DE102013206341B4 - Arched and polygonal crushing tooth arrangement in rotor and roll crushers - Google Patents

Abstract

Crushing tooth arrangement on the circumference of the two rollers or rotors of a roller or rotor crusher with teeth arranged in rows of teeth, wherein a row of teeth described by a shortest and geometrically simplest connecting line of all teeth in an axial direction and along the circumference of the roller or the rotor extending radial direction characterized in that the connecting lines of the rows of teeth (1) of the rollers or rotors are arcuate, continuously differentiable lines and in the axial direction opposite directions of offset angle (8), the course of homogenizing a non-homogeneous material distribution (6) along the length of Rollers or rotors required axial mass flow (8) correspond.

Description

The invention relates to the arcuate and polygonal arrangement of the crushing teeth on the circumference of rotors or rollers of rotor or roll crushers (arc and polygonal formation). The tooth height h related to the rotor or roller outer diameter D determines whether it is a rotor crusher (shaft breaker, sizer) with toothed rotors (h / D≥0.17) or roller crushers with toothed rollers (h / D <0.17) ,

Toothed rotors and rollers are used in rotor and roll crushers to improve feed ratios and to facilitate comminution by a concentrated application of force. Of crucial importance is the arrangement of the crushing teeth (tooth formation / crushing tooth arrangement). This has an effect on the intake behavior, in particular on the pull-in duration of large chunks of material, thus on the throughput behavior, in particular the material distribution along the rotor or roller length (throughput behavior) and ultimately also on the discharge behavior, in particular the oversize and defective form fraction in the crushed product. Furthermore, the breaking behavior, in particular the required breaking work and the temporal power curve and thus also the tooth wear along the length of the rotor or roller can be influenced via the formation of the crushing teeth.

The name of the tooth formation type is the shape of the connecting line of the tooth tips of a row of teeth in the rotor or roll development. To uniquely characterize the formation type, it is first necessary to determine which amount of teeth belongs to a row of teeth, because otherwise any number of periodic patterns can be found. 1 shows this with the example of a developed roller with a spiral tooth arrangement according to EP 0 167 178 B1 in which not only the correct connecting line of the spiral formation (a), for example, but also those of an arrow (b), multiple spiral (c) or alignment formation (d) could be drawn.

First of all, it follows that the type of formation depends only on the shape or inclination of axial connecting lines and on radial connecting lines as in 1 (d) are not named. Although the connection line can partially ( 1a , b) or partially complete ( 1c ) should be oriented radially, but must extend over the entire length of the roller. If it is furthermore assumed that the shortest and geometrically simplest axial connecting line is to be selected, variants (b) and (c) are also eliminated and only the desired variant (a) remains. Although straight lines or polygonal lines always form the shortest, but not in every case the geometrically simplest connection line (eg arrow formation with curved arrow edges in accordance with EP 1 385 630 B1 ). By radial offset of in 1 (a) defined tooth row to the value of the circumferential pitch t _u finally gives the complete Zahnbestückung the roller.

Thus, a row of teeth includes all the teeth in the axial direction, which describe in the settlement solely by radial offset the complete tooth placement and form the shortest and geometrically simplest connection line (= formation line). Analogously to the row of teeth, the toothed ring is defined in the radial direction, so that the number of teeth n is the product of the number of toothed rings n _a and the number of rows of teeth n _u .

Based on this definition, the tooth arrangements belonging to the free or patented state of the art can be defined. One of the simplest formations is the alignment formation, in which the row of teeth forms a straight line parallel to the axis of rotation of the roll or rotor body. Also well known are various offset formations in which the row of teeth forms a non-axis-parallel straight line or curved function.

So revealed the EP 0 167 178 B1 a spiral formation in which the row of teeth forms a straight line inclined in the rotor or roll development by an angle. This formation is found on the two counter-rotating crushing rollers of a mineral crusher, between which the feed material is crushed. The spiral arrangement of a roller can run the same or in opposite directions to the counter roll (see. 2 ). If the material to be fed is fed parallel to the roll axes from the side (axis-parallel task), the opposing spiral formation leads to a directed transport from the fed to the opposite side of the roll. In contrast, the spiral formation in the same direction causes a non-directional material transport above the rollers. In achssenkrechter task, where the material concentrated mainly in the middle of the roll, the opposite spiral formation is only conditionally suitable because it directs the material from the center of only one direction and thus effectively utilizes only one half of the roll. In both variants of this formation, each tooth of a roller to its corresponding tooth on the mating roll axially offset by t _a / 2 (see. 1 ), so that they can mesh with each other when the rollers are revolving. As another example disclosed WO 2010/032037 A1 a mineral crusher with rows of teeth having segmented staggered groups of teeth, and in which a crushing gap is formed between a crushing roller and a side panel attached to a hinge.

If throughput and wear behavior are decisive, it is important to ensure a uniform material distribution along the entire rotor or roller length. With an axis-parallel material supply from a rotor end or roll end, this can best be achieved by an opposing spiral formation (cf. 2 , A) can be achieved, as this activates an axial transport to the opposite side and thus relieves the task side. The axial transport operations above the rotors or rollers are effected by staggered tooth formation of the rotor or roller and counter rotor or roller. These form, while they move towards each other, in the settlement of an opening angle δ. In the opposite spiral formation ( 2 , A) corresponds to this, for example, the double offset angle γ (δ = 2γ, cf. 1 ). However, rotor or roll crushers are usually fed axially, with a different material distribution along the rotors or rolls, depending on the bulk material flow cross section on the supply conveyor. A one-sided axially parallel material supply is then less advantageous.

• – Formationen mit gleich-/ ungleichseitigen Pfeilflanken,
• – Formationen mit gleich/ ungleich geneigte Pfeilflanken,
• – Formationen mit geraden/ hohlkehlförmig gekrümmten Pfeilflanken,
• – Formationen deren Pfeilspitze zum Brechspalt hin / davon weg weist.

In the EP 1 385 630 B1 describes an arrow formation to be counted also to the offset formations, with which the problem of unilateral material transport in centric, achssenkrechter task is to be solved. The rollers of the multi-roll crusher described in this document are equipped with rows of teeth which run in the roll handling arrow-shaped towards the center. Usually, the opposing arrow formations of both rollers offset by half the axial pitch t _a / 2 to each other to allow a meshing of the teeth. The following formations are revealed in Scripture (cf. 3 ):

• - Formations with equal / non-uniform arrow edges,
• - Formations with equal / unequally inclined arrow edges,
• - Formations with straight / hollow-curved curved arrow edges,
• - Formations whose arrowhead points towards the crushing gap / away.

A two-sided material transport to the roll edges is only possible with pointing to the crushing point arrowheads. Otherwise, the material moves to the rotor or roller center.

Dental arrangements are also known from the prior art in which the basic formations occur several times per row of teeth, resulting in a zigzag (multiple arrow formation) or obliquely offset (multiple spiral formation) form for them.

It is also known to combine several basic formation types in each row of teeth. That's how it describes DE 20 2006 014 902 U1 a spiral arrow formation using the example of a single-roller crusher, in which the toothed roller interacts with an anvil and thus comminutes the feed material. The arrangement principle is then transferred to a two-roll crusher. It is characterized in that the teeth are first summarized in the circumferential direction to toothed rings. Two adjacent toothed rings of a roller are offset by a certain angle to each other and form a pair of toothed rings. Since not only the toothed rings of a pair of toothed rings but also the pairs of toothed rings of a roller are axially displaced, a spiral-shaped tooth arrangement with a superimposed arrow formation (cf. 4 ).

The invention has for its object to overcome the disadvantages of the prior art and to optimize the collection, discharge, throughput, crushing and / or wear behavior of rotor and roll crushers by improved tooth arrangements.

This object is achieved by the Brechzahnanordnungen the independent claims 1, 5 and 9. Preferred development of the invention are the subject of the respective dependent claims.

According to the invention the object is achieved by a crushing tooth arrangement on the circumference of the two rolls or rotors of a roll or rotor crusher, characterized in that the connecting lines of the rows of teeth of the rollers or rotors are arcuate, continuously differentiable lines and in the axial direction have opposite Versatzwinkelverläufe, the Course of an axial mass flow required for homogenizing a non-homogeneous material distribution along the length of the rollers or rotors (arc formation).

The axial mass flow necessary for the homogenization or homogenization results from the differential mass balance between the too much or too little discontinued material relative to a flow cross-section which is uniform along the roll or rotor axis (US Pat. 5 A). Thus, for a real bulk material flow cross section, with a linear rise on both sides to a feed maximum in the center of the roll or rotor at L / 2 (L = roll length), a doubly parabolic course over the roll or rotor length results for the material to be fed or removed axially with maxima at L / 4 and 3L / 4 and a minimum at L / 2 ( 5B ). This axial mass flow, with which a uniform material distribution along the rotor or roll length is achieved, follows from the integration of the linear course of the head height difference between the rotor idealized homogeneous and the real bulkhead cross section ( 5A , B).

To generate this Axialmassestroms axial feed forces are necessary, which are generated in rotating rollers or rotors through tooth tips of tooth arrangements with an offset angle γ> 0. The amount of this feed force is dependent on sin (γ) and since sin (γ) ≈ γ holds for small angles, there is a proportional relationship between the offset angle γ and the axial feed force or speed. It follows that the offset angle course necessary for the homogenization corresponds to the course of the axial mass flow necessary for the homogenization ( 5B ). Only with an opposing arrangement of the rows of teeth of the two rollers or rotors results from the respectively generated axial feed forces a directed movement.

Since the ascents of a row of teeth of the two rollers or rotors correspond exactly to the offset angle, their course can be determined by integration of the offset angle profile or the course of axial mass flow (FIG. 5B ) directly. For the non-uniform flow cross-section with a double-sided linear increase to the feed maximum at L / 2 ( 5A ) are thus arcuate rows of teeth for homogenization necessary ( 5C ). For the integration, the offset angle profile must at least be continuous in sections (cf. 5 , B). Consequently, the resulting formation line of the crushing teeth according to the invention is continuously differentiable along the entire axial extent of the roller. Advantageously, by the inventive Brechzahnanordnung any, uneven material supply, if it is known, along the rollers or rotors or homogenized. Such homogenization along the rotors or rollers makes sense, since so the tooth wear in the center of the roll advantageously reduced and thus a longer service life of the roller or the rotor can be achieved. In addition, the material flow in the low-flowed edges is advantageously increased, thereby enabling a higher throughput.

According to the invention, each tooth of a roller is offset axially relative to its corresponding tooth on the mating roller in such a way that it can mesh with one another when the rollers are rotating.

In a preferred embodiment of the arch formation according to the invention, the rows of teeth are in the axial direction by polynomial functions second (see. 7 , A), third (cf. 7 , B) or higher. Particularly preferably, the offset angles of the rows of teeth decrease steadily in the axial direction up to an apex S and have a constant course over the axial overall extent of the roller or of the rotor. In contrast to known arrow formations, the vertices S of the arcuate connecting lines do not form points of discontinuity (arrowhead), so that an excessive stress on the central toothed ring is counteracted. With the further preferred, in the axial direction having a parabolic course having rows of teeth can be many real Schüttquerschnitte easy, without knowledge of the exact cross-section and thus evenly along the roll or rotor axis even.

Furthermore, multiple formations of the crushing tooth arrangement according to the invention are preferred, wherein the rows of teeth in the axial direction have sections of crushing tooth arrangements or offset angle courses which are repeated in sections. This makes it possible to establish several crushing centers along the roll or rotor axis and also to homogenize complicated bulk material flow cross sections. Such a crushing tooth arrangement particularly preferably has rows of teeth which have wave-shaped progressions in the axial direction. If several parabolic tooth formations are arranged one behind the other in the axial direction, the resulting multiple formation at the transitions of the repetitive crushing tooth arrangements can not be continuously differentiated. Apart from these transitions, the multiple formations preferably have no further points of discontinuity.

In a further preferred embodiment of the arch formation according to the invention, the rows of teeth of both rollers or rotors have different offset angle profiles. Thus, the axial feed forces generated by the individual rollers may differ from each other. This advantageously allows the use of different rollers, wherein, for example, a more heavily loaded roller is changed after a certain life, the other, however, remains in the roll or rotor crusher.

Even with the crusher tooth arrangement according to the invention, it is necessary for a combing of the teeth that the rows of teeth of the two rollers have an offset relative to one another in the axial direction. Arc formation according to the invention is therefore particularly preferred in which the rows of teeth of both rolls or rotors are displaced in the axial direction by a distance d _a > 0 (cf. 8th ) and mirroring can be made to coincide on an axis of symmetry parallel to the axis of rotation. Advantageously, decentering or centering crushing tooth formations with rows of teeth, the vertices of which point towards or away from the crushing gap, can be realized.

With the Brechzahnanordnung invention is advantageously ensured that the Teeth of rotor or roller are utilized more uniformly, which increases both the life of the tooth assembly, as well as the throughput of the rotor or roll crusher.

Also advantageous is the versatility of use of the arch formation according to the invention, for any ratios of tooth height h to tooth tip diameter D, so both rotor crushers with toothed rotors (h / D ≥ 0.17) as well as roller crushers with toothed rollers (h / D <0.17 ) can be used. Arc formations can also be advantageously formed from any number of rows of teeth n _u and toothed rings n _a , which have any, in particular not only equal distances from each other. In addition, arc formations can also be used for any desired rotor and roller pairings, for example from a rotor and a roller or two or more rotors and rollers with any desired tooth formation relative to the active partner.

Further subject of the invention is a crushing tooth arrangement on the circumference of the two rollers or rotors of a roll or rotor crusher, characterized in that the rows of teeth of the rollers or rotors of axially aligned tooth subsets consist of at least two teeth which are offset in an arrow shape and arranged in opposite directions to each other in such a way that a tooth subgroup forming the arrowhead in a roll or rotor development has a larger distance to the entrance of the breaker gap than the tooth subgroups which are external in the axial direction. According to the invention, each tooth of a roller is offset axially relative to its corresponding tooth on the mating roller in such a way that it can mesh with one another when the rollers are revolving (polygonal formation).

The rows of teeth are each formed from at least three tooth subgroups, the simplest arrow-shaped offset arrangement consists in that the outer tooth subgroups in the roll or rotor development are positioned closer in the direction of the refractive gap than the middle tooth subgroup. If the row of teeth consists of more than three tooth subgroups, the axially outermost subgroups of teeth in the roll or rotor unwinding are positioned in the radial direction closest to the crushing gap. This radial distance then increases tooth subgroup for tooth subgroup, wherein the "subheading" forming a dental subgroup in the roll or rotor unwinding has the greatest distance to the Brechtspalt. If the row of teeth from this "arrowhead" in the direction of the next tooth subgroups has the same offset angle on both sides, corresponding subgroups of teeth in the "arrow edges" each have the same radial positions.

A rotor or roller pairing with these crushing tooth arrangements with teeth rows arranged in opposite directions advantageously forms a polygonal crushing space for the penetration and crushing of large chunks of material in the development (cf. 9 , B). Due to the dependence of the intake behavior of the forming between the teeth Primärbrechraum above the rotors or rollers causes this Brechzahnanordnung optimized feed behavior, especially for large and hard chunks. In addition, a more uniform load can be achieved when breaking, since fewer teeth engage at the same time. Due to the offset of the tooth subgroups, the polygonal formation according to the invention furthermore advantageously reduces the blockage risk during the breaking operation.

In a preferred embodiment of the polygon formation, the row of teeth has different offset angles from the "arrowhead" in the direction of the next tooth subgroups or between two respectively corresponding tooth subgroups of the two "arrow edges" (cf. 10 , A). Corresponding tooth subgroups then each assume different radial positions in the two arrow flanks of a row of teeth. This advantageously prevents elongated oversize particles from slipping through the rows of teeth without being crushed. Furthermore advantageously, the number of teeth engaging in the material to be broken at the same time can be further reduced.

In a preferred embodiment of the crushing tooth arrangement, the tooth subgroups are tooth pairs or tooth triplets. Also preferably, the number of crushing teeth varies between the individual tooth subgroups. As a result, it is also possible to form complicated polygonal crushing spaces, which can advantageously be adapted to a breaking pattern which frequently occurs in a particular type of rock.

Also preferred is a polygon formation in which the rows of teeth have multiple tooth subgroups offset in the shape of an arrow. As a result, several fracture zones can advantageously be created along the roll or rotor length (cf. 11 , A).

The polygon formations according to the invention can advantageously be used in a variety of ways, in particular for any ratios of tooth height h to tooth tip diameter D, that is to say both in rotor crushers with toothed rotors (h / D≥0.17) and in roller crushers with toothed rollers (h / D <0.17 ), for any number of rows of teeth n _u and toothed rings n _a , which have any, in particular not only equal distances from each other and for any rotor or Walzenwirkpaarungen of a rotor and a roller or two or more rotors and rolling with any tooth formation relative to the active partner.

embodiments

Reference to several embodiments and illustrations, the invention will be explained in more detail below, without being limited to these examples. Showing:

1 : Roll unwinding of a roll with drawn spiral (a), arrow (b), multiple spiral "(c) or" alignment formation "(d), as well as offset angle γ, circumferential pitch t _u and axial pitch t _a ,

2 : Roll unwinding of a roll with a spiral tooth arrangement according to FIG EP 0 167 178 B1 in counter (A) or in the same orientation (B) of the rows of teeth of roller and counter roller,

3 : Roll unwinding of a roll with an arrow-shaped tooth arrangement according to EP 1 385 630 B1 with pointing to the crushing gap, straight (A) and hollow cone-shaped curved (B) arrow edges,

4 : Rolling of a roll with a spiral tooth arrangement with superimposed arrow formation according to DE 20 2006 014 902 U1 .

5 : (A) the dumping height of an idealized (over the roll or Zuförderbreite applied 5 ) as well as a real ( 6 ) Schüttquerschnitts under a angle of repose with a maximum bulk height at L / 2; (B) the axial mass flow applied over the roll width for homogenizing or homogenizing the idealized ( 7 ) as well as the real ( 8th ) Schüttquerschnitts; (C) roll unwinding with the row of teeth with alignment required for homogenizing the idealized bulk material cross section ( 9 ) as well as the row of teeth with arch formation required for homogenizing the real bulk cross section ( 10 )

6 : an isometric 3-D view of a roll (A) and the associated roll development of a sheet formation ( 10 ) (B),

7 : Arc formation with formation lines of a polynomial function of second (A) and third (B) order,

8th : Roll unwinding of a decentering (A) and a centering sheet formation (B),

9 (B) : a roller handling with polygon formation ( 11 )

10 : Roll unwinding of a polygon formation with unequal (A) and equal (B) offset angle between the tooth subgroups,

11 : Roll development of a multiple polygon formation with two crushing spaces (A) and a polygon formation with different tooth subsets (B).

A crushing roller with a bow formation according to the invention 10 is in 6 presented in a 3D view in cavalier perspective as well as in a roll handling.

In the 7 arcuate formations exemplified comprise a bow formation having formation lines of polynomial function of second (A) and third (B) order. Advantageously, the arc formations can be represented by polynomial functions of arbitrary order, since these are always continuously differentiable and exclude points of discontinuity, as they occur in the arrow formation at the arrowhead.

In 8th are archformations with decentering (A) or centering (B) arc segments facing away from the crushing or away, shown. When pointing in the direction of crushing sheets, the material is directed to the rotor / roll edge (decentering) and otherwise to the center (centering).

It is also possible to connect a plurality of curved formations in a multiple arc formation in a wavy manner within a row of teeth.

A crushing roller with a polygon formation according to the invention 11 with a polygonal crushing space 12 is in 9 shown in an isometric 3D view as well as in a roll handling.

The continue in 10 Exemplary polygon formations include those with the same ( 10B ) and unequal ( 10A ) Offset angle between the tooth subsets as well as polygon formation with two 4 ( 10 . 11 ) and three 13 ( 9 . 11 ) Teeth per tooth subgroup. The number of teeth per tooth subgroup can also vary within a rotor or a roller or relative to the counter rotor or the counter roller ( 11 , B). Finally, it is also possible for several polygon formations to be connected in series within a row of teeth (multiple polygon formation) and thus more crushing spaces 12 train ( 11 , A).

LIST OF REFERENCE NUMBERS

1

 teeth

2

 toothed ring

3

 Breaking tooth (peak)

4

 pair of teeth

5

 Idealized flow cross-section

6

 Real pouring cross section under a Schüttwinkel

7

 For homogenizing the idealized bulk flow cross section, the required axial mass flow

8th

 For homogenizing the real bulk cross section required Axialmassestrom or offset angle course

9

 To homogenize the idealized bulk material cross section required row of teeth (corresponds to alignment formation)

10

 Number of teeth required for homogenizing the real bulk cross section (corresponds to arch formation)

11

 polygon formation

12

 Polygonal primary crushing space

13

 Zahntripel

Claims (14)

Crushing tooth arrangement on the circumference of the two rollers or rotors of a roller or rotor crusher with teeth arranged in rows of teeth, wherein a row of teeth described by a shortest and geometrically simplest connecting line of all teeth in an axial direction and along the circumference of the roller or the rotor extending radial direction characterized in that the connecting lines of the rows of teeth ( 1 ) of the rollers or rotors arcuate, continuously differentiable lines and in the axial direction opposite directions of offset angle ( 8th ), which correspond to the course of a homogenization of an inhomogeneous material distribution ( 6 ) axial mass flow required along the length of the rollers or rotors ( 8th ) correspond. Crushing tooth arrangement according to claim 1, characterized in that the rows of teeth can be represented in the axial direction by polynomial functions of the second, third or higher degree. Breaking tooth arrangement according to one of claims 1 and 2, characterized in that the offset angles of the rows of teeth ( 1 ) in the axial direction and in the direction of a vertex (S) decrease and have a steady course. Crushing tooth arrangement according to one of the preceding claims, characterized in that the rows of teeth ( 1 ) in the axial direction parabolic curves ( 10 ) exhibit. Crushing tooth arrangement on the circumference of the two rollers or rotors of a roller or rotor crusher with teeth arranged in rows of teeth, wherein a row of teeth described by a shortest and geometrically simplest connecting line of all teeth in an axial direction and along the circumference of the roller or the rotor extending radial direction characterized in that the connecting lines of the rows of teeth ( 1 ) of the rollers or rotors are in axial sections arcuate, continuously differentiable lines and in the axial direction opposite directions of offset angle ( 8th ), which correspond to the course of a homogenization of an inhomogeneous material distribution ( 6 ) axial mass flow required along the length of the rollers or rotors ( 8th ), the rows of teeth ( 1 ) are formed in the axial direction in sections repetitive crushing gear arrangements according to claim 1. Breaking tooth arrangement according to claim 5, characterized in that the rows of teeth have wave-shaped courses in the axial direction. Crushing tooth arrangement according to one of the preceding claims, characterized in that the rows of teeth of both rollers or rotors differing offset angle profiles ( 8th ) exhibit. Crushing tooth arrangement according to one of the preceding claims, characterized in that the rows of teeth ( 1 ) of both rollers or rotors by displacement in the axial direction by a distance d _a ≥ 0 and mirroring can be brought to an axis of rotation parallel to the axis of symmetry to coincide. Crushing tooth arrangement on the circumference of the two rolls or rotors of a roll or rotor crusher, having crusher teeth arranged in rows of teeth, one row of teeth passing through a shortest and geometrically simplest connection line of all the teeth in an axial direction and a radial direction running along the circumference of the roller or the rotor is described, characterized in that the rows of teeth ( 1 ) of the rollers or rotors each of at least three axially aligned tooth subsets ( 13 ) each having at least two crushing teeth ( 3 ), wherein the tooth subsets are offset in an arrow shape and the rows of teeth are arranged in opposite directions, so that a tooth subgroup forming the arrowhead in a roll or rotor development has a greater distance to the entrance of the crushing gap than the outer tooth subgroups in the axial direction. Crushing tooth arrangement according to claim 9, characterized in that the tooth subgroups are arranged with different offset angles to each other. Crushing tooth arrangement according to one of Claims 9 and 10, characterized in that the dental subgroups are tooth pairs ( 4 ) or tooth triplets ( 13 ). Breaking tooth arrangement according to one of claims 9 to 11, characterized in that the number of crushing teeth ( 3 ) varies between the dental subgroups. Breaking tooth arrangement according to one of claims 9 to 12, characterized in that the row of teeth ( 1 ) is formed of three tooth subgroups. Breaking tooth arrangement according to one of claims 9 to 12, characterized in that the rows of teeth ( 1 ) have multiple arrow-shaped offset to each other tooth subgroups.

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