AT394504B - Centrifugal force sifter - Google Patents

Abstract

A centrifugal force sifter having a sifter housing 12, which has an inlet 10 for the material supply, a fine- material discharge 11 and a coarse-material discharge 16 and in which a cylindrical rotor 13 is mounted such that it can rotate, it being possible for the latter to be set rotating by means of a drive device, and the rotor having on its outside sifting channels 13', via which the material to be sifted enters the interior of the rotor, which is connected to the fine-material discharge, the inlet for the material supplied at the same time forming the sifting-gas inlet and, in relation to the sifting rotor, being arranged essentially radially, and the wall of the sifter housing 12 away from the inlet bounding with the rotor an essentially spiral chamber 14 which, at its outlet end adjacent to the inlet, opens, via a preferably adjustable outlet gap 17, into a coarse- material discharge 16. <IMAGE>

Description

AT 394 504 B

The invention relates to a centrifugal classifier with a classifier housing, which has an inlet for the supply of material, a fine material discharge and a coarse material discharge, a cylindrical rotor being rotatably mounted in the classifier housing, which can be rotated by means of a drive device and has viewing channels on its jacket, via which the material to be sifted enters the inside of the rotor, which is connected to the discharge of fines.

The principle of the rotary sifter or basket sifter has been known for about 15 years. Such sifters have also been used to separate the finest com fractions below 20 pm, that is in the &quot; high performance range &quot; used and also referred to as a turbo sifter The essential feature of every rotary sifter is a cylindrical hollow rotor, the jacket of which consists of fanned lamellas, between which the actual viewing channels are located.

In the known visual principle, finely dispersed visual material is pressed or sucked together with a visual gas through the radial channels of the rotor which rotates rapidly at an adjustable speed. In the visual channels forming the actual visual zone, the individual particles are subjected to both the centrifugal force and the driving force by the visual gas. Depending on the setting of the rotor speed and the sight gas velocity in the channels, a certain grain size will result in a force equilibrium for a certain sight with constant specific weight and geometrically similar single grain shape. Larger particles are carried to the outside due to the predominance of the centrifugal force against the sight flow and separated out as coarse material. Smaller particles enter the interior of the rotor with the classifying gas and leave it again in the axial direction. The material to be separated can be separated from the gas by means of filters or cyclones.

A prerequisite for a good visual effect is, above all, that the material to be viewed is finely dispersed in the gas and that, if possible, all the particles that belong to the fine material due to their size are also reliably fed into the viewing zone.

In conventional rotary sifters that work in the high-performance range, the feed material feed is located on the top of the sifter housing, in which the centrally arranged sifting rotor is installed vertically. The classifier housing narrows conically downwards and merges into a housing part for the supply of classifying gas and the discharge of coarse material.

The sifting gas, usually air, compressed by means of a blower, enters the classifier housing from below through an inlet connection, possibly via a guide vane system, passes through the classifier housing, is rotated by the rapidly rotating rotor, and approaches this in a spiral fashion finally to enter the view channels.

The material to be sifted enters the classifier housing via the feed material feed and is flowed through and dispersed by the classifying gas. As far as the material to be sighted is taken from the sighting gas into the sighting channels of the rotor, it is subjected to centrifugal force screening there. The fine material flows through the rotor with the classifying gas. The coarse material is thrown outwards and falls down. Since the feed material also partially goes down without being carried into the viewing zone, the conventional rotary sifting requires that the material falling down is subjected to a second viewing zone in the area in which the sifting air flows into the sifter housing. Any fine material still present should be carried upwards again with the classifying gas in order to be able to get into the high-performance classifying zone of the rotor. The rest is discharged as coarse material below.

However, this double sighting has an adverse effect on the functioning of the classifier. Depending on the coordination of the two viewing zones, there is too much fine material in the coarse material discharged below, or there is a considerable accumulation of a medium fraction in the classifier housing, which leads to a significant deterioration in the visual performance. In addition, the dispersing action of the known rotary classifiers for high-performance requirements in the fine grain range, where it is necessary to dissolve relatively stable agglomerates, is insufficient due to the lack of corresponding shear forces and turbulence.

The invention aims to avoid the disadvantages described above and to provide a centrifugal classifier of the type specified in the introduction which, with a simple construction, enables perfect dispersion of the material to be sifted and increased visual performance. The centrifugal classifier according to the invention is characterized in that the inlet for the material supply also forms the classifying gas inlet and is arranged essentially radially with respect to the classifying rotor and that the wall of the classifier housing away from the inlet with the rotor delimits a substantially spiral space which at its end Inlet adjacent outlet end opens into a coarse material discharge via a preferably adjustable outlet gap.

In the centrifugal classifier according to the invention, the direct flow of visible material to the rotor results in considerable functional and economic advantages over the conventional classifiers. Particularly advantageous are the simple and orderly routing of visible material and gas and the consequent lower specific energy consumption as well as the excellent dispersing effect. The lack of double sighting results in an improved visual effect and a simple, space-saving and cost-saving design. Furthermore, it is very advantageous for many applications that classifiable material and classifying gas can be fed to the classifier together.

The principle of the invention enables a construction with both vertical and horizontal rotor axes.

The invention is explained in more detail below using an exemplary embodiment with reference to the drawings, in which FIG. 1 shows a rotary sifter according to the prior art in a schematic axial section, and FIGS. 2a and 2b show a schematic axial section through a sifter according to the invention and a section along the line (Ilb-IIb) in Fig. 2a. -2-

Claims (2)

AT 394 504 B In the conventional rotary classifier shown in FIG. 1, a feed material feed (1) is provided above a classifier housing (2) in which a cylindrical rotor (3) is arranged vertically. The classifier housing (2) has a central cylindrical section, narrows conically downwards and merges into a housing part (4) which contains a horizontal classifier gas supply and a vertical coarse material discharge (6). The sifting gas, usually air, compressed by a blower (not shown) reaches the sifter housing (2) from below via an inlet connection (5). The visible air passes through the housing upwards, is set into a rotary movement by the rapidly rotating rotor (3) and approaches the rotor in a spiral manner in order to enter the rotor's view channels (3 ') which are formed on the rotor shell by fanned lamellae. The visible material falls into the classifier housing (2) via the feed material feed (1). It is flowed through and dispersed by the classifying gas. The classifying material taken into the classifying channels (3 ') by the classifying gas is subjected to centrifugal force screening, the fine material flowing into the rotor interior with the classifying gas. The coarse material is thrown outwards and falls down. Feed material that has not been entered into the viewing zone and falls down is subjected to a screening in a second viewing zone (7), which is located in a lower housing area near the housing part (4), in which the viewing air flows into the viewing housing. Existing fine material portions are to be carried up again with the classifying gas. The rest is discharged as coarse material. In the construction according to the invention, according to FIGS. 2a and 2b, the material to be sighted passes together with the sighting gas via an inlet connection (10) into the classifier housing (12), in which the rapidly rotating classifying rotor (13) is mounted horizontally and the radial flow is direct, because the axis of the inlet connector (10) passes through the rotor axis. The classifying gas is suddenly deflected into an inlet spiral (14), which is delimited by the classifier housing wall and the rotor, and flows in a spiral shape to the classifying channels (13 *) in order to enter them. Due to the sudden deflection of the classifying gas in the area (15) in front of the rotor, larger particles and agglomerates of the classifying material are thrown against the rapidly rotating rotor and thus experience a very intensive dispersion. Furthermore, as a result of the deflection, the entire visible material is reliably and quickly fed to the viewing channels (13 ') and is therefore subjected to high-performance screening. The coarse material rejected by the rotor (13) is fed via an adjustable gap (17) at the outlet end of the inlet spiral (14) near the inlet (10) to a coarse material discharge (16) with a small partial flow of the sifting air. The fine material enters the rotor (13) with the main part of the classifying air, leaves it in the axial direction via the fine material discharge (11) and is fed to a fine material separator (filter or cyclone), not shown. Sofeme the sighting material does not already arise from the previous process process together with a suitable sighting gas, the sighting material is the sighting gas via a suitable device, for. B. metered a rotary valve task in the area before the flow to the rotor. In the construction shown there is no danger that larger particles will pass through the classifying rotor ducts due to their kinetic energy, because the peripheral speed of the classifying duct walls of the rotor is considerably greater than the possible entry speed of classifying material particles under the operating conditions to be used and the latter are therefore reliably deflected and rejected. PATENT CLAIMS 1. Centrifugal classifier with a classifier housing, which has an inlet for the supply of material, a fine material discharge and a coarse material discharge, wherein a cylindrical rotor is rotatably mounted in the classifier housing, which can be rotated by means of a drive device and has viewing channels on its jacket, through which the Good to be sifted enters the inside of the rotor, which is connected to the discharge of fines, characterized in that the inlet (10) for the supply of material also forms the sifting gas inlet and is arranged essentially radially with respect to the sifting rotor (13) and that the wall of the sifter housing (12) from the inlet (10) with the rotor (13) delimits an essentially spiral space (14) which opens into a coarse material discharge (16) at its outlet end adjacent to the inlet (10) via a preferably adjustable outlet gap (17) . 2. Centrifugal classifier according to claim 1, characterized in that the classifying rotor (13) is arranged horizontally. To this 2 sheet drawings -3-