TRANSPORT CONTAINER HAVING OFFSET SIDEWALL SLOTS

Abstract

A transport container for receiving and transporting goods within a transport or distribution system by conveyor belts and/or roller conveyors. The transport container includes a base from which four sidewalls extend. At least two opposing sidewalls each have a predefined code section to apply a machine-readable code, in particular a barcode or a QR code, and at least one opening, in particular a plurality of slots extending from the base to the upper edge of the sidewall. The openings in the two opposing sidewalls, in particular those openings which are located directly adjacent to and/or at the same height as the predefined code sections, are arranged offset from one another. A system can include the transport container, a conveyor system, and a scanning device.

Description

FIELD

The present invention relates to a transport container, in particular to a container with offset sidewall slots. Furthermore, the invention relates to a system comprising a conveyor system and a scanning device in which such containers can be transported.

BACKGROUND

In mail distribution centers, delivery service companies, mail order companies or in other goods handling or logistics centers, goods or merchandise are usually transported by means of transport and distribution systems. The goods and merchandise are transported, inter alia, in transport containers. It may be necessary to measure the fill level of such a transport container, for example via an ultrasonic distance measuring device or via an optical identifier, e.g. via a laser device. When using laser devices, correct measurements can be made at high conveying speeds in the transport and distribution system. Furthermore, a laser can simultaneously read barcodes or QR codes applied to the transport container, which contain, for example, further information about the transported goods.

A method and a device for determining the mass flow rate of materials to be conveyed for bulk materials transported on conveyor belts or belt conveyors is already known from DE 34 11 540 A1. In this process, a laser radiates from above onto the transported goods and is reflected. Depending on how much bulk material is on the conveyor belt at the time of measurement, the laser is reflected differently and the reflected signal thus contains information from which the filling cross-section of the transported material can be determined.

Therefore, a device for determining the quantity of conveyed bulk material, which rests directly on a conveyor belt, is known. However, it may be necessary to convey transported goods/loads, such as packages or letters, in transport containers whose upper opening may be closed by a lid. In this case, the fill level of the transport container can no longer be measured from above.

SUMMARY

It is therefore an object of the invention to overcome or minimize the disadvantages of the prior art and, in particular, to configure a transport container that is conveyable in a transport and distribution system in such a way that it is possible to measure the fill level of the transport container via optical identification and, at the same time, to avoid errors when reading a barcode and/or QR code applied to the transport container.

A transport container according to the invention is suitable for receiving goods, such as letters and packages, in order to be able to transport these goods within the scope of a transport or distribution system via conveyor belts and/or roller conveyors. The transport container comprises an, in particular rectangular, container base body with sidewalls and a bottom. Here, a respective predetermined code section for attaching a machine-readable code, in particular a barcode or a QR code, is provided on two opposite sidewalls. In addition, at least one opening, in particular a plurality of slots extending from the bottom to the upper edge of the sidewall, is provided in the two opposite sidewalls. According to the invention, the openings of the two opposite sidewalls are configured in such a way that they are located directly next to and/or at the same height of the predetermined code sections, and are arranged offset from each other.

The openings/slots are provided to prevent reading errors due to an unwanted reflection of a light beam from occurring when the barcode/QR code is read on the outside of the container. The light beam is usually emitted by a scanning device or laser device whose purpose it is to measure the fill level of the container and to simultaneously read-out the barcode or QR code.

Advantageously, the transport container is configured in such a way that the code sections of the two opposite sidewalls are offset from each other. When the container is empty, the laser beam enters the container through the slot on one sidewall and finally hits the inside of an opposite code section. However, if the container is filled, the laser beam hits the transported goods and thus generates different information than in the case of an empty container.

Furthermore, it is conceivable that the plurality of slots are evenly spaced and the slots in one sidewall are offset by half the distance from the slots in the other sidewall. The fill level measurement of a transport container with such offset slots is particularly easy to implement. A regular distance between the slots also makes it easier to read-out the barcodes/QR codes.

In addition, the two opposite sidewalls may be configured point-symmetrically with respect to each other, which simplifies the manufacture of such a container.

It is also conceivable that the code section is limited on both sides by a slot in order to ensure that reading errors can be prevented as effectively as possible.

The object underlying the invention is further solved by a system comprising a conveyor system, one or more transport containers according to the invention transported via the conveyor system, and a scanning device arranged transversely to the transport direction of the transport container for reading a machine-readable code applied to a sidewall of the transport container. The sidewall provided with the code and the opposite sidewall of the transport container do have openings that are not aligned with each other, and the scanning device is oriented in such a way that, when a read signal output by the scanning device passes through an opening located in the sidewall, it hits either a load located in the transport container or an inner wall section of the opposite sidewall of the transport container.

BRIEF DESCRIPTION OF THE DRAWING FIGURES

The present invention is described in more detail hereinafter based on an embodiment with reference to the accompanying drawings, wherein:

FIG. 1 shows a perspective view of the transport container according to the invention;

FIG. 2 shows a top view of the transport container, wherein the slots of the rear sidewall in the top view are shown schematically next to the slots of the front sidewall in the top view; and

FIG. 3 shows a top view of the transport container.

DETAILED DESCRIPTION

The figures are merely schematic in nature and only serve for understanding the invention. Identical elements are assigned the same reference signs. The embodiment is only given as an example and the invention is not limited to this.

FIG. 1 shows the transport container/container 1 in a perspective view. The container 1 has a rectangular bottom 2, from which four sidewalls 4 extend vertically, forming a circumferential sidewall of the container 1. The two opposite longitudinal walls 5 are divided into a plurality of code sections or sidewall sections 6. In this case, each longitudinal wall 5 has six sidewall sections 6. Each sidewall section 6 of the container 1 may have a machine-readable code 7, for example a barcode and/or a QR code. Here, by way of example, a barcode 7 is provided on one of the sidewall sections. The plurality of sidewall sections 6 is separated from each other by slot-like openings/slots 8. The openings 8 of one longitudinal wall 5 are offset from the openings 8 of the opposite longitudinal wall 5. Accordingly, the sidewall sections 6 of one longitudinal wall 5 are also offset from the sidewall sections 6 of the opposite longitudinal wall 5. The slots 8 extend between a container bottom 2 and an upper edge of the sidewalls 5 without being in contact with the container bottom 2 and the upper edge of the sidewalls 5. Thus, in this embodiment, the container 1 has a circumferential upper edge. Each sidewall section 6 is (slightly) offset from the lateral surface of the container 1 towards the inside of the container and is provided with a frame-like bar 9 extending its lateral edges and upper edge in the direction of its outer side.

It can be seen that the sidewall sections 6 are each divided into two by a transverse bar 10, which is formed continuously across all sidewall sections 6. Here, the transverse bar 10 is arranged in such a way that a lower first sidewall section area 12 of the sidewall section 6 is larger than an upper second sidewall section area 14. Thus, the larger (first) sidewall section area 12 may be provided with a barcode 7 (see FIG. 1). The smaller (second) sidewall section area 14, on the other hand, may remain free. At the same time, the second sidewall section areas 14 are separated from each other by indentations 15, which are aligned in the vertical direction with the slots 8. As can be seen in FIG. 1, however, these indentations 15 are no through-openings between the inside of the container and the outside of the container. The indentations 15 are also laterally limited by the frame-like bar 9. On the upper side, the indentations 15 are limited by the upper edge of the sidewalls 5.

A scanning device, which is not shown here, is provided outside the transport container 1, is spaced from a longitudinal wall 5 and is arranged transversely to the transport direction (transport direction here is in the direction of the longitudinal walls, see arrow A) of the container 1 and emits a light beam/laser beam which hits, for example, on a sidewall section 6 having a barcode 7 and then reads it. In this case, the slots 8 arranged next to this sidewall section 6 prevent a reading error when reading the barcode 7. Alternatively, the light beam passes through a slot 8 and in this case measures the fill level of the container 1. If the container 1 is empty, the beam hits a sidewall section 6 of the opposite longitudinal wall 5. If the container 1 is filled, the beam hits the corresponding transported goods, so that the reflection path of the beam in this case is shorter than with an empty container 1.

The container bottom 2 has a plurality of (three) cross-shaped through holes 16. The through holes 16 are arranged along the central longitudinal axis B of the container 1, which is centrally parallel to the longitudinal walls 5. The cross-shaped through holes 16 contribute to good ventilation of the container 1 and can also or alternatively serve as drainage openings when the container 1 is rinsed/cleaned, for example.

The other two sidewalls 4, which are no longitudinal walls 5, are referred to as front walls 18. Starting from the front walls 18, a bottom section 19 chamfered from the sidewalls 18 towards the center of the container extends along the bottom 2. This bottom section 19 has the shape of a symmetrical trapezoid whose longer base side is approximately as long as the length of the front wall 18. When cleaning/rinsing the container 1 with a liquid, the bottom section 19 may serve to direct the liquid towards the center of the container so that it can easily flow out of the container 1 via the through holes 16. A respective (ergonomic) handle 20 is formed axially symmetrically to the vertical center axis of the front walls 18, said handle 20 being configured as a continuous opening in the two front walls 18. A further code section 6 is arranged to each side of the handle 18, which is, however, not limited by slots. Here, one of these two code sections 6 has a barcode 7 in its first sidewall section area 12.

FIG. 2 shows the container 1 in a top view. The slots 8 of the rear longitudinal wall 5 can each be seen as a dashed line, which is shown between two slots 8 of the frontal longitudinal wall 5 (which is opposite the rear longitudinal wall 5). This illustration makes it clear that the slots 8 of the frontal longitudinal wall 5 are offset from the slots 8 of the rear longitudinal wall 5. Therefore, in the case of an empty container 1 as shown herein, the inside of the sidewall sections 6 of the rear longitudinal wall 5 can be seen through the slots 8 of the frontal longitudinal wall 5. Furthermore, it can be seen that the sidewalls 4 are recessed in their area near the bottom and thus form a circumferential stacking border 22. The width of the stacking border 22 advantageously corresponds to the width of the sidewalls 4. In this case, the container 1 can be placed on an identical or compatible container in such a way that its bottom area projects into the lower container, its stacking border 22 rests on the upper edges of the sidewalls of the lower container and the sidewalls 4 of the (upper) container 1 are aligned with the sidewalls of the lower container.

FIG. 3 shows the container 1 in a top view without schematically depicting the rear longitudinal wall 5. Here, too, it can be seen that each slot 8 of the frontal longitudinal wall 5 is opposite a sidewall section 6 of the rear longitudinal wall 5. The stacking border 22 can also be seen.

Claims

1. A transport container for receiving goods in order to be able to transport the goods within a scope of a transport or distribution system via conveyor belts and/or roller conveyors, the transport container comprising: a bottom from which four sidewalls extend, the four sidewalls comprising a first sidewall, a second sidewall opposite the first sidewall, a third sidewall, and a fourth sidewall opposite the third sidewall;a first code section with machine-readable code on the first sidewall;a second code section with machine-readable code on the second sidewall;at least one first opening provided in the first sidewall; andat least one second opening provided in the second sidewall,the at least one first opening and the at least one second opening being arranged offset from each other.

2. The transport container according to claim 1, wherein the code sections on the first and second sidewalls are offset from each other.

3. The transport container according to claim 1, wherein the at least one first opening and the at least one second opening each comprise a plurality of slots that are evenly spaced, and wherein the plurality of slots in the first sidewall are offset from the plurality of slots in the second sidewall.

4. The transport container according to claim 1, wherein the first and second sidewalls are point-symmetrical with respect to each other.

5. The transport container according to claim 1, wherein: the at least one first opening comprises a plurality of first openings,the at least one second opening comprises a plurality of second openings,the first code section is limited on each side by one of the plurality of first openings, andthe second code section is limited on each side by one of the plurality of second openings.

6. A system comprising: a conveyor system;a transport container according to claim 1; anda scanning device arranged transversely to a transport direction of the transport container, the scanning device configured to read the machine-readable code on the first sidewall and second sidewall of the transport container,the scanning device being oriented in such a way that a read signal output by the scanning device hits, via the at least one first opening, either a load located in the transport container or an inner wall section of the second sidewall of the transport container.

7. The transport container according to claim 1, wherein the transport container is configured for receiving letters or packages.

8. The transport container according to claim 1, wherein the bottom of the transport container is rectangular.

9. The transport container according to claim 1, wherein the machine-readable code is a barcode or a QR code.

10. The transport container according to claim 1, wherein the at least one first opening and the at least one second opening are each formed as a plurality of slots, the plurality of slots in the first sidewall extending from the bottom to an upper edge of the first sidewall, and the plurality of slots in the second sidewall extending from the bottom to an upper edge of the second sidewall.

11. The transport container according to claim 1, wherein: the at least one first opening comprises a plurality of first openings, andthe at least one second opening comprises a plurality of second openings,at least some of the first openings being located directly next to and/or at the same height of the first code section,at least some of the second openings being located directly next to and/or at the same height of the second code section,said at least some of the first openings being arranged offset from said at least some of the second openings.