DE19839738C1 - Conveyor scoop pump for cohesive fluids - Google Patents

Abstract

The fluid feed pump has a casing (1) with a inlet (2) and outlet (3) for the fluid separated by a chamber (4) for a rotary scoop wheel (5) defining cells (6). The cells are lined with a flexible material which retracts when aligned with the outlet to separate the fluid from the wheel.

Description

description

The invention relates to a cellular wheel sluice for conveying or dosing bulk material from a housing with an inlet opening for the bulk material, an outlet opening for the Bulk material and a cell wheel rotatably mounted in a bore of the housing with a A plurality of chambers, which are essentially radially extending from each other are separated and their volume depending on the position of the cellular wheel in the housing is changeable.

State of the art

A generic rotary valve is described in published patent application DE 29 36 324 A1 disclosed. In this known lock, a is above the individual chambers of the cellular wheel elastic hose arranged by applying a vacuum in the bottom of the chambers is sucked in, so that these are available for receiving bulk goods and via the Inlet opening can be filled.

When the outlet opening is reached, the hose is opened by applying compressed air Chamber bottom lifted off, which reduces the volume of the chamber and its contents in the Discharge opening emptied, the hose being stripped over an edge of the housing.

Although this device is suitable, it is also suitable for sticky and poorly flowing bulk materials ejecting has the disadvantage that the hose is subject to considerable wear is subject. In addition, the construction of the lock is very complex.  

task

The invention is therefore based on the object, the known device in the To develop further in such a way that the wear and the design effort are reduced.

solution

The object is achieved in that means are provided, the volume of Enlarge chambers when reaching the outlet opening.

The bulk material located in the relevant chamber is therefore not, as from the state of the Known technology, pushed out of the chamber, but falls out of the chamber when the volume of the same increases. A lock equipped in this way is therefore also suitable for conveying or dosing cohesive bulk goods that tend to, according to the Filling the chambers to form a bulk plug corresponding to the contour of the chamber, which can no longer be completely removed from the chamber without additional measures.

By increasing the chamber volume, the adhesion between bulk material and Wall of the chamber reduced so far that the bulk plug under the influence of Gravity releases from the chamber communicating with the outlet opening and is discharged becomes.

Additional measures for emptying the chambers, for example blowing in compressed air, are therefore usually not required. Basically, their application is not in the Contradiction to the present invention.

The webs and / or the bottom of the chambers point in a cellular wheel according to the invention preferably locks deformable walls, which are created by applying a vacuum or Overpressure on the relevant side of the wall can be spaced from the bulk material filling, to detach the bulk material from the wall in the desired manner. In the latter case, Enlargement of the chamber volume according to a particularly advantageous embodiment of the Invention cause that the webs and / or the bottom of the chambers with a kompri  mable coating are provided, which are compressed under the influence of overpressure becomes.

Such a coating preferably consists of a foamed elastomeric material, For example, foamed EPDM or silicone rubber and can be used with a compact layer made of an abrasion-resistant material that is inert to the bulk material be covered.

characters

The figures represent examples and schematically of various designs according to the invention Cellular wheel locks.

Show it:

Fig. 1 shows a longitudinal section through a rotary valve according to the invention

Fig. 2 is an enlarged view of a chamber of FIG. 1 with deformed walls

Fig. 3 shows a longitudinal section through a rotary valve according to a further embodiment of the invention

Fig. 4 is an enlarged view of a chamber of FIG. 3 with a compressed coating

The cellular wheel sluice shown in FIG. 1 comprises a housing 1 with an inlet opening 2 and an outlet opening 3 . A cell wheel 5 is rotatably mounted on an axis 10 in a bore 4 of the housing 1 . It is set in rotation in the direction of arrow 11 via a known drive, not shown. The cellular wheel sluice takes the bulk material from an indicated silo 12 and feeds it into a likewise indicated pneumatic conveying line 13 .

The cellular wheel is hollow in the region of the radially outwardly extending webs 7 and the base 8 of the chambers 6 as well as the axis 10 , the cavities in the cellular wheel and in the axis via an axis-side opening 14 and cell-wheel-side openings 15 depending on speed the position of the cellular wheel can communicate with each other. The openings 14 , 15 are arranged in such a way that they are connected to each other when one of the chambers 6 reaches the outlet opening 3 .

A vacuum is continuously applied to the hollow axis 10 of the cellular wheel sluice, which is transferred via the openings 14 , 15 to the cavities in the cellular wheel 5 . The deformable, comparatively thin stainless steel sheet made walls 9 of the webs 7 , as can be seen in FIG. 2, are spaced apart from the bulk material filling, which subsequently falls out of the chamber in the form of a wedge-shaped bulk material plug 16 . Partitions 17 are arranged in the hollow cellular wheel 5 in such a way that only the walls of the chamber 6 , which faces the outlet opening 3, deform. When the cell wheel 5 rotates further, air enters the associated cavity of the cell wheel 5 via a gap 18 under ambient pressure, so that the volume of the chamber is reduced to the initial size.

Fig. 3 shows another embodiment of the invention, in which the essentially non-deformable webs 7 and the base 8 are provided with a compressible coating 19 , which in the exemplary embodiment is covered with a thin layer of an abrasion-resistant material 20 . Under the influence of an overpressure in the pneumatic delivery line 13 , the compressible coating 19 is compressed so that the volume of the chamber 6 connected to the outlet opening 3 increases, as shown in FIG. 4. Again, the bulk plug 16 is discharged from the chamber only under the influence of gravity. The bulk plug 16 is replaced by a corresponding volume of tensioned gas, which is then expanded via a vent opening 21 located in the housing 1 . In this way, the chambers 6 return to their original size.

Reference list

1

casing

2nd

Inlet opening

3rd

Outlet opening

4th

drilling

5

Cell wheel

6

chamber

7

web

8th

Bottom of the chamber

9

deformable wall

10th

axis

11

Arrow (direction of rotation)

12th

silo

13

pneumatic conveyor line

14

Opening (axis side)

15

Opening (cell wheel side)

16

Bulk plug

17th

partition wall

18th

gap

19th

compressible coating

20th

abrasion resistant material

21

Vent

Claims (7)

1. rotary valve for conveying or dosing bulk material, consisting of a housing ( 1 ) with an inlet opening ( 2 ) for the bulk material, an outlet opening ( 3 ) for the bulk material and a rotatably mounted in a bore ( 4 ) of the housing ( 1 ) feeder are separated with a plurality of chambers (6) by radially extending substantially webs (7) (5) and whose volume is variable in dependence on the position of the cell wheel (5) in the housing (1), characterized in that that means are provided to increase the volume of the chambers ( 6 ) when reaching the outlet opening ( 3 ). 2. rotary valve according to claim 1, characterized in that the webs ( 7 ) and / or the base ( 8 ) of the chambers ( 6 ) have deformable walls ( 9 ). 3. rotary valve according to claim 2, characterized in that the deformable walls ( 9 ) by applying a vacuum on the side facing away from the bulk material filling of the walls of the bulk material filling of the chamber ( 6 ) can be spaced. 4. rotary valve according to claim 2, characterized in that the deformable walls ( 9 ) by applying an overpressure on the side facing the bulk material filling of the walls ( 9 ) from the bulk material filling of the chamber ( 6 ) can be spaced. 5. rotary valve according to claim 4, characterized in that the walls ( 9 ) of the essentially non-deformable webs ( 7 ) and / or of the essentially non-deformable base ( 8 ) of the chambers ( 6 ) with a compressible coating ( 19 ) are provided. 6. rotary valve according to claim 5, characterized in that the compressible coating ( 19 ) consists of a foamed elastomeric material. 7. rotary valve according to claim 5 or 6, characterized in that the compressible coating ( 19 ) is coated with a layer of an abrasion-resistant material ( 20 ).