DE1265081B - Porous floor for pneumatic classifying devices - Google Patents

Description

Porous floor for pneumatic classifiers. The invention refers to porous floors for pneumatic classifiers through which a Gas is blown into a fluidizable mass lying on the ground.

The porous floors used in such apparatus either exist made of grids or porous material, e.g. B. sintered metal or ceramic Material. These known porous floors have various disadvantages. The grids generally have very large mesh dimensions or at least a high one Ratio between the sum of all openings and the total area of the floor. Through this is the passage of fine material possible or dead spaces are formed, through which the material on the bars not through the gas flow is detected. In addition, there is a risk that the metal that makes up the grid are oxidized or corroded by the materials with which it comes in contact will. This influence leads to its self-colmating of the porous floor. at the bottoms of sintered metal, generally sintered bronze also the risk of oxidation or decomposition with the consequence of self-colmation. Furthermore, there is a possibility that the fine materials will be in the pores of the floors. The same disadvantage of pinning fine materials occurs when using floors made of ceramic material. These floors are also still fragile, although the purchase price is relatively high.

The object of the present invention is to provide porous floors to create that by constituents of the air, by moisture and by others Components contained in the treated articles and by the Gas for liquefaction cannot be attacked. Furthermore, the floors should according to the object underlying the invention be designed so that they opposite mechanical stresses are resistant that they are even fine particles of material Do not let them pass, an automatic discharge of fine, into the pores Penetrated particles ensure that they are renewed by simply knocking out and that they ultimately have a high effectiveness with regard to the suspension of particles in the gas flow passing through.

The porous floor according to the invention is essentially by a Porous plate formed from a porous, air-permeable mass, the basic material of which has elastic properties similar to rubber. The ones that can be used for this purpose For example, porous masses can be massive, through a very dense network of perforations be loosened material, the diameter of the perforations on the grain size depends on the material to be suspended or deposited. The porous material can also consist of foam rubber or plastic foam with connecting cells, which merge into a network of very dense pores, at least on the upper surface. The essential feature of these porous masses is that under the gas pressure the pores are slightly expanded, so that the fine penetrated into the pores Particles can be ejected.

The material used according to the invention does not decompose, and there is also no colmatization due to oxidation.

The thickness of the porous plate can vary, depending on the blowing pressure, the grain size, the density of the treated materials or the different ones Density of the products to be separated from one another, as well as depending on other conditions to achieve the desired result. In general, the plate thickness lies in a range between 2 and 15 mm.

In the porous floor according to the invention, the porous plate in held in a frame and supported by a support that maintains the flatness of the porous Plate ensures. The rigid support can be made of a grid or consist of a grate. The cross-section of the elements is chosen as small as possible, depending on the load carried through the porous floor. the Elements of the rigid support form lines of lower porosity, their size depends on the cross-section of the support elements.

A grid or grate with hexagonal mesh is preferred Use. It has been found that the porous floors according to the invention due to the elasticity of the material of the porous plates by resonance in vibration The surfaces bounded by each mesh vibrate individually. These Vibration results in an increase in energy that increases with the effectiveness of the pneumatic classifier or from the swirling device. By deliberation and by experimental comparisons between porous soils with square mesh and hexagonal meshes, it has been found that this vibration effect and thus the effectiveness of the gas blown through the porous floor is essential can be increased if the surface of the mesh comes as close as possible to a circle.

According to the invention, it is expedient to use the carrier and the porous plate made of foam to be attached to each other. This attachment can be done by that the support grid or the grid is glued under the porous plate. By However, the bond creates the risk that the pores in a certain area closed and the lines of reduced porosity widened. According to a Embodiment of the invention, especially with relatively thick-walled porous floors are advantageous, a porous plate made of rubber or plastic foam is used Use in which the rigid grid is embedded. The grid can be used at any altitude be embedded in the material. However, to a distribution in the porous mass outside the area of the non-porous lines created by the grid, To enable the grid to be as close as possible to the lower surface to arrange. Such a mass of porous, reinforced foam can be very simple be made by placing the grid on the surface of the work table or placed on the working level and the liquid mass of latex or resin on This grid is spread out and foaming and hardening occurs.

The new reinforced plastic material produced in this way Foam combines the mechanical resistance of the grid with the deformability of foam. This material can also be used for other industrial purposes will.

Details and advantages of the invention are given below on the basis of exemplary embodiments explained on the basis of the drawings.

The drawings show: F i g. 1 a section of a porous Soil according to the invention, FIG. 2 shows a detailed section of the porous floor according to FIG F i g. 1, Fig. 3 shows a detailed section corresponding to FIG. 2 of another embodiment the invention.

The porous floor (F i g. 1) consists of a frame 1, which is used for fastening the bottom of the classifier's container is determined. Inside the frame is a Support 2 held, which consists of a grid with hexagonal mesh. Farther a porous plate 3 is arranged within the frame. This porous plate 3 can consist of a polyurethane foam with cells that are connected to one another are. The thickness of the plate can vary between 2 and 15 mm. the The underside of the plate is glued to the wires of a grid at 4 (Fig. 2).

In the embodiment of FIG. 3 is the grid 2 in the foam board embedded, directly in the area of the underside of the plate. The grid is also mechanically connected to the foam.

Claims (1)

Claims: 1. Porous floor for pneumatic classifying devices, which contains a stiffened by a support grid, provided with pores plate made of a material with rubber-elastic properties, characterized in that the plate (3) consists of a foam with interconnected cells that are at least in The area of the upper surface of the plate merges into a network of very fine pores. z. Floor according to claim 1, characterized in that the thickness of the porous plate (3) is preferably in the range between 2 and 15 mm. 3. Floor according to claim 2, characterized in that the porous plate (3) is held in a frame (1) and is arranged on a rigid support (2) which maintains the flatness of the porous plate. 4. Floor according to claims 1 to 3, characterized in that the rigid support (2) consists of a grid or a grate. 5. Floor according to claims 1 to 4, characterized in that the rigid support (2) consists of a grid with hexagonal mesh. 6. Floor according to claims 3 to 5, characterized in that the rigid support (2) is attached under the porous plate (3) by gluing. 7. Floor according to claims 3 to 6, characterized in that the rigid support (2) is embedded in the mass of the porous plate (3). Documents considered: German utility model No. 1680 119; U.S. Patent No. 2,255,438.