DE3626696C2 - - Google Patents

Description

The invention relates to a rotary valve with an inlet funnel, an allocation organ and one via a feed chute arranged cellular wheel according to the preamble of claim 1.

Cell locks for the discharge from fine to with telegrained bulk goods made of pressure shock-resistant silos belong to the state of the art. Bulk goods with a Grain that is larger than 40 mm can, however, with the known versions of cell locks only are conditionally carried out.  

From DE-AS 12 02 721 is - apart from the lack of suitability for the promotion of large pieces Bulk goods - a rotary valve according to the generic term of claim 1 known. The upstream of the cellular wheel Allotment member of this known rotary valve is also designed as a cellular wheel. When passing through of elongated coarse parts, e.g. B. briquettes, can the parts upright in the cells of the Allotment organ piled up and over the cell wall stand out from the outside. When rotating the metering organ exists the disadvantage that the parts when approaching the Broken inner wall of the rotary valve housing and lead to canting and jamming.

From the US-PS 15 42 732 is a rotary valve with known as a single rotating wheel. In the Feed shaft to this wheel under the inlet funnel an adjustable weir is arranged.

In JP-PS 53-57 661 is a rotary valve with a cellular wheel and one upstream of it Cell wheel as a feeder for feeding powdered Material revealed. The waves of the two cellular wheels are connected by a common gear transmission coupled.  

DE-OS 30 05 241 is another cellular wheel known lock that in the feed shaft for the Cell wheel an allocation device with at least one with a larger number of radial cell walls provided allocation cell wheel. To the problem to solve that nothing of the good between the ver relatively large circumferential surfaces of the cellular wheel and the inner surface of the lock housing can, is suggested in the cited publication gene to intermittently turn on the allocation device drive that the good trickling out of it only in the respectively released cell opening and not on reaches the peripheral walls of the cellular wheel. This is however, a significant control and regulation effort required, with no ultimate certainty Unit can be prevented that the allocation device  also outside of the standstill times of the tent lenrades due to leaks in the conveyed material lets through. There is also a risk that the component Cell wheel itself jammed when material to be conveyed between the metering wheel chamber walls and the housing inner wall the cell lock.

From DE-AS 26 38 778 is also a cellular wheel lock with an eccentric to the axis of the Axis of the inlet chess lying in the lock inlet known. The cells of the cellular wheel are thus located not directly under the silo outlet, the mentioned device can still not prevent that coarse material between the cell edge and the edge of the housing comes and thus the cellular wheel blocked. In addition, the cellular wheel must be very powerful built and with an excessively strong drive be prepared. The wear on the cells and the The housing leading edge is still very high.

EP 00 82 947 A1 also describes the task to create a device by a be special unicellular rotor cavity construction in Connection with high rotor acceleration and a dosed part quantity from the unlocked rotor No bulk material from the cavity during the rotation Cavity come out between the rotor and housing lets and thus the use of adjacent sliding seal tions as an atmosphere closure. The on gift is solved in that at a dosed Partial quantity through a lightning fast half turn hung the rotor through a gap is separated from the inner wall of the cell that the The rotor then reaches the emptying position and with its wall the discharge seal hidden before the goods are discharged  Reach the seal, destroy it and block the rotor can. This device also has the disadvantage constructively or control-technically complex be.

Finally, simpler solutions are also available been hit, such as B. according to DE-GM 19 93 480 a rotary valve a scraper in front whose area the cellular wheel should have. These Squeegee is designed to prevent individual grains of the bulk material in the gap between the cell wall and conveyor wall of the sluice inlet be pinched and broken. For even Dosage of the material to be spread under consideration Cleaning losses are checked in the DE-PS 30 16 832 also proposed that after the Conveying or dosing stripped Reini loss of the metering device and / or Feeding organs to feed.  

From DE-PS 11 67 764 a non-generic arrangement with a combined racket and beater wheel mill for the ready-to-use preparation of coal sludge is known, in which the beater plates of the beater wheel, which essentially also serves as a discharging impeller, can be replaced. However, these impact plates have the task of generating an air and gas flow and breaking up larger, sticking particles conveyed therein.

It is an object of the present invention To create a device of the type mentioned at the outset, which became known in the prior art which avoids disadvantages, constructively simple is built and with the smallest possible tax or Regulation effort can be operated.  

This task is carried out in the characterizing part of the Features described claim 1 solved. The Allotment roller represents a particularly simple and effective training of the allocation organ. In Connection with the carrier bars allows the Allotment roller has a good alignment, especially elongated Bulk goods parts and has a jamming and jamming effect opposite.  

Tilting of the feed roller is further caused by a adjustable weir on the inlet funnel thereby ver avoided that only certain amounts depending on the speed of rotation of the metering device can be entered into the rotary valve, namely just as much as through the metering roller transported without the risk of overfilling that can.

Those are preferred Driver strips of the metering roller in three or three sections quadrangular and after further training the invention carried out arrow-shaped, d. H. they run from Edge towards the center of the feed roller under one - based on one level the axis of the feed roller - acute angle towards each other. Through this arrow shape the material to be conveyed is consciously directed to the center of the roller where it is ultimately hanging in the angled niches remains and after further rotation of the roller through the own weight falls on the cellular wheel.

Locking the zel is particularly preferred Lenradschleuse outlet or inlet. For this there is a distance between the carrier strips and the inner wall of the cells wheel lock housing chosen to be as small as possible  is, at any rate, smaller than the mean diameter of the conveyed goods to be smuggled. The distance the radial cell walls of the cell wheel to the inner wall of the cell lenradschleusengehäuses is more pressure-resistant for the purpose Sealing as small as possible.

After a development of the invention Cell wheel designed so that at least two cam formed by the radial cell walls on each side of the cellular wheel to the material to be conveyed the outlet or the inlet are closed. This provides a good seal of the Cell lock.

An advantageously easy to carry out För stretching can be accomplished that the cross section of the rotary valve for För dergutaustrag is expanded, preferably there that the width of the cellular wheel is larger than the width of the allocation organ.

In the present invention, the ingredients roller and the cellular wheel either with a ge be provided common drive, with a corresponding gear gradation also different Speed of the feed roller and the cell frame are adjustable, or the feed roller and the cell wheel are driven separately, but geared like that locked together that both wheels are always ge run together. The latter measure prevents changes that certain chambers or cell sections be overloaded when the cell wheel is at a standstill.

An opposite direction of rotation of the feed roller and the cellular wheel effectively prevents blockage ren of the cellular wheel.  

The distance between the allocation organ and the Cell wheel should be dimensioned so that elongated Conveyed goods are not the largest width gets stuck. Because the delivery volume flow of the cellular wheel is always significantly larger than the volume flow through the overlying feed roller, can only stand upright pieces survive. However, these are countered by the additional or the same direction of rotation of the two Wheels tipped into the cells, causing a blockage of the cellular wheel is prevented.

So that the rotary valve for different Conveyed goods can be used, it is preferred with an adjustable speed drive.

The offset rollers of the feed roller and cell wheel (vertical axis shift) for changes just like the measure described above took that no material to be conveyed between the cell wheel walls and the inside wall of the housing.

An embodiment of the invention is in the Drawings shown. It shows

Fig. 1 and 2, a rotary valve in two different cross-sectional views ver and

Fig. 3 shows another embodiment of a rotary valve in cross-sectional view.

The rotary valve shown in Fig. 1 to 3 essentially consists of a feed hopper 1, which is a chute hopper at the same time and on which material to be conveyed is input in a common housing 9 of the cellular wheel sluice, the roller is a metering 2 and an underlying feeder 3 involves. After passing through the common housing 9, the material to be conveyed leaves the rotary valve via the material discharge 10 . The inlet funnel 1 is arranged in such a way that the material to be conveyed is given up to the calipers formed by the verti formed by the axis 13 of the metering roller 2 . The volume flow of the material to be conveyed can be regulated by an adjustable weir 4 .

The coarse material to be conveyed falls on the jacket of the feed roller 2 , which is equipped with driver strips 8 , which are square in cross section. The arrow-shaped arrangement of the driver strips 8 can be seen in FIG. 2. Due to the rotation of the feed roller 2 , the lumpy conveyed material is conveyed through the shaft 7 to the interior of the cell wheel sluice and falls into one of the eight chambers 12 of the cell wheel arranged below the feed roller. The chambers 12 are formed by radial cell walls 11 and a shield 14 placed on each end. The directions of rotation of the partial roller 2 and the cellular wheel 3 are in opposite directions.

With this arrangement, the metering roller 2 assigns the cell wheel 3 underneath such a metered bulk material volume flow that the individual cell chambers 12 are not overfilled, in practice a filling level below 80% is achieved, and thus a jamming of coarse material between the cell wheel 3 and the housing edge 6 , which is formed by the lacing of the common housing 9 , excluded. The speeds of the feed roller 2 and cell wheel 3 are preferably selected differently in order to prevent the cells from overfilling. The adjustable weir is used to adapt the flow För dergutstromes to the natural slope angle of the bulk material and thus prevents the bulk material from falling automatically into the inlet shaft 7 . The weir opening is selected so that jamming of the bulk material is avoided and the natural slope angle closes the bunker. The common housing 9 is formed in the area of the cellular wheel so that at least two chambers 12 on each side to the conveyed material discharge 10 and the inlet funnel ter 1 are closed. This results in a good seal.

The weir 4 is advantageously in front of the vertical right axis of the shaft of the feed roller 2 .

The formation of the driver strips in relation to the direction of rotation can be seen in FIG. 2. The arrow tip is counter to the direction of rotation, so that the material to be conveyed is automatically directed from the edge of the feed roller 2 into the center. The metering roller 2 and the cellular wheel 3 have a common drive 5 which drives the shafts 16 and 17 of the metering roller 2 and the cellular wheel 3 via a gear transmission 15 . The drive 5 is a slip-on drive unit.

While the material to be conveyed is directed to the center by the arrangement of the driver strips 8 in the metering roller, the bottom 18 of the cellular wheel chambers 12 is slightly raised in the middle, so that the material to be conveyed is pushed outwards. This ensures that the material to be conveyed is discharged as evenly as possible via the conveyed material discharge.

The embodiment according to FIG. 3 differs from the cellular wheel sluice described above in that the axes 13 and 19 of the metering roller 2 and the cellular wheel 3 are offset vertically.

The rotary valve according to the invention can both for filling a silo with coarse-grained Bulk as well as for the discharge of coarse-grained Bulk goods from the same pressure-shock-proof silo be used.

Claims (15)

1. Rotary feeder with an inlet funnel, a rotating feeder and a feeder downstream of the feeder, especially for the conveyance of coarse bulk goods, the delivery volume flow of the feeder being greater than the volume flow conveyed by the feeder, characterized in that the feeder as feeder roller ( 2 ) is formed with replaceable wear-resistant carrier strips ( 8 ) located directly on their cylinder jacket. 2. rotary valve according to claim 1, characterized in that the inlet funnel ( 1 ) has an adjustable weir ( 4 ). 3. rotary valve according to claim 1, characterized in that the driver strips ( 8 ) are triangular or quadrangular in cross section. 4. rotary valve according to one of claims 1 to 3, characterized in that the Mitnehmerlei most ( 8 ) are arrow-shaped, ie from the edge to the center of the metering roller ( 2 ) under one - based on a plane through the axis ( 13 ) of Alloting roller ( 2 ) - acute angle to run towards each other. 5. rotary feeder according to one of claims 1 to 4, characterized in that the distance between the driver strips ( 8 ) to the inner wall of the rotary feeder housing ( 9 ) is as small as possible, in any case smaller than the average diameter of the conveyed goods. 6. rotary valve according to one of claims 1 to 5, characterized in that the cellular wheel ( 3 ) has a plurality of radial cell walls ( 11 ), the distance from the inner wall of the rotary valve housing ( 9 ) for the purpose of pressure shock resistant sealing is as small as possible. 7. rotary valve according to claim 6, characterized in that in each case at least two through the radial cell walls ( 11 ) formed chambers ( 12 ) on each side of the cellular wheel ( 3 ) to the delivery outlet ( 10 ) or to the inlet are closed ge . 8. rotary feeder according to one of claims 1 to 7, characterized in that the cross section of the rotary feeder housing ( 9 ) extends to the discharge of material ( 10 ). 9. rotary valve according to claim 8, characterized in that the width (b) of the cellular wheel ( 3 ) is greater than that (b ₁ ) of the metering roller ( 2 ). 10. rotary valve according to one of claims 1 to 9, characterized in that the metering roller ( 2 ) and the cellular wheel ( 3 ) are provided with a common drive ( 5 ). 11. rotary valve according to one of claims 1 to 9, characterized in that in separate drives, the metering roller ( 2 ) and the cell wheel ( 3 ) are locked with each other so that both always run together. 12. rotary valve according to one of claims 1 to 11, characterized in that the metering roller ( 2 ) and the cellular wheel ( 3 ) run in opposite directions. 13. rotary valve according to one of claims 1 to 12, characterized in that the cellular wheel ( 3 ) and the metering roller ( 2 ) have a distance from each other, which is greater than the greatest width or the maximum diameter of elongated pieces to be passed through. 14. rotary valve according to one of claims 1 to 13, characterized in that the speeds for the cellular wheel ( 3 ) and the metering roller ( 2 ), also with each other, are adjustable. 15. rotary valve according to one of claims 1 to 14, characterized in that the metering roller ( 2 ) and the cellular wheel ( 3 ) are arranged in different positions to each other (vertical axis displacement).