AT393466B - VIBRATION SEPARATOR - Google Patents

Description

AT 393 466 B

The invention relates to a vibration separation device.

Such separation devices have been known for a long time and are used in particular for separating bulk material mixtures.

For example, DE-PS 28 54 177 describes a device for separating rejects contained in a pile. The heap is applied to a substantially horizontal plate, which is arranged in a housing. The housing is vibrated in an oblique direction with respect to the vertical, as a result of which the heap reaches the free edge of the feed plate lying inside the housing and from the Plate falls. It encounters a sloping conveying surface that projects under the edge and that is in the conveying direction - d. i. the direction of the vibrations - is profiled, as a result of which parts with a certain combination of geometric shape, density and adhesion on the inclined conveying surface move upwards, but the others move downwards. At the ends of the conveyor surface located in the conveying direction, the components of the pile to be separated can be removed separately.

From No. 1/1988 of the " Processing Technology " a theoretical treatise on the vibration sorting of shredder scrap is known. This immersion comes to the conclusion that the parallel arrangement of several vibrating trays increases the throughput, while the series arrangement of several trays increases the selectivity or the efficiency

As can be seen from this article, when four vibrating trays connected in series were used, a mixture of 50% by volume non-ferrous scrap with 50% by volume rubber was 98% recovered, but the rubber was still about 20% % in the

Scrap component included. The bulk density of the starting material was 800 kg / πΑ. The filling material was only about 45% full, while the void fraction made up about 55%. In general, poorer results can be expected for mixtures with a lower void fraction.

The series connection of several floors is also known from EP-Al 0139 783. The last floor is also designed as a transport device because it is bent like a roof. The break point represents the transition from the swinging floor to the transpoit sheet, beyond the break there is no longer any separation

Furthermore, it can be seen from this document that sieves are provided above the uppermost floor, which may be inclined, and which discharge the material falling through onto the uppermost vibrating floor below the deepest sieve. As a result, the good assignment takes place over an area of the top floor

Such a device is known from US Pat. No. 4,267,037, but the good feed according to this document takes place at the "head" of the system on its own, level feed floor

From US-PS 4 009 833 and FR-PS 78 31596 with publication number 2 407 676 it is known to design oscillating floors as sieves or to provide sieve sections at certain points. The floors used are all degenerate into smooth surfaces, so that we cannot speak of a series of vibrating floors. Both systems serve special purposes, namely the removal of parts of defective batteries or the removal and recovery of tobacco residues from the cigarette store.

In addition to vibrating floor vibrating devices of this type, sieve devices with vibrating sieves are also known, but in which, as is generally the case with sieves, the material to be sieved may or may not be due to the size because particles pass through the sieve, the combination of geometric, density and friction properties mentioned at the beginning at the bottom (sieve) plays no noticeable role and the goods are not divided by the fact that one fraction moves preferentially over one plate edge and another fraction over another plate edge. Usually, several sieves are arranged from top to bottom with passage openings becoming smaller, but there are also other combinations.

It is known from DE-OS 33 24 926 to apply screenings, which consist of at least two fractions, to separate screens in at least two partial streams in order to sieve a large part of the one fraction here. In the middle of the device the two partial streams are combined and the remaining stock of the fraction is screened out along a common screen section. This results in a reduced and, at the end of the sieving process, an increased load on the sieve surface with the fraction to be sieved out, which is in each case closer to the optimal load than in the case of conventional sieves.

From DE-Al-31 39 279 a vibrating machine for sieving and / or conveying is known, in which to increase the working area, in particular in width, without having to accept the usual disadvantages · disproportionate increase in mass, greatly increased energy requirement, It is proposed to subdivide the work surface into at least two work surface segments that can be oscillated independently of one another and / or one behind the other in the flow or conveying direction of the goods, and to provide each segment with an oscillatable bearing and a drivable vibration exciter. The resulting, during the swinging variable gaps between the individual segments are bridged when used with small-sized conveyed material with elastic seals.This device also works, if a separation is to be made, as a sieve and not like a series of swinging floors, since there is no one between the segments Sieve passes

The disadvantages that sieves have in comparison to vibrating body constructions occur fully with the sieve structures mentioned: risk of blockage and contamination, complex construction, expensive -2-

AT 393 466 B

Screen areas, low throughput and short service life.

In contrast, the invention has the aim of creating a compact vibrating floor system which improves the separation performance for all mixtures of solids, with a larger throughput also not leading to a deterioration in the separation performance. According to the invention, this is achieved in that, as is known in the case of individual floors, two Rows of floors are connected in series, the direction of vibration of the two rows is the same, but the inclination of the floors of the two rows is different

In an advantageous embodiment, the inclination of the bottoms of the first (upper) row to the horizontal is smaller than the inclination of the direction of oscillation to the horizontal. The aim in the first row is a verbes-10 series pre-sorting, which further increases the overall separation efficiency of the system.

In a preferred development it is provided that the bottoms of the second row are bent along a horizontal edge transverse to the direction of vibration in such a way that their underside is concave, the flatter section preferably being flatter and the steeper section being steeper than the direction of vibration with respect to the horizontal . This measure makes it possible to increase the throughput of the system without the separation efficiency deteriorating

The last-mentioned embodiment is advantageously developed in such a way that the material falling from the first row of floors between the swinging floors hits the immediate area of the kink of the floors of the lower row. Given a given good, a given inclination of the two rows and a given oscillation frequency, this goal is easy to achieve using a few tests and leads to particularly good separation results. 20 Instead of being kinked, the bottoms can also have an arc shape, in this case the impact area is approximately that which runs parallel to the direction of vibration

The invention is explained in more detail using an exemplary embodiment with reference to the accompanying drawings

A separating device (1) according to the invention has eight bottom plates (11) in an upper row (A) and eight separating plates (21) in a lower row (B). In the example shown, the rows (A and B) 25 are parallel to each other «, but this is not necessary.

All sixteen separating trays are permanently mounted in a housing (131). In the example, an unbalance drive (132) is provided at the lower end of the separating device (1). In such a drive, two masses (133) of equal size are known to run symmetrically to one another in the opposite direction of rotation about axes parallel to one another. The plane of symmetry held is the oscillation plane 30 of the entire device indicated by the arrow (f).

The inclination of this direction of oscillation (f) is greater than the inclination of the oscillating vents (11) d «row (A) in the exemplary embodiment opposite the horizontal (h).

The swing floors (21) of the row (B) are bent around a horizontal edge (32) that runs normal to the swing direction (f). The upper part (33) of the swing floors (31) v «runs flatter than 35 the lower part ( 34) of these swing floors. As a result, a concave formation is achieved below the oscillating floors in the area of their attachment to brackets of the housing

The top floor (11 ') of the row (A) is the loading point. In the case of the exemplary embodiment, it is provided on its upper side with a “deflection bar, which prevents a part of the applied material from leaving this floor upwards.” From this “loading point, the material to be separated moves, braked by the vibrations 40 of the device (1) , from one floor (11) to the next, parts of the material falling into the gaps (12) left between the floors. Such material preferably falls through the gaps that rolls and / or jumps poorly and tends to remain on the floors (11). The vibrations loosen it to such an extent that it slips and preferably falls through the gaps (12)

It preferably falls directly on the area of the edge (32) of the kinked bottoms (21) of the 45 second row (B), which is indicated by a particle loop in the drawing

In the upper row (A) the rollable material preferably reaches the lower end of this row, from where it falls on the lowest area of the lower row (B)

That part of the material that is conveyed upward in the row (B) against gravity on the individual floors (21), ie. L the part with the lower density and the better adhesion to the floors 50 or the part of the material to be separated which is not easily rollable leaves the floors of the lower row (B) at the upper end and thus passes through cracks ( 36) between the floors in the area above the separating strip (34) of the housing.

The other, heavier or rollable parts leave the bottom plate d «second row (B) on the underside and v« leave the device below the separating strip (34). At least in the area d «lower row (B), these parts reach from floor to floor and, because of their horizontal speed, do not fall into the gaps (36) between the floors (21).

With the knowledge of the invention, the control of the material flow between the two rows can easily be adapted to the respective separation process. It is possible, for example, to provide one of the two rows inside the housing so that the individual material loops 60 falling through the gaps (12) can be directed correctly to the desired points of impact on the floors (21).

In one embodiment of the invention, when separating suitable materials, provision can be made for an advantageously upward air flow in the area between the two rows (A, B).

AT393466B to be provided by means of a blower or the connection to a compressed gas line, as a result of which a certain sighting of the particles takes place in flight, which in particular with a corresponding adjustment of the impact points on the bottom row of rows leads to a further improvement in both the throughput and the separation performance

It is of course also possible to equip the two rows with a different number of floors, in particular to extend the lower row (B) downwards.

The device according to the invention has, for example, when sorting stones and other solid, hard materials from sawdust or chips for the production of chipboard and. The like, but also excellently proven when sorting out glass chips from humus. In such applications, it is particularly important that the undesired material is eliminated with certainty in order to avoid destruction or damage in the subsequent processing of the desired material, but on the other hand it is important Eliminate as little of the desired material as possible with the undesired material, as this severely affects the profitability of manufacture.

The device, which has proven itself excellently in this area of application, works with vibration ranges between 1.6 and 12 mm at 3000 to 1000 vibrations per minute, with the high frequencies being assigned to the low vibration ranges. It was even possible to remove sands from sawdust with the device tested.

Knowing the invention, it is easy for a person skilled in the art to modify them variously and adapt them to predetermined boundary conditions. Thus, if desired, further rows of floors can be provided, and even when sifting materials with a continuous range of properties, individual partial streams of the sifted material can be subjected to various further treatments in the same device. It is conceivable, for example, that only a middle fraction obtained is fed to a third or fourth row of trays, while the head or foot fraction is removed from the device.

It is also possible not to bend the bottoms of the lower row, but to bend them, and thus to achieve a spectral distribution around the point of impact. The bottoms of the top row can also have a different size than that of the bottom row, it preferably being provided that their length in the direction of vibration is a multiple of the length since bottoms of the bottom row. For many areas of application, it is advantageous to provide the shelves (11, 21) rotatably in the frame, since in this way consideration can be given not only to the upper row (A) overall, but also to the separation within row (A) . For this reason, the slots (12) between the floors (11) of the upper row are preferably individually adjustable, for. B. by the floors (11) in a groove or the like. In order to be able to adjust the points of impact on the floors (12), it is also advantageous in this case to be able to move the lower floors (12).

It is, of course, also possible to change the size of the floors using valangular pieces or the like so that the width of the column assumes the desired value. It is also conceivable to carry out the vash swiveling of the floors in groups, each floor being rotated about a fixed, horizontal axis which is perpendicular to the direction of oscillation, but the swiveling itself takes place jointly for some floors, e.g. B. by means of a joint parallelogram.

Since the material flow through the individual columns (12) should be adjusted by the choice of column width and the inclination of the above floors so that the load on the lower floors with material to be separated is as equal as possible for all floors.

It is conceivable in the last-mentioned configurations that individual floors of the upper row (A) and the lower row (B) have the same or almost the same inclination, but in contrast to known arrangements there are always floors in the two rows, one have different inclinations. If more than two rows are provided, the measures according to the invention always relate to adjacent rows, additional rows which are identical to one of their neighboring rows can be provided without further notice.

The rows themselves can also deviate from the ideal linear arrangement, e.g. B. if a wind sifting of the falling material is carried out at the same time, the bottoms because the two rows which are the most distant from the gas introduction also have the greatest vertical distance from one another.

In the case of wind sifting, the horizontal arrangement of the bottoms of the lower row relative to the gaps between the bottoms of the upper row is advantageously made such that the material flowing in the form of a veil through the crevices does not affect the influence of wind sifting on the kink or the transition area of the lower Soils. -4-

Claims (8)

AT 393 466 B PATENT CLAIMS 5 1. Vibration separating device with oscillating floors connected in parallel, characterized in that two 10 rows (A, B) of oscillating floors (11, 21) are arranged in series, and that the inclination of the floors of the two rows is different. 2. Vibration separating device according to claim 1, characterized in that the inclination of the bottoms of the first (upper) row (A) to the horizontal is smaller than the inclination of the direction of vibration (f) to the horizontal. 15 3. Vibration separating device according to claim 1 or 2, characterized in that the bottoms of the second row (B) have a flatter and a steeper section and are concave downwards, preferably the shallower section being flat and the steeper section being steeper than the direction of vibration the horizontal is 20 4. Vibration separating device according to claim 3, characterized in that the vibrating trays (11, 21) of the two rows (A, B) are arranged in such a way that from the first row of trays through the gaps (12) between the vibrating trays (11) in shape material falling from veils strikes in the area of the transition of the two sections of the bottoms (21) of the lower row (B). 25th 5. Vibration separating device according to one of claims 1 to 4, characterized in that the columns (12) between the upper floors have adjustable width. 6. Vibration separating device according to one of claims 1 to 5, characterized in that the upper 30 and / or lower floors (11, 21) can be pivoted individually or in groups about a horizontal axis perpendicular to the direction of vibration. 7. Vibration separating device according to one of claims 1 to 6, characterized in that an air or gas flow is passed in one direction through the device, which runs in the direction of vibration (f) or transverse to the 35 material slurry or between these two directions, around the If necessary, bring a material «into the air. 8. Vibration separating device according to one of claims 1 to 7, characterized in that at least the bottoms of one of the rows (A, B) are not arranged in alignment. 40 45 Hiezu 1 sheet drawing -5-