The present invention is related to a watch.
Conveniently, watches each including a curved dial and plural hand axes are known.
The patent document 1 described below discloses a wristwatch in which a hand axis of a main hand and a hand axis of a sub-hand are arranged in parallel and in which a curved dial and the sub-hand are not in parallel to each other.
The wristwatch described in the patent document 1 has a characteristic beauty presented by a curved case, but can cause an unnatural appearance because the rotational plane of the hand and the dial surface are not in parallel. For the problem, making the axis of the hand inclined in conformity with the dial surface might be effective. However, it is very difficult to arrange, in a narrow space, a mechanism that transmits movement power between rotational axes disposed at different inclinations. Even if the mechanism is built, it will significantly increase the manufacturing cost of product.
In view of such problems of the prior art as mentioned above, an object of the present invention is to provide a watch (portable timepiece) that enables an easy manufacturing and includes a hand having a rotational axis thereof along a direction inclined in conformity with the dial surface.
An invention disclosed in the present application for solving the problem described above has various aspects. A summary of typical aspect of those is as follows.
(1) A watch comprises: a first drive mechanism that includes a hand having a rotational axis along a first direction, a wheel train, and a drive power source; and a second drive mechanism that includes a hand having a rotational axis along a second direction different from the first direction, a wheel train, and a drive power source, wherein the first drive mechanism and the second drive mechanism are mounted separately.
(2) In an aspect of (1), each of the first direction and the second direction is defined along a normal direction to a dial at a position of the rotational axis of the hand.
(3) In an aspect of (1) or (2), each of the first drive mechanism and the second drive mechanism is configured to be independently and integrally mounted on, and removed from, the watch.
(4) An aspect of (3) further comprises a main plate including a first attachment surface and a second attachment surface having different orientations from each other, wherein the first drive mechanism is fixed such that a standard surface thereof is in contact with the first attachment surface, and the second drive mechanism is fixed such that a standard surface thereof is in contact with the second attachment surface.
(5) In an aspect of (4), the main plate includes at least a first recess and a second recess, a bottom surface of the first recess is the first attachment surface, and a bottom surface of the second recess is the second attachment surface.
(6) In an aspect of (5), the first recess and the second recess include wall surfaces that are formed in parallel to a common direction or formed like a taper inclined from a common direction.
(7) In an aspect of (5) or (6), the first recess and the second recess are formed on surfaces of the main plate opposite to each other.
(8) In an aspect described in anyone of (1) to (6), the main plate further includes a battery accommodating portion that is a recess, and a battery disposed inside the battery accommodating portion is fixed in a posture inclined from the thickness direction of the watch.
(9) In an aspect of (6) or (7), the main plate further includes a battery accommodating portion that is a recess, a battery disposed inside the battery accommodating portion is fixed in a posture inclined from the thickness direction of the watch, and the battery accommodating portion includes a wall surface that is formed in parallel to the common direction or formed like a taper inclined from the common direction.
(10) An aspect of (8) or (9) further comprises: a first battery pressing member located on a near side when viewed from an opening side of the battery accommodating portion, located at a circumferential position thereof, and supporting an upper surface of the battery; and a second battery pressing member located on a far side when viewed from the opening side of the battery accommodating portion, and pressing a lateral side surface of the battery.
(11) The potable watch described in anyone of (8) to (10) further comprises a tongue-like electrode including a linear distal edge that is oblique from an extending direction thereof and is in elastic contact with a lower surface of the battery.
(12) In an aspect of anyone of (1) to (11), the first drive mechanism and the second drive mechanism include circuit boards, respectively, and the circuit board of the first drive mechanism and the circuit board of the second drive mechanism are connected to each other through a FPC (Flexible Printed Circuit).
(13) In an aspect of (12), the circuit board of the first drive mechanism and the circuit board of the second drive mechanism include connection terminals, respectively.
The aspect of (1) of the present invention provides a watch that enables an easy manufacturing and includes a hand having a rotational axis thereof along a direction inclined in conformity with the dial surface.
The aspect of (2) of the present invention provides a watch that prevents an interference between the hand and the dial and that increases freedom in the arrangement of the hand and in the design of the hand.
The aspect of (3) of the present invention provides a watch that is easily manufactured by a process in which the unified drive mechanisms are assembled.
The aspect of (4) of the present invention provides a watch in which the inclination angles of the drive mechanisms are accurately fixed.
The aspect of (5) of the present invention provides a watch that enables an easy assembling and is a thin type.
The aspect of (6) of the present invention provides a watch a main plate of which enables an easy injection molding.
The aspect of (7) of the present invention provides a watch that includes a sub-hand at a position overlapping with a winding stem.
The aspect of (8) of the present invention enables the battery to be disposed inside the main plate and along the curvature of the main plate, which makes a wristwatch be a thin type.
The aspect of (9) of the present invention provides a watch which not only enables the battery to be disposed inside the main plate and to be arranged along the curvature of the main plate and makes the wristwatch be a thin type, but also enables the main plate to facilitate an injection molding.
The aspect of (10) of the present invention enables the battery to be stably fixed and ensures an electrical conductivity to the battery, in a watch including an inclined dial surface.
The aspect of (11) of the present invention provides a watch that not only enables an electrode thereof to be in line contact with an accommodated and inclined battery and stabilizes an electric conductivity, but also prevents a damage due to a torsion force.
The aspect of (12) of the present invention provides a watch in which the drive mechanisms are stably fixed and which includes circuit boards easily mounted in a curved surface.
The aspect of (13) of the present invention provides a watch in which each drive mechanism has a stable ground potential provided thereto.
Hereinafter, embodiments according to the present invention will be described with reference to the drawings.
In the wristwatch 1, a wind shield made of a transparent material such as glass is attached to the body 6, covering the dial 2. Further, a back lid on the side opposite to the wind shield is attached to the body 6. In the present specification, the side on which the wind shield of the wristwatch 1 is disposed will be hereinafter referred to as “front side”, and the side on which the back lid is disposed will be hereinafter referred to as “back side”.
The dial 2 in the present embodiment is gently curved bulging toward the front side. The body 6 is also curved like the dial 2 and thus has a shape to conform to the curvature of the user's arm when the wristwatch 1 is worn on the arm.
The design of the wristwatch 1 shown in
The wristwatch 1 according to the present embodiment includes the first drive mechanism 10 including a hand having the rotational axis A along the first direction, a wheel train and a drive power source, and includes the second drive mechanisms 20 including a hand having the rotational axis B along the second direction different from the first direction, a wheel train and a drive power source. The first drive mechanism 10 and the second drive mechanisms 20 are mounted separately on the wristwatch 1. The first drive mechanism 10 includes the first hand shaft 11 that is the hand axis of the hour hand 3a and the minute hand 3b. The first hand shaft 11 is driven by the drive power source via the wheel train in the first drive mechanism 10. The second drive mechanism 20 includes the second hand shaft 21 that is the hand axis of the first sub-hand 4a. The second hand shaft 21 is driven via the wheel train by the drive power source of the second drive mechanism 20 that is independent of the drive power source of the first drive mechanism 10. The hands (that is, the hour hand 3a and the minute hand 3b) of the first drive mechanism 10 and the hand (that is, the first sub-hand 4a) of the second drive mechanism 20 are mounted to a common dial surface. That is, the hands of the first drive mechanism 10 and the hand of the second drive mechanism 20 are not mounted to plural dial surfaces, respectively, but mounted to a common dial surface so that a user is allowed to simultaneously see the hands of the first drive mechanism 10 and the hand of the second drive mechanism 20.
A structure in which the first drive mechanism 10 for driving the hour hand 3a and the minute hand 3b and the second drive mechanism 20 for driving the first sub-hand 4a are composed separately from one another eliminates necessity for a mechanism that transmits power to the plural hand axes that have different orientations, and thus provides the watch in which the rotational axes of the hands are inclined in conformity with the dial surface while facilitating the manufacturing of the watch. The structure in which the drive mechanisms are separated for the plural hand axes is beneficial especially for electrical watches, whereas the structure is difficult to be mounted in mechanical watches, which are difficult to include plural drive power sources.
As described above, each of the first direction (the direction along the rotational axis A) and the second direction (the direction along the rotational axis B) is defined along the normal direction to the dial 2. Though the dial 2 is omitted from the cross-sectional view of
Since the first direction and the second direction is respectively defined along the normal lines that is perpendicular to the dial 2 and that is located at the positions of the rotational axes of the hands, the hand axes 11, 21 are defined substantially perpendicular to the dial 2 and thus each of the plural hands is arranged substantially in parallel to the dial. Therefore, the hands and the dial are prevented from causing an interference therebetween, and freedom in arrangement of the hands and freedom in design thereof can be improved.
Each of the first drive mechanism 10 and the second drive mechanism 20 is configured to be independently and integrally mounted to, removed from, the wristwatch 1 according to the present embodiment. Each of the first drive mechanism 10 and the second drive mechanism 20 is a unit component that operates individually. Accordingly, the wristwatch 1 can be easily manufactured by combining the drive mechanisms each unified. The structure related to the benefit mentioned here will be described in detail with reference to
The wristwatch 1 according to the present invention includes a main plate 30 including a first attachment surface 31a and second attachment surfaces 32a that have different orientations from each other. The first drive mechanism 10 is fixed such that the standard surface thereof is in contact with the first attachment surface 31a. The standard surface of the first drive mechanism 10 is a flat surface formed on a side opposite to a side from which the first hand shaft 11 projects. The second drive mechanisms 20 are fixed such that the standard surfaces thereof are in contact with the second attachment surfaces 32a. The standard surface of the second drive mechanism 20 is a flat surface formed on a side from which the second hand shaft 21 projects.
Each of the first attachment surface 31a of the main plate 30 and the standard surface of the first drive mechanism 10 according to the present embodiment is a flat surface. Accordingly, attaching the first drive mechanism 10 to the main plate 30 to make the two surfaces be in contact with each other enables the inclination angle of the first drive mechanism 10 to be accurate. Further, each of the second attachment surface 32a of the main plate 30 and the standard surface of the second drive mechanism 20 is a flat surface, and thus attaching the second drive mechanism 20 to the main plate 30 to make the two surfaces thereof be in contact with each other enables the inclination angle of the second drive mechanism 20 to be accurate. The first attachment surface 31a and the second attachment surface 32a are formed in the main plate 30, being inclined from each other by the angle θ. Therefore, when the first drive mechanism 10 is fixed such that the first attachment surface 31a and the standard surface of the first drive mechanism 10 are in contact with each other and when the second drive mechanisms 20 are fixed such that the second attachment surfaces 32a and the standard surfaces of the second drive mechanisms 20 are in contact with each other, the angle θ is made between the rotational axis A and the rotational axis B and between the rotational axis A and the rotational axis C. If the first attachment surface 31a and the second attachment surfaces 32a described above are not formed on the main plate 30 and thus the inclination angle of the first drive mechanism 10 and the inclination angles of the second drive mechanisms 20 need to be adjusted in the manufacturing process, it is necessary for a manufacture to attach the first drive mechanism 10 and the second drive mechanisms 20 to the main plate 30 such that each of the first hand shaft 11 and the second hand shafts 21 is perpendicular to the dial 2 (or the first support plate 40) and such that the angles θ are secured between the rotational axis A and the rotational axis B and between the rotational axis A and the rotational axis C, which complicates the manufacturing process. Contrary to that, in the wristwatch 1 according to the present embodiment, it is not necessary to adjust the inclination angles when the first drive mechanism 10 and the second drive mechanisms 20 are attached to the main plate 30, which facilitates the manufacturing process. Note that, the first attachment surface 31a, the standard surface of the first drive mechanism 10, the second attachment surface 32a, and the standard surface of the second drive mechanism 20 may not be flat surfaces and may be surfaces having a projection and a recess fitting to each other.
The main plate 30 according to the present embodiment includes at least a first recess 31 and second recesses 32. The bottom surface of the first recess 31 is the first attachment surface 31a. The bottom surface of the second recess 32 is the second attachment surface 32a. The first drive mechanism 10 is disposed inside, and attached to, the first recess 31 of the main plate 30. The second drive mechanism 20 is disposed inside, and attached to, the second recess 32 of the main plate 30. As the first drive mechanism 10 is disposed inside the first recess, the standard surface of the first drive mechanism 10 is in contact with the bottom surface (the first attachment surface 31a) of the first recess 31. Further, as the second drive mechanism 20 is disposed inside the second recess 32, the standard surface of the second drive mechanism 20 is in contact with the bottom surface (the second attachment surface) of the second recess 32.
The structure in which the first drive mechanism 10 and the seconds drive mechanisms 20 are disposed inside the first recess 31 and the second recesses 32, respectively, reduces the thickness thereof and makes the thickness of the whole wristwatch 1 smaller than that in a structure where the first drive mechanism 10 and the seconds drive mechanisms 20 are disposed on a flat main plate. Further, the first recess 31 and the second recesses 32 indicate the attachment positions and the attachment direction of the first drive mechanism 10 and the second drive mechanisms 20, which facilitates the manufacturing process.
The first recess 31 and the second recesses 32 include wall surfaces formed in parallel to a common direction or formed like a taper inclined from a common direction. More specifically, the first recess 31 includes a first wall surface 31b formed like a taper inclined from the first direction (the direction along the rotational axis A). Further, the second recess 32 includes a second wall surface 32b formed like a taper inclined from the first direction (the direction along the rotational axis A). The first wall surface 31b has a taper the internal dimension of which becomes wider toward the front side. The second wall surface 32b has a taper the internal dimension of which becomes wider toward the back side.
If the wall surface of the first recess 31 and the wall surface of the second recess 32 are formed perpendicular to the attachment surfaces (that is, the first attachment surface 31a and the second attachment surface 32a), difficulty is caused in the manufacturing process because it is difficult for dies to be removed from the molded main plate 30 in injection molding. Contrary to that, the structure in which the first recess 31 and the second recess 32 include the wall surfaces formed in parallel to the common direction or formed like a taper inclined from the common direction enables removing the dies from the molded main plate 30 in the same common direction. Therefore, it is possible to manufacture the main plate 30 by injection molding, which improves productivity for the main plate 30 to reduce the cost and the time necessary in manufacturing the main plate 30. The first recess 31 and the second recesses 32 that include the wall surfaces formed as tapers having so-called drafts inclined from the common direction facilitate the injection molding.
In the main plate 30 according to the present embodiment, the first recess 31 and the second recesses 32 are formed on sides of the main plate 30 opposite to each other. More specifically, the first recess 31 is formed on the front side of the main plate 30. The second recesses 32 are formed on the back side of the main plate 30. This structure will be described in detail with reference to
As shown in
Since the first drive mechanism 10 is a unit component independent of the other components, the drive mechanism 10 is allowed to be used in another watch. Further, the first drive mechanism 10 can be independently subject to a performance test, and a defective drive mechanism can be excluded before it is mounted in a watch, which improves a product yield rate of the watch 1 efficiently.
The battery accommodating portion 26 has a negative electrode 26a located at a deep position thereof. The negative electrode 26a becomes in contact with the anode surface of the battery inside the battery accommodating portion 26 to make an electrical connection. In the present embodiment, the negative electrode 26a is formed of a tongue-like metal plate that is bent at an angle toward the near side from the far (deep) side inside the battery accommodating portion 26. Thus, when a battery is placed inside the battery accommodating portion 26, the negative electrode 26a is pressed to, and is elastically in contact with, the anode of the battery. The negative electrode 26a includes a distal edge that is not perpendicular to the extending direction of the negative electrode 26a, but is linear and oblique from the extending direction.
The reason is that since the wristwatch 1 itself is curved, the battery is disposed inside the battery accommodating portion 26, being inclined from the thickness direction of the wristwatch 1 (that is, the direction from the front side to the back side of the wristwatch 1). According to the example shown in
The first drive mechanism 10 and the second drive mechanisms 20 include a first circuit board 15 and second circuit boards 22, respectively. The first circuit board 15 and the second circuit board 22 are connected to each other through a FPC (Flexible Printed Circuit) 23. Each of the first circuit board 15 and the second circuit boards 22 is a so-called rigid circuit board and has such rigidity as to hardly bend even when receiving a force. Whereas, the FPC 23 has flexibility and is allowed to bend. The first circuit board 15, the second circuit boards 22, and the FPC 23 as whole constitute a so-called rigid flexible printed wiring board.
If a single rigid circuit board constitutes a circuit board of the first drive mechanism 10 and the second drive mechanisms 20, it is difficult that the circuit board is mounted in the curved body 6 without an unnecessary space inside there, which causes an unutilized space inside the body 6 and thus unnecessarily increases the thickness of the watch. On the other hand, if a flexible printed circuit constitutes the whole of the first circuit board 15 and the second circuit boards 22, the first drive mechanism 10 and the second drive mechanisms 20, which are inclined from each other, are not stably fixed in position and would need a troublesome process in assembling the components. Unlike the structures described above, employing the first circuit board 15 and the second circuit boards 22 connected through the FPC 23 as seen in the wristwatch 1 according to the present embodiment enables the circuit boards to be arranged inside the curved body 6 without causing unnecessary spaces, while stably fixing the first drive mechanism 10 and the second drive mechanisms 20 at appropriate inclination angles, respectively.
Each of the first circuit board 15 and the second circuit boards 22 includes a ground terminal 24. Providing the ground terminal 24 to each drive mechanism, that is, providing the ground terminals 24 for the stepping motors respectively, enables each drive mechanism to have a stable ground potential. This stabilizes voltages supplied to the motor driving IC's included in the first circuit board 15 and the second circuit boards 22 and thus improves tolerance against, for example, change in static electricity. The first circuit board 15 and the second circuit boards 22 include connection terminals (not shown in the figures) for transmitting signals to the stepping motors on the sides opposite to the ground terminals 24 each formed on the first circuit board 15 and the second circuit boards 22 (that is, the stepping motors on the surfaces opposite to the surfaces on which the ground terminals 24 are disposed respectively). Each ground terminal 24 is electrically grounded by fixing the second support plate 41 to the main plate 30 by a screw. When the second support plate 41 is fixed to the main plate 30, the circuit boards are pressed to the stepping motors to make the electrical connections between the stepping motors and the connection terminals. The structure described above enables the grounding of the circuit board and the electrical connection between the circuit board and the stepping motor to be simultaneously built.
Since the second drive mechanism 20 is a unit component independent of the other components, the drive mechanism is allowed to be used in another watch. Further, the second drive mechanism 20 can be independently subject to a performance test and a defective drive mechanism can be excluded before it is mounted in a watch, which improves a product yield rate of the watch efficiently.
The wristwatch 1 according to the present embodiment is assembled by the following processes. First, the first drive mechanism 10 is disposed inside the first recess 31 of the main plate 30. Then, the first support plate 40 is provisionally fixed to the main plate 30 to press the first drive mechanism 10. The first support plate 40 may include a hook and may be provisionally fixed to the main plate 30 with the hook caught on the main plate 30. This prevents the first drive mechanism 10 from being removed from the first recess 31 and thus allows the main plate 30 to be overturned for a next manufacturing process.
Next, the second drive mechanisms 20 are disposed inside the second recesses 32 of the main plate 30. Then, the first circuit board 15, the second circuit boards 22, and the FPC's 23 are mounted on the main plate 30. The second support plate 41 is fixed to the main plate 30 with a screw, while covering the first circuit board 15, the second circuit boards 22, and the FPC's 23. After that, the first support plate 40, which has been provisionally fixed to the main plate 30, is fixed to the main plate 30 with a screw. Further, the third support plate 42 for enveloping the internal structure is fixed to the main plate 30 with a screw, covering the second support plate 41.
The battery 26b is disposed inside the battery accommodating portion 26, being inclined such that a portion thereof toward the 6 o'clock position subsides when the front side of the watch is viewed. A perpendicular line to a flat surface of the battery 26b (that is, the anode surface or the cathode surface thereof is substantially in parallel with the rotational axis C. The incline of the battery 26b enables the battery 26b to be disposed inside the main plate 30 in conformity with the curvature of the main plate 30 and contributes toward thinning the wristwatch 1 down. For example, for the structure in which the main plate 30 curves from the 12 o'clock to 6 o'clock direction and the first drive mechanism 10 is located spreading between the 3 o'clock position and the 9 o'clock position, it is preferable for reducing the thickness of the wristwatch 1 that the battery 26b is arranged causing no interference with the first drive mechanism 10. Since the position of the battery is inclined from the thickness direction of the wristwatch 1 due to the curvature of the main plate 30, inclining the battery 26b in conformity with the incline of the main plate 30 reduces the thickness of the wristwatch 1. Further, for the structure in which the second drive mechanisms 20 are located in the 12 o'clock position and the 6 o'clock position as shown in the present embodiment, it is preferable that the battery 26b is arranged causing no interference with the second drive mechanisms 20. With this regard, the battery 26b may be disposed at a position between the 12 o'clock position and the 3 o'clock position, at a position between the 3 o'clock position and the 6 o'clock position, at a position between the 6 o'clock position and the 9 o'clock position, or at a position between the 9 o'clock position and the 12 o'clock position. In the present embodiment, the battery 26b is disposed at the position between the 6 o'clock position and the 9 o'clock position.
The battery 26b is elastically fixed in the battery accommodating portion 26 by a first battery pressing member 26c and the second battery pressing member 26d not so as to be removed therefrom. The first battery pressing member 26c is a metal plate located on the cathode surface of the battery and supporting a portion of a peripheral portion of the cathode surface. In the present embodiment, when viewed in
The battery accommodating portion 26 is a recess formed in the main plate 30, and includes an accommodating portion wall 26e formed in parallel to a common direction or formed like a taper inclined from a common direction. The common direction described here is identical to the common direction for the first recess 31 and the second recess 32. In the present embodiment, the common direction corresponds to the first direction (that is, the direction along the rotational axis A). Accordingly, the battery accommodating portion 26 includes the accommodating portion wall 26e formed like a taper inclined from the first direction (that is, the direction along the rotational axis A). Since the battery accommodating portion 26 opens toward the back side of the watch, the accommodating portion wall 26e, which is formed like a taper, is formed such that the battery accommodating portion 26 widens toward the back side. Like the taper of the first recess 31 and the second recess 32 described above, the taper of the accommodating portion wall 26e is a so-called draft angle for injection molding of the main plate 30. The accommodating portion wall 26e formed like a taper inclined from the common direction facilitates the injection molding of the main plate 30.
The battery accommodating portion 26 includes an accommodating portion bottom 26f. The battery 26b is fixed such that the anode surface (flat surface) is in contact with the accommodating portion bottom 26f. Each the anode surface of the battery 26b and the accommodating portion bottom 26f is a flat surface. Further, when the battery 26b is disposed inside the battery accommodating portion 26, the anode surface thereof is fixed in contact with the accommodating portion bottom 26f. Accordingly, the inclination angle of the battery 26b corresponds to the inclination angle of the accommodating portion bottom 26f. In this situation, the second battery pressing member 26d is preferably located at a far (low) position in a view from the back side of the watch (that is, in a view from the opening of the battery accommodating portion 26) in the inclined direction of the battery 26b. That is, the second battery pressing member 26d is preferably located at a near position in a view from the front side of the watch. The second battery pressing member 26d at the position presses the side surface of the battery 26b. The first battery pressing member 26c is preferably located at a near position in a view from the back side of the watch 1 (that is, a far (deep) position in a view from the front side of the watch) in the inclined direction of the battery 26b, and supports the cathode surface of the battery 26b.
The reason for the above arrangement will be described with reference to
In the example of the present embodiment, the farthest position within the battery 26b in a view from the back side of the watch is located at the 12 o'clock position, and accordingly the position of the second battery pressing member 26d is preferably defined in a half circumferential area of the battery 26b toward the 12 o'clock position, that is, defined in an area ranging from the 9 o'clock position to the 3 o'clock position through the 12 o'clock position. The closer to the 12 o'clock position the second battery pressing member 26d is located, the higher the benefit that the battery 26b is stably fixed and that the electrical connection to the cathode is reliable is. The position of the first battery pressing member 26c is preferably defined in a half circumferential area of the battery 26b toward the 6 o'clock position, that is, defined in an area ranging from the 3 o'clock position to the 9 o'clock position through the 6 o'clock position. In the present embodiment, the second battery pressing member 26d is located between the 10 o'clock position and the 11 o'clock position, and the first battery pressing member 26c is located opposite thereto and between the 4 o'clock position and the 5 o'clock position.
An embodiment according to the present invention have been described above. However, the specific structure shown in this embodiment is described as an example of the present invention, and thus the scope of the present invention is not limited to this structure. For example, in the wristwatch 1 according to the present embodiment, the body 6, the dial 2, etc. curves gradually. However, the dial 2 may be bent at an obtuse angle. In this structure, the dial 2 may include plural flat surfaces in the single dial surface thereof and the hands may be provided on the flat surfaces, respectively. A wristwatch has been described as the embodiment. However, the same structure may also be applied to other watches such as a pocket watch etc. A skilled person in the art may appropriately modify the described embodiment. The scope of the invention disclosed in the present specification should be understood as including the modifications.
Number | Date | Country | Kind |
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2015-188338 | Sep 2015 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/052493 | 1/28/2016 | WO | 00 |