RU2802938C1 - Cone crusher with advanced hydraulic system - Google Patents

Abstract

FIELD: heavy engineering

SUBSTANCE: invention relates to crushing and grinding equipment, in particular to cone crushers, and can be used in technological processes in the construction and mining and processing industries. The cone crusher comprises a housing 2, an outer cone 5 and an inner cone 4 placed inside it, forming a crushing chamber between them. The vertical shaft 6 of the inner cone 4 is located in the eccentric assembly 7 connected to the electric drive 19. In this case, the vertical shaft 6, through the support bearing, rests on a damping hydraulic system, configured to adjust the position of the inner cone 4 and comprising a hydraulic cylinder body 14 with a main piston installed in it and with a chamber for hydraulic fluid, connected to a hydraulic accumulator and a hydraulic pump through pipelines. The improved hydraulic system comprises the main piston 13 installed inside the body 14 of the hydraulic cylinder, made in the form of an open glass, so that in its internal cavity there is additionally placed a locking block and a block of elastic elements 11, on which the movable piston, made in the form of a washer with a central hole, rests, configured to move inside the main piston, a thrust bearing is placed above the movable piston, on which the support bearing and the vertical shaft of the inner cone rest.

EFFECT: damping hydraulic circuit is compensated.

12 cl, 3 dwg

Description

The invention relates to the field of heavy engineering, to crushing equipment, in particular to cone crushers, and can be used in technological processes in the construction and mining industries.

The device of an eccentric cone crusher is known from the prior art. The crusher contains a body with an outer cone and an internal movable cone located inside it. The surfaces of the cones facing each other form a crushing chamber. The movable cone is rigidly fixed on the main vertical shaft of the crusher. In the upper part of the housing there is a suspension unit for the main vertical shaft. The lower part of the main vertical shaft is freely inserted into an inclined eccentric sleeve, which in turn is inserted into the eccentric sleeve, forming an eccentric assembly. The main shaft rests on a support bearing. The eccentric assembly is connected through a gear transmission to a horizontal drive shaft, which is connected to an electric motor.

The crusher drive motor rotates the eccentric assembly at a constant speed through a gear train. Rotation of the eccentric assembly causes the lower part of the main shaft to move in a circular motion. At the top of the main shaft is a crosshead bearing that serves as the center point for its circular motion. The geometric axis of the shaft describes a conical surface with its apex at the suspension point. In this case, the inner movable cone will roll along the inner surface of the stationary cone. The process of crushing the material occurs in a crushing chamber formed between the cones, into which the material is supplied from a feeder located on top of the crusher.

The circular motion of the main shaft causes a constant change in the distance between the surfaces of the movable and fixed cones. When this distance decreases, the crushed material is subjected to compressive stress and collapses. After the movable cone moves away from the stationary one, the distance increases and the crushed material passes down into the discharge chute under the influence of its own weight. The width of the crushing chamber is usually characterized by the minimum distance between the crushing cones, called the unloading gap. The size of the unloading gap primarily affects the size of the crushed material fractions.

The working surfaces of the crushing cones are lined with special armor, which wears out during operation and must be replaced. Wear of the armor leads to an increase in the size of the unloading gap, so it needs to be adjusted during operation. Adjusting the unloading gap allows you to compensate for the wear of the working surfaces of the cones and maintain the size of the gap at a given value, and also allows you to set different sizes of fractions of crushed material.

The eccentric crusher can be equipped with a damping hydraulic main shaft support system. The damping system supports the main shaft and regulates its height position due to dynamic changes in pressure in the working cavity of the hydraulic cylinder. By moving the main shaft up and down, and consequently moving the internal movable cone with it, the size of the unloading gap can be adjusted.

The damping system is also designed to provide protection against overloads caused by so-called “unbreakable bodies” - random metal inclusions and/or other fragments of material that cannot be crushed. The damping system allows you to increase the unloading gap, allow uncrushed bodies to pass through, and then return the main shaft and crushing cone to the preset operating position.

It is known from the prior art that ensuring the fulfillment of the intra-layer crushing condition is the most effective way to destroy the material in the crushing chamber. To ensure the condition of intra-layer crushing in a crusher, the crushing force acting on the material must always be within the specified design limits, determined based on the balance of forces and the physical characteristics of the resistance of the crushed material.

The difficulty in adjusting the parameters of a cone eccentric crusher lies in the fact that the crushing force changes continuously and at high speed. This leads to both the risk of creating increased loads and the risk of underloading. Increased loads can lead to peak values and the risk of emergency situations. Underloads can lead to failure to meet the conditions necessary for intra-layer crushing, thereby reducing technological indicators, primarily to reducing the degree of crushing.

Therefore, a special damping hydraulic system has been developed for eccentric crushers, the task of which is to quickly and in real time respond to changes in crushing force, absorb peak loads and compensate for low loads, returning parameters to preset values.

The invention known from the prior art is “Device for preventing overload in crushers”, patent GB1517963(A), priority 07/01/1975, which proposes the design of a damping hydraulic system.

Currently, crushers with hydraulic overload protection systems are widely used in the industry. Cone eccentric crushers having similar systems are described in detail in open sources, see for example,

https://www.rockprocessing.sandvik/en/products/stationary-crushers-and-screens/stationary-cone-crushers/

or https://www.911metallurgist.com/blog/tramp-steel-cone-crusher-hydroset

However, in practice it turns out that hydraulics do not work dynamically enough and have a number of other limitations, therefore various additional solutions are used in crusher designs aimed at improving the quality of operation of the damping system.

The invention “REDUCING PRESSURE FLUCTUATIONS IN CRUSHERS”, publication WO 2009/123531, dated 10/08/2009, patent RU2487761, taken as a prototype, is known from the prior art.

The purpose of the invention of the prototype was to create a crushing system with a built-in vibration damping system, in which the risks of structural fatigue failure would be reduced and the load could be increased without reducing the service life of the crusher.

The crushing unit proposed in the prototype contains a housing, a first crushing surface and a second crushing surface for crushing the material between them, as well as a damping hydraulic system for adjusting the discharge gap by adjusting the position of the first crushing surface through the hydraulic system. The hydraulic system contains a hydraulic cylinder filled with hydraulic fluid and a piston made in the form of a closed glass. The hydraulic system additionally contains a hydraulic accumulator 26 connected to the hydraulic cylinder through a pipe for working hydraulic fluid; the accumulator contains a separate chamber for working hydraulic fluid and a separate chamber for gas. The accumulator is preloaded to a preload pressure equal to the pressure in the gas chamber when the working hydraulic fluid chamber is empty, and which is at least 0.3 MPa lower than the average working pressure in the hydraulic cylinder, so that the accumulator operates, and the hydraulic pressure fluctuations generated in the hydraulic cylinder during operation of the crushing system are weakened.

The hydraulic system 16, according to Fig. 1, included in the prior art description of the invention, includes a pump 18 that forces hydraulic fluid into or out of hydraulic cylinder 10 via pipe 20. Pressure relief valve 22 is configured to quickly release hydraulic fluid from hydraulic cylinder 10, particularly in situations when cone crusher 2 becomes overloaded. The pressure relief valve 22 is configured to discharge the working hydraulic fluid into the reservoir 24, which also serves as a sump for the pump 18.

The control system 28 includes a control device 30 that receives various signals indicative of the operation of the cone crusher. The control device 30 receives a signal from the position sensor 32, which provides an indication of the current vertical position of the vertical shaft 8. The width of the unloading gap 12 can be calculated based on this signal. In addition, the control device 30 receives a signal from the pressure sensor 34 to provide an indication of the hydraulic pressure in the hydraulic cylinder 10. Based on the signal from the pressure sensor 34, the control device 30 can calculate the actual average operating pressure and the maximum pressure in the cone crusher. The control device 30 may also receive a signal from a power sensor 36 to measure the power supplied to the cone crusher from a motor 38 that rotates the vertical shaft 8. The rotational movement of the vertical shaft 8 is accomplished by a motor 38 that drives an eccentric 39 into which the vertical shaft is inserted. shaft 8. Power sensor 36 transmits a signal to control device 30 indicating the number of revolutions of the eccentric 39.

The control device 30 controls the operation of the pump 18, in an on/off mode or in a proportional control mode, so that the pump 18 supplies a certain amount of hydraulic fluid to the hydraulic cylinder 10, which provides a predetermined vertical position of the vertical shaft 8 and a predetermined gap width 12. The control device 30 also controls the opening of the pressure relief valve 22. High pressure peaks caused by a non-crushing body caught in the gap 12 are handled by the control device 30, which transmits a signal to the pressure relief valve 22 that immediate opening is required.

Thus, the problem associated with long fluctuations in hydraulic pressure of 1 second or more is eliminated by the control device 30 controlling the pump 18. The problem of large and unexpected pressure peaks caused by, for example, a solid body is eliminated by the control device 30 controlling the valve 22 pressure releases.

An advantage of the prototype crushing system is that fatigue stresses in the crushing system can be significantly reduced because the accumulator in communication with the hydraulic cylinder during normal operation of the crushing system is configured to attenuate almost all load changes so that the load on the crushing system and, in particular, the pressure in the hydraulic system will vary to a much lesser extent compared to known crushing systems.

The disadvantages of the system proposed in the prototype are as follows.

The crushing force in the crushing chamber changes continuously and at high speed, so the damping system must respond as quickly as possible, absorbing peak loads in real time. The use of a hydraulic accumulator, pumps and pipelines in the hydraulic circuit, the operation of which, due to the characteristics of their design, is characterized by a certain inertia of reaction, makes the entire damping system as a whole very inertial.

Inertia, in other words, a delay in the response of the damping system, leads to the inability to process critical values of load changes as quickly and sharply as required for trouble-free operation of the crusher. Correcting load changes late, in turn, leads to insufficient attenuation of peak values, which manage to have a negative impact on the crushing unit before the system has time to correct them.

From the analysis of the prototype, we can conclude that for the assigned tasks it is advisable to use devices with low, or better yet, no response inertia.

The system described in the prototype, including pipelines and reservoirs for hydraulic fluid, is unnecessarily complex, and is also physically located at a significant safe distance from the crusher. Therefore, to reduce response time, the damping system should be located close to, or directly in, the crusher, but in such a way that the reliability and durability of its operation is not significantly compromised.

In connection with the above, the purpose of the present invention is to improve the technological parameters of a cone crusher, in particular, the degree of crushing. A significant increase in the degree of crushing can be achieved by creating conditions for constant intra-layer crushing of the material in the crushing chamber. Conditions for intra-layer crushing are achieved when the flow of crushed material is in constant close contact with the crushing surfaces of the cones.

To do this, it is necessary to create a crushing unit with an effective support system for the main shaft and internal crushing cone, designed to reduce the negative effects of sudden, sudden and/or significant changes in dynamic load.

Such a support system must have the fastest possible response speed to work in real time with minimal delays.

It is advisable to use mechanical elastic elements to create such a system, since, as is known from the prior art, they have the lowest response inertia.

It is advisable to integrate such a support system into the cone crusher design along with the existing damping hydraulic system known in the art, which is widely used in the industry and solves similar problems.

To solve the assigned problems, it does not seem appropriate to significantly change and/or increase the size of the crushing unit; or accompany the unit with additional external devices.

This goal can be achieved by improving the known design of a cone crusher with a damping hydraulic system by introducing elastic mechanical elements, such as springs or spring blocks, into an existing block design.

This goal is achieved by a cone crusher with an improved hydraulic system; it contains a housing, an outer cone and an inner cone placed inside it, forming a crushing chamber between them,

the vertical shaft of the inner cone is located in the eccentric unit connected to the electric drive,

wherein the vertical shaft, through a support bearing, rests on a damping hydraulic system, configured to adjust the position of the internal cone and containing a hydraulic cylinder body with a main piston installed in it and a chamber for hydraulic fluid,

connected to the hydraulic accumulator and to the hydraulic pump through pipelines,

characterized in that

the improved hydraulic system contains a main piston installed inside the hydraulic cylinder body, made in the form of an open cup,

so that in its internal cavity there are additionally placed

a locking block and a block of elastic elements on which a movable piston rests, made in the form of a washer with a central hole, configured to move inside the main piston,

a thrust bearing is placed above the movable piston,

on which the support bearing and the vertical shaft of the inner cone rest.

A cone crusher with an advanced hydraulic system may have the following additional differences.

The block of elastic elements consists of at least one twisted metal spring.

The block of elastic elements consists of two or more twisted metal springs placed around the central axis of symmetry of the main piston.

The block of elastic elements consists of at least one block of disc springs arranged so that the axis of symmetry of the spring block coincides with the axis of symmetry of the main piston.

The locking block consists of at least one metal cylinder having a flat base and a threaded pin on the upper surface, and the lower surface of the movable piston washer has at least one corresponding threaded hole for fixing said threaded pin of the cylinder therein.

The movable piston is made in the form of a washer of such a size that the outer diameter of the washer corresponds to the inner diameter of the main piston, taking into account technological clearances.

At least one horizontal oil-conducting channel is made in the thickness of the movable piston washer.

Outside, along the entire circumference of the rim of the movable piston washer, there is at least one groove for a plastic ring.

Under each twisted metal spring, a receiving recess is made in the bottom part of the main piston cup so that the spring fits into the corresponding recess and is fixed in it.

Under each twisted metal spring, a receiving recess is made on the lower surface of the movable piston washer so that the spring fits into the corresponding recess and is fixed in it.

The thrust bearing is made in the form of a thin washer with a central hole, on the upper surface of which there are oil-conducting grooves.

Between the movable piston and the thrust bearing there is a fixing pin to prevent axial rotation of the mentioned parts relative to each other, for which a recess of the appropriate size is made on the lower surface of the thrust washer, and a recess of the appropriate size is made on the upper surface of the movable piston washer so that the fixing pin fits completely into them.

The invention is illustrated by three figures.

Fig. Figure 1 is a cutaway view of a cone crusher with an advanced hydraulic system.

Fig. 2 shows an improved hydraulic cylinder assembly.

Fig. 3 shows the elements included in the improved hydraulic cylinder.

The invention is implemented as follows.

In the body 2 of the cone crusher there is a fixed cone 5, inside of which there is a movable crushing cone 4, as shown in Fig. 1. The surfaces of cones 4 and 5 facing each other form a crushing chamber, which is characterized by the presence of a discharge gap 3. The movable cone 3 is fixed on a vertical shaft 6. In the upper part of the housing 2 there is a traverse bearing 1 of the vertical shaft 6. The lower part of the vertical shaft 6 is inserted into an eccentric sleeve, which, in turn, is inserted into the eccentric cup, thus forming an eccentric unit 7. The eccentric unit 7 is connected to the a horizontal drive shaft, which is connected to an electric motor 19. The crusher drive motor 19 rotates the eccentric assembly 7 at a constant speed through a gear 8. The rotation of the eccentric assembly 7 causes the lower part of the vertical shaft 6 to move in a circular motion. The traverse bearing 1, located in the upper part of the vertical shaft 6, serves as the center for its circular motion.

Thus, the geometric axis of the shaft 6 describes a conical surface with its apex at the traverse point 1. The circular motion of the vertical shaft 6 causes a constant change in the distance between the surfaces of the movable 4 and fixed 5 cones. The process of crushing the material occurs in the crushing chamber formed by cones 5 and 4, where the crushed material is supplied from a feeder, always located on top of the crushing unit, not shown in the figure.

The crusher of the known design is equipped with an improved hydraulic main shaft support system.

The advanced hydraulic system includes the following elements. The hydraulic cylinder body 14 is made in the form of an open glass, the bottom 19 of which has a central through hole designed to accommodate a sensor 17 indicating the position of the main shaft 6.

The main piston 13 is inserted into the glass of the hydraulic cylinder housing 14, which, unlike the known design, is made in the form of an open glass of such a size that the outer diameter of the piston glass 13 corresponds to the internal diameter of the glass of the hydraulic cylinder housing 14, taking into account technological gaps.

In the center of the piston cup 13 there is a hollow vertical pin 34, open at the bottom and closed at the top, to accommodate the vertical shaft position sensor 17 inside. In the outer wall of the piston cup 13 there are oil-conducting windows 37. Along the outer wall of the piston cup 13 there are grooves for plastic rings.

The cavity 15 between the bottom 19 of the hydraulic cylinder housing and the main piston 13 is filled with hydraulic fluid and is equipped with a hydraulic fluid pressure sensor 16.

The vertical shaft position sensor 17 is made in the form of a vertically oriented spoke and is fixed in the bottom 19 of the hydraulic cylinder body so that its upper part can be placed in the internal cavity of the pin 34 of the main piston 13.

A movable piston 10 is placed inside the cup of the main piston 13, made in the form of a washer of such a size that the outer diameter of the washer corresponds to the inner diameter of the main piston 13, taking into account technological clearances. The piston washer 10 has a central hole at least of such a size that a pin 34 with a vertical shaft position sensor 17 can fit into it. In the thickness of the piston washer 10 there are horizontal oil-conducting channels 26, the number of which corresponds to the number of oil-conducting windows 37 of the main piston 13. On the outside, along the entire circumference of the rim of the piston washer 10, there are grooves 31 for plastic rings. On the upper surface of the piston washer 10 there is a recess 35 for the fixing pin. 25.

On top of the piston 10 there is a thrust bearing 9, made in the form of a thin washer with a central hole 28. On the upper surface of the thrust washer 9 there are oil-conducting grooves 23. On the lower surface of the thrust washer there is a recess 24 for the fixing pin 25.

The fixing pin 25 is located between the movable piston 10 and the thrust bearing 9, in recesses 35 and 24 corresponding to its size, and is designed to prevent axial rotation of the thrust bearing 9 relative to the piston 10.

In the internal cavity of the main piston 13, between the bottom of the piston cup and the movable piston 10, there is a block of elastic elements 11, which can be made using various devices, for example, mechanical springs that have the necessary elastic properties.

The block of elastic elements 11 can be made, for example, in the form of twisted metal springs, as shown in Fig. 2 and fig. 3. The number of springs can vary depending on the required load, from one single spring to the maximum number of springs that can be placed in the internal cavity of the main piston 13 cup.

It is advisable to make a circular receiving recess 27 for each coiled spring in the bottom part of the main piston 13 cup, and make it of such a size that the coiled spring fits into the corresponding recess and is fixed in it.

Similarly, for each coil spring on the lower surface of the piston 10, it is advisable to make a circular receiving recess 36 of such a size that the coil spring fits into the corresponding recess and is fixed in it.

Recesses 27 and 36 hold the coil springs in place, preventing any movement during operation of the unit.

In the internal cavity of the main piston 13, between the bottom of the piston cup and the movable piston 10, there is a locking block, which must contain at least one thrust stopper. The thrust stops are designed to prevent compression of the spring block 11 beyond the established permissible limit.

The locking block can be made in the form of one single stopper, but it is advisable to implement it from three thrust stoppers, made in the form of vertically oriented metal cylinders 33, and mounted on the lower surface of the movable piston 10. For this purpose, each cylinder of the stopper 33 has a flat base and a threaded pin 32 on the top surface.

Under each stopper 33, on the lower surface of the washer of the movable piston 10, there are receiving threaded holes 30 so that the threaded pin 32 of the stopper is screwed into the corresponding hole 30 and is fixed in it. It is advisable to determine the number of thrust stops for the stop block based on the required strength for each specific crusher, however, for most standard sizes, installing three stops will be sufficient.

Above the thrust bearing 9 there is a support bearing 12, assembled from a curved and concave disk. The vertical shaft 6 directly rests on the thrust bearing 12.

Thus, in the proposed design, the vertical shaft 6, assembled with a movable cone 4, through a support bearing 12 and a thrust bearing 9, rests on a movable piston 10, which in turn rests on a spring block 11.

It is advisable to determine the elastic properties of block 11, as well as the type and number of springs used, individually for each crushing system, based on the size of the machine, the maximum pressure under the main piston and the maximum permissible load during crushing.

The block of elastic elements 11 can be made, for example, from disc springs. In this case, it is advisable to place the disc springs in the cavity of the main piston 13 in such a way that the axis of symmetry of the springs coincides with the axis of symmetry of the cup of the main piston 13. The disc springs can be arranged in any way in which they can perform their function, and the number of springs in addition to the required load will be determined by the distance between the bottom of the main piston 13 cup and the movable piston 10.

The spring block 11 is always in a spring-loaded state, including when the crusher is not working or is idling, since the block 11 bears the full weight of the crushing structure assembly, resting on the movable piston 10. At the same time, the spring block 11 must have a certain margin of compression free play until the moment when the thrust stops 33 rest against the bottom of the main piston 13.

The size of the unloading gap 3 is set taking into account the spring-loaded state of the cone 4.

The crusher has a control system. The control system contains a control device, which is configured to receive and process various signals characterizing the operation of the cone crusher.

The hydraulic system contains two circuits: a hydraulic fluid supply circuit and a damping circuit.

Hydraulic fluid is pumped into the hydraulic system in a known manner, not shown in the figures. For this, a reversible pump is used that supplies fluid into or out of cavity 15, a hydraulic pipeline with a locking valve, and a hydraulic fluid pressure sensor 16 in cavity 9. Before starting work, the control device opens the lock valve and commands the pump to supply a certain amount of hydraulic fluid through pipeline into the cavity 15.

The hydraulic fluid pumped up in this way creates pressure in the cavity 15, under the influence of which the main piston 13 rises up, together with the movable piston 10, vertical shaft 6 and movable cone 4. The vertical position of the shaft 6 is controlled by sensor 17. At the same time, sensor 16 monitors the fluid pressure in the cavity 15. As soon as the position of the vertical shaft 6 reaches the specified values, the control device closes the shut-off valve, the pump operation and the supply of hydraulic fluid are stopped. In this way, the required value of the unloading gap 3 is established. Based on the signal from the sensor 16, the control device can calculate the actual average operating pressure and the maximum pressure in the cavity 15 of the hydraulic system.

The damping circuit of the hydraulic system is known from the prior art; it contains a hydraulic accumulator 21 connected by a pipeline 22 to the limit pressure valve 18 and to the cavity 15. The hydraulic accumulator 21 is designed to quickly discharge hydraulic fluid from the cavity 15, and quickly return the fluid to the cavity 15.

The flow of crushed material, which is supplied to the crusher feeder, always has a heterogeneous structure, in which all elements differ in size, material hardness and feed flow density. As already mentioned, one of the conditions for increasing the efficiency of the crushing process is to ensure conditions for intralayer crushing of the material in the crushing chamber. To comply with this condition, the crushed material must at any time be in the most intimate contact with the crushing surfaces of the cones.

The heterogeneity of the incoming flow of crushed material leads to the fact that the situation in the crushing chamber is constantly changing: the flow of large and/or strong elements provides greater resistance to the crushing force, and therefore puts a greater load on the movable cone 4; and the flow of small and/or soft elements obviously provides less resistance to the crushing force, therefore giving less load on cone 4. In this regard, the crushing force in the chamber is constantly changing.

Since the movable cone 4 is always in a spring-loaded state, the variable load on the cone 4 described above is compensated by the operation of the block of elastic elements 11 at each moment of time. Due to this constant compensation of the variable load, cone 4 tends to return to the most intimate contact with the flow of crushed material in the chamber at each moment of time. Thus, the crushed material with any characteristics of the incoming flow is always in the closest possible contact with the crushing surfaces of cones 4 and 5.

That is, the operation of the block of elastic elements 11 compensates for the inhomogeneity of the flow, which provides the condition for intra-layer crushing. Compensation occurs without delay, in real time, thanks to the physical properties of the spring block 11, which acts as a “spring” for assembling the cone 4, vertical shaft 6 and movable piston 10. This “spring” has a preset free play reserve, determined by the height of the limiting stops 33. Stoppers 33 rest against the main piston 13 when the set value of the free play of the movable piston 10 is exceeded.

When, during the operation of the crusher, an unusual situation occurs in which the crushing resistance and the load on the cone 4 exceed the maximum set value, for example, when an uncrushed body enters the unloading gap 3, then the main piston 13 comes into operation. Under the influence of the above-mentioned increased load, the cone 4 assembly , the vertical shaft 6 and the movable piston 10 go down, the spring block 11 compresses and selects the entire preset free play reserve. After which the stoppers 33 rest against the main piston 13. As a result, the pressure on the main piston 13 increases, the pressure of the hydraulic fluid in the cavity 15 increases, the pressure sensor 16 sends a corresponding signal to the control device.

The pressure limit valve 18 reacts to exceeding the preset pressure value and opens. Hydraulic fluid from cavity 15 through valve 18 through pipeline 22 is discharged into hydraulic accumulator 21.

As a result of the release of hydraulic fluid, the pressure in the cavity 15 drops, so the main piston 13 is lowered. Together with the piston 13, the vertical shaft 6 and cone 4 are lowered, as a result of which the unloading gap 3 increases, the uncrushed body is released from the gap and passes from the crushing chamber down into the unloading chute.

After which the load on the assembly cone 4, vertical shaft 6, movable piston 10 and main piston 13 weakens, therefore the pressure in the cavity 15 weakens, the limit pressure valve 18 reacts to a decrease in pressure, the hydraulic accumulator 21 returns the hydraulic fluid through the pipeline 22 to the cavity 15, the valve 18 closes, the hydraulic pressure in cavity 15 returns to preset values. The main piston 13 returns to its preset position.

The weakening of the load on the piston 10 also leads to the fact that the spring block 11 is released from the excess pressure of the movable piston 10, regains the ability to move freely within specified limits, as a result of which the assembly of the piston 10, vertical shaft 6 and cone 4 returns to the sprung state.

Such a dynamic regulation of the alternating and/or joint operation of elastic elements and the hydraulic damping system is implemented as necessary, quickly responding to changes in the situation in the crushing chamber, throughout the entire process of operation of the crushing unit and in relation to any crushed material.

As a result of the use of such a complex design in the crushing unit, problems associated with significant changes and emergency situations in the crushing chamber are resolved using a damping circuit with a hydraulic accumulator, and problems caused by the variable nature of the flow of crushed material and changes in the crushing force are solved using the operation of a block of elastic elements.

At the same time, the presence of a block of elastic elements makes it possible to partially compensate for the insufficient performance of the damping hydraulic circuit.

Consequently, the improved hydraulic system is able to effectively cope with various problems that arise during the operation of the crusher without stopping work, which makes it possible to improve its technological performance, in particular, the degree of crushing.

Claims (12)

1. A cone crusher with an improved hydraulic system, containing a housing, an outer cone and an inner cone placed inside it, forming a crushing chamber between them; the vertical shaft of the inner cone is placed in an eccentric unit connected to an electric drive, while the vertical shaft rests on a damping element through a support bearing a hydraulic system configured to adjust the position of the inner cone and containing a hydraulic cylinder housing with a main piston installed in it and a chamber for hydraulic fluid, connected to a hydraulic accumulator and a hydraulic pump through pipelines, characterized in that the improved hydraulic system contains a main piston installed inside the housing hydraulic cylinder, made in the form of an open glass, so that in its internal cavity there is additionally placed a locking block and a block of elastic elements, on which a movable piston rests, made in the form of a washer with a central hole, made with the ability to move inside the main piston; a thrust bearing is placed above the movable piston , on which the support bearing and the vertical shaft of the inner cone rest. 2. Cone crusher according to claim 1, characterized in that the block of elastic elements consists of at least one twisted metal spring. 3. Cone crusher according to claim 1, characterized in that the block of elastic elements consists of two or more twisted metal springs placed around the central axis of symmetry of the main piston. 4. Cone crusher according to claim 1, characterized in that the block of elastic elements consists of at least one block of disc springs arranged so that the axis of symmetry of the spring block coincides with the axis of symmetry of the main piston. 5. The cone crusher according to claim 1, characterized in that the locking block consists of at least one metal cylinder having a flat base and a threaded pin on the upper surface, and the lower surface of the movable piston washer has at least one corresponding threaded hole for fixation in it the mentioned threaded pin of the cylinder. 6. Cone crusher according to claim 1, characterized in that the movable piston is made in the form of a washer of such a size that the outer diameter of the washer corresponds to the inner diameter of the main piston, taking into account technological clearances. 7. Cone crusher according to claim 1, characterized in that at least one horizontal oil-conducting channel is made in the thickness of the movable piston washer. 8. Cone crusher according to claim 1, characterized in that at least one groove for a plastic ring is made on the outside along the entire circumference of the rim of the movable piston washer. 9. The cone crusher according to claim 1, characterized in that a receiving recess is made under each twisted metal spring in the bottom part of the main piston cup so that the spring fits into the corresponding recess and is fixed in it. 10. The cone crusher according to claim 1, characterized in that a receiving recess is made under each twisted metal spring on the lower surface of the movable piston washer so that the spring fits into the corresponding recess and is fixed in it. 11. Cone crusher according to claim 1, characterized in that the thrust bearing is made in the form of a thin washer with a central hole, on the upper surface of which there are oil-conducting grooves. 12. The cone crusher according to claim 1, characterized in that between the movable piston and the thrust bearing there is a locking pin to prevent axial rotation of the mentioned parts relative to each other, for which a recess of the appropriate size is made on the lower surface of the thrust washer, and on the upper surface of the movable piston washer a recess of the appropriate size so that the locking pin fits completely into them.