DE2418619A1 - ROTOR FOR HAMMER CRUSHERS - Google Patents

Description

7 ^ 03-099

Hammer crusher rotor

The invention relates to a rotor for hammer crusher, the breaker hammers of which can be freely pivoted by jGO degrees are mounted between two adjacent disc sectors axially offset from one another over the circumference. In such a hammer crusher, the hammers are mounted in such a way that adjacent hammers are offset from one another in the circumferential direction in order to avoid impact-free zones by overlapping one another. The hammers protrude beyond the outer diameter of the rotor body so that the crushed material is crushed by impact.

A rotor for hammer crusher is already known (DT-AS 1 206 707), its freely pivotable through 360 degrees Breaker between every two over the circumference

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axially offset disk sectors are mounted, which are surrounded by radial ribs to the rotor shaft Support parts are connected. The disk sectors are as annular disk sectors on the outer zone of the rotor and connected by axially parallel ribs to a largely hub-free structure. In one embodiment of this known Rotor, the structure is provided on both sides with disc sectors having hubs, and the rotor shaft consists of two shaft stubs fastened in these hubs. With this embodiment the However, the rotor body can be formed in one piece over its entire length in order to thus become a support body form, which is to be connected rigidly to the shaft stubs. However, this makes them large and complicated Castings required and is also the application of the modular principle when building the rotor not possible. Venn several individual disks lined up in the aforementioned known rotor for hammer crusher the use of a continuous shaft as a load-bearing component is necessary because the lined-up panes do not have any bending or tensile stresses be able to record.

The object of the present invention is to provide a rotor for hammer crusher, which consists of individual There are panes that are connected without shafts to form a self-supporting body using the modular principle. The hammer crusher provided with such a rotor is also intended to crush hot material be suitable and consequently be cooled by forced ventilation.

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According to the invention, these objects are achieved by that the rotor body consists of several stacked disks, which extend through in the axial direction extending separate anchors are connected to a shaftless self-supporting body. Next to the The omission of a separate continuous shaft, which results in cost savings, is provided by the invention Hammer crusher rotor has the further advantage that the outer diameter of the rotor is against smaller than a version with a shaft who can. By connecting the individual panes a very rigid, self-supporting rotor body is created by means of an anchor on the outer edge of the rotor, which considerably exceeds the rigidity of a separate rotor shaft and thus one opposite Flexural and torsional vibrations represent a much more favorable construction.

The invention also has the advantage of having different rotor lengths as multiples of the disk length to be made by simply adding one or more panes in the manner of the modular system. This saves additional casting models, and storage is also made easier .

According to a further feature of the invention are the ■ Hubs of the individual disks plugged into one another in such a way that a central axial cavity acts as a cooling air duct is formed. The hubs of the individual disks have radially arranged openings for passage provided with cooling air. In this way, the hammer equipped with such a rotor is suitable

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Crusher is also particularly suitable for shredding hot material, as the rotor body and the hammers have forced ventilation be cooled. The supply of the necessary cooling air, according to the invention by the the hubs of the stacked disks formed hollow shaft is guided, takes place in a simple manner by, for example, rotary feedthroughs at one or both ends of the rotor. With a shaft provided A hollow shaft would have to have a considerable diameter, especially with larger rotor lengths and would thus increase the rotor outer diameter and the impact circle diameter of the hammers, provided that the The hammer can be rotated 360 degrees and should be free from the hollow shaft when it hits the bottom. The saving of the shaft in the present hammer crusher rotor So, as already said above, it has the outer diameter of the rotor compared to a version Keep wave smaller.

It is already a version of an air-cooled Rotors for hammer crusher known (DT-AS 2 004 385), in which the cooling air in a coaxially arranged to the shaft Hollow cylinder is passed. This known embodiment has overlooked the present invention however, the disadvantage of greater effort due to the additional cladding tube, a separate air supply housing, the required through shaft as well as due to the larger impact circle diameter in the event that the hammer should also be designed to be pivotable through 360 degrees.

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Further features of the present invention are that the axial armature with the individual disks are welded. The axial anchors can, however, also be provided with threads on at least one find each for holding a clamping nut.

The rotor according to the invention is further characterized by that the first and last disc of a rotor is designed so that stub shafts develop. The first and last disk can be made as one-piece castings.

The invention is explained in more detail below with reference to the drawing, which shows an advantageous Embodiment illustrated. She shows in

Fig. 1 shows a longitudinal section through the rotor at the marked with arrows C-D Places of the figure 2,

Fig. 2 shows a cross section through the rotor

at the points in FIG. 1 marked with arrows A-B,

3 shows a development of the entire circumference of the rotor s,

FIG. K shows an enlarged section at the point marked with K in ¹⁷ XgUr 1,

Fig. 5 shows a cross section of the arrows

E-F marked points of Figure 4,

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6 shows an enlarged section of the section marked with K. Place of Figure 1 in another embodiment and

FIG. 7 shows a cross section at the points indicated by arrows G-H in FIG Figure 6.

In Fig. 1, the structure of, for example, five center disks 1 and two end disks 2 with the integrally formed stub shafts 20 composite Rotor can be seen. Between the center disks 1 or between the center disks 1 and End plates 2, the hammer 10 are mounted on the continuous hammer shaft 11. The hubs l8 of the Center disks and 19 of the end disks are tubular so that they can be plugged into one another that an axial Cavity 9 is created, into which cooling air can be introduced from the ends, through radial bores 21 cools the rotor disks and hammers. The rotor is on both stub shafts through the bearings 8 stored.

The stacked discs are through the Anchor 5 to a self-supporting body of great Strength connected.

Fig. 2 shows in cross section an embodiment of the center disks 1. Four hammers 10 are shown on the

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Circumference and consequently four anchors 5 · There are, however Embodiments with different numbers of hammers per disc and a corresponding arrangement of the anchors are also possible. The dash-dotted circular lines 12 show the hitting circle of the single hammers which can be rotated by 3 ° 0 degrees 10.

In Fig. 3 an embodiment for the arrangement of the hammers is shown. The middle disks have the axial extension 3 »the end disks have the axial extension k . The sectors Ik and 15 of the center disks are indented so far from the respective ends that a minimal axial overlap 17 of the hammers is created, which gives a complete overlap of the striking tracks in the axial direction over the entire length of the rotor. The disk sectors Ik and 15 each have bearing hubs I3 on both sides, which are used to mount the hammer 10. The end disks have bearing hubs l6 for storing the hammers at two locations 18Ο degrees opposite.

FIG. K shows an embodiment of the invention in which the connection of the disks 1 and 2 is made by means of welded-in square anchors 5, the central disks extending over the length 3 and the end disks over the length k . As can be seen from FIG. 5, the disk sectors are excluded in the area of the continuous armature corresponding to the armature cross-section, which in this case is, for example, square. FIG. 5 also shows the continuous weld 22 between the armature and the disks 1 and 2.

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6 shows another embodiment of the invention, in which the individual washers 1 'and 2 ", which extend over the lengths 3 and k , are supported by an anchor 6 with a round cross-section and thread at one or both ends for the purpose of receiving a clamping nut 7 be connected in order to produce a self-supporting rotor body in this way.

It can be seen from FIGS. K and 6 that the hub joints 23 are designed in such a way that the radial joints are reduced by chamfering to such an extent that the deposition of material to be crushed is avoided or material to be crushed can easily fall off again.

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Claims (1)

; .- A..jD'U-3 = 'fc-S ^£ -? S5 AK "SNGESE SHAFT H.M3LRG Claims 1. Rotor for hammer crusher, its free by 360 degrees swiveling breaker hammer between each two over the periphery axially offset adjacent disk sectors are mounted, thereby characterized in that the rotor body consists of several discs (1, 2) stacked on top of one another, by a separate armature (5, 6) extending in the axial direction to form a shaftless one self-supporting bodies are connected. 2. Rotor according to claim 1, characterized in that the hubs (L8, I9) of the individual disks (1, 2) are plugged in so xnexnander that a central axial cavity (9) as a cooling air line is formed. 3. Rotor according to claims 1 and 2, characterized in that the hubs (l8, 19) of the individual Disks (1, 2) are provided with radially arranged openings (21) for the passage of cooling air. k. Rotor according to claim 1, characterized in that that the axial armature (5) are welded to the individual disks (1, 2). 5. Rotor according to claim 1, characterized in that that the axial armature (6) are each provided at at least one end with a thread for receiving one Clamping nut (7) 509845/0039 - 10 - I I3URG 3 » 6. Rotor according to claim I _1, characterized in that the first and last disc (2) of a rotor is designed so that stub shafts (20) are formed. 509845/0039 Blank page