DE1254000B - Agitator mill - Google Patents

Description

Agitator mill The invention relates to a continuous working agitator mill with upright grinding container to which the grist is from is fed in at the bottom, with a sieve at the top outlet and one in the center of the grinding container arranged, consisting of a plurality of disk-shaped stirring elements Agitator.

Mills of this type are known. In general, such mills a cylindrical container in which a disc agitator is arranged concentrically is. The container is between 30 and 90% with grinding media of small diameter filled, between which the ground material pumped in from below with the agitator running must pass through.

The grinding media are now due to the upward flow movement more or less raised with. On average, the rate of descent must be the The grinding media correspond to the rate of rise of the grist. Due to the The inside of the cylindrical grinding container is practically divided into several chambers with stirring disks divided up. The main grinding effect takes place on the periphery of the agitator disks instead of. In order to achieve good grinding effects, minimum distances are allowed between the agitator disks and container are not fallen below. At these points, the grist flow velocities are therefore due to the small passage cross-section, relatively large. On the other hand, this means that at the points mentioned there is always the risk that grinding media from a Chamber to be carried up to the next chamber. This phenomenon is limited the throughput speed of the known mills is relatively fast.

It has already been suggested to remedy this phenomenon by that the agitator disk is not designed as a solid disk, but as a disk ring, and that the connections of the disc ring to the shaft are oriented downwards Agitators are formed. This embodiment is intended to achieve that too much upwardly conveyed grinding media through the inner disk opening again be promoted downwards. However, detailed observations show that the aforementioned Forming the agitator disks as a disk ring this task only to a small extent able to solve and also brings other difficulties with it.

Enrichment of the container with grinding media from bottom to top that is to say, even if there is a high rotational speed of the mixer or the agitator disks grist and grinding media only one ring on the Form the container wall, which is not at all up to the openings in the agitator disk enough. If, on the other hand, the grist is pumped in so strongly that this ring up to this If breakthroughs are sufficient, there is a risk that the grist will pass through these inner ones openings is pushed up. This appearance is supposed to be due to the downside directed, designed as agitator spokes are prevented. The effect however, the spoke is not satisfactory. Even if the spokes work in the desired sense, there is still a significant disadvantage in that then a reverse cycle arises, d. H. the grist goes through more the friction gap formed on the outer container wall in connection with the agitator disk to the top, taking with it the grinding media and partly entering through the openings the agitator disk back down again. So there is a considerable impulse to move in and against the general direction of flow. This cause amplified impulses however, that inadequately treated regrind reaches the outlet faster than desired and fine grist remains in the mill longer than necessary.

Finally, a continuously operating agitator mill is proposed has been brought, which is not part of the known state of the art and in the in an upright grinding container a screw conveyor is used to hold the grinding media in the middle of the trough upwards, with the grinding media from the upper edge of the container from falling down again in the edge zone. Since this mill shows very high signs of wear occur on the container wall, it is the task of the older proposal, the occurring Signs of wear and tear on the inner surface of the grinding container and on the screw conveyor to diminish. It is common to do this to reinforce the vulnerable areas of a mill to execute or to provide them with coatings. The older suggestion consists of horizontal and horizontal on the inner wall of the cylindrical grinding container Arrange vertical ribs.

Furthermore, mills with grinding containers are known whose shape of the Circular cylindrical shape differs, but it is in these known mills to Grinding container with horizontal axis. After all, you know someone who is standing upright Agitator mill, the grinding container of which deviates from the circular cylindrical shape. These known mill, however, has three agitators, which consist of individual stirring rods. The shape of the grinding container, which differs from the circular cylinder, is evident in this mill the geometric arrangement of the agitator shafts on the end points of an equilateral Triangle conditional. So that the ground material located above the grinding elements in the grinding zone reaches it, it is pumped out in the circuit at the lower end of the trough and again at the top admitted. With this arrangement of the discontinuously operating mill, there is no step the problems whose solution is sought by the subject matter of the invention.

The grinding problem explained at the beginning, as it occurs with continuously working, upright agitator mills with closed disc agitators occurs, in which the ground material is fed in from below and in which the grinding media during the Grinding process should remain in the same height ranges of the mill, is of these older proposals are not affected.

The invention is based on the object of creating an agitator mill, in which a homogeneous distribution of the grinding media is maintained, the Grinding media should remain within certain height ranges of the grinding container.

To solve this problem, according to the invention, a continuous working agitator mill with upright grinding container to which the grist is is pumped in from below, with a sieve at the upper outlet and one in the center of the grinding container arranged, consisting of a plurality of disk-shaped stirring elements Agitator, proposed that the grinding container has a shape deviating from the circular cylinder Has shape. This ensures that the entrainment of grinding media through the ground material through the respective gap between the container wall and the agitator disk is prevented from the outset. For a design of the grinding container according to the above There are various possible embodiments as marked invention. So can the grinding container can have any polygonal shape or is equipped with built-in components will.

According to one embodiment of the agitator mill according to the invention, can the agitator axis and the longitudinal axis of the container form an acute angle with one another.

According to a further feature of the invention, the of the Circular cylindrical shape deviating shape of the grinding container causing dust barriers, the corners of the container or the corrugations of a corrugated cylinder in the longitudinal direction of the container has a slight helical shape. This helix can thereby run in the same direction as the direction of rotation of the agitator shaft, but also in the opposite direction. In the embodiment with helical lines attached to the inner wall of the container The grinding media are significantly reduced by baffles as they migrate with the grist to the mill outlet prevented and thus increased the maximum throughput of the mill. Because these dust barriers on the one hand, the rolling speed of the grinding media-grist mixture on the trough wall and on the other hand the stress area between the agitator disk and the trough wall enlarge, the embodiment with dust barriers is particularly useful. The dust barriers can for example consist of spring steel, which is wound on a core and is then introduced into the grinding container by means of this core. In the grinding container the spring steel is released from the core, whereupon the coil spring relaxes and with its own spring tension on the inner wall of the trough to form the stowage barrier.

The container wall parts closest to the agitator, for example the elevations of a corrugated trough jacket are for the speed difference between the regrind and agitator disks, while the bulges act as calming and Weaning rooms are used. This embodiment maintains the large differential speed between grist and agitator disks, as necessary for the effect of such mills is, wholeheartedly. Compared to the known facilities, however, it has the advantage that in the enlarged bulges the grinding media gradually sink slowly can, and to a much greater extent than in the pure friction gaps has been possible so far. Due to the centrifugal pressure of the grinding elements, the The process of lowering the auxiliary grinding body is favored. This differs the solution according to the invention also basically differs from the known one described at the beginning Execution with openwork friction discs.

The lowering movement in the enlarged trough spaces is therefore slow, if the pumping speed of the grist is low; it increases when regrind is enforced. Even with unintentionally strong funding, at which anomalous number of auxiliary grinding bodies would be conveyed upwards is a very short one Time has been given as much compensation as possible.

In a preferred embodiment, the agitator disks have different ones Diameter, the diameter of the agitator disks increasing from bottom to top. Analogously, another feature of the invention is that the agitator next Container wall parts run conically in the longitudinal direction. This design variation has the advantage that the mills are better suited to their throughput length progressive grinding movement on the one hand and to the resulting forces between Have the gravitational acceleration and centrifugal acceleration adjusted. This adaptation is supported when the dust barriers are arranged in a slight helical shape are. These dust barriers can also extend over the entire length of the container extending ledges exist.

Further advantages and details of the invention are based on the Drawing explained in more detail, which illustrates various embodiments of the invention. F i g. 1 shows a vertical section through one designed according to the invention continuously operating agitator mill, FIG. 2 shows a section in the direction I-1 the F i g. 1, F i g. 3 another embodiment with rectangular trained container and F i g. 4 a wave-shaped container jacket.

The agitator mill according to the invention consists of a container jacket 1, the container bottom 2 with an inlet opening 3 for the ground material. An agitator shaft 4 with agitator disks 5 revolves concentrically in the container. A sieve 6 , which is intended to hold back the grinding media, is arranged above the container jacket. A collecting cup 8, which has an outlet spout 9, is arranged around the sieve 6, preferably over part of the length of the sieve.

According to one possible embodiment of the invention, fixtures 10 are provided on the container jacket l. These internals 10 preferably consist of radially directed strips extending over the entire length of the container jacket 1. The ground material is pumped in according to the arrow a at the inlet opening 3 , has a general translational movement upwards according to the arrow b and a smaller translational movement downwards according to the arrows c in the spaces formed by the internals 10. Above all, the translational movement in direction b is of course superimposed on a rotary movement. According to the arrows d and e, the finished ground material then flows through the sieve 6 into the collecting cup 8 and from there through the outlet spout 9 .

In Fig. Fig. 2 is a cross section taken along line I-1 of Fig. 1. 1 of the first embodiment shown. The container jacket is marked with 1 again, while 4 denotes the agitator shaft and 5 denotes a disk. From Fig. 2 the radial direction and the extent of the strips 10 can be seen. The radial length is chosen so that the distance between the edges adjacent to the agitator disks and the agitator disks themselves is optimally adapted to the grinding conditions, while the spaces between two internals 10 are at a greater distance from the agitator disk, so that the previously described lowering movement of the grinding elements can take place in these rooms.

In the case of the one shown in FIG. 3, the container 11 has, for example, a rectangular cross-sectional shape, the smallest distance between the disk 5 and the container wall 11 being approximately the distance between the internals 10 and the disks 5 of FIG. 2 corresponds. The widenings of the rectangular container jacket 11 formed in the corners serve as calming and settling areas.

Another possible embodiment of the container jacket is shown in FIG. 4 shown. The jacket 12 is designed in the form of a corrugated pipe with waves in the direction of the axis of the pipe. The elevations of this corrugated container jacket 12 closest to the disks are in turn responsible for the differential speed between the ground material and the agitator disk. The bulges in turn serve as seating areas.

The invention is not limited to the illustrated and described exemplary embodiments. For example, it is possible to surround the container jackets 1, 11 and 12 with cooling or heating devices. It is also possible, as mentioned above, to use stirring disks 5 with different diameters, the diameters preferably increasing from bottom to top. Similarly, there is the possibility of conical design of the container jacket with respect to the longitudinal axis of the container. In many cases it is also expedient not to arrange the internals or the edges or corrugations of the container shell parallel to the axis, but rather in the form of a helical line with a steep incline. The helical line can run in the same direction as the direction of rotation of the agitator shaft, but also in the opposite direction.

Claims (7)

Claims: 1. Continuously working agitator mill with upright standing grinding container, to which the ground material is pumped from below, with a sieve at the upper outlet and one arranged in the center of the grinding container, of a plurality agitator consisting of disc-shaped agitator elements, characterized in that that the grinding container has a shape deviating from the circular cylindrical shape. 2. Mill according to claim 1, characterized by a grinding container with preferably dust barriers directed radially inwards. 3. Mill according to claim 1, characterized through a grinding container with an angular, predominantly rectangular cross-section. 4. Mill according to claim 1, characterized by a grinding container with a corrugated jacket. 5. Mill according to one of Claims 1 to 4, characterized in that in the longitudinal direction of the axis the distance between the outer edge of the agitator disks and those closest to them Container wall parts is different. 6. Mill according to claim 5, characterized in that that the agitator axis and the longitudinal axis of the container form an acute angle with one another form. 7. Mill according to one of claims 1 to 6, characterized in that the dust barriers causing the shape of the grinding container deviating from the circular cylindrical shape, the corners of the container or the waves of a corrugated cylinder in the longitudinal direction of the container have a slight helical shape. B. Mill according to one of claims 1 to 7, characterized in that the agitator disks have different diameters. 9. Mill according to claim 8, characterized in that the diameter of the agitator disks increase from bottom to top. 10. Mill according to one of claims 1 to 9, characterized in that the container wall parts closest to the agitator are conical in the longitudinal direction. Considered publications: German Patent Nos. 489 327, 576 946, 614 149; U.S. Patent No. 3,008,657. Prior Patents Considered: German Patent No. 1195 145.