DE102022005030A1 - Device for small-volume bulk goods - Google Patents

Abstract

A device (1) for small-volume bulk material is described, comprising an arrangement for separating (3) and a measuring device (23) arranged below the arrangement for separating (3), the measuring device (23) comprising at least one measuring station with which a bulk material can be measured. A transport device (19) is provided between the arrangement for separating (3) and the measuring device (23), with which the bulk material can be fed to the at least one measuring station of the measuring device (23).

Description

The invention relates to a device for small-volume bulk material according to the features of patent claim 1.

In order for small-volume bulk goods to be measured in terms of quality and properties, such as hardness, the bulk goods must first be separated. This is done with a device for separating bulk material. After the bulk material has been separated, it can be measured using measuring stations. Devices that include both a device for separating and measuring stations require a lot of parking space because they are built very expansively.

The object of the present invention is therefore to provide a device for small-volume bulk material that is very compact. This object is achieved by a device according to the features of patent claim 1.

The invention thus relates to a device for small-volume bulk material, comprising a separating arrangement with which the bulk material can be separated, and a measuring device arranged below the separating arrangement. The measuring device has at least one measuring station with which a bulk material can be measured. The small-volume bulk material is, for example, a medical product, such as a tablet. The term bulk goods is used below for a single product and in some passages also as a collective term for several of these products (bulk goods).

A transport device is provided between the arrangement for separating and the measuring device, with which the bulk material can be transported to the at least one measuring station of the measuring device.

The advantage of this device is that it is very compact. It is also advantageous that the arrangement for separating comprises a storage container and a plate element designed as a vibration plate, with the storage container being arranged above the vibration plate. This ensures that the bulk material reaches the vibrating plate solely by gravity and no additional drive is required to transport the bulk material onto the vibrating plate. Since there is no need for an additional drive, this design contributes to the device being of compact design. Another advantage is that the vibration plate is very easy to clean.

The device comprises a vibrating drive which is arranged below the vibrating plate and with which the vibrating plate can be made to vibrate in order to separate the bulk material coming from the storage container and to transport it to the transport device. The fact that the vibration drive is arranged directly below the vibration plate contributes to the device having a compact design.

Advantageously, the bulk material separated by the separation arrangement is transported onto the transport device via an opening in the plate element. A central axis runs through a center of the device, with the storage container and the vibration drive being arranged on the central axis and with the central axis running centrally through the vibration drive and the storage container, as a result of which the transport device rotates about the vibration drive and the central axis. As a result, the device has a compact structure.

The transport device is preferably a transport star or a transport rake, because the vibration drive is then laterally surrounded by the transport device. The transport device thus rotates around the vibration drive. This design saves space and also contributes to the compactness of the device.

It is also advantageous that the storage container has a standard connection at a feed opening through which bulk material can be introduced into the storage container, to which bulk material feeds of different types can be quickly and easily attached and removed again. This feed opening and the

Standard connection can be provided in an upper section of the reservoir or also on one side of the reservoir. A conversion and thus an adaptation of the arrangement for separating bulk material feeds of different types is therefore not necessary. As a result, the device can be used at different locations, ie also at locations where there is no space for a conversion or adaptation of the arrangement for isolation or tools for conversion or adaptation are not available.

It is hereby also explicitly proposed to combine several features of the individually described embodiments with one another.

• 1 eine Seitenansicht einer Vorrichtung für kleinvolumiges Schüttgut;
• 2 eine Draufsicht auf die in 1 gezeigte Vorrichtung nach Schnitt durch eine Ebene S;
• 3 einen Längsschnitt entlang A-A durch die in 2 gezeigte Vorrichtung und
• 4 eine Draufsicht auf die Vorrichtung nach Schnitt durch die Ebene B-B bei der in 1 gezeigten Vorrichtung.

The device is explained in more detail below with reference to figures. Show it:

• 1 a side view of a device for small-volume bulk material;
• 2 a top view of the in 1 device shown after a section through a plane S;
• 3 a longitudinal section along AA through the in 2 shown device and
• 4 a plan view of the device after sectioning through the plane BB at FIG 1 shown device.

1 shows a side view of a device 1 for small-volume bulk material. The small-volume bulk material is, for example, a medicinal product that can be in the form of a tablet, an oblong or a granule. The device 1 is used both for separating and for measuring bulk material. This device 1 comprises a lower section 2 and an upper section 3 . The lower section 2 is surrounded by a housing 4 . In the upper section 3 there is an arrangement for separating 3, whereby the upper section corresponds to the arrangement for separating. This arrangement for separating 3 comprises a plate element 5 designed as a vibrating plate and a storage container 6 which can be easily removed and in which bulk material can be stored. The reservoir 6 can either be permanently connected to the plate element 5 or be decoupled from this plate element 5 . If the reservoir 6 is decoupled from the plate element 5, the reservoir 6 can be connected to the housing 4, for example.

The reservoir 6 includes a small, lower opening 7 in a lower area, through which the bulk material can reach the plate element 5 . Bulk is in the 1 not shown. Bulk material can be introduced into the storage container 6 via an upper feed opening (not visible in this view), which is located in an upper region of the storage container 6 . For this purpose, bulk material feeds can be attached to the upper area of the storage container 6 .

So that bulk material feeds of different types can be attached to the storage container 6 quickly and easily, the storage container 6 has a standard connection 8 in the upper area. This standard connection can be, for example, a clamp with which the corresponding bulk material feed can be attached to the storage container 6.

A conversion and thus an adaptation of the arrangement for separating to different bulk material feeds is therefore not necessary. As a result, the device can be used at different locations, ie also at locations where there is no space for a conversion or adaptation of the arrangement for isolation or tools for conversion or adaptation are not available.

At the in 1 illustrated bulk material feed 9 is a hose 90 through which bulk material can be introduced into the reservoir 6 .

Since the storage container 6 has a standard connection 8, another bulk material feed, for example a funnel, can also be attached to the storage container 6 quickly and easily.

Since the storage container 6 can be easily removed, the storage container 6 can also be filled separately and then placed back onto the device 1.

In 2 is a plan view of the in 1 shown device 1 represented by a section through a plane S.

The plate element 5 of the upper section 3 is arranged on the lower section 2 of the device 1 . The lower opening 7 of the storage container 6 can also be seen through the section, through which the bulk material can reach the plate element 5 . The bulk material in 2 in the form of oblongs is only partially provided with the reference number 9 for the sake of clarity. This bulk material 9 is introduced via a feed opening 10 which is attached in the upper area of the storage container 6 . However, it is also possible to provide the supply opening 10, for example, on the side opposite the opening 7 and not in the upper region of the storage container 6.

The bulk material 9 is moved along a path 14 in the direction of arrow 11 by a vibration drive, for example a throw conveyor, until it finally reaches an opening 12 and falls down. There, the separated bulk material falls into a chamber of a transport device, for example into a chamber of a transport star. The transport device with the chambers is located in the lower section 2 and is therefore in 2 not to be seen. When the bulk material is transported in the direction of the arrow 11, ie in the direction of the opening 12, the bulk material 9 is also separated by the vibration drive. Because the vibration drive is in the lower section 2, it is in 2 also not visible.

When the bulk material 9 is transported in the direction of the opening 12 , the bulk material is guided over a sieve 13 . Dust or smaller fragments of the bulk material 9 falls through this screen 13 downwards into a container (not visible) arranged under the screen 13 and is thus removed from the plate element 5 removed. This prevents dust or smaller fragments from getting into the opening 12 and thus falsifying the results of the measurements of the bulk material to be measured.

The web 14 on which the bulk material 9 is transported is preferably divided into several web sections, as a result of which the path of the web 14 is long enough for the bulk material 9 to be separated on the way to the opening 12 . The track 14 of the plate element 5 has a spiral structure and has three track sections, namely an inner track section 14', a middle track section 14'' and an outer track section 14''' adjoining it. The boundaries of the individual track sections 14', 14", 14"' are identified by dashed lines 16, 17. The web 14 is surrounded on the outside by an outer wall 15 which prevents the bulk material 9 from falling off the plate element 5 . It goes without saying that the track 14 does not have to have a spiral structure, but can also have a different structure.

3 shows a longitudinal section along -A through the in 2 Device 1 shown, wherein the upper section 3 is in turn arranged above the lower section 2. The upper section 3 is the arrangement for separation 3 and consists of the plate element 5 and the reservoir 6, which can either be connected to the plate element 5 or arranged decoupled from it. In addition to the lower opening 7 for discharging the bulk material onto the plate element 5, the standard connection 8 can also be seen. A bulk material feeder is in 3 not shown. It was also refrained from 3 Show bulk material that is transported on the path 14 of the plate element 5 in the direction of the opening 12.

The size of the lower opening 7 of the storage container 6 can preferably be adjusted, as a result of which the discharged quantity of bulk material per unit of time can be changed or adapted to the size of the bulk material.

In the lower section 2, directly below the plate element 5, is the vibration drive 18, shown only schematically, with which the bulk material is not only transported in the direction of the opening 12, but is also isolated on the way there. The vibration drive 18 can be a throw conveyor, which transports the bulk material by vibration and separates it from one another. Vibration drives for the transport of bulk material by means of vibration are known, which is why a detailed description of the vibration drive 18 is omitted at this point.

The vibration drive 18 is surrounded on the side by the transport device 19, with the transport device 19 preferably being designed in the form of a wheel and in particular as a transport star (as in 3 shown) or is designed as a transport rake.

The transport device 19 designed as a transport star 19 is arranged above a floor 20 and comprises a number of chambers in which a previously isolated bulk material is transported. In the 3 only two chambers 21, 22 can be seen.

Below the floor 20 there is a measuring device 23 which comprises at least one measuring station, the measuring device 23 only being shown schematically and in part. However, the measuring device 23 preferably comprises a plurality of measuring stations so that as many parameters as possible of the bulk material can be measured.

As in 3 As can be seen, the chamber 21 of the transport device 19 is located directly below the opening 12 of the plate element 5. This allows bulk material falling through the opening 12 to enter the chamber 21 of the transport device 19 directly. The opening 12 is equipped with a detector, for example a sound detector, with which it can be detected whether only one bulk material or several bulk materials have entered the chamber.

After the bulk material has fallen into the chamber 21 of the transport device 19 and the detector has determined that only one bulk material has actually entered the chamber 21, the bulk material is guided in a first direction around the vibration drive 18 and above the measuring device 23. The bulk material lying in the chamber 21 passes at least the first measuring station of the measuring device 23. This first measuring station is preferably a scale.

The scales are used to detect whether only bulk material has actually entered the chamber 21 . If the scales determine that several bulk goods or even only a few fragments of a bulk goods have entered the chamber 21, the chamber 21 is emptied. For this purpose, the transport device 19 is moved back in a second direction, i.e. in the opposite direction to the first direction. In doing so, the chamber 21 is moved to a waste container (not visible) which is installed in the floor 20 . As soon as the chamber 21 is above the waste container, fragments or the multiple bulk materials fall into this waste container and are thus disposed of.

The detector and the scale ensure that only one bulk material is ever measured by the measuring device.

In addition to the scales, the measuring device 23 preferably also includes other measuring stations, as a result of which a wide variety of parameters can be determined. Thus, these further measuring stations can be video cameras and/or NIR sensors and/or even a fracture chamber. In addition to hardness, the width and length of a bulk material can also be measured in this fracture chamber. With the NIR sensors, for example four or eight such sensors can be provided, the chemical composition or the quality of the bulk material is determined. Video cameras are used to check whether only a bulk material has actually reached the transport device 19 via the opening 12, or also to check whether the bulk material has the desired shape.

In 3 a central axis M running through the device 1 is shown, which runs through the center of the device 1 . The reservoir 6 and the vibration drive 18 are arranged on this central axis M. The central axis M thus also runs centrally through the vibration drive 18 and the storage container 6. Therefore, the transport device 19 rotates not only about the vibration drive 18, but also about the central axis M.

4 shows a plan view of the lower portion 2 of the device according to a horizontal section along a plane BB (see 1 ). The transport device 19 surrounds the vibration drive 18 on all sides and can be moved forwards around this vibration drive 18 in the direction of arrow 40 or moved back in the direction of arrow 41 .

The transport device 19 is in 4 designed as a transport star and has several chambers 21, 22, 24 to 33 which can accommodate bulk material. One bulk material 34 to 38 designed as an oblong is already in the chambers 21, 22, 24, 25, 26. The other chambers 27 to 33 are empty.

The bulk material 38 has already been introduced into the chamber 21 from above via the opening 12 of the plate element 5 (see also 3 ). This chamber 21 and the bulk material 38 located therein is in a position P0 (starting position). Since the detector attached to the opening 12 (not visible) has determined that it is only a bulk material, the chamber 21 with the bulk material 38 therein is moved further forward in the direction of the arrow 40 and thus in the direction of the position P10 . The bulk material 38 first reaches the position P1. A first measuring station of the measuring device 23 in the form of a scale is located in the floor 20 in this position P1. The scales are used to determine whether the material in chamber 21 is actually just bulk material. If there were only a few fragments or even two bulk materials in the chamber 21, the transport device 19 would move back in the direction of the arrow 41 until the chamber 21 has reached the position Px. There is an opening 42 in the floor 20, under which a waste container (not visible) is arranged, so that the bulk material or fragments in the chamber 21 fall into the waste container and are thus disposed of. The device 19 is then moved forward again in the direction of the arrow 40 until the chamber 21 has again reached the starting position P0. In this starting position P0, the chamber 21 is once again loaded with a bulk material.

Disposal of fragments prevents fragments from being transported further forward in the direction of position P10 and thus remaining on the following measuring stations and thus polluting these stations.

It goes without saying that it is thus also possible for the transport device 19 to be moved further forward in the direction of the position P10 and that disposal of fragments can also be dispensed with.

However, since there is only one bulk material 38 in the chamber 21, the transport device 19 is moved further forward in the direction of the arrow 40. The bulk material 33 successively passes through the positions P2 to P10. A further measuring station of the measuring device 23 can be arranged in the floor 20 at each of the positions P2 to P9. It is thus possible, for example, to provide an NIR sensor in each case in the floor 20 as measuring stations. Each NIR sensor thus forms a measuring station and—like the scales at position P1—is part of the measuring device 23. When passing these positions P2 to P9, the bulk material 38 is thus measured using NIR. The measuring device 23 thus includes eight NIR sensors. Of course, it is also conceivable that 20 NIR sensors are provided as measuring stations in the floor only at positions P2 to P5 and that the bulk material is measured by video cameras in positions P6 to P9. For this purpose, the video cameras are also arranged in the floor 20, with each video camera forming a measuring station. In this case, the measuring device 23 would also have nine measuring stations, namely a scale, four video cameras and four NIR sensors.

After the chamber 21 with the bulk material 38 has passed the position P9, the transport device 19 is moved further in the direction of the arrow 40 until the chamber 21 with the contained therein chen bulk material 38 has reached the position P10. In position P10, the base 20 preferably has an opening 43 through which the bulk material 38 can be removed, for example because the waste container is arranged below the opening 43.

However, it is also conceivable that the bulk material 38 is fed via the opening 43 to a further measuring station, such as a fracture chamber (not visible), which is also located in the lower section 2 of the device 1, but below the vibration drive 18 and the transport device 19 is arranged. In addition to a hardness measurement, the width and length of the bulk material can also be measured in this fracture chamber.

It goes without saying that the transport device 19 can also have more or fewer than just 12 chambers, with which the transport device can also move to more or fewer positions. A measuring station of a measuring device can be provided for each of the positions approached by the transport device, so that the bulk material can be measured in each of the positions.

Reference List

1

Side view of a device

2

lower section

3

isolation

4

Housing

5

plate element

6

reservoir

7

opening

8th

standard connection

9

bulk goods

10

feed opening

11

Arrow

12

opening

13

Sieve

14

Train

15

outer wall

16:17

Dashed lines

18

vibration drive

19

transport device

20

Floor

21:22

chambers

23

measuring device

24 to 33

chambers

34 to 38

bulk goods

39

--

40.41

Arrow

42

--

43

opening

90

Hose

M

central axis

Claims (3)

Device for small-volume bulk material, comprising - an arrangement for separating (3) with which the bulk material can be separated, - a measuring device (23) arranged below the arrangement for separating (3), the measuring device (23) comprising at least one measuring station with which a bulk material (9) can be measured, with a transport device (19) being provided between the arrangement for separating (3) and the measuring device (23), with which the bulk material can be fed to the at least one measuring station of the measuring device (23), the Separation arrangement (3) comprises a storage container (6) and a vibration plate (5), the storage container (6) being arranged above the vibration plate (5) and a vibration drive (18) being provided below the vibration plate (5). is arranged and with which the vibrating plate (5) can be made to vibrate in order to separate the bulk material coming from the storage container (6), the bulk material (9) separated by the arrangement for separation (3) passing through an opening (12) of the plate element (5) reaches the transport device (19), characterized in that a central axis (M) runs through a center of the device (1), with the storage container (6) and the vibration drive (18) on the central axis (M) is arranged and wherein the central axis (M) runs centrally through the vibration drive (18) and the storage container (6), whereby the transport device (19) rotates about the vibration drive (18) and the central axis (M). device after Claim 1 , characterized in that the vibration drive (18) is surrounded laterally by the transport device (19). device after Claim 1 , characterized in that the storage container (6) has a standard connection (8) to which bulk material feeds of different types can be attached.

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