DE102018210954A1 - Load carriers for bulk goods - Google Patents

Abstract

The invention relates to a load carrier (1) for bulk material (2) which has respective side walls (5) for receiving the bulk material (2) and a base (6) which has a plurality of openings (7), below the base ( 6) a collecting container (8) with a collecting element (9) is arranged, by means of which particle contamination (4) of the bulk material (2) passing through the bottom (6) can be collected.

Description

The invention relates to a load carrier for bulk goods according to the preamble of patent claim 1.

Load carriers for transporting bulk material within production plants, for example in order to transport the bulk material to an assembly site at which motor vehicles are assembled, are already generally known and can be used, for example, in DE 10 2015 007 863 A1 be removed. A load carrier basically has a receiving space for receiving bulk goods, which is delimited by respective side walls and a floor.

Furthermore, lattice boxes are generally known as load carriers, in which the side walls and the bottom are formed by respective lattices, which are held together by a steel structure. Thus, the bottom of the mesh box has a plurality of openings provided by the mesh.

The object of the present invention is to provide a load carrier for bulk material, which enables the bulk material to be separated from particle contaminants.

This object is achieved according to the invention by a load carrier for bulk goods with the features of the independent patent claim.

The invention relates to a load carrier for bulk material, which has respective side walls for receiving the bulk material and a base, which in turn has a plurality of openings. In order to enable the bulk material to be separated from particle contaminants, in particular when the bulk material is being transported, it is provided according to the invention that a collecting container with a collecting element is arranged below the bottom, by means of which particle contaminants of the bulk material passing through the bottom can be collected. The bulk material can be, for example, motor vehicle components which are to be transported within a production facility for producing motor vehicles by means of the load carrier. The particle contaminants can be separated from the bulk material by means of the load carrier. In this case, the bulk material is picked up by means of the base which provides a receiving surface for the bulk material and which has at least the plurality of openings for separating the particle contaminants from the bulk material. In particular, the bulk material is received in a receiving space which is laterally delimited by the side walls and delimited downwards by the floor. The particle contaminants passing through the plurality of openings in the base are collected by means of the collecting element which provides a receiving surface for the particle contaminants. The bulk material can be transported by means of the load carrier while the bulk material is separated from the particle contaminants. The particle contaminants collected by means of the collecting element can be analyzed and, depending on the analysis, a cleanliness level of the bulk material can be determined. The load carrier can be set up to be moved within the production system in order to transport the bulk material or alternatively can be designed as a stationary bulk material supply system, for example a vibratory bowl feeder. The load carrier thus enables the particle contaminants to be separated from the bulk material in order to make the bulk material particularly clean for a production process.

In this context, it has proven to be advantageous if the collecting element is an adhesive strip. The adhesive strip can in particular have an adhesive to which the particle contaminants passing through the floor can stick to the collecting element in order to thereby fix the particle contaminants on the collecting element. As an alternative to fixing the particle contaminants to the collecting element by means of the adhesive, the particle contaminants can be held in place by means of electrostatic adhesive force by means of the collecting element, for example by statically charging the collecting element. A double-sided adhesive tape, for example, can be used as the adhesive strip, which has the advantage that it can be replaced regularly, for example to analyze particle contamination of the bulk material over time. Furthermore, an adhesive strip is particularly easy to attach to the collecting container and is particularly simple and quick to replace.

In a further advantageous embodiment of the invention it is provided that the base has a perforated grid and / or a grid. A hole pattern is to be understood in particular as a hole pattern with a large number of openings. In particular, the hole pattern has a regular hole pattern, in which the openings have a uniform diameter and are arranged at uniform intervals relative to one another. This can ensure that the particle contaminants are evenly separated from the entire bulk material.

In a further advantageous embodiment of the invention it is provided that the openings each have a smaller diameter than a smallest bulk material element of the bulk material. This can ensure that the Bulk material remains on the floor and the collecting element is or remains free of bulk material. In particular, a sieving effect can be achieved in this way, in that the bulk material is received on the bottom of the load carrier and only the particle contaminants pass through the majority of the openings in the bottom and are collected by means of the collecting element. As a result, the particle contaminants are sieved off from the bulk material by means of the plurality of openings in the bottom, so that the bulk material is freed from the particle contaminants. Alternatively or additionally, a respective contour of the openings can be designed in such a way that the respective bulk material elements of the bulk material cannot be moved through the openings, despite the regionally larger diameter of the openings compared to the bulk material elements. In this case, the respective openings are to be made particularly large at the same time, so that particularly many particle contaminants can be separated from the bulk material through the openings. In this way, a particularly clean separation of the bulk material from the particle contaminants can be achieved. A geometry of the openings can thus prevent the bulk material from passing through the openings and into the collecting container.

In a further advantageous embodiment of the invention it is provided that the bottom and the collecting element are arranged at a distance from one another. This can ensure that a particularly large number of particle contaminants can be absorbed by means of the collecting container and in particular by means of the collecting element. In particular, the spaced arrangement of the collecting element from the floor provides a particularly large collecting space within which particle contaminants separated from the bulk material can be received.

In a further advantageous embodiment of the invention it is provided that the bottom and the collecting element are arranged parallel to one another. The collecting element is arranged, in particular, on a side of the bottom facing away from the bulk material, the side of the bottom facing away from the bulk material extending parallel to a collecting surface of the collecting element that receives the particle contaminants. This makes it possible to determine in which area of the base a particularly large number of particle contaminants pass through the openings in the base, since a relative movement of the particle contaminants relative to the collecting element along an extension plane of the base can be at least substantially prevented. In particular, it can be ensured that particle contaminants passing through the openings in the floor cover an at least substantially the same distance until they arrive on the collecting surface of the collecting element and are thus collected by the collecting element. Advantageously, a local assignment of particle contaminants collected and fixed by means of the collecting element to respective areas of the bottom of the load carrier can thus take place, so that a local contamination of the bulk material can be analyzed.

Further features of the invention result from the claims, the figures and the description of the figures. The features and combinations of features mentioned above in the description and the features and combinations of features mentioned below in the description of the figures and / or shown alone in the figures can be used not only in the respectively specified combination but also in other combinations or on their own.

The invention will now be explained in more detail using a preferred exemplary embodiment and with reference to the drawing. The sole FIG. 1 shows a schematic perspective view of a load carrier for receiving and transporting bulk goods with a floor, which provides a receiving surface for the bulk goods, and with a collecting container with a collecting element, by means of which particle contaminants that have passed through openings in the floor are collected can.

In the single figure is a schematic perspective view of a charge carrier 1 shown from the inside. By means of the load carrier 1 is bulk material 2 , which has a plurality of bulk material elements 3 includes, transportable within a production facility. In the present case, the bulk goods are concerned 2 around nuts, which are to be transported for the assembly of a motor vehicle to an assembly site within the production plant.

When storing or transporting bulk goods 2 can component surfaces of individual bulk material elements 3 of the bulk goods 2 with particle contamination 4 be contaminated. Contamination with the particle contaminants 4 can in particular by direct contact on a packaging material and / or friction on the respective other bulk material elements 3 or other components and / or due to environmental pollution. An assembly worker grabs contaminated bulk goods 2 , the assembly employee's glove surfaces can remove the particle contamination 4 record so this particle contamination 4 from the assembly worker to a cleanliness-critical installation location, in particular, a cleanliness-critical area within the production plant can be carried over.

To avoid this carryover of particle contamination 4 In the cleanliness-critical installation location to avoid, it is provided that by means of the load carrier 1 particle contamination 4 of the bulk goods 2 of bulk goods 2 be separated. For this, the load carrier points 1 one through side walls 5 and a floor 6 formed receiving space for receiving the bulk material 2 on, being the bottom 6 a plurality of openings 7 having. The openings 7 have a smaller diameter than the bulk material elements 3 and especially a smallest bulk element 3 of the bulk goods 2 so that the bulk material elements 3 of the bulk goods 2 from the floor 6 are recorded and remain recorded without going through the openings 7 pass therethrough. The majority of the openings 7 is in this case across the floor 6 spread that floor 6 has a hole pattern with a predetermined regular hole pattern. As an alternative to the perforated grid, the bottom can 6 have a grid which is set up for the bulk material 2 record without the bulk material 2 through mesh openings of the mesh.

Through the openings 7 of the floor 6 can the particle contamination 4 of the bulk goods 2 get through so that by means of the openings 7 the particle contaminants 4 of the bulk material 2 can be separated. The floor 6 thus serves as a sieve to remove the particle contaminants 4 of bulk goods 2 sieve off.

As can be seen in the single figure, the charge carrier points 1 below the floor 6 and thus on the bulk material 2 opposite side of the floor 6 a receptacle 8th on which the bulk material 2 separated particle contaminants 4 are recordable. To the particle contamination 4 relative to the collecting container 8th to fix after collecting them, has the collecting container 8th a collecting element 9 on, by means of which through the floor 6 particle contamination 4 of the bulk goods 2 are catchable. With the collecting element 9 In the present case, it is a double-sided adhesive tape, which has one of its adhesive sides on a container bottom 10 of the collecting container 8th is stuck. At the bottom of the container 10 the collecting element catches away from, also adhesive side 9 the particle contaminants 4 on which through the floor 6 got through. By means of the collecting element 9 are the particle contaminants 4 relative to the collecting container 8th fixable to ensure that the particle contamination 4 which are in the receptacle 8th are included, the bulk material 2 after their separation from the bulk material 2 do not contaminate again. Based on a respective arrangement of the means of the collecting element 9 captured and fixed particle contaminants 4 can a respective local contamination and possibly a cause of contamination of the bulk material 2 to be analyzed.

As can be seen in the single figure, the collecting container bottom is present 10 parallel to the floor 6 arranged so that on the bottom of the receptacle 10 arranged collecting element 9 also parallel to the floor 6 is aligned. This can ensure that a particular path of particle contamination to be covered 4 through the openings 7 through from the floor 6 to the collecting element 9 over an extension area of the floor 6 is always the same length. Using an impurity pattern of particle contaminants 4 on the collecting element 9 can cause local contamination of the bulk material 2 can be determined particularly well in the recording room. In addition, the collecting element is present 9 and the floor 6 spaced apart from each other. This can prevent the particle contamination 4 in the openings 7 dammed up, and it can be ensured that the particle contamination 4 which of the bulk material 2 have been completely separated through the openings 7 get through and in the receptacle 8th be included. Thus, from the collecting container 8th especially many particle contaminants 4 be included.

The particle contaminants 4 sediment due to their size and acting forces on the ground 6 of the load carrier 1 , Through the openings 7 , which are holes in the present case, on the ground 6 of the load carrier 1 can the particle contamination 4 be removed. A respective diameter of the bores is smaller than the smallest component dimension of the bulk material 2 and therefore smaller than the smallest bulk element 3 , Using the double-sided adhesive tape in the collecting container 8th can the particle contamination 4 be taken safely. The captured particle contaminants 4 can be analyzed to determine the cleanliness level of the bulk material 2 in particular to measure "inline", which is an investigation in the ongoing process. This can ensure a cleanliness level of the bulk material 2 can be controlled particularly advantageously and a particle carryover of particle contaminants 4 preventively in a cleanliness critical area of the production plant. The load carrier 1 can be used in particular as a mobile means of transport for transporting bulk goods 2 or as a feed system for small parts to production facilities, especially for vibratory bowl feeders.

LIST OF REFERENCE NUMBERS

1

charge carrier

2

bulk

3

bulk element

4

particle pollution

5

Side wall

6

ground

7

opening

8th

collecting container

9

collecting element

10

Collecting container base

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102015007863 A1 [0002]

Claims (6)

Load carrier (1) for bulk material (2) which has respective side walls (5) for receiving the bulk material (2) and a base (6) which has a plurality of openings (7), characterized in that below the base (6 ) a collecting container (8) with a collecting element (9) is arranged, by means of which particle contaminants (4) of the bulk material (2) passing through the bottom (6) can be collected. Load carriers (1) after Claim 1 , characterized in that the collecting element (9) is an adhesive strip. Load carriers (1) after Claim 1 or 2 , characterized in that the bottom (6) has a perforated grid and / or a grid. Load carrier (1) according to one of the preceding claims, characterized in that the openings (7) each have a smaller diameter than a smallest bulk material element (3) of the bulk material (2). Load carrier (1) according to one of the preceding claims, characterized in that the bottom (6) and the collecting element (9) are arranged at a distance from one another. Load carrier (1) according to one of the preceding claims, characterized in that the bottom (6) and the collecting element (9) are arranged parallel to one another.

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