DE202019000426U1 - Dosing unit with a rotary driven cellular wheel and distribution machine with such a dispenser unit - Google Patents

Abstract

Dosing unit (100) for dosing flowable solid particles, with a dosing housing (101) which has at least one inlet (102) and at least one outlet (103), and with at least one rotary-driven cellular wheel (104) mounted in the dosing housing (101) with a plurality of cell walls (105) which extend essentially radially and delimit the cells of the cell wheel (104) in the circumferential direction, two adjacent cell walls (105) being connected to one another in the region of their radially inner ends by means of a cell base (106), characterized in that the cell bottoms (106) of the cell wheel (104) are formed by resiliently flexible membranes (107), each of which is connected to two adjacent cell walls (105) in the region of the radially inner ends and one each radially on the inside of a respective one Reach over the membrane (107) arranged cavity (108).

Description

The invention relates to a metering unit for metering flowable solid particles, with a metering housing which has at least one inlet and at least one outlet, and with at least one rotary-driven cellular wheel mounted in the metering housing with a plurality of essentially radially extending cells and the cells of the cellular wheel in the circumferential direction delimiting cell walls, wherein two adjacent cell walls are connected to each other in the area of their radially inner ends by means of a cell bottom. The invention further relates to a distribution machine which comprises at least one such metering unit for metering flowable solid particles and at least one distributor element arranged downstream of the metering unit for distributing the solid particles metered by means of the metering unit onto or into the soil.

Dosing units of this type with one or more cellular wheels or cellular wheels mounted in a metering housing are known from the prior art and are used in a wide variety of fields of application wherever powder and / or particulate solids are to be metered. In this context, filling and packaging machines and systems for compiling the desired recipes from a plurality of such flowable solids may be mentioned as examples, such as those used in the construction, food and luxury goods industries, in the chemical, biochemical and pharmaceutical industries or in the plastics industry Get involved.

A particular area of application of generic metering units is in distribution machines, in particular for agricultural purposes or in the form of winter service spreaders, the flowable solids to be metered in the former case being primarily fertilizers and / or seeds, but also various crop protection agents, while the flowable solids in the latter case are usually formed by grit, sand, road salt and the like. Agricultural spreading machines are used in particular in the form of pneumatic spreading machines, such as, for example, pneumatic seeders, seed drills and pneumatic fertilizer spreaders, so-called fan spreaders, but also, for example, in the form of disc fertilizer spreaders. They exist on the one hand in a lightweight design as attachments which can be coupled to the three-point of a tractor, such as a tractor, on the other hand they can be placed on a axle-supported trailer or a self-propelled vehicle in a heavy design. While disc fertilizer spreaders each have a distribution element arranged downstream of a respective metering unit in the form of a rotary-driven distributor disc provided with throwing vanes, pneumatic distribution machines usually comprise one or a plurality of laterally projecting outriggers which accommodate distribution lines which end at different distances from one another. A blower is used to convey the flowable solids, the pressure line of which opens into a pressure distributor, to which several distributor lines are connected. Transfer chambers arranged between the pressure distributor and the distribution lines, which can be equipped, for example, with injectors, serve to transfer the flowable solids from a respective metering wheel to the distribution lines, in order to ensure that each distribution line is fed with the amount of solids which is connected to the distribution line Distribution organ to be deployed. Alternatively, only one delivery line can lead to the outlet of a respective metering unit, which leads into or into a respective distributor head, from which a plurality of distributor lines branch off. The flowable, powdery and / or particulate solids are finally conveyed pneumatically via the outwardly deflected distribution lines to the end where they strike distribution elements, which are usually formed by baffle plates or coulters, and from there essentially fan-shaped (in the case of Baffle plates) or roughly linear (in the case of coulters) on the ground or in a furrow created in the ground. The main advantage of pneumatic spreaders compared to disc spreaders equipped with distributor disks is that they can achieve a more uniform distribution over a larger spreading width. Such a pneumatic spreader is for example from the DE 10 2004 030 240 A1 known.

For metering the flowable solids, such as, for example, essentially powder and / or particulate seeds and / or fertilizers or, if appropriate, also other granules, for example for plant protection, in addition to metering slides, such as are used primarily in disc spreaders, have been used in particular in generic distribution machines Dosing units of the type mentioned at the outset with rotationally driven metering wheels in the form of cellular wheels or also cam wheels, which are usually mounted in a metering housing with an inlet arranged on its upper side and an outlet arranged on its lower side, have proven successful. Depending on the distribution material used, the metering wheel can be configured, for example, essentially in the form of a cellular or cam wheel, which should expediently be interchangeable in order to be able to take into account different types of the flowable solids to be metered. The metering wheel can be one, two or even have several metering wheel elements which are driven together or independently of one another (cf. for example the DE 10 2017 005 094 A1 ). By changing the speed of rotation of the metering wheel or a respective metering wheel segment thereof, the metering quantity of the solid particles enriched in the cam troughs of a cam wheel arranged between the cells of the cell wheel or in the cam valleys arranged between the cam mountains can be easily controlled and / or regulated.

As already mentioned, the shape of the metering wheel or its metering wheel segments should in principle be adapted to the respective (fine) particulate solid type in order to ensure correct metering with the desired mass flow. In the case of agricultural spreading machines, this is primarily due to the fact that different metering wheels are required for particulate fertilizers and for particulate, but also finely particulate, and in particular seeds that are significantly more sensitive to mechanical influences. For fertilizers, cam wheels are currently often the means of choice because the usually hygroscopic fertilizer particles tend to stick to the metering wheel and can practically not be removed by metering wheels in the form of cellular wheels, at least during operation, so that it occurs in the individual cells solid particles remaining in the cellular wheel lead to incorrect metering. By contrast, such caking can be removed from cam wheels by means of suitable cleaning devices even during operation, such cleaning devices e.g. pins which engage between the cam mountains of the cam wheel and / or between individual cam wheel segments from which the cam wheel is formed, in order to be able to “scrape” adhering fertilizer particles from the cam wheel. In contrast, metering wheels in the form of cellular wheels are the means of choice for the precise metering of seed, with different metering wheels also being able to be used for special applications, such as perforated or grooved wheels, the lateral surface of which has hole-like or, in particular, extending circumferentially, groove-shaped recesses are equipped, which can gently receive the seed to be metered.

The above-described problem of caking of the flowable solid particles to be metered in the cells of the cellular wheel arises in a corresponding manner in the case of distributors in the form of winter service spreading machines which are equipped with generic metering units, the hygroscopic character of road salt in particular intensifying this effect. In general, this is a problem inherent in the generic metering units, which, depending on the flowable solid to be metered, in particular in the case of relatively fine particulate and / or hygroscopic solids, can occur in practically all of its fields of application and leads to incorrect metering. Examples in this context are particulate building materials, such as Cement, sand or the like, all kinds of life, e.g. Milk powder, cocoa or the like, tobacco, a wide variety of chemicals and pharmaceuticals including their fillers and adjuvants and plastic granules mentioned. The caking of flowable solids in the cell wheel of the metering unit is often further increased by the fact that the solids to be metered are usually kept in stock in storage containers and are fed to the inlet of the metering unit under a sometimes considerable back pressure, so that they are compressed in the cells of the cell wheel and be agglomerated.

In practice, one tries to counter this problem with generic metering units by using cellular wheels made of resiliently elastic materials, such as various silicone or rubber compositions, whose cell walls can consequently deform elastically during operation and thus the danger reduce caking of solid particles. However, cellular wheels made of resilient materials are also unable to prevent the accumulation of solid aggregates, particularly in the cell bottoms, so that incorrect metering continues to occur.

The invention has for its object to further develop a metering unit of the type mentioned at the outset, avoiding the above-mentioned disadvantages as far as possible, in such a simple and cost-effective manner that the risk of accumulation of hygroscopic and powdery and / or particulate solids in the cells, which tends to stick the cellular wheel is banned or at least reduced compared to the prior art. It is also directed to a distribution machine equipped with at least one such metering unit.

According to the invention, this object is achieved in a metering unit for metering flowable solid particles of the type mentioned at the outset in that the cell bottoms of the cell wheel are formed by elastically flexible membranes, each of which is connected to two adjacent cell walls in the region of the radially inner ends and one each overlap radially on the inside of a respective membrane

To achieve this object, the invention provides one with at least one Dosing unit equipped distribution machine of the type mentioned above also proposes that the dosing unit is a dosing unit of the aforementioned type.

The configuration according to the invention gives the cell bottoms of the cellular wheel of the metering unit, where, according to the prior art, there is primarily agglomeration or caking of the solid particles to be metered, due to the configuration of the cell bottoms in the form of a membrane, which both inside a respective cell (i.e. approximately radially outwards) as well as in the direction of the cavity it overlaps (i.e., radially inwards), a very high elastic compliance, so that the membrane forming a respective cell floor forms during operation solely due to the rotation of the cell wheel on it acting forces and due to the forces acting during or filling a respective cell with or from the metered solid particles are always at least slightly deformed, so that initial deposits of particle aggregations are immediately released again from the membrane and nd there is no accumulation of solid particles in the cells, which could lead to incorrect dosing due to a reduction in the intended cell volume. In order to ensure the highest possible elasticity of the membranes or for the free movement of the membranes as possible, the cavities can preferably extend over substantially the entire axial length of the cellular wheel and these e.g. prevail entirely.

As is known as such from the prior art, at least the cell walls of the cell wheel or, in particular, essentially also the entire cell wheel of the metering unit can preferably also be formed from an elastically flexible material, the cell walls in particular being one that is elastically flexible relative to the cell bottoms forming the cell bottoms Membranes have less compliance, ie the cell walls are preferably more rigid than the membrane forming the cell bottoms. In this way, not only can the cell walls deform at least slightly elastically during operation in order to prevent solid particles from caking there according to the prior art, but it also results in a significantly greater deformation of the cell walls forming the cell bottoms than the more or less rigid cell walls. elastically resilient membranes are achieved because they are each connected to these in the radially inner region of two adjacent cell walls and are consequently deformed in the event of an elastically resilient deformation of one or both cell walls in order to reliably prevent caking of solid particles on the cell bottoms.

In this context, it can preferably be provided that at least the cell walls of the cellular wheel are formed from the same elastically flexible material as the elastically flexible membranes forming the cell bottoms, in particular in one piece with them, the elastically flexible membranes forming the cell bottoms in particular having a smaller thickness have than the cell walls of the cell wheel in order to give the cell bottoms a higher elastic compliance than the cell walls, ie to make the cell walls more rigid than the cell floors.

Any flexible elastomeric materials known from the prior art, such as rubber, silicone and preferably thermoplastic elastomers, e.g., come as resiliently elastic materials for the cell bottoms and also for the cell walls or for essentially the entire cellular wheel of the metering unit according to the invention. thermoplastic polyurethanes or the like, which, depending on the desired elasticity, can be used both as more or less compact materials or as, preferably closed-cell, foam materials by using plastic materials mixed with suitable physical and chemical blowing agents. The cellular wheel can then be produced using any thermoplastic or thermosetting plastic processing method, such as Injection molding, 3D printing, molding and the like.

According to an advantageous development of the metering unit according to the invention, it can be provided that the cavities of the cellular wheel arranged radially on the inside of a respective membrane forming a respective cell bottom are closed at least at their axial ends. This not only prevents any contamination of the cellular wheel due to solid particles penetrating into the cavities over a long period of operation, but also prevents any accumulation of solid particles or other contaminants that have penetrated into the cavities, which reduce the free mobility of the membrane and thus its elasticity could lead.

In this context, in particular in the case of cavities penetrating the cellular wheel over substantially its entire axial length, it can be provided, for example, that the cavities are sealed by means of a film applied to their axial ends. As an alternative or in addition, it is conceivable, for example, that the cavities are filled with an elastically flexible filler which is introduced into the cavities and has a greater flexibility than the membranes forming the cell bottoms of the cellular wheel are. In the latter case, the filler material has a very high elasticity, so that it does not form any significant resistance to deformation in order to practically not impair the freedom of movement and the elasticity of the membrane. Examples of suitable materials include, for example, highly elastic and preferably porous foams, sponges or the like.

The cellular wheel of the metering unit can also expediently have a central bore which extends in its axial direction and which serves for the rotationally fixed arrangement of the cellular wheel on a rotationally driven shaft mounted on the metering housing. For this purpose, the central bore of the cellular wheel can e.g. at least in sections have a polygonal inner profile or at least in sections accommodate a sleeve which is fixed in the bore in a rotationally fixed manner and is provided with a polygonal inner profile. The latter can, for example, be positively and / or non-positively fixed in the central bore, such a sleeve e.g. also encapsulated with a plastic material forming the cellular wheel (if it is thermoplastic and polymers, in particular thermoplastic elastomers) or can be cast (if it is thermosetting polymers, in particular in the form of elastomers).

In order - as already mentioned above - to ensure the greatest possible elastic deformation of the membranes forming the cell bottoms as a result of the greatest possible elastic deformation of the cell walls to which they are attached, during operation and in this way any caking of solid particles on the cell walls and To prevent in particular also on the cell bottoms, it can be provided, for example, that the cell walls of the cell wheel are designed with an, in particular slight, oversize in relation to the inner cross section of the metering housing, in order to deform them elastically when the cell wheel is rotated and thereby the cell bottoms connected therewith deforming membranes elastically. In view of any wear that may occur after a long period of operation, the oversize of the cellular wheel compared to the inner cross section of the metering housing should, however, only be slight, and as a rule a slight deformation of the cell walls caused by this is sufficient to prevent the cell walls from deforming during operation, primarily as a result of rotation of the Cell wheel as well as due to the filling and emptying of a respective cell with or from the metered solid particles - to increase the deformation forces acting on the membranes and thus to increase the resilient deformation of the membranes forming the cell bottoms.

As an alternative or in addition, the cellular wheel of the metering unit according to the invention can have, for example, at least one inner circumferential recess which extends completely from the longitudinal center axis of the cellular wheel to the membranes forming the cell bottoms.

Such a configuration of the cellular wheel makes it possible, in particular, for a pin to engage in the inner circumferential recess of the cellular wheel, arranged in a rotationally fixed manner with respect to the metering housing and extending essentially in the radial direction of the cellular wheel, which pin forms at least up to a respective cell bottom of the cellular wheel The membrane extends to elastically deform the membrane as the cell wheel rotates as it passes the pin. The length of the pin, which extends predominantly or more exactly in the radial direction of the cell wheel, is consequently dimensioned such that a respective membrane, which passes through the pin when the cell wheel rotates, is at least slightly elastically bent toward the interior of a respective cell, i.e. the elastic deformation of the membranes forming the cell bottoms occurs not only passively due to the deformation forces acting thereon, but also actively through elastic deformation as a result of coming into contact with the pin.

In terms of design, it can be provided for this purpose that the pin received in the inner circumferential recess of the cellular wheel extends essentially radially from the outer circumference of a support sleeve which is arranged in a rotationally fixed manner with respect to the metering housing and which is arranged, in particular, coaxially with the axis of rotation of the cellular wheel the support sleeve is rotatably received in a central bore extending in the axial direction of the cellular wheel with respect to the cellular wheel. The support sleeve can thus e.g. can be mounted in a rotationally fixed manner on or in the metering housing, so that the pin is held stationary, in contrast, the cellular wheel being freely rotatable with respect to the support sleeve.

In order to ensure simple assembly of the support sleeve provided with the pin in the central bore of the cellular wheel, so that the pin extends approximately in the radial direction inside the inner circumferential recess of the cellular wheel, the pin can, for example, between an assembly position in which it is located Is located inside the support sleeve (the support sleeve can thus simply be inserted into the central bore of the cellular wheel), and an operating position in which the pin extends essentially radially away from the outer circumference of the support sleeve (the pin can then with the during the rotation of the cellular wheel to come into contact with the membranes passing through it and to deform them elastically), can be moved back and forth, whereby it can be locked in the operating position.

In this context, the central bore of the cellular wheel can in particular be designed such that it has a polygonal inner profile at its first bore section, which extends from an axial end to the inner circumferential recess of the cellular wheel, or has a polygonal fixed in the first bore section Receives the inner profile provided sleeve, so that the first bore section serves for the rotationally fixed arrangement of the cellular wheel on a rotatably driven shaft mounted on the metering housing with a complementary outer profile, as already explained above. At its second bore section, which extends from the other axial end to the inner circumferential recess of the cellular wheel, the central bore, on the other hand, can have a circular cross section, which, in contrast, serves to rotatably accommodate the support sleeve provided with the pin.

The pin which comes into successive contact with the membranes forming the cell bottoms during operation of the cellular wheel can expediently be arranged in the region of the outlet of the metering housing, i.e. it extends in particular approximately radially in the direction of the outlet, so that a respective cell is completely emptied due to active elastic deformation of the membrane, after which the completely emptied cell can be completely refilled as soon as it passes the inlet of the metering housing after further rotation of the cell wheel.

Incidentally, it should be expressly pointed out here that the metering unit according to the invention naturally has one, two or more cellular wheels or other metering wheels, such as e.g. Can have cam wheels, of which at least one cellular wheel has the inventive design. In the case of several metering wheels, it can prove to be particularly useful if individual metering wheels, e.g. by means of suitable couplings, can be decoupled from their rotary drive or in particular each metering wheel has its own drive, so that very different metering quantities can be taken into account through different speeds of rotation up to a complete shutdown of individual metering wheels and / or different metering wheels for different types of flowable solid particles Can find use.

• 1 eine schematische Ansicht einer Ausführungsform einer landwirtschaftlichen Verteilmaschine in Form einer nach Art einer Drillmaschine ausgegestalteten pneumatischen Verteilmaschine von deren Heck aus betrachtet;
• 2 eine schematische perspektivische Ansicht der in Form eines Verteilerkopfes ausgestalteten Verteileinheit der Verteilmaschine gemäß 1 einschließlich des Auslasses einer Dosiereinheit, des Gehäuses der Übergabekammer und der pneumatischen Förderkomponenten;
• 3 eine schematische perspektivische Ansicht einer Ausführungsvariante einer Dosiereinheit der Verteilmaschine gemäß 1 und 2 mit aus Veranschaulichungsgründen aufgebrochen dargestelltem Dosiergehäuse;
• 4 eine schematische perspektivische Schnittansicht der Dosiereinheit gemäß 3;
• 5 eine schematische perspektivische Ansicht eines Zellenrades der Dosiereinheit gemäß 3 und 4;
• 6 eine schematische Seitenansicht des Zellenrades gemäß 5 in Richtung des Pfeils VI betrachtet;
• 7 eine schematische Seitenansicht des Zellenrades gemäß 5 in Richtung des Pfeils VII betrachtet;
• 8 eine schematische perspektivische Ansicht einer weiteren Ausführungsvariante der Dosiereinheit gemäß 2 mit aus Veranschaulichungsgründen aufgebrochen dargestelltem Dosiergehäuse;
• 9 eine schematische perspektivische Schnittansicht der Dosiereinheit gemäß 8;
• 10 eine schematische perspektivische Schnittansicht eines Zellenrades der Dosiereinheit gemäß 8 und 9;
• 11 eine schematische perspektivische Explosionsansicht des Zellenrades gemäß 10 einschließlich seiner zur drehbaren Lagerung in dem Dosiergehäuse dienenden Welle;
• 12 eine schematische Schnittansicht des in dem Dosiergehäuse gelagerten Zellenrades gemäß 10 und 11; und
• 13 eine schematische Seitenansicht des in dem Dosiergehäuse gelagerten Zellenrades gemäß 10 und 11 entlang einer unter einem Winkel von 90° in Bezug auf die Schnittebene der 12 angeordneten Schnittebene.

Further features and advantages of the invention result from the following description of exemplary embodiments with reference to the drawings. Show:

• 1 a schematic view of an embodiment of an agricultural distributor in the form of a pneumatic distributor designed in the manner of a seed drill viewed from the rear thereof;
• 2nd is a schematic perspective view of the distribution unit in the form of a distributor head of the distributor according to 1 including the outlet of a metering unit, the housing of the transfer chamber and the pneumatic conveying components;
• 3rd is a schematic perspective view of an embodiment of a metering unit of the distributor according to 1 and 2nd with dosing housing shown broken away for reasons of illustration;
• 4th is a schematic perspective sectional view of the metering unit according to 3rd ;
• 5 a schematic perspective view of a cellular wheel of the metering unit according to 3rd and 4th ;
• 6 is a schematic side view of the cellular wheel 5 in the direction of the arrow VI considered;
• 7 is a schematic side view of the cellular wheel 5 in the direction of the arrow VII considered;
• 8th a schematic perspective view of a further embodiment of the metering unit according to 2nd with dosing housing shown broken away for reasons of illustration;
• 9 is a schematic perspective sectional view of the metering unit according to 8th ;
• 10th is a schematic perspective sectional view of a cellular wheel of the metering unit 8th and 9 ;
• 11 is a schematic perspective exploded view of the cellular wheel according to 10th including its shaft for rotatable mounting in the metering housing;
• 12th is a schematic sectional view of the cellular wheel mounted in the metering housing 10th and 11 ; and
• 13 is a schematic side view of the cellular wheel mounted in the metering housing 10th and 11 along one at an angle of 90 ° with respect to the section plane of the 12th arranged cutting plane.

In the 1 is an embodiment of a distribution machine shown schematically, which in the present case like a Pneumatic distribution machine, such as a seed drill for distributing flowable solid particles in the form of fertilizer and / or seeds on or in the ground, and can be detachably fixed, for example, to a conventional three-point linkage of a tractor, such as a tractor. The distribution machine includes a storage container 1 to hold the solid particles to be distributed with a cover 2nd which on supports 3rd are carried by a frame. There is also a blower on the latter 4th set to generate an air flow. Below an outlet of the storage container tapering downwards in a funnel shape 1 is in the 2nd more recognizable housing 5 a transfer chamber 14 which are used to transfer the solid particles to a delivery line 6 serves. The latter is from the blower 4th with an air flow to the solid particles upwards in a distribution unit 7 to promote. The distribution unit 7 is formed in the present case by a distributor head and comprises a plurality of connections distributed around its circumference, in the present case extending approximately radially outward, to each of which a distributor line 8th connected. The connection of the distribution lines 8th can for example by means of a housing 18th (cf. the 2nd ) happen, which is expediently equipped with a shut-off device for interrupting the fluidized particle flow as required, in order to be able to provide different working widths or partial section switching. That from the distribution head of the distribution unit 7 outgoing distribution lines 8th , which can be designed, for example, in the manner of hoses and in which 1 are shown broken off for reasons of clarity, are essentially guided downwards and backwards, with their free, the distribution unit 7 opposite ends are provided with distribution members. In the present exemplary embodiment, the distribution members are coulters not recognizable in detail in accordance with the prior art with strikers arranged downstream of them 9 , so-called weeding. Any other known distribution elements, such as, for example, baffle plates or plates or the like, can also be provided (not shown). The frame of the distributor can, moreover, have support wheels 10th on the ground 11 supported and in particular raised by these.

The 2nd shows the pneumatic conveyor components of the distributor according to 1 which is used to transfer the solid particles from the inside of the housing 5 located transfer chamber 14 into the distribution unit designed in the manner of a distribution head 7 by means of the delivery line 6 serve. The latter points at the distribution unit 7 opposite end of a connecting piece 12th for fluid contacting of the blower 4th (please refer 1 ) on. Downstream of the connector 12th the outlet opens 103 a metering housing one below with reference to the 3rd ff dosing unit described in detail in the transfer chamber 14 a, which is from the conveyor line 6 is crossed. From there, the solid particles dispersed in the air flow first reach an approximately horizontal section of the delivery line 6 into a riser pipe section thereof, which from below into the center of the distributor head of the distributor unit 7 opens out around the circumference of the radial connections for the housing 18th are arranged, to which in turn each one in which 2nd distribution line, not shown again in the drawing 8th connects. Inside the case 5 the one below the outlet 103 the dosing unit arranged transfer chamber 14 , which in the present case, for example, transversely to the direction of travel of the delivery line 6 is penetrated, on the one hand a nozzle (not recognizable), on the other hand a diffuser (also not recognizable) designed in the manner of an expansion nozzle of an injector, which are arranged coaxially to one another and, for example, approximately perpendicular to the direction of travel of the distributor at the lowest point thereof. The actual transfer chamber 14 is located in the space between the nozzle and the diffuser of the injector. While the injector nozzle on the in 2nd left end of the case 5 the transfer chamber 14 to the blower 4th (please refer 1 ) is connected, connects to the injector 's diffuser at the 2nd right end of the case 5 the transfer chamber 14 the conveyor line 6 on. In this way, the flowable solid particles, after they have been metered in a desired mass flow by means of the metering unit (see below), in the transfer chamber 14 transferred into the diffuser by means of the gas stream flowing in via the nozzle and from there into the delivery line 6 .

The in the 1 and 2nd reproduced distribution machine can also - as is known per se - be equipped with a control and / or regulating device, not shown in the drawing, which controls and / or regulates the functional components of the distribution machine. The control and / or regulating device is in particular in operative connection with the dosing unit described in detail below in order to control and / or regulate the latter to the desired target mass flow of solid particles, calibration tests being carried out in a manner known per se for calibration of the dosing unit be able to determine the actual mass per revolution of the solid particle type to be distributed and to control and / or regulate the speed on the occasion of the subsequent distribution work depending on this.

While in the 3rd a first embodiment of a dosing unit 100 the Distributor according to the 1 and 2nd is shown with the front wall of the metering housing broken open, shows the 4th a sectional view of the same metering unit 100 . As can be seen from this, the dosing unit comprises 100 a dosing housing 101 with an inlet arranged on its top 102 which, for example, is approximately funnel-shaped in the direction of the interior of the metering housing 101 tapered, and with an outlet arranged on its underside 103 which - as above with reference to the 3rd mentioned - in the transfer chamber 14 the distributor opens. In the dosing housing 101 is a cellular wheel 104 rotatably mounted, which is rotationally driven by means of a drive, not shown in the drawing, for example electrical, and is in particular in operative connection with the control and / or regulating device of the distribution machine, also not shown in the drawing, around the cell wheel 104 to set in rotation according to the desired mass flow of solid particles to be discharged.

Like the one in particular 5 to 7 can be seen, includes the cellular wheel 104 a plurality of substantially radially extending cells of the cellular wheel 104 circumferentially limiting - here: for example ten - cell walls 105 , with two adjacent cell walls in the circumferential direction 105 their radially inner ends by means of a cell bottom 106 are interconnected. For caking of, in particular, hygroscopic solid particles in the area of the cell bottoms 106 of the cellular wheel 104 and to avoid incorrect doses caused by this are the cell bottoms 106 each with an elastically flexible membrane 107 formed, each in the region of the radially inner ends of two adjacent cell walls 105 is connected to them and one radially inside the membrane 107 arranged cavity 108 spreads. The one from the the cavities 108 spanning membranes 107 formed cell floors 106 of the cellular wheel 104 have a very high elastic flexibility in this way, the membranes 107 both inside a respective cell of the cellular wheel 104 (ie approximately radially outwards) as well as in the direction of the cavity it overlaps 108 (ie, radially inward), so that agglomerations or caking of the metered solid particles are reliably avoided. Such elastic deformations of the membranes 108 , which lead to flaking of any caking, can occur during operation solely due to the membrane 106 during the rotation of the cellular wheel 104 acting forces and due to the forces acting during the filling and emptying of a particular cell with or from the metered solid particles. In addition, it proves advantageous in this context, if at least the cell walls 105 of the cellular wheel 104 or essentially the entire cellular wheel 104 are formed from an elastically resilient material, so that the cell walls 105 can deform elastically due to the forces acting on it during operation. As a result, not only caking from the cell walls is possible 105 quickly to be solved again, but this results in a significantly greater deformation of the cell bottoms compared to more or less rigid cell walls 106 forming, resilient membranes 107 because these are in the radially inner area of two adjacent cell walls 105 are connected to these and in the case of an elastically flexible deformation of one or both cell walls 105 in turn be deformed. The cell walls 105 appropriately have one over the cell floors 106 forming, resilient membranes 107 have less flexibility, ie the cell walls 105 are preferably more rigid than the membrane 107 to ensure the necessary sealing of the cellular wheel 105 against the inside cross section of the dosing housing 101 (cf. the 3rd and 4th ) to care. Both the cell walls 105 as well as the the cell floors 106 forming membrane 107 can be made, for example, from suitable polymer materials, with essentially the entire cellular wheel in the present exemplary embodiment 104 is made from a thermoplastic elastomer, for example from a thermoplastic polyurethane (PUR) with a hardness of 65 ° Shore-A, which, depending on the desired elasticity, may be in the form of a, preferably closed-cell, foam by the use of a blowing agent. The one in the present case with the cell walls 105 connected membrane 107 have a smaller thickness than the cell walls 105 to give them a higher elastic resilience.

In order for a very high elastic compliance of the cell floors 106 of the cellular wheel 104 forming membranes 107 or to ensure a very high freedom of movement of the same, the cavities spanned by them extend 108 in the exemplary embodiment shown over substantially the entire axial length of the cellular wheel 104 and consequently enforce it in the manner of through cavities. Depending on the method of manufacture of the cell wheel - as already mentioned - made of an elastomeric plastic material 104 can the cavities 108 For example, either slightly taper from one axial end to the other axial end (for example, for simple demolding of a cellular wheel produced by tipping or casting 104 to ensure), or can the cavities 108 for example, also have a constant cross-section (for example, if the cell wheel is generated 104 using 3D printing). In the case of the cellular wheel 104 completely penetrating cavities 108 can safely prevent penetration of the particulate solids or other contaminants, such as dirt, dust particles and the like, into the cavities 108 it should also be provided that the cavities 108 are closed at least at their axial ends. This can be done, for example, by sealing one onto the axial ends of a respective cavity 108 applied, for example thermoplastic film (not shown) or in a respective cavity 108 can be, for example, an elastically flexible filler (also not shown) with one opposite the cell bottoms 106 forming membranes 107 higher flexibility can be introduced, the filler material, for example in the form of highly porous sponges or foams, has a very high elastic flexibility and no significant resistance to deformation of the membranes 107 offers, so as not to impair their freedom of movement.

As further from the 3rd to 7 can be seen, the cellular wheel 104 for example also with a central bore extending in its axial direction 109 be provided, which for the rotationally fixed arrangement of the cellular wheel 104 on one on the dosing housing 101 mounted, rotationally driven shaft 110 (cf. the 3rd and 4th ) serves. The central hole 109 has a non-circular cross-section in the present case and is used opposite the cellular wheel 104 rotationally fixed receptacle of a sleeve 111 with one to the hole 109 essentially complementary outer cross-section, the sleeve 111 has a polygonal inner profile, which leads to a polygonal outer profile of the shaft 110 is complementary to the cellular wheel 105 by rotating the shaft 110 by means of the drive (not shown in the drawing) to rotate. Instead, the central hole can of course also be used 109 of the cellular wheel 104 be provided with such a polygonal inner profile to the shaft 110 directly, ie without intermediate arrangement of the sleeve 111 , in the hole 109 to be able to introduce (not shown).

In addition, it may prove useful if the cell walls 105 of the cellular wheel 104 with an, in particular slight, oversize compared to the inner cross section of the metering housing 101 the dosing unit 100 are trained to turn them on the cell wheel 104 to deform elastically and thereby the associated cell floors 106 forming membranes 107 deform elastically. Like the one in particular 3rd and 4th can be seen, the cell walls 105 - and with them the membranes 107 - the rotating cell wheel 104 in this way by pressing against the inner cross section of the metering housing 101 (or more precisely: to yourself between the entrance 102 and its outlet 103 extending inner sealing wall 112 of the dosing housing 101 ) elastically deformed as soon as a respective cell wall 105 the entrance 102 of the metering housing has passed and in pressure contact with itself between the inlet 102 and the outlet 103 extending inner sealing wall 112 of the dosing housing. Arrives at a respective cell wall 105 by further turning the cell wheel 104 after the outlet 103 of the dosing housing 101 , so it becomes - and with it the membrane arranged on it 107 - In turn elastically transferred back to the undeformed state, so that any caking of the dosed solid particles flake off and into the outlet 103 reach.

In the 8th to 13 is a second variant of a dosing unit 100 the distributor according to 1 and 2nd schematically reproduced, identical and functionally identical components are provided with the same reference numerals and require no further explanation.

The dosing unit 100 according to the 8th to 13 differs from that of 3rd to 7 in particular in that the cellular wheel 104 an inner circumferential recess 113 has (see in particular the 9 , 10th and 12th ), which is from the longitudinal central axis of the cellular wheel 104 around the entire circumference of the cell cell floor 106 forming membranes 107 extends and consequently, for example, with the radially inside of the membranes 107 subsequent cavities 108 corresponds. That in the present case on a central section of the cellular wheel, viewed in the axial direction 104 arranged circumferential recess 113 serves to hold a pin engaging in it 114 which in relation to the dosing housing 101 is rotatably arranged (ie the cell wheel 104 is relative to the stationary pin 114 rotatable) and essentially in the radial direction of the cellular wheel 104 in the area of the outlet 103 of the dosing housing 101 extends. The radial length of the pen 114 is dimensioned such that it extends at least to a respective cell floor 106 of the cellular wheel 104 forming membrane 107 extends to the membrane 107 when turning the cellular wheel 104 to resiliently deform when the pin 114 happens. In this way, the resilient membrane 107 a respective cell of the cellular wheel from the free end of the pin 114 always actively deformed elastically or turned inside the respective cell when this cell rotates the cell wheel 104 the outlet 102 of the dosing housing 101 happens so that any caking or aggregation of the dosed solid particles flake off and completely in the outlet 102 be transferred. One above with reference to the 3rd to 7 described formation of the cellular wheel 104 with a certain excess compared to the inner cross section of the dosing housing 101 is unnecessary in this way, but can of course also be provided in addition.

In terms of design, it can be provided that the pin 114 from the outer circumference in relation to the dosing housing 101 non-rotatably arranged support sleeve 115 (ie the cellular wheel 104 is in relation to the stationary support sleeve 115 with the pen 114 rotatable) extends substantially radially, the support sleeve 115 in the axial direction of the cellular wheel 104 extending, central bore 109 in relation to the cellular wheel 104 is rotatably received. For easy insertion of the support sleeve 115 in the central hole 109 on the occasion of assembly or simply pulling out the support sleeve 115 from the central hole 109 The pin is to enable on the occasion of disassembly 114 in the present embodiment between an assembly position, not shown in the drawing, in which it is located inside the support sleeve 115 is located, and an operating position shown in the drawings, in which it is from the outer periphery of the support sleeve 115 extends approximately radially in the direction of arrow P 11 can be moved back and forth, whereby it can be locked in the operating position.

As especially from the 9 , 10th and 12th emerges, has the central hole 109 of the cellular wheel 104 in the second embodiment variant, it extends from an axial end to the inner circumferential recess 113 extending first bore section 109a a polygonal inner profile (or according to the first embodiment variant, a non-rotatable in the first bore section 109a fixed sleeve with a polygonal inner profile; not shown), which for receiving the rotary shaft 110 serves with a complementary polygonal outer profile. At its itself from the other axial end to the inner peripheral recess 113 of the cellular wheel 104 extending, coaxial to the first bore section 109a arranged second bore section 109b shows the central hole 109 on the other hand, has a circular cross-section which, in contrast, rotatably receives the pin 114 provided support sleeve 115 serves. The inner cross section of the second bore section 109b can be at least slightly larger than the outer cross section of the support sleeve 115 so that between the rotating cell wheel 104 and the stationary support sleeve 115 no friction occurs due to non-contact. Instead, the second bore section 109b but also one on the outer cross section of the support sleeve 115 have adapted internal cross-section, so that the support sleeve 115 an additional bearing function of the cellular wheel 104 comes like a plain bearing. The inner cross section of the in the second bore section 109b the central hole 109 of the cellular wheel 104 recorded support sleeve 115 is expediently larger in both cases than the outer cross section of the rotationally fixed in the first bore section 109a the central bore 109 seated wave 110 , so the latter the support sleeve 115 engages without contact in the assembled state and on the two opposite sides of the dosing housing 101 can be stored (see in particular the 12th ).

At this point it should be pointed out that the two embodiment variants of the dosing unit according to the invention which are shown in the drawing 100 have been described above in relation to an agricultural distributor, but the metering units 100 can of course also be used in any other application wherever flowable solid particles are to be metered, such as in filling and packaging machines as well as systems for compiling desired formulations from a plurality of flowable solid particles or powders, such as those used in construction -, Food and luxury goods industry, in the chemical, biochemical and pharmaceutical industry or in the plastics industry.

QUOTES INCLUDE IN THE DESCRIPTION

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Patent literature cited

• DE 102004030240 A1 [0003]
• DE 102017005094 A1 [0004]

Claims (15)

Dosing unit (100) for dosing flowable solid particles, with a dosing housing (101) which has at least one inlet (102) and at least one outlet (103), and with at least one rotary-driven cellular wheel (104) mounted in the dosing housing (101) with a plurality of cell walls (105) which extend essentially radially and delimit the cells of the cell wheel (104) in the circumferential direction, two adjacent cell walls (105) in each case being connected to one another in the region of their radially inner ends by means of a cell bottom (106), characterized in that the cell bottoms (106) of the cell wheel (104) are formed by resiliently flexible membranes (107), each of which is connected to two adjacent cell walls (105) in the region of the radially inner ends and each has a radially inner side of a respective one Grip over the membrane (107) arranged cavity (108). Dosing unit after Claim 1 , characterized in that at least the cell walls (105) of the cellular wheel (104) are formed from an elastically flexible material, the cell walls (105) in particular having a lower flexibility than the elastically flexible membranes (107) forming the cell bottoms (106) . Dosing unit after Claim 2 , characterized in that at least the cell walls (105) of the cellular wheel (104) are formed from the same elastically flexible material as the elastically flexible membranes (107) forming the cell bottoms (106), in particular in one piece with them, the cell bottoms ( 106) forming, elastically resilient membranes (107) in particular have a smaller thickness than the cell walls (105) of the cell wheel (104). Dosing unit according to one of the Claims 1 to 3rd , characterized in that the radially on the inside of a respective membrane (107) forming a respective cell bottom (106) arranged cavities (108) of the cellular wheel (105) are closed at least at their axial ends. Dosing unit after Claim 4 , characterized in that the cavities (108) - sealed by means of a film applied to their axial ends and / or - by means of an elastically flexible filler which is introduced into the cavities (109) and which has a cell bottom (106) of the cellular wheel (104 ) forming membranes (107) are filled with higher flexibility. Dosing unit according to one of the Claims 1 to 5 , characterized in that the cellular wheel (105) has a central bore (109) which extends in its axial direction and which serves for the rotationally fixed arrangement of the cellular wheel (105) on a rotatably driven shaft (110) mounted on the metering housing (101). Dosing unit after Claim 6 , characterized in that the central bore (109) of the cellular wheel (104) has at least in sections a polygonal inner profile or at least in sections receives a sleeve (111) which is fixed in the bore (109) and is provided with a polygonal inner profile. Dosing unit according to one of the Claims 2 to 7 , characterized in that the cell walls (105) of the cellular wheel (104) are designed with an, in particular slight, oversize in relation to the inner cross section of the metering housing (101) in order to elastically deform them when the cellular wheel (104) is rotated and thereby to connect the cells connected to them to elastically deform the cell bottoms (106) forming membranes (107). Dosing unit according to one of the Claims 1 to 8th , characterized in that the cellular wheel (104) has at least one inner circumferential recess (113) which extends from the longitudinal center axis of the cellular wheel (104) to the membranes (107) forming the cell bottoms (106). Dosing unit after Claim 9 , characterized in that a pin (114) engages in the inner peripheral recess (113) of the cellular wheel (104) in a rotationally fixed manner with respect to the metering housing (101) and extends essentially in the radial direction of the cellular wheel (104) and extends at least up to to a respective membrane (107) forming a cell bottom (106) of the cellular wheel, in order to elastically deform the membrane (107) when the cellular wheel (104) rotates when it passes through the pin (114). Dosing unit after Claim 9 , characterized in that the pin (114) extends essentially radially away from the outer circumference of a support sleeve (115) arranged in a rotationally fixed manner with respect to the metering housing (101), the support sleeve (115) extending in an axial direction of the cellular wheel (104) extending central bore (109) is rotatably received with respect to the cellular wheel (104). Dosing unit after Claim 11 , characterized in that the pin (114) between an assembly position, in which it is located inside the support sleeve (115), and an operating position, in which it extends essentially radially away from the outer circumference of the support sleeve (115), and is relocatable (P), whereby it can be locked in the operating position. Dosing unit after Claim 11 or 12th , characterized in that the central bore (109) of the cellular wheel (104) - at its first bore section (109a), which extends from an axial end to the inner circumferential recess (113) of the cellular wheel (104), has a polygonal inner profile or a rotatably fixed in the first bore section (109a), provided with a polygonal inner profile, and - at its second bore section (109b), which extends from the other axial end to the inner peripheral recess (113) of the cellular wheel (114), has a circular cross section which, on the other hand, serves for rotatably receiving the support sleeve (115) provided with the pin (114). Dosing unit according to one of the Claims 10 to 13 , characterized in that the pin (114) is arranged in the region of the outlet (102) of the metering housing (101). Distributing machine, comprising at least one dosing unit (100) for dosing flowable solid particles and at least one distribution member arranged downstream of the dosing unit (100) for distributing the solid particles dosed by means of the dosing unit (100) onto or into the soil, characterized in that the dosing unit (100) by a dosing unit (100) according to one of the Claims 1 to 14 acts.

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