DE19631734C2 - Impact crusher - Google Patents

Description

The invention relates to an impact crusher according to the Oberbe handle of claim 1.

DE-30 13 662 A1 is an impact crusher with a vertical Known axis of the rotor, which has a crusher housing, the surrounds the rotor in a ring. The bottom wall of the breakwater häuses has outlets for the crushed or regrind that from the ring wall are spaced. The bottom wall forms dementia speaking around a paragraph.

In impact crushers known from DE 38 44 178 A1 The generic type is the feed material in the middle of the rotor fed, which is comparatively high speed rotates and has flinging edges on its outer circumference, which give the crushed material a correspondingly high speed. In order to protect the crusher housing ring wall, it is provided regularly a material cushion made of crushed material all around leave. This cushion allows a massive, heavy one and avoid material-intensive design of the ring wall. It is also expedient below this material cushion another material cushion over a corresponding paragraph to provide. Due to the roughness of the material surface there is a certain braking effect for the discharge material and also a certain braking effect for any material dust.

Although generic impact crusher in comparison are lightweight and the crusher housing the occurring Withstand loads for a long time, it turns out that the rotor life is comparatively poor. The Slingshot edges are subject to heavy wear, and their brackets and the rotor outer wall is also covered by he  flying stones impaired.

In contrast, the invention is based on the object To create impact crusher according to the preamble of claim 1, which has an improved overall lifespan, equally is lightweight, but overall less prone to failure is working.

This object is achieved by claim 1. Advantageous further developments result from the dependent claims chen.

According to the invention, the paragraphs for the on Shorten the fill of the material cushion, taking it understands that nevertheless over the entire height of the crusher casing se-ring wall the material cushion is applied, and to the paragraph or the bottom wall of a cone tapering downwards join, which is an enlarged gap between the bre chergehäus bottom wall and the rotor. Will be surprising through this measure the lifespan of those used in the rotor Slingshot edges drastically extended by up to 80%. The lower rotor wall is also no longer back bouncing stones reached, these are rather along the Cone wall discharged downwards, so that the rotor as a whole has a longer service life.

Another particular advantage relates to the use of different degrees of moisture of the crushed material. If that Load was quite damp, it tended to be known th horizontal impact crushers, i.e. impact crushers with in the we significant vertical rotor axis, to growth in the area of the material cushion. These increases could also become one Closure of the crushing zone result in a corresponding Ma machine downtime and other disadvantages. Overra This tendency to grow can be achieved with the combination the features of the invention, that is, the shortened bottom wall  and avoid the cone that follows this. In spite of of the thinner material cushion is the service life of the crushing ridges Housing ring wall is not reduced, so that a total of both Lifetime and the susceptibility to failure of the fiction moderate impact crusher is better.

It is particularly advantageous if the gap width of the gap between the inner end of the bottom wall and the outer edge of the lower rotor wall approximately the radial length of the bottom wall ent speaks. The bottom wall is expediently comparatively radial short if the ring wall has a low height, and radial long if the ring wall has a comparatively large height points. Furthermore, the radial length of the bottom wall is from the mi the nominal angle of repose of the material to be crushed. The required Length can easily be determined experimentally by the driest and most pourable feed to use is well used and the resulting bulk angle of the material cushion is measured. With a medium one Angle of repose of an average height of the ring wall can make the gap width chosen approximately as large as the axial length of the bottom wall become, although it is understood that a very different length, such as double or half Length, is possible.

The cone angle preferably also corresponds to the cone wall essentially the angle of repose. It is understood that this Angle can be very different and only at one preferred embodiment can be 45 °. Preferably points accordingly the lower end of the cone wall has an In diameter larger than the outside diameter of the Rotors is about half the gap width.

The gap width is before in another according to the invention preferred design about as large as the height of the rotor, each but less than the height of the crushing zone, i.e. the height of the Ring wall. In relation to the rotor diameter, it leaves the  Adapt the gap width in wide areas to the requirements. For example, it can be about 1/4 of the rotor diameter gene, tests have shown that the lower rotor wall and the flinging edges of rebounding stones na no longer be hit when the angle of repose appropriate cone angle is provided.

Further details, advantages and features result from the following description of an embodiment of the Er finding based on the drawing.

The only figure of the drawing shows an embodiment of an impact crusher according to the invention in section in schematic representation.

An impact crusher 10 according to the invention has a rotor 12 which is mounted on a bearing 14 and is driven by a motor (not shown) via pulleys 15 . The impact crusher 10 also has a crusher housing 16 to which a motor is connected via a V-belt, not shown. The crusher housing 16 has a loading opening 18 and a discharge opening 20 , between which it extends vertically. Accordingly, the axis 22 of the rotor 12 also extends vertically.

The crusher housing 16 forms a crushing zone 24 around the rotor 12 . This is closed on the outside by a crusher housing ring wall 26 , against which a material cushion 28 made of crushed material rests during operation. The annular wall 26 extends circularly and has at its upper end a flange 30 on which a cover wall 32 is fastened, which is stiffened with ribs 34 '. The top wall 32 also forms the upper end of the crushing zone 24th

A bottom wall 34 adjoins the ring wall 26 at the bottom and extends just below the lower end of the rotor 12 . At the bottom wall adjoins a cone wall 36 at the bottom / inside, followed by another ring-shaped guide wall 38 . At the height of the discharge wall 38 struts 40 are supported, which serve to support the rotor. 4 struts 40 preferably extend at an angle of 90 ° to one another. The bottom wall 34 and the cone wall 36 are stiffened by ribs 42 which extend outside these walls.

Downward to the discharge wall 38 , a discharge cone 44 is flanged, which forms a further bottom wall 46 , which serves as a shoulder for the crushed material and generates a white material pad 48 during operation.

The rotor is formed in a manner known per se from an upper and a lower rotor wall 50 , 52 and the rotor outer wall. Between the rotor walls extend on the outer circumference or just inside the outer circumference 3 outlet openings with corresponding centrifugal edges 54 .

In operation, the loading opening 18 is continuously with loading material in the form of material to be broken. These pass through a rotor opening 56 into the rotating rotor, in which they are discharged to the outside. By the rotor they are brought to a high speed and leave the area of the rotor 18 at this speed. When they hit the material cushion 28 , they break into pieces in the breaking zone 24 and slide down along the cone wall 36 . The material cushion 28 automatically adjusts to a substantially trapezoidal cross-section, with an angle of repose 58 depending on the material to be crushed.

It is understood that preferably the rotor 12 runs at a lower speed when first loading, in order to initially build a material cushion 28 to protect the housing wall 26 .

The angle of repose 58 has a tendency to increase, because moist bulk material with a steeper angle of repose remains more easily in the area of the material cushion 28 than dry material with a correspondingly low angle of repose.

Due to the diverting function of the cone wall 36 , the feared bouncing back of stones against the centrifugal edges 54 and / or the outer rotor wall is largely avoided. On account of an enlarged gap width 60 , growths that could lead to a blockage of the crushing chamber or the crushing zone 24 can be largely avoided. Accordingly, the impact crusher 10 according to the invention works both with low wear and with little interference.

The crushed material is guided along the discharge wall 38 and slides along the material cushion 48 into the discharge cone 44 . By this measure, the exit speed is equalized and vibrations largely avoided by a possible vertical impact on a floor wall. According to a modified embodiment, the discharge cone 44 has a further paragraph corresponding to paragraph 46 . This embodiment is used when the exit speed of the crushed material is to be reduced further in accordance with the type of loading material used.

The preferred embodiment shown in the figure has a gap width 60 which essentially corresponds to the radial length of the bottom wall. In the example, the height of the cone wall 36 is somewhat larger than the gap width 60 . The remaining relative dimensions of the individual components to one another can be seen in the drawing, it being understood that a corresponding modification is possible depending on the field of application.

Claims (14)

1. Impact crusher with a rotor with a substantially vertical axis, which is surrounded by a crusher housing ring wall facing crushing zone, to which an inwardly projecting bottom wall connects below, with a gap between the end facing the rotor and the rotor is formed, characterized in that wall to the end of the bottom (34) is followed by tapering down cone wall (36) and that the radial length of the bottom wall (34) in the order of magnitude of the gap width (60). 2. Impact crusher according to claim 1, characterized in that the length of the bottom wall ( 34 ) speaks approximately the gap width ( 60 ) ent. 3. Impact crusher according to one of the preceding claims, characterized in that the cone wall ( 36 ) has a cone angle which speaks ent essentially the angle of repose ( 58 ). 4. impact crusher according to claim 3, characterized in that the cone angle is between 20 ° and 150 °. 5. impact crusher according to claim 4, characterized in that the cone angle between 30 ° to 90 ° and preferably about 45 ° is. 6. Impact crusher according to one of the preceding claims, characterized in that the cone wall ( 36 ) has a height which corresponds approximately to the height of the rotor ( 12 ). 7. impact crusher according to claim 6, characterized in that the height of the cone wall ( 36 ) is slightly less than the height of the crushing zone ( 24 ). 8. Impact crusher according to one of the preceding claims, characterized in that the gap width ( 60 ) is 1/12 to 1/2 of the rotor diameter. 9. impact crusher according to claim 8, characterized in that the gap width 1/3 to 1/6 and preferably about 1/4 of the rotor diameter is. 10. Impact crusher according to one of the preceding claims, characterized in that the length of the bottom wall ( 34 ) viewed in ra dialer direction is shorter than the height of the crusher housing ring wall ( 26 ) surrounding the rotor ( 12 ). 11. Impact crusher according to claim 10, characterized in that the length of the bottom wall is approximately half as long as the ring wall ( 26 ). 12. Impact crusher according to one of the preceding claims, characterized in that a discharge wall ( 38 ) for the discharge of the crushed material closes at the cone wall ( 36 ) after un th. 13. Impact crusher according to claim 12, characterized in that the diameter of the discharge wall ( 38 ) is slightly larger than the outer diameter of the rotor ( 12 ). 14. Impact crusher according to one of the preceding claims, characterized in that a discharge cone ( 44 ) adjoins the discharge wall ( 38 ) just below the end of a rotor-bearing housing ( 14 ).