JP3154702U - Load collapse prevention device - Google Patents

Abstract

The present invention relates to an operator for detaching a load collapse prevention band that is wound around and fixed to a stacked cargo box and the labor and time of the operator to wind and fix the load collapse prevention band around the stacked cargo box. A one-touch type collapse prevention tool that can reduce labor and time. In a collapsible prevention device comprising two beam members A and B and a beam member AB, which is bridge-fixed by the beam member AB, the beam members A and B are connected to the side plate 10a of the uppermost packing box 10 and the outermost plate 10a. It is characterized in that it is installed with one touch on the uppermost packing box so as to sandwich the side plate 20b of the upper packing box 20. [Selection] Figure 5

Description

The present invention relates to a load collapse prevention device.
More specifically, the present invention relates to a load collapse prevention tool that prevents a cargo box stacked on a cargo handling pallet or a cart from falling onto a floor surface due to vibration, impact, or the like during transfer.
More specifically, the present invention relates to a versatile load collapse prevention device that can handle various loads having different height dimensions, shapes, and the like.

Conventionally, in order to prevent the collapse of cargo stacked on cargo handling pallets, trolleys, etc., a long load collapse prevention band is wound horizontally around the outer periphery of the stacked cargo. Was done.
A number of anti-load collapse bands have been proposed.
For example, Japanese Patent Application Laid-Open No. 2004-331130 (Patent Document 1), Utility Model Registration 3129985 (Patent Document 2), Utility Model Registration 3116169 (Patent Document 3), and the like are disclosed.
Patent Document 1 provides a load collapse prevention band for wrapping and fixing to a stacked load, and the solution means includes a band-shaped winding portion, a first handle rod attached to a first end, a through hole, , A support rod attached to the second end, a narrow band fixing part extending from the center of the second end, a second handle rod attached to the end of the band fixing part, and one side of the band fixing part And a second surface fastener provided at the end, and the band fixing portion is passed through the through hole and folded to join the first and second surface fasteners.
Patent Document 2 has an object to uniformly apply a tensile force to the entire belt body when winding the transported object on the belt body, and the solution is loaded in a stacked manner on a transportation pallet. In the belt body that prevents the load from collapsing by winding around the transported material,
Tightening means for further tightening the winding force with respect to the conveyed object is provided, and the tightening means is a free end portion that can be folded back at one end of the central sewing portion with respect to the belt main body, and the surface has a longitudinal direction along the surface. Tightening band with hook-and-loop fastener installed, and insertion that connects to the belt body facing the free end of the tightening band, and allows the free end to be inserted and folded before joining to the hook-and-loop body itself It consists of a ring.
Patent Document 3 provides a simple and repetitive load collapse prevention cover, and the solution is to use a four-axis fabric or two biaxial fabrics that are resistant to omnidirectional tensile load on the trunk fabric of the load collapse prevention cover. Use a cloth that is sewn at 45 degrees, sew a triangular cloth to be hooked on the load, and sew it on the corner of the top surface of the rectangle. Each band was provided with a magic fastener (registered trademark) and sewed in parallel so as to face the body-wrapping cloth. Transparent rectangular pockets were provided on each rectangular vertical surface so that the contents of the load could be displayed. It is also characterized in that it can be folded and stored easily after use.
JP 2004-331130 A Utility model registration No. 3129985 Utility model registration No. 3116169

However, in factories or warehouses, loads loaded on cargo handling pallets are often box-shaped, and the belt-shaped load collapse prevention described in the above-mentioned patent document is applied to box-shaped loads (packing boxes). In the case of a non-standard load box, the packing style (peripheral length, height, etc., depending on the load shape) varies in various ways. The conventional technology and commercial products are uneconomical and smooth because of the so-called made-to-order method, in which each dimension must be measured and a load collapse prevention band of a size that fits the packaging must be selected. The inconvenience of not being able to proceed was also pointed out.
In addition, when a load collapse prevention band is used to wrap and fix the cargo on the stacked load, there has been a disadvantage that it takes labor and time for the operator to wind and fix the load collapse preventive band on the stacked load. .
In addition, when unloading the stacked cargo from the cargo handling pallet or the like, there has been a drawback that it takes labor and time for the operator to remove the wrapping and fixing cargo collapse prevention band.
In other words, the conventional load collapse prevention band is used to remove the load collapse prevention band from the worker's labor and time before transporting, which is required to wrap and fix the load collapse prevention band around the stacked cargo. There has been a drawback in that it takes labor of the worker who takes it after transportation.
In addition, the conventional load collapse prevention band can be secured by wrapping and fixing the load collapse prevention band around the stacked cargo or removing the fixed load collapse prevention band by winding it around the stacked cargo box. There has been a drawback that a considerable work space is required around the cargo handling pallets and the like stacked in layers.
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○ The first problem to be solved by the present invention The first problem to be solved by the present invention is the labor, time, and stacking of the operator to wind and fix the load collapse prevention band around the stacked boxes. Another object of the present invention is to provide a one-touch type load collapse prevention tool that can reduce the labor and time of an operator to remove a load collapse prevention band that is wound around a fixed packing box.
The second problem to be solved by the present invention The second problem to be solved by the present invention is to fix a load collapse prevention band by wrapping it around a stacked cargo, or by winding it around a stacked cargo box. An object of the present invention is to provide a load collapse prevention device capable of reducing a work space required around a cargo handling pallet or the like in which stacked loads are stacked in order to remove a collapse prevention band.
The third problem to be solved by the present invention The third problem to be solved by the present invention is that the side plate 10a of the stage packing box 10, the side plate 20b of the upper stage packing box 20, and the upper stage packing box An object of the present invention is to provide a one-touch type load collapse prevention tool that can reduce labor and time of an operator even for a packing box in which 30 side plates 30c are stacked so as to intersect like a three-way crossing.
The fourth problem to be solved by the present invention The fourth problem to be solved by the present invention is that the side plate 10a of the stage packing box 10, the side plate 20b of the top stage packing box 20, and the top stage packing box Even when 30 side plates 30c are stacked so as to cross like a three-way crossing, a load collapse prevention band is wrapped around and fixed to a stacked package, or is wound and fixed to a stacked package. An object of the present invention is to provide a load collapse prevention tool capable of reducing the work space required around a cargo handling pallet or the like on which stacked loads are stacked in order to remove the load collapse prevention band.

Means for solving the problem is a device described in each claim of [Utility Model Registration Claim] of the present application.
In order to resolve the doubts regarding the interpretation of terms such as the scope of the utility model registration request, description, drawings, etc., the terms will be explained below.
<Explanation of terms>
In the present specification, the girder material is a main member for exerting the effect of preventing load collapse of the stacked boxes that are mechanically constrained to move the side plate of the uppermost box. .
○ Beam material refers to a horizontal material (sub-member) for bridging and fixing girders.
○ Packing box is a box for storing luggage. In the present application, it refers to a packing box that can be stacked.
○ The uppermost packing box is the uppermost packing box among a plurality of stacked packing boxes.
In this specification, a box means a rectangular parallelepiped or cubic container without a lid during transportation.
That is, the box is composed of a bottom plate and four side plates in this specification.
In the case of a rectangular parallelepiped box, the box is composed of a bottom plate, two long side plates, and two short side plates.
○ A rectangular parallelepiped is a solid that is surrounded by two squares and four rectangles, or six rectangles, and all adjacent faces are vertical. The case where all the adjacent surfaces are plate materials and the rectangular parallelepiped is hollow or solid is also included.
○ The vertical surface of the girder means a vertical surface that dynamically restrains the movement of the side plate of the uppermost packing box.
○ A vertical plane means a plane that is parallel to the direction of gravity and is not an upper surface or a lower surface among the surfaces of the beams.
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In view of various problems that the conventional installation anchor bolt is not removed, the inventor has intensively studied and completed the present invention.
Means for solving the problem is a device described in each claim of the utility model registration claim of the present application, and specific means for solving the problem are as follows.
-First device (device described in claim 1)
A first device for solving the above problems (the device described in claim 1) is:
In the collapsible prevention device which is composed of two beam members A and B and a beam material AB and is bridged and fixed by the beam material AB, the beam members A and B are the side plate 10a of the uppermost packing box 10 and the uppermost packing box. It is a load collapse prevention device characterized in that it is installed in the uppermost packing box with one touch so as to sandwich the 20 side plates 20b.
-Second device (device described in claim 2)
A second device for solving the above problem (the device described in claim 2) is as follows.
2. The load collapse prevention tool according to claim 1, wherein the beams A and B are rectangular parallelepipeds, and the vertical surfaces Sa and Sb of the beams A and B are parallel to each other.
-Third device (device described in claim 3)
A third device for solving the above problem (the device described in claim 3) is:
The load collapse according to claim 1, wherein the side plate 10 a of the uppermost packing box 10 and the side plate 20 b of the uppermost packing box 20 are stacked so as to be in phase contact with each other. It is a prevention tool.
-Fourth device (device described in claim 4)
A fourth device for solving the above-described problem (the device described in claim 4) is:
The beam material AB is composed of two plate materials of the beam material AB1 and the beam material AB2, and the longitudinal direction of the beam material AB1 and the beam material AB2 is perpendicular to the vertical surface Sa and the vertical surface Sb of the beams A and B. The load collapse prevention device according to any one of claims 1 to 3, wherein the load collapse prevention device is configured as described above.
-Fifth device (device described in claim 5)
The fifth device (the device described in claim 5) for solving the above problem is as follows.
It consists of three girders A, B, C and beam ABC, and the girders A and girders B, C are the side plate 10a of the uppermost packing box 10, the side plate 20b of the uppermost packing box 20, and The side plate 30c of the uppermost packing box 30 is sandwiched, and the girders B and C are further sandwiched between the side plate 20b of the uppermost packing box 20 and the side plate 30c of the uppermost packing box 30. It is a load collapse prevention device characterized in that it is installed in a single packing box with one touch.
-Sixth device (device described in claim 6)
The sixth device (the device described in claim 6) for solving the above-described problem is as follows.
The beam members A, B, and C are rectangular parallelepiped, and the vertical surfaces Sb and Sc of the beam members B and C are parallel or orthogonal to each other, and the vertical surface Sa of the beam member A and the beam members B, 6. The load collapse prevention device according to claim 5, wherein the vertical surface Sb and the vertical surface Sc of C are parallel or orthogonal to each other.
-Seventh device (device described in claim 7)
The seventh device (the device described in claim 7) for solving the above problem is
The side plate 10a of the uppermost packing box 10, the side plate 20b of the uppermost packing box 20, and the side plate 30c of the uppermost packing box 30 are in contact with each other and are connected to the side plate 20b of the uppermost packing box 20. The load collapse prevention tool according to any one of claims 5 to 6, wherein the side plate 30c of the uppermost packing box 30 is also in phase contact.
-Eighth device (device described in claim 8)
The eighth device (the device described in claim 8) for solving the above-described problem is as follows.
The beam material ABC is composed of three plate materials of a beam material ABC1, a beam material ABC2, and a beam material ABC3, and the longitudinal direction of the beam material ABC1 and the beam material ABC2 and the vertical surface Sa of the beam member A are orthogonal to each other.
The load collapse prevention tool according to any one of claims 5 to 7, characterized in that the longitudinal direction of the beam material ABC3 and the vertical surface Sa of the beam material A are parallel to each other.
-Ninth device (device described in claim 9)
The ninth device (the device described in claim 9) for solving the above problem is as follows.
The longitudinal direction of the beam material ABC1 and the beam material ABC2 and the vertical surfaces Sb and the vertical surfaces Sc of the beams B and C are parallel or orthogonal,
The load collapse prevention tool according to claim 8, wherein the longitudinal direction of the beam material ABC3 and the vertical surfaces Sb and the vertical surfaces Sc of the beams B and C are parallel or orthogonal to each other.

The load collapse prevention tool according to the present invention is composed of the above-mentioned characteristic configuration requirements, and has the following effects specific to the present invention according to the characteristic configuration requirements.
Moreover, according to the load collapse prevention tool comprised from the above characteristic structural requirements, the subject of this invention was able to be solved sufficiently.
○ Effect of the first device According to the first device,
In the collapsible prevention device which is composed of two beam members A and B and a beam material AB and is bridged and fixed by the beam material AB, the beam members A and B are the side plate 10a of the uppermost packing box 10 and the uppermost packing box. Due to the characteristic configuration requirement of one-touch installation on the uppermost packing box with 20 side plates 20b being sandwiched,
The first and second problems to be solved by the present invention can be achieved, and a remarkable effect unpredictable by those skilled in the art can be achieved.
○ Effect of the second device According to the second device, the beams A and B are rectangular parallelepiped, and the vertical surfaces Sa and Sb of the beams A and B are parallel to each other. Depending on requirements
The first and second problems to be solved by the present invention can be achieved, and a remarkable effect unpredictable by those skilled in the art can be achieved.
Effect of the third device According to the third device, the side plate 10a of the uppermost packing box 10 and the side plate 20b of the uppermost packing box 20 are stacked so as to be in contact with each other. Depending on requirements
The first and second problems to be solved by the present invention can be achieved, and a remarkable effect unpredictable by those skilled in the art can be achieved.
○ Effect of the fourth device According to the fourth device, the beam member AB is composed of two plate members, the beam member AB1 and the beam member AB2, and the longitudinal direction of the beam member AB1 and the beam member AB2 and the beam member A, Due to the characteristic configuration requirement that the vertical surface Sa and the vertical surface Sb of B are configured to be orthogonal to each other,
The first and second problems to be solved by the present invention can be achieved, and a remarkable effect unpredictable by those skilled in the art can be achieved.
○ Effect of the fifth device According to the fifth device,
It consists of three girders A, B, C and beam ABC, and the girders A and girders B, C are the side plate 10a of the uppermost packing box 10, the side plate 20b of the uppermost packing box 20, and The side plate 30c of the uppermost packing box 30 is sandwiched, and the girders B and C are further sandwiched between the side plate 20b of the uppermost packing box 20 and the side plate 30c of the uppermost packing box 30. Due to the characteristic configuration requirement of one-touch installation in the packing box
The third to fourth problems to be solved by the present invention can be achieved, and a remarkable effect unpredictable by those skilled in the art can be achieved.
Effect of the sixth device According to the sixth device, the beams A, B, C are rectangular parallelepiped, and the vertical surfaces Sb and the vertical surfaces Sc of the beams B, C are parallel or orthogonal to each other. In addition, by making the vertical surface Sa of the beam A and the vertical surface Sb and the vertical surface Sc of the beams B and C are parallel or orthogonal to each other,
The third to fourth problems to be solved by the present invention can be achieved, and a remarkable effect unpredictable by those skilled in the art can be achieved.
Effect of the seventh device According to the seventh device, the side plate 10a of the uppermost packing box 10, the side plate 20b of the uppermost packing box 20, and the side plate 30c of the uppermost packing box 30 are in phase. Due to the characteristic configuration requirement that the side plate 20b of the uppermost packing box 20 and the side plate 30c of the uppermost packing box 30 also come into contact with each other,
The third to fourth problems to be solved by the present invention can be achieved, and a remarkable effect unpredictable by those skilled in the art can be achieved.
Effect of Eighth Device According to the eighth device, the beam material ABC is composed of three plate materials of the beam material ABC1, the beam material ABC2, and the beam material ABC3, and the longitudinal direction of the beam material ABC1 and the beam material ABC2 The vertical surface Sa of the beam A is orthogonal,
Due to the characteristic configuration requirement that the longitudinal direction of the beam material ABC3 and the vertical surface Sa of the beam material A are configured to be parallel,
The third to fourth problems to be solved by the present invention can be achieved, and a remarkable effect unpredictable by those skilled in the art can be achieved.
Effect of the ninth device According to the ninth device, the longitudinal direction of the beam material ABC1 and the beam material ABC2 and the vertical surface Sb and the vertical surface Sc of the beams B and C are parallel or orthogonal,
Due to the characteristic configuration requirement that the longitudinal direction of the beam material ABC3 and the vertical surfaces Sb and the vertical surfaces Sc of the beams B and C are parallel or orthogonal,
The third to fourth problems to be solved by the present invention can be achieved, and a remarkable effect unpredictable by those skilled in the art can be achieved.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the best embodiment relating to a load collapse prevention device according to the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view of a load collapse prevention device according to a first embodiment of the present invention.
FIG. 2 is a plan view, a front view, and a right side view of the load collapse prevention device of the first embodiment according to the present invention.
Fig.2 (a) is a top view of the load collapse prevention tool of 1st Embodiment based on this invention.
FIG.2 (b) is a front view of the load collapse prevention tool of 1st Embodiment based on this invention.
FIG.2 (c) is a right view of the load collapse prevention tool of 1st Embodiment based on this invention.
FIG. 3 is a perspective view of the load collapse prevention device according to the second embodiment of the present invention.
FIG. 4 is a plan view, a front view, and a right side view of the load collapse prevention device of the second embodiment according to the present invention.
Fig.4 (a) is a top view of the load collapse prevention tool of 2nd Embodiment based on this invention.
FIG.4 (b) is a front view of the load collapse prevention tool of 2nd Embodiment based on this invention.
FIG.4 (c) is a right view of the load collapse prevention tool of 2nd Embodiment based on this invention.
FIG. 5 is an installation view of the load collapse prevention device of the first embodiment according to the present invention.
FIG. 6 is an installation view of the load collapse prevention device of the second embodiment according to the present invention.
FIG. 7 is an installation view of another load collapse prevention device according to the first embodiment of the present invention.
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<Unloading prevention tool of the first embodiment>
Hereinafter, the load collapse prevention tool according to the first embodiment of the present invention will be described with reference to FIGS. 1, 2, and 5.
The load collapse prevention tool 100 includes two beam members A and B and a beam material AB, and is bridged and fixed by the beam material AB.
In the load collapse prevention device 100, the girders A and B are installed in the uppermost packing box with one touch so as to sandwich the side plate 10a of the uppermost packing box 10 and the side plate 20b of the uppermost packing box 20. The
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In the load collapse prevention tool, the girders A and B are rectangular parallelepipeds.
The vertical surfaces Sa and the vertical surfaces Sb of the beams A and B are parallel to each other.
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In the load collapse prevention device, the side plate 10a of the uppermost packing box 10 and the side plate 20b of the uppermost packing box 20 are stacked so as to contact each other.
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In the load collapse prevention tool, the beam member AB is composed of two plate members, the beam member AB1 and the beam member AB2, and the longitudinal direction of the beam member AB1 and the beam member AB2 and the vertical surfaces Sa and the vertical surfaces of the beam members A and B are perpendicular to each other. The load collapse prevention device according to any one of claims 1 to 3, wherein Sb is configured to be orthogonal to each other.
<Load collapse prevention device of the second embodiment>
Hereinafter, the load collapse prevention tool according to the second embodiment of the present invention will be described with reference to FIGS. 3, 4, and 6.
The load collapse prevention tool 200 includes three beam members A, B, and C and a beam member ABC.
In the load collapse prevention tool 200, the girders A and the girders B and C are formed from the side plate 10a of the uppermost packing box 10, the side plate 20b of the uppermost packing box 20, and the sides of the uppermost packing box 30. The girders B and C are installed on the uppermost packing box with one touch so as to sandwich the side plate 20b of the uppermost packing box 20 and the side plate 30c of the uppermost packing box 30. The
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In the load collapse prevention tool 200, the girders A, B, and C are rectangular parallelepipeds.
The vertical surfaces Sb and Sc of the beams B and C are parallel or orthogonal to each other, and the vertical surface Sa of the beams A and the vertical surfaces Sb and Sc of the beams B and C are parallel or Orthogonal.
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In the load collapse prevention device 200, the side plate 10a of the uppermost packing box 10, the side plate 20b of the uppermost packing box 20, and the side plate 30c of the uppermost packing box 30 are in phase contact with each other, and The side plate 20b of the packing box 20 and the side plate 30c of the uppermost packing box 30 are also in phase contact with each other.
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In the load collapse prevention tool 200, the beam material ABC is composed of three plate materials of the beam material ABC1, the beam material ABC2, and the beam material ABC3, and the longitudinal direction of the beam material ABC1 and the beam material ABC2 and the vertical surface Sa of the beam material A. And are orthogonal,
The longitudinal direction of the beam material ABC3 and the vertical surface Sa of the beam material A are configured to be parallel to each other.
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In the load collapse prevention tool 200, the longitudinal direction of the beam material ABC1 and the beam material ABC2 and the vertical surfaces Sb and the vertical surfaces Sc of the beams B and C are parallel or orthogonal,
The longitudinal direction of the beam material ABC3 and the vertical surfaces Sb and the vertical surfaces Sc of the beams B and C are parallel or orthogonal to each other.
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In <the load collapse prevention tool of the first embodiment>, the beam material AB1 and the beam material AB2 are disclosed as having an equilateral mountain shape,
FIG. 7 discloses a case where the beam member AB1 and the beam member AB2 are plate members.

FIG. 1 is a perspective view of a load collapse prevention device according to a first embodiment of the present invention. FIG. 2 is a plan view, a front view, and a right side view of the load collapse prevention device of the first embodiment according to the present invention. Fig.2 (a) is a top view of the load collapse prevention tool of 1st Embodiment based on this invention. FIG.2 (b) is a front view of the load collapse prevention tool of 1st Embodiment based on this invention. FIG.2 (c) is a right view of the load collapse prevention tool of 1st Embodiment based on this invention. FIG. 3 is a perspective view of the load collapse prevention device according to the second embodiment of the present invention. FIG. 4 is a plan view, a front view, and a right side view of the load collapse prevention device of the second embodiment according to the present invention. Fig.4 (a) is a top view of the load collapse prevention tool of 2nd Embodiment based on this invention. FIG.4 (b) is a front view of the load collapse prevention tool of 2nd Embodiment based on this invention. FIG.4 (c) is a right view of the load collapse prevention tool of 2nd Embodiment based on this invention. FIG. 5 is an installation view of the load collapse prevention device of the first embodiment according to the present invention. FIG. 6 is an installation view of the load collapse prevention device of the second embodiment according to the present invention. FIG. 7 is an installation view of another load collapse prevention device according to the first embodiment of the present invention.

100 Load collapse prevention tool (load collapse prevention tool of the first embodiment)
200 Load collapse prevention tool (load collapse prevention tool of the second embodiment)
A, B, C Girder AB Beam material (beam material of the first embodiment)
AB1, AB2 Beam material (beam material of the first embodiment)
ABC beam material (beam material of the second embodiment)
ABC1, ABC2 Beam material (beam material of the second embodiment)
ABC3 beam material (beam material of the second embodiment)
10, 20, 30 Uppermost packing box 10a Side plate of uppermost packing box 10
20b Side plate 30c of the uppermost packing box 20 Side plate of the uppermost packing box 30
Sa Vertical surface of the beam A Sb Vertical surface of the beam B Sc Vertical surface of the beam C

Claims (9)

  In a collapsible prevention device that consists of two beam members (A), (B) and a beam member (AB) and is bridge-fixed by the beam member (AB), the beam members (A), (B) are the uppermost loads. A load collapse prevention tool, which is installed in the uppermost packing box with one touch so as to sandwich the side plate (10a) of the box (10) and the side plate (20b) of the uppermost packing box (20).   The beams (A) and (B) are rectangular parallelepipeds, and the vertical surfaces (Sa) and (Sb) of the beams (A) and (B) are parallel to each other. The load collapse prevention device described in 1.   The side plate (10a) of the uppermost packing box (10) and the side plate (20b) of the uppermost packing box (20) are stacked so as to be in phase contact with each other. The load collapse prevention device described in any one.   Beam material (AB) is composed of two plate materials, beam material (AB1) and beam material (AB2). The longitudinal direction of beam material (AB1) and beam material (AB2) and beam material (A), (B) The load collapse prevention device according to any one of claims 1 to 3, wherein the vertical surface (Sa) and the vertical surface (Sb) are configured to be orthogonal to each other.   It consists of three girders (A), (B), (C) and a beam (ABC). The girders (A) and girders (B), (C) are the uppermost packing box (10). The side plate (10a), the side plate (20b) of the uppermost packing box (20), and the side plate (30c) of the uppermost packing box (30) are sandwiched. C) is installed in the uppermost packing box with one touch so as to sandwich the side plate (20b) of the uppermost packing box (20) and the side plate (30c) of the uppermost packing box (30). The load collapse prevention tool.   The girders (A), (B), (C) are rectangular parallelepiped, and the vertical surfaces (Sb) and (Sc) of the girders (B), (C) are parallel or orthogonal to each other. The vertical surface (Sa) of the beam (A) and the vertical surfaces (Sb) and (Sc) of the beams (B) and (C) are parallel or orthogonal to each other. The load collapse prevention device described in 1.   The side plate (10a) of the uppermost packing box (10), the side plate (20b) of the uppermost packing box (20), and the side plate (30c) of the uppermost packing box (30) are in phase contact with each other. The side plate (20b) of the uppermost packing box (20) and the side plate (30c) of the uppermost packing box (30) are also in phase contact with each other. Unloading prevention tool. The beam material (ABC) is composed of three plate materials, ie, a beam material (ABC1), a beam material (AB2), and a beam material (AB3). The longitudinal direction of the beam material (ABC1) and the beam material (AB2) and the beam material ( A) is perpendicular to the vertical plane (Sa),
The load collapse according to any one of claims 5 to 7, wherein the longitudinal direction of the beam member (AB3) and the vertical surface (Sa) of the beam member (A) are parallel to each other. Prevention tool. The longitudinal direction of the beam member (ABC1) and the beam member (AB2) and the vertical surface (Sb) and the vertical surface (Sc) of the beam member (B), (C) are parallel or orthogonal,
The load according to claim 8, wherein the longitudinal direction of the beam member (AB3) and the vertical surfaces (Sb) and (Sc) of the beams (B) and (C) are parallel or orthogonal to each other. Collapse prevention tool.