JP5109512B2 - Storage device for plate-like body - Google Patents

Description

  The present invention relates to a storage device for a plate-like body.

  Conventionally, a glass plate pallet has been used when transporting a multilayer glass. Since this glass plate pallet contains and ships various sizes of glass plates required at the work site, any glass plates can be removed in any order during the process of attaching to the sash at the work site. In order to cope with this, it is generalized that the glass plate is packed independently. Patent Documents 1 to 3 disclose a glass plate pallet that is suitably used for transporting and taking out glass plates.

The glass plate pallet described in Patent Document 1 is generally configured from a rectangular parallelepiped frame, a plurality of slits, and a detachable stopper. The frame has a plate glass outlet. The slit is composed of a plurality of partition bars.
Glass plates A, B, and C, large and small, are placed one by one between the slits in an upright state from the loading / unloading port, and are always sandwiched by one of the partition bars, so that glass plates of different sizes can be stored and handled. It is disclosed that it becomes possible.

In addition, the glass plate pallet described in Patent Document 2 includes a floor portion that is vertically and horizontally framed, a back frame that is fixedly attached to the floor portion, a front frame and a side stopper that are detachably provided, and a plurality of partition members. It is roughly composed of A support member is provided on the floor, and supports the lower end side of the glass plate. Moreover, the partition member is provided in the diagonal form of the glass plate, and has partitioned adjacent glass plates. Further, the front frame is provided with a front stopper and a front pressing tool, and is in contact with the front frame side vertical side of the glass plate. Moreover, the rear part is provided in the floor part, and presses the back frame side vertical side of a glass plate.
Thus, it is disclosed that glass plates of different sizes can be stored and transported because the three sides of the glass plate are sandwiched and fixed. Also, since the end of the glass plate can be aligned on the front frame side, it is possible to take out a glass plate of any size from the side where the end of the glass is aligned by removing the front frame and side stopper This is disclosed.

Furthermore, the glass plate pallet described in Patent Document 3 is generally configured by a floor portion, an upright rear wall that intersects the floor portion at a substantially right angle, and an elastic restraint body. The edge of the glass plate is in contact with the floor and the rear wall and is supported vertically, and the glass plates are partitioned by a grooved panel unit provided on the rear wall. Furthermore, each elastic restraint body contact | abuts to the upper front corner | angular part of each glass plate, and is pressing this.
Thus, it is disclosed that glass plates of different sizes can be stored and transported because the two sides of the glass plate are sandwiched and fixed.
JP-A-10-86941 JP 2001-253485 A Japanese Patent No. 3273149

The pallet for glass plates described in Patent Documents 1 to 3 is suitable for accommodating glass plates of various sizes, and can accommodate the glass plates of various sizes in an arbitrary order.
In particular, in the case of double-glazed glass, the total thickness of the whole changes greatly depending on the thickness of the internal air layer, so that the thickness of the plate glass accommodated varies.
The glass plate pallets disclosed in Patent Literatures 1 to 3 have slits, partition members, or grooved panels, and can accommodate plate glass having various thicknesses within the range of the slits and the like.
However, in the pallet for glass plates of Patent Documents 1 to 3, the glass surface is kept away from scratching so as not to be scratched, and since two to three edges of the glass plate are held, a slit or the like and the plate glass There is a gap. Therefore, it has been necessary to protect the glass surface by packing a buffer material in the gap between the slit or the like and the plate glass. As a result, there is a problem that work at the time of packing or unpacking takes time and waste is generated at the time of unpacking.

Further, in the glass plate pallet described in Patent Document 1 and Patent Document 3, since the edge of the glass plate opposite to the take-out side is in contact with the frame or the back plate, for example, it is accommodated between large glasses. There was a problem that it was difficult to take out the small glass.
On the other hand, in patent document 2, since the glass edge part is arranged in the extraction side of a glass plate, the extraction of the small glass between large glass is attained. However, since it is difficult to handle the side stopper that fixes the glass plate to the front frame side, and it is difficult to remove the front frame and the side stopper, there is a problem that workability is poor.

The present invention has been made in view of the above circumstances, and it is possible to simultaneously load plate bodies of different sizes and plate bodies of different thicknesses, and packaging work is easy. And it aims at providing the storage apparatus for plate-shaped objects which a waste does not generate | occur | produce at the time of unpacking.
It is another object of the present invention to provide a storage device for a plate-like body that can be easily taken out.

In order to achieve the above object, the present invention employs the following configuration.
The storage device for a plate-like body of the present invention includes a base portion and a plurality of partition members attached on the base portion, and the plate-like body is erected between a pair of partition members. The plate-like body is placed on the base, and a part of the partition member is brought into contact with one surface and the other surface of the plate-like body so that the plate-like body is sandwiched and fixed by the pair of partition members. A storage device for a plate-like body,
The partition member includes a rotatable rotating shaft that is erected substantially vertically from the base portion, and a base end portion that is attached at a height between the upper end and the lower end of the rotating shaft depending on the size of the plate-like body. Is attached to the rotary shaft body in such a manner that the front end portion of the plate-like body is protruded in a direction substantially perpendicular to the axial direction of the rotary shaft body, and the contact surface is directed to one surface or the other surface of the plate-like body. An elastic plate having
By rotating the rotary shaft body, at least a portion of the contact surface of the elastic plate close to the tip is configured to contact one surface or the other surface of the plate-shaped body. To do.
Further, in the storage device for a plate-like body according to the present invention, when the abutment surface comes into contact with one surface or the other surface of the plate-like body, the elastic plate corresponds to the amount of rotation of the rotary shaft body. It is preferable that the elastic plate is elastically deformed and the elastic plate presses the plate-like body.
Furthermore, in the storage device for a plate-like body of the present invention, a positioning member for positioning a side end portion of the end portions surrounding the one surface and the other surface of the plate-like body is attached to the base portion. It is preferable.

Furthermore, in the storage device for a plate-like body of the present invention, it is preferable that the partition member is detachable from the base portion.
Moreover, it is preferable that the storage device for a plate-like body of the present invention has a rotation control means capable of simultaneously controlling the rotation of the plurality of rotating shaft bodies.
Furthermore, in the storage device for a plate-like body according to the present invention, the positioning member is detachably attached between a pair of support columns erected at both ends of the rear edge of the base portion and the support columns. A plurality of support members,
The portion where the side end of the plate-like body of the support member abuts is provided with an uneven contact member,
It is preferable that a portion between the pair of support columns in a state where the support member is removed becomes a carry-in / out portion of the plate-like body .
According to the method for storing the plate-like plate of the present invention in the storage device, the base portion and a plurality of partition members attached on the base portion are provided, and the plate-like body is interposed between the pair of partition members. The plate-shaped body is placed on the base portion in an upright state, and a part of the partition member is brought into contact with one surface and the other surface of the plate-shaped body, thereby separating the plate-shaped body with the pair of partitions. It is a method of storing in a storage device for a plate-like body that is sandwiched and fixed by members,
The partition member includes a rotatable rotating shaft body standing substantially vertically from the base portion, and a rotating shaft body whose base end portion is changeable between an upper end and a lower end of the rotating shaft body. And an elastic plate having a front end projecting in a direction substantially perpendicular to the axial direction of the rotary shaft body and having a contact surface directed to one surface or the other surface of the plate-like body. ,
By changing the mounting height of the elastic body according to the size of the plate-like body and rotating the rotating shaft body, at least a portion near the tip of the contact surface of the elastic plate is placed in the plate-like shape. It is made to contact | abut on the one surface or other surface of a body.

According to the storage device for a plate-like body described above, the plate-like body inserted between the pair of partition members facing each other with a predetermined interval is rotated to rotate the rotating shaft body so that the contact surface of the elastic plate is made. Since it makes it contact from both surfaces of a plate-shaped object, it can fix on both sides of a plate-shaped object. For this reason, the plate-like body can be placed vertically without falling down.
In addition, when a relatively thin plate-like body is inserted between the pair of partition members, the gap between the pair of partition members and the plate-like body is large, but the amount of rotation of the rotary shaft body is relatively large. By doing so, the contact surface of the elastic plate which is a part of the partition member can be brought into contact with the plate-like body. On the other hand, when a relatively thick plate-like body is inserted between the pair of partition members, the gap between the pair of partition members and the plate-like body is small, and the amount of rotation of the rotating shaft body is relatively small. Thus, the contact surface of the elastic plate can be brought into contact with the plate-like body. Accordingly, it is possible to stack plate-like bodies having different thicknesses, and further, it is not necessary to adjust the interval between the partition members according to the thickness of the plate-like body, so that the plate-like body can be easily packed. .
In addition, according to the storage device for a plate-like body, the elastic plate abutted on the plate-like body is elastically deformed according to the amount of rotation of the rotary shaft body. While the elastic plate is greatly elastically deformed, the elastic plate is elastically deformed to a relatively thin plate-like body, and in any case, the contact surface of the elastic plate can be brought into contact with the plate-like body. Therefore, it is possible to mix and load plate-like bodies with different thicknesses, and even when plate-like bodies with different thicknesses are mixed and loaded, it is not necessary to pack the gaps with packing materials for packing and to open the gaps. No waste is generated even when packed. Further, since the elastic plate is pressed and supported while being elastically deformed, the elastic plate of the partition member can mainly receive and absorb vibrations and impacts received by the plate during packing and transportation. Therefore, troubles such as breakage of the plate-like body can be prevented.

Furthermore, according to the storage device for a plate-like body described above, since the partition member is detachable from the base portion, the position of the partition member can be freely changed. Thereby, plate-shaped bodies of different sizes can be mixed.
Further, since the partition member is detachable, the maintenance work of the plate-shaped body storage device can be made efficient.
Furthermore, according to the storage device for a plate-like body, since the rotation control means capable of connecting a plurality of rotating shaft bodies of the plurality of partition members is provided, the rotation of the plurality of rotating shaft bodies is controlled simultaneously. Thus, the plate-like body can be fixedly supported. In addition, even if all the rotating shafts have the same amount of rotation, the elastic plate in contact with the plate-like body is elastically deformed according to the thickness of the plate-like body, so the pressing force on the surface of the plate-like body is adjusted. can do. For this reason, a thick plate and a thin plate can be mixedly mounted without causing damage to the surface of the plate-like body due to excessive rotation amount of the rotary shaft body or lack of support due to insufficient rotation amount. Furthermore, by controlling the rotation amount of the rotary shaft body to be constant, it is possible to eliminate variations in work by different workers.

Moreover, according to the storage device for a plate-like body, since the positioning member of the side end portion of the plate-like body is attached to the base portion, the inserted plate-like bodies can be positioned in the arrangement direction. . Thereby, the space | interval between adjacent plate-shaped bodies can be kept appropriate. In addition, since there is a concavo-convex abutting portion at the portion where the side end of the plate-like body abuts, while the side end is pushed into the concavo-convex portion, the position of the plate-like body in the depth direction is aligned. It can be fixed to a storage device for a plate-like body.
Furthermore, according to the storage device for the plate-like body, the support member constituting the positioning member is detachable, and the portion between the support columns from which the support member has been removed becomes the carry-in / out portion of the plate-like body. The plate-like body can be easily carried in and out. Further, since the side ends of the plate-like bodies are aligned on the carry-in / out side, even if plate-like bodies having different sizes and thicknesses are inserted in any order, any plate-like body Can be easily taken out.

As described above, according to the present invention, plate bodies of different sizes and plate bodies of different thicknesses can be mixed and loaded at the same time, and the packing operation is easy, and at the time of unpacking A storage device for a plate-like body that does not generate waste can be provided.
Furthermore, according to the present invention, it is possible to provide a storage device for a plate-like body in which an arbitrary plate-like body can be easily taken out.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The drawings referred to in the following description are for explaining the storage device for a plate-like body that is an embodiment of the present invention. The size, thickness, dimensions, etc. of each part shown in the drawings are the actual plate-like shapes. The dimensional relationship of each part in the body storage device may be different.
FIG. 1 is a perspective view of a glass plate storage device (plate body storage device) 1 according to the present embodiment, FIG. 2 is a schematic side view, FIG. 3 is a schematic plan view, and FIG. Is a schematic bottom view, and FIG. 5 is a schematic back view. 6 is a schematic cross-sectional view corresponding to the line AA ′ in FIG. 2, FIG. 7A is a schematic side view of the rotation control means, and FIG. 7B is a schematic view of the rotation control means. It is a plane perspective view. 8A is a side view showing the relationship between the partition member and the rotation control means, and FIGS. 8B to 8E are plan views or bottom views showing the relationship between the partition member and the rotation control means. It is. FIG. 9 is a schematic plan view showing a crank of the rotation control means. 10A is a schematic plan view of the support member attaching / detaching mechanism, FIG. 10B is a schematic side view of the support member attaching / detaching mechanism, and FIG. It is a back surface schematic diagram of an attachment / detachment mechanism. Further, FIG. 11A is a schematic plan view of the contact member 53, and FIG. 11B is a schematic plan view of the contact member 54. Furthermore, FIG. 12 (A) and FIG. 12 (B) are schematic side views of the positioning member at the lower end of the side end portion of the glass plate.

As shown in FIG. 1 to FIG. 5, the glass plate storage device 1 of the present embodiment is schematically configured from a base portion 2 and a plurality of partition members 3 attached on the upper surface 2 e of the base portion 2. ing. The glass plate which becomes the stacking target of the glass plate storage device 1 of the present embodiment is mainly a double-glazed glass for housing, and has a rectangular shape. In the glass plate storage device 1 of the present embodiment, a rectangular glass plate is placed on the upper surface 2e of the base portion 2 in a state where the rectangular glass plate is erected between the pair of partition members 3, and one surface of the glass plate and the other. The glass plate is sandwiched and fixed between the pair of partition members 3 by bringing a part of the partition member 3 into contact with the surface.
Further, the plate-like body in the present invention includes a rectangular plate-like body in terms of shape, and a metal plate, a resin plate wood plate, and a glass plate in terms of material. Furthermore, in terms of glass plate, it is generally composed of single plate glass, tempered glass, multi-layer glass, laminated glass, glass with metal wire, etc. In addition to inorganic glass, the materials include polycarbonates, polystyrenes, polymethyl methacrylates, etc. Or so-called organic transparent resin glass, or a laminate of two or more of them alone. The present invention is particularly suitable for multilayer glass.

As shown in FIGS. 1-2, the base part 2 is comprised from the plate-shaped member of planar view substantially rectangular shape, and a pair of long side part is made into the rear edge part 2a and the front edge part 2b, respectively, Each of the short sides is a side edge 2c. In addition, a pair of support columns 71 are erected on both ends of the front edge portion 2 b of the base portion 2. Further, another pair of support columns 51 are erected on both ends of the rear edge 2 a of the base 2.
The base portion 2 is horizontally fixed by a pair of support columns 51 and 71. A sub-base portion 24 having the same size as the base portion 2 is fixed below the base portion 2 so as to be substantially parallel to the base portion 2. The base portion 2 and the sub base portion 24 are connected by support columns 51 and 71. Further, a rotation control means 4 to be described later is provided in the space between the base portion 2 and the sub base portion 24.
A plurality of frames 25 are attached to the lower surface of the sub-base portion 24 so as to be parallel to the side edges of the sub-base portion 24. Further, a plurality of support columns 75 are erected on the sub-base portion 24. Since the forklift claw can be inserted into the space between the frames 25, the storage device 1 for glass plates can be easily transported. Further, the sub-base portion 24 has a structure that protects the rotation control means 4 during transportation.

  A support member 72 is detachably attached between the upper ends of the pair of columns 71. Furthermore, between the support | pillar 71 and the support | pillar 51, the horizontal stretch 73 which connects the support | pillar 71 and the support | pillar 51 along the side edge part 2c of a base part is provided. Furthermore, each lateral stretch 73 and the side edge portion 2 c of the base portion are connected by a plurality of longitudinal stretches 74. The glass plate can be protected by the column 51 and the tensions 73 and 74.

The base part 2 has a plurality of panel units 21. Each panel unit 21 is composed of a rectangular plate-shaped member, a pair of long side portions are respectively a rear edge portion 21a and a front edge portion 21b, and a pair of short side portions are respectively side edge portions 21c. ing. Further, the rear edge portion 21 a is disposed so as to face the rear edge portion 2 a side of the base portion, and the front edge portion 21 b is disposed so as to face the front edge portion 2 b side of the base portion 2. Furthermore, a pair of side edge part 21c of each panel unit 21 is arrange | positioned so that a part of side edge part 2c of a base part may be comprised.
Each panel unit 21 has an insertion hole 22 into which the fixed shaft body 31 of the partition member 3 to be described later is inserted on the rear edge portion 21a side, and an insertion hole 23 into which the rotary shaft body 32 is inserted on the front edge portion 21b side. A plurality of penetrating holes are provided from 21e to the lower surface 21d. A pair of insertion hole 22 and insertion hole 23 is used for one partition member 3.
Moreover, as shown in FIG. 4, the rotation control means 4 mentioned later is provided in the lower surface 21d of each panel unit.
Furthermore, since each panel unit 21 is detachably attached to the base portion 2, the structure of the partition member 3 of the glass plate storage device 1 can be easily changed depending on the size of the glass plate to be placed. It has become. Furthermore, the workability of maintenance of the rotation control means 4 is also improved.
In addition, you may coat | cover the surface of the upper surface 2e (the upper surface 21e of each panel unit 21) of the base part 2 with a buffering material so that a glass plate side edge may not be damaged. Further, the glass plate may be covered with a member that is difficult to slip on the upper surface 2e.

Next, as shown in FIGS. 1 to 3, the partition member 3 includes a fixed shaft body 31, which has a lower end attached to the insertion hole 22 of the panel unit 21 constituting the base portion 2 and is erected substantially vertically. The lower end is attached to the insertion hole 23 of the panel unit 21, and the rotary shaft body 32 is erected almost vertically and the elastic plate 33 is attached to the rotary shaft body 32.
The fixed shaft body 31 has a lower end inserted into the insertion hole 22, and a vertical portion 31 </ b> A that is erected substantially vertically up to the same height as the rotation shaft body 32, and substantially from the vertical portion 31 </ b> A to the rotation shaft body 32 side. It is comprised from the bending part 31B bent horizontally. Further, the tip end portion 31a is positioned so as to support the upper end 32a of the rotating shaft body 32 at the tip end portion 31a of the bent portion 31B.
The rotating shaft body 32 is erected substantially vertically with the lower end inserted into the insertion hole 23. The upper end 32 a of the rotating shaft body 32 is rotatably attached in a state where it is supported by the distal end portion 31 a of the fixed shaft body 31.
The shapes of the fixed shaft body 31 and the rotating shaft body 32 are not particularly limited, but may be a round bar shape, a polygonal bar shape, or may be hollow. The diameters of the fixed shaft body 31 and the rotating shaft body 32 are not particularly limited, but are preferably 12 mm or more in diameter. Furthermore, the material of the fixed shaft body 31 and the rotating shaft body 32 is not particularly limited, but it is preferable to employ a material having high rigidity such as steel. Furthermore, it is preferable that the surfaces of the fixed shaft body 31 and the rotating shaft body 32 are covered with a cushioning material.

Next, as shown in FIGS. 1, 2, and 6, the elastic plate 33 has a proximal end portion 33 a attached to the shaft of the rotating shaft body 32, and a distal end portion 33 b that is substantially from the axial direction of the rotating shaft body 32. The two are protruded in a direction orthogonal to each other, and the two are attached in a symmetrical manner with the rotating shaft body 32 as a center.
The elastic plate 33 is elastically deformed along the rotation direction of the rotary shaft body 32 on the distal end portion 33 b side in a state where the base end portion 33 a is fixed to the rotary shaft body 32.
The elastic plate 33 includes elastic members 331 and 332 and a buffer material 333 that covers the elastic members 331 and 332. The pair of elastic members 331 and 332 protrude in a direction substantially orthogonal to the axial direction of the rotating shaft body 32 and are attached substantially symmetrically about the rotating shaft body 32.
The shape of the elastic members 331 and 332 is a rectangular plate shape, but is not particularly limited thereto, and a polygonal shape or an elliptical shape can be applied. The surfaces of the elastic members 331 and 332 are covered with a cushioning material 333 made of rubber, foamed resin, or the like. Furthermore, the material of the elastic members 331 and 332 is not particularly limited, and an elastic material such as a leaf spring or rubber can be applied.
The elastic member 331 has one end 331a fixed by a pair of fixing members 32A attached on the surface of the rotating shaft 32, and the other end 331b protruding in a direction substantially perpendicular to the axial direction of the rotating shaft 32. The rotating shaft body 32 is fixed. The method of fixing the elastic member 331 to the rotating shaft body 32 is not limited to this method. A groove for attaching the elastic member 331 is formed in the rotating shaft body 32, and the elastic member 331 is inserted and fixed there. May be. Similarly, the elastic member 332 is attached so as to be symmetric with respect to the rotating shaft body 32.
Furthermore, the surfaces of the cushioning material 333 covering the elastic members 331 and 332 are contact surfaces 33A and 33B to the glass plate. Since each contact surface is constituted by the buffer material 333, the surface of the glass plate is hardly damaged.

Although the length between the base end part 33a and the front-end | tip part 33b of the elastic board 33 is not specifically limited, It is possible to change suitably according to the relationship with the space | interval of the partition member 3 mentioned later. For example, when the elastic member 331 (332) constituting the partition member 3 is made of stainless steel having a thickness of 0.6 mm and the interval between the partition members 3 is 45 mm, the base end portion 33a and the distal end portion 33b Is preferably in the range of 45 to 120 mm, more preferably in the range of 70 to 100 mm. When the length of the base end portion 33a and the tip end portion 33b is less than 45 mm, when the relatively thin glass plate is inserted between the pair of partition members 3, the tip end portion of the elastic plate contacts the surface of the glass plate. A relatively large amount of rotation until contact is made, and the tip of the elastic plate comes into contact with an acute angle, which may damage the surface of the glass plate. Since the distance of the part which contact | abuts the other surface spreads and the force which contact | abuts a glass plate surface becomes weak, a glass plate cannot be fixed firmly. On the other hand, when it is in the range of 45 to 120 mm, the elastic plate 33 can be brought into contact with the glass plate even if the amount of rotation of the rotary shaft 32 is small, and the distance between the portions that make contact with both surfaces of the glass plate is appropriate. The glass plate can be firmly fixed.
In addition, the distance between the fixed shaft body 31 and the rotary shaft body 32 and the distance between the insertion hole 22 and the insertion hole 23 are set at least as described above so that the elastic plate 33 attached to the rotary shaft body 32 can rotate. The elastic plate 33 is set to be longer than the length between the proximal end portion 33a and the distal end portion 33b.

The height of the partition member 3 is not particularly limited, and can be appropriately changed depending on the size of the glass plate to be placed. It is also possible to attach partition members 3 having different heights at the same time. Further, the number of elastic plates 33 attached to the rotating shaft body 32 is not particularly limited, and can be appropriately increased or decreased depending on the size of the glass plate. The elastic plates 33 attached to the same rotating shaft body 32 are attached so as to be in the same direction.
One glass plate is fixedly held by the pair of partition members 3. As shown in FIGS. 1 and 3, when four partition members 3 are arranged in the thickness direction of the glass plate, three glass plates can be inserted. The number of the partition members 3 of the present embodiment is not particularly limited, and a plurality of glass plates can be simultaneously mounted by arranging the plurality of partition members 3. Moreover, although the space | interval of the adjacent partition member 3 is not specifically limited, The relationship between the length between the base end part 33a and the front-end | tip part 33b of the above-mentioned elastic board 33 so that it can respond to the thickness of the glass plate to stack | stack. However, it is possible to change appropriately. For example, when the glass plate to be loaded is a double-glazed glass for residential use, it is preferably about 45 mm (range of 45 to 55 mm) so as to correspond to a thickness of 12 to 32 mm. The interval between the insertion holes 22 and 23 provided in the panel unit 21 is the above-described interval.
As described above, by appropriately changing the configuration of the partition member 3, glass plates having different sizes and thicknesses can be mixedly mounted.
The partition member 3 is detachably attached to the panel unit 21 that constitutes the base portion 2. The maintenance work of the partition member 3 is improved, and when the partition member 3 is damaged, only the partition member 3 can be easily replaced.

Next, as shown in FIG. 4, the rotation control unit 4 is generally configured by a pair of fixed rails 42 and 43 disposed on the lower surface 21 d of the panel unit 21 and a movable rail 44. The fixed rail 42 is provided with an insertion hole 42 a at a position corresponding to the insertion hole 23 of the panel unit 21. Further, in the vicinity of the insertion hole 42 a provided in the fixed rail 42, a rotatable hollow cylindrical fixing member 42 b is rotatably attached to the fixed rail 42 as shown in FIG. 7A. The hollow portion of the fixing member 42b and the insertion hole 42a communicate with each other. An insertion hole 43 a is provided in the fixed rail 43 at a position corresponding to the insertion hole 22 of the panel unit 21. The movable rail 44 is provided with a substantially elliptical insertion hole 44 a so as to correspond to the insertion hole 42 a provided in the fixed rail 42. Further, the movable rail 44 is movably attached to the lower surface 21 d of the panel unit 21 by a plurality of fixing members 48.
As shown in FIGS. 7A and 8A, the fixed shaft body 31 of the partition member 3 is inserted from the insertion hole 22 provided in the upper surface 21e of the panel unit 21, and is further provided in the fixed rail 43. The insertion hole 43a is penetrated and fixed to the fixed rail 43 by a nut 43b. The rotating shaft body 32 is inserted through the insertion hole 23 and is connected to a rotatable fixing member 42 b provided on the fixed rail 42. Further, the fixed member 42 b and the insertion hole 44 a provided in the movable rail 44 are connected by a connecting member 45.

As shown in FIG. 8, an adjustment mechanism 46 that moves the movable rail 44 is provided near one end of the movable rail 44. The adjustment mechanism 46 includes a female screw member 46a joined to the lower surface 2d of the base part 2, a male screw member 46b attached to the female screw member 46a, a drive part 46c attached to the tip of the male screw member 46b, An urging unit 49 that urges the driving unit 46c is included. The drive unit 46 c is joined to the movable rail 44. The urging portion 49 includes a U-shaped flange portion 49a attached to the base portion 2 and an elastic member 49b attached to the flange portion 49a. One end of the elastic member 49b is joined to the flange portion 49a, and the other end is brought into contact with the drive portion 46c to urge the drive portion 46c. The male screw member 46b is provided with an insertion hole (not shown) into which a later-described crank 41 is inserted.
On the other hand, a butting plate 44 c is joined to the vicinity of the other end of the movable rail 44. Further, a stopper 47 corresponding to the abutting plate 44 c is attached to the lower surface 2 d of the base portion 2.

The rotation control means 4 is used using a crank 41 as shown in FIG. The crank 41 has a threaded portion 411 at the end of the crankshaft 412 and two grip portions 413.
As shown in FIG. 8C, in a state in which the male screw member 46b is not pushed into the female screw member 46a, the position of the driving portion 46c is located on the near side, and thereby the movable rail 44 is moved. At the initial position, as shown in FIG. 8B, a glass plate can be inserted between the elastic plates 33.
Next, as shown in FIG. 8E, when the male screw member 46 b is rotated by the crank 41 and the male screw member 46 b is screwed into the female screw member 46 a, the drive portion 46 c is elastic of the biasing portion 49. Shifting to the far side against the biasing force of the member 49b, the movable rail 44 moves from the initial position to the other end side. Accordingly, the linear motion of the movable rail 44 is converted into a rotational motion that rotates the rotary shaft body 32 via the connecting member 45 and the fixed member 42b. As a result, as shown in FIG. 8D, the plurality of rotary shaft bodies 32 are simultaneously rotated by the same rotation amount, and the elastic plate 33 is inclined as viewed from above.
Further, when the male screw member 46b is rotated in the reverse direction by the crank 41 and the male screw member 46b is retracted from the female screw member 46a, the driving portion 46c is pushed by the urging force of the elastic member 49b of the urging portion 49. Shifting to the near side, the movable rail 44 returns to the initial position again, and the glass plate can be inserted between the elastic plates 33.
The moving amount of the movable rail 44 is controlled by the abutting plate 44c attached to the movable rail 44 abutting against the stopper 47.

  Next, as shown in FIG. 2, the positioning member 5 is detachably attached between a pair of support columns 51 erected on both ends of the rear edge 2 a of the base unit 2 and the pair of support columns 51. The plurality of support members 52 and contact members 53 and 54 attached to the contact portions of the glass plate of the support member 52 are configured. By pressing the side edge of the glass plate inserted between the partition members 3 against the support member 52, the glass plate is aligned along the rear edge 2 a side of the base portion 2 and attached to the support member 52. By arranging the glass plate between the contact members 53 and 54, the side end of the glass plate is held.

As shown in FIG. 10, the support member 52 and the support column 51 include a lock mechanism. The end portion of the support member 52 is provided with a stopper 52a having an inclined surface at one end portion and a case 52b that slidably holds the stopper 52a. The case 52b incorporates an urging means such as a spring or rubber (not shown), and the urging means urges the stopper 52a toward the end of the support member 52. A trigger 52d is attached to the cylindrical portion 52c, which is the other end of the stopper 52a.
On the other hand, the support column 51 is provided with a receiving portion 51a into which the end of the stopper 52a is inserted. The end portion of the stopper 52a can be freely inserted into and removed from the receiving portion 51a. By inserting the end portion of the stopper 52a into the receiving portion 51a, the stopper 52a and the receiving portion 51a are engaged, The support member 52 is fixed to the support column 51.
When removing the support member 52 from the support column 51, the stopper 52a is slid by pulling the trigger 52d, and one end of the stopper 52a is removed from the receiving portion 51a, whereby the stopper 52a and the receiving portion 51a are engaged. To cancel.
When the support member 52 is attached to the support column 51, the stopper 52a slides while being inclined by pressing the stopper 52a against the receiving portion 51a. When the stopper 52a is in the locked position, the stopper 52a slides into the receiving portion 51a to stop the stopper 52a. And the receiving portion 51 a are engaged, and the support member 52 is attached to the column 51.
Thus, since the support member 52 is detachable from the support column 51, the glass plate can be carried in and out from the rear edge portion 2a of the base portion 2.

Next, the contact members 53 and 54 are attached to the contact portion of the glass plate of the support member 52 as shown in FIGS. 11 (A) and 11 (B). The abutting member 53 includes a guide portion 53a having a tip formed at an acute angle and an abutting portion 53b. On the other hand, the contact member 54 includes a rectangular guide part 54a and an abutting part 54b. The shapes of the contact members 53 and 54 are not limited to these, and can be selected when attaching to the surface of the support member 52. In addition, it is preferable to select the contact member 53 for the support member 52 that contacts at least the upper end side among the support members 52 that contact the side edge of the glass plate.
The material of the abutting member is not particularly limited, but the guide portions 53a and 54a are preferably elastic members in order to guide the side end portions of the adjacent glass plates to a predetermined position, and for protecting the surface of the glass plate. Is preferably covered with a buffer material. The material of the abutting portions 53b and 54b is not particularly limited, but is preferably covered with a buffer material for protecting the side end portion of the glass plate. Further, the guide portions 53a and 54a and the abutting portions 53b and 54b can be integrally formed.

  Moreover, you may attach the position alignment member 6 for aligning the lower end of the side edge part of a glass plate to the base part 2, as shown in FIG.2 and FIG.12 (A) and (B). The alignment member 6 includes a plate member 61 and a plate member 62. The plate-like member 61 and the plate-like member 62 are integrated, and are slidably attached in the vertical direction of the rear edge portion 2a of the base portion 2.

FIG. 13 is an enlarged schematic side view of the crank housing portion. As shown in FIG. 2 and FIG. 13, in the glass plate storage device 1 of the present embodiment, rotation control is performed by the hook portion 73 a attached to the horizontal stretch 73 and the hook portion 74 a attached to the vertical stretch 74. The crank 41 used in the means 4 can be stored.
Moreover, FIG. 14 is the side view which accumulated the storage apparatus 1 for glass plates. In the glass plate storage apparatus 1 of the present embodiment, a stacking stopper member 8 is provided on a lateral stretch 73 as shown in FIG. On the glass plate storage device 1 on which no glass plate is placed, another glass plate storage device 1 is stacked in the same direction and fixed to the rear edge 2a of the base portion 2. The supporting column 51 can be stacked at a position where it comes into contact with the stacking stopper member 8.

Next, the form which mounts a glass plate on said glass plate support apparatus is demonstrated.
FIG. 15 is a perspective view showing a state in which the glass plates 9A are stacked.
When loading the glass plates 9A, as shown in FIG. 8C, it is confirmed that the male screw member 46b is not pushed into the female screw member 46a. In this state, the position of the drive part 46c is located on the near side. As a result, the movable rail 44 is at the initial position, and the glass plate can be inserted between the elastic plates 33 as shown in FIG.

  Next, all the support members 52 constituting the positioning member 5 are removed. When removing the support member 52 from the column 51, as shown in FIGS. 10A to 10C, the stopper 52a is slid by pulling the trigger 52d, and one end of the stopper 52a is moved from the receiving portion 51a. By pulling out, the engagement between the stopper 52a and the receiving portion 51a is released. Thereby, the support member 52 can be removed from the support column 51.

Next, the glass plate 9 </ b> A is carried in from the rear edge portion 2 a of the base portion 2. Since the part from which the support member 52 is removed becomes a carry-in part, even a relatively large glass size can be carried in easily.
Further, the glass plate 9 </ b> A is erected, inserted one by one between the partition members 3, and the lower end portion is placed on the upper surface 2 e of the base portion 2.
FIG. 16A is a schematic cross-sectional view showing a state where the glass plate 9 </ b> A is inserted between the partition members 3. The glass plate 9 </ b> A is disposed in the vicinity of the middle between the adjacent elastic plates 33 so that the glass surface does not strongly interfere with the adjacent elastic plates 33.
Next, the alignment member 6 at the lower end of the side end portion of the glass plate is slid upward. Further, the glass plate 9 </ b> A inserted between the partition members 3 is pushed back until it hits the alignment member 6. The alignment member 6 functions as a stopper, and the side end portions of the glass plate 9A are aligned.

  Then, the support member 52 is attached to the support column 51. By pressing the stopper 52a against the receiving portion 51a, the stopper 52a slides while tilting. When the stopper 52a reaches the locked position, the stopper 52a slides into the receiving portion 51a, and the stopper 52a and the receiving portion 51a engage with each other. Is attached to the column 51. Attachment is performed sequentially from the uppermost support member 52, and the entire support member 52 is mounted on the column 51. Further, the contact member attached to the uppermost support member 52 is preferably the contact member 53. Since the tip of the guide portion 53a is thin, even if the upper end of the glass plate 9A is not in an appropriate position, a slight shift is allowed. When pushing into the back of the guide part 53a, the glass plate 9A is adjusted to an appropriate position.

  Next, as shown in FIG. 8E, the male screw member 46 b is rotated by the crank 41. When the male screw member 46b is screwed into the female screw member 46a, the drive portion 46c shifts to the back side against the biasing force of the elastic member 49b of the biasing portion 49, whereby the movable rail 44 is moved from the initial position to the other side. Move to the end side. Accordingly, the linear motion of the movable rail 44 is converted into a rotational motion that rotates the rotary shaft body 32 via the connecting member 45 and the fixed member 42b. As a result, as shown in FIG. 8D, the plurality of rotating shaft bodies 32 are simultaneously rotated by the same amount of rotation, and the elastic plate 33 is brought into contact with both surfaces of the glass plate 9A, thereby fixing and supporting the glass plate 9A. .

FIG. 16B is a schematic cross-sectional view showing a state in which the glass plate 9A is sandwiched and fixed.
As shown in FIG. 16 (B), the elastic plate 33 positioned between the glass plates 9A has the surface of the glass plate 9A as the rotating shaft 32 rotates even after the tip end abuts against the glass plate 9A. It is elastically deformed in a state where it is energized. The elastically deformed contact portion 334 of one elastic plate 33 contacts the surface of one glass plate 9A, and the contact portion 335 of the other elastic plate 33 that is also elastically deformed contacts the surface of the other glass plate 9A. Abut.
Therefore, one glass plate is fixed and held by the contact portion 334 and the contact portion 335 of the pair of elastic plates 33.

In addition, when a relatively thin glass plate is inserted between the pair of partition members 3, the gap between the pair of partition members 3 and the glass plate is large, but the amount of rotation of the rotary shaft body 32 is relatively small. By increasing the size, the contact surfaces 334 and 335 of the elastic plate 33 which is a part of the partition member 3 can be brought into contact with the glass plate. On the other hand, when a relatively thick glass plate is inserted between the pair of partition members 3, the gap between the pair of partition members 3 and the glass plate is small, and the amount of rotation of the rotary shaft body 32 is relatively small. By doing so, the contact surfaces 334 and 335 of the elastic plate 33 can be brought into contact with the glass plate. For this reason, it is not necessary to adjust the space | interval of the partition member 3 according to the thickness of a glass plate.
In addition, since the elastic plate 33 in contact with the glass plate is elastically deformed according to the amount of rotation of the rotary shaft 32, the elastic plate 33 is largely elastically deformed with respect to a relatively thick glass plate, while being relatively thin. The elastic plate 33 is small and elastically deformed with respect to the glass plate, and in any case, the contact surfaces 334 and 335 of the elastic plate 33 can be brought into contact with the glass plate. Accordingly, even when glass plates having different thicknesses are mixedly mounted, the glass plate is supported in a state where the elastic plate 33 is elastically deformed. Therefore, the glass plate can be supported and fixed with an appropriate stress.

FIG. 17 is a schematic side view showing a state in which glass plates having different sizes are stacked.
As shown in FIG. 17, when a large glass plate 9 </ b> A is stacked vertically, the tall partition member 3 is adopted and the elastic plate 33 is attached to a high position of the rotary shaft body 32 and stably held. Can be fixed.
Next, when a large glass plate 9B is stacked on the side, the height of the partition member 3 may be low, and it is not necessary to increase the mounting height of the elastic plate 33 to the rotating shaft 32. By installing 21 rows in 21 rows, it can be stably held and fixed.
Further, when stacking small glass plates 9C, the partition member 3 may be low and the number of elastic plates 33 attached may be small. Furthermore, the panel unit 21 can be stably held and fixed by only one row installation.

  In this way, as shown in FIG. 15, the glass plates 9 </ b> A are sequentially stacked between the partition members 3 and are sandwiched and fixed in an upright state. And by adjusting the height of each partition member 3, the number of arrangement, and the attachment position and number of elastic plates, glass plates 9A, 9B, and 9C having different sizes can be simultaneously mounted as shown in FIG. .

As described above, according to the glass plate storage device 1 described above, the elastic plate 33 is brought into contact with the glass plate 9 </ b> A inserted between the pair of partition members 3 by rotating the rotating shaft body 32. Since the surfaces 334 and 335 are brought into contact with both surfaces of the glass plate 9A, the glass plate 9A can be sandwiched and fixed. For this reason, the glass plate 9A can be placed vertically without falling down.
When a relatively thin glass plate is inserted between the pair of partition members 3, the gap between the pair of partition members 3 and the glass plate 9 </ b> A is large, but the amount of rotation of the rotating shaft body 32 is compared. The contact surfaces 334 and 335 of the elastic plate 33, which is a part of the partition member 3, can be brought into contact with the glass plate 9A. On the other hand, when a relatively thick glass plate 9A is inserted between the pair of partition members 3, the gap between the pair of partition members 3 and the glass plate 9A is small, and the amount of rotation of the rotary shaft 32 is compared. The contact surfaces 334 and 335 of the elastic plate 33 can be brought into contact with the glass plate 9A. For this reason, it is not necessary to adjust the space | interval of the partition member 3 according to the thickness of the glass plate 9A, and the packing operation | work of the glass plate 9A can be performed easily.

  In addition, according to the glass plate storage device 1 described above, the elastic plate 33 in contact with the glass plate is elastically deformed according to the amount of rotation of the rotary shaft 32, so that the glass plate 9A is relatively thick. While the elastic plate 33 is greatly elastically deformed, the elastic plate 33 is small elastically deformed with respect to the relatively thin glass plate 9A. In any case, the contact surfaces 334 and 335 of the elastic plate 33 are brought into contact with the glass plate 9A. You can touch. Therefore, even when the glass plates 9A having different thicknesses are mixedly loaded, an operation of packing the gap with the packing material for packing is unnecessary, and no waste is generated even when unpacking. Further, since the glass plate 9A is supported in a state where the elastic plate 33 is elastically deformed, the elastic plate 33 of the partition member 3 can mainly receive and absorb vibrations and shocks received by the glass plate 9A during packing and transportation. Therefore, troubles such as breakage of the glass plate 9A can be prevented.

Furthermore, according to the glass plate storage device 1 described above, since the partition member 3 is detachable from the base portion 2, the position of the partition member 3 can be freely changed. Thereby, the glass plate of a different magnitude | size can be mixedly mounted.
Moreover, since the partition member 3 is detachable, the maintenance work of the storage device for the glass plate 9A can be made efficient.
Furthermore, according to the storage apparatus 1 for glass plates, since the rotation control means 4 that can connect a plurality of rotating shaft bodies 32 of the plurality of partition members 3 is provided, a plurality of rotating shaft bodies 32 are provided. The glass plate 9A can be fixedly supported by simultaneously controlling the rotation of the glass plate 9A. Even if the plurality of rotary shaft bodies 32 are all set to the same rotation amount, the elastic plate 33 that contacts the glass plate 9A is elastically deformed according to the thickness of the glass plate 9A. Can be adjusted. For this reason, a thick glass plate and a thin glass plate can be mixedly mounted without causing damage to the surface of the glass plate 9A due to an excessive amount of rotation of the rotating shaft 32 and insufficient support due to an insufficient amount of rotation. Furthermore, by controlling the rotation amount of the rotary shaft body 32 to be constant, it is possible to eliminate work variations among different workers.

Further, according to the glass plate storage device 1 described above, since the positioning member 5 at the side end of the glass plate 9A is attached to the base portion 2, the inserted glass plates 9A are positioned in the alignment direction. Can do. Thereby, the space | interval between adjacent glass plates can be maintained appropriately. In addition, since the concave and convex contact portions 53 and 54 are provided in the portion where the side end portion of the glass plate 9A contacts, the position of the glass plate 9A in the depth direction can be obtained by pushing the side end portion into the concave and convex portion. And can be fixed to the glass plate storage device 1.
Furthermore, according to said storage apparatus 1 for glass plates, the support member 52 which comprises the positioning member 5 can be attached or detached, and the part between the support | pillars 51 from which the support member 52 was removed is the carrying in / out part of the glass plate 9A. Therefore, the glass plate 9A can be easily carried in and out. Moreover, since the side edge part of the glass plate 9A is arranged in the carrying in / out side, even if the glass plate from which the magnitude | size and thickness of a glass plate differ is inserted in arbitrary orders, arbitrary glass plates are easy. It can be taken out.

Furthermore, since the partition member 3 is covered with the buffer material, it can be fixed and supported without damaging the glass plate surface.
Moreover, since the base part 2 is comprised by the panel unit 21 which can be attached or detached, the partition member 3 and the rotation control means 4 can be removed with the panel unit 21 together. This facilitates maintenance work of the partition member 3 and the rotation control means 4.

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, the maximum size glass plate 9A shown in FIG. 15 and FIG. 17 may be placed in a state where the longitudinal direction is horizontal, instead of being placed in a state where the longitudinal direction is vertical as shown. Is possible. In this case, the mounting area can be expanded by removing the support members 72 that are detachably installed between the upper ends of the pair of support columns 71 erected on both ends of the front edge portion 2b of the base portion 2. Is possible.
Further, a recess may be provided on the upper surface 2e of the base portion 2 to form a guide groove for the glass plate. This prevents the glass surface from being damaged by contacting the partition member 3 when the glass plate is inserted. Moreover, since the movement of the lower end portion of the glass plate is restricted by the guide groove, it can be stably held and fixed without being greatly displaced during transportation.
Furthermore, the shape of the elastic plate 33 can be changed. 18A and 18B are schematic cross-sectional views of modifications of the elastic plate 33. FIG. As shown in FIG. 18A, the elastic plate 33 has a substantially rhombus cross-sectional shape, so that the end of the elastic plate 33 contacts the glass plate when the glass plate 9A is inserted between the partition members 3. Thus, the possibility of damaging the glass surface is reduced. Furthermore, as shown in FIG. 18B, when the rotating shaft 32 rotates, the areas of the portions 334 and 335 that contact the glass plate 9A increase, and the surface of the glass plate can be fixed and held over the entire surface. it can. Thereby, the damage to the glass surface by the urging | biasing force concentrating on the contact parts 334 and 335 of the elastic board 33 can be reduced. Furthermore, since the distance between the abutting portion 334 of one partition member 3 that abuts on both surfaces of the glass plate 9A and the abutting portion 335 of the other partition member 3 is shortened, it can be stably fixed even with a small stress. Can hold.

  The present invention can be applied to general rectangular panels of plate-like bodies that require protection of the panel surface, such as decorative glass panels and glossy metal panels, in addition to double-glazed glass.

FIG. 1 is a perspective view of a glass plate storage device (a plate-shaped storage device) 1 of the present embodiment. FIG. 2 is a schematic side view of the glass plate storage device (plate-shaped body storage device) 1 according to the present embodiment. FIG. 3 is a schematic plan view of the glass plate storage device (plate-shaped body storage device) 1 of the present embodiment. FIG. 4 is a schematic bottom view of the glass plate storage device (plate-shaped body storage device) 1 of the present embodiment. FIG. 5 is a schematic back view of the glass plate storage device (plate-shaped body storage device) 1 of the present embodiment. 6 is a schematic cross-sectional view corresponding to the line A-A ′ of FIG. 2. FIG. 7A is a schematic side view of the rotation control means, and FIG. 7B is a plan perspective view of the rotation control means. FIG. 8A is a side view showing the relationship between the partition member and the rotation control means, and FIGS. 8B to 8E are plan views or bottom views showing the relationship between the partition member and the rotation control means. . FIG. 9 is a schematic plan view showing a crank of the rotation control means. 10A is a schematic plan view of a support member attaching / detaching mechanism, FIG. 10B is a schematic side view of the support member attaching / detaching mechanism, and FIG. 10C is a support member attaching / detaching mechanism. FIG. FIG. 11A is a schematic plan view of the contact member 53, and FIG. 11B is a schematic plan view of the contact member 54. 12 (A) and 12 (B) are schematic side views of the alignment member at the lower end of the side end portion of the glass plate. FIG. 13 is an enlarged schematic side view of the crank housing portion. FIG. 14 is a side view in which the glass plate storage devices 1 are stacked. FIG. 15 is a perspective view showing a state in which the glass plates 9A are stacked. FIG. 16A is a schematic cross-sectional view showing a state in which the glass plate 9A is inserted between the partition members 3, and FIG. 16B shows a state in which the glass plate 9A is sandwiched and fixed. FIG. FIG. 17 is a schematic side view showing a state in which glass plates having different sizes are stacked. 18A and 18B are schematic cross-sectional views of modifications of the elastic plate 33. FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Storage device for glass plates (storage device for plate-like body), 2 ... Base part, 2a ... Rear edge part of base part, 2b ... Front edge part of base part, 2c ... Side edge of base part, 2d ... Lower surface of base part, 2e ... Upper surface of base part, 21 ... Panel unit, 21a ... Rear edge part of panel unit, 21b ... Front edge of panel unit, 21c ... Side edge of panel unit, 21d ... Lower surface of panel unit, 21e ... Upper surface of panel unit, 22 ... Insertion hole, 23 ... Insertion hole, 24: Sub-base portion, 25: Frame, 3: Partition member, 31: Fixed shaft body, 31A: Vertical portion of fixed shaft body, 31B: Bending of fixed shaft body Part, 31a ... tip of fixed shaft body, 32 ... rotating shaft body, 32A ... fixed member, 32 ... upper end of rotating shaft, 33 ... elastic plate, 33A, 33B ... contact surface to glass plate, 33a ... base end of elastic plate, 33b ... tip of elastic plate 331, 332 ... elastic member, 331a, 332a ... one end of the elastic member, 331b, 332b ... the other end of the elastic member, 333 ... buffer material, 334, 335 ... contact portion, DESCRIPTION OF SYMBOLS 4 ... Rotation control means, 41 ... Crank, 411 ... Screw part, 412 ... Crank shaft, 413 ... Grip part, 42, 43 ... Fixed rail, 44 ... Movable rail 42a, 43a, 44a ... insertion hole, 42b ... fixing member, 43b ... nut, 44c ... abutting plate, 45 ... connecting member, 46 ... adjustment mechanism, 46a ... -Female screw member, 46b ... Male screw member, 46c ... Part, 47 ... stopper, 48 ... fixing member, 49 ... biasing part, 49a ... flange part, 49b ... elastic member, 5 ... positioning member, 51 ... strut, 51a ... receiving portion, 52 ... support member, 52a ... stopper, 52b ... case, 52c ... cylindrical portion, 52d ... trigger, 53, 54 ... contact member, 53a 54a ... guide part, 53b, 54b ... abutting part, 6 ... positioning member, 61,62 ... plate-like member, 71 ... post, 72 ... support member, 73 ... Horizontal stretch, 74 ... Vertical stretch, 73a, 74a ... Hook, 75 ... Post, 8 ... Stopper member for loading, 9A, 9B, 9C ... Glass plate

Claims (7)

A base portion and a plurality of partition members attached on the base portion are provided, and the plate-like body is placed on the base portion in a state where the plate-like body is raised between a pair of partition members. A plate-like storage device that fixes the plate-like body sandwiched between the pair of partition members by bringing a part of the partition member into contact with one surface and the other surface of the plate-like body,
The partition member includes a rotatable rotating shaft that is erected substantially vertically from the base portion, and a base end portion that is attached at a height between the upper end and the lower end of the rotating shaft depending on the size of the plate-like body. Is attached to the rotary shaft body in such a manner that the front end portion of the plate-like body is protruded in a direction substantially perpendicular to the axial direction of the rotary shaft body, and the contact surface is directed to one surface or the other surface of the plate-like body. An elastic plate having
By rotating the rotary shaft body, at least a portion of the contact surface of the elastic plate close to the tip is configured to contact one surface or the other surface of the plate-shaped body. A storage device for a plate-like body.   When the contact surface comes into contact with one surface or the other surface of the plate-like body, the elastic plate elastically deforms according to the amount of rotation of the rotary shaft body, and the elastic plate presses the plate-like body. The storage device for a plate-like body according to claim 1.   The storage device for a plate-like body according to claim 1 or 2, wherein a positioning member for positioning a side end portion of the plate-like body is attached to the base portion. The storage device for a plate-like body according to any one of claims 1 to 3 , wherein the partition member is detachable from the base portion. Storage device for plate-like body according to any one of claims 1 to 4, characterized in that it has at the same time rotating controllable rotation control means a plurality of said rotary shaft. The positioning member includes a pair of support columns erected at both ends of the rear edge of the base portion, and a plurality of support members attached detachably between the support columns.
The portion where the side end of the plate-like body of the support member abuts is provided with an uneven contact member,
4. The storage device for a plate-like body according to claim 3, wherein a portion between the pair of support columns in a state where the support member is removed becomes a carry-in / out portion of the plate-like body. A base portion and a plurality of partition members attached on the base portion are provided, and the plate-like body is placed on the base portion in a state where the plate-like body is raised between a pair of partition members. And storing the plate-like body in a storage device for the plate-like body that is sandwiched and fixed by the pair of partition members by bringing a part of the partition member into contact with one surface and the other surface of the plate-like body. Because
The partition member includes a rotatable rotating shaft body standing substantially vertically from the base portion, and a rotating shaft body whose base end portion is changeable between an upper end and a lower end of the rotating shaft body. And an elastic plate having a front end projecting in a direction substantially perpendicular to the axial direction of the rotary shaft body and having a contact surface directed to one surface or the other surface of the plate-like body. ,
By changing the mounting height of the elastic body according to the size of the plate-like body and rotating the rotating shaft body, at least a portion near the tip of the contact surface of the elastic plate is placed in the plate-like shape. A method in which a plate-like plate is stored in a storage device in contact with one surface or the other surface of the body.

Images