RU91007U1 - CONE CRUSHER - Google Patents

Abstract

1. A cone crusher comprising a housing with an outer cone mating with a thread, and also with a spherical support for the inner cone with a shaft and an eccentric of the inner cone mounted on it with a bearing, mating with a cylindrical bearing bush located in the housing aligned with it, and also with a transmission connected to an electric motor, characterized in that the eccentric is placed freely in the radial direction relative to the bearing sleeve, which is made in the form of an eccentric drive element ka. ! 2. Crusher according to claim 1, characterized in that the cylindrical bearing sleeve is made in the form of an intermediate support of the eccentric. ! 3. Crusher according to claim 1, characterized in that the cylindrical bearing sleeve is equipped with a device for adjusting the radial amplitude of the eccentric and the inner cone.

Description

The utility model relates to crushers of medium and fine crushing. It can be used for crushing ores, building and metal materials.

The existing technological lines for crushing and grinding materials in the world require the sequential installation of 4-6 machines. In particular, cone crushers and rod or ball mills.

Due to the fact that the efficiency of mills does not exceed 1%, and in crushers it is close to 20%, there is a tendency to transfer the main part of the grinding work to crushers, excluding mills. However, over the last 150 years of the existence of cone crushers, their degree of crushing has been increased from 4 to 7, although a crushing degree of at least 30 is required for the reduction in the amount of equipment mentioned above.

Crushing in cone crushers is carried out by compression and shear. However, the level of these deformations is determined by the amplitude of the inner cone, which has a certain value equal to the eccentricity of the drive eccentric of the inner cone. The rigid kinematic connection between the crushing cones, similar to a crank drive like that of a steam locomotive, allows efficient crushing of the material only in a thin layer, which leads to a decrease in productivity and to the possibility of crushing the crusher during overloads. An attempt to establish a large discharge gap between the cones leads to a small deformation of the material layer and to a decrease in the degree of crushing under conditions of a forcedly constant amplitude of the cone.

A known Symons cone-type eccentric crusher (US patent No. 3302896, 11/14/1965, B02C), which includes a housing with an external cone and an internal cone placed on a spherical support, is mounted on the shaft of which an eccentric mounted on a shaft is installed in the bearing sleeve of the housing and connected by a gear pair to the engine.

The known crusher does not regulate the crushing force and the degree of crushing, which can only be increased to 5 by setting a small discharge gap by rotating the outer cone in the thread, which inevitably leads to a decrease in productivity. In addition, at the same time, to avoid a decrease in the degree of crushing, the material is loaded into the crusher in a metered way, preventing overflow of the crushing cavity. Another disadvantage of the known crusher is the impossibility of starting or stopping it when the crushing chamber is completely filled in order to avoid breakage of the crusher drive mechanism, as well as the impossibility of maintaining a stable degree of crushing during the abrasive wear of crushing cones.

Known cone eccentric crusher with hydraulic adjustment of the position of the inner cone in height to change the size of the discharge gap (US patent No. 3456889, 04/10/1967, V02C).

The crusher comprises a housing with an outer cone and an inner cone with a drive clown on its shaft installed in the bearing sleeve of the housing. The inner cone with the upper part of the shaft installed in the hinge of the housing, and the lower part supported through a spherical support on the piston of the hydraulic cylinder that controls its vertical position, that is, the size of the discharge gap between the cones.

As in the first analogue, the crushing force is not regulated in the known crusher, but it is possible to stabilize the size of the discharge gap between the cones by continuously compensating for the abrasive wear of the cone armor due to the automatically working hydraulic system for adjusting the position of the inner cone. Thus, at the cost of greater complexity of the design, a higher degree of crushing is achieved than in the first analogue, equal to 6.

Known for the prototype cone eccentric crusher (US patent No. 4339087, 8.09.1980, B02C), comprising a housing with an outer cone, means for its threaded height adjustment, a support for the inner cone with the shaft and a drive eccentric placed thereon using a bearing mounted inside the bearing bush of the housing and connected to the transmission by an electric motor.

A disadvantage of the known invention is the presence of a rigid kinematic connection between the inner cone and the outer one. The drive eccentric is coupled to the crusher body through a bearing with small clearances, therefore, when the eccentric is rotated, the inner cone receives gyration oscillations corresponding to the eccentricity of the eccentric, which eliminates the use of an eccentric and an internal cone for crushing centrifugal forces, which in this case overloads the bearing and prevents an increase in the number cone swings. Therefore, the layer of crushed material cannot be deformed by a value greater than the value of the eccentricity. Hence, the degree of crushing of such a machine does not exceed 7. In addition, such a machine cannot be switched on and stopped under load to prevent damage to the drive mechanism. In order to pass through an unbreakable body, the crusher must have spring or hydraulic safety devices, which complicates the design.

The objective of this utility model is to create a cone eccentric crusher having an adjustable degree of crushing from 5 to 30 while increasing productivity.

Another objective of this utility model is to create conditions for selective crushing over weak mineral surfaces due to self-grinding of the mineral in a thick layer in combination with control of the crushing force.

The next objective of this utility model is to create a design that allows you to turn on and stop the crusher under load and adjust the wear of the cones by armor by self-screwing the outer cone in the thread through the use of crushing force.

Another objective of the utility model is to provide conditions for the release of the crushing cavity from the indestructible body without the use of safety devices and stopping the crusher.

The final objective of this utility model is to simplify the drive of the inner cone.

These and other tasks of the utility model are implemented in a crusher containing a housing with an external cone threaded to it, as well as a spherical support for the inner cone with a shaft and an internal eccentric eccentric mounted on it using a bearing and mated to a cylindrical bearing bush located in housing coaxial with it, as well as with a transmission connected to an electric motor, in which, in accordance with this utility model, the eccentric is freely positioned in the radial direction relative to a rose bush, which is made in the form of an eccentric drive element.

It is also advisable that the cylindrical bearing sleeve was made in the form of a link of the intermediate support of the eccentric.

In addition, it is advisable that the cylindrical bearing sleeve was equipped with a device for adjusting the magnitude of the radial amplitude of the eccentric.

In the proposed crusher, the eccentric is placed freely relative to the bearing sleeve, so that it can freely move inside it in the radial direction when it rotates on the shaft of the inner cone, which under the action of the centrifugal force of the eccentric receives gyration movement on the spherical support until the cones come in contact with the cones in the absence of crushed material. To exclude a crusher of contact, which is dangerous for reliability, by armor, it is equipped with a device for adjusting the amplitude of the inner cone.

Distinctive features of the claimed device allow you to control the amplitude of the inner cone and the mutual movement of the cones relative to each other, as well as adjust the crushing force, the amount of deformation of the layer of crushed material, productivity and degree of crushing.

The inventive crusher provides the destruction of pieces of material about each other in a thick layer, which in turn leads to an increase in the degree of crushing from 5 ÷ 6 to 20 ÷ 30. Thanks to new properties, the crusher can replace the fine crusher and ball mill, working in a closed cycle.

In particular, the implementation of the inventive crusher with a cone with a diameter of 2200 mm and a special crushing chamber that accepts 85% of granite pieces smaller than 120 mm will produce a product containing 85% of particles smaller than 5 mm with a capacity of 350 t / h and an installed engine power of 320 kW. The degree of crushing is 24, and according to the average particle size in the food and in the product - 32.

Fig. 1 shows in longitudinal section a structural diagram of the proposed cone eccentric crusher, which contains a housing 1 with an outer cone 2 and a spherical support 3 for the inner cone 4, having a shaft 5, on which with the help of the bearing 6 there is a drive clown 7 mounted freely in a cylindrical bearing sleeve 8 on its spherical heel 9. The sleeve 8 is mounted in the housing 1 by means of a radial bearing 10 and a thrust bearing 11. A gear wheel 12 which is included in the bushing is rigidly fixed to said sleeve 8 gear with a gear 13 connected through an elastic coupling 14 with an electric motor 15. The shaft 16 of the gear 13 is placed in the bearings 17 of the housing 1. The sleeve 8, with its eccentric surface 18, is in contact with the cam 7. For free movement in the radial direction of the cam 7 inside the bush 8 (Fig. .2 and 3) the minimum clearance 19 between their surfaces in the horizontal plane is set larger than the maximum allowable discharge clearance 20 between the cones 2 and 4. However, the size of this clearance can be adjusted by the crescent-shaped insert 21, closed insulated on sleeve 8 with the possibility of circular movement and fixation. The outer cone 2 is interfaced with the housing 1 by means of a thread 22. The housing 1 is mounted on a support using elastic shock absorbers 23.

Figure 4 shows a variant of the proposed crusher with a V-belt drive 24.

Figure 5 shows an isometric image of the proposed crusher.

Crusher works as follows.

First, the crusher is loaded with gravity material from the hopper, providing a pressure at the inlet of the crushing chamber of at least 0.7 t / m ² , then the crusher is turned on. The eccentric 7 receives rotation from the electric motor through the clutch 14, the gear wheel 12 and the gear 13, the sleeve 8, through its eccentric surface 18. When the eccentric 7 rotates, a centrifugal force develops, causing the inner cone 4 to make gyration movements on the spherical support 3, rolling around over the crushed layer material, and deforming it by a value proportional to the centrifugal force of the eccentric 7 and the inner cone 4.

Thus, in the zone of maximum convergence of the cones, a layer is formed corresponding to the established value of the crushing force and the resistance of the material layer.

That is, the joint rotation of the sleeve 8 and the eccentric 7 is carried out by involving the latter in the rotation of the inner surface 18 of the sleeve 8, without restricting the movement of the eccentric in the radial direction.

The deviation of the eccentric 7 and the cone 4 from the axis of the crusher can be adjusted by a crescent-shaped liner 21, which can move along the inner eccentric surface 18 of the sleeve 8, changing the radial clearance 19 between the eccentric 7 and the inner surface of the liner 21. The gap 19 can be set so that it will be exclude contact of cones 2 and 4 in the absence of material between them. If the gap 19 is made close to zero, then the crusher turns into a prototype with a degree of crushing 7. In addition, the greater the mass of the unbalanced part of the eccentric 7, that is, the greater its static moment, the greater the centrifugal force, the amplitude of the inner cone 4, the deformation of the layer material and degree of crushing.

In the proposed crusher, the conditions of Newton’s second law on the dynamic interaction of freely moving bodies are satisfied, when the action is equal to the reaction MA = ma, where M and m are the masses of the bodies, respectively, A and a are the accelerations of these bodies. M and A are the characteristics of the housing 1, and m and a are the characteristics of the inner cone 4 in total with the eccentric 7. The total centrifugal (crushing) force of the inner cone 4 is determined by the formula F = F _c + F _e = ω ² (m _c · l _c + m _e · l _e ), where F _c and F _e are the centrifugal forces of the inner cone 4 and the eccentric 7, respectively; ω is the angular velocity of rotation of the eccentric; m _c is the mass of the inner cone 4; m _e - unbalanced mass of the eccentric portion 7; l _c is the amplitude of the center of gravity of the inner cone 4; l _e is the distance from the center of gravity of the eccentric 7 to the axis of the inner cone 4.

Thus, it can be seen from formula F that a 2-fold increase in the number of revolutions of the eccentric makes it possible to increase the crushing force by 4 times, and an increase in the mass of the inner cone, its amplitude, and the mass of the unbalanced part of the eccentric makes it possible to increase the crushing force in direct proportion.

The free movement of the eccentric 7 inside the sleeve 8, respectively, creates the conditions for the free movement of the inner cone 4 inside the outer cone 2. Due to this, the crusher can be switched on under load, gradually increasing the amplitude of the inner cone 4. For the same reason, if an invisible body enters the crushing cavity, the inner cone 4 it will shift in the opposite direction and let the body pass through without breaking the drive mechanism.

If the size of the discharge gap between the cones exceeds the permissible idle speed of the crusher, then the cones will not collide, since the eccentric 7 will come into contact with the inner surface of the sleeve 8, which eliminates further convergence of the cones. Work in the operating mode with such constant contact will be equivalent to the known eccentric crushers with a low degree of crushing 4 ÷ 5.

Thus, the distinctive features given in the formula are necessary and sufficient for the implementation of all tasks.

Thus, any cone eccentric crusher, including the above analogues, can be redone in accordance with the distinguishing features of the present invention. At the same time, it will receive an adjustable degree of crushing from 5 to 30 and a productivity increased by 30%. The cost of such an alteration will not exceed 20% of the initial cost of manufacturing a crusher.

Claims (3)

1. A cone crusher comprising a housing with an external cone mating with a thread, as well as a spherical support for the inner cone with a shaft and an eccentric of the inner cone mounted on it with a bearing, mating with a cylindrical bearing bush located in the housing aligned with it, and also with a transmission connected to an electric motor, characterized in that the eccentric is placed freely in the radial direction relative to the bearing sleeve, which is made in the form of an eccentric drive element ka. 2. Crusher according to claim 1, characterized in that the cylindrical bearing sleeve is made in the form of an intermediate support of the eccentric. 3. Crusher according to claim 1, characterized in that the cylindrical bearing sleeve is equipped with a device for adjusting the radial amplitude of the eccentric and the inner cone.