DE2641068A1 - Air sifter for granular material - uses settling tank for conveying channels and removal of oversized particles - Google Patents

Abstract

The sifting plant serves for sifting grain material used for chipboard production. The plant removes also oversize grain and sand from the sifted material. The plant is fitted with zig-zag sifting channel (1) with settling tank (2) mounted underneath consisting of perforated material carrier surface (3) on which a thin layer of glass balls is provided. Shanking mechanism (5) keeps the carrier in vertical swinging motion. The material, still containing sand, is fed into the plant via hopper (6). Underneath the carrier bed fan (7) fitted with rotating valve (8) on its discharge side produces an intermitten airflow, whereby the layer of material on the bed is lifted and continuously turned over. The heaver particles i.e. sand drifts downwards into chutes (10). The fine particles i.e. chips are kept in a floating state by jets (12) and finally enter the zig-zag channels of the sifter (1).

Description

Riser air sifter for the desanding of wood chips

The invention relates to a riser pipe wind sifter with parallel sifting tubes for the sifting of wood chips for chipboard production, with the next to the separation From Oberkorn it is also possible to sand the wood chips at the same time.

The processing of wood chips into one for chipboard production suitable Fonii requires extensive equipment with large space and cost needs.

So it is necessary that the top grain is removed from the wood chips, as it is above all the strength, the surface quality and also the appearance of the finished product Chipboard significantly impaired. The upper grain is separated off frequently in riser air separators, e.g. B. zigzag separators with parallel sight tubes to which the feed material is fed at the foot of the sight tubes.

Such separators consist of a device for transporting the feed material and feeding to the sighting tubes and removal of the upper grain from the actual Classifier with a series of parallel, from which the classifying air flowed through from bottom to top Sight tubes and subsequent devices to even out the air flow, as well as from pipelines, finished product separator and exhaust fan.

In addition to the separation of the top grain, the desanding of the Wood shavings are especially necessary for the top and middle layers because that is in the storage area and other material contaminated with sand during further processing makes expensive knife tools unusable in a very short time, as well as in leaves holes and cracks in the sanded surfaces of the finished chipboard.

For the desanding of the wood chips, sieves or sifters are different Types used, which the sand according to the respective equivalent grain size create into fine or coarse material. The diameter is the equivalent grain size to understand spheres that have the same physical properties as the irregularly shaped good particles, d. H. treated by the sieve or sifter in the same way are like the relevant chip or

the grain of sand in question.

It has been shown that the sanding of the wood chips with sieves or However, sifting alone is not a satisfactory solution. The screening does not bring the necessary cleanliness of the goods and, moreover, often a cumbersome screen change or a sieve cleaning is required. When sighting it is a disadvantage that usually considerable amounts of good chip material are carried out with the sand, and the finest portion of sand remains almost completely in the sintered fine material, i.e. in the Particle board is also processed.

A well-known ascending pipe separator seeks to solve this problem by that the bottom of the classifying space is designed as a sieve. It is thereby achieved that the sand collects and passes through the sieve as a result of boundary layer effects whose holes fail downwards. The disadvantage here is that only part of the abandoned Good in contact with the boundary layer on the sieve comes so that off the other part is the total fine fraction X determined by the separating limit of the separator of the sand goes into the chipboard production.

Experiments by the inventors have shown that it is possible to use the sand separated from the wood chips by means of an air jig known per se.

The disadvantage here is that a separate machine is required, to the particular also devices for the separation of the in the exhaust air of the setting machine The fine chips contained and their re-admixture before the panel production. Due to the high proportion of fine chips, these devices are very extensive, so that they require a considerable amount of space and costs.

The object of the invention is therefore to create a device with desanding that meets the requirements for chipboard production the wood chips is possible with the lowest space and cost requirements.

The solution to this problem is that in a riser air classifier the device with parallel sight tubes with feed of the sight material at the foot of the sight tubes for the transport of the goods and their supply to the sight tubes and for the Removal of the upper grain is designed as a setting bed of an air setting machine.

This arrangement enables the functions of two individual machines carried out by a single one, thereby saving a considerable amount of space and costs can be achieved, because the extensive devices for the deposition of in the The fine chips contained in the exhaust air of the jig are dispensed with, as are the transport devices of the riser separator.

When setting work with pulsating blasts of air, the entire feed material, d. H. the wood chip-sand mixture, constantly turned in the bed, and finally like that stratified so that the specifically heavy part, i.e. the sand, migrates downwards and the wood portion is arranged above it. The top layer of wood is in brought the area of influence of a higher and uniform flow velocity, through which the sanded wood shavings to the riser air separator arranged above the settling bed Tobe offered. The oversized grain separated by the sifter falls back onto the settling bed back and is transported in this transverse to the direction of flow to the outlet. The chip material taken up by the sifter is known as the finished product Tracks separated and sent for further processing.

All versions of the known air setting machines can be used as a set bed be used. However, a set bed has proven to be particularly effective Settlement carrier an auxiliary layer made of, for example, ceramic or glass spheres is placed and the seed carrier in vibrations - preferably in a vertical position Direction - is offset, whereby the auxiliary layer is subjected to a loosening will. As is known, this ensures that the downward movement is achieved through the setting work Sunken material, in this case the sand, through the auxiliary layer and the sediment carrier is discharged through it without first being transported transversely to the direction of flow the air through the whole set bed would be required.

However, there is a problem with the training according to the invention in that the flow velocity of the working air in the settling bed is essential must be less than in the ascending pipe separator above, so not finer Sand is carried up into the sifter area and so in the Sifter fine material arrives. Another problem is that flow cross-sections of sifter and bed according to different laws depending on the type of to processed goods and the 4 aabenstellung are to be interpreted. The set bed cross section can therefore be larger, equal to or smaller than the sifter cross-section. The amount Experience has shown that the setting air, on the other hand, is usually greater than the amount of air that is visible smaller, in exceptional cases at most equal.

The full amount of air is then introduced by introducing additional Obtain air above the setting bed, which together with the setting air, the sifting accomplished. It is useful if the outlet openings for the additional Air are designed as nozzles to generate sharp jets, which are used to to blow the top layer of the settling bed up to the sight tubes. The required The transition from the bed cross-section to the smaller sifter cross-section is preferred arranged in the area of the top layer of the bed, whereby it should be noted that that the set bed height from the feed point of the material to the top grain discharge decreases evenly. In order to ensure an even load on the individual sight tubes received, it can therefore be useful to place a displacement body above the settling bed to attach. By choosing the cross-sectional shape of this displacement body can achieve a cross-sectional constriction adapted to the respective operating conditions. It can be advantageous to use the displacement body as a feed line for the additional To use part of the sifting air. The displacement body is then with the corresponding To provide outlet openings.

There is another possibility for supplying the additional classifying air in this, to carry them away in countercurrent over the settling bed, which in this case with the same The width of the sight tubes is made, and its length is correspondingly larger is than that of the riser windsifter. For better transport of the top grain the bed can be divided into stepped sections.

Exemplary embodiments of the invention are illustrated with reference to the drawings explained in more detail. 1 shows a riser pipe air classifier with a settling bed in a longitudinal section FIG. 2 shows the ascending pipe air classifier according to FIG. 1 in cross section with a displacement body above the set bed Fig. 3 shows another embodiment of a riser pipe wind sifter with stepped sections of the set bed.

The ascending pipe sifter according to FIG. 1 consists essentially of the parallel zigzag sight tubes 1 and the settling bed 2 underneath, in which 3 glass balls 4 lie in a thin layer on the perforated set carrier, and that is caused by the vibrator 5 in vorzugsvfe, se vertical vibrations. The sifted material contaminated with sand is fed through the airtight feeding device 6 abandoned the riser air separator. The fan 7 with downstream The pulsating setting air generated by the rotary valve 8 is passed through equalizing sieves 9 fed to the bed 2 from below. This is what makes the material to be seen - in this case that Wood chip-sand mixture - constantly turned and finally layered in such a way that the specifically heavy portion, i.e. the sand, migrates downwards and through the Riittlern 5 loosened layer of glass balls 4 and the set carrier 3 through it falls into the discharge cell lock 10. The wood chips are made from the layer Glass balls 4 are not allowed through, but remain in the by the weir 11 determined layer height on the settling bed. This is where the top layer comes in in the area of influence of the nozzle-shaped outlet openings 12 opening here for the additional amount of air drawn in from the room and is constantly being whirled up and at the same time the zigzag sight tubes 1 offered. The fine chips are in these separated from the top grain, which falls back onto the settling bed, while the fine chips be taken up by the sifting air and separated in the cyclone 13. the Fan 14 is responsible for extracting the classifying air. The oversized grain gradually migrates transversely to the direction of flow of the setting air in the setting bed to the outlet 15 and is discharged here through an airtight lock 16.

With a riser pipe wind sifter designed according to FIG. 1, for example in the case of wood chips with a sand content of around 3%, which are used as a top layer in chipboard production are used, the sand content can be reduced to 0.3% in the finished product, whereby this remainder consisted only of the very finest particles that were used in further processing no longer appear disturbing.

The riser air classifier according to Fig. 2 is designed so that sight tubes 1 and set bed 2 have the same air flow rate. So no additional ones here Air required. The lower rate of climb in the settling bed is achieved through greater width of the set bed 2 achieved. The required transition from the set bed cross-section to the smaller sifter cross-section is in the area of the top layer of the settling bed. An even load on the sight tubes 1 is ensured by a displacement body 17 reached, with its cross-sectional shape a gradual cross-sectional transition and an automatic control of the layer height of the settling bed is achieved because with increasing The amount of material in the settling bed is above the average operating value lying proportion in the spaces formed by the displacement body 17 and the walls 18 pushed and immediately seized by the rising air flow and upwards taken into the sight tubes.

In the embodiment according to FIG. 3, the set bed 2 is step-shaped separated sections divided. The difference to the ascending pipe wind sifter Fig. 1 and 2 is that the additional air at the outlet 15 for the Oberkorn is introduced and for the pneumatic conveying and foraging of the Oberkorns is carried away in countercurrent over the settling bed.

The outlet 15 for the oversized grain can be because of the omitted lock 16 make it easier.

Claims (9)

Claims (Öi. Riser pipe wind sifter with parallel sight pipes, in particular zigzag sifter, with feed of the material to be separated at the foot of the sifting tubes Sifting of wood chips for chipboard production, thereby g e n e n c e i c h n e t that the device for the transport of the material to be classified and its supply to the sight tubes (1) and one for the removal of the top grain as a settling bed (2) Air jig is designed. 2. Riser pipe wind sifter according to claim 1, characterized in that g e k e n n z e i c h -n e t that the set carrier (3) of the set bed (2) has an auxiliary layer Balls (4), e.g. B. made of ceramic or glass, and that the seed carrier with Means (5) is equipped for generating vibrations. 3. Riser air classifier according to claim 1 or 2, g e k e n n z e i c h n e through outlet openings (12) opening above the bed 2 for the Supply of part of the classifying air. 4. ascending pipe wind sifter according to claim 3, characterized in that g e k e n n z e i c h n e t that the outlet openings (12) act as nozzles for generating sharp jets are trained. 5. ascending pipe air classifier according to one of claims 1 to 4, characterized it is noted that the transition from the cross-section of the settling bed (2) to the smaller cross-section of the sight tubes (1) in the area of the top layer of the Set bed is arranged. 6. ascending pipe wind sifter according to claim 5, characterized in that g e k e n n z e i c h -n e t that a displacement body which determines the transition cross-section (17) is arranged above the set bed (2). 7. Riser air classifier according to claim 3 or 4 and claim 6, characterized it is not shown that the displacement body (17) has outlet openings (12) is provided for the supply of part of the classifying air. 8. ascending pipe air classifier according to one of claims 1 to 3, characterized G e -k e n n n n e i c h n e t that the additional classifying air is in countercurrent the bed (2) is led away. 9. ascending pipe wind sifter according to claim 8, characterized in that g e k e n n z e i c h -n e t that the settling bed (2) is divided into stepped sections is.