KR101391864B1 - Conecrusher having count hausing with oil injection hole formed in the center - Google Patents

Abstract

The present invention relates to a cone crusher having an oil injection hole at the central part of a count housing, and more desirably, to a cone crusher having a thin oil flow between the count housing and an oil flinger, which forms a vacuum membrane while rotating the oil flinger by a packing ring attached to the count housing, thereby preventing leakage of oil and discharging air to an air discharge unit connected to the count housing to block fixation by heat during rotation, adjusting pressure in the count housing to prevent heat generation caused by the rotation of a count shaft and maintaining a temperature which is appropriate for machine operation. A configuration of the present invention is comprised of a mantle (110), a concave (120), and a crusher.

Description

Corncrusher having count hausing with oil injection hole formed in the center}

The present invention relates to a cone crusher in which an oil inlet is formed in the center of the count housing, more preferably, the thin oil flow between the count housing and the oil flinger is oil-throwed by packing attached to the count housing. When the oil flinger rotates, a vacuum film is formed to prevent oil leakage, and at the same time, air is discharged to the air outlet connected to the count housing to prevent fixation caused by heat when rotating, and the pressure in the count housing is controlled to count. It is to prevent heat generation due to the rotation of the shaft and to maintain a temperature suitable for driving the machine.

In general, the collecting process of an aggregate has a crushing process in which a rock is exploded using an explosive material such as dynamite in a place such as a quarry or a mine, and then crushed to an appropriate size required by a user using a grinder.

Examples of the crusher include a jaw crusher for crushing a relatively large lump of aggregate, and a cone crusher for crushing aggregates crushed from the jaw crusher to a smaller size.

Here, the cone crusher will be dealt with, and its general structure is a structure in which aggregate is crushed by inserting aggregate between an eccentrically rotating cone-shaped mantle and a fixedly installed cone cave.

Typically, the cone crusher is classified into C.C (Crusher Coarse) type and C.S.H (Crusher Short Head) type according to the structure and shape of the crushing chamber.

As shown in FIG. 1, the conventional CC type cone crusher is a main frame 10 of a substantially cylindrical shape, and a rotating shaft 20 accommodated inside the main frame 10 and installed to be rotatable in an eccentric state And, the cone-shaped mantle core 35 and the mantle 30 coupled to the outer circumferential surface of the rotating shaft 20, the top frame 40 and the top frame 40, which is mounted on the top of the main frame 10, and the top frame 40 It is screwed to) and is divided into a top cell (60) with a mantle (30) and a concave (50) spaced a suitable distance apart.

In addition, a release spring 70 is installed between the top frame 40 and the main frame 10 to handle the vertical load generated during the grinding process of aggregate.

In addition, the top cell 60 is configured such that the vertical cross section has a trapezoidal shape, and a distributor 80 for dispersing aggregate is installed at the top of the rotating shaft 20.

In addition, one side of the main frame 10 has a shape in which a drive shaft housing 97 for providing a driving force to the rotating shaft 20 can be coupled, and a pulley 92 that receives driving force from a separate power source in the portion And, a drive shaft 95 horizontally installed to interlock with the pulley 92, and a drive shaft housing 97 surrounding the outside of the drive shaft 95 and coupled to the main frame 10.

2 shows a CSH type cone crusher, the CSH type cone crusher is used to crush aggregates of a smaller size than the CC type cone crusher, and accordingly, the length of the mantle 30 is short as well as the slope The angle is also formed high.

This, CSH-type crushing chamber when crushing a relatively small size aggregate than the CC-type crushing chamber, the space between the aggregate and the aggregate is dense, so the repulsive load on the crushing force acts a lot, so the above structure Because there is no choice but to adopt.

In the conventional cone crusher having such a structure, since the aggregate is usually introduced into the crushing chamber through the hopper, the gap between the mantle 30 and the cone cave 50 varies depending on the eccentric rotation of the rotating shaft 20, so that the aggregate has its gap After being crushed by the change and dropped to the lower side of the crushing chamber, it is sorted by size through a sorting network and then transferred to the next process through each conveyor belt (not shown).

In general, the cone crusher has a characteristic in which its crushing performance varies depending on the length, angle, and spacing of the concave 50 and the mantle 30 forming the crushing chamber.

In addition, these two types of cone crusher are C.C type cone crusher installed in the crushing process facility of aggregate, and then C.S.H type cone crusher is disposed in the process, so that the aggregate is crushed sequentially.

In addition, in the Korean Patent Registration No. 10-1245249, "Consher Crusher capable of producing excellent granular aggregate," it was disclosed that the technical configuration to smoothly drive the main shaft by supplying oil to the center of the main shaft, but smoothly driving the count shaft. At the same time, research on technology for preventing oil leakage has not been conducted.

1. Domestic patent registration: No. 10-1245249

2. Domestic patent registration: No. 20-0292658

3. Domestic patent registration: No. 10-0999193

4. Domestic patent registration: No. 20-0292658

In the prior art as described above, the oil inlet is formed at the center of the main shaft and discharges the injected oil to the outer circumferential surface of the main shaft to smoothly induce driving of the main shaft, but on the other hand, to drive the count shaft driving the main shaft. In order to solve the problem of not being able to induce smoothly, the present invention eliminates the fixation phenomenon of the count shaft according to a method in which oil is introduced into the oil injection port formed in the center of the count housing to diffuse the oil into the bushings in both left and right directions. It aims to make it.

In addition, by configuring the air outlet on one side of the count shaft, it is intended to discharge air generated in the count housing to prevent the sticking phenomenon due to heat during rotation, and to control the pressure in the count housing.

That is, the purpose is to maintain the proper temperature for the role of preventing heat generation due to rotation and machine driving.

In addition, an oil flinger is formed on the count shaft between the count housing and the pulley, and a count housing is formed on the outer surface of the count shaft, so that the thin oil flow formed between the count housing and the oil thrower is count housing. The purpose of the present invention is to prevent leakage of oil by forming a vacuum film when rotating the oil flinger by a packing ring mounted on one side of the end and closely contacting the outer circumferential surface of the oil washer.

Besides. Since the existing cone crusher uses an oil seal made of rubber, it wears out after a certain period of use and generates a leak, but in the present invention, the purpose is also to prevent wear and leak by forming a packing ring in a casting type. have.

In addition, the conventional cone crusher performs a key operation on the outer circumferential surface of the count shaft after shrink fit to fix the pulley and the count shaft, but this causes deformation due to the forced heat treatment on the bushing side. In order to fix the pulley, by inserting the outer slope of the power lock into the space formed on the inner slope of the pulley without heat treatment, the inclined faces are in close contact with each other so that pressure can be applied in a wedge-like manner, bushing, etc. The purpose is also to prevent deformation of the internal parts.

The configuration of the present invention for achieving the above object will be described in detail with reference to the accompanying drawings as follows.

3A, 3B, and 4, the mantle 110 rotates eccentrically by rotation of the main shaft 100 that rotates by receiving power from a motor inside the frame (not shown), as shown in FIGS. 3A, 3B, and 4. , In order to facilitate the crushing of the stone introduced into the variable space between the mantle 110 and the concave 120 formed to maintain a variable space, and the mantle 110 and the concave 120,

The count shaft 130 is formed on the outer circumferential surface of the count shaft 130 so as to protect the count shaft 130 that drives the main shaft 100 eccentrically, and the oil injection port 150 is provided on the outer circumferential surface of the center of the count housing 140. ) Is formed to diffuse the injected oil in both left and right directions, and an air discharge unit 160 is provided on one side of the count housing 140 to discharge air generated in the count housing 140. Forming, forming an oil flinger 170 on the outer circumferential surface of the count shaft 130 between the count housing 140 and the pulley 200, and the count housing 140 and the oil thrower 170 The thin oil flow between is attached to the count housing 140 to form a vacuum film when the oil flinger 170 is rotated by the packing ring 180, which is in close contact with the outer circumferential surface of the oil washer 17, thereby forming a vacuum film. In order to prevent leakage, and to fix the count shaft 130 and the pulley 200, the wedge-shaped power lock 190 is formed between the count shaft 130 and the pulley 200 without heat treatment. When the inclined surface 191 of the power lock 190 is tightly inserted into each other, it is characterized in that it is configured to be coupled while pressure is applied in a wedge manner.

In addition, the present invention is characterized in that the packing ring 180 is formed by casting so that wear and leakage do not occur.

In addition, the present invention is an outer surface of the power lock 190 for fixing the count shaft 130, one end of which is formed with a narrow width, and the other end is formed with a wedge of an inclined surface 191 formed by forming a wide width. In addition, to enable the power lock 190 to be inserted into the space between the count shaft 130 and the pulley 200, one end of the pulley 200 is formed with a wide width, and the other end has a width. It characterized in that the inclined surface 201 formed by forming a narrow wedge-shaped.

The present invention made of the above-described configuration combines an air discharge unit, which is a regulating device for controlling air discharge, on one side of the count housing to discharge air generated from the count housing to the outside, thereby controlling the flow of oil inside the cone crusher or It acts as an air intake and serves as a cooling device that controls when the oil temperature rises, thereby improving durability.

Further, in the past, the count shaft is fixed by using the count housing as a bearing type. However, since the present invention has a structure in which an oil film is formed and rotated in a bushing type, there is an effect of improving the durability of the count shaft.

In addition, the thin oil flow between the count housing and the oil flinger forms an vacuum film when the oil flinger rotates by the packing ring attached to the count housing, thereby preventing oil leakage. have.

1 is a cross-sectional view of a conventional CC (Crusher Coarse) type crusher,
Figure 2 is a cross-sectional view of a conventional CSH (Crusher Short Head) type crusher,
Figure 3a is a cross-sectional view showing the interior of the cone crusher according to the present invention,
Figure 3b is a cross-sectional view showing an enlarged state coupled to the oil thrower and pulley to the count shaft according to the present invention,
4 is a plan view schematically showing a state in which the oil outlet is connected to the count housing of the cone crusher according to the present invention.

Hereinafter, a preferred embodiment of a cone crusher in which an air outlet is formed in a count housing according to the present invention will be described in detail with reference to the accompanying drawings.

The cone crusher of the present invention is a configuration for compressing and crushing aggregate while rotating eccentrically to produce a small aggregate, omitting a general known configuration, and eccentrically mounted on the top of the main shaft 100 pursuing in the present invention In order to smoothly crush the aggregate by variably forming a space between the mantle 110 and the concave 120 that rotates, the configuration of the count shaft 130 that rotates the main shaft 100 eccentrically will be described. do.

That is, in order to smoothly rotate the count shaft 130, the air generated in the count housing 140 is discharged to the outside through the air discharge unit 160 coupled with one side of the count shaft 130, and the count housing By installing the packing ring (180) in (140), it controls the oil flow inside the cone crusher or acts as an air intake to act as a cooling device that controls when the oil temperature rises and prevents oil leakage. to be. The configuration for this will be described in more detail below.

As shown in Figure 3a and 3b, the configuration of the present invention is a count shaft 130 to drive the main shaft 100 eccentrically by receiving the power of a motor (not shown) to crush the aggregate pulley 200 It is composed by connecting with the motor.

In addition, in order to fix the integrally by combining the count shaft 130 and the pulley 200, the conventional cone crusher performs a key operation on the shaft side after shrink fit, but this causes deformation due to forced heat treatment on the bushing side. Occurs. Therefore, the present invention is configured to prevent deformation of internal parts such as a bushing by treating the wedge-type power lock 190 without heat treatment.

That is, the power lock 190 that is inserted into the space between the count shaft 130 and the pulley 200 to fix the count shaft 130 is formed on the outer surface with a narrow width at one end and a wide width at the other end. The inclined surface 191 formed is formed in a wedge shape.
And in correspondence with the power lock 190, the pulley 200 is also formed to have an inner surface with a wide width and a wide end with a narrow width so that the pulley 200 can be in close contact with the inclined surface 191. Make up with older brother. Accordingly, when the inclined surface 191 of the power lock 190 is inserted into the inclined surface 201 of the pulley 200 formed in the space between the count shafts 130, the power lock along the inclined surface 201 of the pulley 200 As the inclined surfaces 191 of 190 are inserted in close contact with each other, the pulley 200 is configured to be fixed without being flowed to the count shaft 130 by applying a wedge pressure to the pulley 200 outward.

And as shown in Figure 3a, to smoothly drive the count shaft 130, and at the same time to control the oil flow inside the cone crusher or to act as an air intake to act as a cooling device that controls when the oil temperature rises. The oil shaft 150 is formed at the central portion of the count housing 140 that protects the count shaft 130 so that the injected oil is spread through the bushings on both the left and right sides of the count shaft 130, so that the count shaft is configured. It is configured so that there is no sticking phenomenon of the count shaft 130 according to the rotation of the 130.

In addition, as shown in FIG. 3B, an oil flinger 170 is configured on the outer peripheral surface of the count shaft 130 between the counting housing 140 and the pulley 200 formed on the outer peripheral surface of the count shaft 130. do. Therefore, the thin oil flow between the counting housing 140 and the oil washer 170 is attached to the inner surface of the counting housing 140 and is oiled by the packing ring 180 that is in close contact with the outer peripheral surface of the oil washer 170. When the oil flinger 170 rotates, a vacuum film is formed to prevent leakage of oil and wear of the count shaft 130.

That is, the packing ring 180 is a casting type to prevent wear and leakage.

In addition, as shown in FIG. 4, it is configured to discharge the air generated in the count housing 140 to the outside by combining with the air discharge unit 160 on one side of the count housing 140. That is, the air discharge unit 160 prevents the sticking phenomenon due to heat when the count shaft 130 rotates, controls the pressure in the count housing 140, prevents heat generation due to rotation, and the temperature suitable for driving the machine. It is a configuration to keep.

In the present invention having the above-described configuration, as shown in FIG. 3B, the pulley 200 receiving the power of the motor rotates. At this time, the count shaft 130 coupled with the pulley 200 is also rotated. Since the pulley 200 coupled with the count shaft 130 is coupled and rotated by a wedge-shaped power lock 190, it is unlikely to cause deformation of internal parts such as the bushing 210.

In addition, since oil is supplied to the left and right while oil is injected through the oil inlet 150 formed in the central portion of the count housing 140 that protects the count shaft 130, the count shaft 130 rotates when rotating. Accordingly, the fixation phenomenon of the count shaft 130 is eliminated.

In addition, as shown in FIG. 3A, since the packing ring 180 is mounted on the pulley 200 side of the count housing 140 and rotates simultaneously with the oil thrower 170, the count housing 140 and the oil thrower ( The thin oil flow between the oil flingers 170 forms a vacuum film when the oil flinger 170 is rotated by the packing ring 180 attached to the count housing 140 to prevent oil leakage. will be.

In addition, as shown in FIG. 4, when the count shaft 130 rotates, the air generated within the count housing 140 is discharged to the air discharge unit 160 coupled to one side of the count housing 140 to count the housing. Since cooling occurs in the interior of the 140, it prevents fixation due to heat when rotating, and controls the pressure within the count housing 140, and also prevents heat generation due to the rotation of the count shaft 130 and drives the machine. To maintain the proper temperature.

Although the present invention having the configuration as described above has been described by a limited embodiment, the present invention is not limited by this, and the technical idea of the present invention and the following by a person skilled in the art to which the present invention pertains Various modifications and variations will be possible within the scope of the claims to be described in.

100. Main shaft 110. Mantle
120. Concave 130. Count shaft
140. Count housing 150. Oil inlet
160. Air outlet 170. Oil thrower
180. Packing Ring 190. Power Rock
191.Slope 200. Pulley
201. Slope 210. Bushing

Claims (3)

Formed to maintain a variable space between the mantle 110 and the mantle 110 that rotates eccentrically by rotation of the main shaft 100 that rotates by receiving the power of the motor from the inside of the frame (not shown) In order to facilitate the crushing of the stone introduced into the variable space between the concave 120 and the mantle 110 and the concave 120,
The count shaft 130 is formed on the outer circumferential surface of the count shaft 130 so as to protect the count shaft 130 that drives the main shaft 100 eccentrically, and the oil injection port 150 is provided on the outer circumferential surface of the center of the count housing 140. ) Is formed to diffuse the injected oil in both left and right directions, and an air discharge unit 160 is provided on one side of the count housing 140 to discharge air generated in the count housing 140. Forming, forming an oil flinger 170 on the outer circumferential surface of the count shaft 130 between the count housing 140 and the pulley 200, and the count housing 140 and the oil thrower 170 The thin oil flow between is attached to the count housing 140 to form a vacuum film when the oil flinger 170 is rotated by the packing ring 180 that is in close contact with the outer circumferential surface of the oil washer 17 to form an oil film. In order to prevent leakage, and to fix the count shaft 130 and the pulley 200, the wedge-shaped power lock 190 is formed between the count shaft 130 and the pulley 200 without heat treatment. When the inclined surface 191 of the power lock 190 is closely inserted to each other, a cone crusher having an oil injection port in the center of the count housing, characterized in that it is configured to be coupled while being pressed in a wedge manner. According to claim 1,
The packing ring 180 is formed by casting, and a cone crusher having an oil injection port in the center of the count housing, characterized in that it is configured to prevent wear and leakage. According to claim 1,
The outer side of the power lock 190 for fixing the count shaft 130 is formed with a narrow width at one end and a wide at the other end to form a wedge-shaped inclined surface 191 made of a wide width. To allow 190 to be inserted into the space between the count shaft 130 and the pulley 200, one end of the pulley 200 is formed with a wide width, and the other end is formed with a narrow width. A cone crusher having an oil inlet in the center of the count housing, wherein the inclined surface 201 is formed in a wedge shape.

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