EP0318054A1 - Method of and device for separating heavy impurities from grain - Google Patents

Abstract

The invention relates to a method and a device for reading out heavy admixtures from a product stream (20), in particular stones (28) from grain material, in which the product stream (20) is fed and essentially layered on a shift table (3; 3b; 3d) is guided over the inclined, air-flowed and vibrating shift table surface in such a way that the heavy admixtures lying directly on the shift table (3; 3b; 3c) are conveyed upwards and discharged separately at the higher end of the table, the feed of the product stream (20) using a Feed channel takes place, which opens into the area of the higher table ends and feeds the material as a wide-area stream into the separation zone of the material layers (25, 26) located there.

Description

The invention relates to a method for reading out heavy admixtures, in particular stones made of grain material, in which the material is fed onto a shift table and is guided in a layered manner over the inclined, air-flowed and vibrating shift table surface in such a way that the heavy admixtures lying directly on the shift table are upstream of the table promoted and discharged separately at the higher table end.

In the past, attempts have been made in a variety of ways to divide a grain mixture into heavy and light grain fractions. A key problem is the selection of stones from the grain. Stones, broken glass, metal parts and other admixtures that differ significantly in size from the size of a medium grain are separated using sieves. As is known, there are the same types of grain as wheat, barley, rye, oats, spelled, but also other seeds such as coffee, cocoa beans, field beans, seeds, flower seeds, etc., the outer dimensions of the grains in a relatively narrow grain size range. What is larger than a certain perforation or smaller than a second finer perforation can easily be separated as a different good by simple sieving. The difficulty lies in reading out the foreign components, which are roughly the same size as the good grain, and carrying them away separately.

In the past, a water bath was often used, in which all foreign components that were heavier than the grain sank to the bottom of the water bath. The gravity effect and the buoyancy of the water were used. The main advantage of this method was the simultaneous washing effect of the grain. Because of the washing water also produced as a result and partly because of the associated microbial problems, this solution has been replaced almost completely by the so-called dry cleaning for several years.

During dry cleaning, vibrations and a strong air flow over a table surface basically generate similar buoyancy forces to those used in the wash water. In practice, the generic readout method for stones already proposed by the applicant has become the most popular in the past two decades, at least where high demands have been placed on the readout level (see DE-PS 1 913 707). First, a pre-stratification along a precaution channel is created. The heavy additions sink to the area near the table. Then, at the same time, the light layer lying at a distance above the table slides over the table surface in the direction of the end which is at its lowest point due to the inclination, or to the corresponding outlet for the lighter fraction. The heavy admixtures lying on the table surface are caused by the swinging and conveying movement of the table surface in the direction of the higher end of the table, the stones being completely separated in an end separation zone and discharged via the corresponding outlet. The main disadvantage of this known solution is the specially required triangular table shape, which only allows a limited increase in throughput.

As a result, various other solutions have been tried, but without resounding practical success. In the majority of cases, it was not possible to achieve the readout quality of the first-mentioned solution. Various attempts have been made to operate with two work tables lying one above the other, the upper table mostly having a sieving and layering function, as shown for example in DE-OS 25 33 274. With this solution, it is only possible with additional measures, such as special internals, etc., to achieve an essentially perfect, i.e. H. to reach almost 100% stone selection.

From GB-PS 1 536 905 a grain separator is known in which an air flow is generated with the aid of a fan arranged under an inclined and perforated chute. The housing housing the entire separator and fan is rigidly arranged and only the receiving table can be moved.

The classic air recirculation system is disclosed here, but in practice there were always problems with the pressures in the respective sections of the housing. In particular, the problem of so-called false air could not be eliminated.

Finally, the air flow was problematic in the known grain mixture separation processes, in particular heavy goods selection processes, which applies in particular to the mutually undisturbed, optimal flow of goods and air, including feed and air feed, with the result that Limiting the improvement in throughput, especially with good selection.

The invention is based on the object of providing a new method for reading out heavy admixtures, in particular a new stone selection method and a device for carrying out this method or a new dry gravity reading system which allows a higher throughput.

This object is achieved in a generic method in that the material is fed as a wide-area stream into the area of the separation zone of the material layers located at the higher table end.

The first practical experiment with the new inventive idea was surprising in two ways. Firstly, the readout rate was immediately unexpectedly high, and secondly, the inventor chose an infeed point which, according to all previous convictions, must have been wrong among experts. However, she did achieve the desired success. So far, not least based on the idea of pre-separation (see DE-PS 1 913 707), the method was presented in two spatially and temporally separate steps. The first step was stratification, the layer near the table should contain all heavy admixtures, and only as a subsequent step should the layering carried out in a channel be fed undisturbed onto the table surface and the stones to the outlet for the stones. The effective separation and separate routing of the stones only took place in the area of the highest reading table end. The heavy admixtures should usually only make up a very small percentage of the grain, so that the final separation zone accordingly had the smallest dimensions (the tip of a triangle), because only a small proportion of the entire product quantity was carried up to that point. Were now the final separation zone or the table inclination set incorrectly, where too much grain could get there, or if the local air flow was chosen unfavorably, either the stone selection was poor or the stones were separated out several times in good grains. The final separation zone was then also a place that always had to be specially monitored. The thought of pouring a large amount of fresh grain in the stone separation zone onto the table would have been completely absurd. Every fault at the point showed an immediate deterioration in the working of the reading tables.

Because the inventor has completely detached himself from all previous concepts and the supposedly derived unchangeable natural laws,
- be it that pre-separation is necessary at all,
- and this takes time and distance to separate the heavy admixtures
- or by placing the product over a larger area of the table, in the opinion that each stone then has the greatest possible chance of being separated,
he was only able to free himself and realize the new idea unencumbered, which in particular consists in the fact that
- The good feed occurs as wide as possible good flow
- and this is placed directly in the area of the separation zone at the top of the table.

The shift table should work as a good shift table in that it is designed in such a way that the heavy admixtures below are conveyed upwards. In this way, with a product task at the higher table end, the most heavy admixtures remain in the Area of the separation zone. Should they be dragged down a bit, they will move back up to the final separation zone with even greater certainty than all previously known solutions. Now it is only a question of the clean design of the final separation zone, the correct setting of the air volume and table inclination to achieve an optimal way of working. The invention enables particularly good prerequisites for a practical optimization in that the creation of a wide-area stream of material results in the final separation at the maximum possible width, that is to say without unnecessary layer thickness.

The new invention now allows a whole number of further, particularly advantageous configurations. For example, a uniform layer flow (difficult upstream, slightly downward) with flow direction reversal in the region of the higher end of the layer table is preferably generated on the stratification table, and the product stream is fed directly into the region of the flow direction reversal.

The reversal of the direction of flow for the light parts is generated in a manner known per se, a table piece which is continued further upwards also having air flowing through it, so that the light parts stand out from the table surface. At the same time, the product layer, with the exception of the stones, is prevented from moving further up the table by an air flow directed towards the separation zone and downstream of the table, which acts almost like a blower or air blast device (see FIG. 2).

In a further very particularly preferred embodiment, the material is first fed to a first, uppermost vibrating table and at least a first part of the heavy material fraction flowing upstream of the table and consisting of a mixture of heavier grain material and stones is guided at the upper end of the first table in such a way that the heavy goods fraction is widely fed from there to the upper end region of a table surface, through which the same air flows, of a second, lower layer table located underneath.

This measure allows approximately half the throughput from the upper table surface, which now contains almost 100% of all heavy admixtures, to be discharged as a heavy layer onto the lower table. The actual separation of the heaviest admixtures to be separated takes place here on the lower table. In this way, the throughput can be doubled in a single device with the same amount of air, and without the slightest loss in separation quality.

In a further preferred embodiment of the method according to the invention, the material is moved upwards on the upper layer table with a lower conveying component than on the lower layer table, and a second part of the heavy material fraction is fed from the upper layer table to the lower end region and / or the center of the lower layer table.

This has the advantage that the stone selection takes place in two temporally and spatially separate stages.

The product stream is particularly preferably fed in via a guide plate arranged at a distance above the table surface. As a result, the product stream can advantageously be conducted across the entire table width of the shift table.

It is also proposed to feed the product stream in the direction of the flow direction of the light grain layer (or against the flow direction of the heavy grain layer).

In a particularly preferred embodiment of the In order to separate the heaviest admixtures (stones) from the shaped material, the method according to the invention blows an air stream (blow-back stream) in the direction of a reversal of the direction of flow of the heavy grain material migrating up the table onto the separation zone.

This has the advantage that a promotion of the light parts or grains together with the heaviest additions on the table is prevented.

In a further particularly advantageous embodiment of the method, the blow-back stream is conducted between the guide plate and the layer table. In this way it is in particular possible to guide the air flow in a simple manner, through which the heavy and light particles of the goods can be separated.

In a further preferred embodiment of the method, the at least one shift table, together with a covering assigned to it for recirculation mode, is set in common vibrations with separate guides for supply and exhaust air.

This has the advantage that the whole system has a self-cleaning effect. Adhering dust particles are shaken off continuously by the shaking movement. This eliminates the need for time-consuming cleaning. This ensures that the flow paths are not changed in their cross-sections by adhering particles, so that constant flow conditions can always be guaranteed.

Since the individual elements are arranged within the cladding and the cladding can vibrate with it, the good is continuously shaken when the goods are fed onto the good table.

The fact that table as well as good distribution elements shaken at the same time, the veil-like, widespread spread of the material on the shift table is essential for the separation process. This joint formation of the elements within the cladding essential for the separation process also has the advantage that the sealing problems disadvantageous in the prior art can be avoided.

In a further very particularly preferred embodiment, the cladding, together with the shift table, forms a box which is supported in an oscillatory manner, and the box, including the shift table, is set in common vibrations.

Another very advantageous design idea is that the material feed occurs as a wide-area stream into the area of the separation zone of the material layers located at the higher end of the table, the air is removed from the center of the covering at the top and is supplied in a wide area in the area of the lower end of the layer table. This has the advantage that the air supply acts on the entire table width from below right from the start. It is also possible to achieve an air flow within the box that works almost without undesired eddy formation.

Due to the compact, elegant design and the transmission of the required vibrations to all components, it is suddenly possible in a simple manner to separate the individual functions from one another and to fasten the cladding in a sealing manner.

In a further preferred embodiment of the method, the circulating air in the region above the central air discharge and the lower air supply is cleaned of dust components. This allows the flowing air to be cleaned advantageously at a time when undesired eddy formation occurs Laxative elements for cleaning can not yet interfere with the air flow acting on the table.

In a further preferred embodiment, the material on the upper layer table is guided over a trough-shaped depression (stone and manor swamp), the heavy goods fraction entering the depression via bottom openings of the depression and then over a slide inclined in the opposite direction to the upper layer table middle floor of the lower stratified table, on the other hand, the light material fraction flowing over in the flow direction of the trough-shaped depression of the upper stratified table is fed to an outlet for light material. In this way, the heavy layer can advantageously permanently sink completely into the stone sump and be discharged directly downwards. This results in a very high degree of selection for the heaviest admixtures and, in addition, a clean separation can be carried out with only minimal additional effort.

In a particularly preferred embodiment, a shifting suction hood and a stationary platform arranged above it are assigned to the shift table, the material being fed in via an inlet in the stationary platform, guided via flexible sleeves into a distribution box of a dining channel that moves with the suction hood, and cascading from the distribution box a guide bleach is poured, whereby a multitude of downdraft is generated across the entire width of the shift table.

The invention further relates to a device for separating and reading out heavy admixtures from a product stream, in particular stones from grain material, with a feed channel for feeding the product stream onto an air-flowed, vibratable, inclined shift table with an oscillating conveyor component in the direction of the higher table end.

The object mentioned above in the context of the method is achieved in a generic device in that the feed channel opens into the area of the higher table end.

The first test results with the new device were particularly surprisingly good, since with the same readout rate and the same air consumption, the throughput of goods in some cases could be increased by more than 50%, without the construction of the new device requiring major structural expenditure.

In a preferred embodiment of the device according to the invention, the feed channel opens out over the entire width of the shift table. This has the advantage that a wide and generous loading of the material to be separated is possible.

In a very particularly preferred embodiment, the mouth of the feed channel has a guide plate arranged at a distance above the shift table. This guide plate has the advantage of evenly distributing the material to be loaded over the shift table and at the same time serving as a guide for air currents on its underside.

In another preferred embodiment, the feed channel has a distribution box and a guide plate, which form a cascade for the feed product flow to generate a uniform falling flow over the entire width of the shift table.

In a particularly preferred embodiment, the guide plate has an overflow edge and bottom openings in the region of its end pointing in the direction of flow, in such a way that the majority of the material flows as a wide-area flow of material onto the shift table and the heavy ones Additions can be drained through the bottom openings. With this overflow edge, a particularly wide area of the product flow is achieved, because after the full width of the trough has been filled in front of this overflow edge, a uniform flow then flows, which is fed by the trough down onto the layer table below.

In a preferred embodiment, an end separation zone for reading the stones is arranged between the guide plate and the table surface of the layer table.

A further breakthrough in terms of higher throughputs could only be achieved by arranging two jointly vibrating shift tables directly one above the other and the same air flowing through them.

The lower layer table preferably has a larger conveying component in the upward direction than the upper layer table, the surface of which is rougher than that of the upper layer table. As a result, the upper layer table advantageously serves as a pre-layer table. It is equally advantageous if the upper layer table has at least one discharge opening serving as a feed channel for the lower layer table at its higher end. In this way, a micro-heavy load fraction can be directed directly to the higher end of the lower table.

The feed channel for the lower shift table particularly preferably extends over the entire width of the upper shift table in order in turn to produce a uniform distribution of material on the lower shift table.

The two shift tables are advantageously arranged in relation to one another in such a way that the upper shift table feeds well onto the upper table end of the lower shift table. In this way it is possible that almost the entire proportion of the material to be separated is fed in at the location of the lower table where the unexpectedly good separation is possible.

The at least one shift table is particularly preferably part of a box which vibrates together with it and is designed for recirculation mode.

This has the advantage that not only the shift table but also the box connected to it is shaken at the same time. A self-cleaning effect can thus be achieved in that adhering dust particles can be shaken off during the operation of the system.

At the same time, it is possible to design the entire system inside the box without the usual sealing problems, because the system according to the invention is tight on the outside, so that the air inside can be controlled in a targeted manner.

If the system inside the box were not sealed against the outside air, you would get secondary air that would disturb the entire air duct system. It is also advantageously possible to introduce air over the entire lower table surface in the lower region of the product table. Overall, therefore, an optimal product supply with the possibility of fanning out over a wide area with simultaneous optimal air supply can be achieved without the product supply and air supply interfering with one another.

In a further advantageous embodiment of the device, the material feed is part of the box. This has the advantage that the material feed resonates with the box and, by means of this oscillating movement, the material is loosened before it hits the shaking table and forms a so-called veil. That veil is the guarantee for a wide distribution on the table. In addition, with simultaneous cleaning due to the shaking movement, the feeder can also be cleaned.

In a further preferred embodiment, the following are provided within the box: an air suction space and a circulating air supply duct separate therefrom, which opens in the region of the lower end of the at least one shift table. This makes it possible to make the air extraction space and also the air circulation duct so generously dimensioned that no severe constrictions trigger undesired eddies or other unpleasant flow effects. The entire air flow can be guided through the tables within the box without interference and, in particular in the width of the lower surface of the bottom table, can pass through the table evenly over its full width.

In a further preferred embodiment of the device according to the invention are arranged on the top of the box: on one end side a material inlet, approximately in the middle an air suction nozzle and on the opposite end side an air return line for the recirculating air duct. This makes it possible to extract the circulating air conveyed through the respective shift table in the middle under good flow conditions, without a disturbance of the flow properties being expected from the material fed in. With the lateral feed of goods, it is nevertheless possible to feed the goods to be fed into the middle of the shift table to be loaded. At the same time, this preferred embodiment makes it possible to conveniently suck off the air above the center. This leaves enough space for the circulating air supply duct, because the so-called outlets for the goods can be made relatively narrow without interfering with the routing of the goods. As a result, the air supply from the bottom can be wide from the start in the lower area of the shift table, that is, it can feed the entire table width from below. take place.

In a further particularly preferred embodiment, the box is mounted so as to be capable of swinging in a frame which has a stationary head piece in its upper region, the head piece being connected to the box via the air extraction nozzle with a circulating air separator and via flexible sleeves. Due to this compact and elegant design, sealing problems can only arise at the three nozzles on the box surface, which are connected to the stationary part of the non-oscillating frame, the head, via flexible sleeves. The seals can be designed to be particularly reliable since flexible sleeves that have been tried and tested for a long time can be used for this purpose. The operational safety through the seals ultimately leads to a trouble-free flow within the box.

In a preferred embodiment, the circulating air separator is connected to a suction fan and to a dust discharge line. In this way, the disruptive part of fine shells and dust can be removed from the air flow. It is also advantageous to connect the air recirculation duct to an aspiration connection for fine dust filters. A dust accumulation in the entire device can thereby advantageously be avoided and operational safety and hygiene increased. Due to the recirculation mode, only a small proportion of the total air volume has to be passed through the fine dust filter.

In a further preferred embodiment, the lower table area has a trough-shaped surface (stone or manor swamp) with through-openings in the trough bottom for additional separation of the product flow into a heavy and a light fraction.

In addition, with the invention, a high degree of stone reading can be carried out, specifically reading out any foreign heavy parts still present in the screened grain. In addition, little air is advantageously used and the method and the device are simple and, in particular, not very sensitive to fluctuations in throughput.

• ig. 1 die einfachste Form eines Kleintischauslesers für Steine,
• Fig. 2 die Produkteinspeisung auf den Schichttisch,
• Fig. 3 denselben Lösungsansatz wie Fig. 1, jedoch mit zwei Tischflächen, besonders für einen großen Produktdurchsatz,
• Fig. 4 eine Lösung gemäß Fig. 1, jedoch mit einem Umluftkanal,
• Fig. 5 eine Lösung gemäß Fig. 3, jedoch mit einem Umluftkanal,
• Fig. 6 die Fig. 5 mit Umluftabscheider,
• Fig. 7 ist eine Lösung ähnlich Fig. 3 mit zusätzlicher Bildung von zwei Schwerefraktionen nebst der Steinauslese,
• Fig. 8 ist eine Ausführungsvariante zu der Fig. 7,
• Fig. 9 zeigt einen Steinsumpf auf der Schichttischflä­che,
• Fig. 10 zeigt die Vorrichtung wie bei den Fig. 3, 7 und 8 mit durch den Kasten geführtem Umluftka­nal.

Some exemplary embodiments of the invention are explained in more detail below. It shows

• ig. 1 the simplest form of a small table reader for stones,
• 2 shows the product feed on the shift table,
• 3 the same approach as FIG. 1, but with two table surfaces, especially for a large product throughput,
• 4 shows a solution according to FIG. 1, but with a circulating air duct,
• 5 shows a solution according to FIG. 3, but with a circulating air duct,
• 6 shows the FIG. 5 with circulating air separator,
• 7 is a solution similar to FIG. 3 with the additional formation of two heavy fractions in addition to the stone selection,
• 8 is an embodiment variant of FIG. 7,
• 9 shows a stone sump on the layer table surface,
• Fig. 10 shows the device as in Figs. 3, 7 and 8 with the recirculated air duct guided through the box.

In the following, reference is now made to FIGS. 1 and 2. 1 shows a basic type for a new stone reader 1, the fresh grain being passed through an inlet 2 to a shift table 3 and being discharged from there as cleaned grain via an outlet 4. A closed hood 5 is arranged above the layer table 3 and has a suction opening 6 having. The hood 5 forms, together with the shift table 3, an oscillating device 7 which can be set in motion by a vibration exciter 8 with an oscillating component in the direction of the upper end of the shift table 3. The upper end of the layer table 3 is formed by a guide plate 19 as an end separation zone. The entire vibrating unit 7 is supported by spring elements 9 on a frame 10 which is fixed on a floor 11. Also fixed to the frame 10 is a non-vibrating head piece 12, in which the inlet 2 and an air suction line 13 are attached. Furthermore, an air quantity adjustment flap 14 is arranged in the air suction line 13 for setting the air aspirated by the entire stone reader 1. The connection of the vibrating parts, or the vibrating unit 7 and the head piece 12, takes place via flexible sleeves 15, which are arranged after the inlet 2.

When viewed in plan, the layer table 3 preferably has an at least approximately rectangular shape. On the side of the higher end of the shift table, the shift table 3 can be pulled out for service work. The product transfer point extends across the full table width. The width is designated in FIG. 2 with "B", the layer thickness with "D". The formation of a wide-area flow of goods 20, also called a good veil, for the purpose of feeding the goods takes place in two stages. As part of the swinging hood 5, the fresh grain is guided in a distribution box 17. The vibration promotes the uniform, wide distribution of the grain in the distribution box 17, which is widened downwards to reinforce this effect, is cascaded. The same purpose is served by a stowage flap 18 also provided in the distribution box 17, so that the grain material is passed as a wide-area product stream directly onto the guide plate 19 extending over the entire table width and then as a uniform, wide product stream 20 onto the layer table 3. The broad spread device of the product stream 20 is further supported by the fact that the guide plate 19 has an overflow edge 16 at its free end, that is to say it is trough-shaped. To pre-separate heavy and light goods, the trough-shaped guide plate 19 can also have bottom openings for the passage of the heavier admixtures.

The broad, uniform product flow spread on the shift table 3 is particularly illustrated in FIG. 2. The stratification is deliberately overemphasized in the same figure. The layer table 3 has a rough mesh screen 21 as a product support and is constructed in a manner known per se in the so-called sandwich construction, the mesh screen 21 forming the upper side, supported by honeycomb-shaped sheet metal strips 34 which are held downwards by a fine perforated plate 22 . In the individual fields 23 between the metal strips 34, cleaning bodies 24 are arranged which keep both the mesh 21 and the perforated plate 22 clean. It is also important here that the perforated plate 22 has an air resistance that is much greater than the air resistance of the mesh 21, z. B. in the order of 1: 10. With this measure, the air distribution can be kept approximately constant over the entire surface of the layer table 3 regardless of the layer thickness on the mesh screen 21.

The material stratification itself essentially consists of three different layers, a lower, heavy layer 25 containing the heavy admixtures being conveyed upward by the mechanical throwing motion. A light layer 26 freed from the heavy admixtures is kept in suspension not only in the relaxed state but also at a distance above the mesh 21 by the targeted air flow. Since the layer table 3 is slightly inclined and the upper light layer 26 does not directly face the table Received delivery impulse, but is kept in vibration, this swims towards the lower side of the table. In addition, the inclination of the shift table 3 can be adjusted by an adjusting device 35. A third layering 27 consists of the actual heavy admixtures, usually only individual particles, individual foreign bodies, stones 28, etc. Good, heavy grains 29 and light parts, e.g. B. half grains, shell parts 30 are shown in the approximately corresponding shape. The heavy material with the stones 28 immediately sinks onto the vibrating table surface 7 and moves up the table due to the vibration and the rough table surface designed as a mesh 21.

For the function described, it is now important that the air flow is guided correctly. The entire surface of the shift table is flowed through uniformly from bottom to top by a suction air flow, the direction of flow of which is illustrated by arrows 31. This air flow 31 brings the grain to a highly fluidized state. Since only the heaviest parts, i.e. H. the stones 28 are separated on the higher end of the table and are to be conveyed from there to a stone lock 45, a corresponding blow-back flow 33 is formed, which prevents light parts or grains with the heaviest admixtures from being conveyed upwards. The blow-back stream is preferably formed under the guide plate 19. If the guide plate 19 is firmly connected to the hood wall, the air guided in the slot between the guide plate and the shift table can only escape in the direction 33.

With the exception of the stones 28 located therein, the material is prevented from moving further upwards by the air flow in front of the final separation zone. The stones 28 can continue their movement towards the higher end of the table.

The same blow-back flow 33 causes a flow front or flow direction reversal 32 which is clearly established in practice. At the location of the flow direction reversal 32, the grain 29 freed from the stones 28 is lifted off the table surface by the strong air flow 31, 33 and now flows freely together with all light goods with the upper lifted light layer 26 down the table. The lightest fraction is discharged immediately at outlet 4; an average grain fraction can possibly make a circular traveling movement up-table-down several times, which is particularly true for boundary grains.

In FIGS. 1 and 2, the product stream 20 is fed directly into the zone of the flow direction reversal 32. The flow direction reversal 32 is generated from the three forces of mechanical conveying action up-table, floating of the upper layer 26 down-table and blow-back flow 33.

The main structural difference between FIG. 3 and FIG. 1 is that in FIG. 3 two shift tables, an upper shift table 3a and a lower shift table 3b are used. Basically, both shift tables 3a and 3b have the same structure, e.g. B. as in FIG. 2. In principle, the top blow table 3a lacks the blow-back flow 33, so that not only the heaviest admixtures, but the whole heavy layer 25 can be moved up the table and can fall onto the guide plate 19 through a discharge channel 40 via a steering plate 41. From the guide plate 19, the mode of operation of the shift table 3b is identical to that of the shift table 3 in FIGS. 1 and 2, respectively.

In order to prevent the freshly entering product stream 20 from the distribution box 17 from being mixed directly with the heavy layer 25, a guide plate 42 is arranged at the uppermost point between the distribution box 17 and the layer table 3a.

The flowing product stream is drained via a product lock 43 directly into an outlet channel 44 of the lower layer table 3b. The two material flows of the two shift tables 3a and 3b, which are the heaviest admixtures, are then brought together again in the outlet 4. All heaviest admixtures, such as stones 28, etc., are first separated from the upper layer table 3a together with the heavy layer 25. The actual separation and the separate removal of the stones 28 via the stone lock 45 then take place on the lower layer table 3b. The stone selection takes place here in two temporally and spatially separated stages. This is because concentrate is first formed with all heavy goods, e.g. B. 30% to 60% of the entire material throughput on the upper shift table 3a and only from the reduced material throughput the stones and other heaviest admixtures are read out and carried away separately.

FIG. 4 is identical to FIG. 1 in terms of product management, and FIG. 5 corresponds to FIG. 3. The solution concept of FIGS. 4 and 5 additionally contains an all-round closed box 50, which can be closed by the, respectively the shift table (s) is divided into an upper suction chamber 51 and a lower suction chamber 52. Laterally at the lower end of the or the shift table (s) is a recirculation channel 53, which is connected via a flexible hose 54 and an air return pipe 55 'to an air return line 55. An air flow restrictor 56 is arranged in the air return line 55. 4 and 5, the box 50 itself is supported on the stationary frame 10 by means of spring elements 9. At the top of the box 50 is on one end side of a Guteinlaufstutzen 2 'connected to the inlet 2, approximately in the middle with the air suction line 13 interconnected air suction 13' and on the opposite end side with the air return line 55 connected to the air return line 55 'arranged. The aforementioned connections 2 ', 13', 55 'are connected via flexible sleeves 15, 54 on the one hand to the non-vibrating head piece 12 and on the other hand to the box 50 in order to be able to participate in its movement in this way. In the double machine in FIG. 5, two outlets 4 are arranged as tubular product channels 57 on both sides (perpendicular to the image plane), so that the remaining space between the two product channels 57 remains for the circulating air channel 53. The box 50 is bordered in Figures 4 and 5 for better identification with a dashed line.

In addition to FIGS. 4 and 5, FIG. 6 additionally shows a circulating air separator 60 with a suction fan 61 and a motor drive 62. The air suction nozzle 13 leads directly into the circulating air separator 60, the essential or disruptive part of fine shells and dust being removed from the air flow via a dust discharge line 64.

In most cases where recirculated air is used, air cleaning is advantageous because it can effectively avoid dust accumulation in the entire device and increase operational safety and hygiene. The recirculation mode has the great advantage that only a minimal amount of air, e.g. B. 10% of the circulating air volume must be passed through fine dust filters. For this purpose, an aspiration connection 65 is provided. The circulating air separator 60 can be attached directly to the ceiling 66 with a fan.

Fig. 7 has a fundamental difference compared to Fig. 3 insofar as in Fig. 7 only a small part of the material throughput from the upper shift table 3c at the highest point through a series of larger holes 71 across the entire table width down the upper zone of the direction of flow reversal of the lower layer table 3d is released. The Most of the heavy goods are passed in the area of the lower table end via a chute 72 approximately to the middle of the lower layer table 3d, again over the entire table width. Many series of measurements have shown that, with this solution, the large part of the stones is nevertheless released through the holes 71 directly onto the lower layer table 3d. In the solutions according to FIGS. 7 and 8, it is important that the upper layer table only has a less rough surface than the lower layer table 3d, as shown in FIG. 9, by the upper layer table 3c made of perforated sheet metal and the lower layer table 3d is formed from mesh.

A particularly interesting, independent idea is now shown in FIGS. 8 and 9. This is the use of a stone sump 80 in the area of the upper layer table 3c. The method of operation is as follows: The stone sump 80 consists of a trough-like depression 81 which extends over the entire width of the layer table 3c. Similar to FIG. 2, two different layers are formed in FIGS. 8 and 9, namely the heavy layer 25 and the light layer 26 freed from the heavy additives.

• 1. Es ergibt sich auf diese Weise ein sehr hoher Auslesegrad für die schwersten Beimengungen (Steine, usw.)
• 2. Es kann mit nur einem minimalen Mehraufwand zusätzlich zu der Abtrennung der schwersten Beimengungen in eine saubere schwere Fraktion (gute Körner) und den Rest in eine leichte Gutfraktion (Schalen, Schmacht- und Bruchkörner) getrennt werden.

Because the surface of the upper layer table 13 has only a slight roughness, there is no actual upward flow; at least the whole heavy layer 25 cannot be moved up. Rather, the lower heavy layer 25 flows down the table in a greatly delayed manner, as is indicated by the single arrow 82. In contrast, the light layer 26 flows down the table at high speed (double arrow 83). The heavy layer now sinks, once it has reached the area of the recess 81, into the stone sump 80. The stone sump 80 now has a number of through openings 84 on its bottom, through which part of the material, together with the stones, continuously onto the underlying slide 72 or the lower shift table 3d is carried out. With the correct coordination of the number of effective diaphragm openings 84 in relation to the mass flow of the heavy layer, the light and heavy layers can be separated in such a way that the heavy layer 25 continuously sinks completely into the stone sump 80 and is discharged directly downwards. This has two major advantages:

• 1. This results in a very high degree of selection for the heaviest admixtures (stones, etc.)
• 2. In addition to separating the heaviest admixtures, it can be separated into a clean, heavy fraction (good grains) and the rest into a light good fraction (shells, grainy and broken grains) with only a minimal additional effort.

This makes it possible to separate the different basic fractions (stones, etc., heavy, light) in a single device and with very high quality.

Finally, FIG. 10 shows a device which functions according to the same principles as the device according to FIGS. 3, 7 and 8. For this reason, the description of the same components is not repeated here. The device according to FIG. 10 differs from the aforementioned devices only in that a recirculating air duct 53 is arranged separately in the box 50, and the influence it has on the flow properties of the air in the box 50 can be avoided.

Claims (33)

1. A method for reading out heavy admixtures, in particular stones (28) from grain material, in which the material is fed onto a shift table (3; 3b; 3d) and essentially layered and passed over the inclined, air-flowed and vibrating shift table surface in such a way that the on the shift table (3; 3b; 3d), heavy admixtures lying directly on top are conveyed upwards and discharged separately at the higher end of the table,
characterized in that
the material is fed as the broadest possible flow into the area of the separation zone of the material layers (25, 26) located at the higher end of the table. 2. The method according to claim 1, characterized in that on the layer table (3; 3b; 3d) a uniform layer flow (25, 26) (heavy (25) table on upward, slightly (26) downstream of the flow direction (32) in the region of the higher end of the layer table (3; 3b; 3d), so that the product stream (20) is fed directly into the region of the flow direction reversal (32). 3. The method according to at least one of the preceding claims, characterized in that the material is first fed to a first, upper layer table (3a; 3c) and that at least a first part of the upstream table, from a mixture of heavier grain (29) and stones (28) existing heavy goods fraction (25) is guided at the upper end of the first table (3a; 3c) in such a way that the heavy goods fraction (25) broadly covers the upper end region of a table surface through which the same air flows and of a second lower lower table (3b ; 3d) is fed. 4. The method according to claim 3, characterized gekennziechnet that the material on the upper shift table (3a; 3c) is moved up with a lower conveying component than on the lower shift table (3b; 3d) and a second part of the heavy goods fraction (25) from the upper Shift table (3a; 3c) is fed to the area of the lower end and / or the center of the lower shift table (3b; 3d). 5. The method according to at least one of the preceding claims, characterized in that the product stream (20) is fed via a guide bleach (19) arranged at a distance above the table surface. 6. The method according to at least one of the preceding claims, characterized in that the product flow in the direction of flow of the light grain layer (26) (or against the flow direction of the heavy grain layer (25)) is fed. 7. The method according to at least one of the preceding claims, characterized in that for the separation of the heaviest admixtures (stones (28)) from the grain (29) an air stream (blow-back flow 33) in the direction of a reversal of the direction of flow of the upward moving grain (29) on the Separation zone (32) is blown. 8. The method according to claim 7, characterized in that the blow-back stream (33) between the guide plate (19) and the layer table (3; 3b; 3d) is guided. 9. The method according to at least one of the preceding claims,
characterized in that
the at least one shift table (3; 3a; 3b; 3c; 3d) is placed in common vibrations together with a covering assigned to it for recirculation mode with separate guides for supply and exhaust air. 10. The method according to claims 9, characterized in that the lining together with the shift table (3; 3a; 3b; 3c; 3d) forms a vibratably supported box (50) and the box (50), including the shift table (3; 3a ; 3b; 3c; 3d) is set in common vibrations. 11. The method according to claims 9 or 10, characterized in that the good feed as a wide-area stream in the area of the higher table end separating zone (32) of the good layers (25, 26) takes place, the air removed from the top center of the panel and Wide area in the area of the lower end of the shift table becomes. 12. The method according to at least one of claims 9 to 11, characterized in that the circulating air in the region above the central air discharge (13) and the lower air supply (23) is cleaned of dust components. 13. The method according to at least one of the preceding claims with two layer tables arranged directly one above the other (3c, 3d), characterized in that the material on the upper layer table (3c) is guided over a trough-shaped depression (stone and material sump (80)) which heavy material fraction (25) entering the recess via bottom openings (84) of the recess and then via a slide (72) inclined in the opposite direction to the upper layer table (3c) to the middle area of the lower layer table (3d), which is led into The flow direction of the trough-shaped depression (80) of the upper layer table (3c) overflowing light material fraction (26), however, is fed to an outlet (44) for light material. 14. The method according to at least one of the preceding claims, characterized in that an oscillating suction hood and a stationary platform (12) arranged above it is assigned to the shift table, the material being fed in via an inlet (2) in the stationary platform (12) flexible sleeves (15) are guided into a distribution box (17) of a feed channel that resonates with the suction hood and is poured from the distribution box (17) in a cascade-like manner via a guide bleach (19), thereby producing a multitude of falling currents across the entire width of the shift table. 15. Device for separating and reading out heavy admixtures from a product stream (2), in particular stones (28) made from grain material (29) with a feed channel for feeding the product stream (20) onto an inclined layer table (3; 3b; 3c) with an oscillating conveyor component in the direction of the higher table end,
characterized in that
the dining channel opens into the area of the higher table end. 16. The apparatus according to claim 15, characterized in that the feed channel opens over the entire width of the layer table (3; 3b; 3c;). 17. The apparatus according to claim 15 or 16, characterized in that the mouth of the feed channel has a guide bleaching (19) arranged at a distance above the shift table (3; 3b; 3d). 18. The device according to at least one of claims 15 to 17, characterized in that the feed channel has a distribution box (17) and the guide bleach (19) which form a cascade for the food product stream to generate a uniform falling stream over the entire width of the shift table. 19. The apparatus of claim 17 or 18, characterized in that the guide bleaching (19) in the region of its end pointing in the direction of flow has an overflow edge (16) and bottom openings, such that the main amount of the material as a wide-area flow of material (20) on the shift table (3; 3b; 3c) flows and the heavy admixtures (28, 29) are discharged through the bottom openings. 20. The device according to at least one of claims 17 to 19, characterized in that an end separation zone for reading the stones is arranged between the guide plate (19) and the table surface of the layer table (3b). 21. The device according to at least one of claims 15 to 20, characterized in that two jointly vibrating shift table (3a; 3b; 3c; 3d) are arranged directly one above the other and the same air flows through them. 22. The apparatus according to claim 21, characterized in that the lower layer table (3b; 3d) has a larger conveying component in the upward direction than the upper layer table (3a; 3c) and for this purpose its surface is rougher than that of the upper layer table (3a; 3c) . 23. The device according to claim 22, characterized in that the upper layer table (3a; 3c) has at its higher end at least one serving as a feed channel for the lower layer table (3b; 3d) discharge opening (40; 71). 24. The device according to claim 23, characterized in that the feed channel for the lower layer table (3b; 3d) extends over the entire width of the upper layer table (3a; 3c). 25. The device according to at least one of claims 21 to 24, characterized in that the two layer tables (3a; 3b; 3c; 3d) are arranged in relation to one another such that the upper layer table (3a; 3c) well on the upper table end of the lower layer table (3b; 3d) feeds. 26. The device according to at least one of claims 15 up to 25
characterized in that
the at least one shift table (3; 3a; 3b; 3c; 3d) is part of a box (50) which vibrates together with it and is designed for recirculation mode. 27. The apparatus according to claim 26, characterized in that a material feed (2) is part of the box (50). 28. The apparatus according to claim 26 or 27, characterized in that within the box (50) are provided: an air suction space (51) and a separate air supply duct (53) which in the region of the lower end of the at least one layer table ( 3, 3b; 3d) opens. 29. The device according to at least one of claims 26 to 28, characterized in that on the top of the box (50) are arranged: on one end a good inlet (2), approximately in the middle an air suction nozzle (13) and on the opposite end an air return line (55) for the air recirculation duct (53). 30. The device according to claim 29, characterized in that the box (50) is mounted so that it can vibrate in a frame (10) which has a stationary head piece (12) in its upper region, the head piece (12) above the air suction nozzle (13 ) with a circulating air separator (16) and via flexible sleeves (54) with the box (50). 31. The device according to claim 30, characterized in that the circulating air separator (60) with a suction fan (61) and with a dust discharge line (64) is connected. 32. Device according to at least one of claims 26 to 31, characterized in that the recirculation channel (53) is connected to an aspiration connection (65) for fine dust filters. 33. Device according to at least one of claims 15 to 32, characterized in that the upper table surface (3a) in its lower region a trough-shaped depression (stone or manor sump 80) with through openings (84) in the trough bottom for additional separation of the product flow in has a heavy (25) and a light fraction (26).

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