DE19855274A1 - Cellular wheel sluice for moving loose material has cells which as they turn downwards are biased with pressurised gas before reaching outlet shaft - Google Patents

Abstract

The cell wheel (6) mounted in a housing bore (4) has cells (7) which as they turn downwards are biased with pressurised gas before reaching the outlet shaft (3) which is mounted in the housing. The cells can be biased with gas and discharged through a common opening (17) in the side cover (10). The opening can have a cross-section in the form of two spaced circle arcs connected at the ends by radii. The opening can be changed by turning the relevant side cover.

Description

The invention relates to a rotary valve for conveying or dosing bulk goods, comprising a housing with an inlet shaft and one rotatably mounted in a housing bore, Cellular cell wheel, the housing bore laterally through the side cover is closed and at least in a side cover an opening for a compressed gas supply opens, by means of which the cells can be blown out into an outlet shaft when they reach it.

Rotary valves are usually used to separate bulk goods from one Inlet connected to the receptacle and either dosed in a with the Handover of the outlet chute or into a container with the outlet chute connected pneumatic supply line under positive or negative pressure.

In both cases it is desirable that the cells of the cellular wheel overlap with each other Empty the outlet shaft completely into this to ensure good dosing accuracy or to achieve a high delivery rate. In the case of cohesive goods, the discharge of the Bulk materials from the cells cause difficulties, since such products are particularly useful Excess pressure in the outlet shaft tends to constrict in the cells which conically constrict towards the shaft to compress the cellular wheel.

From the published patent application DE-OS 31 02 153 a generic rotary valve is known, with regard to a uniform, pulsation-free discharge of the bulk material, less is optimized for a complete emptying of the cells. There is an opening in one of the side covers for blowing an air stream into the cell of the cellular wheel, which is directed towards the outlet shaft provided, through which the bulk material is transferred to a constriction in the outlet shaft and out this is evenly entered into a conveyor line underneath.  

Blowing the air flow from the side can empty the cells of numerous bulk materials improve, but is not sufficient for residue-free discharge of distinctly cohesive goods.

US Pat. No. 5,020,550 describes a rotary valve for the processing of tobacco discloses, in which the cells rotating downwards towards the outlet chute successively with a pressure is applied which corresponds to the pressure in the outlet shaft. The gradually Pressure build-up is essentially the result of multiple withdrawals of process gas (carbon dioxide) taken from the upward rotating cells of the cellular wheel, this way can largely be traced back to the processing process. The process gas is the downward rotating cells over radially arranged in the circumference of the lock housing internally directed holes supplied.

This approach is unsuitable, an adequate one when promoting distinctly cohesive goods Ensure emptying of the cells, as these are under the influence even in the prestressed state gravity is extremely reluctant to fall from the cells into the outlet shaft.

task

The invention is based, a powerful, self-cleaning lock for the task Delivering and dosing of distinctly cohesive goods.

solution

The object is achieved in that the downward rotating cells are reached before they are reached of the outlet shaft can be covered with compressed gas. The downward rotating cells will be there biased to a pressure that corresponds at least to the pressure in the outlet shaft, preferably but by an amount of, for example, 0.5 to 1.0 bar above this and thus in essentially corresponds to the pressure of the compressed gas provided for blowing out the cells.  

Surprisingly, this procedure can largely empty the cells in the outlet shaft can be achieved either in the housing or in the opening for the Compressed gas supply is arranged opposite the side cover.

It is particularly advantageous to also cover the cells with compressed gas via one in one the opening arranged in the side cover, that is to say essentially in the axial direction, the openings for blowing and stringing face each other, but also on the same side. It is of course also within the scope of this invention possible to cover as well as blow out with compressed gas via each side cover to make. These arrangements basically prevent the material being conveyed through the covering is pressed into the tapered bottom of the cells, which at a radially inward supply of compressed gas through the housing in particular high gas speeds inevitably occurs.

Manufacturing and connection technology, it is particularly cheap, both the covering and that Blow out through a common opening in the side cover. The opening is in align this case to the housing of the rotary valve that at least part of the time its cross-section is separated from the outlet shaft by a web of the cellular wheel.

The common opening can, for example, be essentially circular Cross-section, but also the shape of an elongated hole bent around the axis of rotation of the cell wheel have that from two mutually spaced, connected at the end via radii Circular arc exists.

In order to be able to adapt the rotary valve optimally to the circumstances, it is advantageous to if the arrangement of the openings for the compressed gas, especially the common Opening for covering and blowing out relative to the housing can be changed later. This can, for example, by rotating the relevant side cover about the axis of the Housing bore done. Another possibility for fine adjustment, in which also the radial Alignment of the opening in the side cover can be changed is the eccentric arrangement the opening in a circular cover segment, for example, that in turn is off-center and rotatably sealed in the side cover.  

In order to remove the adhering bulk material particularly carefully from the bottom of the cell, the Compressed gas flow in the same direction and thus inclined with respect to the axis of the cellular wheel become.

A special chambering of the cells serves the same purpose extends outer surface line of the cellular wheel. It is asymmetrical when blowing in from one side, when blowing in from both sides, however, to be carried out symmetrically to the center plane of the cellular wheel.

characters

The figures represent, by way of example and schematically, various embodiments of the invention Rotary valves in longitudinal and cross section.

Show it:

Fig. 1 is a rotary valve according to the invention according to claim 2

Fig. 2 shows a lock according to claim 5

Fig. 3 shows a further lock according to claim 5

Fig. 4 shows a rotary valve according to claim 7

Fig. 5 shows a lock according to claim 9

Fig. 6 is a rotary valve according to claim 11

A sluice FIG. 7 according to claim 3

The cellular wheel sluice depicted in FIG. 1 consists of a housing 1 with an inlet shaft 2 and an outlet shaft 3 . In a housing bore 4 , a cellular wheel 6, which is closed on one side by a flanged disc 5 axially sealed by a sealing element 12 ″, is rotatably mounted in the direction of arrow A, the cells 7 of which are formed by a plurality of radially extending webs 9 arranged on a shaft 8 .

The housing bore 4 is closed on both sides by side covers 10 , 10 ', which accommodate the bearings 11 , 11 ' and sealing elements 12 , 12 'for the shaft 8 . The shaft 8 is guided on one side to introduce the drive torque out of the side cover 10 '. The bearing 11 assigned to the open side of the cellular wheel 6 is designed as a fixed bearing, by means of which a narrow axial gap between the webs 9 and the side cover 10 can be set. The on-board disk 5 facing bearing 11 'forms the bearing, since the sealed on its circumference by the seal member 12 "flanged wheel 5 is slidable in the axial direction without sealing loss. In order to improve the seal, the annular space between the flanged wheel 5 and lid 10' with an additional Barrier gas are applied, the pressure of which is slightly above the highest gas pressure occurring in the lock.

The side cover 10 has two openings 13 , 14 with associated connecting pieces 15 , 16 . Via the connecting piece 15 and the opening 13 , the compressed gas for blowing out the cells 7 communicating with the outlet shaft 3 is supplied. The connecting piece 16 and the opening 14 serve to cover the downward rotating cells 7 to the outlet shaft 3 with a compressed gas to a pressure which preferably corresponds to or is greater than the pressure in the outlet shaft 3 before reaching the same. At least at times, the openings 13 , 14 are separated from one another by a web 9 which seals toward the housing bore 4 in such a way that the compressed gas cannot escape into the outlet shaft 3 for covering.

Since the compressed gas is supplied via separate connecting pieces 15 , 16 , it is possible to individually control the gas pressure for the covering and blowing out.

In the cellular wheel sluice according to FIG. 2, the compressed gas for covering and blowing out is supplied via a common opening 17 and a common connecting piece 18 . The opening 17 is arranged in the manner of the housing 1 of the cellular wheel sluice in such a way that at least temporarily two successive cells 7 are pressurized, one of which is connected to the outlet shaft 3 , but the other is separated from the latter via a web 9 as shown .

The opening 17 has a circular cross section, which can be connected to the circular flange 19 in a particularly simple manner via the connecting piece 18 .

Of course, the invention is not limited to blowing in compressed gas on one side, but can also be supplied via both side covers 10 , 10 ', as shown in FIG. 3.

In order to allow the compressed gas to act on a larger number of cells 7 , it can be advantageous to make the opening 17 elongated, for example in the form of an elongated hole bent around the axis 20 of the cell wheel 6 . In the lock shown in FIG. 4, the time available for blowing out the cells 7 is significantly extended.

In the locks described above, in particular in the locks according to FIGS. 2 to 4, it is helpful to be able to subsequently change the position of the openings 13 , 14 , 17 in the housing in order to achieve a particularly favorable ratio between the covering with compressed gas and for each application to be able to adjust the blow-out using compressed gas. This setting can be made particularly simply by turning the side cover 10 about the axis of the housing bore 4 or, as shown in Fig. 5, by turning an eccentrically arranged in the side cover 10 , to this rotatably sealed cover segment 21 , in which the opening 17 and the connecting piece 18 for the supply of compressed gas are eccentrically attached. In this way, the opening 17 can also be aligned radially.

A combination of both settings is of course also possible.

FIG. 6 shows a cellular wheel sluice in which a further improvement in emptying is achieved by special chambering of the cells 7 . The chambering is carried out by means of a chamber plate 22 inserted into the cell 7 , which extends in the blowing direction from the cell base 23 to the outer circumferential surface 24 of the cell wheel 6 . The chamber plate 22 covers the part of the cell 7 that can only be reached to a limited extent by the compressed gas and therefore cannot fill with bulk material. Such locks are to be preferred in particular when conveying perishable bulk goods.

In order to remove adhering deposits particularly thoroughly from the walls of the cell 7 , the direction B of the compressed gas supply is inclined towards the cell base with respect to the axis 20 of the cell wheel 6 .

In a departure from the locks shown above, the outlet shaft 3 in the cellular wheel lock according to FIG. 7 is arranged laterally in the side cover 10 ′ opposite the common opening 17 . The invention can also be successfully implemented in this device, referred to as a blow-through lock.

The invention is not limited to the embodiments shown, but includes all for the Variations obvious to a specialist. In particular, the cellular wheel can also be one of the Cylindrical shape deviating, for example conical shape. The cross section of the Blowing openings are not exhausted in the preferred versions.  

Reference list

1

casing

2nd

Inlet shaft

3rd

Outlet shaft

4th

Housing bore

5

Flanged wheel

6

Cell wheel

7

cell

8th

wave

9

web

10th

Side cover

11

camp

12th

Sealing element

13

Opening for compressed gas

14

Opening for compressed gas

15

Connecting piece

16

Connecting piece

17th

Opening for compressed gas

18th

Connecting piece

19th

flange

20th

axis

21

Cover segment

22

Chamber sheet

23

Cell base

24th

Lateral surface

Claims (11)

1. rotary valve for conveying or metering bulk material, comprising a housing (1) with a feed shaft (2) and a rotatably mounted in a housing bore (4), cells (7) having cellular wheel (6), wherein the housing bore laterally through the side cover ( 10 , 10 ') is closed and at least one opening ( 13 , 14 , 17 ) for a pressurized gas supply opens into a side cover, by means of which the cells can be blown out when an outlet shaft ( 3 ) is reached, characterized in that the downward-rotating cells can be covered with compressed gas before reaching the outlet shaft ( 3 ). 2. rotary valve according to claim 1, characterized in that the outlet shaft ( 3 ) in the housing ( 1 ) is arranged. 3. rotary valve according to claim 1, characterized in that the outlet shaft ( 3 ) in the opening ( 13 , 17 ) for the compressed gas supply opposite side cover ( 10 ') is arranged. 4. rotary valve according to claim 1 to 3, characterized in that the downward rotating cells ( 7 ) before reaching the outlet shaft ( 3 ) through an opening ( 14 , 17 ) in the side cover ( 10 , 10 ') can be covered with compressed gas. 5. rotary valve according to claim 4, characterized in that the covering of the downward rotating cells ( 7 ) with compressed gas and the blowing out of the cells ( 7 ) when reaching the outlet shaft ( 3 ) via a common opening ( 17 ) in the side cover ( 10 , 10 ') takes place. 6. rotary valve according to claim 5, characterized in that the opening ( 17 ) has a substantially circular cross section. 7. rotary valve according to claim 5, characterized in that the opening ( 17 ) has a cross section substantially in the form of two mutually spaced circular ends connected by radii. 8. rotary valve according to one of claims 4 to 7, characterized in that the arrangement of the opening (s) ( 17 ) by rotating the relevant side cover ( 10 , 10 ') is variable. 9. rotary valve according to one of claims 4 to 8, characterized in that the opening (s) ( 17 ) are arranged eccentrically in a cover segment ( 21 ) which in turn is arranged eccentrically and rotatably sealed in the side cover ( 10 , 10 '). 10. Rotary valve according to one of the preceding claims, characterized in that the direction (B) of the compressed gas supply to the axis ( 20 ) of the cellular wheel ( 6 ) is inclined. 11. rotary valve according to one of the preceding claims, characterized in that the cells ( 7 ) are provided with a in the direction of blowing from the cell base ( 23 ) to the outer circumferential surface ( 24 ) of the cellular wheel ( 6 ) extending chamber.