DE3624229A1 - Closed bead sand mill - Google Patents

Abstract

Closed bead sand mill for the very fine comminution and dispersion of solids in liquids with the aid of small, round, bead-like and sand-like grinding bodies which are accommodated in a narrow, essentially smooth-walled annular space which accommodates approximately 3 to 6 layers of grinding bodies and is formed by a closed circular trough, which can be cooled or heated, and a rotor which rotates at high speed in the trough and is surrounded by the solid-liquid mixture which passes axially through the trough, the grinding bodies performing random rolling-rubbing movements, and a return device being situated on the rotor, and having a conveying rate which corresponds as exactly as possible to the throughflow rate of the mixture of material which is ground. <IMAGE>

Description

The invention relates to closed pearl sand mills with annular gap-like grinding rooms to the top Concept of claim 1.

Pearl sand mills of this type are different. The close grinding, only about 3 to 6 layers of grinding media space has an excellent power density and therefore high grinding performance in small grinding rooms with accordingly small amounts of grinding media. Unfortunately arise as Result of the small grinding chamber cross section through the grinding so high pressures on the grinding media that they are in front the outlet separation can be blocked. This leads to ver blockages and overheating, as well as excessive milling and grinding media wear. All known or suggested The gap-type pearl sand mills have therefore become imperative special grinding media to reduce the grinding media concentration return conveyor lines.

In DE-OS 28 11 899 is a split-room pearl sand mill shown with a double-conical grinding chamber. Central in the rotor is the return line from the outlet to Inlet side, the centrifugal forces of the grinding media Feed pressure of the regrind must be superior. Schwie issues regarding the return quantity, especially for Changing the size and weight of the grinding media and the Grist viscosity is preprogrammed from the danger Not to mention the immediate shoot through of regrind.

DE-OS 31 06 062 is a split-room pearl sand mill described with a cylindrical grinding chamber, for grinding body return an outer, axially parallel tube ge is used. The flow of funding should also be here by difference  are generated by centrifugal forces. Are practical for most regrinds, especially if they are used for Cementing or tend to dilate flow behavior, the grinding media not to be in a cycle at all because of.

In "Farbe + Lack" 90th year, issue 11/1984 page p. 913 are already controlled in Figures 10 and 11 Screws for the return of the grinding media are proposed. However, this solution does not only require a significant one Effort, their area of application is limited because the screws to avoid grinding media breakage elastic, unfortunately only limited solvent-resistant, Material must exist.

The invention sets itself the task of making this difficult fixes and dependency at the same time of these mills from the rheological properties of the consisting of solid, liquid and grinding media Reduce grinding mixture.

Accordingly, it is proposed to provide return elements on the rotor cylinder, the return flow rate ent about the regrind throughput speaks. Of course, these return conveyors are allowed elements influence the gap space character only insignificantly sen. In particular, the radial expansion must not Pearl break still lead to dead dreams. The return conveyor mente should not be higher than the maxi male grinding media diameter.

Particularly flat return threads are suitable as return elements, which also allow the simplest calculation calculation. Here is an example: The optimal power density is achieved by a given gap mill with a rotor diameter of 200 mm and a rotor speed of 600 min ^-1 . This power density corresponds to a target throughput of the ground material of 200 l / h, which corresponds to a delivery rate of 5.55 cm ³ per rotor revolution. A return flow of the same height, neglecting the conveying efficiency, is achieved by a thread groove of 5 mm by 1.8 mm or also 9 mm by 1 mm. - It proves to be an advantage that the conveying efficiency becomes better and better as the grinding media density increases and that a corkscrew effect occurs shortly before the grinding media blockage, thereby reliably preventing grinding media blockages.

Return threads can be fed directly into the Rotorzy be cut less. For reasons of closure, however it is recommended to lightly thread the thread to design interchangeable wear bands. - Under tapes of different thicknesses allow complete ver wear cover of the rotor. - Hollow bands allow one inevitable coolant flow directly in the Proximity of heat generation. - By temperature differences Adjacent belts can be used in products with temperature dependent viscosities the support effect supports will.

Individual funding can also be used as funding elements surfaces or threaded pieces are provided. These Subdivision allows constructions that the return performance may also need to be changed during operation equip. So these individual elements can be by themselves knew mechanisms mounted in the rotor cylinder, so probably be adjusted radially as well as in the angle of attack.

For optimal use of the pearl sand according to the invention The following procedure is proposed. More normal an even grinding media becomes wise for pearl sand mills per concentration over the entire length of the trough. For The above split-room pearl sand mills will do this  reached when the throughput and the return flow are approximately the same, so the proportionality factor is 1 be wearing. The statistical distance from grinding media to grinding body is the same size everywhere.

For many agglomerate grinds, however, it is advantageous if the distance between the grinding media is the agglomeration merate reduction is adjusted, d. H. the grinding media must be large on the inlet side and on the outlet side be small. This condition is reached when the Return flow of the rotor less than the throughput performance, i.e. the proportionality factor is less than 1 lies.

Aggregates and primary grain particles, on the other hand, require the Grinding forces adapted to the particle size. This awake sen with the higher grinding media concentration to the inlet side is achieved when the return flow is greater than the flow rate, the proportionality factor is over 1.

The invention is based on schematic drawings refines, with known details such. B. drive and cooling elements are omitted. In detail shows

Fig. 1 is a longitudinal sectional view of a gap-Perlsandmühle with incised into the rotor cylinder return screw threads,

Fig. 2 is a longitudinal section through a rotor cylinder with ver different return feed threads,

Fig 3 shows the view conveying elements. A rotor cylinder with a single return,

Fig. 4 shows the partial section through a rotor with radially adjustable return elements and

Fig. 5 shows the partial section through a rotor with radially and in the angle of return adjustable return surfaces.

The gap-type pearl sand mill shown in FIG. 1 is made up of the grinding trough 1 , the end wall 2 with a run nozzle 3 , the end wall 4 with the outlet housing 5 and the outlet nozzle 6 . In the trough 1 , the rotor cylinder 7 with the incised return conveyor winch 8 . The beads 9 demonstrate the gap width ratios. About the drive shaft 10 , the Rotorzy cylinder 7 is driven quickly. The disc 11 forms with the end wall 4 a separation gap for retaining the grinding media.

Fig. 2 shows the rotor cylinder 7 a with different thread designs in section. All constructions use helical tapes. - The flat strips 12 are advantageously attached with spot welding. For the wire tapes 13 , a corresponding bias is sufficient. The flat belts 14 and 15 of different heights protect the outer surface of the rotor from any wear. The hollow tape 16 allows an intensive cooling and, in conjunction with the uncooled intermediate band 17 in products with temperature-dependent viscometers ty an additional recirculation effect. With the combi nation of wire band 13 a and flat band 15 a is also a complete protection of the rotor cylinder.

Fig. 3 shows the view of a rotor cylinder 7 b with differently arranged return surfaces. The Rückför derflächen 18 can be fixed or radially displaceably attached to the ro tor cylinder. The return surfaces 19 are fixed to the rotating bodies 20 .

Fig. 4 shows a partial mill section in the region of a radially adjustable return surface 18 which slides in the rotor 7 b . The adjustment is effected via the bolt 21 , which slides in the gap 22 of the sliding block that is axially adjustable from the outside by the drive shaft. This adjustability allows adjustment of the return flow rate and wear compensation.

FIG. 5 shows a mill partial section in the region of a rotating body 20 mounted on a return conveyor surface 19. The rotating body 20 has the toothing 24 for the engagement of a rack, not shown here, for the rotary adjustment and the pin 25 for the connection of a pull rod. The seal 26 seals the rotary body 20 against the rotor wall 7 b . Here, too, the return flow rate can be adjusted and wear compensated. The bead density can be influenced by extreme radial displacement of the rotating body 20 and, if necessary, the rotor start-up can be facilitated.

The invention is not limited to gap-pearl sandmills with cylindrical grinding trough and not to the illustrated examples of the return elements.

Claims (11)

1.Closed pearl sand mill for finely crushing and dispersing solids in liquids with the help of small, round, pearl and sand-like grinding media, which are formed in a narrow, essentially smooth-walled, approx. 3 to 6 layers grinding media, formed by a closed, if necessary, coolable or heatable, circular trough and a rapidly revolving, possibly heatable or coolable rotor, surrounded by the solid-liquid mixture, which is pumped to the trough at one end, to the other end after passing through a separation device to leave the grinding media to leave, perform intense, disorderly rolling friction movements, characterized in that on the rotor Rückförderele elements are provided, the delivery rate corresponds approximately to the throughput. 2. Pearl sand mill according to claim 1, characterized in that return threads are attached to the rotor. 3. Pearl sand mill according to claim 2, characterized in that the return thread through on or inlaid Bands are created, which may be the actual rotor cover completely. 4. pearl sand mill according to claim 3, characterized in that the bands for the coolant flow are hollow.   5. pearl sand mill according to claim 1, characterized in that the rotor is equipped with individual return surfaces. 6. Pearl sand mill according to claim 5, characterized in that the return surfaces are radially adjustable. 7. Pearl sand mill according to claim 5, characterized in that the return surfaces are variable in the angle of attack. 8. Method for operating a pearl sand mill according to An saying 1 to 7, characterized by a changeable Proportionality between the rotor speed or rotor delivery rate and the regrind throughput to the desired loading influence of the pearl density distribution over the length of the trough. 9. The method according to claim 8, characterized by the Proportionality factor 1 for even pearl density distribution over the entire length of the trough. 10. The method according to claim 8, characterized by Pro proportionality factors less than 1 for higher pearl density towards the trough outlet. 11. The method according to claim 8, characterized by Pro proportionality factors greater than 1 for higher pearl density towards the trough inlet side.