WO1998022221A1 - Impact crusher - Google Patents

Abstract

The invention relates to an impact crusher (1) with a rotor (2) rotatably localised around a substantially vertical axis (3) and with a substantially ring-shaped case (5) surrounding the rotor (2). The inner wall of the case has impact surfaces (6) for crushing the material that emerges from the rotor (2). The feeding into the rotor (2) of the material that is to be crushed takes place mainly centrally and vertically in axial direction. The rotor (2) is designed with outlets (9) in its exterior circumference for the output of the material into the annular space that is defined by the case (5). The rotor (2) is designed with a projecting part or elevation (12) which protrudes from the outer circumference (13) of the rotor (2) at the edge of each outlet (9) upstream in the direction of rotation (10). The projecting part or elevation (12) is connected or arranged to run tangentially to the outer circumference (13) of the rotor (2), so as to enable the protection of the outlet (9) and, in particular, of the edge of each outlet (9) downstream in rotation direction, with corresponding abrasion resistance of the projecting part or elevation (12).

Description

 P RA L L M Ü H L E

The invention relates to an impact mill with a rotor rotatably mounted about an essentially vertical axis and an essentially ring-shaped housing surrounding the rotor, on the inner wall of which impact surfaces are provided for the comminution of material emerging from the rotor material to be shredded is carried out essentially centrally and vertically in the rotor in the axial direction and the rotor is formed on its outer circumference with outlet openings for the discharge of the material into the annular space defined by the housing, the rotor being on the leading edge of each outlet opening in the direction of rotation a projection or a protrusion protruding from the outer circumference of the rotor is formed.

Impact mills or impact crushers of this type, which due to the arrangement of the rotor are also referred to as vertical crushers or vertical mills, are used for crushing rock, sand, grit and crushed stone or, for example, for crushing lumpy, non-metallic material, for example cement clinker or the like. Used. In general, in impact machines of this type, the material to be comminuted is fed into a rotating rotor essentially in the center and in the axial direction, whereupon the material is subsequently thrown through outlet openings or passage openings on the outer circumference of the rotor and impinges on the inner wall of a housing surrounding the rotor , wherein the inner wall is optionally formed with baffle elements, for example in the form of specially designed baffle surfaces or tooth-like projections. The crushing effect takes place essentially in that the material to be crushed, which is accelerated by the rotor, hits the impact surfaces arranged on the inner circumference of the housing at high speed. The material rebounding or rebounding from the baffle arranged on the inner periphery of the housing again hits the outer periphery of the rotor. Around To obtain appropriate protection of the rotor and a corresponding comminution effect in such impact mills, a wide variety of embodiments have become known.

For example, both DE-C 43 19 702 and DE-OS 44 13 532 show an impact crusher or an impact mill, in order to achieve a multiple crushing or crushing process, the material to be reduced is radially directed from such a rotor against an inner wall of the housing is thrown, with a conically widening truncated cone rotatingly arranged underneath the rotor and the inner wall of the housing being provided to widen conically, so that when the material to be shredded moves due to the force of gravity to the bottom of the housing, a multiple breaking effect on the respectively conically widening surfaces of the To enable the inner wall of the housing as well as the insert connected to the rotor.

Furthermore, DE-OS 39 26 203, for example, shows an impact mill of the type mentioned at the outset, with additional impact surfaces or impact elements being provided on the outer circumference of the rotor to improve the size reduction effect of the material rebounding from the housing inner wall in the direction of the rotor outer wall, in such a way to achieve a corresponding crushing effect on the outer circumference of the rotor. A disadvantage of this embodiment is the fact that corresponding recesses or recesses are to be provided on the outer circumference of the rotor for accommodating additional baffle surfaces or baffle elements, so that overall drum-type rotors which are not commonly used can be used, in which, under certain circumstances, essentially flat, additional armor made of harder material are provided in order to avoid damage to the rotor by rebounding material as far as possible. In such impact mills it is also known that a point exposed to extremely high wear is the edge of the essentially radial outlet openings of the rotor and in this connection in particular the edge lagging in the direction of rotation. It is therefore known to design the edge of each outlet opening lagging in the direction of rotation with a corresponding hard material or with a hard metal reinforcement, reinforcement having become known, for example, from AT-PS 381 246 or from German utility model DE-U 89 13 943. Reinforcements of this type at the exit end of essentially arcuately curved passage channels through the rotor to accelerate the material to be comminuted in the radial ejection direction from the rotor are usually in the form of strips, since the hard material used is usually very expensive and extremely wear-resistant to abrasion, however is sensitive to impact stress due to the brittleness of this material. For the material to be properly discharged from the outlet openings, however, this reinforcement or such a wear element must be guided up to the outer circumference of the rotor in the region of the trailing edge of the outlet opening, so that these wear elements are exposed to an increased risk of material rebounding from the inner wall of the housing an impact load to be destroyed or damaged, which results in a time loss for performing the maintenance work as well as a high cost for the provision of the individual wear elements for a replacement of such a strip.

An impact mill of the type mentioned at the outset can be found in EP-B 0 276 848, for example, by providing projections on the leading edge of each ejection opening in the direction of rotation, a certain protection of the trailing edge provided with reinforcement is to be achieved. In this known design, these projections are formed by plate-shaped elements which protrude in the radial direction from the outer circumference of the rotor and which on the limiters each ejection opening are defined. However, these radially projecting projections are exposed to excessive wear and an increased risk of breakage due to material rebounding from the inner wall of the housing and therefore often have to be exchanged with great expenditure of time in order to achieve the desired protective effect, or they have to be produced from extremely expensive material.

The present invention now aims to develop an impact mill of the type mentioned at the outset in such a way that the projections or elevations provided in the region of the leading edge of an outlet opening are subject to less wear and thus the service life of the rotor is increased. The increased wear resistance of the protrusions or elevations further aims to prevent damage to the essentially radial outlet openings and in particular to wear elements which may be provided in the region of the edges of the outlet openings lagging in the direction of rotation due to material rebounding or rebounding from the inner wall of the housing and in particular of any metallic impurities that may be contained in the material to be shredded, which may have a higher mass than the material to be shredded and thus have a greatly increased impact impulse when rebounding from the inner wall of the housing, and thus reduce the service life or operating time of the Rotor and in particular the wear elements of the passage channels through the rotor as well as the outlet openings and in particular the wear elements on the edges lagging in the direction of rotation increase the outlet openings together with the projections or elevations on the leading edges.

To achieve this object, the impact mill according to the invention is essentially characterized in that the projection or the elevation are connected or arranged tangentially to the outer circumference of the rotor. Since according to the invention the rotor on the leading in the direction of rotation Edge is each formed with a protruding, tangential projection or an elevation, it is avoided that the materials rebounding from the housing inner wall, in particular metallic contaminants, onto the outlet opening and in particular onto the edge formed with a wear element and lagging in the direction of rotation in the region of the outlet openings hit. To reduce the wear of the elevations or projections, it is proposed according to the invention that the projection or the elevation or the wear elements connect tangentially to the outer circumference of the rotor or are arranged thereon. Wear elements, which are tangential to the outer wall of the rotor, for forming the projections or elevation on the leading edge of each outlet opening allow an essentially continuously running, largely flat outer surface of the rotor, in order to provide reduced wear of the material forming the projections or elevations and thus also to increase the overall service life of the rotor. Thus, with slight wear of the projections or elevations on the leading edge, effective protection of the outlet opening and in particular of the wear element on the trailing edge against material rebounding from the housing inner wall in the direction of the outer circumference of the rotor, so that the use or service life of the outlet opening and in particular a wear element is essentially limited by the naturally specified abrasion resistance, while damage to the wear element due to impact stress due to its brittleness can be largely ruled out. In particular, impurities, which can be formed, for example, by metallic parts which are contained in the material to be comminuted, are usually not comminuted during application and impact on the inside wall of the housing, so that their mass is the mass of the same on the inside wall of the housing during the first impact crushed material can significantly exceed and thus a great danger to the outlet opening and for the Represent wear elements in the area of the outlet openings of the rotor.

According to a particularly preferred embodiment, the design according to the invention is such that the projection or the elevation in the region of each outlet opening is formed by at least one wear element which can be fixed in particular releasably to a separate support element of the rotor. The use of detachably fixable wear elements to form the protrusions or protrusions protruding from the outer circumference of the rotor enables a secure arrangement and adaptation of the protrusions or protrusions to the operating conditions of the rotor. It is also possible to easily adapt already existing rotors by using, in particular, detachably determinable wear elements for the projections or elevations, and furthermore, when these projections or elevations wear, the wear elements can be replaced in a simple manner, in which case Context is particularly preferably proposed that the wear elements are formed from plate-shaped elements made of highly wear-resistant material, which are preferably releasably attached to the carrier elements of the rotor by means of a screw connection. In general, however, it should be noted that for the protruding, tangential projections or elevations, the insertable, for example plate-shaped, wear elements are significantly cheaper and easier to manufacture than, for example, wear strips to be provided in the region of the edges lagging in the direction of rotation, or generally protective elements for the outlet openings, so that also a if necessary, replacement of these wear elements projecting from the rotor circumference, which is to be provided at shorter intervals, is in any case more cost-effective than the usually more complex and costly replacement of the already known wear edges. Here, the additional wear elements according to the invention for forming the projections or elevations can also be made of one that is more resistant to impact loads and thus tougher material in contrast to the wear strips made of hard metal in the region of the trailing edges, since they are usually subject to abrasion to a much reduced extent. According to the invention, for example, a screw connection of the wear elements on corresponding carrier elements of the rotor is provided for a particularly simple fixing, it being immediately apparent that existing rotors can also be easily retrofitted by simply arranging carrier elements in the region of the outer circumference.

In order to adapt the operating conditions of the impact mill, it is also provided that the inclination of the support element and / or the wear elements of the projection or the elevation can be adjusted relative to the radial direction of the outlet opening, as corresponds to a further preferred embodiment of the invention. By adjusting the inclination and thus also the extent to which the wear elements forming a projection or a protrusion protrude from the outer circumference of the rotor, it can be ensured that the entire outlet opening and in particular the trailing edge with the brittle wear strip are securely in the drop shadow of the Projection or the elevation on the leading edge remains.

For a further adaptation to different purposes and, if appropriate, to increase the operating time of the wear elements forming the projections or elevations, it is also particularly preferred that wear elements with different thicknesses can be fixed on the carrier element or the outer circumference of the rotor.

In such impact mills or vertical mills at speeds of rotation, which can be, for example, about 600 to 1,400 revolutions per minute, and a rotor diameter of about 1 to 1.5 m, and the resulting peripheral speeds of the order of 40 to 80 m / s , surely an impact from the inside of the housing - o -

In order to avoid rebounding material or possibly larger metallic contaminants onto the outlet openings and in particular at the trailing edges of the outlet openings, it is also preferred that the projection or the elevation or the wear elements at least in the area of the leading in the direction of rotation Edge of the outlet opening protrudes the outer dimensions of the rotor by about 2-10%, preferably at least 5%, of the radius of the rotor. Such an elevation or such a projection must of course only be provided to this extent essentially in the region of the leading edge in the direction of rotation in order to ensure a sufficient drop shadow during the rotary movement for the outlet opening and in particular the trailing edge.

In the case of essentially plate-shaped wear elements, which are fixed to support elements in the region of the outside of the rotor, for further protection of the ends or edges of such wear elements facing away from the outlet openings, it is also preferably provided that the protrusion or the elevation or the Wear elements are followed by armor tapering towards the outer circumference of the rotor.

For a further reduction in the wear of the outer jacket of the rotor, it is also preferably proposed that the outer jacket of the rotor be formed with additional armor between the outlet openings, whereby a correspondingly wear-resistant outer jacket of the rotor can be achieved.

For a large number of known impact mills, an arcuately curved course of the passage channels through the rotor is proposed for the passage channels inside the rotor between the essentially central feed opening and the substantially radially oriented outlet openings located on the outer circumference of the rotor, by a to achieve corresponding deflection movement of the centrally and essentially vertically supplied material to be comminuted in the interior of the rotating rotor. Furthermore, such arcuate passage channels mostly result in the formation of material accumulations on the side surfaces of the passage channels lying on the outside in the direction of rotation, so that additionally supplied material to be shredded strikes these outer walls provided with a material layer and thus essentially by the impact of the material to be shredded when deflected by one vertical feed movement in a radial ejection movement the wear of the outer surfaces of the passage channels can be reduced by the material accumulations formed. As already mentioned several times, such designs are usually provided with a special ejection edge or wear strip made of hard metal in the region of the radial outlet openings on the edge lagging in the direction of rotation, in order to ensure a correspondingly long service life of the rotor on the particularly stressed ejection edge . However, it is immediately apparent that when additional material to be shredded collides with material that has already accumulated in the passage channels, frictional losses occur in such a way that the speed of the material to be shredded radially from the rotor is reduced, and thus the shredding effect due to the reduced speed is reduced when discharging the material and when impacting on the impact surfaces of the housing surrounding the rotor. In this context, according to a further preferred embodiment of the impact mill according to the invention, it is proposed that straight passage channels extend inside the rotor between the central feed opening for the material to be shredded into the rotor and the radial outlet openings of the rotor. Such essentially rectilinear passage channels in the interior of the rotor ensure that the entire energy originating from the rotary movement of the rotor is converted into a speed component to the essentially radial discharge of the material to be shredded is implemented from the rotor, whereby the radial arrangement of the passage channels prevents material accumulations inside the rotor, so that the friction losses which have to be taken into account in the case of curved passage channels due to material accumulations that form are avoided. The entire energy available through the rotary movement of the rotor can thus essentially be converted into kinetic energy for a corresponding acceleration of the material to be comminuted from the rotor.

In such straight-line passage channels, it is also proposed that the passage channels with a radial between the central feed opening for the material to be shredded into the rotor and the radial outlet openings of the rotor have an acute angle of less than 10 °, in particular an angle of approximately 5 °. or include an obtuse angle of more than 170 °, in particular of about 175 °, as this corresponds to a further preferred embodiment of the invention. This slight inclination relative to a radial means that the achievable acceleration and comminution effect can be matched exactly to the intended use, with a correspondingly higher acceleration when inclined by a positive angle and a correspondingly lower acceleration when a negative or obtuse angle is provided.

According to a particularly preferred embodiment, it is further proposed in this connection that the passage channels have a substantially rectangular cross section and are delimited by box profiles coated with elements made of highly wear-resistant material over substantially the entire length of the passage channels, thereby ensuring that the passage channels essentially are designed to be wear-resistant over their entire length. The elements can be used here highly wear-resistant material for cladding the passage channels can also be formed from corresponding smaller individual elements, so that if partial areas of the wear elements in the passage channels are damaged, a simple replacement of individual wear elements of small area can be carried out and the entire lining of the passage channels does not have to be replaced. Furthermore, due to the fact that essentially the entire length of the through-channels is lined with a wear-resistant material, this material does not have to be as wear-resistant as in the case in which the total wear effect is effective only on the wear edge of an ejection opening lagging in the direction of rotation is, so that overall with materials with increased mechanical strength and lower manufacturing costs can be found.

The impact mill according to the invention is explained in more detail below with reference to exemplary embodiments schematically illustrated in the accompanying drawing. In this show:

Figure 1 is a schematic sectional view through an impact mill according to the invention.

Figure 2 is a plan view of an impact mill according to the invention in the direction of arrow II of Figure 1 after removal of the cover.

3 shows an enlarged view of a schematic, perspective illustration of a rotor of an impact mill according to the invention; 4 shows a sectional view through the rotor of an impact mill according to the invention shown in FIG. 3;

5 is a perspective view of a modified embodiment of an impact mill according to the invention; and FIG. 6 shows a section similar to FIG. 4 through the rotor of an impact mill according to the invention shown in FIG. 5. In Fig. 1, 1 generally designates an impact mill or vertical mill, in which a rotor 2, which will be described in more detail below, is rotatably mounted about an essentially vertical axis and designated 3, the elements of a rotary drive in FIG .

1 are indicated schematically with 4. The impact mill 1 further comprises a housing 5 which surrounds the rotor 2 essentially in an annular manner, impact surfaces 6, schematically indicated at a distance from the rotor 2, being shown on an inner wall of the housing 5. Material to be shredded is introduced into the interior of the rotor 2 in the direction of arrow 7 in a substantially vertical direction. From this, the material to be comminuted, after corresponding acceleration, comes out of the rotor 2 via essentially radially oriented outlet openings, which are shown more clearly in the following figures, and is thrown onto the baffle surfaces 6 and crushed there. Shredded material is drawn off in the bottom region of the housing 5 via a schematically indicated opening 8 in the substantially vertical direction indicated by the arrow 19.

In the illustration according to FIG. 2, the reference numerals of FIG. 1 have again been retained for the same components. It can be seen that the rotor 2 in this embodiment has four substantially radially oriented outlet openings 9, from which material introduced into the interior of the rotor 2 is discharged and subsequently onto the baffle surfaces 6, which are only indicated by their outer contour, on an inner wall of the housing 5 hits. In the sense of the direction of rotation indicated schematically by 10, the rotor 2 points at the trailing edge in the region of the outlet openings 9 at the end of an arcuate passage channel 20 through the interior of the rotor

2 each have a wear strip or a wear element 11 which is formed from very abrasion-resistant hard material, in particular hard metal, for example tungsten carbide. Due to the composition of such hard metal inserts or strips, there is a high abrasion resistance speed, however, such strips 11 are very sensitive to impact stress, since such materials are usually very brittle. It is obvious that material emerging via the outlet openings 9 is reflected and thrown back by the impact elements 6 after impacting them, care being taken to ensure that an impact of material or, in particular, metallic foreign bodies contained in the material to be comminuted in Area of the wear edges 11 is prevented in order to avoid destruction or damage to the outlet openings 9 and in particular the wear edges 11. For this purpose, an essentially tangential projection or an elevation 12 is provided in the area of the outlet openings 9 on the edge leading in the direction of rotation 10, which protrudes beyond the outer jacket 13 of the rotor 2, so that a through the elevation or the projection 12 Drop shadow is formed, which prevents material rebounding from the impact surfaces 6 in the direction of the rotor 2 from striking the wear strips 11 at the edge of each outlet opening 9 lagging in the direction of rotation 10. Hiebei must be ensured that the elevation or the projection 12 has such a height and inclination relative to the jacket 13 of the rotor 2 that during the period necessary to cover the entire angular extent of an outlet opening 9 a predetermined position material bouncing back from the impact surfaces 6 cannot cover the path from the elevation or the projection 12 to the wear strip 11 in the direction of the rotor 2, but only in an area behind the outlet opening 9 and in particular behind the wear strip 11, in the direction of rotation 10 of the rotor 2 seen on the jacket 13 of the rotor 2.

3 and 4, a modified, special embodiment of the arrangement of such projections or elevations, which protrude from the jacket 13 of the rotor, is shown in detail. With this training, the - -

jumps or elevations of essentially plate-shaped wear elements 14 made of highly wear-resistant material, which can each be detachably fastened to a separate support element 15 fixed on the rotor jacket 13, screw connections 16 being indicated in this connection, for example. It can be seen that the projections or elevations formed by the plate-shaped wear elements 14 protrude from the outer contour of the jacket 13 of the rotor 2, in the plane of which the outer region of the outlet openings 9 and in particular the wear strips 11 also lies on the edges that lag in the direction of rotation , so that there is reliable protection of the wear strips 11 against rebounding material during the rotary movement 10.

4 it can be seen that the tangentially running wear plates 14 project from the jacket surface 13 of the rotor 2 by about 7 to 8% of the radius of the rotor 2 in the area directly at the leading edge of the outlet opening 9, this is sufficient to prevent the impact of material bouncing off the inner wall of the housing (not shown in FIGS. 3 and 4) on the outlet openings 9 and in particular the wear strips 11 at a conventional speed of such a rotor 2 in an impact mill.

Wear elements 14 of different thicknesses can be used for adaptation to different purposes, so that the height of the projection or the elevation can also be influenced directly. Furthermore, the tangential inclination angle of the wear elements 14 relative to the outer circumference 13 of the rotor 2 can also be set accordingly by means of correspondingly shaped wear elements 14 and / or by an additional adjustability of the support elements 15. In order to ensure an essentially continuous transition between the jacket surface 13 of the rotor and the protruding wear elements even when plate-shaped wear elements 14 are used, 3 and 4, an additional armoring 17 is indicated in each case. A further armouring between the individual outlet openings 9 or in the areas 14 not occupied by the elevations or projections on the outer circumference of the rotor 2 is indicated by 21.

In order to be able to ensure an essentially continuous course in the area of the leading edge of each outlet opening 9 by the provision of the carrier elements 15 and the wear elements 14, the carrier element 15 is in the embodiment according to FIG. 4 at its outlet opening 9 facing end beveled, as indicated at 18.

In the embodiment according to FIGS. 5 and 6, the reference numerals of the preceding figures have been retained for the same components. 5 is again a perspective view of a rotor 2, to which material to be shredded is fed via a central and essentially vertical task 22. Deviating from the preceding embodiments, in which essentially arc-shaped passage channels are provided in the interior of the rotor, in the embodiment according to FIGS. 5 and 6 it is provided that at the central feed opening 22, in each case essentially straight passage channels, possibly slightly inclined to the radial direction Connect 23, the radial outlet openings on the outer circumference of the rotor 2 are in turn designated 9. The course of the passage channels in the interior of the rotor 2 is indicated in FIG. 6 by the hatched areas 23, these hatched areas representing the wear elements schematically indicated in FIG. 5 and extending essentially over the entire length of the straight passage channels. The passage channels 23 of the embodiment according to FIGS. 5 and 6 have an essentially rectangular cross section and are delimited, for example, by corresponding box profiles, with a cross member running in the radial direction having 24 It is indicated to which cross members or cross flanges 25 each connect to the top and bottom sides, as can be seen particularly clearly from FIG. 5. The straight-line arrangement of the passage channels 23 enables an improved acceleration effect to be achieved on the material introduced into the interior of the rotor 2 essentially centrally via the feed opening 22.

5 and 6, in each case in the region of the edge of each outlet opening 9 leading in the direction of rotation 10, a tangentially extending projection formed by a plate-like wear element 26 or an elevation projecting beyond the outer circumference 27 of the rotor 2 is arranged, a screw connection is in turn schematically designated 16. The projections or elevations 26 provided in this embodiment in the region of the leading edges of each outlet opening 9 in the direction of rotation 10 also prevent the housing inner wall or the ring, which is again not shown in FIGS. 5 and 6, from surrounding the rotor whose impact surfaces rebounding material hits the outlet openings 9 during the rotary movement of the rotor 2 and thus leads to damage to the outlet openings 9 or the passage channels 23. Again, a corresponding adaptation to the operating conditions of the rotor 2 can be achieved by a corresponding choice of the length of the plate-shaped wear elements 26 projecting from the outer circumference 27.

Claims

Patent claims 1. Impact mill (1) with a rotor (2) rotatably mounted about an essentially vertical axis (3) and a substantially annular housing (5) surrounding the rotor (2), on the inner wall of which impact surfaces (6) for comminution of material emerging from the rotor (2) are provided, the material to be shredded being fed essentially centrally and in the axial direction vertically into the rotor (2) and the rotor (2) on its outer circumference with outlet openings (9) for the The material is discharged into the annular space defined by the housing (5), the rotor (2) at the leading edge of each outlet opening (9) in the direction of rotation with a projection or a protrusion (12) protruding from the outer circumference of the rotor (2) ) is formed, characterized in that the projection or the elevation (12) is tangential to the outer circumference (13) of the rotor (2) or are arranged. 2. Impact mill according to claim 1, characterized in that the projection or the elevation in the region of each outlet opening (9) by at least one on a separate carrier element (15) of the rotor (2) in particular releasably fixable wear element (14) is formed. 3. Impact mill according to claim 1 or 2, characterized in that wear elements of the projection or the elevation of plate-shaped elements made of highly wear-resistant material (14, 26) are formed, which on carrier elements (15) of the rotor (2) preferably by means of a screw connection (16 ) are fixed releasably. 4. Impact mill according to claim 2 or 3, characterized in that the inclination of the carrier element (15) and / or the wear elements (14) of the projection or the elevation is adjustable relative to the radial direction of the outlet opening. 5. Impact mill according to one of claims 1 to 4, characterized in that wear elements (14, 26) with different thicknesses on the carrier element (15) or the outer circumference (13, 27) of the rotor (2) can be fixed. 6. Impact mill according to one of claims 1 to 5, characterized in that the projection or the elevation (12) or the wear elements (14, 26) at least in the region of the leading in the direction of rotation (10) leading edge of the outlet opening (9) the outer dimensions of the rotor (2) protrude by about 2 - 10%, preferably at least 5%, of the radius of the rotor (2). 7. Impact mill according to one of claims 1 to 6, characterized in that on the projection or the elevation (12) or the wear elements (14) in the direction of the outer circumference (13) of the rotor (2) tapered armor (17) connects. 8. Impact mill according to one of claims 1 to 7, characterized in that between the outlet openings (9) the outer jacket of the rotor (2) is formed with an additional armoring (21). 9. Impact mill according to one of claims 1 to 8, characterized in that in the interior of the rotor (2) rectilinear passage channels (23) between the central feed opening (22) for the material to be shredded into the rotor (2) and the radial Extend outlet openings (9) of the rotor (2). 10. Impact mill according to claim 9, characterized in that the passage channels (23) with a radial between the central feed opening (22) for the material to be shredded in the rotor (2) and the radial outlet openings (9) of the rotor (2) one acute angle of less than 10 °, in particular an angle of approximately 5 °, or one include obtuse angles of more than 170 °, in particular of about 175 °. 11. Impact mill according to claim 9 or 10, characterized in that the passage channels (23) have a substantially rectangular cross-section and of substantially over the entire length of the passage channels (23) with elements made of highly wear-resistant material coated box profiles (24, 25) are.