DE1164805B - Schlaegermuehle with vertically mounted Schlaegerrotor - Google Patents

Description

Beater mill with vertically mounted For industrial grinding processes machines have recently come to the fore, which the classic ways of crushing, throwing, compressing, largely avoid friction, shearing or press rolling, in which rather, the material to be shredded is transported pneumatically and through vortex zones is directed. In these vortex zones, the material experiences such strong movements, Pressure fluctuations and energy charges, so that an intensive grinding process, before mainly due to the abrasion of the particles against each other. Particularly This process is advantageous for fine and ultra-fine grinding.

Structurally, the structural prerequisites for these effects become usually generated by a rotor with radial blades or beaters that brush past a vertically corrugated stator, with the eddies behind the Shovels are particularly effective because in these zones the grist varies in height and is exposed to low pressure caused by the rapid passage of these blades is generated on the corrugated stator. These grinding effects make themselves special noticeable in substances which, according to their structure, have internal tensions and which then tend to split along these internal lines of tension.

It has now been found in the operation of these machines that the air flow and more attention must be paid to the air volume control than after the previous knowledge of the relationships was to be assumed. Because the air on the grinding process participates, is partly also the carrier of the grinding energy, a certain result arises optimal ratio between air volume, ground product and air speed. at This consideration is the amount of air in the pore volume of the granular ground material is always neglected, as this proportion, measured against the required Amounts of air that is negligibly small.

The relevant technology already knows grinding apparatuses that have an air admixing stage for better grinding. Another apparatus that has become known leads in the funnel shortly before the first grinding stage, one-stage air into the grist en; this measure was also unsatisfactory.

The previously common designs carry the regrind directly in the amount of first and second rotor blades. It results in braking and reinforced Wear effects and a significant reduction in grinding performance in qualitative terms and quantitative terms. Another design brings the 2 grist through the hollow The central shaft is in the center of the lower rotor blades, due to the sharp deflection however, a uniform loading of the rotor blades cannot be achieved by 180 °. In addition, there is increased wear at the deflection points.

The previous rotor bodies of the grinding device had fixed impact plates with a constant distance between the stator edge and the outermost blade edge. This constant Distance took into account the different grinding work of the individual grinding stages not; he had a performance-reducing effect. Another disadvantage arose from the grinding principle, that works with rapidly successive pressure fluctuations. The resulting Those arranged after the last grinding stages regularly left high vibration frequencies Break the webs of the rotating discharge equipment. This caused serious operational disruptions, because the centrifugal force is great at the necessary high peripheral speeds.

The invention is based on the knowledge that the first grinding stage must be loaded completely evenly, and it therefore leads the grist below of the rotor together with the air flow and distributes the grist even before it is reached the first grinding stage completely evenly in the air stream. The air duct is thereby designed so that immediately after the mechanical supply an air opening allows the suction the amount of air necessary for the transport of the ground material. The for the The amount of air required for the grinding purpose, which is significantly larger than that for transport necessary air is sucked in in the fan zone.

The beater mill designed according to the invention consists of a vertical mounted beater rotor, which in turn consists of several superimposed with Beat plates provided grinding stages is composed and which the grist in his lower part fed by a mechanical feeder will and by adding a stream of air pneumatically from bottom to top through the Grinding stages also conveyed pneumatically and pneumatically in the upper part of the mill is carried out. The actual invention is characterized in that the mixing of the transport air to the ground material takes place in two stages, namely the first admixture immediately behind the mechanical conveyor and the second Mixing immediately before the lowest grinding stage.

The drawings show an exemplary embodiment of the inventive concept.

F i g. Figure 1 shows a cross-section through the beater mill including that of the feeding devices and the air lock; F i g. 2 shows a section through FIG. 1 along line 1-I; F i g. 3 shows a section through FIG. 1 along line 11-11 of FIG. 1; F i g. FIG. 4 shows a section along the line 111-111 of FIG. 1- F i g. 5 shows the top view of the beater mill.

The beater mill consists of the feed hopper 1, the metering screw 2, the possibly second allocation 3 and one from the overflow of the machine between the end of the feed screw 2 and the beater mill attached air opening 5, called the airlock. If the auger introduces more grist than the Grinder can cope, so the air supply through the opening is automatically reduced 5, since this then covers part of the opening 5. The grist feed increases even further on, then no more air at all passes through the opening 5, then it is because of the lack of ventilation and because the pneumatic one for the regrind Carrier body air is missing, the grinding process interrupted. This is how this opening works 5 self-regulating and as a safety device.

The F i g. 2 shows the openings 7 and 8 in the feed duct 6 for the secondary air, which are enlarged or reduced by the slides 9 and 10 for the correct mixture between the amount of air and the material to be ground. This optimal grinding material-air mixture is measured pneumatically by the rotor stages with the beater plates 11 . The stator space is surrounded by the stator casing 12.

It has surprisingly been found that by this type of supply and Air control the performance is multiplied. While so far there has always been the danger that the machine was operated with too little air, causing overheating that is dangerous for operation occurred, this danger is not only eliminated by the special allocation devices, It has also made possible grinding operations that were previously in the relevant technology were only possible with considerably more effort or not at all. The so far The measures outlined now even allow the step of grinding drying. Since the Temperature in the machine is technically controlled by the air control, could even warm air can be supplied with a slow increase. Introduction temperatures up to 200 ° C were reached in practical continuous operation. That then gives the opportunity to allow thick grist to run into the grinder. The hot air is sent to the Introduced into the apparatus where the cold air would otherwise be introduced.

When the ground material has left the individual grinding zones of the rotors, it arrives in a chamber 13 in which a rotary body 14 with milled slots 15 is located. In these webs 16 are fitted, on which ejection plates 17 are arranged at such an angle to the outer wall that they convey the heavy, coarse or even the non-grindable parts of the ground material tangentially to the outlet 18. The outlet is partially closed by a flap 19 so that only the specifically heavy or too coarse parts that are driven onto the inner wall 20 of the stator cylinder 12 pass the outlet 18. The separation can be controlled by the position of the flap 19. If the ejected grist is no longer to be processed, it can be collected or sacked separately after leaving the mill. However, it can also be fed into the pipe 3 and fed back to the metering screw 2 there.

The grist, which has the desired fineness, is made by the The upper fan 22 is sucked into the support housing 23, this is like the FIG. 5 shows, formed spirally. It enlarges towards the discharge side, so that the grist reaches lower speeds here. It can then in one the usual separators can be collected.

Claims (3)

Patent: 1. Beater mill with vertically mounted beater rotor, of several superimposed grinding stages provided with beater plates consists and the ground material in its lower part by a mechanical feed device is supplied and pneumatically from below by mixing in an air stream Pneumatically conveyed through the grinding stages at the top and pneumatically in the upper part of the mill is discharged, characterized in that the admixing of the transport air to Grist takes place in two stages, namely the first admixture immediately behind the mechanical feed device (2) and the second admixture immediately before the lowest grinding level. 2. Beater mill according to claim 1, characterized in that that the feed device consists of a screw conveyor (2) with a horizontal axis, into a pneumatic conveying channel provided below the lowest grinding stage (6) promotes, which cannot be vibrated following the screw conveyor on its top has an air inlet opening (5) and in the region of which traverses the conveying channel Rotor shaft (4) on its underside with two further, preferably diagonally opposite one another Air inlet openings (7, 8) is provided. 3. Beater mill according to claim 2, characterized in that the air inlet openings (7, 8) lying in the region of the rotor shaft (4 ) have devices (9, 10) for adjusting their opening width. Documents considered: German Patent No. 438 027; USA. Patent Nos. 1,744,895, 2,752,097.