WO2024053682A1 - Container - Google Patents

Abstract

A container 10 comprises a pair of front/rear surfaces 14, a pair of side surfaces 12, a top surface structure 16, and a bottom surface structure 18 such that it is possible to accommodate the side surfaces 12 on the inside of the top surface structure 16. The container 10 further comprises front/rear surface frames 20 configured so as to surround the four sides of the respective front/rear surfaces 14, and the front/rear surface frames 20 standing upright on the bottom surface structure 18 can be folded down towards the bottom surface structure 18 while being lifted. The top surface structure 16 in which the side surfaces 12 have been accommodated can be raised and lowered along support pillars 20A between the upper ends of the upright front/rear surface frames 20 and the bottom surface of the bottom surface structure 18, and the front/rear surfaces 14 can be placed in prone upon the top surface structure 16 that has been lowered onto the bottom surface.

Description

container

The present invention relates to containers used for freight transportation, truck boxes, railway freight cars, container houses, etc.

Demand for cargo transport is generally asymmetric between regions, so when transporting cargo using containers, the containers often become empty on the outbound or return journey. Containers occupy the same volume regardless of whether they are loaded with cargo or not, so a large number of empty containers are transported. To solve this problem, the applicant separated the container into an upper and a lower container, and made it possible to fold the supports provided at the four corners of the container inward using the upper container or the lower container as a fulcrum. has proposed a container that can reduce the container volume by half or less (Patent Document 1). On the other hand, in the case of truck boxes, railway freight cars, container houses, etc., reducing the volume of containers when not in use is not usually considered.

Patent No. 6311850

An object of the present invention is to provide a container whose volume when empty is further reduced and transportation efficiency when empty is increased.

The container of the present invention is a container comprising a pair of end faces, a pair of side faces, a top structure and a floor structure, the sides being placed below the top structure or on top of the floor structure. A side tipping means for folding, a gable frame configured to surround the gable on all sides, and a gable frame that stands upright on the floor structure can be lifted and folded toward the floor structure. The top structure is movable up and down along the support between the upper end of the upright gable frame and the floor surface of the floor structure, and the gable tipping means is , is characterized in that it can be placed with its end face down on top of a top structure lowered to the floor.

In the floor structure, a recess is provided under the gable frame that stands upright to accommodate the auxiliary support column in a fallen state, and when the auxiliary support column is set upright, the tip of the auxiliary support column will be placed above the top structure. It extends to a higher position than the gable surface on which it is placed. A connecting mechanism for connecting the containers to each other is provided at the tip of the auxiliary support.

The gable overturning means includes, for example, a rotation shaft provided on the side of the floor structure, and an arm whose one end is pivotally supported by the rotation shaft and whose other end is fixed to the lower end of the support column. , located a predetermined distance inside along the longitudinal direction from the gable surface.

The gable tipping means includes, for example, a gable guide member provided on the side of the floor structure and having a guide groove extending in the vertical direction, one end of which is engaged with the guide groove, and the other end of which is engaged with the lower end of the support column. Equipped with a fixed gable rotation axis.

A side surface engaging portion that engages with the upper end or lower end of the side surface may be provided along the side of the top surface structure or the floor surface structure. In addition, a side housing part that can accommodate the side surfaces may be provided on the lower side of the top structure. contained within the body. For example, the side surfaces are divided into an even number of upper and lower panels so that they can be folded inward, and a pair of side surfaces are folded in a state in which the left and right sides are parallel. Further, a locking mechanism may be provided on the support column to prevent the top structure from falling.

According to the present invention, it is possible to provide a container whose volume when empty is further reduced and transportation efficiency when empty is increased.

FIG. 1 is a perspective view schematically showing the configuration of a container according to the first embodiment. FIG. 2 is a perspective view schematically showing the structure of a forklift engaging portion provided on the top surface used for folding the container of FIG. 1; They are a side view schematically showing how the container top is lowered, and a partially enlarged view showing the configuration of a mechanism for preventing the container top from falling, which is provided on a support. FIG. 2 is a perspective view schematically showing how the front and rear frames (pillars) are folded together with the front and rear doors (gable side). FIG. 2 is a perspective view schematically showing the configuration of an auxiliary support column used when stacking folded containers. FIG. 2 is a perspective view schematically showing the configuration of a container according to a second embodiment. It is a perspective view which shows typically the structure which accommodates a side surface in a container top surface part in 2nd Embodiment. It is a perspective view which shows typically the structure of the container of 3rd Embodiment. FIG. 2 is a perspective view schematically showing a state in which folded containers are stacked. It is a typical perspective view of the container of a 4th embodiment assembled to a 1st height. It is a typical sectional view of a side engaging part. It is a typical cross-sectional view of a container of a 4th embodiment. It is a typical perspective view when folding the container of 4th Embodiment of 1st height. It is a typical perspective view of the container of a 4th embodiment folded to the 2nd height. It is a typical perspective view seen diagonally from below showing the structure of the groove of the side engaging part corresponding to a corrugated steel plate. It is a typical sectional view of the side engaging part of a modification. It is a partial typical perspective view of the container of 5th Embodiment. It is a partial typical perspective view of the container of 5th Embodiment. It is a partial schematic perspective view of the container of the modification of 5th Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. Note that the container according to the present invention can be used not only as a marine container (intermodal container), but also as a truck box or a railway freight car, and can also be used as a container house. Therefore, in the specification and claims of this application, the term "container" includes marine containers, packing boxes, freight cars, and container houses. FIG. 1 is a perspective view showing a rough configuration of a container according to a first embodiment of the present invention.

The container 10 of the first embodiment includes a pair of left and right sides 12, a pair of front and rear gables 14, a top structure 16, and a floor structure 18. As shown in FIG. 1, the side surface 12 is pivotally supported on the side of the top surface structure 16 via a hinge or the like (side surface overturning means) and is rotatable toward the inside of the container. The height of the folded side surface 12 is shorter than the width of the top surface structure 16, and the side surface 12 rotated inward is inserted from the lower side into the inside of the side surface storage section provided under the top surface structure 16. It can be accommodated. Note that the left and right side surfaces 12 are housed in the top structure 16 while being alternately stacked on top of each other at different heights relative to the top structure 16, and are fixed within the top structure 16 by a locking mechanism (not shown). be done. Further, the height at which the left and right side surfaces 12 are pivotally supported by the sides of the top surface structure 16 is determined according to the aspect ratio of the container 10, and in order to alternately fold both side surfaces 12, They may be set at different heights. For example, an ISO standard container has a width W of 2438 mm and a height H of three types: 2896 mm, 2591 mm, and 2438 mm, so the height at which the side surface 12 is pivoted is adapted to each. Note that when the left and right side surfaces 12 are standing upright, the lower sides of the side surfaces 12 can be fixed to the sides of the floor structure 18 by a locking mechanism (not shown).

FIG. 2 is a schematic enlarged view of the top surface of the container 10. In addition, in FIG. 2, the gable surface 14 on the near side is omitted. A pair of forklift holes 16A into which forks of a forklift are inserted are provided near the longitudinal center of the top structure 16 so as to span over the left and right side frames. The forklift hole 16A is used when raising and lowering the top structure 16 in which the side surfaces 12 are accommodated, and the lifting of the top structure 16 is performed using the power of the forklift.

FIG. 3 is a side view showing how the top structure 16 is lowered, and FIG. 4 is a side view showing how the gable 14 is pushed down onto the top structure 16 lowered onto the floor structure 18. It is. Note that FIG. 4(a) shows a state in which the front and rear gables 14 are standing upright on the floor structure 18, and the top structure 16 is lowered onto the floor. 4(b) shows a state in which only the front gable surface 14 is folded over the floor surface structure 18, with the rear gable surface 14 standing upright.

As shown in FIG. 4, the four sides of the gable surface 14 are surrounded by the gable surface frame 20, and inside the gable surface frame 20, for example, a double door 22 and a wall surface 24 are attached. It is also possible to use a door 22 at both the front and rear, a wall surface 24 at both the front and rear, the door 22 at one end, and the wall surface 24 at the other end. Posts 20A that support the top structure 16 are arranged on the left and right sides of the gable frame 20, and the upper and lower ends of the posts 20A are connected through crossbeams 20B. A coupling mechanism 26 is provided at the upper end of the support column 20A, which is used for coupling with a container stacked on top during container operation. Note that a connection mechanism 26 used for connection with the container below is provided on the bottom surface of the floor structure 18 corresponding to the position of the support column 20A. Note that the connection mechanism 26 uses, for example, a structure similar to that of a conventional container.

The lower end of the support column 20A is fixed to the other end of an arm (end surface overturning means) 28 whose one end is pivotally supported by the side frame of the floor surface structure 18. The rotation axis 28A of the arm 28 provided on the side frame of the floor structure 18 is located inside along the longitudinal direction by a predetermined distance D from the center of the gable frame 20 that stands upright. The distance D is determined according to the thickness of the top structure 18 lowered onto the floor. That is, when the gable frame 20 is rotated around the rotation axis 28A and tilted toward the top structure 16 on the floor structure 18, the gable frame 20 is lifted and the gable 14 is moved toward the top structure 16. It is set so that it can be folded almost perfectly onto the top of the screen.

When the gable frame 20 is upright, the top structure 16 is arranged to be sandwiched between the front and rear gable frames 20. When loading cargo, the top structure 16 is placed at the height (first height) of the upper end of the gable frame 20, as shown by the solid line in FIG. Lock mechanisms 30 are provided at predetermined height intervals on the surface of the support column 20A that is in contact with the top surface structure 16. The locking mechanism 30 prevents the top structure 16 from falling by engaging the claw pushed out of the support column 20A by a biasing force such as a spring, and also prevents the top structure 16 from falling when the top structure 16 is raised. It has a latch bolt structure in which the claw is pushed back into the support column 20A.

When used at the first height, the top structure 16 is supported by the lock mechanism 30, and its end is fixed to the upper end of the support column 20A by a lock mechanism (not shown). Note that the gable frame 20, which is now standing upright, is fixed to the frame of the floor structure 18 by a locking mechanism (not shown). When the top surface structure 16 is lowered to the height (second height) in contact with the floor surface structure 18, the lock mechanism 30 is housed in the support column 20A by a lock release mechanism (not shown).

Further, as shown in FIG. 5, an auxiliary support 32 is provided on the frame of the floor structure 18 at a position corresponding to the bottom of the upright support 20A. The auxiliary support column 32 can be tilted inward in the width direction, and is housed in a recess 32A provided in the frame of the floor structure 18 when the gable frame 20 is erected. As shown in FIG. 4(b), when the end surface 14 is folded onto the top surface structure 16 placed on the floor surface structure 18, it becomes possible to stand the auxiliary support column 32 upright. The upright auxiliary column 32 can be fixed in position by a locking mechanism (not shown).

A connecting mechanism 34 having the same function as the connecting mechanism 26 is provided at the upper end of the auxiliary column 32. When the container 10 is completely folded, that is, the front and rear gables 14 are folded over the top structure 16 and fixed to the floor structure 18 by a locking mechanism (not shown), the auxiliary support 32 is When erected, the connecting mechanism 34 is placed at a slightly higher position than the gable 14 folded over the top structure 16. As shown in FIG. 9, when the folded containers 10 are stacked, the connecting mechanism 34 is engaged with and fixed to the connecting mechanism 26 provided on the floor structure 18 of the upper container 10. Note that the same configuration is the same in other embodiments.

On the other hand, when unfolding the container 10 that has been folded to the second height and assembling it to the first height, an operation opposite to the above-mentioned folding operation is performed. That is, after the front and rear gables 14 are stood upright, the top structure 16 is lifted to the first height using a forklift and fixed to the gable frame 20, and then the left and right side surfaces 12 are unfolded to open the side surfaces of the container 10. It is sealed and fixed to the gable frame 20 or the floor structure 18. Note that corners such as both ends of the frame on the gable surface 14 side of the top surface structure 16 are rounded, and when the top surface structure 16 is lifted, the gable surface 14 is raised by contact with the top surface structure 16. It is also possible to have a configuration in which In this case, it is preferable that the surface of the top structure 16 in contact with the gable frame 20 be treated with a special material in consideration of wear resistance and low friction. Examples of surface treatments include coatings (such as Dichlon coating) and plating (such as electroless nickel plating and hard chrome plating), and special materials include ABREX (registered trademark), HARDOX (registered trademark), and EVERHARD ( Possible uses include registered trademarks.

Note that when loading or unloading the container 10, one or both of the left and right side surfaces 12 are placed inside the top structure 16 while maintaining the top structure 16 at the first height. These operations can be performed from the side of the container 10.

As described above, according to the container of the first embodiment, the volume when empty can be further reduced, and as a result, the transportation efficiency when empty can be increased. Moreover, its structure is simple, and the folding work of the container can be easily carried out by a small number of people. The use of auxiliary struts also allows containers that are folded when empty to be safely stacked in a manner similar to conventional containers.

Next, the structure of the container 36 of the second embodiment will be explained with reference to FIG. 6, which is a perspective view showing the rough structure of the container 36, and FIG. 7, which is an enlarged view of the top surface of the container 36. explain. In addition, in FIG. 7, the gable surface 14 on the near side is omitted. The container 36 of the second embodiment has substantially the same configuration as the container 10 of the first embodiment, but the structure of the side surface 12 is different. The same reference numerals are used for the same configuration as in the first embodiment, and the description thereof will be omitted.

The side surface 38 of the second embodiment is vertically divided into a plurality of (even number of) panels, each of which is connected by a hinge. The panel can be folded into a bellows shape toward the inside of the container 36. In the example of FIG. 6, it is divided into two upper and lower panels 38A and 38B. The upper side of the upper panel 38A is pivotally supported by the side of the top structure 16, and the lower side is connected to the upper side of the lower panel 38B via a hinge. Both ends of the lower side of the lower panel 38B are configured to be movable along guide grooves provided along the support column 20A. The upper and lower panels 38A, 38B are folded toward the inside of the container 36 in a folding operation. When the lower side of the lower panel 38B reaches the height of the top structure 16, the upper and lower panels 38A and 38B are accommodated in the top structure 16 in a folded state. The folded left and right side walls 38 are dimensioned so that they do not interfere with each other within the top structure 16. In addition, when dividing into four or more panels, both ends of the lower sides of even-numbered panels from the top are configured to be movable along the support column 20A.

As described above, the same effects as in the first embodiment can be obtained in the container of the second embodiment. In the second embodiment, the lower side of the lower panel 38B is made detachable from the frame of the floor structure 18, and the side surface 38 is lifted while being folded and housed in the top structure 16. It is also possible to adopt a configuration in which the lower side is pivotally supported on the side side of the frame of the floor surface structure 18. In this case, the side surfaces 38 are folded as the top structure 16 descends, and when the top structure 16 contacts the floor structure 18, it is accommodated within the top structure 16. This eliminates the need for a locking mechanism for fixing the upper and lower panels 38A, 38B within the top structure 16.

Next, the container of the third embodiment will be described with reference to FIG. Similar to the second embodiment, the container of the third embodiment differs from the first embodiment in the side configuration. The other configurations are the same as those in the first and second embodiments, and the same reference numerals are used for the same configurations, and the description thereof will be omitted.

The side wall 42 of the container 40 of the third embodiment includes a plurality of (even number of) panels 42A, 42B connected by hinges as in the second embodiment, and a tilt plate-like structure that is completely separated from the panels 42A, 42B. It is divided into a panel 42C. Panels 42A and 42B have the same configuration as panels 38A and 38B of the second embodiment. The lower edge of the panel 42C is pivotally supported by the side edge of the floor structure 18, and the panel 42C is rotatable to the inside or outside of the container 40. When fixing the top surface structure 16 at the first height, the panels 42A, 42B, and 42C are stood upright, and the lower side of the panel 42B and the upper side of the panel 42C are fixed by a locking mechanism (not shown). When the top structure 16 is lowered onto the floor structure 18 and the container 40 is folded, the panels 42A and 42B are folded and housed in the top structure 16, and the panel 42C is placed on the floor structure 18. can be folded onto the floor. When loading and unloading the container 40 with the side wall 42 open, the panel 42C is rotated to the outside of the container 40.

As described above, the same effects as the first and second embodiments can be obtained in the container of the third embodiment.

Next, the container of the fourth embodiment will be described with reference to FIGS. 10 to 15. FIG. 10 is a perspective view of the container 50 of the fourth embodiment assembled at the first height. The container 50 of the fourth embodiment has a structure in which left and right side surfaces 52 are folded inward along the sides of the floor structure 18. Each side 52 can be staggered over the floor structure 18 along the sides of the floor structure 18 using, for example, hinges. Further, the top surface structure 16 of the container 50 is provided with side surface engaging portions 54 along the lower surface of each side. The other configurations are substantially the same as those in the first to third embodiments, and similar configurations will be designated by the same reference numerals and their descriptions will be omitted.

As shown in the cross-sectional view of FIG. 11, the side surface engaging portion 54 is provided with a groove 54A capable of accommodating the upper end portion of the side surface 52. It is fitted in the groove 54A of the side surface engaging portion 54 in a watertight manner (for example, a sealing member 54B is provided in the groove 54A). The side surface engaging portion 54 partially plays the role of a side surface in the upper part of the container, and the height of the side surface 52 is set to be shorter than the width W. Further, the lower ends of the left and right side surfaces 52 are pivotally supported around rotation axes L1 and L2 provided at different heights with respect to the floor structure 18. With the above configuration, the left and right side surfaces 52 can be folded in a staggered manner on the floor surface of the floor surface structure 18, as shown in the cross-sectional view of FIG.

When folding the container 50 with the top structure 16 assembled at the first height to the second height, as shown in the perspective view of FIG. is lifted and the upper end of the side surface 52 is removed from the groove 54A of the side surface engaging portion 54. Each side 52 is then folded onto the floor surface of the floor surface structure 18. Next, as shown in the perspective view of FIG. 14, the top structure 16 is placed on the side surface 52 folded over the floor structure 18 by a lifting device such as a forklift, and the As in the third embodiment, the front and rear end surfaces 14 are folded over the top surface structure 16 placed on the side surface 52, and the auxiliary support column 32 is erected.

In addition, when a corrugated steel plate is used for the side surface 52, the groove 54A is also structured to correspond to the corrugated shape of the side surface 52, as shown in FIG. mated to.

Further, as a modification of the side engaging part 54, as shown in the cross-sectional view of FIG. It's okay. In this case, the side surface 52 can be operated without significantly lifting the top structure 16.

As described above, in the container of the fourth embodiment, the same effects as those of the first to third embodiments can be obtained, and higher watertightness can be ensured. Note that the configuration of the side surface engaging portions 54 and 55 of the fourth embodiment can also be applied to the floor surface structure 18 side of the first embodiment. Further, in the fourth embodiment, a groove like a side surface engaging portion is provided along the side of the floor surface structure 18, and the lower end portion of the side surface 52 is fitted into the floor surface structure 18 in a slightly watertight manner. You can also do that.

17 and 18 are partial perspective views of the container of the fifth embodiment. In the first to fourth embodiments, a substantially L-shaped arm 28 is used as the gable tipping means, but in the fifth embodiment, a gable guide member 56, which will be described later, is used. Note that the other configurations are substantially the same as those of the fourth embodiment, and the same reference numerals are used for the similar configurations, and the description thereof will be omitted.

FIG. 17 is a perspective view of the area around the gable guide member 56 when the container is assembled at the first height, and FIG. 18 shows the side surface 52 folded onto the floor structure 18, A state in which the top surface structure 16 is placed on the side surface 52 and the gable surface 14 is guided by the gable surface guide member 56 and folded over the top surface structure 16 is shown.

The gable guide member 56 is a long plate member, and the center thereof is provided with a slit-shaped guide groove 56A extending along the longitudinal direction (vertical direction). A gable surface rotating shaft 14B that protrudes outward is provided at the lower end of the support column 20A of the gable surface 14. The gable guide member 56 is attached to the floor structure 18 so as to be disposed along the outside of the support column 20A, and the gable rotation shaft 14B is engaged with the guide groove 56A. Thereby, the end surface rotating shaft 14B can move in the vertical direction within the guide groove 56A.

As shown in FIG. 18, when the left and right side surfaces 52 are folded onto the floor structure 18 and the top surface structure 16 is placed on the folded side surfaces 52, the gable surface 14 (gable surface frame 20 ) is lifted using a lifting device such as a forklift while maintaining an upright position. At this time, the gable surface rotating shaft 14B is moved along the guide groove 56A while the gable surface 14 is kept upright. When the gable surface rotating shaft 14B reaches the upper end of the guide groove 56A, the gable surface 14 is folded onto the top surface structure 16 that has been lowered to the second height with the gable surface rotating shaft 14B as the rotation axis. Here, the length of the guide groove 56A approximately corresponds to the predetermined distance D, for example.

Further, at the four corners of the floor structure 18, there are guide columns (not shown) that maintain the upright state of the gable surface 14 on the floor structure 18 and guide the elevation and descent of the gable surface 14 in the upright state. may be provided. The guide columns protrude vertically upward from, for example, the four corners of the floor surface structure 18, and engage with each of the columns 20A. The guide column is a member shorter than the distance D, and is inserted into a guide hole provided along the longitudinal direction inside the column 20A. When the gable 14 is placed upright on the floor structure 18, the guide support is fitted into the guide hole from the bottom of the support 20A. When the end face 14 (post 20A) is lifted vertically, the support post 20A is moved along the guide post while maintaining the vertical state, and when the end face rotation axis 14B reaches the upper end of the guide groove 56A, the guide post moves into the guide hole. The end face 14 is completely removed from the container, and the end face 14 becomes rotatable toward the inside of the container around the end face rotation axis 14B.

Further, the gable frame 20 is provided with a gable lift member 14A at an appropriately predetermined position, and when folding the gable 14, a wire is hooked onto the gable lift member 14A, and a lifting device such as a forklift lifts the gable. lift up. In the examples shown in FIGS. 17 and 18, the gable lift members 14A are provided at two locations on the left and right of the lower crossbeam 20B, but the gable lift members 14A are provided at the left and right columns 20A and the upper crossbeam 20B. They may be provided at a plurality of heights on the gable surface 14, respectively. Further, it may be provided at a location other than the gable frame 20 if there is no problem in terms of strength.

FIG. 19 is a partial perspective view of a container showing the configuration of a modified example of the fifth embodiment. In the fifth embodiment, the gable guide member 56 is arranged outside the support column 20A (outside the frame of the floor structure 18), but in a modified example, the gable guide member 56 is arranged on the frame of the floor structure 18 adjacent to the support column 20A. It will be established. For example, an L-shaped gable rotation shaft 15 that engages with the guide groove 56A of the gable guide member 56 is provided at the lower end of the support column 20A. One end of the L-shaped end surface rotating shaft 15 is attached to the inner surface of the support column 20A in the longitudinal direction of the container and extends along the longitudinal direction of the container, and the other end is bent outward by 90 degrees and engages with the guide groove 56A. will be combined. As a result, the gable surface rotation shaft 15 can be moved up and down along the guide groove 56A, and the gable surface is lowered to the second height with the gable surface rotation shaft 15 as the rotation axis at the upper end of the guide groove 56A. It can be folded up. Note that the shape of the end face rotating shaft 15 is not limited to this embodiment as long as it serves as a rotating shaft, and may be U-shaped, for example. In this case, both ends of the U-shape are attached to the support column 20A. Moreover, the attachment location to the support column 20A is not limited to this embodiment. Moreover, in this modification, the gable surface rotating shaft 15 and the gable surface guide member 56 are configured to be arranged outside the recess of the side surface 52 made of a corrugated steel plate.

As described above, the fifth embodiment can also achieve the same effects as the first to fourth embodiments.

In addition, when the container of this embodiment is used as a loading box of a truck or a freight car on a railway, it can be used on the assumption that the container will be attached to and detached from the chassis of a truck or freight car, but it may be used without assuming that it will be removed. It can also be used in any condition.

Here, the configuration of each part described in each embodiment can be applied independently to other embodiments as long as there is no structural contradiction. For example, the configuration in which the side surface of the second and third embodiments is divided into a plurality of panels is also applicable to the side surface of the fourth and fifth embodiments. Further, the configuration of the gable face overturning means can also be replaced in each embodiment, and other configurations can also be replaced as long as they do not conflict structurally.

Claims (9)

1. A container comprising a pair of end faces, a pair of side faces, a top structure and a floor structure,
   side tipping means for folding the side surface under the top structure or onto the floor structure;
   a gable face frame configured to surround the gable face on all sides;
   and a gable tipping means that makes it possible to lift the gable frame standing upright on the floor structure while tilting it down toward the floor structure,
   The top surface structure is movable up and down along the support between the upper end of the upright gable frame and the floor surface of the floor structure,
   The container, wherein the gable end overturning means is capable of being placed on the top structure lowered onto the floor surface with the gable end facing down.
2. In the floor structure, a recess for accommodating the auxiliary support column in a fallen state is provided below the gable frame that stands upright, and when the auxiliary support column is set upright, the tip of the auxiliary support column touches the ceiling. The container according to claim 1, wherein the container extends to a higher position than the end surface placed on the surface structure.
3. 3. The container according to claim 2, wherein a connecting mechanism for connecting the containers to each other is provided at the tip of the auxiliary support.
4. The gable surface overturning means includes a rotating shaft provided on a side of the floor structure, and an arm having one end pivotally supported by the rotating shaft and the other end fixed to the lower end of the support column,
   The container according to any one of claims 1 to 3, wherein the rotation axis is located inside the end surface by a predetermined distance along the longitudinal direction.
5. The gable overturning means includes a gable guide member provided on a side of the floor structure and having a guide groove extending in the vertical direction, one end of which is engaged with the guide groove, and the other end of which is engaged with the guide groove. The container according to any one of claims 1 to 3, further comprising a gable rotation shaft fixed to the lower end.
6. Any one of claims 1 to 3, characterized in that a side engaging portion that engages with an upper end or a lower end of the side surface is provided along a side edge of the top surface structure or the floor surface structure. The container described in paragraph 1.
7. A side accommodating portion capable of accommodating the side surface is provided on the lower side of the top surface structure, and the upper side of the side surface is pivotally supported by the side surface of the top surface structure, and the left and right side surfaces are overlapped to form the top surface. 2. A container according to claim 1, wherein the container is housed within a structure.
8. 2. The container according to claim 1, wherein the side surface is divided into an even number of upper and lower panels so that it can be folded inward, and the pair of side surfaces are folded in a state in which the left and right sides are parallel.
9. The container according to claim 1, wherein the support is provided with a locking mechanism that prevents the top structure from falling.

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