Certain embodiments of the present invention relate, for example, to transport and devices for transport and storage.
Embodiments of the present invention include a collapsible shipping container suitable for automatic disassembly and assembly. The collapsible shipping contain has a structure that when upright can be disassembled turning it into a flat structure with overlapping walls, and that can be easily reassembled, thanks to a connection system and forced wedging locks.
Embodiments of the present invention include a method of disassembly and assembly in which a stage sequence easily enables disassembly and assembly of a container provided with the above mentioned connection system and locks.
Imbalances in world trade—in particular, among countries that are mainly exporters, and those countries that are mainly importers—cause inefficiencies in shipping. For example, containers that are originally loaded when transported to a country often come back empty.
Empty containers occupy space within the means for transport, and thus shipping these empty containers incurs high costs.
Conventional load containers have a fixed structure that cannot be disassembled temporarily. To address the inconvenience of shipping empty containers, containers are designed with structures that are detachable and/or foldable.
Such is the case of the container disclosed by the patent document AR 065037 A1, by the same inventor of the present invention.
Other containers include those disclosed by the patent documents U.S. Pat. No. 3,765,556 and U.S. Pat. No. 5,190,179, whose foldable structure is mainly based on some longitudinally foldable side walls. This type of structure has a large manufacturing cost, and, in addition, they are complex and prone to failure and hindrances that prevent their adequate folding or deployment.
Patent documents JP 1,153,480 and JP 63,203,580 show the use of wedges to connect mainly the side walls and the base. In addition, patent document JP 63,307,087 discloses the use of wedges that also connect the side walls with the top wall. Wedges are also used at the container corners.
On the other hand, patent document U.S. Pat. No. 3,327,882 discloses a plastic container with lengthened wedges which are fixed on the lid or top wall, which work associated to an inner protruding portion of said lid, and that fit into some slots formed on the side walls. The same system is used to connect the side walls with the base.
U.S. Pat. No. 4,069,938 discloses a system based on a top wall with an inner closure wall that have some wedge-shaped members, but which act as guides.
Embodiments of the present invention include a collapsible container (either by disassembly or folding) that may be easily disassembled, shipped and assembled again at the place of destination.
Embodiments of the present invention also include a container that may be disassembled easily, with low cost and safety, avoiding accidents, and/or preventing the different components of its structure from suffering blows or deterioration.
Embodiments of the present invention also include a container able to be disassembled or assembled using an automatic machine or device, without direct intervention of human operators. In some embodiments, the container is such that an appropriate automatic device, with a sequence of simple and quick operations, may disassemble the container and arrange the container conveniently folded and reduced to its minimum volume.
In certain embodiments, the characteristics of the side walls, base and top wall enable the structure to remain orderly disassembled, so that the assembly process may also be carried out sequentially, automatically, quickly and simply. In this regard, in an embodiment, the longitudinal locks should not be removed during the disassembly and kept until the time of assembly, as they remain connected to the top wall, and consequently, into the disassembled container.
An advantage of certain embodiments of the present invention is that the container can do without axes, bushings and similar rotary devices. This provides the following benefits:
Definitively, axes and bushes are overlooked, not only in the connection between the top wall and the side walls, but also between the side walls and the base, which substantially reduces the chance of failure.
Another advantage of certain embodiments is that the presence of the longitudinal locks enables a reduction in the amount of connections between the top wall and the side walls. These longitudinal locks may, for example, have different sizes, with the possibility to use only a few or even only one lock per each longitudinal edge. The smaller quantity of locks avoids rotary systems or with numerous locks, or small connections.
A larger amount of locks or connections increases the chance that a failure will prevent the top wall from being disassembled, or that the top wall does not close perfectly when assembled. In addition, a large amount of locks increases complexity, cost and the probability of failure.
Therefore, a further advantage of certain embodiments of the present container is the presence of a system of longitudinal locks, which are simply pushed, either for their wedging or removal.
Another advantage of certain embodiments is the provision of the possibility to use side locks that may be removed using magnetic devices (either electromagnets or permanent magnet). Thus, it is possible to manage without systems with rotary pieces or with removal locks that require a running gear, rotation and reverse blocking, to remove the locks. In this manner, failures originating from the presence of slurries, oxides and other elements that, during maritime and terrestrial shipping of the containers, cause obstructions in any opening or exposed cavity can be avoided. Additionally, a reduction of requirements for an automatic assembly and disassembly machine or device can be realized.
A further advantage of certain embodiments is the possibility of using in the different wedging pieces, a system of elastic positional locks which supplement the other systems. In this manner, a system of corner wedges with rotary system and lock is not required. This system also prevents failure and reduces the requirements for an automatic assembly and disassembly machine or device.
Drawing A is a cross section which shows the cuneiform member positioned and with the wedge removed in the opening of the forced wedging; and
Drawing B is another cross section where the cuneiform member is shown, already wedged in the connection and lock position.
Drawing A is a longitudinal section of a longitudinal edge of the top wall, into which the insertion pieces may be observed;
Drawing B is another longitudinal section of the longitudinal edge of the top wall, into which the insertion pieces and a wedged cuneiform member may be observed; and
Drawing C is an upper and top view, of the longitudinal edge of the top wall with the wedged cuneiform member.
Drawing A is an upper, top view of a simple insertion piece;
Drawing B is an upper, top view of a double insertion piece; and
Drawing C is a cross section of the insertion pieces.
Drawing A is a longitudinal cross section of a longitudinal edge of the top wall into which a set of insertion pieces may be observed;
Drawing B is a longitudinal section of a longitudinal edge of the top wall into which two one-piece insertion pieces may be observed; and
Drawing C is a longitudinal section of a longitudinal edge of the top wall into which an insertion piece with more than one forced wedging passage may be observed.
Drawing A is an upper, top view of a longitudinal edge of the top wall with several longitudinal locks;
Drawing B is an upper, top view of a longitudinal edge of the top wall with two longitudinal locks; and
Drawing C is an upper, top view of a longitudinal edge of the top wall, with only one longitudinal lock which extends throughout the edge.
Drawing 9 is a perspective view of the present container entirely mounted with its upright structure and indicating the removal of the side locks.
Drawing A is a perspective view of an upper lock that connects the top wall to a side wall;
Drawing B is a front elevated view, of the lock of drawing A;
Drawing C is a side elevated view, of the lock of drawing A;
Drawing D is a back, elevated view, of the lock of drawing A; and
Drawing E is a cross section of the lock of drawing A, where the elastic lock may be observed.
Drawing A, a perspective view of an upper lock which connects the top wall with a side wall, in an embodiment with side fixing opening;
Drawing B is a front, elevated view of the lock of drawing A;
Drawing C is a side, elevated view of the lock of drawing A;
Drawing D is a back, elevated view of the lock of drawing A; and
Drawing E is a cross section view of the lock of drawing A, where the detail of the fixing opening may be observed.
Drawing A is a side, elevated view, which shows the articulation between a major side wall and the base wall; the latter standing upright;
Drawing B is a side, elevated view, which shows the articulation between a major side wall and the base wall; the latter being disassembled or folded; and
Drawing C is a perspective view of a detail of the articulation.
Drawing A is a detail in front, elevated view, where the misaligned lock members may be seen, and opposite to their respective inlets, provided by the head walls, and
Drawing B is a detail in front, elevated view, where it may be observed how the misalignment between the locking members enables that they remain by each other, and ready for the placement of a forced wedging lock.
In the different figures, the same numbers and/or reference letters indicate equal or corresponding parts.
Embodiments of the present invention include a collapsible shipping container whose structure, which is usually upright, may be disassembled by the release of a system of locks which comprises: upper longitudinal locks (7) of forced wedging, which connect the adjacent edges (40)(20) of the top (4) and side walls (2)(3); and forced wedging side cuneiform locks (6) that connect the minor or head side walls (3) with the top walls (4) and major side walls (2). Embodiments of the present invention also include a method in which said locks are removed (6)(7), the top wall is removed (4), its head walls are disassembled (3), the major side walls are lowered (2) and all these walls are overlapped (2)(3)(4) on the base wall (1) until forming a flat structure. This flat structure may be assembled again in the inverse manner, until the structure stands upright and the container again shapes the load housing.
In embodiments of the present invention, the container comprises an upright structure that, either collapsible or foldable, may be disassembled until turning it into a flat structure and vice versa. This capability of assembly and disassembly is due to the particular constitution and relation among the walls (1) (2) (3) (4).
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The base wall (1) may show different building variations, including the arrangement of floors on the base wall (1). In the embodiment shown in
The side walls (2) comprise a first (2a) and a second (2b) side wall. The first side wall (2a) connects to the base wall (1) using an articulation bend (22), which allows the first side wall (2a) to be lowered or placed upright relative to the base wall (1). In addition, the second side wall (2b) also connects to the base wall (1) using a corresponding articulation bend (22), although in this case, the second side wall (2b) has a lowering compensator (26) which elevates the second side wall (2b) over the first side wall (2a).
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The side positional elastic locks (64) comprise, for example, projecting members—for instance balls—that, under the influence of elastic means, project themselves out of their splits and fit into positional recesses provided by the forced wedging walls to which they are applied (51a)(52a).
In an embodiment, the forced wedging side locks (6) comprise a material susceptible to magnetic induction, allowing them to be removed using magnetic devices, based on electromagnets, as well as on permanent magnets.
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These upper longitudinal locks (7) comprise cuneiform, lengthened members (70)—in the longitudinal sense of said walls (40) (20)—which fit into forced wedging passages (77) defined by insertion pieces (75) (76).
The cuneiform members (70) form an upper wall (71), from which side wedging walls (72) extend, until ending in a wedge-removing end (73).
In an embodiment, the forced wedging passages (77) start in an existing wedging opening (41) in the profiles that form the longitudinal edges (40) of the top wall (4). The upper insertion pieces (75) are placed into the longitudinal edge (40) so as to form the first portion of the wedging passages (77).
The second portion of the wedging passages (77) is formed by the lower insertion pieces (76), which are placed into the profiles that form the upper longitudinal edges (20) of the side walls (2). The wedging passages (77) have wedging openings (20a) existing in the lower wall (20b) of the longitudinal edges (20).
In an embodiment, the insertion pieces (75) (76) may be one-piece or may form a set. In the case of the one-piece insertion piece (75) (76), a single piece may define a single forced wedging passage (77). Furthermore, in an embodiment a single insertion piece (75) (76) provided with one or more forced wedging passages (77) may be used for the adjacent edges (20) (40).
In another embodiment, there may be one or more of the wedge-removing openings (20a) per each wedging passage (77). This is due to the fact that the forced wedging passage (77) may be longer than the wave passage (110) of the plate that forms the side walls (2) (3) (See, e.g.,
In an embodiment, on one of the wedging walls (72) of the cuneiform member (70), there is a guide stop (72a) in which a retention lock (42) fits. The guide stop (72a) is situated in the edge of the opening or the wedging access (41). This arrangement keeps the cuneiform member (70) in the wedging passage (77), either if the cuneiform member (70) is wedged or wedge-removed, because the cuneiform member (70) is retained, enabling its wedging and wedging-removal travel or run in the insertion pieces (75)(76).
In an embodiment, the longitudinal locks comprise upper elastic positional locks (74). The upper elastic positional locks (74) fit into positional recessing guides (78) provided in the walls of the insertion pieces (75)(76) within the wedging passage (77). The upper elastic positional locks (74) aid in ensuring the forced wedging of the cuneiform member (70).
In an embodiment, when taking into account the functions of the system of upper longitudinal locks (7), the forced wedging passage (77) will have an inclination that is such that the wedge-removing openings (20a) remain outside or in the outer part of the side walls(2).
In an embodiment, upper longitudinal waterproof insulators (101) are arranged between the upper longitudinal edges (40) (20) in a location that is between the upper longitudinal locks (7) and the container housing. The longitudinal waterproof insulators (101) may create a seal and ensure the tightness of the upper part of the container.
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The distribution of these hanging supports (46) along the top wall (4) enables to avoid its deformation during the maneuvers.
In case the top wall (4) is mainly structured in profiled plates, advantage is taken from this condition, by fixing the hanging support (46) in a bridge like manner, between two adjacent projecting profiles (43) (See
With the container assembled and in an upright state, the removal of the upper longitudinal locks (7) [that connect the top wall (4) with the side walls (2) (3)] and the removal of the side locks (6) [which connect the top wall (4) with the columns (30) (31) of the minor side or head walls (3)] enables the top wall (4) to be lifted off the container by, for example, an appropriate device. For this operation, the hanging supports (46) are available, as well as the structural corners (5) that provide some upper openings (50) suitable for this purpose.
In an embodiment, the removal of the forced wedging upper longitudinal locks (7) that connect the adjacent longitudinal edges (40) (20), is made through the wedge-removing openings (21), which enables to disconnect the top wall (4) from the side walls (2) (3).
Further, in an embodiment, the removal of the forced wedging side locks (6) that connect the lower part of the columns (30) (31) with the lower lock members (51) of the base wall (1), leaves the head walls (3) in condition to be detached from the side walls (2).
For this, the side connections (8) must be disconnected. In the present embodiment, as they are guide locks, disconnection is achieved by raising the above mentioned head walls (3) and moving them far from the base wall (1) (See
With the structure in these conditions, the first side wall (2a) may be lowered until it overlaps the base wall (1). This is possible because the articulation bend (22) of the first side wall (2a) turns within the articulation profile (23) (See
Similarly, the second side wall (2b) may be lowered until it overlaps the side wall (2a). The presence of the lowering compensator (26) allows both side walls (2a) (2b) to overlap in a parallel manner (See
Over the above mentioned lowered second side wall (2b), the head walls are placed (3). The free edges of the columns (30) (31) fit into the space formed between the articulations and the longitudinal edges (21) of the base wall (1) (See
In an embodiment the columns (30) on one side are narrower than the columns (31) on the other side. This difference in width compensates for the presence of the lowering compensator (22) and therefore, the head walls (3) may overlap and remain parallel to the side walls (2).
To avoid the undesired movement of the head walls (3), they remain immobile between the lower lock members (51) and some travel stops (53) situated on the longitudinal edges of the base wall (1) (See
Finally, the top wall overlaps (4). As the lower lock members (52) are misaligned with respect to the lower lock members (51), the lower lock members (52) (51) are arranged one by the other with their corresponding aligned lock passages (51a) (52a) (See
For the assembly, the inverse process is carried out, removing the forced wedging locks (6), raising the top wall (4), removing and standing up the head walls (3), lifting the side walls (2), locking with the head walls (3) and placing the top wall (4) with the corresponding side locks (6) and upper forced wedging locks (7).
Embodiments of the present invention also include methods of disassembly and assembly of present container which comprise a series of stages, in which, for the disassembly, the top wall (4) and the head walls (3) are disassembled, the side walls are lowered (2) on the base wall (1) and the top wall is overlapped (4), forming a flat structure. For the assembly, the top wall (4) is removed, the side walls (2) are raised, the head walls are mounted (3) and the top wall structure (4) is mounted, thus assembling the container.
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In an embodiment, accessory devices or structures mounted on the head walls (3) [for example, freezing equipment, ancillary equipment, etc.] are removed and separately stored so that they do not form part of the flat structure.
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In an embodiment of the present invention, for container assembly, first, the locks (6) are released and the means (51) (52) that connect the top wall (4) with the base wall (1) are disconnected.
Then, the top wall (4) is lifted up to a height above the side walls (2) and head walls (3).
After that, the head walls (3) are removed—or, if they had been stored separately, they are brought in—and then, the side walls (2) are raised until they stay upright. Then, the head walls (3) are raised until they also stay upright. Side connections (8) are connected to the side walls (2), and, the lower inlets (32) and lower lock members (51) are used to connect to the base wall (1).
Finally, the top wall (4) is mounted and all the locks and/or the necessary means (6) (7) (8) are placed to keep the structure upright and assembled.
Undoubtedly, upon putting the present invention into practice, modifications may be introduced regarding certain construction details and form, without leaving the essential principles that are clearly explained in the claims below:
Number | Date | Country | Kind |
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20120104995 | Dec 2012 | AR | national |