This application claims priority to Japanese Patent Application No. 2011-189498 filed on Aug. 31, 2011. The entire disclosure of Japanese Patent Application No. 2011-189498 is hereby incorporated herein by reference.
1. Technical Field
The present invention relates to a dial assembly and a timepiece.
2. Background Technology
Known from the past are wrist watches equipped with two dials arranged via a gap, and a movement for which an hour hand, minute hand, and second hand are supported with rotation movement (see Patent Document 1, for example). With the wrist watch noted in this Patent Document 1, an alignment pin for regulating the positional relationship (height relationship) of the two dials to each other is fixed to the movement. Specifically, with the wrist watch noted in Patent Document 1, the mutual positional relationship of the two dials is regulated via an alignment pin fixed to the movement. For that reason, the constitution is such that the size of the gap (gap length) between the two dials is fixed (unchanging).
To apply the wrist watch noted in Patent Document 1 to a chronograph having another miniature hand other than the hour hand, minute hand, and second hand, for example, there are cases of arranging the miniature hand in a gap between the two dials. However, in that case, depending on the miniature hand position (height), there are cases as described previously when the size of that gap is fixed and cannot be changed, and as a result, there is the problem that the miniature hand could not be arranged within the gap.
Japanese Laid-open Patent Application No. 2010-145206 (Patent Document 1) is an example of the related art.
An advantage of the invention is, using a simple constitution, to provide a dial assembly for which it is possible to reliably form a space in which miniature hands rotate according to the position of the miniature hands, and a timepiece equipped with that dial assembly.
Such an advantage is achieved by the invention as noted hereafter.
The dial assembly of the invention is a dial assembly held within a timepiece case together with a movement for which the hour hand and minute hand are supported to be able to rotate, which supports at least one miniature hand to be able to rotate at a position different from the hour hand and minute hand, the dial assembly including
a first dial that is light transmissive,
a second dial arranged on the back surface side of the first dial, and
at last one spacer forming a ring shape arranged between the first dial and the second dial,
wherein the miniature hand rotates within a space enclosed by the first dial, the second dial, and the spacer.
As a result, with a simple constitution, it is possible to reliably form a space for the miniature hand to rotate according to the position of the miniature hand.
With the dial assembly of the invention, preferably, the spacer has a step part of a different thickness, and the first dial is placed on that step part.
As a result, it is possible to make the dial assembly relatively thin.
With the dial assembly of the invention, preferably, with the first dial, the hour hand and the minute hand fulfill indicating functions, and
with the second dial, the miniature hands fulfill indicating functions.
As a result, it is possible to confirm the time according to the positions respectively indicated by the hour hand and minute hand. Also, when the second dial has the function of displaying the day of the week, for example, it is possible to confirm the day according to the position indicated by the miniature hand.
With the dial assembly of the invention, preferably, the movement is an item that respectively supports the two miniature hands to be able to rotate, and
the second dial includes a first display part for which one miniature hand of the two miniature hands performs indicating, and
a second display part for which the other miniature hand performs indicating.
As a result, for example it is possible to use one of either the first display part or the second display part as the 24-hour display, and to use the other as the day display.
With the dial assembly of the invention, preferably, on the first dial, on the part that the first display part faces, a first opening part is formed piercing that concerned part, and on the part that the second display part faces, a second opening part is formed piercing that concerned part.
As a result, it is possible to visually recognize the first display part and one miniature hand via the first opening part, and to visually recognize the second display part and the other miniature hand via the second opening part.
With the dial assembly of the invention, preferably, within the case, a solar battery is arranged on the back surface side of the second dial, and
the second dial is light transmissive.
As a result, the light that is transmitted through the first dial is further transmitted through the second dial, and thus, light is received by the solar battery.
The dial assembly of the invention preferably includes a ring member arranged on the front side of the first dial, and forming a ring shape along the edge part of the first dial.
As a result, for example, it is possible to add a scale to the ring member, and to use that ring member as part of a holding tab.
With the dial assembly of the invention, preferably, within the case, on the back surface side of the second dial, a solar battery having a light receiving surface for receiving light is arranged, and the light receiving surface is divided into a plurality of areas, and
at least one of the first dial, the second dial, the spacer, and the ring member has a mask part that in plan view overlaps the boundary part of adjacent areas.
As a result, it is possible to hide the boundary part, and thus, to improve the aesthetics of the timepiece.
The dial assembly of the invention preferably includes regulating means for regulating the mutual positional relationships of the first dial, the second dial, the spacer, and the movement.
As a result, it is possible to reliably mutually fix the members including the first dial, the second dial, the spacer, and the movement, and to reliably prevent them from slipping when using the timepiece.
The timepiece of the invention includes the dial assembly of the invention,
a movement for which the hour hand and minute hand are supported to be able to rotate, which supports at least one miniature hand to be able to rotate at a position different from the hour hand and minute hand, and
a case in which the dial assembly and the movement are held.
As a result, with a simple constitution, it is possible to reliably form a space for the miniature hand to rotate according to the position of the miniature hand.
With the invention, with a simple constitution, it is possible to provide a dial assembly for which it is possible to reliably form a space for the miniature hand to rotate according to the position of the miniature hand, and a timepiece in which that dial assembly is equipped.
Referring now to the attached drawings which form a part of this original disclosure:
Following, we will give a detailed description regarding preferred embodiments of the dial assembly and timepiece of the invention shown in the drawings.
The wrist watch 1 shown in
As shown in
A winding stem (not illustrated) is fit into the outer circumference part 23 of the body 2, and a crown 12 is provided to be able to rotate on the winding stem. By doing a rotation operation of the crown 12, the torque is transmitted to the movement 9. As a result, the indicator 10 is rotationally driven, and thus, it is possible to adjust the displayed time. Also, at both sides via the center axis, lugs 24 are provided as connector parts by which the band 20 is connected to the outer circumference part 23 of the body 2. The band 20 is used when wearing the watch 1 on the arm.
The cover glass 5 forms a round disk shape, and is constituted from a transparent member. Note that a “transparent member” means an item having transparency for which the visible light transmission rate is about 50% or greater. Also, “transparent” includes transparency with color (colored) in addition to colorless transparency. As the constituent material of the cover glass 5, though not specifically restricted, for example inorganic glass or the like can be used. As the constituent material of the cover glass 5, though not specifically restricted, for example inorganic glass or the like can be used. As this inorganic glass, examples include soda lime glass, borosilicate glass, Hardrex (inorganic tempered glass), Clearex (non-reflective treated), spinel glass, sapphire glass or the like. For inorganic glass, since the material strength (strength) is high, for example it is possible to reduce deformation and breaking due to pressure or impact, and to make it so that it does not scratch easily and also has good specularity. As a result, the strength of the cover glass 5 itself is high, and it is possible to improve visibility. Also, with inorganic glass, it is easily possible to perform adhesion using an adhesive agent, and thus, there is a wide range of selections of types of adhesive agent and adhesion method with which high adhesive strength can be obtained.
The back cover 3 is constituted with a round disk shaped member. It is also possible to interpose packing between the back cover 3 and the body 2. As a result, when the back cover 3 is mounted on the body 2, this packing is compressed, and it is possible to reliably maintain the air tight and liquid tight state between the back cover 3 and the body 2. As the constituent material for the body 2, the back cover 3, and the indicator 10, though not specifically restricted, examples include various metal materials such as stainless steel, titanium, and titanium alloys (including alloys), and various types of resin materials (plastic materials) and the like. Among these, metal materials are preferably used because they are excellent in terms of aesthetic aspect and strength. The body 2, the back cover 3, and the indicator 10 can be constituted using the same materials as each other, and can also be constituted using different materials.
A disk shaped movement 9 is also fixed on the back cover 3. As shown in
This movement 9 has a built in mechanism that drives (rotates) the hour hand 101, the minute hand 102, and the second hand 103 via the shaft 91, drives the 24-hour hand 104 via the shaft 92, and drives the day hand 105 via the shaft 93 using power supplied from the solar battery 70. This mechanism is not specifically restricted, but examples that can be used include an electric double layer capacitor that stores electromotive force, a lithium ion secondary battery, a quartz oscillator as a time reference source, a semiconductor integrated circuit that generates a drive pulse for driving the watch based on the oscillating frequency of the quartz oscillator, a step motor for driving the indicator each second with the train wheel mechanism that receives this drive pulse, or an item equipped with the train wheel mechanism for transmitting the movement of the step motor to the indicator.
The disk shaped (plate shaped) solar battery 70 is arranged overlapping the movement 9. The solar battery 70 is electrically connected to the movement 9, generates power by receiving light, and can supply power to the movement 9. As the solar battery 70, for example, it is possible to use an item that overlaps and joins a p type semiconductor and an n type semiconductor. The p type semiconductor is an item which has a trace amount of trivalent element such as boron mixed in a high purity level silicon semiconductor, and the n type semiconductor is an item for which a trace amount of a quinquevalent element such as arsenic is mixed in a high purity level silicon semiconductor. When light is irradiated on a solar battery 70 with this kind of constitution, electrons and positive holes are generated within the silicon interior by the photoelectric effect. Also, at the pn junction which is the boundary part of the p type semiconductor and the n type semiconductor, of the generated electrons and positive holes, the positive holes having a plus charge are separated and conducted to the p type semiconductor side, and the electrons having a minus charge are separated and conducted to the n type semiconductor side. As a result, each semiconductor is charged to plus and minus, electric potential difference is generated, and thus, it is possible to supply power to the movement 9. Note that the vicinity of the pn junction is a depletion layer.
Also, on the solar battery 70, at positions corresponding to the shafts 91 to 93 of the movement 9, insertion holes 701 in which those shafts 91 to 93 are inserted are formed (see
Also, the assembled state is maintained on the dial assembly 60. Specifically, a regulating means 15 is provided for regulating the mutual positional relationship of the ring member 4, the first dial 6, the spacer 7, the second dial 8, and the movement 9. With this regulating means 15, the ring member 4, the first dial 6, the spacer 7, the second dial 8, and the movement 9 members are reliably fixed to each other, and it is possible to reliably prevent them from slipping while the watch 1 is being used. The constitution of the regulating means 15 will be described later.
As shown in
An insertion hole 63 in which the shaft 91 of the movement 9 is inserted is formed at the center part of the main unit part 61. By inserting the shaft 91 of the movement 9 into the insertion hole 63, the hour hand 101, the minute hand 102, and the second hand 103 supported on the shaft 91 are placed on the front side of the first dial 6 (reference 2). Also, a plurality of plate piece shaped display parts (scales) 64 having the function of displaying the time indicated by the hour hand 101, the minute hand 102, and the second hand 103 are arranged on the front side surface 612 of the main unit part 61. These display parts 64 are intermittently arranged along the circumference direction of the main unit part 61, and correlate to the times “1,” “2,” “4,” “5,” “7,” “8,” “9,” “11,” and “12.” It is then possible to confirm the time by the position indicated at the respective display parts 64 by the hour hand 101, the minute hand 102, and the second hand 103.
Also, each display part 64 is respectively fixed to the main unit part 61. As this fixing method, though not specifically restricted, examples that can be used include a method using crimping, a method using fitting, a method using adhesion (adhesion using an adhesive agent or solvent) or the like. As the constituent material for each display part 64, though not specifically restricted, it is possible to us the same constituent materials as for the body 2, for example.
On the main unit part 61, a first opening part 65 is formed near the position correlating to the time “6,” a second opening part 66 is formed near the position correlating to the time “10,” and a third opening part 67 is formed near the position correlating to the time “3.” The first opening part 65, the second opening part 66, and the third opening part 67 are respectively constituted by through holes piercing the main unit part 61 in its thickness direction.
Then, the first opening part 65 forms a circle in plan view, and faces the first display part 83 of the second dial 8. Via this first opening part 65, it is possible to visually recognize the first display part 83 and the 24-hour hand 104 supported on the shaft 92 of the movement 9. The second opening part 66 forms roughly a semicircle in plan view, and faces the second display part 84 of the second dial 8. Via this second opening part 66, it is possible to visually recognize the second display part 84 and the day hand 105 supported on the shaft 93 of the movement 9.
The third opening part 67 forms a quadrangle in plan view, and faces the “date” (not shown) displayed with the movement 9. Via this third opening part 67, it is possible to visually recognize the aforementioned date. The projecting pieces 62a to 62d are arranged at equal intervals along the circumference direction of the outer circumference part of the main unit part 61. Also, the projecting pieces 62a to 62d respectively form long plate pieces along the circumference direction of the outer circumference part of the main unit part 61. Then, on the projecting pieces 62a to 62d are respectively formed deficit parts 621 midway in the lengthwise direction. Each deficit part 621 has a pin 721 of a spacer 7 described later respectively inserted therein, and together with that pin 721, is a part that becomes a portion of the regulating means 15.
As shown in
The first display part 83 constitutes a plate shaped body that forms a circle in plan view. At the center part of this first display part 83 is formed an insertion hole 831 in which the shaft 92 of the movement 9 is inserted. By inserting the shaft 92 of the movement 9 in the insertion hole 831, the 24-hour hand 104 supported on the shaft 92 is placed on the front side of the first display part 83. On the front side surface 832 of the first display part 83, a rib 833 forming a ring shape is formed projecting along the circumference direction. The numbers “1” to “24” (not shown) are respectively attached on this rib 833. It is possible to confirm the time by the 24-hour hand 104 (one of the miniature hands) indicating any of these numbers.
The second display part 84 is constituted by a plate shaped body forming a semicircle in plan view. At the center of the arc of this second display part 84 is formed an insertion hole 841 in which is inserted the shaft 93 of the movement 9. By the shaft 93 of the movement 9 being inserted in the insertion hole 841, the day hand 105 supported on the shaft 93 is placed on the front surface of the second display part 84 (see
As shown in
The projecting pieces 82a to 82d respectively form long plate pieces along the circumference direction of the outer circumference part of the main unit part 81. Then, on the projecting pieces 82a to 82d are respectively formed deficit parts 821 midway in the lengthwise direction. In the deficit part 821 of the projecting piece 82a is inserted the pin 95a fixed to the movement 9, in the deficit part 821 of the projecting piece 82b is inserted the pin 95b fixed to the movement 9, in the deficit part 821 of the projecting piece 82c is inserted the pin 95d fixed to the movement 9, and in the deficit part 821 of the projecting piece 82d is inserted the pin 95d fixed to the movement 9. As a result, the positional relationship of the second dial 8 and the movement 9 is regulated. In this way, each deficit part 821 is respectively a part that becomes part of the regulating means 15.
As shown in
The first step parts 72a to 72d are respectively parts for which the spacer 7 thickness differs, in other words is decreased (lowered) by the thickness amount of the first dial 6. Then, the projecting piece 62a of the first dial 6 can enter (be placed) at the first step part 72a, the projecting piece 62b can enter at the first step part 72b, the projecting piece 62c can enter at the first step part 72c, and the projecting piece 62d can enter at the first step part 72d. As a result, by the front side surface 612 of the first dial 6 and the front side surface 71 of the spacer 7 being placed on the same surface, the dial assembly 60 is made thinner.
Also, pins 721 are formed projecting respectively at the first step parts 72a to 72d. The pin 721 of the first step part 72a is fit into (inserted in) the deficit part 621 of the projecting piece 62a of the first dial 6, the pin 721 of the first step part 72b is fit into the deficit part 621 of the projecting piece 62b, the pin 721 of the first step part 72c is fit into the deficit part 621 of the projecting piece 62c, and the pin 721 of the first step part 72d is fit into the deficit part 621 of the projecting piece 62d. As a result, the positional relationship of the first dial 6 and the spacer 7 is regulated.
The second step parts 73a and 73b are respectively parts for which the thickness of the spacer 7 changes by the amount of the projecting parts 43a and 43b of the ring member 4 described later. The projecting part 43a of the ring member 4 is inserted in the second step part 73a, and the projecting part 43b of the ring member 4 is inserted in the second step part 73b. Also, pins 731 are respectively formed projecting at the second step parts 73a and 73b. Each pin 731 is respectively fit into the recess part (guide hole) 431 of the projecting parts 43a and 43b of the ring member 4, and functions together with each recess part 431 as part of the regulating means 15.
As shown in
As constituent materials for the spacer 7 and the ring member 4, though not specifically restricted, for example it is possible to use various metal materials or various resin materials. As shown in
As shown in
Also, a recess part 431 for which a part is depressed is formed respectively on the projecting parts 43a and 43b. Then, on each recess part 431, the pin 731 is fit onto the respective step parts 73a and 73b of the spacer 7. As a result, the positional relationship between the ring member 4 and the spacer 7 is regulated. As described previously, the positional relationship of the first dial 6 and the spacer 7 is regulated, and the positional relationship of the spacer 7 and the movement 9 is also regulated. Furthermore, the positional relationship of the ring member 4 and the spacer 7 is also regulated. In this way, via the spacer 7, the positional relationship of the first dial 6, the ring member 4, and the movement 9 is regulated collectively.
Also, as described previously, the positional relationship of the second dial 8 and the movement 9 is also regulated. Therefore, with the watch 1, the ring member 4, the first dial 6, the spacer 7, the second dial 8, and the movement 9 members are in a state reliably fixed to each other by the regulating means 15. As a result, these members slipping during use of the watch 1 is reliably prevented.
With the dial assembly 60 in an assembled state aligned as described above, as shown in
In this way, with the watch 1, with a simple constitution overlapping and assembling the first dial 6, the second dial 8, and the spacer 7, it is possible to reliably form the space 601 in which the 24-hour hand 104 and the day hand 105 can rotate. Also, the formed space 601 is of a size according to the position of the 24-hour hand 104 and the day hand 105. Specifically, if the 24-hour hand 104 and the day hand 105 are positioned at the same height, it is possible to have a dial assembly 60 with one spacer 7 placed as shown by the constitution in the drawing (this embodiment). In contrast to the constitution in the drawing, it is also possible to have a dial assembly 60 with a plurality of spacers 7 placed overlapping when one of the 24-hour hand 104 and the day hand 105 is at a position higher than the other. As a result, it is possible to expand the size of the space 601.
Other than that the ring member constitution is different, this embodiment is the same as the first embodiment. As shown in
Also, with the solar battery 70, the light receiving surface 702 on which light irradiated from the front surface is received is divided into a plurality of areas (four with the constitution shown in
With this embodiment, the “mask part” is provided on the ring member 4A, but the invention is not limited to this, and for example it is also possible to provide it on at least one of the first dial 6, the second dial 8, the spacer 7, and the ring member 4A. Above, we described the dial assembly and watch of the invention with the embodiments in the drawings, but the invention is not limited to these, and each part constituting the dial assembly and the watch can be substituted with items of any constitution for which similar functions can be exhibited. It is also possible to add any structural items.
Also, the dial assembly and the watch of the invention can also be items for which any two or more of the constitutions (characteristics) of the aforementioned embodiments are combined. Also, with the second dial, the first display part and the second display part have mutually the same position in the thickness direction of the second dial with each of the embodiments, but the invention is not limited to this, and for example it is also possible to have mutually different positions in the thickness direction of the second dial.
Number | Date | Country | Kind |
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2011-189498 | Aug 2011 | JP | national |