The invention relates to a container for flat objects in a vertical position. These objects can be, for example, flat items of mail of different formats. Modern letter sorting systems reach peak throughputs of up to 45,000 items of mail per hour. As a rule, emptying is carried out manually, that is to say the sorted stacks of items of mail are transferred by hand from the sorter into mail containers. In the process, the items of mail have to be put into the mail containers from above. The mail containers themselves are then either stacked manually onto carts or transferred to tray management systems. This manual process is associated with a high error rate on the part of the operator, high physical stress on the operator and low throughputs.
During the supply of the items of mail into the sorters, there is likewise generally a manual transfer from containers to the separating apparatus of the sorter.
During this unloading process, the items of mail are lifted out of the container, shaken out or the container is tipped upside down and lifted off the items of mail (DE 195 45 716 C1). In particular in the case of items of mail with different formats or items of mail with large formats, this procedure is complicated or even not possible at all without the alignment of the items of mail on two edges being lost.
In EP 0 109 325, FR 2 621 297, mail containers needed for this purpose are described. These consist of plastic (PP) and have various reinforcements in order to achieve the necessary dimensional stability. These containers are configured in such a way that, if they are aligned mutually with one another and aligned so as to be rotated through 180° about the vertical axis in relation to one another, they can be stacked in one another.
An appropriate container for flat objects, such as letters, in a vertical position has also been described in DE 94 17 521 U1.
Also known is a container having an end wall which is designed as a roller shutter which can be displaced downward into an intermediate space in the bottom (DE 92 11 U1). This roller shutter solution is relatively heavy and needs a great deal of space.
The invention is therefore based on the object of providing a container for flat objects in a vertical position, having at least one end wall which can be displaced downward into an intermediate space in the bottom and which, as compared with the prior art, is designed to be lightweight and space-saving.
The material web consists of a flexible thin material web which, at its ends running perpendicular to the longitudinal walls, is spread out between two rods.
The lower rod is guided in the interspace in the bottom and can be moved, and the upper rod can be displaced between the bottom and upper edge along the front boundary of the longitudinal walls. Here, at their lateral ends on each longitudinal side of the container, the rods are guided jointly in a retaining mechanism which is fixed to the long walls such that it can be pivoted and holds the material web. The retaining mechanism comprises three rotating levers, to whose ends oriented toward the end of the container the upper rod is fixed. They are mounted approximately in the center of their longitudinal direction such that they can be rotated on the lateral longitudinal walls, the two axes of rotation being aligned and perpendicular to the longitudinal walls. The lower rod is connected to the other ends of the levers via floppy elongated pulling elements, which are deflected on the bottom, so that the material web/s remain/s spread out over its/their length in any pivoted position. This solution is lightweight, space-saving and uncomplicated.
It is advantageous if the pulling elements are elastic and under prestress.
As a result, tolerances which occur can be compensated for, so that the material web can be kept continually taut.
In order to limit the pivoting movement of the retaining mechanisms, the lateral longitudinal walls advantageously have stops.
The lateral longitudinal walls preferably have recesses on the outside, in which the levers are arranged to be countersunk such that they can be rotated and which can be closed by external coverings. This avoids the retaining mechanism being hampered during its movement. In order to relieve the material webs of tensile stresses, it is advantageous to fix flexible tensile straps of the same length as the material webs between the two rods.
It is also advantageous if the material web/s has/have a handle cutout on the upper rod. As a result, the upper rod can be used as a carrying handle.
In a further advantageous refinement, a plurality of thin flexible material webs are fixed to the two rods at a distance from one another. In the region of the gaps, at the end between the material webs, the bottom has lugs which dip into the slots between the material webs and in this way prevent objects being drawn in between the material web and bottom when the container is opened.
The invention will now be explained in more detail in an exemplary embodiment and by using the drawing, in which:
The container has two lateral longitudinal walls 10 and two end walls. The end walls can be opened and closed independently of each other. Opening is carried out by means of simply pressing the end wall downward and closing by means of simply pulling the end wall upward. An end wall comprises three broad, parallel, flexible thin material webs 1 which, at their end running perpendicularly with respect to the longitudinal walls 10, are spread out between two rods 2, 3. The upper rod 2 is formed as a handle bar. In the center of the handle bar, the central material web has a corresponding handle cutout (12). The lower rod 3 is located in an interspace in the bottom. The handle bar is fixed at the lateral ends to two parallel levers 4, which are mounted such that they can rotate on coaxial axes 5 perpendicular to the lateral longitudinal walls 10. The levers 4 are designed so as to be countersunk in recesses (11) whose boundaries form stop surfaces 7 for the levers 4, the position of the stop surfaces 7 being chosen such that, in the upper position, the handle bar is located slightly below the upper edge of the lateral longitudinal walls 10 and, in the lower position, is located underneath the supporting surface of the bottom. Here, the stops are located symmetrically with respect to a horizontal plane through the axis of rotation 5. In addition, the stop surfaces 7, the diameter of the handle bar and the thickness of the bottom are designed such that the handle bar is located in the region underneath the inner surface of the container bottom and above the outer surface of the container bottom when the end of the container is opened.
At the ends, the longitudinal walls 10 have extensions which are shaped like circular arcs, project beyond the bottom and prevent objects slipping through the gap between longitudinal wall 10 and material web 1. In the recesses in each lateral longitudinal wall 10, between the other end of the levers 4 and the lower rod 3, in each case an elastic pulling element 6 is fixed in the bottom. It is in each case deflected at two rounded edges in the longitudinal wall 10 and is under slight prestress, by which means the end wall is spread out.
As viewed in the direction of the axis of rotation 5, the levers 4 form with the material webs 1 spread out between the handle bar/upper rod 2 and the lower rod 3 and the pulling elements 6 a “self-contained unit” with an approximately constant arc length which, as the container is opened and closed, is subjected to only slight fluctuations, which are compensated for by the elastic pulling elements 6. The material webs 1 by means of which the ends of the container are closed are pulled into the interspace in the bottom by the pulling elements 6 at the lower rod 3 as the container is opened. As the container is opened, the material webs 1 are pulled out of the interspace in the bottom by the handle bar and pulled upward again. In order that, when the container is opened, no flat objects are pulled into the gap between the material webs 1 and the bottom, there are spaces between the parallel material webs 1. In these regions, the bottom is lengthened by projecting lugs 8, which dip into the spaces between the material webs 1 and thus prevent objects being pulled in between material webs 1 and container bottom as the container is opened.
As a result of the prestress of the pulling elements 6, the friction between the moving elements and the container rises, which means that the force for opening and closing and the actual locking force of the entire closing mechanism is increased in the opened and closed position and in possible intermediate positions.
If the inherent locking force of the closing mechanism resulting from friction is not sufficient since, for example, forces act on the handle bar as a result of a tilting stack of flat objects, it is advantageous to provide an additional locking means. This can be designed, for example, in the form of spring-loaded ball catches which, in the closed position, latch into one or both levers 2, 3.
Number | Date | Country | Kind |
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102 31 305.9 | Oct 2002 | DE | national |
The present application is a continuation of international application PCT/DE2003/002164, filed 30 Jun. 2003, which designated the United States, and further claims priority to German patent application 10231305.9, filed 10 Jul. 2002, the both of which are herein incorporated by reference.
Number | Date | Country | |
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Parent | PCT/DE03/02164 | Jun 2003 | US |
Child | 11024695 | Dec 2004 | US |