EP0164512A1 - Milling process and milling device - Google Patents

Abstract

The invention relates to a grinding process and a plant for the simultaneous production of at least two finished products of different fineness using an annular mill (1). In this case, a pre-classification takes place in the nozzle ring (15) by adjusting the air quantity and air speed, and the coarse components conveyed up by a mechanical conveying device (3) are subjected to a reclassification, at least one partial fraction being withdrawn as a finished product.

Description

The invention relates to a grinding method according to the preamble of claim 1 and a plant for performing this method.

Ring mills are known in particular in the form of roller mills or ball ring mills. The grinding tools, which are designed as balls or rollers, roll on an annular grinding plate, the grinding pressure being generated by spring force, hydraulic cylinders, by centrifugal force or by the weight of the grinding tools.

In such mills, an air stream is fed through a nozzle ring which is arranged in a fixed manner on the outer circumference of the grinding plate and which detects and carries up the fine constituents of the comminuted ground material discharged over the edge of the grinding plate, and carries the coarse constituents downward through the nozzle ring against the air flow fall and, for example, are re-fed to the mill via a mechanical conveyor.

So far, ring mills of this type have only been used to produce a relatively fine-grained finished product. This finished product is discharged from the mill with the air flow and separated in separate separators (such as cyclones, filters).

In practice, there is an occasional need to produce finished products of different fineness. For example, the production of aggregates requires both a fine product, such as filler (with a grain size of less than 0.2 mm), and addition to a coarse product, such as masonry mortar (with a grain size of 0 to 4 mm). Finished products of different fineness of this type have hitherto generally been produced using separate grinding plants, which requires considerable outlay in terms of plant technology.

The invention is therefore based on the object of designing a grinding process of the type required in the preamble of claim 1 (i.e. using an annular mill) in such a way that at least two finished products of different fineness are produced simultaneously in a simple manner.

This object is achieved by the combination of the features mentioned in the characterizing part of claim 1.

Appropriate embodiments of the invention are the subject of the dependent claims.

In the method according to the invention, at least two finished products of different fineness are produced simultaneously using the same ring mill (roller or ball ring mill), for example a fine finished product with a grain size between 0 and 100 microns and a coarse finished product with a grain size of 0.1 to 2 mm . For this purpose who which the amount of air and the air speed in the nozzle ring set so that a pre-classification (caution) takes place in the nozzle ring and the coarse constituents in a defined amount and a certain grain composition fall down through the nozzle ring.

Compared to the previously usual mode of operation of roller mills (with air speeds in the nozzle ring between 70 and 100 m / s), significantly lower air speeds (in the order of magnitude between 30 and 60 m / s) are used according to the grinding method according to the invention, which - together with the invention set specific amount of air in the nozzle ring - leads to the failure of the coarse components in a defined amount and grain composition. The flow conditions in the nozzle ring are selected in principle so that the coarse constituents of the ground material falling down through the nozzle ring contain little fines.

The coarse constituents of the ground material which have precipitated through the nozzle ring and are conveyed up by means of a mechanical conveying device are then subjected to a reclassification (sieving or classifying) in the grinding process according to the invention, at least a partial fraction of the coarse constituents being withdrawn as a further finished product and the residual fraction containing the coarsest constituents again the mill can be abandoned.

• Fig.1 eine Schemadarstellung einer Anlage zur Durchführung des erfindungsgemäßen Mahlverfahrens,
• Fig.2 eine Aufsicht auf den Mahlteller und den Düsenring der Rollenmühle gemäß Fig.1,
• Fig.3 einen Schnitt längs der Linie III-III der Fig.2,
• Fig.4 eine schematische Aufsicht auf eine abgewandelte Ausführung der Rollenmühle gemäß Fig.1,
• Fig.5 ein Diagramm zur Erläuterung des erfindungsgemäßen Mahlverfahrens.

An embodiment of the invention is illustrated in the drawing. Show it

• 1 shows a diagram of a plant for carrying out the grinding process according to the invention,
• 2 shows a top view of the grinding table and the nozzle ring of the roller mill according to FIG. 1,
• 3 shows a section along the line III-III of FIG. 2,
• 4 shows a schematic plan view of a modified embodiment of the roller mill according to FIG. 1,
• 5 shows a diagram for explaining the grinding method according to the invention.

The grinding system shown in FIG. 1 contains a roller mill 1 with a static classifier 2 arranged above it, a bucket elevator 3, a sieve device 4 and an electrostatic filter 5.

The details of the roller mill 1, insofar as they are essential for the understanding of the invention, are first explained in more detail with reference to FIGS. 2 and 3.

The roller mill 1 schematically illustrated in FIGS. 1 and 2 contains an annular grinding plate 12 rotating about a vertical axis 11 roll the two pairs of rollers 13, 14.

On the outer circumference of the grinding plate 12 there is a stationary nozzle ring 15 which serves to supply an air flow (see arrow 38 in FIG. 3) which detects the fine constituents of the crushed ground material discharged over the edge of the grinding plate 12 and carries it upwards (Arrow 39), while the coarse constituents of the ground material fall downward against the air flow through the nozzle ring 15 (arrow 40).

The nozzle ring 15 is divided into several segments, of which the segment 15a is illustrated in detail in FIG.

The segment 15a of the nozzle ring 15 contains an inner stationary wall part 16, which is connected to the housing 19 of the roller mill 1 via two lateral guide parts 17, 18. The stationary inner wall part 16 carries a number of webs 16a which point outwards.

Furthermore, the segment 15a of the nozzle ring 15 contains an outer adjustable wall part 20 which is connected to the push spindle 21 of a pneumatic cylinder 22. The thrust spindle 21 is guided radially in slide guides 23, 24. The pneumatic cylinder 22 is carried by a flange 25 which is fastened to the housing 19 by means of struts 26, 27.

The outer wall part 20 of the segment 15a of the nozzle ring 15 is adjustable by means of the spindle 21 of the pneumatic cylinder 22 in the radial direction (double arrow 28), namely between a radially outer position in which the wall part 20 is located near the housing 19 and one Position 20 'indicated by dashed lines, in which the adjustable wall part 20 touches the struts 16a of the stationary inner wall part 16 and in which it limits the clear cross section of the interior 29 of the segment 15a through which the air flows.

The adjustable wall part 20 of the segment 15a is guided in the region of the ends facing the adjacent segments on parallel guide surfaces 17a, 18a of the guide parts 17, 18. In addition, a link guide can be provided in the area of these guide surfaces 17a, 18a in order to exclude the risk of the adjustable outer wall part 20 tilting with respect to a horizontal plane.

As can be seen from FIG. 1, the fresh material to be ground from the roller mill 1 is fed in via a conveyor belt 41 and a chute 42.

The air supply to the roller mill 1 takes place via a line 43 which is divided into sub-lines 43a, 43b and which is connected to a suitable hot air source.

The coarse constituents of the ground material precipitating through the nozzle ring 15 reach the bucket elevator 3 via a line 44 and are fed by this to the screening device 4. At least one partial fraction resulting from the reclassification of the coarse constituents in the screening device 4 (for example the semolina with a grain size between 0 and 4 mm) is drawn off as a finished product (arrow 45), while the residual fraction containing the coarsest constituents (arrow 46) again Mill 1 is fed.

The fine constituents discharged pneumatically upward from the mill 1 by the air flow are subjected to a sifting in the static sifter 2. The fine constituents leaving the classifier 2 with the air stream are separated in the electrostatic filter 5 as a further finished product (arrow 47).

The grains separated in the classifier 2 can be re-fed to the grinding table 12 of the roller mill 1 in the usual way via the separating funnel 48. However, a selectable portion of this semolina separated in the sifter 2 can be drawn off by a discharge device 49 (for example a screw conveyor) connected to the separating funnel 48 and can also be fed to the bucket elevator 3 via a line 50. Instead, however, it is also possible to subtract part of the semolina obtained in classifier 2 as a further finished product.

The diagram according to FIG. 5 explains the relationship between the flow conditions in the nozzle ring and the quantity and fineness of the material falling down through the nozzle ring and conveyed upwards via the bucket elevator.

The ordinate of the diagram according to FIG. 5 shows the quantity of material in bucket elevator 3 (expressed as a percentage of the quantity of fresh material to be fed into the mill). The specific air volume in the nozzle ring is plotted on the abscissa of the right part of the diagram (expressed in m ³ / kg fresh material mill feed quantity). The abscissa of the left part of the diagram according to Fig. 5 corresponds to the fineness of the bucket elevator material (expressed in percent residue on a sieve with x mm mesh size). The estate becomes coarser to the left and finer to the right.

The two curves in the right part of the diagram show the conditions for two different air velocities V ₁ and V ₂ in the nozzle ring (where V ₁ <V ₂ ). It can be seen that as the specific amount of air in the nozzle ring increases, the amount of material in the bucket elevator decreases. If the air speed in the nozzle ring increases while the specific air volume remains the same, the amount of bucket material is also reduced.

The characteristic curve field in the left part of the diagram is assigned to the two curves in the right part of the diagram. So it can be changed by changing the air speed in the nozzle ring and the specific Air volume achieve different quantities of material in the bucket elevator ("nozzle ring diarrhea") with different grain spectrum.

For example, the following conditions can arise:

While the air velocity prevailing in the nozzle ring is primarily influenced by adjusting the outer wall parts 20 of the nozzle ring, the amount of air supplied to the nozzle ring can be influenced, for example, by adjusting a delivery blower and / or by adjusting adjusting flaps provided in the air feeds to the nozzle ring.

FIG. 4 shows an embodiment in schematic form, in which four air inlets 60, 61, 62, 63 are provided, to which separately adjustable segments 15'a, 15'b, 15'c and 15'd of a nozzle ring 15 'are assigned. These four segments of the nozzle ring 15 ', the details of which are not illustrated in FIG. 4, have, as in the exemplary embodiment already explained with reference to FIGS. 2 and 3, a wall which is adjustable from the outside during operation and which limits and through the clear cross section of the nozzle ring whose adjustment can thus change the flow conditions of the air in the area of the segment concerned. The devices for adjusting the cross section of the nozzle ring are likewise not illustrated in FIG.

In the air supply lines 60 to 63, adjusting flaps 64 to 67 are provided, which permit a more or less severe throttling of the air flows supplied. The air supplied by the air supply lines 60 to 63 is distributed in the manner schematically indicated by the arrows over the circumferential length of the segments 15'a to 15'd of the nozzle ring 15 '. In this exemplary embodiment according to FIG. 4, the circumferential zones of the grinding plate assigned to the individual segments 15'a to 15'd of the nozzle ring 15 'can be ventilated differently (with regard to the flow quantities and flow velocities), which is due to the different material accumulation in the individual Zones enables an optimization of the pneumatic material discharge or of the coarse material falling downwards against the air flow through the nozzle ring.

While in the embodiment shown in FIGS. 2 and 3 the outer wall parts 20 of the individual segments of the nozzle ring 15 are adjustable by means of pneumatic cylinders 22, within the scope of the invention an adjustment can also be actuated by an electric or hydraulic drive or by means of a handwheel Spindle are provided.

The number of elements of the nozzle ring 15, each provided with a separate drive, ventilated and adjustable, is adapted to the respective application. The nozzle ring can also contain individual non-ventilated segments between ventilated and adjustable segments. For example, a version with eight ventilated, adjustable segments and four non-ventilated segments arranged between them is conceivable.

The air speed in the nozzle ring is between 30 and 60 m / s, preferably between 35 and 45 m / s in the grinding process according to the invention.

The amount of coarse constituents falling through the nozzle ring and conveyed up again by the mechanical conveying device is 25 to 200%, preferably 30 to 80%, of the amount of the mill freshly abandoned good.

Finally, the specific amount of air in the nozzle ring is between 0.5 and 4 m ³ / kg, preferably between 0.8 and 2 m ³ / kg, of the material freshly fed to the mill.

The coarse constituents falling down through the nozzle ring or the partial fractions obtained in the final classification and used as finished product can, if necessary, be subjected to post-drying, for which purpose, for example, a riser dryer, a spreading dryer or a drying drum can be used.

The flow conditions in the nozzle ring can be changed not only in the manner described by adjusting a wall that limits the cross section of the nozzle ring, by adjusting flaps in the air supply lines and by adjusting a delivery blower, but also, for example, by partially covering the nozzle ring or by partial ventilation or partially different ventilation of the nozzle ring.

Finally, it should be pointed out that the roller mill used in the context of the grinding process according to the invention for the simultaneous production of at least two finished products can, of course, also be used in a conventional manner to produce a single finished product, the devices for influencing The air volume and air speed in the nozzle ring allow the mill to be optimally adapted to the prevailing conditions.

• Aufgabeleistung: 125 t/h (trocken), 0-50 mm Fertigprodukt 1: 80 t/h bei 12% Rückstand auf Sieb 0,09 mm
• Umlaufgut: ca. 90 t/h bei 0-40 mm ca. 45% Rückstand auf Sieb 4,0 mm ca. 95% Rückstand auf Sieb 0,09 mm

The following working example serves to further explain the invention:

• Feed rate: 125 t / h (dry), 0-50 mm finished product 1: 80 t / h with 12% residue on sieve 0.09 mm
• Circulating goods: approx. 90 t / h at 0-40 mm approx. 45% residue on sieve 4.0 mm approx. 95% residue on sieve 0.09 mm

• Fertigprodukt 2: ca. 45 t/h bei 0-4 mm ca. 90% Rückstand auf Sieb 0,09 mm
• Grobgut (zurück zur Mühle)_ ca. 45 t/h, 2-40 mm.

By classifying the amount of bucket material, the following is obtained:

• Finished product 2: approx. 45 t / h at 0-4 mm approx. 90% residue on sieve 0.09 mm
• Coarse material (back to the mill) _ approx. 45 t / h, 2-40 mm.

The specified performance is based on dry product. Effectively, the feed performance due to the water contained - depending on the feed moisture - is higher.

Claims (17)

1. Milling process in which the fine components of the material comminuted in a ring mill (1) are discharged pneumatically upwards by means of an air stream supplied via a nozzle ring (15) and form a finished product, while the coarse components counteract the air flow through the nozzle ring downwards fall and are conveyed up again via a mechanical conveyor device (3),
characterized,
that the combination of the following features is provided for the simultaneous production of at least two finished products of different fineness: a) the amount of air and the air speed in the nozzle ring (15) are set so that there is a pre-classification in the nozzle ring and the coarse constituents in a defined amount and grain composition fall down through the nozzle ring; b) the coarse constituents conveyed up by the mechanical conveying device (3) are subjected to a reclassification, with at least a partial fraction of the coarse constituents being withdrawn as a further finished product. 2. The method according to claim 1, characterized in that the residual fraction containing the coarsest constituents is again fed to the mill (1). 3. The method according to claim 1, in which the pneumatically discharged from the mill (1) upward fine components are subjected to a screening, characterized in that at least a portion of the greens resulting from this screening together with those through the nozzle ring (15) coarse constituents that fail below are reclassified 4. The method according to claim 1, in which the pneumatically discharged from the mill (1) upward fine components are subjected to a screening, characterized in that at least a portion of the resulting from this screening is withdrawn as a further finished product. 5. The method according to claim 1, characterized in that the coarse constituents falling down through the nozzle ring (15) or the partial fraction used in the final classification and used as the finished product are subjected to post-drying 6. A method according to claim 1, characterized in that the air speed in the nozzle ring is between 30 and 60 m / s, preferably between 35 and 45 m / s. 7. The method according to claim 1, characterized in that the amount of the coarse constituents falling down through the nozzle ring (15) and conveyed up again by the mechanical conveying device (3) 25 to 200%, preferably 30 to 80%, the amount of the Mill (1) freshly added good. ₈ . A method according to claim 1, characterized in that the specific amount of air in the nozzle ring (15) is 0.5 to 4 m ³ / kg, preferably 0.8 to 2 m ³ / kg of the freshly fed material to the mill. ₉ . Plant for carrying out the method according to claim 1, containing a) an annular mill (1) with a rotating around a vertical axis (11) grinding table (12), rolling on it, designed as balls or rollers grinding bodies (13, 14) and with a stationary on the outer circumference of the grinding plate (12) arranged nozzle ring (15) for supplying an air stream which captures the fine constituents of the comminuted ground material discharged over the edge of the grinding plate (12) and carries them upwards, while the coarse constituents fall down through the nozzle ring (15), b) a mechanical conveyor device (3), preferably designed as a bucket elevator, for conveying up the coarse components falling down through the nozzle ring (15),
characterized by the following features: c) there are devices for adjusting the air volume and air speed in the nozzle ring (15); d) there is a post-classification device (4) for screening or classifying the coarse components conveyed up by the mechanical conveying device (3). 10. Plant according to claim 9, in which a preferably static classifier (2) is arranged above the mill (1), characterized in that on the separating funnel (48) of this classifier (2) a discharge device (49) for deducting a selectable portion the semolina separated in the sifter (2) is connected. 11. Plant according to claim 9 ", characterized in that at least one of the clear cross section of the nozzle ring (15) delimiting wall (20) is adjustable during operation from the outside. 12. Plant according to claim 10, characterized in that the nozzle ring (15) is divided into a plurality of separately adjustable segments (15a). 13. Plant according to claim 11, characterized in that a plurality of air supply lines (60, 61, 62, 63) are provided, to which separately adjustable segments (15'a, 15'b, 15'c, 15'd) are assigned. 14. Plant according to claims 10 and 11, characterized in that the clear cross section of the individual segments (15a) of the nozzle ring (15) outwardly delimiting wall parts (20) in the radial direction by means of a spindle operable by a handwheel or by an electrical , hydraulic or pneumatic drive (22) are adjustable. 15. Plant according to claim 13, characterized in that the adjustable wall parts (20) in the region of their ends facing the adjacent segments on parallel guide surfaces (17a, 18a) of fixed guide parts (17, 18) are guided. 16. Plant according to claim 10, characterized in that the nozzle ring (15) between ventilated and adjustable segments has individual non-ventilated segments. 1 ₇ . Installation according to claim 9, characterized in that means for influencing the _D üsenring (15 ') amount of air supplied, preferably an adjustable blower and / or Verstellklappen (64, 65, 66, 67) into the air inlets (60, 61, 62, 63) to the nozzle ring.

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