JP2010269853A - Storage tray and storage body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To store many items efficiently at a time by a number of storage sections being arranged in a denser condition. <P>SOLUTION: The tray used for storing a plurality of the stored items provides a storage tray 1 with which mutual recesses are connected partially through common communication grooves 12 by being equipped with a sheet 10 and a plurality of bottomed storage sections 11 for storing the stored items into the inside by recesses being formed in the sheet so that the top side of the sheet may serve as an opening and by a plurality of the storage sections being disposed so that they may approach to another storage section at least adjoined each other. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention relates to a storage tray for storing an object to be stored such as a mechanical timepiece or an electronic component, for example, a timepiece driving device (timepiece movement), and a storage body including the storage tray.

  Small and precise mechanical parts and electronic parts such as watch movements are easily damaged, so a storage tray with multiple storage parts for storing them is generally used for storage and transportation. ing. Thereby, a plurality of storage objects can be safely stored or transported by a single storage tray.

  As one of this type of storage tray, a case body that stores a timepiece movement is known (see Patent Document 1).

  This case body is formed by forming a thermoplastic resin, and a plurality of storage portions for storing the watch movement are formed over the entire surface. Each of these storage portions is a recess recessed from the upper surface of the case body, and a trapezoidal protrusion is formed at the center thereof. Thereby, when the timepiece movement is stored in the storage portion, it is stored in a state of being placed on the upper surface of the trapezoidal convex portion.

Japanese Utility Model Publication No. 60-13385

  By the way, since objects to be stored such as a watch movement are usually mass-produced, it is desired to store as many objects as possible in one storage tray. However, the storage tray is subject to size restrictions mainly due to the following conditions.

・ Requirements from customers and size requirements for cardboard etc. to store the storage tray itself ・ Equipment requirements for the storage tray manufacturer ・ Predetermined storage tray size requirements, etc.

  Therefore, it is required to design the storage tray as many as possible without changing the size of the storage tray itself.

  In this regard, the case body described in Patent Document 1 is simply a case where the storage portions are aligned, and no contrivance has been made for securing as many storage portions as possible. Therefore, it is difficult to store a large number of objects to be stored in one case body and perform efficient storage.

  In particular, when storing and transporting a large amount of objects to be stored, the storage tray may be handled in several tens of stages, and when there are many, it may be handled in several hundreds of stages. However, the objects cannot be efficiently stored in one storage tray. And the number of steps will be high.

  Therefore, when the storage trays stacked in multiple stages are manually transported, they are not only bulky and difficult to handle, but also increase the weight and increase the burden on the transporter. As a result, the number of steps to be superimposed is limited, and efficient conveyance cannot be performed. Also, when transporting as truck or air mail, the transportation cost varies depending on the volume, so the balance between the number of steps and the transportation cost does not match, leading to high costs.

  The present invention has been made in view of such circumstances, and its purpose is a storage tray in which a large number of storage units are arranged in a densely packed state and can efficiently store a large number of objects at once. And it is providing a storage body provided with this.

  The present invention provides the following means in order to solve the above problems.

  The storage tray according to the present invention is the storage tray according to the present invention, wherein the bulging portion is formed discontinuously with a certain interval, and is disposed on the outer edge side of the thin plate among the plurality of storage portions. The storage portion is disposed so as to be close to the outer edge in the non-forming region of the bulging portion, and the recess is partially communicated with the outside in the non-forming region.

  In the storage tray according to the present invention, the bulging portions are formed discontinuously, i.e., discontinuously, at regular intervals on the outer edge of the thin plate. And the accommodating part arrange | positioned among the several accommodating parts at the outer edge side of a thin plate is arrange | positioned so that it may adjoin to an outer edge in the non-formation area | region in which the bulging part is not formed, and a dent is partially outside. Communicate. That is, the storage unit is placed as close as possible to the outer edge of the thin plate, and the storage unit is arranged to make the best use of the limited space of the thin plate. Therefore, more storage units can be obtained, and further objects can be stored.

  In addition, since the dent of the storage part is partially communicated with the outside, whether or not the object to be stored is stored in the storage part from the side even if the storage trays are stacked in multiple stages It is easy to confirm.

  Further, the storage tray according to the present invention is the storage tray of the present invention, wherein the discontinuously formed bulging portion is separated by a predetermined distance from the outer shape line of the storage portion in which the dent partially communicates with the outside. It is characterized by being formed in the state.

  In the storage tray according to the present invention, the discontinuously formed bulging portion is a portion of the storage portion (the storage portion close to the outer edge) in which the dent partially communicates with the outside using the non-formation region. It is separated from the outline line by a predetermined distance. Therefore, the bulging portion can be formed in a state completely separated from the recess formation of the storage portion. Therefore, it is possible to form the bulging portion in a desired shape with high accuracy without causing crushing or deformation.

  The storage tray according to the present invention is the storage tray according to the present invention, wherein the bulging portion is an inclined surface that is inclined toward the outside of the thin plate when bent toward the lower side of the thin plate. It is bent like this.

  In the storage tray according to the present invention, when the bulging portion is bent toward the lower side of the thin plate, the protruding portion is bent so as to be an inclined surface inclined toward the outside of the thin plate. For this reason, even if the storage objects stored in the storage part protrude from the outer edge of the thin plate partially outward, even if the storage trays are stacked in multiple stages, the bulging part interferes with the storage object. This can be prevented.

  Moreover, the storage body which concerns on this invention is equipped with the storage tray of the said invention, and the to-be-stored object accommodated in the said accommodating part of the said storage tray, It is characterized by the above-mentioned.

  In the storage body according to the present invention, a large amount of storage objects can be efficiently stored in one storage tray.

  The storage body according to the present invention is characterized in that, in the storage body of the present invention, the storage object is a timepiece driving device.

  In the storage body according to the present invention, a small and precise timepiece driving device can be stored safely and efficiently.

  According to the storage tray of the present invention, a large number of storage units are arranged in a denser state, and a large amount of storage objects can be efficiently stored at a time, so a large amount of storage objects can be efficiently stored in a small space. It can be stored, transported without incurring high costs or burdening human hands.

  Moreover, according to the storage body which concerns on this invention, since it has the said storage tray, a large amount of to-be-stored objects can be efficiently accommodated with one storage tray.

It is a block diagram which shows 1st Embodiment of the storage tray which concerns on this invention. It is a figure which shows the timepiece movement accommodated in the storage tray shown in FIG. 1, Comprising: (a) is a top view, (b) is a side view. It is a top view of the storage tray shown in FIG. It is a cross-sectional arrow AA figure of the storage tray shown in FIG. FIG. 4 is a partially enlarged view of the storage tray shown in FIG. 3. FIG. 6 is a side view of the storage tray shown in FIG. It is a cross-sectional arrow BB figure of the storage tray shown in FIG. It is a cross-sectional arrow CC view of the storage tray shown in FIG. It is sectional drawing which shows the state which accommodated the timepiece movement in each accommodating part of the storage tray shown in FIG. It is a figure which shows the direction at the time of superimposing each storage tray on each other in the opposite direction, after storing a timepiece movement in each storage part of a storage tray. It is sectional drawing when a storage tray is piled up in the direction shown in FIG. It is sectional drawing which shows the relationship between a projection part and a fitting hole when a storage tray is piled up in the direction shown in FIG. It is sectional drawing which shows the relationship between a projection part and a timepiece movement when a storage tray is piled up in the same direction. It is a top view which shows the modification of the storage tray which concerns on this invention.

  Hereinafter, an embodiment according to the present invention will be described with reference to FIGS. In the present embodiment, as an example of an object to be stored, a tray that stores a timepiece movement (a timepiece driving device) having a pointer shaft will be described as an example.

  As shown in FIG. 1, the storage tray 1 of the present embodiment is a tray that can store a plurality of timepiece movements M at a time. When a plurality of timepiece movements M are stored in the storage tray 1, a storage package (storage body) P is obtained.

  Here, the timepiece movement M will be briefly described first. As shown in FIGS. 2A and 2B, the timepiece movement M of the present embodiment is a small precision component having a diameter of about 22 mm to 24 mm, and the pointer shaft M1 projects from the center of the upper surface. Yes. The pointer shaft M1 is a shaft having a diameter of about 0.2 mm, and a hand is attached when the pointer shaft M1 is incorporated in a watch. In addition, the timepiece movement M is formed in an outer shape so that the lower surface side is stepped so that the flange portion M2 is formed on the periphery.

  As shown in FIGS. 3 and 4, the storage tray 1 is formed by forming a thin plate 10 having a thickness of 1 mm or less by a technique such as vacuum forming, and a plurality (50 pieces) of storing the watch movement M over the entire surface. The storage portions 11 are arranged in a lattice shape along two directions, ie, a vertical direction (arrow L1 direction) and a horizontal direction (arrow L2 direction) orthogonal to each other.

  The thin plate 10 is a resin sheet made of polystyrene resin or the like, and is formed in a rectangular shape in plan view in which the length in the vertical direction is longer than the length in the horizontal direction.

  The storage portion 11 is formed in a bottomed shape by being recessed in the thin plate 10 so that the upper surface side of the thin plate 10 becomes an opening. At this time, each storage portion 11 is formed in a stepped shape with a bottom portion further recessed by one step, and is provided with a step portion 11a. Thus, since each accommodating part 11 is formed in the step shape, it is the state where the in-plane intensity | strength is high and rigidity increased. Further, since it is formed in a stepped shape, the shape follows the outer shape of the timepiece movement M. Thereby, when the timepiece movement M is stored in the storage portion 11, it is possible to store the watch movement M with the pointer shaft M1 facing upward and the hook portion M2 in contact with the step portion 11a.

  By the way, the plurality of storage units 11 are formed so that five rows are arranged at regular intervals in the horizontal direction, and ten rows are continuously arranged in the vertical direction per row. At this time, the storage unit 11 is formed symmetrically with respect to the longitudinal center line C1 of the thin plate 10 in the longitudinal direction, and is asymmetrical with respect to the longitudinal center line C2 of the thin plate 10 with respect to the lateral direction. ing.

  In addition, the storage units 11 arranged in the vertical direction are arranged so as to be close to the other storage units 11 adjacent to each other, and the respective recesses are partially connected via the common communication groove 12. It has become. That is, the storage units 11 arranged in the vertical direction are in a dense state, and are designed to be taken as many as possible in the limited space of the thin plate 10. In addition, among the storage portions 11 arranged in the vertical direction, the storage portion 11 arranged on the outer edge side of the thin plate 10 is close to the outer edge in a non-formation region where a bulging portion 15 described later is not formed. The dent is partially in communication with the outside. In other words, a large number (ten) of the storage portions 11 are arranged in the vertical direction using the space of the thin plate 10 to the maximum.

  Further, the plurality of storage portions 11 are formed to be slightly larger than the size of the timepiece movement M, and the entire inner peripheral wall is in contact with the side surface of the timepiece movement M to suppress play as much as possible. Specifically, when the timepiece movement M is stored, the size is designed so that only play of about 0.15 mm occurs. Therefore, it is possible to prevent the displacement of the timepiece movement M during storage.

  The storage units 11 arranged in the vertical direction are close to each other so that when the timepiece movement M is stored, the interval between the timepiece movements M is only about 1 mm. At this time, as described above, since the position of the timepiece movement M is prevented from being displaced, even a gap of only about 1 mm does not interfere with each other. Even if the adjacent watch movements M approach each other by an amount of play of 0.15 mm, there is still a margin of 0.7 mm between them. Therefore, they do not interfere with each other.

  Further, the timepiece movement M stored in the storage portion 11 provided on the outer edge side of the thin plate 10 does not jump out of the bulging portion 15.

  Next, the arrangement of the storage units 11 in the horizontal direction will be described.

Regard lateral, housing portion 11 are arranged in five rows spaced a predetermined distance B _0. At this time, the storage portions 11 arranged in two rows at both ends are designed to be separated from the outside of a later-described bulging portion 15 formed on the outer edge of the thin plate 10 by the distance shown below.

That is, the storage units 11 arranged in one row are separated by a distance B ₁ , and the storage units 11 arranged in the other row are designed to be separated by a distance [B ₁ + (D + B ₀ ) / 2]. Yes.

  Note that D is the lateral length of the storage portion 11.

  Therefore, the 50 storage portions 11 are generally located on one side (right side with respect to the paper surface of FIG. 3) and are asymmetrical about the longitudinal center line C2 as described above. Since the formation position of the storage unit 11 is designed in this way, when the storage trays 1 are stacked in multiple stages, if the storage trays 1 are stacked in different directions, the storage unit 11 of the upper storage tray 1 The storage unit 11 of the storage tray 1 on the lower side overlaps with a state shifted by a half pitch in the horizontal direction. That is, the lower surface of the storage portion 11 of the upper storage tray 1 is overlapped with the upper surface of a gap area 20 (described later) of the lower storage tray 1. At this time, a gap space 21 described later of the upper storage tray 1 is positioned above the storage portion 11 of the lower storage tray 1.

  When the storage trays 1 are stacked in the same direction, the storage units 11 are overlapped.

  By the way, a bulging portion 15 that is bent toward the upper side of the thin plate 10 and then bent toward the lower side of the thin plate 10 is formed on the outer edge of the thin plate 10 over substantially the entire circumference. In particular, the bulging portion 15 is formed in an outwardly expanding taper shape so as to be an inclined surface inclined toward the outside of the thin plate 10 when bent toward the lower side of the thin plate 10. The inclination angle θ is inclined about 5 ° from a vertical state. The bulging portion 15 overlaps the bulging portion 15 formed on the upper storage tray 1 when the storage trays 1 are overlapped. As a result, the stacked storage trays 1 are positioned with respect to two directions (plane direction) in the vertical direction and the horizontal direction.

  The lower end of the bulging portion 15 is an edge portion 15a bent in the horizontal direction. The edge portion 15a is a notched portion 16 in which three portions of the corner portions corresponding to the four corners of the thin plate 10 are subjected to curved surface processing (R processing), but one portion is cut obliquely. The notch 16 functions as a mark for recognizing the orientation when the storage trays 1 are overlapped.

  The bulging portion 15 formed in this way is continuously formed along the longitudinal direction of the thin plate 10, and is discontinuous, that is, discontinuous with a certain interval along the short direction. Is formed. And in the non-formation area | region in which the bulging part 15 is not formed, as mentioned above, the dent of the accommodating part 11 is connected in part outside.

  At this time, as shown in FIGS. 5 and 6, the discontinuously formed bulging portion 15 is formed in a state where the dent is separated by a predetermined distance H from the outer shape line of the storage portion 11 partially communicating with the outside. Has been. That is, the bulging portion 15 is formed in a state completely separated from the recess formation of the storage portion 11. Therefore, the bulging portion 15 is less likely to be crushed or deformed, and is formed in a desired shape with high accuracy.

  As shown in FIG. 3 and FIG. 4, a region located between the storage portions 11 adjacent in the horizontal direction among the remaining regions of the thin plate 10 is a gap region 20. The gap area 20 is an area in which a gap space 21 that is recessed in a valley shape is secured on the lower surface side of the thin plate 10. That is, since each storage part 11 is formed as a depression, a gap space 21 that is recessed in a valley shape exists between the storage parts 11. A region where the gap space 21 is secured on the lower surface side of the thin plate 10 is a gap region 20.

  Moreover, as shown in FIG.7 and FIG.8, the some protrusion part 22 and the fitting hole 23 are formed in the thin plate 10, respectively. In the present embodiment, a case where twelve are formed is taken as an example. However, it is not limited to this number.

  The protrusion 22 is formed so as to protrude downward from the thin plate 10 relative to the storage portion 11. The fitting hole 23 is formed at a position facing the protruding portion 22 when the storage trays 1 are stacked in opposite directions (with the directions different from each other by 180 degrees). It is a hole to be accommodated. By the way, the plurality of protrusions 22 come into contact with the upper surface of the timepiece movement M stored in the storage unit 11 when the storage trays 1 are overlapped in the same direction. This point will be described in detail later.

Further, as shown in FIG. 3, a long hole is formed between the storage portion 11 and the bulging portion 15 in a row separated by a distance [B ₁ + (D + B ₀ ) / 2] from the outer edge of the thin plate 10. A plurality of recessed portions 24 are formed. The concave portion 24 is for the purpose of reinforcing prevention of the rigidity of the thin plate 10 and is formed in the vicinity of the bulging portion 15 with a gap in the vertical direction.

  The lower surface of the recess 24 is designed to be flush with the lower surface of the storage unit 11 and is flush with the timepiece movement stored in the lower storage tray 1 when the storage trays 1 are overlapped. It also plays the role of holding M from above.

  Next, a case where the timepiece movement M is stored using the storage tray 1 configured as described above will be described.

  First, after preparing a plurality of storage trays 1, the timepiece movement M is sequentially stored in the storage portion 11 of each storage tray 1. At this time, as shown in FIG. 9, the timepiece movement M is accommodated so that the pointer shaft M1 faces upward. Then, the timepiece movement M is stored in a state where the collar portion M2 is placed on the stepped portion 11a of the storage portion 11. Thereby, the timepiece movement M is stably accommodated in each accommodating part 11.

  In particular, the storage units 11 arranged in the vertical direction are close to the other storage units 11 adjacent to each other, and the recesses are partially connected to each other through the common communication groove 12. In addition, the storage portion 11 arranged on the outer edge side of the thin plate 10 is close to the outer edge in the non-formation region where the bulging portion 15 is not formed, and the dent communicates with the outside.

  As described above, the limited space of the thin plate 10 is utilized to the maximum, and a plurality of storage portions 11 are arranged in the vertical direction in a dense state. Thereby, more storage units 11 can be secured without changing the size of the storage tray 1 itself from the conventional size. As a result, as many as 50 watch movements M can be efficiently stored in one storage tray 1.

  Further, when the timepiece movement M is stored, the inner peripheral wall of the storage portion 11 is in contact with the side surface of the timepiece movement M, and the play between them is suppressed to about 0.15 mm. As a result, the timepiece movement M is prevented from being displaced in the storage portion 11 and is stably stored without rattling. In particular, even when the watch movement M is stored in the storage portions 11 that are close to each other in the vertical direction, the watch movements M do not interfere with each other due to rattling or the like. A gap is secured. Therefore, the watch movement M can be stored in a state in which the quality of the watch movement M is reliably maintained.

  Incidentally, even if it is attempted to narrow the gap with the gap region 20 as much as possible without providing the communication groove 12 between the adjacent storage portions 11, the above-mentioned small gap cannot be realized due to manufacturing limitations, and storage is performed. The tray 1 becomes large. In this regard, according to the storage tray 1 of the present embodiment provided with the communication grooves 12, a large number of storage portions 11 can be secured without such problems.

  In addition, each storage portion 11 is formed in a stepped shape with a bottom portion recessed by one step and has increased rigidity, so that the stored timepiece movement M can be stored stably. In addition, since the rigidity of the entire storage tray 1 can be expected to increase as the rigidity of each storage portion 11 increases, bending, twisting, and the like can be suppressed. Therefore, a high quality tray suitable for storage can be obtained.

  Further, since the bulging portion 15 is formed at the outer edge of the thin plate 10, the rigidity of the entire tray is increased. Also in this point, it is possible to more effectively suppress bending, twisting, and the like of the entire storage tray 1. Further, when the storage tray 1 is picked, it can be gripped using the portion of the bulging portion 15, so that it can be carried without touching the stored timepiece movement M.

  As described above, the storage package P can be obtained by storing 50 timepiece movements M in each storage tray 1. Next, after storing the timepiece movement M in each storage tray 1, as shown in FIG. 10, the storage trays 1 are stacked while being alternately stacked. In FIG. 10, only four stages are shown. At this time, the storage trays 1 are overlapped so as to be opposite to each other. At this time, the edge 15a of the storage tray 1 is formed with the notch 16 for recognizing the direction, so that the direction of the notch 16 is overlapped so that the directions of the notch 16 are alternately located on the opposite side, thereby making the wrong direction. The storage trays 1 can be overlapped without any problems.

  Therefore, the overlaying operation can be performed reliably and efficiently. In addition, since the bulging portion 15 is formed in each storage tray 1, the bulging portion 15 can be used as a clue at the beginning of stacking. Therefore, it is possible to perform the superposition work speedily.

  When the storage trays 1 are stacked, as shown in FIG. 11, the lower surface of the storage unit 11 of the upper storage tray 1 comes into contact with the upper surface of the gap area 20 of the lower storage tray 1. As a result, the stacked storage trays 1 are positioned in the height direction and are in a state where they are stably overlapped in a close contact state. In FIG. 11, only four stages are shown.

  In addition, at this time, the gap space 21 of the upper storage tray 1, that is, the valley-like depression formed between the storage portions 11 protruding by forming the recess is located above the storage portion 11 of the lower storage tray 1. It is supposed to be. Therefore, a space can be secured above the timepiece movement M stored in the lower storage tray 1.

  Therefore, when the storage trays 1 are stacked in multiple stages, the upper storage tray 1 does not come into contact with the pointer shaft M1, and no influence (load) is exerted on the pointer shaft M1. Therefore, it is possible to prevent the contact with the pointer shaft M1 from being adversely affected.

  As a result, a large amount of the watch movement M can be efficiently stored in a small space while maintaining the quality, and can be transported without incurring a high cost or burdening human hands.

  In particular, since a large number of timepiece movements M can be stored in one storage tray 1, when the same number of timepiece movements M are stored, the number of stages can be reduced as compared with the conventional case. Therefore, when the storage trays 1 are transported in multiple stages, not only the handling becomes easy, but also the transportation cost can be reduced and the cost can be reduced.

  In addition, when transporting after stacking in multiple stages, it is preferable to place the empty storage tray 1 on the top as a role of a lid. Moreover, when conveying after laminating | stacking in multiple stages, it is preferable to cover the whole with a heat shrink film, and to pack. By doing so, it is possible to effectively prevent dust and the like from adhering to the timepiece movement M.

  Moreover, since each storage tray 1 can be piled up stably, even if it piles up in multiple stages, it is excellent in stability. In particular, when the storage trays 1 are overlapped, the bulging portions 15 overlap as shown in FIG. Therefore, since the storage tray 1 is positioned with respect to the in-plane direction, the storage tray 1 is not displaced during the overlapping. Therefore, it is possible to perform superposition in a more stable state, and to reliably maintain a state in which no load is applied to the pointer shaft M1 of the timepiece movement M.

  In addition, since the concave portion of the storage portion 11 arranged on the outer edge side of the thin plate 10 partially communicates with the outside, even when the storage trays 1 are stacked in multiple stages, the storage portion 11 is viewed from the side. It is easy to check whether or not the watch movement M is housed therein.

  By the way, when the storage trays 1 are overlapped, as shown in FIG. 12, the protrusions 22 formed on the upper storage tray 1 fit into the fitting holes 23 formed in the lower storage tray 1. Stored. Therefore, the storage trays 1 can be overlapped without being obstructed by the protrusion 22.

  Next, a description will be given of a case where the storage trays 1 are not stacked in the reverse direction but are stacked in the same direction by mistake.

  In this case, as shown in FIG. 13, the protrusion 22 formed on the upper storage tray 1 moves the pointer shaft M1 of the timepiece movement M stored in the storage portion 11 of the lower storage tray 1. Abuts the top surface. Moreover, since the protruding portion 22 is formed so as to protrude downward from the storage portion 11, the protrusion 22 abuts before the storage tray 1 completely overlaps. Therefore, the storage tray 1 does not overlap any more. Therefore, it is possible to prevent the load from being applied by the upper storage tray 1 coming into contact with the pointer shaft M1. Accordingly, the quality of the watch movement M can be maintained even when the watches are stacked in the same direction.

  In the present embodiment, when the storage trays 1 are stacked in the same direction, the protrusion 22 comes into contact with the upper surface excluding the pointer shaft M1 of the timepiece movement M stored in the lower storage tray 1. However, the present invention is not limited to this case, and may be in contact with the upper surface of the gap area 20 of the lower storage tray 1 or may be in contact with both.

  In the above embodiment, the case where the watch movement M is first stored in each storage tray 1 and then overlapped is described as an example. However, the present invention is not limited to this case. For example, after the timepiece movement M is stored in the first storage tray 1, the empty storage tray 1 may be stacked, and then the timepiece movement M may be stored in the empty storage tray 1. Even in this order, the same effects can be obtained.

  The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

  For example, in the above-described embodiment, the timepiece movement M having the pointer shaft M1 has been described as an example of an object to be stored. However, other precision machine parts and electronic parts may be used.

  In addition, as an example of the timepiece movement, the timepiece movement M in which the lower surface side is stepped and the flange portion M2 is formed on the periphery has been described as an example, but is not limited to this shape. For example, it may be a round plan view with no step at the periphery, or it may be a watch movement with a square view. In this case, the inner peripheral wall of the storage portion 11 may be changed according to the shape of the timepiece movement to prevent the position movement of the timepiece movement.

  Moreover, in the said embodiment, when the timepiece movement M was accommodated in the accommodating part 11, the case where the collar part M2 contact | abutted to the step part 11a was mentioned as an example, but the collar part M2 contact | abutted to the step part 11a. It may be in the form of being stored by contacting the storage portion 11 with the lowermost surface of the timepiece movement M in front. Even in this case, the same effects can be achieved.

  Depending on the relationship between the thickness of the timepiece movement M and the depth of the storage portion 11, whether or not the collar portion M and the stepped portion 11a are in contact with each other is different. In either case, the same effect can be obtained. That is, even the watch movement M having different thicknesses can be stored without any problem.

  In the above embodiment, the entire inner peripheral wall of the storage portion 11 is in contact with the side surface of the timepiece movement M to suppress play and prevent the position of the timepiece movement M from being displaced, but at least a part of the inner peripheral wall is a timepiece. You may comprise so that a play may be suppressed in contact with the side surface of the movement M. FIG.

  Further, in the above-described embodiment, among the plurality of storage units 11, only the storage units 11 arranged in the vertical direction are brought close to each other to be in a dense state. May be formed in a dense state. That is, the plurality of storage portions 11 are arranged in a grid pattern in the vertical direction and the horizontal direction so as to be close to all the adjacent storage portions 11, and the respective recesses are partially connected via the common communication groove 12. It does not matter even if it is in the state. By configuring the storage tray 30 in this way, it is possible to secure a larger number of storage units 11 (70 pieces), and it is possible to efficiently store more timepiece movements M with one storage tray 30. .

  In this case, the plurality of storage portions 11 may be arranged in a zigzag pattern instead of being arranged in a lattice shape in the vertical direction and the horizontal direction.

  Moreover, although the case where the projection part 22 and the fitting hole 23 were formed 12 each was taken as an example in the said embodiment, it is not limited to this number, You may design freely. For example, 30 or more may be formed. In this case, in addition to the functions as the protrusion 22 and the fitting hole 23, it can be expected that the strength of the storage tray 1 itself is increased and the rigidity is further increased.

  Moreover, in the said embodiment, although the notch part 16 which cut a part of the edge part 15a of the thin plate 10 diagonally was used as the mark for direction recognition, it is good also as a mark by writing some index instead of a notch.

  In the above embodiment, the operation of storing the watch movement M in the storage tray 1 and the operation of stacking the storage tray 1 may be performed by a machine such as a robot. In particular, when the storage tray 1 is superposed using a machine such as a robot, it is preferable that the notch 16 is formed. That is, by programming so that the notch 16 is used as an index, the orientation of the storage tray 1 can be recognized with high accuracy, so that the operation can be performed more reliably and the control becomes very easy.

  In addition, when the storage trays 1 are overlapped, the lower surface of the storage unit 11 of the upper storage tray 1 comes into contact with the upper surface of the gap region 20 of the lower storage tray 1 to perform positioning in the height direction. Alternatively, a step portion may be formed in the bulging portion 15 and the height direction may be positioned using this step portion.

  In addition, when the watch movement M is stored in the storage portion 11 on the outer edge side of the thin plate 10, the watch movement M is prevented from jumping out of the bulging portion 15. There is no contact with the storage tray 1. That is, when the bulging portion 15 is bent toward the lower side of the thin plate 10, the bulging portion 15 is bent outwardly so as to be an inclined surface that is inclined outward. 15 and the watch movement M are unlikely to interfere directly. Therefore, the storage part 11 can be brought closer to the outer edge side of the thin plate 10 and can be connected to a large number of timepiece movements M.

M ... Clock movement (Clock drive, stored item)
P ... Storage package (container)
DESCRIPTION OF SYMBOLS 1 ... Storage tray 10 ... Thin plate 11 ... Storage part 12 ... Communication groove 15 ... Swelling part

Claims (6)

A storage tray for storing a plurality of items to be stored,
With a thin plate,
A plurality of bottomed storage portions that are recessed in the thin plate so that the upper surface side of the thin plate is an opening, and stores the object to be stored therein;
A bulge portion bent toward the lower side of the thin plate after being bent toward the upper side of the thin plate at the outer edge of the thin plate;
With
The bulging portion is formed discontinuously with a certain interval,
Among the plurality of storage portions, the storage portion disposed on the outer edge side of the thin plate is disposed so as to be close to the outer edge in the non-formation region of the bulging portion, and the recess communicates with the outside in the non-formation region. The two storage trays are placed on the one storage tray in a state where the other storage tray is rotated 180 degrees with respect to one storage tray around the axis in the direction in which the two storage trays are stacked. A storage tray in which a non-formation region of the bulge portion of the one storage tray is covered with the bulge portion of the other storage tray when the two are stacked. The storage tray according to claim 1,
The storage tray is characterized in that when the storage trays are stacked, the expansion portion overlaps with the expansion portion of the other storage tray and performs positioning in the planar direction. The storage tray according to claim 1,
The bulging portion formed discontinuously is formed in a state in which a recess is formed at a predetermined distance from an outer shape line of the storage portion that is partially communicated to the outside. The storage tray according to claim 1,
The storage tray, wherein the bulging portion is bent so as to have an inclined surface that is inclined toward the outside of the thin plate when bent toward the lower side of the thin plate. The storage tray according to any one of claims 1 to 4,
And a storage object stored in the storage portion of the storage tray. The storage body according to claim 5,
The storage object is a timepiece driving device.

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