JP2011051609A - Solar battery panel conveyance tray and solar battery panel package - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solar battery panel conveyance tray 10, made of foam resin, for horizontally accommodating a solar battery panel 1, which is a heavy load, the tray 10 being configured so that the corners and periphery of the solar battery panel 1 are prevented from being damaged in the event that an impact load is suddenly applied thereto and so that even if the solar battery panel 1 to be accommodate has a projection 2 in its face, the panel 1 can be accommodated in the tray 10 in a stable position. <P>SOLUTION: In the solar battery panel conveyance tray 10, a bottom plate 11 and four side walls 12 define an accommodating space 13 for horizontally accommodating the solar battery panel 1. The four corners of the accommodating space 13 and the upward faces 15 of the side walls have areas (first recesses 16 and second recesses 17) with which the peripheral edges and bottoms of the accommodated solar battery panels 1 do not come into contact. Further, the bottom plate 11 has a through-hole 14 for accommodating the projection 2 formed on the accommodated solar battery panel 1. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a solar cell panel transfer tray and a solar cell panel package, and more particularly to a solar cell panel transfer tray and a solar cell panel package suitable for packing and transferring a solar cell panel in a horizontal posture.

  In recent years, with increasing interest in the environment, demand for solar cells that convert light energy into electrical energy has increased, and solar cell panels with frame structures and terminal boxes attached to solar cell modules have become widely distributed. Yes. On the other hand, solar cell panels are generally large and heavy, and are easily damaged by vibrations during transportation. Therefore, a solar cell panel transport tray that can safely transport multiple solar cell panels Is required. On the other hand, a glass substrate for an image display device such as a liquid crystal display is thin and easily broken, and as its size increases, more careful handling is required. As some proposals have already been made.

  For example, Patent Document 1 discloses a unit package in which a plurality of glass substrates are housed in a stacked state in a horizontal posture with a foamed resin sheet interposed between each other in an internal housing space of a box. There is described a glass plate packaging unit that is stacked and accommodated in a plurality of stages in the vertical direction inside the enclosure.

  In Patent Document 2, an accommodation portion that accommodates a glass substrate as an object to be conveyed is formed on the upper surface and is positioned in the horizontal direction, and the lower surface is inserted into an accommodation portion of a stacked lower conveyance tray. In addition, a frame-shaped transport tray is described in which a protrusion that restricts lifting of the glass substrate housed in the lower transport tray is formed.

  Patent Document 3 discloses a glass substrate transport tray made of a polyolefin resin foam in which a plurality of housing portions for horizontally housing a glass substrate are formed on the upper surface of the tray, and the tray housing portion is a glass substrate. Describes a glass substrate carrying tray having a bottom surface in which the substrate is accommodated and a side wall surrounding the bottom surface, and a recess formed on the periphery of the bottom surface.

JP-A-2005-75366 Japanese Patent Laid-Open No. 10-197855 JP 2002-353302 A

  Although the transport tray can be used as it is as the solar cell panel transport tray for the glass substrate of the above-described form, there are some disadvantages. For example, in a configuration in which a plurality of glass substrates are accommodated in a stacked manner in a horizontal posture as described in Patent Document 1, when an attempt is made to accommodate a large and heavy solar cell panel, between solar cell panels Even if a foamed resin sheet or the like is interposed between the solar cell panels, the solar cell panel is likely to be damaged due to vibration or shaking during transportation. In addition, a countermeasure for the case where the container has a convex portion such as a connector in the surface is not particularly considered.

  The conveyance tray having a frame shape as described in Patent Document 2 is a form in which only the peripheral part of the conveyed product is supported by the conveyance tray, and the stored item has a convex part in the surface. It can be accommodated as it is. However, since it has a member that supports the central portion from the back side, it is inevitable that the support becomes unstable when a large and heavy solar cell panel is accommodated. In addition, since the entire periphery of the stored object is stored in contact with the side wall of the storage unit formed on the transport tray, damage to the periphery of the large and heavy solar cell panel occurs when an impact load occurs. There is a fear.

  The glass substrate carrying tray described in Patent Document 3 basically accommodates one glass substrate in one accommodating portion, and stacks it in multiple stages to form a package. Can be avoided. Further, by forming a recess in the peripheral edge of the bottom surface of the storage portion, the peripheral edge is prevented from coming into contact with the tray body when the stored item vibrates. However, the contents accommodated in the tray are supported only by the upper and lower surfaces, and it is impossible to completely avoid the movement in the horizontal direction due to the vibration during the conveyance. In the case of a large and heavy solar cell panel, the movement becomes significant, and the periphery of the solar cell panel repeatedly contacts the side wall of the storage unit irregularly even during normal transportation. This may cause damage around the solar cell panel. In addition, a countermeasure for the case where the container has a convex portion such as a connector in the surface is not particularly considered.

  The present invention has been made in view of the above circumstances, and in a solar cell panel transfer tray that can accommodate a heavy solar cell panel in a horizontal posture, the solar cell panel accommodated in the tray is not prepared. It can be firmly positioned in the box so that it does not move, but in the event of a sudden impact load, damage to the surroundings can be avoided. It is a first problem to disclose a solar cell panel carrying tray that can be accommodated in the tray in a stable posture even when it has a convex portion. Moreover, it is set as the 2nd subject to disclose the solar cell panel package using the said tray for solar cell panel conveyance.

  The solar cell panel carrying tray according to the present invention is a foamed resin solar cell panel carrying tray in which a housing space that can accommodate a solar cell panel in a horizontal posture is formed by a bottom plate and a side wall provided upright on the four circumferences of the bottom plate. In the four corners of the housing space, regions where the peripheral edge and bottom surface of the housed solar cell panel do not contact are formed, and the bottom plate is formed with protrusions formed on the housed solar cell panel. A through hole for accommodating the portion is formed.

  In the above solar cell panel transport tray, the peripheral edge of the solar cell panel accommodated in the accommodating space is basically supported by the side wall surface of the accommodating space, and it is inadvertently moved in the horizontal direction during conveyance. Absent. In addition, the solar cell panel transfer tray is made of foamed resin and has a required cushioning property. Since slight movement due to vibration is absorbed by the solar cell panel transfer tray, the solar cell panel is damaged. There is nothing. On the other hand, at the four corners of the housing space, regions where the periphery and bottom surface of the housed solar cell panel are not in contact are formed, and this region reduces the impact force applied to the corners of the solar cell panel during a drop impact or the like. Therefore, the corner portion of the solar cell panel can be prevented from being damaged by the impact load.

  Furthermore, since the through-hole for accommodating the convex part formed in the solar cell panel to accommodate is formed in the bottom plate of a tray, even if it is a case where a solar cell panel has a convex part in a surface, It can be accommodated in the tray in a stable posture.

  In one embodiment of the solar cell panel transfer tray according to the present invention, a region where the peripheral edge and the bottom surface of the accommodated solar cell panel are not in contact with each other is also formed in a part of the accommodation space along the side wall. In the solar cell panel transport tray of this embodiment, the impact force applied to the side edge of the solar cell panel at the time of a drop impact or the like can be partially alleviated in the region, so that the impact load is applied to the side edge of the solar cell panel. Damage can also be mitigated.

  In one form of the solar cell panel carrying tray according to the present invention, a ridge is formed on all or a part of the outer peripheral surface of the upper surface of the side wall, and a portion corresponding to the ridge on the outer peripheral side of the lower surface of the side wall. Is formed with a notch having a shape corresponding to the ridge into which the ridge enters. In this embodiment, when the solar cell panel transfer trays are stacked, the protrusions enter the cutout portions, thereby preventing lateral displacement and stabilizing the stacking posture.

  In the present invention, the solar cell panel carrying tray can be made of any resin material provided that it has the required buffering properties and mechanical strength. Preferably, it is an in-mold foam molded product of a thermoplastic resin. Thermoplastic resins include polystyrene resins, polyolefin resins (eg, polypropylene resins, polyethylene resins, etc.), polyester resins (eg, polyethylene terephthalate, polybutylene terephthalate, polyethylene naphthalate, etc.), polycarbonate resins, polyresins. Examples include lactic acid resins. Among these, it is preferable to use a composite resin containing polystyrene and polyethylene. The magnification of the foam may be appropriately set in consideration of the weight of the solar cell panel to be packed, etc., but is preferably about 30 to 60 times from the viewpoint of good buffering property, light weight and economical. .

  The solar cell panel packing body according to the present invention has any one of the above-described solar cell panel transfer trays stacked in at least two or more stages, and other solar cell panel transfer trays excluding the uppermost solar cell panel transfer tray A solar cell panel is accommodated in the accommodation space formed in the above.

  In said solar cell panel package, a plurality of solar cell panels can be made into one package using a plurality of solar cell panel transfer trays of the same form. As described above, each solar cell panel is housed in a stable state in each tray, and it can be avoided that the housed solar cell panel is damaged or collapsed when the package is transported. . In addition, in the package, when the solar cell panel to be accommodated has a convex portion in the surface, the specification is that a single solar cell panel is accommodated in one solar cell panel transfer tray, but there is no convex portion. When packing the solar cell panel of a form, the specification which accommodates one or more solar cell panels in one solar cell panel conveyance tray is also possible.

  In another form of the solar cell panel package according to the present invention, in addition to the solar cell panel package described above, at least an exterior material that wraps the solar cell panel package and a support pallet are included. Since the solar cell panel package in this form is provided with an exterior material and a support pallet, it becomes a more stable package, so that it can be easily conveyed during distribution. Although the exterior material can be made of an appropriate material, the exterior material made of corrugated cardboard is preferable in terms of ease of manufacture and light weight. The pallet may also be conventionally known, and may be made of metal, resin, wood, or the like.

  By using the solar cell panel carrying tray according to the present invention, even a solar cell panel having a convex portion in the surface can be stably accommodated in a horizontal posture. Further, when a sudden impact load such as a drop load is generated, it is possible to avoid the occurrence of damage at the corners or the periphery of the housed solar cell panel. Therefore, by using a plurality of solar cell panel transfer trays as described above to form a solar cell panel package, a plurality of solar cell panels can be safely delivered to the physical distribution.

The perspective view which shows one form of the tray for solar cell panel conveyance by this invention. 2A is a cross-sectional view taken along the line II-II in FIG. 1, and FIG. 2B is an enlarged view of a main part. The figure which shows typically an example of the solar cell panel which is a storage thing. The top view which shows the state which accommodated the solar cell panel shown in FIG. 3 in the solar cell panel conveyance tray shown in FIG. Fig.5 (a) is sectional drawing which shows an example of the solar cell panel package by this invention, FIG.5 (b) is an enlarged view of the principal part.

  Hereinafter, a solar cell panel transfer tray and a solar cell panel packing material according to the present invention will be described based on embodiments. In addition, in this invention, as shown in FIG. 3, the solar cell panel 1 which is a conveyance target object has an overall shape that is a rectangle in plan view, and a convex portion 2 that functions as a connector on a part of the plane. Have.

  The solar cell panel carrying tray 10 according to the present invention shown in the figure is made of foamed resin, and is molded by in-mold molding of foamable particles of thermoplastic resin. The solar cell panel transfer tray 10 has a bottom plate 11 and four side walls 12 erected on the four circumferences of the bottom plate 11, and the above-described sun is formed on the upper surface of the bottom plate 11 by the bottom plate 11 and the four side walls 12. An accommodation space 13 in which the battery panel 1 can be accommodated in a horizontal posture is formed. And the through-hole 14 is formed in the site | part from which the said convex part 2 will be located when the solar cell panel 1 is accommodated in the appropriate place of the baseplate 11. FIG.

  In the solar cell panel transfer tray 10, the position of the rising surface 15 on the inner surface side of the four-round side wall 12 is a position where the four-side edge 3 abuts when the solar cell panel 1 is accommodated in a horizontal posture. It is said that. The four corners are respectively formed with first recesses 16 having a required depth and size. Further, an appropriate number of second recesses 17 having a required depth and size are also formed on the four rising surfaces 15 (two in each rising surface 15 in the illustrated example). The second recess 17 can be omitted.

  FIG. 4 shows a state where the solar cell panel 1 shown in FIG. 3 is accommodated in the solar cell panel transfer tray 10 as a plan view, and FIG. 5B shows an enlarged main part. The solar cell panel 1 accommodated in the accommodating space 13 has a part of the side edge (periphery) 3 supported by the rising surface 15 of the solar cell panel transfer tray 10, but the side edge at the corner. Due to the presence of the first recess 16, the (periphery) and the bottom surface do not come into contact with the solar cell panel transfer tray 10 during housing. Similarly, the side edge and part of the bottom surface of the accommodated solar cell panel 1 do not come into contact with the solar cell panel transfer tray 10 when accommodated due to the presence of the second recess 17. .

  Further, in the solar cell panel transport tray 10, an appropriate number of protrusions 18 (two in each side wall 12 in the illustrated example) are formed on the outer periphery of the upper surface of each side wall 12, Further, a cutout portion 19 having a size into which the ridges 18 enter is formed on the outer peripheral side of the lower surface of each side wall 12 and corresponding to the ridges 18. A second notch portion 20 having a required depth is formed in the ceiling portion of the notch portion 19.

  FIG. 5 (a) shows a case in which the solar cell panel 1 is accommodated in the solar cell panel transport tray 10 in multiple layers, and is wrapped with an exterior material 30 that is, for example, corrugated cardboard, and is further mounted on the support pallet 40. The placed solar cell panel packing body 50 is shown. However, the solar cell panel 1 is not accommodated in the uppermost solar cell panel transfer tray 10. Although omitted in the figure, in actual conveyance, the solar cell panel 1 is accommodated in each solar cell panel conveyance tray 10 with a resin sheet having an appropriate thickness laminated on both surfaces thereof. .

  As shown in the figure, the solar cell panel 1 is accommodated in a solar cell panel transfer tray 10 in a posture with the convex portion 2 facing upward, and the convex portion 2 is stacked in a higher level. It enters into the through hole 14 formed in the transfer tray 10. Therefore, even if it is the solar cell panel 1 which has the convex part 2 in a surface, it can accommodate stably in each solar cell panel conveyance tray 10 with a horizontal attitude | position, and stacks it easily. be able to. Although not shown in the figure, it can also be accommodated in the solar cell panel transfer tray 10 in a posture in which the convex portion 2 is on the lower side. In any case, the thickness of the bottom plate 11 of the solar cell panel transfer tray 10 is set to a thickness that can accommodate the convex portion 2 of the solar cell panel 1.

  Furthermore, as shown in FIG.5 (b), in the state which stacked | stacked each solar cell panel conveyance tray 10, the upper surface side of the solar cell panel 1 accommodated in the low order solar cell panel conveyance tray 10a is a high-order. The thickness of the bottom plate 11 and the depth of the cutout portion 19 are set so that the bottom of the bottom plate 11 of the solar cell panel transfer tray 10b can be pressed.

  In the solar cell panel package 50, in the state where the solar cell panel transfer trays 10 are stacked, the ridges 18 formed on the lower solar cell panel transfer tray 10a are positioned higher than the solar cells. The posture is fitted into the notch 19 formed in the panel transfer tray 10b, and the stacking posture is stable. Moreover, each notch part 19 has the 2nd notch part 20, and when stacked, since the 2nd notch part 20 remains as a space | gap, the tray for stacking the stacked solar cell panels The operation of taking out 10 one by one is also facilitated.

  In the solar cell panel package 50 described above, as described above, the peripheral edges (four side edges 3) of the solar cell panel 1 accommodated in the accommodating space 13 of each solar cell panel transfer tray 10 are basically accommodated. It is supported by the side wall surface (the rising surface 15) of the space 13, and does not move in the horizontal direction inadvertently during conveyance. Further, the solar cell panel transfer tray 10 is made of foamed resin and has a required buffering property, and slight movement due to vibration is absorbed by the solar cell panel transfer tray 10. There will be no scratches.

  On the other hand, the four corners of the accommodation space 13 are formed with regions where the peripheral edge and bottom surface of the corner portion of the accommodated solar cell panel 1 do not contact, that is, the first recess 16 described above. The impact force applied to the corners of the solar cell panel 1 at the time of impact is alleviated. Thereby, it can prevent that the corner | angular part of the solar cell panel 1 is damaged by an impact load.

  Further, in the solar cell panel transport tray 10 described above, a part of the side edge and the bottom surface of the solar cell panel 1 accommodated also contacts a part of the portion of the housing space 13 along the side wall (rise surface 15). The second recess 17 is formed, that is, the impact force applied to the side edge 3 of the solar cell panel 1 at the time of a drop impact or the like is partially relieved in the second recess 17. As a result, damage to the side edge 3 of the solar cell panel 1 due to the impact load can be mitigated.

1 ... solar panel,
2 ... the convex part which exists in the surface of a solar cell panel,
3 ... Side edge (periphery) of solar cell panel,
10 ... Tray for transporting solar panel,
11 ... bottom plate,
12 ... 4 lap side walls,
13 ... Containment space,
14 ... through hole,
15 ... Rising surface on the inner surface side of the four-round side wall,
16 ... 1st recessed part (The area | region where the periphery and bottom face in the corner | angular part of the accommodated solar cell panel formed in the four corners of the accommodation space do not contact),
17 ... 2nd recessed part (area | region where the periphery and bottom face of the accommodated solar cell panel which were formed in the four side walls of the accommodation space do not contact),
18 ... ridges,
19 ... a cutout portion of a size into which the ridge enters,
20 ... a second notch formed in the notch,
30 ... exterior material,
40 ... support pallet,
50: A solar battery panel package.

Claims (5)

A solar cell panel transport tray made of foamed resin in which a housing space is formed in which a solar cell panel can be accommodated in a horizontal posture with a bottom plate and side walls erected around the circumference of the bottom plate,
In the four corners of the housing space, regions where the peripheral edge and the bottom surface of the housed solar cell panel do not contact are formed, and the bottom plate accommodates convex portions formed on the housed solar cell panel. A through hole for forming the solar cell panel is provided.   It is a solar cell panel conveyance tray of Claim 1, Comprising: The area | region where the periphery and bottom face of the accommodated solar cell panel do not contact also in part of the part in alignment with the said side wall of the said accommodation space is formed. A tray for carrying solar cell panels.   It is a solar cell panel conveyance tray of Claim 1 or 2, Comprising: The convex strip is formed in all or one part of the upper surface outer peripheral side of the said side wall, The said convex strip on the lower surface outer peripheral side of the said side wall is formed. A tray for carrying a solar cell panel, wherein a cutout portion into which the protruding line enters is formed in a corresponding portion.   The solar cell panel transport tray according to any one of claims 1 to 3 is stacked in at least two or more stages, and is formed on another solar cell panel transport tray excluding the uppermost solar cell panel transport tray. A solar cell panel package comprising a solar cell panel accommodated in the accommodation space.   A solar cell panel package comprising at least the solar cell panel package according to claim 4, an exterior material that wraps the solar cell panel package, and a support pallet.

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