DE1243955B - Cone crusher - Google Patents

Description

Cone crusher The invention relates to a cone crusher, the Movable crushing cone with its lower stub axle mounted in a single eccentric bushing is that gives him a gyrating pendulum motion, whereby the stub axle means an intermediate member which transmits the pressure to a supporting member connected to the housing is supported movably on all sides.

There are already cone crusher known in which this intermediate link is designed as a bearing disk between the crushing cone axis and the with the Housing connected support member is provided. In such an embodiment the bearing washer is arranged to move freely in the horizontal plane, and its The bearing surface for the crushing cone axis is spherically concave. With another Embodiment, the bearing washer has a bearing surface that is inclined to the horizontal for the crushing cone axis, whereby- the bearing disc with the rotating eccentric bushing is connected in such a way that it rotates with this.

The main disadvantage of this known support structure is in that due to the large relative movements between the crushing cone axis and the bearing washer on the one hand and the bearing washer and the support member on the other hand high friction losses occur. In addition, these known constructions are correct When adjusting the height of the crushing cone, the geometric bearing conditions no longer exist agree, which causes additional wear.

The aim of the invention is therefore to avoid these disadvantages, in particular to reduce the friction loss work in the bearing points as much as possible.

This object is achieved according to the invention in that the the Intermediate member that transmits axial pressure is designed as an all-round movable pendulum seat is, both with their spatially movable bearings located at both ends in the lower surface of the stub axle as well as in the supporting member connected to the housing intervenes. Significantly lower relative values occur at the bearing points of the pendulum support Bearing movements than in the known bearing washers. With the same vertical Loads are therefore the friction losses at the bearing points of the pendulum support much less than with the known designs of intermediate links.

In an advantageous solution to the inventive concept, it is proposed that that the spatially movable bearings of the pendulum support from spherical or hollow spherical There are bearing surfaces that are in corresponding cabbage ball or spherical counter bearings engage on the undersurface of the axle and on the support member. It is also suggested the counter bearing of the pendulum support on the support member via one or more prestressed To connect pressure accumulator with an adjusting element, this adjusting element for example be designed as a threaded spindle or as a hydraulic piston-cylinder unit can.

Another advantageous embodiment of the invention results in that the hydraulic piston-cylinder unit is designed to be double-acting.

In a further embodiment of the invention, it is proposed that the spherical To guide the bearing surfaces of the pendulum support beyond the center of the ball and of corresponding hollow spherical counter bearings, which are connected to the undersurface of the axle and the support element are connected to be encompassed, so that of the two bearings of the pendulum support Pressure and tensile forces can be transmitted.

Forces directed downwards in a large vertical direction can then also act on the Crushing cones are transmitted. The crushing cone can then; even if crushed material is between Crushing cone and crushing jacket is jammed, are moved downwards. This is also then possible if, due to the shape of the crushing cone and the crushing jacket, the: resulting crushing pressure is horizontal and therefore not a vertical component this resulting crushing force causes the downward movement of `des. Crushing cone supported.

The downward movement of the crushing cone causes the material to be crushed in the crushing chamber loosened and a restart of the cone crusher filled with crushed material without With the help of a special centrifugal coupling made possible.

Further advantages of the invention emerge from the description of the illustrated embodiments. It shows _ F i g. 1 one axial vertical section of a cone crusher with spring-loaded, mechanically adjustable Support member, F i g. 2 a support structure with a hydraulically adjustable support element, F i g. 3 a support structure with a hydraulically adjustable support member and a Pre-tensioned overload protection spring built into the support element, F i g. 4 one Supporting structure with spherical ones that extend beyond the center of the sphere on both sides Bearings and with double-acting hydraulic support and adjustment elements.

The cone crusher consists in a known manner of a lower housing part 1, an outer crushing ring 2, which is provided with a crushing chuck 4, and a Inlet funnel 3. With the inlet funnel 3, the upper bearing housing 5 is by means of several arms 6 connected. In this the crushing cone axis 7 is in a bearing bush 8 mounted longitudinally displaceable. This bearing bush 8 has a spherical bearing surface on the outside, which is supported on correspondingly shaped bearing shells 9. The upper neck storage room is protected against the ingress of dirt by a cover 10. On the crushing cone axis 7 is, in a manner known per se, a crushing cone 11 made of wear-resistant material attached.

With the lower housing part 1 is a central to the housing center by means of webs arranged bearing bush 12 firmly connected. In this is an eccentric bushing 13 stored in a known manner. The eccentric bushing 13 has one to the center of the bearing bush 12 and thus arranged obliquely eccentrically to the center of the eccentric bushing outer surface Hole for receiving the crushing cone axis 7. The center line 17 of this hole intersects in the middle of the upper neck bearing the housing center line 18.

The eccentric bushing 13 is from a countershaft 16 via a Bevel pinion 15 and a bevel gear 14 ixt rotating movement. When turning the eccentric bushing 13 around the housing center line 18 describes the center line of their Bore 17 has a conical surface. The tip of this cone is also the center 19 of the spherical neck bearing. The storage space of the eccentric bushing is against the crushing space 20 by a dust seal 21 of known type, which is simplified in the drawing is shown, shielded.

A bottom housing 22 is provided below the eccentric bushing, which the support members for the crushing cone axis 7 and the axial bearing 23 for the eccentric bushing 13 records.

In the implementation proposal shown in F i g.1, there are Support members essentially consist of a sleeve 27, which is in the bottom housing 22 Is mounted longitudinally displaceable, a pretensioned spring 28, a spring plate 29 and an adjusting spindle 30. The crushing cone axis 7 is supported on the sleeve 27 by means of a pendulum support 24. The pendulum support 24 has in the illustrated Suggested design at both ends of spherical or spherical shell-shaped bearing surfaces. These are in corresponding spherical counter bearings 25, 26 on the underside of the crushing cone axis and stored on the support member.

With a special design of the crushing cone 11 and the outer crushing tools 4, as is common with so-called secondary crushers, the crushing pressure creates a vertically downward force: the preload of the spring 28 is expediently set so high that it does not yield under normal vertical loading. If unbreakable foreign bodies get into the crushing space, the vertically downwardly directed forces exceed the normal level, the spring 28 is then compressed, and the crushing cone 11 can. evade downwards. The risk of any damage to machine parts through the entry of unbreakable foreign bodies into the crushing chamber is thereby avoided.

By turning the adjusting spindle 30, the support member, the Pendulum support 24 and the crushing cone 11 moved up and down. This will make the The crushing gap is reduced or enlarged. - The movement of the adjusting spindle 30 can be done manually or by machine.

Since all parts of the eccentric drive and the crushing cone support are within a closed gear room is a simple supply all bearing points with lubricant possible in a known manner.

In Fig. 2 is the execution of the supporting element with hydraulic Adjustment possibility and overload protection shown.

The lower counter bearing 26 for the pendulum support 24 is on a piston 31., which in a corresponding bore of the bottom housing 22 up and down can be moved, arranged. On the base of the bottom housing 22 is a Line 32 of a hydraulic system connected. This essentially consists from a pneumatic pressure accumulator 33 of known construction, a pump 34 and a liquid reservoir 35. Is removed from the reservoir by the pump 34 35 liquid is pressed into the cylinder space 36, the piston 31 and thus the crushing cone axis 7, 11 moves upwards. The crushing gap is reduced.

If the liquid is withdrawn from the cylinder space 36, the Dodge piston 31 downwards under the weight of the crushing cone axis. The crushing gap is enlarged.

If the crushing cone 11 and the outer crushing tools 4 are formed in such a way that vertically downwardly directed crushing forces act on the crushing cone, the above-described hydraulic adjustment device in conjunction with the pneumatic hydraulic accumulator 33 can act as an overload protection device. If the liquid pressure in the hydraulic system exceeds the gas pressure in the hydraulic accumulator 33, the liquid can escape from the hydraulic system into the hydraulic accumulator 33. The piston 31 moves downward and the crushing gap is enlarged.

In Fig. 3 is the execution of the support element with hydraulic Adjustment option and combined mechanical-hydraulic overload protection shown. The functioning of this system with the crushing cone adjustment is as already described above. Different from that in FIG. 2 shown Execution is here between the lower bearing 26 of the pendulum support 24 and the piston 37 a pretensioned spring 38 is arranged. The bias of this spring 38 is so chosen so that they are subject to normal stress from the crushing cone weight and the vertical crushing pressure component, which is used in secondary crushers of known design occurs, cannot evade.

Cone crushers, especially those for fine crushing, are today with eccentric bushing speeds on the order of '300 up to 500 rev / min. driven. If unbreakable foreign bodies get into the crushing chamber, To avoid machine damage, it is necessary that the overload protection respond very quickly. In the execution according to FIG. 3 becomes the first overload surge added by the pretensioned spring 38. Inadmissibly high pressure increases in the Hydraulic system and the associated leakage losses are avoided.

In the case of the in FIG. 4 is the embodiment of the support member shown, different from the embodiment according to F i g. 2, the adjusting piston 39 is designed as a double-acting piston. The spherical bearing surfaces of the pendulum support 40 extend beyond the center of the sphere and are encompassed here by the hollow spherical counter bearings 41, 42 by means of flanges 47 attached to them, so that 40 compressive and tensile forces can be transmitted from the pendulum support. It also corresponds to the sense of the invention if the spherical bearing surfaces are not arranged on the pendulum support but on the crushing cone axis 7 and the support member 26 and the corresponding hollow spherical counter bearings are arranged on the pendulum support 24. The bearing surfaces for absorbing the compressive forces can also be designed with different radii than the bearing surfaces for absorbing the tensile forces.

When adjusting the crushing cone, liquid enters the cylinder space 43 or 44 pressed below or above the piston 39 or drained therefrom. How the overload protection works in conjunction with the hydraulic accumulator 33 is as in FIG. 2 described. There is also the option of choosing between Pressure bearing 42 and piston 39 to arrange a preloaded spring, which in case of overload sprung. In the illustrated embodiments you can, if as a pressure fluid Lubricating oil is chosen, the spherical bearings of the pendulum support 40 over Supply bores 45, 46 with lubricant from cylinder space 43. In this case the oil pressure in the bearings would be proportional to the vertical load. It devices of a known type would then have to be provided which compensate which allow oil losses.

There is also the possibility of not how the eccentric bushing 13 in Fig. 1 shown to be stored in plain bearings, but in roller bearings. aside from that with a special design of the crushing area and the eccentric bearing, the upper one can Neck bearings are omitted.

Claims (7)

Claims: 1. Cone crusher, whose movable crushing cone with his lower stub axle is mounted in an eccentric bushing that gives him a spinning oscillating movement issued, whereby the stub axle by means of a pressure on a with the case. connected support member transmitting intermediate link on all sides is movably supported, characterized in that the intermediate member is a pendulum support (24) is formed, which are spatially movable with their located at the two ends Bearing points (25, 26) both in the lower surface of the stub axle (7) and in the support member (27) connected to the housing engages. 2. Cone crusher according to claim 1, characterized in that the spatially movable bearings of the pendulum support (24) consist of spherical or hollow spherical bearing surfaces which engage in corresponding hollow spherical or spherical counter bearings (25,26) on the lower surface of the axle and on the support member (27) . 3. cone crusher according to claim 1 or 2, characterized in that the counter bearing (26) of the pendulum support (24) on the support member (27) via one or more prestressed pressure accumulators (28, 33, 38) with an adjusting element connected is. 4. Cone crusher according to claim 3, characterized in that the Adjusting member is a threaded spindle (30). 5. cone crusher according to claim 3, characterized characterized in that the adjusting element consists of a hydraulic piston-cylinder unit in a known manner consists. 6. Cone crusher according to claim 5, characterized in that the hydraulic piston-cylinder unit.double-acting is trained. 7. Cone crusher according to claim 4 or 6, characterized in that with spherical bearing surfaces at the ends of the pendulum support (24), the hollow spherical counter bearings on the axle lower surface and on the support member are each provided with a flange, which the spherical bearing surfaces of the pendulum support to over the center of the ball encompass. Documents considered: German Auslegeschrift No. 1064 322; French Patent No. 1242124; USA. Patent Nos. 997918, 2349790, 2448 936, the 2,791,383th