EP0347948A2 - Plural-stage mill - Google Patents

Abstract

A grinding mill containing a plurality of milling sections and composed of: a single cylindrical stator common to all milling sections; a rotor mounted in the stator for rotation about the longitudinal axis of the stator and having a plurality of milling plates spaced apart along the longitudinal axis and each disposed in a respective milling section; and a blower facility fastened to the rotor for rotation therewith and disposed near the bottom of the stator below the lowermost milling section for conveying material to be ground and conveyor gas through a central opening in the bottom of the stator to the milling sections. An auxiliary flow inducing device is connected to the outlet of the mill. The mill further includes a finger sifter mounted adjacent the outlet end of the milling sections and rotated at a rate selected independently of the rate of rotation of the rotor. Each milling plate can be formed to have an irregular working surface.

Description

The invention relates to a mill with a plurality of grinding stages, consisting of an essentially cylindrical stator common to all grinding stages, a rotor equipped with a plurality of grinding plates arranged one above the other in several stages, with a conveying device for a carrier gas which supplies the mill with the regrind interspersed, as well as with a finger sifter in the outlet area of the mill.

A mill of this type is known from the publication "Ultra-Rotor" from the company "Altenburger Maschinen". The crushing principle of this mill, which works with air as the carrier gas, is based on the fact that the regrind particles within the large number of air vortices generated by the grinding plates are accelerated to a high speed and preferably execute mutual impacts. These mutual impacts break the particles apart. Only a small part of the shredding processes occurs when the regrind particles meet the stationary or rotating machine parts. The fact that the mutual collisions of the particles in the air flow predominate means that the ground material is reduced particularly gently.

This shredding principle has proven itself particularly when grinding temperature-sensitive products. Because the product is constantly in turbulent air flows, the heat that is unavoidable during shredding is immediately dissipated. At the same time, any moisture that may be present is also absorbed by the air, so that intensive drying of moist regrind can additionally be achieved.

The finger classifier arranged in the outlet area of the mill is arranged on the shaft of the rotor and thus has a speed corresponding to the rotor. An adaptation of the sifter properties, which e.g. if it is desired if higher carrier gas rates are used, but a simultaneous change in the grain sizes of the grinding result is to be avoided, it is only possible in the known mill by exchanging the classifier fingers. This measure requires extremely cumbersome assembly work and thus results in long business interruptions.

The present invention has for its object to provide a mill of the type mentioned, in which the sifter properties can be changed, without the need for assembly work.

According to the invention, this object is achieved in that the finger classifier is equipped with a separate drive. This makes it possible to set the speed - and thus the properties - of the finger sifter independently of the speed of the rotor. Not only the setting of a certain grain size of the grinding result but also an adaptation of the grinding process to the product properties are possible by simply changing the speed of the finger sifter.

Further advantages and details of the invention will be explained on the basis of the exemplary embodiments illustrated in FIGS. 1 to 5.

In the mill shown in FIG. 1, the stator or the stator housing is denoted by 1, the rotor generally by 2, the feed hopper by 3 and the feed screw by 4.

The mill is equipped with five superimposed grinding stages 5. Each grinding stage is formed by a plurality of grinding plates 7 fastened on the circumference of a circular disc 6 (e.g. about 50). The grinding plates 7 each extend radially and parallel to the axis of rotation 8 of the rotor. The discs 6 carrying the grinding plates 7 are fastened to the hub sections 9, which in turn are connected to the shaft 11 of the rotor 2. The shaft 11 is supported above and below the rotor 2 in bearings 12, 13. The drive, not shown, is located below the lower bearing 12.

On the rotor shaft 11, the radial impeller 15 is additionally fastened, specifically immediately below the lowest grinding stage 5. Its axial inlet 16 is directed downward and faces a space 17 into which the feed shaft for the ground material with the screw 4 and an air supply duct 18 open . For better guidance of the ground material and the air when it enters the impeller 15 is the one occurs 16 surrounding edge 19 is provided, which extends perpendicular to the plane of the wheel 15 in the direction of the central space 17.

Above the grinding stages 5, a disk 21 is attached to the shaft 11, on the circumference of which the classifier fingers 22 are attached. Above the classifier fingers 22 there is an essentially circular outlet opening 23, to which the ring channel 24 and the outlet opening 25 connect. The outlet opening 25 is connected either directly or via a separator, not shown, to the fan 26, the motor of which is designated 27.

In Figure 2, the impeller 15 is shown again. It has a total of eight blades 28 curved to the rear.

During the operation of the mill, the ground material and the amount of air required for both transport and grinding enter the space 17 and from there enter the fan wheel 15 axially and centrally. Within the rapidly rotating fan wheel 15, the regrind and the air are set in rotation and conveyed radially outwards. This results in a uniform distribution of the ground material on the inner wall of the stator, which is followed by an equally uniform ascent of the ground material through the grinding stages 5. At the same time, the impeller 15 has a dissolving effect, that is, given if existing lumps of ground material are broken up. The product and air then pass through the grinding stages 5. Sufficiently finely ground material is able to pass through the rotating classifier fingers with the carrier air. Through the channel 24 and the outlet opening 25, the regrind-air mixture leave the mill 1 and are then separated from one another in the separators (not shown). Grist held back by the classifier fingers leaves the mill through the overflow flap 29 and is returned to the grist inlet.

In the mill shown, the impeller 15 and the fan 26 effect the conveyance of the carrier gas and thus the conveyance of the ground material. The delivery rate of the fan 15 corresponds to the speed of the rotor 2, so it does not change when the rotor speed is constant. If, according to an advantageous development of the invention, the speed of the motor 27 and thus the power of the fan 26 can be regulated, then the residence time of the product in the area of the grinding stages 5 can be influenced. Also the adaptation of the carrier gas flow conditions required for the transport of a product, which is dependent on many properties of the product to be ground, e.g. depend on its specific weight, is particularly simple with the help of the controllable fan 26.

For example, if a product has a high specific weight, then the upper fan 26 is on a high delivery rate to ensure that the heavy product is conveyed safely.

If the product is moist and the moisture is to be evaporated during the grinding process, it is expedient to throttle the upper fan 26. This increases the residence time of the air-material mixture in the mill, so that the desired drying occurs during the grinding. The drying capacity can be increased further by supplying hot air to the mill 1 via the channel 18.

Even when processing products that are difficult to grind, e.g. with fiber character, the upper fan must be throttled so that the desired grinding effect can be achieved better.

When processing products that require a particularly gentle grinding treatment, it is necessary to drive at low temperatures. This can be achieved by working with as much air as possible. In applications of this type, the delivery rate of the upper fan 26 must therefore be increased.

Furthermore, it is expedient in the context of the present invention, the finger sifter located above the rotor 2 to be equipped with its own drive so that the speed of the finger sifter can be set independently of the speed of the rotor 2. This measure not only makes it possible to influence the grain size of the product, it also allows the grinding process to be adapted to the product properties. If, for example, a specifically light product is to be ground particularly finely and particularly gently, then a strong carrier gas flow and a particularly high speed of rotation of the finger sifter must be used. The strong carrier gas flow keeps the temperature of the ground material low. However, it also has the effect that the material passes through the mill particularly quickly, that is to say it is not ground sufficiently finely. The fast rotating finger classifier therefore does not let the product come out of the mill. It is returned to the mill entrance. During this time, it is subject to a break from grinding, so that it cools down further before it is subjected to the grinding process again.

Figure 3 shows an embodiment for a separate finger classifier drive. For this purpose, a sleeve 31 is assigned to the upper end of the shaft 11 of the mill 1, which is only shown in part, which is rotatably supported on the shaft 11 via the bearings 32, 33. Outside the sleeve 31, another bearing 34 is featured see through which the sleeve 31 is supported in the mill housing. The sleeve 31 is thereby rotatably supported independently of the rotating shaft 11.

The lower end of the sleeve 31 protrudes into the mill housing and there carries the disk 21 with the classifier fingers 22. It passes through the wall of the mill housing and is sealed therein with sealing rings, which are not described in detail. Outside the mill, it protrudes so far that it can be coupled to a controllable drive motor 35 by means of belts 36.

The fingers 22 usually have a rod-like shape. As a result of their radial arrangement, the gap between the fingers increases in the radial direction. In order to achieve an approximately constant gap width in the radial direction, it is expedient within the scope of the invention to use classifier fingers, the width of which increases in the radial direction. Exemplary embodiments for this are shown in FIGS. 4 and 5. With classifier fingers of this type, an advantageous influence on the action of the classifier, e.g. an equalization of the classifying effect.

Claims (7)

1) Mill with several grinding stages (5), consisting of an essentially cylindrical stator (1) common to all grinding stages (5), with a rotor (2) equipped with a plurality of grinding plates (7) arranged one above the other in several stages a conveying device (26) for a carrier gas which passes through the mill with the ground material, and with a finger sifter (21, 22) in the outlet area of the mill, characterized in that the finger sifter (21, 22) is equipped with a separate drive (35) is. 2) Mill according to claim 1, characterized in that the speed of the drive (35) is adjustable. 3) Mill according to claim 1 or 2, characterized in that an adjustable gear motor (oil motor) is provided as the drive for the finger classifier (21, 22). 4) Mill according to claim 1, 2 or 3, characterized in that the finger classifier (21, 22) is attached to a sleeve (31) which surrounds the upper end region of the rotor shaft (11), rotatably mounted on the shaft (11) is (bearings 32, 33) and in turn is supported by a bearing (34) in the housing of the mill (1). 5) Mill according to claim 4, characterized in that the drive motor (35) is coupled to the portion of the sleeve (31) located outside the mill (1). 6) Mill according to one of claims 1 to 5, characterized in that the width of the classifier fingers (22) increases in the radial direction to the outside. 7) Mill according to claim 6, characterized in that the width of the classifier fingers (22) increases in the radial direction to the outside in such a way that the gap formed by two classifier fingers (22) arranged next to one another has an approximately uniform width.

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