The present invention relates to a box or container. More particularly this invention concerns a plastic storage/transport container.
A typical storage and transport container made of plastic normally is of parallepipedal shape with a square or rectangular footprint. Two side walls project parallel to each other from opposite side edges of the floor and two end walls, which normally are shorter than the side walls, project upward from opposite end edges of the floor and are connected at vertical corners to the side walls. The upper edges of the side and end walls define an opening and are intended to fit with the lower edges of a similar box stacked on it to form a stable stack.
In order to achieve the goal of a high degree of container stiffness during favorable production by extrusion, and the capability of being transported via various, known transport systems, many container designs have been created. The standard box unit described above is often used for storage and transport of the most diverse products such as, for example, in the automobile industry for holding parts carriers, deep-draw parts or the like. Flexible containment is achieved for products of different dimensions by providing grid spacers inside the container.
Frequently, large and heavy products require correspondingly dimensioned containers that can have basic dimensions of, for example, 600×500 mm even up to 1000×600 mm. Because the containers must be able to be moved on automatic conveyor belts or on rollers and reels tracks, and the products must be handled by robots, especially in the case of large containers with heavy loads, stability is extremely problematic. In containers known in practice that are designed with a structure of intersecting vertical and horizontal ribs on the outer faces of their walls, and in which a flat upper edge is supported by vertical ribs, it has been shown that when bearing a load, damage to the container is unavoidable.
Due to the upper edge structure, an automatic grab, such as a lifting tools or other special gripper system that acts from the top or from the side, have only a small surface to catch by hook or to grip. This is made even more difficult in that the containers deform starting at the upper edge and/or can even tear, or are distorted inward at the container walls due to their low resistance to bending. Optimal removal of the contents located close to the walls by an automatic gripper or robot is thus extraordinarily difficult, as the gripper/robot would hit the inwardly bent container wall. In addition to making product handling more difficult, the grab itself could be damaged.
If the grab cannot grip the products as intended, failures occur in the automatic systems, as a result of which production is delayed and overall productivity decreased. Although the stability of the container could be improved by using a larger thickness of the material, this, however would not only be associated with additional material and higher production costs, but would also lead to a higher total weight of the container.
It is therefore an object of the present invention to provide an improved plastic storage and transport container.
Another object is the provision of such an improved plastic storage and transport container that overcomes the above-given disadvantages, in particular that offers in particular, in spite of economical production, a high degree of stability that is also sufficient for transporting and handling heavy products, as well as overall improved features.
In a transport/shipping box having a polygonal floor with a plurality of straight edges, respective flat walls extending upward from the edges and joined together at corners to form an upwardly directed opening, this object is attained in that the walls have upper edges that are of upwardly open U-section.
Due to this shape or profile of the upper edge, it and thus the entire container has significantly more stability and stiffness, so that deformation of the upper edge because of the forces due to the load that are acting in particular during the condition of being carried, can be avoided. Automatic handling is thus not impaired, because grabs, crane gear or the like can grip the container and the product without interference.
According to an advantageous embodiment of the invention the upper edge defined by the container walls projects outward on one side, so that end sections of the container walls simultaneously form an inner flange of the upper edge. The upper edges of the container walls thus simultaneously also form a part of the upper edge. In contrast, the outer flange of the upper edge extends, according to the invention, parallel to the outer faces of the container walls.
The upper edge that is according to the invention upwardly makes it advantageously possible that water drainage holes can be formed in the floor web of the upper edge, as well as lift holes. The outwardly opening water drainage prevents rain water and dirt from accumulating.
The stability and stiffness of the container can be increased in that the upper edge is divided into compartments or chambers by wall/rib elements extending across the upper edge's full width.
According to a preferred embodiment of the invention, reinforcement strips can be fitted into the upwardly open U-section upper edge, siting flatly on them and secured therein by catch formations. Alternative to this, reinforcement strips can also be designed in accordance with the invention in such a way that after insertion and snapping into the upper edge, sit atop it and cover its entire width. The reinforcement strips, advantageously likewise plastic profiles that are snapped into the upper edge in a simple way with the help of snap tools, lead to an additional increase in the stability of the upper edge or the container. They can be distributed over the entire upper frame, but also precisely targeted by bridging a corner, i.e. starting at a certain position on the facing side over the corner up to a certain position of the adjacent side wall. In this case, the corner sections of the upper edge, which always must withstand very large forces, would be preferentially reinforced, which significantly improves the lateral warp stiffness.
Further, in accordance with the invention, the reinforcement strips can preferably be designed as color-identification means, whereby according to an advantageous embodiment of the invention, at least one snap means of the reinforcement strip engages in a throughgoing catch hole opening to the outside or a through hole of the upper edge. As the marker/reinforcement strips can be provided in different colors, the contents can be immediately defined by means of this color assignment. Thus, each type of content is associated with a certain color that is stored in an identification system. This does not preclude that the container can also be set up to carry a combination of different colors for different types of contents. The marker strips with color identification can be removed if needed, and exchanged if the contents change.
This is not possible with a known color identification system in which plastic containers are provided with color identification on a certain part of the container by means of being hot-stamped, as hot-stamping cannot be removed. Even identification by labels is disadvantageous, as the containers in the stack must necessarily be stacked on top of each other in such a way that the label is always visible and recognizable. In contrast, the through hole of the catch opening for the marker strip that is to be inserted into the upper edge in accordance with the invention offers recognizability that is always visible from the outside, in particular also in the case of containers that are stacked on top of each other. The catch openings or through holes can be provided at any position and in any number. If such marker strips that close the upper edge are not snapped in, rain water can naturally also drain through these through holes in the lower section of the U-profile of the upper edge.
A further preferred embodiment of the invention provides that the stacking edge is designed as a flared inverted-U-section downwardly open profile, whereby its outer flange reaches over the outer flange of upper edge of the lower container while containers are being stacked on top of each other. The stacking edge that is advantageously U-shaped, just like the upper edge, can be provided in alignment with the upper edge at the outer sides of the container walls. Thus the stacking edge of an upper container can be completely put over the upper edge of a lower container. Thus, water is neither able to seep into the lower container, even if no marker/reinforcement strip has been snapped into the upper edge, nor flow into the upwardly open upper edge. Due to the open profiles extending parallel on the top and bottom in opposite directions of upper edge and stacking edge, the container is imparted with such stability and stiffness that additional horizontally extending ribs, which are customary in known containers and which can, for example, get caught in the materials handling devices preventing uniform further transport, can be eliminated.
Finally, it is possible that when stacking containers on top of each other, for example, on a pallet for transport, a protective cover only needs to be placed on the uppermost container of each stacks. Each individual container does not need to be closed with a cover, which can thus, just like subsequent measures, for example, cleaning of the covers, but also storage space and working time can be saved, as the stacked containers are not required to first be individually, manually unstacked for removing the covers and the covers are not required to be placed at a different location for intermediate storage. The containers must then perhaps be stacked onto the pallet again for further transport, in order to, for example, bring them to the robot unloading station. In contrast, during the stacking process of containers on top of each other in accordance with the invention, only the upper protective cover must be removed, after which the pallet with the container stack can immediately be brought to the commissioning station or to the robot removal station. This results in a correspondingly higher availability and lower facility downtime.
The above and other objects, features, and advantages will become more readily apparent from the following description, reference being made to the accompanying drawing in which:
As seen in
As can be seen more clearly in
The upper edge 5 is subdivided by transverse and vertical stiffening ribs or webs 9 into a multiplicity of short upwardly open pockets or chambers 10 so that this upper edge 5 is very stiff, and as shown in
When two containers 1 are stacked on top of each other, the lower edge 6 of upper container 1b fits around the upper edge 5 of the lower container 1a. The outer flange 6c of the stacking edge 6 somewhat overlaps the outer flange 5c of the upper edge 5 as shown in
A further embodiment of a marker/reinforcement strip 19 is shown in
The marker/reinforcement strips 15a, 15b and 19 are in colors that contrast that of the boxes 1 and that can be of various different colors to allow immediate identification of the container contents from the outside. Since the
Number | Date | Country | Kind |
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102009053353.2 | Nov 2009 | DE | national |