RU103749U1 - CONE CRUSHER - Google Patents

Abstract

 1. A cone crusher containing a bed, an external fixed cone, mounted with the possibility of adjusting its height position, a support ring of an external fixed cone, interfaced with the frame body, a movable crushing cone located inside the frame body, rigidly mounted on the main vertical shaft and resting on a spherical thrust bearing, and the working surfaces of the cones are lined, in addition, containing an eccentric shaft, in the hole of which is installed the lower end of the vertical shaft, and the eccentrics the second shaft is placed freely in a cylindrical sleeve, pressed into the central cup of the bed, and a transmission for connecting the eccentric shaft with an electric motor, characterized in that it additionally contains a group of paired damping springs, with each group having one spring and the other spring, each pair mounted coaxially on the corresponding hairpin in cups of adjustable height, while the lower part of the support ring of the external fixed cone, which is made cylindrical th thread connected to the housing frame, and on top of the support ring, which is tapered by a depreciation of said springs mounted on the studs fixed outer cone, wherein the cushioning spring installed around the perimeter of the outer cone, and their axes coincide with the direction of the resultant force crushing. ! 2. Cone crusher according to claim 1, characterized in that for regulating the height of the glasses in which the shock absorbing springs are installed, they are equipped with adjusting nuts and are made sliding

Description

The utility model relates to crushing equipment, namely to conical eccentric crushers and can find application in metallurgy, chemical and non-metallic industry, as well as in the production of building materials.

The cone crusher according to the patent for utility model RU 91298, IPC В02С 2/02, publ. 02/10/2010. This crusher comprises a fixed cone connected to the bed by means of powerful springs, and a movable cone mounted on the main vertical shaft. The lower end of the main vertical shaft is mounted in an eccentric sleeve on which a bevel gear is fixed, which is meshed with a bevel gear mounted on the drive shaft. The working surfaces of the fixed and movable cones are lined with crushing plates of manganese steel, moreover, a spiral-shaped protrusion is made on the lining of the movable cone on its lateral surface.

The spiral-shaped protrusion allows you to forcibly "push" the material down the crushing chamber (the effect of the "meat grinder"). This allows you to get the effect of crushing stone material in the crusher "under the rubble" without excessive load on the elements of the crusher. In addition, the flaky grains that are present in the starting material and formed during crushing are destroyed as mechanically the weakest. Which leads to a high percentage of obtaining cube-shaped crushed stone (85-90%).

However, the use of this design of crushers does not allow to fully obtain the specified particle size distribution, since the crushing process is inevitably accompanied by regrinding of the crushed material, as a result of which increased energy consumption is traced, and this design does not provide for the unimpeded withdrawal of the crushed body if it gets into the crushing chamber.

Also known cone eccentric crusher according to the patent for invention RU 2284858, IPC V02C 2/04, publ. 10/10/2006. The cone eccentric crusher comprises a housing with an external crushing cone, inside of which there is an internal crushing cone with a shaft and with a drive eccentric mounted on it, which can rotate around the shaft. The eccentric is installed inside the cylindrical bearing sleeve mounted in the housing bore, with a radial clearance exceeding the size of the discharge gap between the cones. The cylindrical sleeve is coupled to the electric motor through a gear pair.

The proposed solution to the design of the drive unit allows the eccentric, and therefore the inner cone to perform circular oscillations with a relatively free amplitude and trajectory, which are limited by the size of the discharge gap between the inner and outer cones. The possibility of increasing the size of the discharge gap to the maximum allowable leads to an increase in the amount of processed raw material, i.e. makes it possible to work on a thick layer, which provides a more efficient process of its intralayer destruction, and, in turn, leads to an increase in the degree of crushing and productivity of the crushing process.

However, an overestimated stroke in the lower zone of the crushing chamber leads to excessive compaction of the crushed material, and the resulting prepressing of the material increases the energy consumption of crushing and the load on the drive units, and also contributes to wear of the cones by the armor.

Known cone crusher medium and fine crushing No. 2343000 RU IPC V02C 2/02, publ. January 10, 2009, which is adopted as a prototype, contains a bed, a movable inner cone, a fixed outer cone, a support ring of a fixed cone, an eccentric, a drive transmission of rotation of the eccentric connected to an electric motor.

The fixed cone is installed with the possibility of adjusting its height position; for this, the housing of the fixed external cone has a persistent external thread that mates with the support ring.

The movable crushing cone rests on a spherical support and is rigidly mounted on the shaft. The shaft end of the vertical shaft is mounted in the hole of the eccentric, which, in turn, is mounted in the central bore of the bed.

The bed is mounted on a support using elastic shock absorbers.

The rotation drive of the eccentric cup is carried out from a horizontal drive shaft through a bevel gear transmission, the wheel of which is rigidly fixed in the upper part of the eccentric. The eccentric is mounted inside the bearing bush and placed freely.

The disadvantage of the prototype, as well as other cone crushers, manufactured according to the design with the upper gyration point, is an unnecessarily large stroke in the lower zone of the crushing chamber. This leads to excessive compaction of crushed material (prepressing) and its further regrinding. As a result, the amount of crushed stone of small fractions increases. A considerable amount of energy is spent on prepressing the material. In addition, prepressing contributes to the inevitable additional wear of the cone armor. However, cone crushers with an upper gyration point cannot operate in the regime excluding this phenomenon due to the kinematics of the moving cone.

The task to which the utility model is directed is to reduce energy consumption, increase the resource of the working surfaces of the crusher, as well as minimize the wear of the main parts and assemblies, and improve the quality of the finished product.

The technical result that allows us to solve the problem is to reduce the effect of prepressing the material during crushing by providing an elastic suspension of the external fixed cone and eliminating its direct contact with mating surfaces.

The technical result is achieved as follows. As in the prototype, the cone crusher contains: a bed, an external fixed cone, mounted with the possibility of adjusting its height position, a support ring of the external fixed cone, conjugated with the frame body, a movable crushing cone located inside the frame body, rigidly mounted on the main vertical shaft and leaning on a spherical thrust bearing.

The working surfaces of the cones, as in the prototype, are lined. In the lower part of the bed, as in the prototype, there is an eccentric shaft, in the hole of which the lower end of the vertical shaft is installed, and the eccentric shaft itself is freely placed in a cylindrical sleeve, pressed into the central glass of the bed. The crusher contains a transmission for transmitting rotation to the eccentric shaft from the electric motor.

Unlike the prototype, the support ring of the stationary outer cone has a cylindrical lower part and a conical upper one. On the inner surface of the cylindrical part there is a persistent thread with which the support ring is mated with the upper part of the bed, which ensures the regulation of the position of the stationary cone in height, and, consequently, the size of the discharge gap.

The difference is also that the inventive cone crusher contains groups of paired depreciation springs, each pair is mounted coaxially on its corresponding stud in adjustable height cups, and in each group, one spring is the main one and perceives the forces arising from crushing, the other performs an auxiliary function and It is additional, due to which the constancy of crushing forces is ensured, which in turn allows avoiding the prepressing of the material in the chamber.

The body of the outer cone, located inside the support ring, is mounted on the upper, conical part of the support ring by means of damping and additional springs on the studs, which are installed around the perimeter of the outer cone and their axis coincides with the direction of the vector of the resulting crushing force. The glasses, in which the springs are installed, are made sliding and equipped with adjusting nuts, thereby it is possible to carry out a preliminary compression of the shock springs.

Among the known sources of information, no designs of cone crushers were found in the totality of the essential features that characterize the claimed utility model, which confirms its novelty.

Such a design of the mating support ring - the outer cone provides an elastic suspension of the outer cone without its direct contact with the mating surfaces.

The elastic suspension of the outer cone ensures the constancy of crushing forces, sufficient to destroy the crushed material and not exceeding the critical value of the forces at which the material is pressed, which allows to obtain a finished product with a high content of cube-shaped grains, reduce energy consumption for crushing due to reduced energy consumption for regrinding , increase the performance of cone crusher. And also to prevent wear or destruction of crusher parts due to the lack of hard contact. With this design, during the normal operation of the crusher, when the prepress phenomenon is not observed, the crushing process in the chamber is carried out as in traditional cone crushers, however, at the time of the prepress, when the forces arising in the crushing chamber exceed the efforts of the pre-loaded springs and the weight of the outer cone , some part of the compression stroke, the inner and outer cones are made together, thereby ensuring the invariability of the crushing forces. With the beginning of the departure of the inner cone from the external load, they decrease and the cones come back together to the lower position, without sharp dynamic impacts and wedging, unloading of material from the chamber begins.

The inventive utility model is illustrated in the drawing, which shows a diagram of the inventive device.

The positions in the drawing indicate the following: 1 - external stationary cone; 2 - movable crushing cone; 3 - a vertical shaft of a crushing cone; 4 - distribution plate; 5 - lining of a movable crushing cone; 6 - lining of a fixed external cone; 7 - a basic ring; 8 - bed with persistent external thread; 9 - depreciation springs of the outer cone; 10 - axial studs depreciation springs; 11 - glasses for installing shock spring; 12 - receiving box, 13 - additional springs, 14 - horizontal drive shaft, 15 - spherical thrust bearing, 16 - eccentric shaft, 17 - bevel gear of the eccentric shaft, 18 - bevel gear of the drive shaft, 19 - cylindrical sleeve.

The movable cone 2, lined with a replaceable crushing cone 5, is rigidly mounted on the main vertical shaft 3. The housing of the movable cone rests on a spherical thrust bearing 15, which receives the mass of the cone 2, shaft 3 and crushing forces.

In the center of the lower part of the frame 8, at the end of the vertical shaft 3, there is an eccentric shaft 16, which rotates with its outer surface in a cylindrical sleeve 19, pressed into the central glass of the frame 8, and rests on a thrust bearing. The transmission of the eccentric shaft 16, contains a horizontal drive shaft 14 mounted on rolling bearings, the horizontal shaft bearings are pressed into the housing. A bevel gear 17 is attached to the eccentric shaft 16, which is meshed with the bevel gear of the drive shaft 18.

In the upper part of the crusher there is a fixed external cone 1 with a replaceable lining 6.

The fixed cone 1 is mounted in the support ring 7 using special shock absorbing 9 and additional 13 springs, which are installed in the respective cups 11 in the direction of the vector of the resulting crushing force around the perimeter of the outer fixed cone 1. The springs are fastened with pins 10.

The support ring 7 has a persistent internal thread, which mates with the counterpart of the thread made on the frame 8 of the crusher. The fixed outer cone 1 can be moved down or up by turning the support ring 7 along the thread, thereby adjusting the crusher discharge gap.

The inventive device operates as follows. The material to be crushed from the receiving box 12 enters the distribution plate 4, mounted on the shaft of the crushing cone 2. When swinging the plate, the feed material is poured into the working space of the crusher, where it is crushed by the surfaces of the lining of the movable 2 and fixed 1 cones.

The drive shaft 14 through a pair of bevel gears 17, 18 transmits the rotation to the eccentric shaft 16. When the eccentric shaft 16 rotates, the crushing cone 2 swings relative to a fixed point - the center of the sphere 15.

Since the stationary outer cone 1 is mounted in the support ring 7 by means of shock-absorbing 9 and additional 13 springs installed in the direction of the vector of the resulting crushing force, at the moment when the crushing forces approach the critical values at which the regrinding of the material begins, the outer cone 1 begins to deviate together with crushing cone 2, thereby preserving crushing forces at the same level, due to this, the prepress effect is reduced, the quality indicators of the finished product are increased.

Passage of non-fragmentable bodies through the crushing chamber in the inventive device is carried out quickly and with less effort.

The cone is returned to its original position without collisions of the mating parts.

Thus, the above device can be used in practice in order to reduce the effect of prepress and improve the technical performance of the crusher.

The implementation of the device does not cause difficulties for specialists in this field. There is the possibility of its multiple manufacture and upon implementation of the receipt of the specified technical result. This confirms the industrial applicability of the utility model.

Claims (2)

1. A cone crusher containing a bed, an external fixed cone, mounted with the possibility of adjusting its height position, a support ring of an external fixed cone, interfaced with the frame body, a movable crushing cone located inside the frame body, rigidly mounted on the main vertical shaft and resting on a spherical thrust bearing, and the working surfaces of the cones are lined, in addition, containing an eccentric shaft, in the hole of which is installed the lower end of the vertical shaft, and the eccentrics the second shaft is placed freely in a cylindrical sleeve, pressed into the central cup of the bed, and a transmission for connecting the eccentric shaft with an electric motor, characterized in that it additionally contains a group of paired damping springs, with each group having one spring and the other spring, each pair mounted coaxially on the corresponding hairpin in cups of adjustable height, while the lower part of the support ring of the external fixed cone, which is made cylindrical th thread connected to the housing frame, and on top of the support ring, which is tapered by a depreciation of said springs mounted on the studs fixed outer cone, wherein the cushioning spring installed around the perimeter of the outer cone, and their axes coincide with the direction of the resultant force crushing. 2. Cone crusher according to claim 1, characterized in that for regulating the height of the cups in which the shock spring is installed, they are equipped with adjusting nuts and are made sliding.