DE875284C - Cone crusher - Google Patents

Description

Cone crusher The invention relates to a cone crusher that from a circular motion and with a: cover made of wear-resistant Material, such as manganese steel, has a crushing level that widens downwards consists, which the latter is in a crushing jacket with a lining of the same resistant material moves. Crushing jacket and crushing cone limit you crushing area directed downwards and outwards. Cone crusher, the crushing chamber of which has one or more Having steps are known. However, the gradation is relatively low and jumps back parallel or perpendicular to the axis of rotation of the crushing cone. None of the known step shapes, however, are capable of the flow or fall of material through the crushing chamber effectively stop. In contrast to the familiar, after the invention one becomes sharp recessed step provided of considerable width, which perpendicular to the conical 1lantelfläche of the crushing cone springs back and forms a pocket, which effectively and actually stops the falling material before it enters the next lower one Part of the crushing area arrives. The brick crusher according to the invention stands out through a better refractive effect, and there will be a more favorable design of the Crushing space and an improvement in the crushing jacket achieved, regardless of whether the the latter consists of one or more parts. With the improvement of the crushing mantle - one of the refractive cones is also pursued. The passage of the Materials through. the crushing zone by delay or. Interruption the material flow can be better controlled. More detailed is the purpose that comes with the invention is followed, even in the following description of the drawing set out.

According to the invention, the crushing space consists of a lower part, the from substantially parallel and conical sides of the crushing surfaces is formed, and a much wider upper part, which (the material feed control and limitation and from the lower part by a sharply recessed Shoulder in the crushing gel is separated, which is perpendicular to the crushing surface of the lower Part is arranged.

The crushing room can. also consist of more than two parts, whereby then each part is further than the next lower and from this through one shoulder or step according to the invention in the crushing. cone is separated. The one of yours -Breaking surfaces formed jacket of the crushing cone has a reinforced edge at the top End on, while the breaking surface of the breaking jacket in a substantially perpendicular Extension of the shoulder or shoulders expanded outward is graduated. Of the The uppermost part of the crushing surface of the crushing jacket also runs essentially parallel to the lowest part.

Finally, it is the one formed by the crushing surfaces of the crushing jacket Conical ring also designed correspondingly conical on its outer side, and the wall thickness is less at the top than at the bottom. The mainly parallel parts of the crushing surfaces of the mantle are connected to each other by those outwardly expanding parts.

A regular break is achieved by .securing a systematic and reined in. Material flow to the filling gap of the crushing chamber and through gradual Braking of the particles falling through the crushing chamber from the filling gap.

The invention is illustrated, for example, with reference to the schematic drawings shown and described.

Fig. Z - is a vertical one. Section through a cone crusher; Fig. 2 is a vertical section on an enlarged scale through the crushing space at the narrowest point; Fig: 3 shows a view corresponding to Figure 2 of the crushing chamber at a location with a larger spacing of the crushing surfaces..

'The outer ° o housing of the crusher is denoted by i, with its Shape is not shown further. Only the upper flange is marked with 2, on which the centering ring.3 for the crushing jacket comes to rest. The mating surfaces are conical in cross-section (outer surface q., inner surface 5). With 6 is a bolt: denotes, which holds the ring 3 in the position shown below Interposition of a helical spring 7 between the end of the bolt and the clamping ring B.

The centering ring 3 has an internal thread 9, which the crushing jacket i i with its outer thread io- carries. At your downward widening cone of the breaking jacket i i is a conical hollow ring i2 which forms the Bzechfläche attached, by means of hook-like lugs 13, which are held by eyelets i ¢. With 15 the hopper in the crushing jacket i i is referred to.

The crusher shaft 2o is eccentric by a rotating sleeve 21 Bore set in rotation, the sleeve 2 i at its upper end the gear 22 carries, which with the gear. 23 combs. As a result of the rotation of the sleeve 2 1 the wave 2o oscillates or circles with the crushing cone 25 around the point X.

The crushing cone z5 has a spherical bearing surface that is convex downwards 26, which is embedded in a l corresponding shell 27 of the cover 28, which the gear 22 protrudes and surrounds. The lid is on a seat 29 of the main frame attached. There are sealing strips on the outwardly extending apron 31 30 attached, which slide on corresponding strips 32 of the cover 28 in a sealing manner. The plate 36 is fastened to the plate carrier 35 with bolts 37. The carrier 35 rests on the upwardly extended sleeve 38, with which it is connected by screws 3.9 is. The sleeve 38 is fastened to the crushing cone head 25 with the screws 40. The sleeve flange 4a holds the locking ring 43 by means of the thread .1 .2. This The ring presses against the jacket 45 of the crushing cone, the design of which will be described later will. 4.6 with a funnel sleeve is referred to, which is on the ring .13 by screws 47 is attached.

Normally, the material to be broken is placed on the plate 36 below Use any. Abandoned feeding device. The material slips over the edge of the plate into the crushing space, .the of the conical surface 12 and the vibrating crushing cone shell .1 .5 is formed.

If a blockage occurs or fragile pieces fall into the crushing chamber between the breaking surfaces i2 and 45, then give the Federar 7 on the overstressed Side to side, the ring 3 gives way upwards and with it the normally stationary one Hollow cone 12.

According to FIG. I, the breaking surface 12 consists of three cones i2a, 12b, i2c of different inclinations together, the cones i? a and i2c being roughly the same Have a tendency. Advantageously, the crushing space expands at its upper end, for what purpose the conical surface recedes, thereby weakening the jacket provided at this point.

The inclination of the lateral surface d.5a corresponds approximately to the inclination of Surface i2a, but at q.5 b it jumps back sharply and points to the upper edge a slight thickening q.5c. The part q.5d of the mantle that does not violin .den Cone 12, works, is beveled. The crushing space is accordingly ring-shaped at A. expanded. The narrow part of the crushing space between, surfaces 12a and d: 5a (Fig. i) is denoted by B.

As a result of the design of the crushing area, there is a mastery of the Material flow through deceleration zones instead of. The pieces can the space between. the funnel walls 15 and 46 just happen so quickly and gradually A slide in as the dimensions of the crushing chamber opening allow. Of course In a crusher according to FIG. 1, only those pieces can be processed, which are no thicker than the distance between surfaces 12c and 45e. There now in the room A an annular pocket 45b is provided to hold a lot of particles can, these are stopped. No particle can therefore unbroken through the Get to the crushing zone. In space A, there is a certain degree of pre-eruption instead, so that particles of uniform size migrate into space B. Of the The breaking process in zone B is thus controlled in terms of time by the material inhibition in Zone A.

In Fig. 2 and 3, the lowermost breaking surface of the hollow cone 112 is with 11211 designated. Further up, the refractive surface recedes in stages, without d-aß the inclination changes significantly: the surfaces widening the crushing space to the outside are denoted by I I2c and, 112e, the inclined surfaces connecting them with 112b and II2d. The surface 1211 corresponds to the breaking surface 14511 of the jacket 145 on the Crushing cone. The receding surface i45 on the crushing cone lies with the crushing surfaces 112b and 112P of the crushing jacket opposite and is opposite to the crushing surface 145a separated by stage I45b. The result is the expanded room C. The von The surface 145e essentially separated from the surface 145e by a further step 145 ' the same inclination as the surfaces 145a and 145e. It then closes. the outer surface 145t at.

Instead of an inhibiting stage 45b in FIG 2 and 3, two stages 145b and 145d are provided. This creates a deeper, expanded crushing zone C and an even larger pocket D. Fig. 2 shows the crushing cone 31 in its narrowest Ouetsch position and FIG. 3 the cone in its furthest position. Through the invention, i.e. the graded design of the crushing space, becomes an increased breaking power. more uniform crushing result and a softer one Causes the machine to work. In addition, there is less wear and tear on the crushing surfaces with the result of greater metal savings. Except for the significant metal savings The time savings are also significant, since the machine is used to renew the crusher walls needs to be shut down less often.

There are of course deviations from the shape of the machine shown here. possible according to size, shape, number, arrangement and ratio of the parts, without d, ate thereby is departed from the inventive concept.

The shape of the crushing space according to the invention was chosen to during a zone with parallel throughout the life of the parts subject to wear Walls (zone B) as accurately as possible (zone between surfaces i2xa and d.511 in Fig. i and between surfaces 11211 and 145a in Fig. 2). Entering. of the material in this parallel delimited gap is only activated by a movement of the Head.

Only if the conical surfaces are parallel or nearly parallel can the crusher work properly. The inhibition level of zone A regulates the feed speed into the parallel zone B. According to FIGS. 2 and 3, two inhibition stages can also be provided be. Breaking to the final grain size begins below the edges 45b or 145b. From then on, acceleration due to gravity is no longer possible.

In the embodiment according to FIGS. 2 and 3, the regulated breaking process begins below the edge 145d. Accordingly, there is only one breakage in the parallel zone uniform grain size instead.

Claims (7)

PATENT CLAIMS: i. Cone! Crusher, consisting of a circular movement: executing and provided with a jacket made of wear-resistant material, such as manganese steel, downwardly widening crushing cone and a crushing jacket with a lining made of the same resistant material, which works together with the crushing surfaces of the crushing cone and. one down. and outside. directed crushing space, characterized in that the crushing space (A, B) consists of a lower part (B) which is formed by essentially parallel and conically oriented surfaces (d.511, iea) of those crushing parts (45, 12), and there is a substantially further upper part (A) which serves to control and limit the material feed and is separated from the lower part by a sharply recessed shoulder (45b) in the crushing cone, which is arranged perpendicular to the crushing surface of the lower part. 2. Cone crusher according to claim i, characterized in that the crushing space consists of more than two parts (B, C, D) , each part being wider than the next lower and from this through a shoulder or step (145b, 145d) is separated in the crushing cone (145). 3. Cone crusher make claim: i or 2, characterized in that that the shell of the crushing cone (45, 145) formed in front of the crushing surfaces at the top End has a reinforced edge (45e, 1451). 4. I, # - gel breaker according to claim 1, 2 or 3, characterized in that the crushing surface (I2, 1I2) of the crushing jacket in an essentially vertical extension of the shoulder or shoulders (45b, 145b, 145d) expanded outwards (, 2b, 112b, II2d) is stepped. 5. Cone crusher after Claim 4, characterized in that the uppermost part (12e, 112e) of the breaking surface of the crushing jacket (I I) essentially parallel to the lowest part (I211, I I211) runs. 6. cone crusher according to claim 4 or 5, characterized in that the formed by the crushing surfaces (I2, 112) of the crushing jacket Conical ring also on the outside correspondingly cone-shaped -is- and: at the top a smaller wall thickness has as. below. 7. Cone crusher according to claim 4 and 5, characterized in that that - the mainly parallel parts (r2a, r2c) of the crushing surfaces, of the crushing mantle (r2) with each other through those outwardly widening parts (12b) are connected. Referred publications: German patent specifications No. 656 857, 555 353-