DE19855647C1 - Cell wheel sluice for conveyance or controlled feed of bulk material comprises housing with inflow and outflow shafts and cell wheel rotatably located on shaft in housing bore - Google Patents

Abstract

A cell wheel sluice gives controlled feed of bulk material. The sluice has a housing (1) with an inflow shaft (2) and an outflow shaft (3). The cell wheel (5) is rotatably located in a housing bore (4) on a shaft (6) The radially extending vanes are connected with chamber dividing plates (15) which form a number of chambers (11). At least one group of chambers (11') abutting on a chamber dividing plate is coverable against bulk material entry from the inflow shaft and communicates via openings (16) in the chamber dividing plates with the chambers of the cell wheel conveying bulk material. This group of chambers can be connected with a pressure gas connection (18).

Description

The invention relates to a rotary valve for conveying or dosing bulk goods, comprising a housing with an inlet shaft, an outlet shaft and one in a housing bore by means of a shaft rotatably mounted cell wheel, the substantially radially extending Wing in connection with disc-shaped arranged coaxially to the cell wheel Chamber dividers form a plurality of chambers, of which at least one is a Chamber partition adjacent group of chambers against bulk entry from the Inlet shaft can be covered and with openings in the chamber dividers communicates bulk cells of the cellular wheel.

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.

From the patent DE 42 28 014 C1 is a generic rotary valve for granulated Bulk goods known. The cellular wheel provided with a radially extending wing is in the middle two chamber dividing plates arranged coaxially to its longitudinal axis in three groups of chamber subdivided, of which the axially external ones are filled with bulk material via the inlet shaft, while the middle group over a located in the inlet shaft, transversely to the axis of the Cell wheel aligned web against direct access of bulk goods from the inlet shaft is covered. The middle group of chambers communicates via radially external ones Openings in the chamber dividers with the other two groups of chambers. At Rotation of the cellular wheel creates outstanding granules over the outer surface of the cellular wheel gripped by a scraper edge in the inlet shaft and the openings in the middle chambers fed to a cutting of the granules between the wings of the cellular wheel and the to prevent inlet-side edges of the housing bore. With a further rotation of the  The granules are removed from all chambers under the influence of gravity in the cell wheel Discharge shaft discharged.

However, the invention is completely different from this task Thought.

When operating cellular wheel sluices, it is desirable that the chambers of the In case of overlap with the discharge shaft, completely empty the cell wheel in this to ensure a good To achieve dosing accuracy or a high delivery rate. With cohesive, powdery goods can be difficult to discharge the bulk material from the cells, since such products tend to overpressure in the outlet shaft, in the Compressing shaft towards conically narrowing cells of the cellular wheel.

In the design specification DE 17 56 238 a cellular wheel sluice for adhesive bulk materials is disclosed, whose shaft is formed as a hollow body and with the recesses arranged in it each connected to the outlet shaft covered chambers of the cellular wheel. Over a The hollow body can be pressurized with compressed air at the side opening in the shaft end on the drive side are the bulk material located in the chambers through the recesses Blows out outlet shaft.

This device is associated with considerable construction costs, since the hollow shaft for Achieving sufficient bending stiffness must have a large diameter. Further the compressed air connection on the drive shaft ends must be rotatably sealed.

In the patent DE 7 07 791 it is proposed that the chambers pass through the outlet shaft arranged to blow out compressed air nozzles directed to the shaft of the cellular wheel.

With this procedure, however, the central area of the chambers can only be limited by free adhering bulk goods, which is why the cellular wheel according to this state of the art  elaborate chambering that reduces the chamber volume in the central area. The The performance of such a lock is therefore limited.

task

The invention has for its object a powerful and simple design Provide lock for cohesive bulk goods.

solution

The object is achieved in that the bulk material entry from the inlet shaft coverable group of chambers can be connected to a compressed gas connection. About the This compressed air can be directed into the product-carrying openings in the chamber dividers Chambers are fed, whereby the bulk material is discharged into the discharge shaft.

The dependent claims 2 to 9 relate to preferred embodiments of the lock which are explained in detail with reference to the figures.

characters

The figures represent examples and schematically designed according to the invention Cell wheel locks in longitudinal and cross section as well as views and sections of the associated Cell wheels represent.

Show it:

Fig. 1 is a rotary valve according to claim 5

Fig. 2 is a half-side-cut cellular out of the lock according to Fig. 1

Fig. 3 shows a further embodied according to the invention lock according to claim 4

Fig. 4 is a half-side-cut cellular out of the lock according to Fig. 3

Fig. 5 is a rotary feeder having the combination of features according to the invention from Fig. 1 and 2

Fig. 6 is a half-side-cut from the cellular wheel sluice according to Fig. 5

Fig. 7 is a rotary valve according to a further embodiment according to claim 8

Fig. 8 is a half-side-cut cellular out of the lock according to Fig. 7

Fig. 9 shows a further rotary valve according to the invention according to claim 9.

The cellular wheel sluice depicted in FIG. 1 consists of a housing 1 with an inlet shaft 2 for the supply of bulk material and an outlet shaft 3 for the discharge of the bulk material, for example into a pneumatic pressure delivery line, not shown. The housing 1 is provided with a cylindrical housing bore 4 , in which a cellular wheel 5 is rotatably mounted in the direction of arrow A. It is supported by a shaft 6 and bearings 7 on both sides in side covers 8 , which close the housing bore 4 laterally. Sealing elements 9 seal the housing bore 4 from the bearings 7 .

From the shaft 6 extend radially, only a small gap from the housing bore 4 spaced vanes 10 , which form a plurality of chambers 11 .

The cellular wheel is laterally provided with flanged wheels 12 , the circumference of which is sealed towards the side covers 8 by means of further sealing elements 13 . A sealing gas can be applied to the annular space 14 between the flanged disk 12 and the side cover 8 .

The cellular wheel 5 is at a distance from the flanged wheels 12 and has chamber dividing plates 15 which are arranged coaxially to the longitudinal axis of the cellular wheel. They divide the chambers 11 formed by the wings 10 into two narrow, lateral and a wide, middle group of chambers 11 . Each lateral chamber 11 ′ is connected to a central chamber 11 ″ via an opening 16 located near the shaft 6 .

The inlet shaft 2 of the housing 1 is provided in the area of the housing bore 4 with lateral projections 17 , which cover the lateral chambers 11 'against bulk material flowing in from the inlet shaft 2 and keep them largely free of bulk material, while the middle chambers 11 "can be filled with bulk material, which at Rotation of the cellular wheel 5 is emptied into the outlet shaft 3 .

In the meantime, the chambers 11 ′ rotating toward the outlet shaft 3 are guided past two pressure gas connections 18 provided radially in the housing 1 and pressurized with a pressure which is above the pressure in the outlet shaft 3 . As soon as one of the central chambers 11 "is connected to the discharge shaft 3, emerges from the associated lateral chamber 11 'pressurized gas through the opening 16 in the middle chamber 11" and blows the bulk material located there in the discharge chute 3 from. Protrusions 19 arranged laterally in the outlet shaft 3 on the circumference of the housing bore 4 prevent the compressed gas from escaping into the outlet shaft 3 beforehand without effect. In contrast to the projections 17 in the inlet shaft 2 , the projections 19 extend only over part of the circumference of the housing bore 4 in the outlet shaft 3 so that, despite the cover, bulk material and dust particles which have been introduced into the lateral chambers 11 'can be discharged into the outlet shaft 3 .

The conveying gas received by the chambers 11 is subsequently expanded to the pressure in the inlet shaft 2 via a vent 20 .

Fig. 2 shows a suitable feeder. 5 Since the projections 19 in the housing 1 prevent premature escape of the compressed gas located in the side cells 11 ', the wings 10 ' of the side chambers 11 'and the wings 10 "of the middle chambers 11 " can each be in alignment with one another.

Although it is inexpensive, it is by no means absolutely necessary to arrange chambers 11 'which can be pressurized with gas on both sides of the middle chambers 11 ". The invention naturally also includes the one-sided design.

The rotary valve according to Fig. 3 differs from the previously described lock in such a manner that the chamber dividing plates 15 toward the center are offset, and a narrow set of chambers 11 'to separate, the rotated by a roof-shaped, with respect to the longitudinal axis of the cellular wheel by 90 ° Web 21 in the inlet shaft 2 are covered against the ingress of bulk material. The filling takes place in the wide lateral chambers 11 ″, which are blown out via the openings 16 when the outlet shaft 3 is reached. A projection 19 arranged in the center plane of the outlet shaft 3 in turn prevents the compressed gas from escaping prematurely.

As can be seen from FIG. 4, a suitable cellular wheel 5 can also have vanes 10 ′, 10 ″ which are aligned with one another on both sides of the chamber dividing plates 15 .

In the rotary valve of Fig. 5 and 6, the inventive features of the locks previously illustrated are combined in such a manner that five groups are formed by chambers 11 by a total of four chamber separating plates, of which the central and the peripheral chambers 11 'connected to the pressure gas connection 18 are.

Notwithstanding the previously shown embodiments, the wings 10 are in the feeder 5 of Fig. 6 continuously generated while the disc-shaped chamber separating plates 15 are composed of a plurality between the inserted circle sectors.

In order to dispense with the projections 19 in the outlet shaft 3 , the cellular wheel 5 according to FIGS. 7 and 8 can be formed. The wings 10 'of the chambers 11 ' which can be connected to the compressed gas connection 17 'are offset from the wings 10 "of the bulk material-conveying chambers 11 " in such a way that the chambers 11 ' are still sealed radially from the circumference of the housing bore 4 , while those with them over the chamber 11 "communicating the openings 16 is already connected to the outlet shaft 3. In this case, the wings 10 'and 10 " are no longer in alignment. Such a cellular wheel 5 can optionally be inserted into a conventional housing 1 which can only be modified slightly.

Of course, it is also possible to provide further chamber dividing plates 15 analogously to FIGS. 5 and 6.

In the embodiment according to FIG. 9, the compressed gas is fed via the compressed gas connection 18 into a channel 22 which is located in a web 23 arranged in the outlet shaft 3 transversely to the longitudinal axis of the cellular wheel 5 and can be connected to the essentially product-free chambers 11 '. The compressed gas blows out the product-carrying chambers 11 ″ via the openings 16 .

The invention is not restricted to the exemplary embodiments described in detail. In particular, it also includes cellular wheels of a non-cylindrical, for example conical shape. The wings also do not have to run in the direction of the generatrix of the cellular wheel, but rather can also be designed obliquely or arrow-shaped. Furthermore, the location of the Compressed gas connection can be carried out very differently.  

Reference list

1

casing

2nd

Inlet shaft

3rd

Outlet shaft

4th

Housing bore

5

Cell wheel

6

wave

7

camp

8th

Side cover

9

Sealing element (for shaft)

10th

wing

11

chamber

12th

Flanged wheel

13

Sealing element (for flanged wheel)

14

Annulus

15

Chamber divider

16

opening

17th

Projection (in the inlet shaft)

18th

Pressurized gas connection

19th

Projection (in the outlet shaft)

20th

Vent

21

Footbridge (in the inlet shaft)

22

channel

23

Footbridge (in the outlet shaft)

Claims (9)

1. rotary valve for conveying or dosing bulk material, comprising a housing ( 1 ) with an inlet shaft ( 2 ), an outlet shaft ( 3 ) and a in a housing bore ( 4 ) by means of a shaft ( 6 ) rotatably mounted cell wheel ( 5 ), the substantially radially extending wings ( 10 ) in conjunction with disk-shaped chamber dividing plates ( 15 ) arranged coaxially to the cell wheel form a multiplicity of chambers ( 11 ), of which at least one group of chambers ( 11 ') adjoining a chamber dividing plate prevents bulk material from entering the chamber Inlet shaft can be covered and communicates via openings ( 16 ) in the chamber dividing plates with the bulk material-carrying chambers of the cellular wheel, characterized in that this group of chambers ( 11 ') can be connected to a compressed gas connection ( 18 ). 2. rotary valve according to claim 1, characterized in that the openings ( 16 ) are arranged in the radially inner region of the chamber separating plates ( 15 ). 3. rotary valve according to claim 2, characterized in that the openings ( 16 ) consists of a radial spacing between the shaft ( 6 ) and the respective chamber partition plate ( 15 ). 4. Rotary valve according to one of claims 1 to 3, characterized in that a group of chambers ( 11 ') which is arranged in the center of the cellular wheel and which can be connected to the pressurized gas connection ( 18 ) adjoins a chamber separating plate ( 15 ) on both sides and through one in the inlet shaft ( 2 ) located web ( 21 ), which is oriented essentially transversely to the longitudinal axis of the cellular wheel ( 6 ), can be covered against entry of bulk material. 5. rotary valve according to one of the preceding claims, characterized in that two laterally arranged on the cellular wheel ( 5 ), with the pressurized gas connection ( 18 ) connectable groups of chambers ( 11 ') each adjoin a chamber separating plate ( 15 ) and a flanged disc ( 12 ) and can be covered against bulk material entry by means of projections ( 17 ) located on the side in the inlet shaft ( 2 ). 6. rotary valve according to one of the preceding claims, characterized in that in the outlet shaft ( 3 ) projections ( 19 ) are arranged which partially cover the chambers ( 11 ') which can be connected to the compressed gas connection ( 18 ). 7. rotary valve according to one of the preceding claims, characterized in that the wings ( 10 ', 10 ") of the chambers ( 11 ', 11 ") are aligned. 8. rotary valve according to one of claims 1 to 6, characterized in that the wings ( 10 ') of the chambers ( 11 ') connectable to the compressed gas connection ( 18 ) and the wings ( 10 ") of the fillable with bulk material chambers ( 11 ") are offset from one another in such a way that the chamber ( 11 ') which can be connected to the compressed gas connection can still be sealed over the circumference of the housing bore ( 4 ) to the outlet shaft ( 4 ), while the associated chamber ( 11 ") which can be filled with bulk material is already in the outlet shaft ( 3 ) can be emptied. 9. rotary valve according to claim 4, characterized in that the two sides of a chamber separating plate ( 15 ) adjoining group of chambers ( 11 ') via a channel ( 22 ) provided, arranged transversely to the longitudinal axis of the cellular wheel, web ( 23 ) in Outlet shaft ( 3 ) can be connected to the compressed gas connection ( 18 ).