DE20316310U1 - Dosing device has feed cells located around drive shaft in star arrangement and consist at least partially of flexible material so that in operation they are deformable during their revolving in feed chamber - Google Patents

Abstract

The dosing device comprises a feed chamber (1) located between an inlet (2) and outlet (3) opening and in which is installed a drive shaft (5). Feed cells (6) are located around the drive shaft in a star arrangement and consist at least partially of a flexible material, which may especially be a rubber-like material, plastic material, plastic compound material or a spring metal material, so that they are deformable. When in operation the feed cells during the revolving in the feed chamber are deformed at least at one point. Independent claims are also included for the following: (a) a sleeve fitted on the drive shaft and upon which the feed cells are constructed; and (b) a distribution device for a material dosing device.

Description

The invention relates to a Dosing device with an inlet opening and an outlet opening and an intermediate delivery chamber, in which there is at least one drive shaft, around which the star delivery cells are arranged, which is received at the inlet opening when the drive shaft is rotating Material, especially granular or powdered bulk, Transport viscous or mud-like material or piece goods to the outlet opening and pour out there. she relates in particular to such a metering device for construction, Agricultural and environmental technology and on a distribution device for construction, agricultural and environmental technology with such a metering device.

Another aspect of the invention is the provision of a feed cell sleeve for a dosing device of the type mentioned at the beginning.

The term "drive shaft" is used here any rod-like means of transmission a drive that drives the star-shaped cells in rotary motion to promote of the material.

Especially with conventional ones Rotary feeders have the problem that there are in the conveyor cells (also called panniers) creates material, which increases the delivery volume of the production cells decreased will and consequently the actually amount of material conveyed with the nominally set delivery rate no longer matches. this leads to for example in the case of binder distributors used for soil stabilization are used in the construction industry to ensure that too little binder gets into the ground and therefore not the expected stability of the ground is achieved.

In the German patent application 27 32 199 is a cellular wheel sluice with inflatable wheel bags described. In this the wheel bags are made using compressed air blown out to them if possible residue of the funded Bulk goods too to free. This solution is on the one hand due to the channels, hoses and Seals and installation in the rotary valve with considerable additional technical Effort connected and guaranteed to other no reliable cleaning with heavily caking materials the panniers.

The present invention lies the object of a metering device of the aforementioned Kind available to provide, during which the cleaning of the conveyor cells during the Operation is technically simple and reliable. Furthermore, a Delivery cells wreath be provided in the dosing device on technical is easily interchangeable.

These tasks are carried out by a Dosing device with the features of claim 1 and through a conveyor cell sleeve with the features of claim 15 solved.

Advantageous configurations and Further development of the dosing device and the feed cell sleeve are in claims 2 to 14 or 16 and 17 indicated.

Particularly preferred uses the metering device are specified in claims 18 to 20.

In a metering device according to the invention are the funding cells at least partially, particularly preferably completely dig of flexible material, in particular made of a rubber-like material, plastic material or plastic compound material, such that the conveyor cells - preferably while the operation of the metering device - is deformable. Is conceivable also that the production cells for example from a resilient metallic material or composite material are made.

Especially for solving conveyed from the inner walls the production cells these are preferred during of circulation in the production chamber at least at one point, in particular by means of a suitable one Installation on or in the production chamber deformed. This deformation of the delivery cells is particularly preferred when they are streaked along a wall the funding chamber, while which the funding cells bend. This is preferably done at least on the delivery chamber wall between inlet opening and outlet opening. In addition can also in other areas of the production chamber deformation of the feed cells respectively. It is also conceivable that the deformation of the feed cells essentially only takes place on their way from the outlet opening back to the inlet opening if this is already the one you want Brings effect.

Pressing the conveyor cells against a wall of the delivery chamber is preferably carried out on the basis of a corresponding shape of the Feed chamber wall, by, for example, at least in the area between inlet and outlet opening is flattened or overall an oval-like or ellipse-like Has shape. Pressing the delivery cells on a wall of the conveyor cells can also be accomplished by the axis of rotation of the drive shaft outside the longitudinal central axis a delivery chamber that is circular in cross section, so eccentric in relation to the delivery chamber runs. These two measures described can alternatively or together in the dosing device.

An alternative or additional means for deforming the conveyor cells comprises at least one web or a wedge, on which walls of the conveyor cells strike as they pass and are deformed during the further movement. Such a web or wedge is preferably arranged between the inlet opening and outlet opening adjacent to, in particular immediately in front of, the outlet opening. It is thereby achieved that the deformation of the delivery cells or a maximum deformation of the delivery cells occurs shortly or immediately before the outlet opening follows.

In a special embodiment The dosing device deforms the feed cells on their way from the inlet opening to the outlet opening and speed up the production cells after reaching the outlet opening back to its original form. The deformation of the conveyor cells between the inlet opening and preferably takes place Continuous exhaust opening to what is preferred by means of an outlet opening to the drive shaft narrowing delivery chamber is reached.

Alternatively, the rest of the Cross section circular or circular delivery chamber between inlet opening and outlet opening be flattened (preferably in the middle between the inlet and outlet opening), so that a maximum deformation in an area between the inlet opening and outlet takes place and the funding cells already on the way from the middle area to the outlet opening Move back the original shape. This makes it possible rapid deformation of the conveyor cells, the too unwanted shocks in the dosing device, in particular at the outlet opening, to lead can, as far as possible to avoid.

In a further special embodiment is the wall of the delivery chamber between inlet opening and outlet opening, on the one with the material to be conveyed filled delivery cells walk past, flexible. This can result in susceptibility to failure of foreign bodies in the conveyed good can be reduced because the wall of the delivery chamber give way locally to the foreign body can. Failure to do so may damage the delivery cells and to faulty operation or even total failure of the metering device come.

To empty the conveyor cells at the outlet opening to support can in the outlet opening a stop element may be provided which with the walls of the Conveyor cells overlap and the walls the production cells as they pass the outlet opening, causing them in the area of the outlet opening be deformed again.

Alternatively, such a stop element be the only component of the metering device, one for the detachment of Deposits in the production cell sufficient deformation of the feed cells causes. The conveyor cells remain in such an embodiment the dosing device for the rest essentially undeformed and are only as strong on the walls of the delivery chamber indicates that a sufficient sealing effect is achieved.

In a particularly preferred embodiment the feeder are the feed cells made of flexible strips that are arched or U-shaped V-shaped and star-shaped with their opening facing outwards are arranged around and attached to the drive shaft. For fastening the conveyor cells are preferably spaced around the drive shaft support strips flexible from one another arranged and attached to the drive shaft. These support strips are directed radially outwards and between two support strips is a U-shaped arch or V-shaped strip arranged, which forms a conveyor cell. The U-like or V-like strips are preferably means Vulcanizing or gluing connected with the support strips. alternative can they Strips also screwed or riveted or clamped together his.

In another advantageous embodiment are the U- or V-like strips and the support strips one piece made of flexible material, attached to the drive shaft and attached to it. Alternatively, the conveyor cells can be made on a one-piece, in particular injection molded or injection molded, sleeve formed be attached to the drive shaft or with the drive shaft firmly connected is completely manufactured. Such a sleeve has a conveyor cell wreath on, on the circumferential side with its opening facing outwards delivery cells are formed and which can be plugged onto the drive shaft. These embodiments the production cells enable advantageously a technically simple exchange of the feed cells.

The funding cells are, for example Made of rubber, fabric rubber, neoprene, fluororubber, teflon, flexible Fabric or a combination of these materials, can but also from others for the suitable flexible materials to be dosed be made.

It is also conceivable, provided that the dimensions of the metering device allow that the Delivery cells wreath and the drive shaft in one piece are made of a flexible material, for example by means of injection molding or injection presses. The required rigidity of the drive shaft and the flexibility required delivery cells can be useful here via setting corresponding material thicknesses and wall thicknesses can be achieved. This embodiment comes preferably for dosing devices with small dimensions, for example in the cm or mm range.

The inner walls of the delivery chamber can be If necessary, be provided with a sliding coating or made of material with good lubricity consist. Alternatively or additionally can the the walls the funding chamber grazing areas of the conveyor cells or the production cells overall be provided with a sliding coating or yourself made of material with good sliding properties on the chamber walls be made. All of these measures can alone or together in combination advantageously the wear on the delivery cells reduce.

In a further embodiment of the present inventions and their advantageous developments, the conveyor cells can be made of a material on which the material to be conveyed al bad or ideally not liable at all. A material that is suitable in many cases is, for example, Teflon.

Dosing devices according to the invention are suitable especially for use with distribution devices of construction, agricultural or environmental technology, such as binder distributors for Soil stabilization. Here, the metering device can be between a material outlet of a storage container and a distribution device, for example, a spreader. With the dosing device is the amount of material discharged during the operation of the distributor set. Alternatively, the metering device can be used simultaneously act as a distribution device; a separate distribution device, like a spreader, is then no longer necessary.

Further advantages, embodiments and further developments of the metering device result from the following in connection with the 1 to 14 explained embodiments.

Show it:

1 1 shows a schematic illustration of a vertical sectional view through a first exemplary embodiment,

2 , a schematic representation of a vertical sectional view through a second embodiment,

3 , a schematic representation of a vertical sectional view through a third embodiment,

4 , a schematic representation of a vertical sectional view through a fourth embodiment,

5 to 9 , schematic representations of vertical sectional views through four exemplary embodiments of a conveyor cell sleeve,

10 1 shows a schematic illustration of a vertical sectional view through a fifth exemplary embodiment,

11 , a schematic representation of a vertical sectional view through a sixth embodiment,

12 , a schematic representation of a vertical sectional view through an eighth embodiment, and

13 and 14 , schematic representations of views of the longitudinal axis of various special arrangements of conveyor cells on the drive shaft.

The figures are consistently only the for the respective embodiment essential elements shown and described. In the different embodiments are the same or equivalent components with the same Provide reference numerals.

At the in 1 The illustrated embodiment of a metering device, here a rotary valve, is a delivery chamber 1 with an inlet opening 2 and an outlet opening 3 provided in which there is a cellular wheel 4 located. The cellular wheel 4 has a drive shaft 5 on to the star-like conveyor cells 6 are arranged, the rotating drive shaft at the inlet opening 2 absorbed material, such as bulk material, viscous or mud-like material for the outlet opening 3 transport. The conveyor cells 6 are made entirely of a flexible material, such as rubber. The between inlet opening 2 and outlet opening 3 trending wall 7 the funding chamber 1 (based on the direction of rotation shown in the drawing 10 ) runs on a radius around the drive shaft 5 , which is smaller than the radius on which the end faces 8th the walls of the feed cells 6 around the drive shaft 5 run. This will cause the side walls of the feed cells 6 on the way from the inlet opening 2 to the outlet opening 3 when sanding along the wall 7 the funding chamber 1 in the direction of the arrows drawn in the figure 9 bent, creating the feed cells 6 be deformed overall.

When the outlet opening is reached 3 the funding chamber 1 speed up the production cells 6 back to their starting position. Due to the deformation and the snapback of the conveyor cells 6 may be on the inside walls of the production cells 6 accumulated material is detached, so that the conveyor cells 6 subsequently ideally again each have their nominal capacity.

The wall 7 can be provided with a sliding coating, for example made of Teflon, or made of a material with good sliding properties compared to the material of the conveyor cells, for example made of Teflon. Likewise, those on the wall 7 forehead areas 8th the side walls of the feed cells 6 be provided with such a sliding coating or the conveyor cells as a whole consist of a correspondingly lubricious material.

Instead of or in addition to the deformation of the feed cells 6 by means of the wall 7 can in the feed chamber 1 at least one web or a wedge (not shown) may be provided on the walls of the conveyor cells 6 Strike while walking past and be deformed while moving on.

The web or the wedge is preferably between the inlet opening 2 and outlet opening 3 adjacent to, in particular immediately in front of the outlet opening 3 arranged so that the or a particularly strong deformation of the feed cells 6 adjacent or immediately in front of the outlet opening 3 he follows.

The conveyor cells 6 are made of flexible strips 61 , for example made of rubber strips, which are U-shaped and star-shaped with their opening outwards around the drive shaft 5 arranged around and attached to this. To the drive shaft 5 around are spaced apart flexible support strips 60 arranged and associated with on the drive shaft 5 attached mounting plates running radially outwards 50 are attached. Between two support strips 60 is a U-like ge arched stripe 61 is arranged, together with the neighboring support strips 60 one funding cell each 6 formed.

The U-like arched stripes 61 are with the adjacent support strips 60 by vulcanizing or gluing to a conveyor cell sleeve 62 (compare 5 ) connected to the drive shaft 5 is attachable. Alternatively, the support strips 61 and the U-like arched stripes 61 , as in 4 indicated, be connected by means of screws or rivets or by means of clamps.

Alternatively, the conveyor cells 6 in a one-piece injection-molded or injection-molded conveyor cell sleeve 62 (compare the 6 and 7 ) be formed on the drive shaft 5 is attachable. Possible materials are given above in the general part of the description.

Alternatively, the conveyor cells 6 in one piece from a flexible layer 63 be produced, the meander-like or star-like around the drive shaft 5 placed and is connected to this, for example by means of vulcanization. Compare the 8th and 9 , Such a meandering or star-like conveyor cell ring can be produced separately in one piece and subsequently plugged onto the drive shaft and connected to it.

It is also possible to form a plurality of flexible strips into a star-like conveyor cell ring as shown in 8th is shown to form the drive shaft. The flexible strips can be connected to one another, for example by means of vulcanization or by means of another suitable technique. Such a conveyor cell ring can also be fastened to the drive shaft, for example, likewise by means of vulcanization or by means of adhesive. But it is also conceivable to fasten the drive shaft by means of screws, rivets, clamps or the like. Such a star-like conveyor cell ring can also be produced separately in one piece and subsequently plugged onto the drive shaft and connected to it.

That in the 2 The second exemplary embodiment shown differs from that in connection with 1 described in particular in that

• - the inlet opening 2 and the outlet opening 3 not exactly across the conveyor chamber 1 are arranged and
• - the distance between the wall 7 and the drive shaft 5 in the course of the outlet opening 3 reduced.

This in 3 The illustrated embodiment differs from the previously described embodiments in particular in that in the outlet opening 3 a stop element 11 is provided with the support strips 60 the production cells 6 overlaps and to which the support strips 60 during operation of the metering device, causing the delivery cells in the area of the outlet opening 3 be deformed again.

In the embodiment according to 10 the delivery chamber wall between the inlet opening and outlet opening is angular. The result of this is that the conveyor cells are alternately deformed more and more weakly on their way from the inlet opening to the outlet opening, and thus an improved detachment of accumulated material can be achieved. In addition, such a configuration of the delivery chamber is technically simple to implement. As an alternative or in addition, the conveying chamber wall can also be angular in a region other than the above-mentioned between the inlet opening and the outlet opening.

The embodiment according to 11 shows another way of how the feed cells can be deformed. Fasteners protrude here 51 for the conveyor cell ring in the drive shaft 5 into which, during rotation of the drive shafts, one or more stop or deflection elements 52 attacks. Of course, other elements can also be provided in or on the drive shaft, which cause the fastening element to deflect out of its rest position.

This in 12 The illustrated embodiment differs from the previously described embodiments in the arrangement of the inlet and outlet openings and is intended to clarify that the arrangement of the inlet and outlet openings can be designed as desired within the scope of the present invention.

The feed cells do not necessarily have to be parallel to the axis of rotation of the drive shaft 5 extend, but can, as in 13 indicated, run obliquely to this axis of rotation. Likewise, as in 14 indicated, several conveyor cell elements can be arranged side by side on a drive shaft. Both embodiments or combinations thereof fall within the scope of the present invention, as well as other expedient variants, such as, for example, a wavy course of the conveyor cells along the axis of rotation of the drive shaft.

Conventional devices such as an electric motor can be used as the drive means for the drive shaft. Alternatively, the cellular wheel 4 by being placed directly on the ground over which the metering device is moved, for example in the case of trailing spreading devices.

The dosing devices described in the exemplary embodiments can preferably be used in construction, agricultural or environmental technology distribution devices, for example in binder distribution devices. Here there are the problems outlined above of the accumulation of material on the inner walls of the cell, in particular in the case of high atmospheric humidity or prolonged downtimes of the distribution device. The metering device can be between a Ma material outlet of a material storage container and a distribution device, for example, a spreader, or even act as a distribution device, in the example, act as a spreader. The metering device feeds the distribution device an adjustable, predetermined amount of material, so that, for example, an amount of binding agent required for the desired soil stability is reliably and very precisely transported through the metering device.

Dosing devices of the general Part of the description and explained in the exemplary embodiments Kind can be taken for granted not only used in the field of binder distributors, but are everywhere there Can be used where it is particularly important to the exact amount of the Dosing device discharged amount of bulk material, mud-like or viscous material, general cargo or the like arrives and / or the material to be conveyed tends to the production cells to put on or wedge. One example is to think to the food industry, the chemical industry, the pharmaceutical Industry and the ceramics industry.

Claims (20)

Dosing device with an inlet opening and an outlet opening and a delivery chamber arranged in between, in which there is at least one drive shaft, around which star-shaped feed cells are arranged, which, when the drive shaft rotates, transport material received at the inlet opening to the outlet opening, characterized in that the feed cells at least partially a flexible material, in particular from a rubber-like material, plastic material, plastic compound material or from a resilient metallic material, are made such that they are deformable. Dosing device according to claim 1, characterized in that the conveyor cells operate while of circulation in the delivery chamber at least deformed at one point. Dosing device according to claim 2, characterized in that the production cells are designed in such a way that they start at their stripes a wall of the delivery chamber be deformed. Dosing device according to claim 3, characterized in that the walls of the cells between inlet port and outlet opening on a delivery chamber wall graze so that the production cells be deformed. Dosing device according to claim 2 or 3, characterized characterized in that the delivery chamber wall at least in a partial area is designed so that the conveyor cells when passing this section alternately stronger and less deformed become. Dosing device according to one of the claims 2 to 5 , characterized in that at least one web or a wedge is provided in the conveying chamber, on which walls of the conveying cells strike as they pass and are deformed during the further movement. Dosing device according to claim 6, characterized in that the web or the wedge is adjacent between the inlet opening and outlet opening for, in particular immediately before the outlet opening, so that the or a particularly strong deformation of the feed cells adjacent or immediately before the outlet opening he follows. Dosing device according to at least one of claims 2 to 7, characterized in that a deformation of the feed cells on their way from the inlet opening to the outlet opening takes place, in particular continuously between the inlet opening and outlet opening increases, and the production cells when passing the outlet opening snap back to its original shape. Dosing device according to at least one of claims 1 to 8, characterized in that the conveyor cells made of flexible strips are made, which, preferably U-shaped or V-shaped, star-shaped are arranged around and attached to the drive shaft. Dosing device according to claim 9, characterized in that that flexible around the drive shaft spaced apart support strips arranged and attached to the drive shaft, the radial or aslant run outwards, and that between two support strips a U-like arch or V-shaped strip is arranged, which is a conveyor cell formed. Dosing device according to claim 10, characterized in that the strips are associated with support strips by means of vulcanizing or gluing or by means of other known appropriate connection techniques are connected. Dosing device according to claim 10 or 11, characterized characterized in that the strips and the associated support strips from one piece are made of flexible material and attached to the drive shaft and connected to it. Dosing device according to at least one of the preceding Expectations, characterized in that the feed cells on an integral injection molded Sleeve formed are, which is attached to the drive shaft. Dosing device according to at least one preceding one Expectations, characterized in that a longitudinal direction of the delivery cells not parallel to the axis of rotation of the drive shaft. Delivery cell sleeve for Use in a metering device according to at least one of the Expectations 1 to 14, which is a conveyor cell wreath has, on the circumferential side with its opening facing outwards delivery cells are formed and on the drive shaft of the metering device can be mounted, in particular plugged on. Delivery cell sleeve for Use in a metering device according to at least one of the Expectations 1 to 14, which is a conveyor cell wreath has, on the circumferential side with its opening facing outwards delivery cells are formed and which consist of at least one flexible strip, is made in particular from rubber strips that are vulcanized are interconnected in such a way that they form the conveyor cell ring form. Delivery cell sleeve after Claim 15 or 16, in which the conveyor cell ring is made in one piece is made of flexible material, in particular injection molded or is injection molded. spreader for the Construction, agricultural and environmental technology with a material storage container that comprises a material outlet, which is followed by a material metering device is characterized in that the material metering device has at least one metering device according to one of the claims 1 to 14 comprises. spreader according to claim 18, characterized in that the material metering device Distribution device, in particular a spreader, is arranged downstream. spreader according to claim 18, characterized in that the material metering device simultaneously is used as a distribution device, in particular as a spreader.