and Li3BO3 when X is 1 is included. Then, in the communication hole 43, the solid electrolyte 44 is non-crystalline.
The present exemplary embodiment is different from the first exemplary embodiment in a point that the first opening 16a in the battery 16 the second opening 15a of the solar panel 15 are a slit. Note that configurations identical to those in the first exemplary embodiment will be denoted by the same reference signs and redundant descriptions will be omitted.
As illustrated in
The solar panel 47 includes a solar circuit portion 48 on surface on aside facing a battery 51. A slit is disposed in the solar circuit portion 48 at a place facing the second opening 47a. The hand shaft 8 passes through the slit of the solar circuit portion 48. A notch portion 48c is formed in the solar circuit portion 48 at a place facing a first wiring substrate 25. The notch portion 48c is larger than the first wiring substrate 25. When the solar panel 47 and the battery 51 overlap each other, the solar circuit portion 48 does not overlap the first wiring substrate 25.
An anisotropic conductive film 49 is disposed between the solar circuit portion 48 and the battery 51. A slit is disposed in the anisotropic conductive film 49 at a place facing the second opening 47a. The hand shaft 8 passes through the slit of the anisotropic conductive film 49. According to this configuration, since the second opening 47a is a slit, the hand shaft 8 can pass through the second opening 47a. The solar circuit portion 48 includes a fifth electrode 48a as an electrode and a sixth electrode 48b as an electrode.
The battery 51 has a first opening 51a. The first opening 51a is a slit extending from a place through which the hand shaft 8 passes toward an outer circumference of the battery 51. The battery 51 includes a negative electrode pad 51g as an electrode and a positive electrode pad 51f as an electrode. The negative electrode pad 51g and the fifth electrode 48a are electrically coupled to each other. The positive electrode pad 51f and the sixth electrode 48b are electrically coupled to each other.
According to this configuration, since the first opening 51a and the second opening 47a are a slit, the hand shaft 8 can pass through the first opening 51a and the second opening 47a. Further, an operator can put in and take out the solar panel 47 and the battery 51 between a dial 7 and a movement 17 by moving the solar panel 47 and the battery 51 toward the side surface.
The present exemplary embodiment is different from the first exemplary embodiment in a point that a date indicator is disposed. Note that configurations identical to those in the first exemplary embodiment will be denoted by the same reference signs and redundant descriptions will be omitted.
As illustrated in
The dial 56 has a first through hole 56a corresponding to the first through hole 7a. The solar panel 57 has a second opening 57a corresponding to the second opening 15a. The battery 58 has a first opening 58a corresponding to the first opening 16a.
The electronic watch 54 includes a date indicator 59 and a date indicator driving wheel 61 between the battery 58 and a movement 17. The date indicator driving wheel 61 is driven by a train wheel mechanism 22, and the date indicator driving wheel 61 rotates the date indicator 59.
The dial 56 includes a date window 56b through which a mark at the date indicator 59 is visible. This mark is a number indicating a date. “1” of a first day and “31” of a 31st day correspond to the mark.
The solar panel 57 has a fourth opening 57b in a position corresponding to the date window 56b. The battery 58 has a third opening 58b in a position corresponding to the date window 56b. Thus, an operator can confirm the mark of the date indicator 59 through the date window 56b, the third opening 58b, and the fourth opening 57b.
The present exemplary embodiment is different from the first exemplary embodiment in a point that the dial 7 including the solar panel 15 and the battery 16 integrated together is provided. Note that configurations identical to those in the first exemplary embodiment will be denoted by the same reference signs and redundant descriptions will be omitted.
As illustrated in
A battery 16 is disposed on a back surface side of the dial 66. A movement 17 is disposed on a back surface side of the battery 16. The dial 66 supplies power to the battery 16. The movement 17, the battery 16, and the dial 66 are disposed in order of the movement 17, the battery 16, and the dial 66.
The dial 66 has a first through hole 66a as a second opening at the center. A hand shaft 8 passes through a first opening 16a and the first through hole 66a.
The movement 17, the battery 16, and the dial 66 are housed in a space enclosed by the cover glass 5, an outer case 67, and a case back 6. A guide frame 68 is disposed between the dial 66, the battery 16, and the movement 17, and the outer case 67. A position of the dial 66, the battery 16, and the movement 17 in a thickness direction of the watch body 65 is determined by the guide frame 68.
According to this configuration, the hand shaft 8 passes through the first opening 16a of the battery 16 and the first through hole 66a of the dial 66, and the hand shaft 8 rotates a hand 13 disposed on the dial 66 side. Therefore, the movement 17 does not have an area where the battery 16 is disposed, and thus the movement 17 can be made thinner and smaller. Since the battery 16 is disposed close to the dial 66 having a function of the solar panel 15, electrical coupling can be easily established between the dial 66 and the battery 16.
In the first exemplary embodiment described above, a planar shape of the watch body 2, the dial 7, and the battery 16 is circular.
A planar shape of the watch body 2, the dial 7, and the battery 16 may be rectangular. The production efficiency of the battery 16 can be improved.
In the first exemplary embodiment described above, a global positioning system (GPS) is not mounted. The GPS may be disposed on the movement 17. A through hole may be formed in the battery 16 at a place facing an antenna of the GPS. The antenna can receive radio waves with excellent sensitivity.
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2020-212195 | Dec 2020 | JP | national |
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