WO2005075082A1

WO2005075082A1 - Conical breaker

Info

Publication number: WO2005075082A1
Application number: PCT/EP2005/000849
Authority: WO
Inventors: Bruno Götz
Original assignee: Aubema Crushing Technology Gmbh
Priority date: 2004-02-03
Filing date: 2005-01-28
Publication date: 2005-08-18
Also published as: DE102004005400A1; EP1711266B1; ATE439188T1; DE102004005400B4; EP1711266A1; DE502005007885D1

Abstract

The invention relates to a conical breaker for rocks comprising braking cones which are arranged on a bearing cone shaft and an upper part associated therewith and to which a breaking cover is fixed, forming, together with the breaking cone, a tapered material inlet. The bearing cone shaft is eccentrically mounted in order to produce a rotating movement in an eccentric bushing and rests upon a lift piston. The eccentric bushing is provided with a drive for a rotational movement about the longitudinal axis thereof. The eccentric bushing is embodied as a cylinder in the lower region thereof, receives the lift piston in said region, is closed on the leg side by the base and rests upon an axial sliding bearing. It is also mounted in a slanted manner on the leg side.

Description

cone crusher

The present invention relates to a cone crusher for crushing rocks. These crushers consist of a support cone shaft with a crushing cone arranged thereon and a crushing jacket located above it. The crushing shell forms with the crushing cone a conically tapered inlet for the rock to be crushed, the crushing shell is fixed and the crushing cone performs a wobbling motion and thus breaks the rock by pressing against the crushing shell. In this way, cuboid fragments, which are e.g. find use in road construction. The crushing cone is freely rotatable relative to the support cone shaft, so that it is also able to perform a retrograde rotational movement with respect to the latter under the effect on the rock.

In the crushers of the prior art, the wobbling motion carrying cone shaft rests on a vertical lifting cylinder, which means that between these a concave plate must be provided as a sliding bearing whose size must exceed the foot of the journal shaft to enable the wobbling motion. The plate is concave.

The disadvantage is once a relatively complex production, on the other collects in the plate inevitably abrasion, which is caused by taking place under high load circular rubbing movement on the plate, the parts are thus subject to high wear.

For this reason, as well as the further high load of the machine with rock dust this is disassembled at regular intervals for cleaning and maintenance purposes. This requires in the prior art, a careful separation of upper and lower parts, ie the device must after unscrewing and removing the upper part by means of a crane ange- ange- be lifted, for example, to be able to pull the lifting cylinder down to flatten out the resting on this resting spherical thrust bearing of the cone shaft.

The present invention has the object of providing a cone crusher, which has a simpler storage of the cone shaft, which is exposed to reduced wear and in which the parts can be pulled upwards, possibly even without separating the device from the foundation ,

The solution to this problem is achieved with a cone crusher for rock with arranged on a support cone shaft crushing cone and this associated upper part to which a crushing shell is attached, which forms a tapered material inlet together with the crushing cone. The support shaft is eccentrically mounted in an eccentric bushing for generating a wobbling motion and rests on a reciprocating piston. The eccentric bush is provided with a drive for a rotational movement about its longitudinal axis, wherein the eccentric bushing is formed in its lower region as a cylinder and receives in this area the reciprocating piston. The eccentric bushing is closed at the bottom by a bottom and stands on a thrust bearing, wherein the eccentric bush is mounted at an angle on the foot side.

According to the invention, therefore, the lifting cylinder performs the same tumbling motion below the cone shaft as the latter; this means that for storage no convex-concave-convex surfaces have to slide on each other, but that flat surfaces can be used which are subject to much lower abrasion, e.g. This is because the abrasion does not accumulate in a depression, but can be carried away by the oil used for lubrication.

Advantageously, the eccentric bush stands on a slanted bottom which closes it downwards or else the lower edge of the eccentric bushing. The socket is itself cut diagonally, whereby the ground can then be up. Alternatively, if the thrust bearing arranged under the floor is firmly connected to the floor, then this too can have the oblique cut, in which case it rotates synchronously.

The cone shaft is guided in the eccentric bushing in the upper and lower radial plain bearings, with the eccentric extended to the top. This "top bearing" allows the cone shaft to rotate e.g. can be pulled out of the eccentric bush together with the reciprocating piston, since there are no undercuts that prevent this. In this case, the crushing cone can basically remain on the support cone shaft. Before, of course, the outer crutch is unscrewed.

The housing surrounding the eccentric bushing is also advantageously designed to widen upward, so that the eccentric bush (simultaneously with the journal shaft or thereafter) can also be pulled out of it.

The eccentric bush can have an (upper) shoulder on which a downwardly pointing pinion is arranged, which meshes with a bevel gear of a drive guided through the housing. When separating the eccentric bushing from the drive, it can remain in place.

In the eccentric sleeve occluding bottom according to the invention a rotary inlet is provided, through which hydraulic fluid can be passed to the underside of the piston to make the support cone shaft for adjusting the wedge-shaped gap between crushing shell and crushing cone. Further, in the bottom of a piston by cross-pipe is provided for Huberfassung, which can serve for the supply of lubricant to the radial sliding bearing. Further lubrication takes place via the bottom axial thrust bearing, which may also be a roller thrust bearing. Such a device is characterized in addition to the above-mentioned advantages of easier disassembly to repair and maintenance and longer service life by a much smaller design. Due to the fact that the piston for generating the stroke of the cone shaft performs the wobbling motion synchronously therewith, it also does not need to meet the high static requirements of the prior art; in the present case it does not perform the support function for the entire load caused by the tumbling motion occurring occurring dynamic forces are passed through the support shaft shaft itself to the eccentric bushing, which in the present case may be in one piece and directs the forces directly downwards over the floor or the foot-side radial bearing to the foundation.

Reference to the accompanying figures, the present invention will be explained in more detail.

Show

Fig. 1 is a section through the device and

Fig. 2 is an enlarged detail of the machine base.

In Fig. 1, the widening upward housing 8 is shown, which rests on a base plate 17. On the foot plate 17 is a thrust bearing

10 and on this the inclined bottom 9. Within the housing 8 is guided in the upper and lower radial plain bearings eccentric bushing 5, which in turn receives the support shaft 1, which also in this radial contact bearings

11 is present.

Also, this eccentric bush expands upwards and thus represents a pot bearing for the support shaft shaft 1. The eccentric bushing 5 has an upper shoulder 12, which carries a bevel gear 14 at its lower edge. The housing 8 has an opening which passes through a drive 7 arranged in a sleeve 18. is gripped, in which a drive shaft is mounted, the front side has a pinion 13 which meshes with the bevel gear 14.

The support shaft 1 is located on a thrust bearing 10, under which the piston 6 is located and which can be acted upon via a rotary inlet with hydraulic fluid to raise or lower the cone shaft as needed. For detecting the distance traveled, the bottom 9 and the piston 6 are penetrated by an oil supply pipe 16, via which lubricant can be supplied to the axial sliding bearing 10 and the radial sliding bearing 11. The inclined bottom 9 is connected to the lower edge of the eccentric bushing 5, rotates with the drive and thus creates the wobbling movement of the support shaft shaft first

On the support shaft 1, the support cone 19 is arranged, which carries the crushing cone 2 and generated by the wobbling motion exerted on it between the top and the crushing shell 4 having top 3 of the crusher a constantly changing wedge gap, whereby abandoned coarse rock is crushed into blocks, which it exits through the shaft 20 down.

2, the machine base is shown in an enlarged view. It can be seen the rotary inlet 15 for the hydraulic fluid within the trained as an inclined discs bottom 9 to the reciprocating 6. The lubrication of the device is designed for heavy contamination and happens once via the first supply line 21 via the oil supply pipe 16 to the inner thrust bearing 10 and the radial plain bearings 11 and on the other via the second supply line 22 to the bottom-side thrust bearing 10 and via this to the outer radial sliding bearing 11. The streams can be combined withdrawn and cleaned. In particular, the lubrication of the drive gears can also be done in this way. LIST OF REFERENCE NUMBERS

1 support cone shaft 2 crushing cone 3 upper part 4 crushing jacket 5 eccentric bush 6 piston 7 drive 8 housing 9 bottom

10 axial sliding bearings

11 radial plain bearings

12 shoulder

13 pinions

14 bevel gear

15 rotary input

16 oil supply

17 foot disk

18 sleeve

19 support cone

20 shaft

21 first supply line

22 second supply line

Claims

1. cone crusher for rock with on a supporting cone shaft (1) arranged crushing cone (2) and this associated upper part (3), to which a crushing jacket (4) is attached, which together with the crushing cone (2) forms a tapered material inlet, whereby the supporting cone shaft (1) is mounted eccentrically to generate a wobble movement in an eccentric bushing (5) and rests on a reciprocating piston (6) and the eccentric bushing (5) is provided with a drive (7) for a rotary movement about its longitudinal axis, characterized by the The following features: a) the eccentric bushing (5) is designed as a cylinder in its lower area and receives the reciprocating piston (6) in this area, b) the eccentric bushing (5) is closed on the foot side by a base (9) and rests on one Axial sliding bearing (10), wherein c) the eccentric bushing (5) is mounted on the foot side scnragstenenα.

2. Cone crusher according to claim 1, characterized in that the supporting cone shaft (1) in the eccentric bushing (5) is guided in upper and lower radial sliding bearings (11) and that the eccentric bushing (5) widens upwards in such a way that the supporting cone shaft (1 ) after removing the crushing jacket (4) together with the crushing cone (2) upwards from the eccentric bushing (5).

3. Cone crusher according to claim 1 or 2, characterized in that the housing (8) is designed to expand upwards, so that the supporting cone shaft (1) together with the eccentric bushing (5) can be removed from the housing (8).

4. Cone crusher according to claim 3, characterized in that the eccentric bushing (5) has an upper shoulder (12), on the underside of which a bevel gear (14) meshing with a pinion (13) of the drive (7) is arranged.

5. Cone crusher according to claim 1-4, characterized in that in the bottom (9) a rotary inlet (15) is provided for the supply of hydraulic fluid to the piston (6).

6. Cone crusher according to claim 5, characterized in that lubricant can be supplied to the upper and lower radial slide bearings (11) between the supporting cone shafts (1) and the eccentric bushing (5) via the tube (16).