JP5181015B2 - Vertically mounted thin panel transport unit - Google Patents

Description

  The present invention relates to a transport unit for a vertically placed thin plate panel, and more particularly, to a transport unit for a vertically placed thin plate panel that can stably transport a plurality of thin plate panels in a vertically placed manner while reducing cost.

2. Description of the Related Art Conventionally, a thin plate panel transport unit that stores and transports a thin panel such as a display in a vertical direction has been used.
Patent Documents 1 and 2 disclose an example thereof.
Both have a rectangular pallet and a pair of side plates, a front plate and a back plate, each of which has a lower end fixed to the peripheral edge of the upper surface of the rectangular pallet and forms a box in cooperation with the rectangular pallet. And a plurality of grooves spaced apart from each other, each extending over the entire height direction of the inner surface and accommodating the side edges of the thin panel. It has a resin cushioning material.
According to such a thin panel transport unit, when storing a plurality of thin panels in the unit, each thin panel can be easily stored by using the guide function of the groove. When transporting the thin panel together with the unit, it was possible to protect the thin panel by effectively preventing the internal thin panel from being damaged by the vibration of the unit by the buffer function of the buffer provided with the groove. .

However, in the conventional thin panel transport unit, the cushioning material has both the protective function of the thin panel and the guiding function when storing the thin panel, which causes an increase in cost as the transport unit. .
That is, firstly, it is not necessary to make a box that can accommodate the entire thin plate panel in order to fully protect the thin plate panel, and secondly, for the guidance of the thin plate panel, There is no need to provide a groove over the entire height. When a groove is provided over the entire height of the inner surface of the box, the contact area between the thin plate panel and the groove is increased, thereby increasing the resistance due to friction and making it difficult to accommodate the thin plate panel in the unit. On the other hand, if the width of the groove is increased with respect to the thickness of the thin panel in order to reduce the frictional resistance, the stored thin panel may cause backlash during transportation.
Furthermore, in Patent Document 2, a cushioning material is provided on the upper surface of the rectangular pallet in addition to the opposing inner surface of the box, but unlike the case of providing it on the inner surface, the weight of the thin plate pallet stored with time elapses. The groove may collapse and the positioning function, and possibly the buffer function may be lost. From this point, in particular, the transport unit disclosed in Patent Document 2 is not suitable for a heavy solar panel.
Japanese Patent No. 4277070 Japanese Patent No. 4284895

  Therefore, in view of the above technical problems, an object of the present invention is to provide a vertically mounted thin plate panel transport unit capable of stably transporting a plurality of thin plate panels in a vertical position while reducing costs.

In order to solve the above problems, a transport unit for transporting a plurality of thin plate panels according to the present invention is a transport unit for transporting a plurality of thin panel panels stored vertically,
A rectangular pallet;
A cylindrical sleeve having a rectangular cross-section that is detachably fixed to the rectangular pallet at the lower end and is lower than the height of the thin panel;
Four corner angles each having an L-shaped cross section and projecting upward from at least the upper end of the cylindrical sleeve in a form applied from the outside to each of the four corners of the cylindrical sleeve of the rectangular cross section;
Each having a pair of substantially rectangular parallelepiped spacers provided with a plurality of grooves parallel to each other at a predetermined interval in the longitudinal direction on one surface, and arranged so that the one surface faces each other, Each of the plurality of grooves has a width capable of receiving a side end portion of a thin plate panel stored vertically in the cylindrical sleeve having the rectangular cross section, and extends over the entire direction perpendicular to the longitudinal direction.
The groove of one spacer and the corresponding groove of the other spacer are spaced so that the thin panel can be held vertically in the cylindrical sleeve of the rectangular cross section,
The pair of spacers includes a pair of first lower spacers provided on an upper surface of the rectangular pallet, and a pair of second lower spacers provided one by one on the upper end of the opposed inner surface of the cylindrical sleeve having the rectangular cross section. A pair of upper spacers provided one by one so as to bridge the upper ends of the adjacent corner angles, and the corresponding grooves of each of the first lower spacer and the second lower spacer are in the vertical direction. It is set as the structure provided so that it may arrange | position on the same surface at intervals.

According to the vertical thin plate panel transport unit having the above configuration, each side edge of the thin plate panel is accommodated when the thin plate panel is vertically accommodated in the rectangular sleeve from the upper opening of the rectangular sleeve. In a state where the portion is received in the groove of the corresponding second lower spacer, it can be easily accommodated in the cylindrical sleeve having a rectangular cross section while being guided by the groove by moving downward toward the upper surface of the rectangular pallet. Is possible. In this case, since the corresponding grooves of each of the first lower spacer and the second lower spacer are provided on the same plane with an interval in the vertical direction, the lower end surface of the thin panel is a rectangular pallet. If it abuts on the upper surface, the middle and lower ends of the side edges of the thin panel are respectively supported and positioned by the corresponding grooves of the first lower spacer and the second lower spacer, respectively.
A plurality of thin plate panels are housed in a cylindrical sleeve having a rectangular section using the groove guiding function in the same manner, and the structural strength is increased by assigning corner angles to the four corners of the cylindrical sleeve having a rectangular section. After securing, the upper spacers provided so as to bridge the upper ends of adjacent corner angles are applied to the side edges of each of the thin panel panels via grooves, so that the cylinder with a rectangular cross-section is caused by vibration during transportation. It is possible to position in a cylindrical sleeve having a rectangular cross section so that adjacent thin plate panels in the cylindrical sleeve do not collide and cause problems such as breakage.
As described above, as in the prior art, in order to store a plurality of thin plate panels in the box body, the thin plate panel can be safely disposed without providing a buffer body having a groove having a guiding function on the entire inner surface facing the box body. Cost is reduced by providing a cylindrical sleeve with a rectangular cross-section of the height necessary for transporting, reducing the amount of material, and placing spacers with a thin panel guide function or thin panel protection function in the right place. It is possible to provide a transport unit of a thin plate panel that can be stably transported while achieving reduction.

Further, the groove provided in each of the pair of second lower spacers has a length sufficient to provide a guiding function for storing the thin plate panel in the cylindrical sleeve having the rectangular cross section from above,
It is preferable that the pair of upper spacers have sufficient buffering properties to provide a protective function for the thin panel.
Furthermore, it further includes a lid portion that covers the upper ends of the four corner angles and a body swelling prevention material that is provided so as to span the opposing inner surfaces.
The torsion preventing material preferably has a recess at each end, having a width corresponding to the thickness of the cylindrical sleeve having the rectangular cross section and opening downward.

Furthermore, the corner angle is made of corrugated cardboard, and the stretch film wound around the portion protruding from the rectangular cross-section cylindrical sleeve of a plurality of thin plate panels housed in the rectangular cross-section cylindrical sleeve is prevented. The material should be formed.
In addition, the upper spacer has a rectangular cross-section having a lateral surface and a longitudinal surface extending over the entire longitudinal direction and intersecting each other, and the plurality of grooves are respectively the lateral surface and the longitudinal surface. Preferably, the upper spacer is formed with a lid that covers from above the upper edge of each of the plurality of thin plate panels accommodated in the cylindrical sleeve having the rectangular cross section.
Further, between the second lower spacer and the upper spacer, corresponding sides of portions projecting from the rectangular cross-section cylindrical sleeves of the plurality of thin plate panels accommodated in the rectangular cross-section cylindrical sleeve, respectively. A pair of middle spacers applied to the end portions are further provided, and the middle spacers preferably have sufficient buffering properties to provide a protective function for the thin panel.

Furthermore, the rectangular pallet has a circumferential groove along the periphery of the upper surface,
The lower end of the cylindrical sleeve can be fitted into the circumferential groove,
Each of the four corner angles may have a lower end portion that can be fitted into the circumferential groove in a form in which the four corner angles are respectively applied to the four corners of the cylindrical sleeve.
In addition, the thin panel may be a rectangular solar panel.

Embodiments of a vertically placed thin panel transport unit 10 according to the present invention will be described below in detail with reference to the drawings, taking a rectangular solar panel P as an example of a thin panel.
The solar panel P has a thin plate shape in which cells are connected in series and protected by resin, tempered glass, or a metal frame. More specifically, the solar panel P is made of silicon between a glass layer and a plastic layer or between a glass layer and a glass layer. It is a laminated structure in which cells composed of the above are embedded, and has a thickness of several millimeters, an area of several square meters, and a weight of 10 to 30 kg.

As shown in FIG. 1, a transport unit 10 for transporting a plurality of solar panels stored vertically is fixed to a rectangular pallet 12 and a rectangular pallet 12 and has a rectangular cross section lower than the height of the solar panel. The cylindrical sleeve 14, four corner angles 18 projecting upward from the upper end 16 of the cylindrical sleeve 14, and a pair of spacers 34, 38, 39, and 40 each having a substantially rectangular parallelepiped shape.
As shown in FIG. 1, the cylindrical sleeve 14 is detachably fixed to the rectangular pallet 12 at the lower end periphery, is lower than the height of the solar panel P, and has a rectangular cross section. The height of the cylindrical sleeve 14 may be appropriately determined according to the height of the solar panel P stored vertically, but from the viewpoint of stability when storing the solar panel P, the solar panel P About half of the height is preferable. The length of each of the long side and the short side of the rectangular cross section may be determined as appropriate according to the width of the solar panel P to be stored vertically and the planned number of installations. The material of the cylindrical sleeve 14 is preferably made of cardboard or resin.

The mechanism 49 for detachably fixing the cylindrical sleeve 14 to the rectangular pallet 12 will be described. As shown in FIG. 13, the mechanisms 49 are respectively provided on the opposite side surfaces of the cylindrical sleeve 14, and the cylindrical sleeve 14. And a receiving portion 56 provided in the rectangular pallet 12 that can be engaged with the flange member 52.
The eaves member 52 has a rectangular plate shape, and a claw portion 54 is formed at the lower end of the eaves member 52 by notching a position away from the bottom of the eaves member 52 by a predetermined distance. On the other hand, the rectangular pallet 12 has a receiving portion 56 for engaging the claw portion 54, and a part of the bulging portion 53 protruding in the circumferential groove 24 for fitting the cylindrical sleeve 14 is formed in a tunnel shape. An opening is formed.
As shown in FIG. 14, the claw portion 54 engages with the receiving portion 56 of the rectangular pallet 121 to fix the rectangular pallet 12 and the cylindrical sleeve 14. The eaves member 52 can be rotated so as to slide on the outer surface of the cylindrical sleeve 14 by a fixing member described later.
As shown in FIG. 14, the collar member 52 is formed with a finger insertion hole 58 for inserting a finger when the collar member 52 is rotated, and the collar member 52 extends along the cylindrical sleeve 14 by a shaft stopping member 53. And is pivotally fixed.
As shown in FIG. 15A, the shaft locking member 53 for fixing the flange member 52 to the cylindrical sleeve 14 includes a first fixing member 60 and a second fixing member 62. The first fixing member and the second fixing member are engaged with each other so as to sandwich the cylindrical sleeve 14. As shown in FIG. 14B, the first fixing member 60 is locked by the locking member 61 of the first fixing member 60 described later being locked to the reduced diameter portion 63 of the second fixing member 62 described later. It is fixed to the second fixing member 62 and cannot be removed. Utilizing this fact, the flange member 52 is attached to the cylindrical sleeve 14. In a state where the flange member 52 is attached to the cylindrical sleeve 14, the first fixing member 60 and the flange member 52 are integrally fixed by fitting or the like.

The first fixing member 60 is configured such that a pair of locking members 61 and a pair of latching members 65 at the crossing position are provided on the substrate in an annular shape. The locking member 61 is formed with a locking projection 67 for preventing the first fixing member 60 from coming off the second fixing member 62. A hooking protrusion 69 is formed on the hooking member 65. An annular center formed by the pair of latching members 61 and the pair of latching members 65 by allowing the latching projection 69 to be latched in a latching groove 65 of the second fixing member 62 described later. The eaves member 52 can be intermittently rotated around the position, and a so-called click feeling is generated in the operation of the user.
On the other hand, the second fixing member 62 includes a cylindrical main body 71 and a flange extending outward from the edge of the main body 71. The inner wall of the main body 71 is formed with a reduced diameter portion 63 protruding from the inner wall. The reduced diameter portion 63 is formed with a plurality of latching grooves 73 for latching the latching protrusions 69, and there are also a plurality of other latching grooves 73 at positions facing the latching grooves 73. It is formed. On the other hand, the latching protrusion 69 of the latching member 65 of the first fixing member 60 is latched in the latching groove 73 of the second fixing member 62. Since the first fixing member 60 moves integrally with the hook member 52, the hook protrusions 69 are sequentially engaged with the hook grooves 73 when the hook member 52 rotates. Therefore, the user can rotate the saddle member 52 while temporarily stopping the saddle member 52 at a constant angle.

As shown in FIGS. 1 and 2, the rectangular pallet 12 has a cylindrical sleeve 14 and four corner angles 18 to be described later fixed to the upper surface 22, and has a circumferential groove 24 along the periphery of the upper surface 22. The lower end portion of the cylindrical sleeve 14 can be fitted into the circumferential groove 24, and four corner angles 18 to be described later are respectively applied to the four corners of the cylindrical sleeve 14 from the outside. It can be fitted in the circumferential groove 24. The rectangular pallet 12 is provided with a fork insertion opening 13 of a forklift used for conveyance, and is preferably made of resin from the viewpoint of ensuring strength. As will be described later, when a plurality of solar panels P are accommodated vertically, the thermoplastic sheet 60 having a predetermined thickness is placed on the upper surface 22 so that the lower end surface of the solar panel P does not directly contact the upper surface 22. The panel P is pasted at positions corresponding to both sides of the lower end surface.
The resin material of the rectangular pallet 12 is a thermoplastic resin, such as an olefin resin such as polyethylene or polypropylene, or an amorphous resin, and more specifically ethylene, propylene, butene, isoprene pentene, methyl pentene, or the like. A polyolefin (for example, polypropylene or high-density polyethylene) which is a homopolymer or copolymer of olefins, and can be molded by a known molding method as appropriate, such as vacuum molding, blow molding or injection molding.

As shown in FIG. 1, four corner angles 18 are provided, each having an L-shaped cross section, and at least a cylindrical sleeve in a form applied from the outside to each of the four corners of the cylindrical sleeve 14 having a rectangular cross section. 14 protrudes upward from the upper end 16 of 14.
The corner angle 18 is made of corrugated cardboard, and the thickness thereof may be appropriately determined from the viewpoint of securing strength so as to function as a strength material, particularly when the transport units 10 are stacked. Further, the corner angle 18 is formed of a stretch film 26 (see FIG. 12) wound around a portion protruding from the cylindrical sleeve 14 having a rectangular cross section of a plurality of solar panels P housed in the cylindrical sleeve 14 having a rectangular cross section. Form a tear prevention material. More specifically, it is possible to avoid the risk that the stretch film 26 is broken by the exposed sharp corners of the plurality of solar panels P to be stored. A lid portion 43 is provided so that the upper end portions of the four corner angles 18 are inserted therein, and reinforcing members 45 having an L-shaped cross section are applied to both ends of the lid portion 43.

As shown in FIG. 1, the pair of spacers are a pair of first lower spacers 34 positioned on the upper surface 22 of the rectangular pallet 12 and a pair of upper spacers 16 positioned on the opposing inner surface 36 of the cylindrical sleeve 14 having a rectangular cross section. Each of the first lower spacer 34 and the second lower spacer 38. The second lower spacer 38 and a pair of upper spacers 40 fixed one by one so as to bridge the upper ends of the adjacent corner angles 18 are provided. Corresponding grooves 30 are provided so as to be arranged on the same plane with an interval in the vertical direction.
Since the pair of first lower spacers 34 and the pair of second lower spacers 38 have substantially the same structure, the pair of first lower spacers 34 will be described as shown in FIG. Each of the spacers 34 has a substantially rectangular parallelepiped shape including a plurality of grooves 30 that are parallel to each other at a predetermined interval in the longitudinal direction on one surface 28, and are arranged so that the one surface 28 faces each other. The length in the longitudinal direction of the spacer may be determined according to the number of solar panels P to be accommodated in the cylindrical sleeve 14, that is, the number of necessary grooves 30, but in the present embodiment, a pair of spacers is provided. It has a length corresponding to the width of the inner surface of the cylindrical sleeve 14 to be mounted. The interval between the adjacent grooves 30 may be determined as appropriate so that the adjacent solar panels P in the cylindrical sleeve 14 do not come into contact with each other during conveyance.

Each of the plurality of grooves 30 has a width W that can receive the side end portion 32 of the solar panel P stored vertically in the cylindrical sleeve 14 having a rectangular cross section, and extends over the entire direction orthogonal to the longitudinal direction. The groove 30 of one spacer that is attached to one of the opposing inner surfaces of the cylindrical sleeve 14 and the corresponding groove 30 of the other spacer that is attached to the other of the cylindrical sleeves 14 The spacing is such that it can be held vertically in the cylindrical sleeve 14. In addition, it is preferable that the groove | channel 30 has a cross-sectional shape of a divergent shape toward the inner side of the cylindrical sleeve 14, so that the side edge part 32 of the solar panel P may be received easily.
In each of the pair of first lower spacers 34, the grooves 30 provided in each of them have a length L (see FIG. 3) sufficient to provide a guiding function for storing the solar panel P in the cylindrical sleeve 14 having a rectangular cross section from above. See).
As shown in FIG. 4, the pair of upper spacers 40 has a rectangular cross-sectional recess 46 having a lateral surface 42 and a longitudinal surface 44 that extend over the entire longitudinal direction and intersect each other. The upper spacer 40 is provided across the horizontal surface 42 and the vertical surface 44, respectively, and the upper spacer 40 covers the upper side end portions of each of the plurality of solar panels P accommodated in the cylindrical sleeve 14 having a rectangular cross section. The cap is formed and has sufficient buffering properties to perform the protective function of the solar panel P.

Further, a pair of middle spacers 39 are provided between the second lower spacer 38 and the upper spacer 40, and each of the plurality of solar panels P accommodated in the cylindrical sleeve 14 having a rectangular cross section has a cylindrical shape. It is applied to the corresponding side end portion 32 of the portion protruding from the sleeve 14, and has a sufficient cushioning property to exhibit the protective function of the solar panel P, like the pair of upper spacers 40.
The pair of spacers are made of foamed resin. In particular, in the case of the pair of upper spacers 40 and the pair of middle spacers 39, if the thickness and / or the foaming ratio are appropriately determined, buffering properties can be ensured. Good.
As shown in FIG. 1, the upper end 16 of the cylindrical sleeve 14 is provided with a body swelling prevention material 50 so as to span the opposing inner surfaces 36. As shown in FIG. 5, the torsion preventing material 50 is provided with a width W1 corresponding to a thickness obtained by adding the thickness of the cylindrical sleeve 14 and the thickness of the second lower spacer 38 at each end portion 51 and opens downward. A recess 47 is formed. A small protrusion 75 is provided at the lower end of the opening of each recess 47, and when the recess 47 is fitted into the upper edge of the cylindrical sleeve 14 provided with the second lower spacer 38 from above, the cylindrical sleeve 14 is firmly fixed. As a result, for example, due to vibration during transportation or by stacking the conveyance units 10, the cylindrical sleeve 14 of the lower conveyance unit 10 is opposed to the opposite side wall surface of the cylindrical sleeve 14 due to the weight of the upper conveyance unit 10. A so-called torso bulge that deforms so that the relative position is disengaged occurs, the side end portion 32 of the stored solar panel P falls out of the corresponding groove 30, and the adjacent solar panels P come into contact with each other. In addition, it is possible to prevent a situation where the panel is damaged or damaged, and by installing the anti-bulging material 50 between the adjacent grooves 30, the storage of the solar panel P can be prevented. It is possible not to become. The depth D of each recess 47 may be determined from such a viewpoint.

The operation of the thin plate transport unit 10 having the above configuration will be described in detail below with reference to the drawings.
First, as shown in FIG. 6, the cylindrical sleeve 14 is installed on the rectangular pallet 12, and the pair of first lower spacers 34 and the pair of second lower spacers 38 are attached to the cylindrical sleeve 14. .
More specifically, first, the cylindrical sleeve 14 is locked to the rectangular pallet 12. In this case, the hook member 52 is rotated, and the claw portion 54 is engaged with the receiving port portion 56 of the rectangular pallet 12 to be locked. Next, each of the pair of first lower spacers 34 and the pair of second lower spacers 38 is applied with a double-sided tape, for example, on the surface opposite to the surface having the groove 30, thereby the inner surface 36 of the cylindrical sleeve 14. Fix it. At this time, when the solar panel P is stored in the cylindrical sleeve 14, the pair of first lower spacers so that the groove portions of the pair of first lower spacers 34 and the pair of second lower spacers 38 have a guiding function. The 34 grooves 30 and the corresponding grooves of the pair of second lower spacers 38 are arranged on the same plane with an interval in the vertical direction so as to be aligned in the vertical direction.

Next, as shown in FIG. 7, the three torsion preventing materials 50 are wound around the upper end 16 of the cylindrical sleeve 14 in parallel with each other.
More specifically, the concave portions 47 provided at the respective end portions 51 of the three body swelling prevention members 50 are fitted into the corresponding portions of the second lower spacer 38 where there are no grooves 30, and the inner surfaces of the cylindrical sleeve 14 facing each other. 36. For example, when the completed conveyance units 10 are stacked, the three cylinder swelling prevention materials 50 effectively prevent the cylindrical sleeve 14 of the lower conveyance unit 10 from being swollen by the weight of the upper conveyance unit 10. From the viewpoint of prevention, it is preferable that the second lower spacer 38 of the cylindrical sleeve 14 is disposed at a substantially central portion in the longitudinal direction.

Next, as shown in FIG. 8, the solar panels P are stored one by one in the cylindrical sleeve 14 in the vertical direction.
More specifically, when the solar panel P is accommodated vertically from the upper opening of the cylindrical sleeve 14 having the rectangular cross section into the cylindrical sleeve 14 having the rectangular cross section, each side end portion 32 of the solar panel P corresponds. By being moved downward toward the upper surface 22 of the rectangular pallet 12 while being received in the groove 30 of the second lower spacer 38, it is easily accommodated in the cylindrical sleeve 14 having a rectangular cross section while being guided by the groove 30. It is possible. In this case, since the groove 30 is not provided over the entire height direction of the cylindrical sleeve 14, the frictional resistance between the side end portions 32 of the solar panel P and the groove 30 is small, and the solar panel P is smooth. It is possible to store in.
In this case, since the corresponding grooves 30 of the first lower spacer 34 and the second lower spacer 38 are provided so as to be aligned with each other in the vertical direction, the lower end surface of the solar panel P is the upper surface 22 of the rectangular pallet 12. If it contacts, the intermediate part and the lower end of each side edge part 32 of the solar panel P are respectively supported and positioned by the corresponding grooves 30 of the first lower spacer 34 and the second lower spacer 38, respectively.
If a plurality of solar panels P are accommodated in the cylindrical sleeve 14 having a rectangular cross section by using the guiding function of the groove 30 in the same manner, the adjacent grooves of the first lower spacer 34 and the second lower spacer 38 respectively. The interval between 30 becomes the stacking pitch of the solar panels P (for example, 30 mm), and when the transport unit 10 is transported, the situation where the adjacent solar panels P collide with each other due to the vibration at that time and are damaged is effective. It is possible to prevent.

Next, as shown in FIG. 9, a pair of middle spacers 39 and a pair of upper spacers 40 protrude from the cylindrical sleeve 14 and are applied to a plurality of exposed solar panels P.
More specifically, the pair of middle spacers 39 are fixed to the corresponding side end portions 32 of the plurality of aligned solar panels P by, for example, double-sided tape, while the pair of upper spacers 40 are aligned with the plurality of aligned spacers. It arrange | positions so that it may cover from the upper part the upper edge part of the corresponding side edge part 32 of the solar panel P of. More specifically, the groove portion of the vertical surface 44 is applied to the side end portion 32 from the side, and the groove portion of the horizontal surface 42 is applied to the upper end portion from above.
In addition, about the installation level of a pair of middle spacer 39, in order to protect the several solar panel P in the cylindrical sleeve 14 in conveyance like a pair of upper spacer 40, it installs so that a buffer function may be show | played Therefore, the central portion of the exposed portion of the plurality of solar panels P, that is, the central portion of the pair of second lower spacers 38 and the pair of upper spacers 40 installed at the upper end 16 of the cylindrical sleeve 14 is used. It is preferable to install in.

Next, as shown in FIG. 10, corner angles 18 are fixed to the four corners of the cylindrical sleeve 14.
More specifically, the lower end portion of the corner angle 18 is fitted to the corresponding corner portion of the cylindrical sleeve 14 from the outside, and is fitted into the circumferential groove 24 of the rectangular pallet 12, and the intermediate portion of the corner angle 18 is paired with a pair of middle spacers. It fixes to the corresponding edge part of 39 with a double-sided tape, for example.

  Next, as shown in FIG. 11, the lid 43 is placed on the upper ends of the plurality of solar panels P in such a manner that the tops of the four corner angles 18 are inserted inside. In particular, when the transport units 10 are stacked, the reinforcing member 45 having an L-shaped cross section may be fixed to both end portions of the lid portion 43.

Next, as shown in FIG. 12, the stretch film 26 is wound around the exposed portions of the plurality of solar panels P.
More specifically, by collapsing a plurality of solar panels P with the stretch film 26 having shrinkage, it is possible to effectively prevent the collapse of the load during conveyance. At this time, even if the stretch film 26 is tightly wound, the sharp portions at the four corners of the plurality of solar panels P are directly connected to the inner surface 36 of the stretch film 26 by the corner angles 18 applied to the four corners of the plurality of solar panels P. It is possible to effectively prevent the stretch film 26 from being broken as compared with the case of hitting.

Next, the transport unit 10 is completed by hanging a band (not shown) around the upper end and the opposite side surface of the solar panel P in an inverted U shape.
If necessary, a new transport unit 10 may be completed and stacked on the upper surface of the lid portion 43. In this case, the corner angles 18 applied to the four corners of the plurality of solar panels P function as strength members.
When the completed transport unit 10 is transported, for example, by inserting a fork of a forklift into the fork insertion opening 13 of the rectangular pallet 12, or when transported by loading on a truck, the transport unit 10 is loaded vertically due to vibrations associated with transport or transport. A plurality of solar panels P are displaced in the inside of the cylindrical sleeve 14, and the adjacent solar panels P collide with each other so that they can be stably transported or transported without being damaged or damaged. Is possible.
In addition, when unpacking at the destination, the work may be performed according to the reverse procedure. Also, when storing without unpacking, store each solar panel P in a non-contact state and reduce storage space compared to stacking solar panels P horizontally and vertically. Is possible.

According to the vertical thin plate panel transport unit 10 having the above configuration, when the solar panel P is accommodated vertically from the upper opening of the rectangular sleeve 14 into the rectangular sleeve 14, In a state where each side edge of the optical panel P is received in the corresponding groove 30 of the second lower spacer 38, it is easily moved while being guided by the groove 30 by moving downward toward the upper surface 22 of the rectangular pallet 12. It can be accommodated in a cylindrical sleeve 14 having a rectangular cross section. In this case, since the corresponding grooves 30 of the first lower spacer 34 and the second lower spacer 38 are provided so as to be aligned with each other in the vertical direction, the lower end surface of the solar panel P is the upper surface 22 of the rectangular pallet 12. If it contacts, the intermediate part and the lower end of each side edge part 32 of the solar panel P are respectively supported and positioned by the corresponding grooves 30 of the first lower spacer 34 and the second lower spacer 38, respectively.
A plurality of solar panels P are accommodated in the cylindrical sleeve 14 having a rectangular cross section by using the guide function of the groove 30 in the same manner, and corner angles 18 are assigned to the four corners of the cylindrical sleeve 14 having the rectangular cross section. Thus, after ensuring the structural strength, the upper spacer 40 provided so as to bridge the upper ends of the adjacent corner angles 18 is applied to the side end portions 32 of each of the plurality of solar panels P via the grooves 30. Thus, positioning in the cylindrical sleeve 14 having the rectangular cross section prevents the adjacent solar panels P from colliding with each other in the cylindrical sleeve 14 having the rectangular cross section and causing problems such as breakage due to vibration during conveyance. Is possible.

  From the above, in order to store the entire plurality of solar panels P in the box as in the past, the solar panel without providing a buffer having a groove having a guiding function on the entire inner surface facing the box A cylindrical sleeve 14 having a rectangular cross section having a height necessary for safely transporting P is provided to reduce the amount of material, and a spacer having a solar panel P guiding function or a solar panel P protecting function is provided. By arranging the right material at the right place, it is possible to provide the transport unit 10 of a thin panel that can be stably transported while reducing the cost.

The embodiments of the present invention have been described in detail above, but various modifications or changes can be made by those skilled in the art without departing from the scope of the present invention.
For example, in the present embodiment, the case where each of the pair of first lower spacers 34 is fixed to the opposing inner surfaces of the cylindrical sleeve 14 has been described. However, the present invention is not limited thereto. Unlike the optical panel P, if the panel is light and there is no risk of the groove 30 being crushed by the weight of the panel, the opening of the groove 30 faces upward and is fixed to the upper surface of the rectangular pallet 12. The groove 30 of the first lower spacer 34 and the corresponding groove 30 of the second lower spacer 38 may be arranged on the same plane with a space in the vertical direction.
Further, in the present embodiment, the pair of middle spacers 39 and the pair of upper spacers 40 are mounted on the inner surfaces of the cylindrical sleeve 14 to which the pair of first lower spacers 34 and the pair of second lower spacers 38 are fixed, respectively. However, the present invention is not limited thereto, and may be fixed to the inner surface intersecting with the inner surface of the cylindrical sleeve 14 to which the lower spacer is fixed.
Furthermore, in this embodiment, the cylindrical sleeve, the corner angle, the body swelling prevention material, and the cap are each made of corrugated cardboard. However, the present invention is not limited to this. For example, when transporting in an environment wet with rain or the like, May be made of resin.

It is a whole perspective view of the conveyance unit of the vertically installed thin plate panel which concerns on embodiment of this invention. It is a perspective view of the upper surface of the pallet of the conveyance unit of the vertically placed thin panel according to the embodiment of the present invention. It is a perspective view of the lower spacer of the conveyance unit of the vertically mounted thin panel according to the embodiment of the present invention. It is a perspective view of the body swelling prevention material of the conveyance unit of the vertical-placement thin panel which concerns on embodiment of this invention. It is a perspective view of the upper spacer of the conveyance unit of the vertically placed thin panel according to the embodiment of the present invention. It is a perspective view which shows the condition which installs a cylindrical sleeve in the pallet of the conveyance unit of the vertical-position thin board panel which concerns on embodiment of this invention. It is a perspective view which shows the condition which installs the cylinder swelling prevention material 50 in the cylindrical sleeve of the conveyance unit of the vertical-position thin board which concerns on embodiment of this invention. It is a perspective view which shows the condition which inserts a thin plate panel in the cylindrical sleeve of the conveyance unit of the vertical-placement thin plate panel which concerns on embodiment of this invention. It is a perspective view which shows the condition which attaches a middle spacer and an upper spacer to the thin panel in the cylindrical sleeve of the conveyance unit of the vertical-placement thin panel which concerns on embodiment of this invention. It is a perspective view which shows the condition which installs the corner angle of the conveyance unit of the vertical-position thin board panel which concerns on embodiment of this invention. It is a perspective view which shows the condition which puts a cap on the top part of the corner angle of the conveyance unit of the vertically mounted thin panel which concerns on embodiment of this invention. It is a perspective view which shows the condition which winds a stretch form around the corner angle of the conveyance unit of the vertical-position thin board which concerns on embodiment of this invention. It is the elements on larger scale around the collar member of the conveyance unit of the vertical-position thin board panel which concerns on embodiment of this invention. In FIG. 13, it is the elements on larger scale seen from the other side on both sides of the cylindrical sleeve. It is sectional drawing which shows the state which fixed the collar member which concerns on this embodiment to the sleeve using a shaft stop member, and Fig.15 (a) is before engaging a 1st fixing member and a 2nd fixing member. FIG. 15B is a cross-sectional view showing the state after the first fixing member and the second fixing member are engaged.

P Solar panel
W width 10 conveying unit 12 rectangular pallet 14 cylindrical sleeve 18 corner angle 22 upper surface 24 circumferential groove 26 stretch film 30 groove 32 side end 34 pair of first lower spacers 36 inner surface 38 pair of second lower spacers 39 pair of medium Spacer 40 A pair of upper spacers 42 Horizontal surface 44 Vertical surface 46 Concave portion 47 Concave portion 43 Lid portion 50 Body bulge prevention material 51 End portion 52 Gutter member 53 Swelling portion 54 Claw portion 56 Receiving portion 58 Finger insertion hole 60 First fixing member 61 Locking member 62 Second fixing member 63 Reduced diameter portion 65 Locking member 67 Locking protrusion 69 Locking protrusion 71 Main body portion 73 Locking groove

Claims (8)

A transport unit for transporting a plurality of thin plate panels stored vertically,
A rectangular pallet;
A cylindrical sleeve having a rectangular cross-section that is detachably fixed to the rectangular pallet at the lower end and is lower than the height of the thin panel;
Four corner angles each having an L-shaped cross section and projecting upward from at least the upper end of the cylindrical sleeve in a form applied from the outside to each of the four corners of the cylindrical sleeve of the rectangular cross section;
Each having a pair of substantially rectangular parallelepiped spacers provided with a plurality of grooves parallel to each other at a predetermined interval in the longitudinal direction on one surface, and arranged so that the one surface faces each other, Each of the plurality of grooves has a width capable of receiving a side end portion of a thin plate panel stored vertically in the cylindrical sleeve having the rectangular cross section, and extends over the entire direction perpendicular to the longitudinal direction.
The groove of one spacer and the corresponding groove of the other spacer are spaced so that the thin panel can be held vertically in the cylindrical sleeve of the rectangular cross section,
The pair of spacers includes a pair of first lower spacers provided on an upper surface of the rectangular pallet, and a pair of second lower spacers provided one by one on the upper end of the opposed inner surface of the cylindrical sleeve having the rectangular cross section. A pair of upper spacers provided one by one so as to bridge the upper ends of the adjacent corner angles, and the corresponding grooves of each of the first lower spacer and the second lower spacer are in the vertical direction. A transport unit for a vertically placed thin plate panel, characterized in that the transport unit is provided so as to be arranged on the same surface with an interval therebetween. The groove provided in each of the pair of second lower spacers has a length sufficient to provide a guiding function for storing the thin plate panel in the cylindrical sleeve having the rectangular cross section from above.
2. The transport unit for a vertically mounted thin panel according to claim 1, wherein the pair of upper spacers has a sufficient buffering property to exhibit a protective function of the thin panel. Furthermore, it has a lid portion covering the upper ends of the four corner angles, and a body swelling prevention material provided so as to span the opposing inner surfaces,
The torsion preventing material has a width corresponding to a thickness obtained by adding the thickness of the cylindrical sleeve having the rectangular cross section and the thickness of the pair of second lower spacers at each end, and has a recess opening downward. The conveyance unit of the vertically placed thin panel according to claim 1.   The corner angle is made of corrugated cardboard, and forms a stretch film tear prevention material that is wound around a portion protruding from the rectangular cross-section cylindrical sleeve of a plurality of thin plate panels accommodated in the rectangular cross-section cylindrical sleeve. The conveying unit of the vertically placed thin panel according to claim 1.   The upper spacer has a rectangular cross-sectional recess that extends in the entire longitudinal direction and has a transverse surface and a longitudinal surface intersecting each other, and the plurality of grooves span the lateral surface and the longitudinal surface, respectively. The vertical spacer according to claim 1, wherein the upper spacer forms a lid portion that covers a top edge of each of a plurality of thin plate panels accommodated in the cylindrical sleeve having the rectangular cross section from above. Thin panel transport unit.   Furthermore, the side corresponding to the part which protrudes from the cylindrical sleeve of the rectangular cross section of the some thin panel accommodated in the cylindrical sleeve of the rectangular cross section between the said 2nd lower spacer and the said upper spacer, respectively. The transport unit for a vertically placed thin plate panel according to claim 1, wherein a pair of middle spacers applied to the end portions are provided, and the middle spacers have sufficient buffering properties to perform a protective function of the thin plate panel. The rectangular pallet has a circumferential groove along the periphery of the upper surface;
The lower end of the cylindrical sleeve can be fitted into the circumferential groove,
The conveyance of the vertically placed thin panel according to claim 1, wherein each of the four corner angles has a lower end portion that can be fitted into the circumferential groove in a form applied to each of the four corners of the cylindrical sleeve. unit.   The said thin plate panel is a conveyance unit of the vertically installed thin plate panel of any one of Claim 1 thru | or 7 which is a rectangular-shaped solar panel.

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