KR100865868B1 - Lock post clamp of cone crusher - Google Patents

Abstract

A lock post clamp is provided to prevent a projection guide pin from being separated from a flange in a process that a saw frame reciprocates along the projection guide pin. A lock post clamp is installed inside the saw cell frame(200) and rotates and stops a saw cell(210) which supports a concave(240). The saw cell frame which is covered by the saw cell is combined with the top of the saw frame(300) to which the saw cell is combined. A clamping having a cylinder(110), a piston(120) and a lock post(130) is installed on the upper part of the saw cell frame. The cylinder is welded to the upper part of the saw cell frame which is formed of an oil inlet and an oil outlet.

Description

Lock post clamp of cone crusher

TECHNICAL FIELD The present invention relates to a lock post clamp for a crasher, in particular a lock post which allows the gap between the mantle and the convex to be kept constant by allowing the lock post to be unlocked in accordance with the oil pressure supplied through the oil supply. It is easy to adjust the quality to produce high-quality aggregates by size, and to check and replace quickly to reduce the downtime, increase the productivity of aggregates and promote the safety of workers, and also the process of crushing aggregates The top frame is prevented from being rotated along the iron flange in the state where the top frame is placed on the iron flange by the centrifugal force or friction driving force generated in the step, thereby preventing the distance between the congeb and the mantle to be variable. Allow aggregate to be produced, and the top frame is stepped guide A is a phase, in the process of being moved reciprocally by the lower stepped guide pin to be prevented from being separated from the flange along the convex.

In general, the cone crusher is to finely crush the finely ground crushed stone by the jaw crusher, as shown in Figure 1, the outside of the inside of the concave 510 fixed to the inside of the frame 500 A raw stone introduced into the top of the distributor 550 is rotated around the accent bush 540 while the main shaft 530 coupled to the mantle 520 is rotated by a belt connected to a motor (not shown). And by the wedge action generated between the mantle 520 can be obtained aggregate.

In addition, a top frame 560 having a female thread 561 formed on an inner circumference is seated at an upper portion of the frame 500, and a top cell 570 having a male thread 571 formed on the female thread 561 is coupled to be adjustable. The crushing force and the particle size of the product can be controlled. At this time, the interval adjustment is to use the hammer to prevent the fixing bolt 580 installed on the top of the top frame 560 to cover the outside of the top cell 570 through the top cell frame 572 to prevent loosening on the top of the top cell 570. By being screwed in a state in which the impact is applied, even when the fixing bolt 580 is separated, the same process, that is, by applying a hammer to the fixing bolt 580 with a hammer can be released.

In addition, by operating the hydraulic actuating rod (not shown) in the state in which the fixing bolt 580 is separated, the top cell inside the top cell frame 572 according to the direction in which the protrusion 573 formed on the outside of the top cell frame 572 is pressed. As the 570 moves upward or downward, the distance between the bottom surface of the convex 510 from the mantle 520 is variable.

However, in the process of applying a hammer to the fixing bolt using a hammer in the process of loosening or tightening the fixing bolt (580) takes a lot of work time and at the same time there was a problem that the worker is injured.

On the other hand, the top frame 560 seated on the upper portion of the frame 500 is fixed pin 580 as a way to prevent the flow of the mantle 520 by the rotational force or friction force in the process of the raw material is crushed aggregate produced ) Is coupled to the fixing groove 501 formed on the upper edge of the frame 500 in the form of fit fitting from the top to the bottom, and the upper portion of the fixing pin 580 is formed in the top frame 560. Coupling 562 to the middle fit allows the topframe 560 to be prevented from flowing along the top of the frame 500.

However, while the top frame 560 is repeatedly moved up and down along the fixing pin 580, the fixing pin 580 was separated from the fixing groove 501, and because of this cause, the top frame 560 The gap between the mantle 520 and the concave 510 according to the flow of the) is variable, the size of the aggregate is uneven, there is another problem that the quality of the product is lowered.

The present invention unlocks the lockpost screwed through the top of the top cell and the top of the top frame in accordance with the oil pressure supplied through the oil supply portion so that the gap between the top cell, that is, the convex from the mantle is easily adjusted. In order to produce high quality aggregates by size, and also to quickly check and replace the concave and mantles, it is possible to reduce the downtime of the work, to increase the productivity of the aggregates and promote the safety of the workers. In addition, the stepped guide pin is coupled to the iron flange of the support frame by interference fit, and the exposed stepped guide pin is inserted through the slide groove formed in the top frame, so that the centrifugal force or friction generated in the process of crushing the aggregate The top flange is mounted on the flange with the driving force, By preventing the rotation of the gap between the convex and the mantle is prevented from being rotated so that the aggregate having a uniform size can be produced, and the stepped guide in the process of the top frame reciprocating up and down along the stepped guide pin It is an object of the present invention to provide a lock fork clamp for a crasher that can prevent the pin from being separated from the iron flange.

In the present invention, the top cell frame 200 to which the top cell 210 is covered is coupled to the top of the top frame 300 to which the top cell 210 is coupled, and the top cell 210 to the top of the top cell frame 200. In the lock post clamp for the crasher configured to be coupled to the clamping portion 100 to be connected to), the clamping portion 100 is composed of a cylinder 110 and the piston 120 and the lock post 130 The cylinder 110 has a lower portion formed with an oil inlet 111 and an oil outlet 111 ′ coupled to an upper portion of the top cell frame 200, and the piston 120 has a hollow outer circumference portion 110. The inner periphery is fitted to abut the outer periphery of the hollow guide tube 140, the lock post 130 is fitted to the hollow guide tube 140, the lower portion of the top shell frame 200 It is coupled to the top cell 210 by penetrating through the screw groove 201 formed in the hook Is formed so that the upper portion of the piston 120 is locked by pressing the locking projection 131 by the oil pressure of the oil supply unit 150, the oil supply unit 150 is an oil tank An inlet side of the first valve 153 is coupled to an oil supply pipe 154 on the discharge side of the oil pump 152 that sucks, compresses and discharges the oil of 151, and the discharge side of the first valve 153. One side of the first check valve 155 is coupled and the other side of the first check valve 155 is characterized in that coupled to the oil inlet 111 of the cylinder (110).

According to the present invention, the lock post screwed through the upper part of the top cell and the upper part of the top frame is unlocked according to the oil pressure supplied through the oil supply part, so that the distance between the convex from the mantle can be easily adjusted. The effect of producing high quality aggregates by size can be obtained.

In addition, the inspection and replacement of the convection and mantles can be quickly reduced, reducing the downtime of the work, thereby increasing the productivity of the aggregates, and improving the safety of workers without the impact of hammers. .

In addition, the stepped guide pin is coupled to the stepped groove formed in the iron flange of the support frame by interference fit and the stepped guide pin exposed to the upper is inserted through the slide groove formed in the top frame, thereby crushing the aggregate. Due to the centrifugal force or friction driving force generated, the top frame is prevented from being rotated along the iron flange while the top frame is mounted on the iron flange to prevent the gap between the convex and the mantle from varying. The effect can be obtained.

In addition, the top frame is prevented from being separated from the iron flange while the top frame is moved back and forth along the step guide pin, thereby reducing the time required to replace the step guide pin.

An embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a front view illustrating the compactor of the lock post clamp in the coupled state according to the present invention, and FIG. 3 is a perspective view illustrating the upper portion of the compactor in the locked post clamp coupled to the present invention. 4 is a perspective view showing the inside of the upper portion of the compactor with the lock post clamp according to the present invention, Figure 5 is an enlarged cross-sectional view of the main portion of the compactor with the lock post clamp according to the present invention, FIG. 6 is a hydraulic circuit diagram of an oil supply unit for driving a lock post according to the present invention.

The lock post clamp for the crasher according to the present invention is installed inside the top cell frame 200 and has the function of fixing and rotating the top cell 210 supporting the convex 240 to which the top cell 210 is coupled. The top cell frame 200 to which the top cell 210 is covered is coupled to the top of the top frame 300, the cylinder 110 to be connected to the top cell 210 on the top of the top cell frame 200 And a clamping part 100 having a piston 120 and a lock post 130.

Here, the cylinder 110 has a lower portion formed with an oil inlet 111 and an oil outlet 111 'are coupled to the upper portion of the top cell frame 200 by welding joints, respectively, and each of the oil inlet 111 and the oil outlet. 111 is connected to each other via a connection hose 112 is configured so that the oil can be supplied to all the cylinders 110 through the first check valve 155 of the oil supply unit 150 to be described later.

In addition, the cylinder 110 has a first male thread portion 112 formed at the upper portion thereof, so that the first female threaded portion 114 formed at the lower portion of the cylinder cap 113 is coupled so that foreign matters are normally caught from the outside of the piston 120. And it is configured to prevent the fit on the surface of the lock post 130 to be described later, when rotating the lock post 130, is configured to be able to separate the cylinder cap 113 from the top of the cylinder 110 have.

The piston 120 has a hollow shape in the form of a pipe, the outer periphery of which is fitted to abut on the inner edge of the cylinder 110, and the inner periphery is configured to be fitted to abut on the outer periphery of the hollow guide pipe 140. .

In addition, the piston 120 has a locking jaw 121 is formed on the top to surround the hollow guide tube 140, the inner diameter of the locking jaw 121 is formed the same as the outer diameter of the rock post 130 rock post It is configured to be moved up and down along the outside of the 130.

In addition, the seating jaw 122 is formed in the lower portion of the piston 120 is coupled to the upper portion of the oil guide portion 123 and the oil guide portion 123 in the hollow form the lower portion of the outer peripheral cylinder 110 Opposed to the inner circumferential edge of the pressing groove jaw (123a) is formed in the lower portion of the inner peripheral portion is configured to be pressed against the pressing projection 141 formed in the lower portion of the hollow guide tube (140).

Wherein the inlet 111 and the oil outlet 111 'which is the center portion of the outer periphery is formed inclined portion (123b) is narrowed to the upper side is formed and the oil pressure acts on the inclined portion (123b) Hollow guide tube 140 is pressed to the top of the top shell frame 200, so that the hollow guide tube 140, such as the piston 120 is configured to prevent the movement to the top, through which the oil is the top cell It is configured to prevent leakage through the screw groove 201 formed in the frame 200.

The lock post 130 is inserted into the hollow guide tube 140, the lower portion is screwed to the top cell 210 through the screw groove 201 formed in the top cell frame 200, the locking projection 131 is on the top It is formed so that the upper portion of the piston 120 is locked by pressing the locking projection 131 by the oil pressure of the oil supply unit 150.

In addition, a second male screw portion 132 is formed at the lower end of the lock post 130 to be screwed to the second female screw portion 211 formed at the top cell 210, and the upper portion of the lock post 130 is polygonal. By forming a locking projection 131 having a shape is configured to rotate the rock post 130 by using a wrench and wrench not shown.

As shown in FIG. 6, the oil supply unit 150 has an inlet side of the first valve 153 on the discharge side of the oil pump 152 that sucks, compresses and discharges the oil in the oil tank 151. 154, one side of the first check valve 155 is coupled to the discharge side of the first valve 153, the other side of the first check valve 155 is the oil inlet of the cylinder 110 It is configured to be connected to the (111).

In addition, one side of the second valve 156 is connected between the discharge side of the oil pump 152 and the first valve 153 and one side of the branch pipe 157 is connected to the other side of the second valve 156. The setting cylinder 158 having the pushing rod 158a is coupled to the other side of the branch pipe 157, and the pushing rod 158a has a predetermined interval along the circumference of the outer circumference of the top cell frame 200. It is configured to be able to press the pushing projection 230 formed to have.

On the other hand, the top frame 300 is supported by the support frame 400 installed in the lower stepped groove 411 is formed perpendicular to the iron flange 410 formed on the upper side edge of the support frame 400 The lower end of the stepped guide pin 420 is coupled by interference fit toward the top from the bottom of the iron flange 410, the slide groove 310 facing the stepped groove 411 on the top frame 300 The slide groove 310 is formed in the middle fitting to the step guide pin 420 is formed so that the slide groove 310 is guided by the step guide pin 420, the top frame 300 is upper, lower It is configured to be able to reciprocate.

The process of adjusting the distance between the top cell 210 and the mantle 600 supporting the convex 240 using the lock post clamp having such a configuration is as follows.

First, when the oil supply to the inside of the cylinder 110 is stopped by the first valve 153 while the oil supply unit 150 is operated, the oil supplied to the inside of the cylinder 110 is the first check valve 155. And return to the oil tank 151 through the first valve 153. In this state, while rotating the cylinder cap 113 coupled to the upper portion of the cylinder 110 counterclockwise, the first male thread portion 112 is released from the first female thread portion 114 and the cylinder cap 113 is rotated. ) Are separated.

Next, the locking protrusion 131 of the lock post 130 is rotated counterclockwise using a spanner or a wrench to release the restraining force, and then the second valve 156 is repeatedly opened and closed, thereby providing an oil pump ( The oil compressed by the 152 is repeatedly supplied to the setting cylinder 158 through the branch pipe 157 so that the pushing rod 158a reciprocates to form the pushing protrusion 230 formed at the outer periphery of the top cell frame 200. The top cell frame 200 is rotated.

Next, as the top cell frame 200 is rotated, the top cell 210 is coupled to the top frame 300 in the form of a screw, thereby moving upward or downward. That is, when the top cell 210 is rotated in the clockwise direction, the gap between the convex 240 and the mantle 600 is opened and when the top cell 210 is rotated in the counterclockwise direction, between the convex 240 and the mantle 600 The gap becomes narrower.

Next, after the interval between the convex 240 and the mantle 600 is adjusted, the operation of the pushing rod 158a of the setting cylinder 110 is stopped by using the second valve 156 and then released. After tightening the lock post 130, the cylinder cap 113 is coupled to the upper portion of the cylinder 110.

Next, while the oil of the oil pump 152 is supplied back into the cylinder 110 through the first valve 153, the oil pressure introduced into the oil inlet 111 acts on the inclined portion 123b to guide the oil. The lower portion of the hollow guide tube 140 is pressed against the upper end of the top shell frame 200 by pressing the lower portion 123, and the piston 120 is hollow guide tube 140 by the oil pressure which is continuously supplied. The lockpost 130 is locked (fixed) as the upper portion of the piston 120 presses the lower portion of the locking protrusion 131 formed at the upper end of the lockpost 130. You lose. That is, the lock post 130 can be prevented from loosening due to vibration.

Through this process, while driving the drive motor (not shown) in a state where the gap between the convex 240 and the mantle 600 is adjusted, the mantle (by the interlocking of a known drive shaft, a driving bevel gear and a driven bevel gear) 600 is rotated and the raw material is injected from the top while the mantle 600 is rotated, and the input ore is crushed by the interval between the mantle 600 is rotated in the lower portion of the convex 240 The aggregate and crushed aggregate is dropped to the bottom and discharged.

At this time, the top frame 300 seated on the iron flange 410 of the support frame 400 is lifted upward by the size or impact force of the raw stone generated in the process of being crushed, and the same direction as the rotation of the mantle 600 In order to be rotated to one, at this time, the lower portion of the tandump guide pin 420 is coupled to the stepped groove 411 formed in the iron flange 410 by interference fit and the stepped guide pin exposed to the upper portion of the iron flange 410 ( Since the 420 is inserted into the slide groove 310 formed in the top frame 300, the rotation direction of the mantle 600 is repeated only by the action of returning to the upper part of the top frame 300 which is slightly spaced apart. The rotation can be prevented accordingly. The stepped groove 411 is preferably such that the stepped groove 411 is formed through a drill process, and then its inner surface is smoothed through a boring process.

1 is a front view showing a compactor according to the prior art.

Figure 2 is a front view showing the compactor with the lock post clamp is coupled in accordance with the present invention.

Figure 3 is a perspective view showing the upper portion of the compactor with the lock post clamp is coupled in accordance with the present invention.

Figure 4 is a perspective view showing the inside of the upper of the compactor with the lock post clamp is coupled according to the present invention.

Figure 5 is an enlarged cross-sectional view of the main portion of the compactor with the lock post clamp according to the present invention in a coupled state.

6 is a hydraulic circuit diagram of an oil supply unit for driving a lock post according to the present invention.

<Brief description of symbols for the main parts of the drawings>

100: clamping part 110: cylinder

111: oil inlet 111 ': oil outlet

120: piston 130: rock post

131: locking projection 140: hollow guide pipe

150: oil supply unit 151: oil tank

152: oil pump 153: first valve

154: oil supply pipe 155: first check valve

200: top cell frame 201: screw groove

210: top cell 300: top frame

Claims (5)

The top cell frame 200 to which the top cell 210 is covered is coupled to the top of the top frame 300 to which the top cell 210 is coupled, and is connected to the top cell 210 to the top of the top cell frame 200. In the lock post clamp for the crasher configured to be coupled to the clamping portion 100 to be, The clamping part 100 includes a cylinder 110, a piston 120, and a lock post 130, and the cylinder 110 has a top cell having an oil inlet 111 and an oil outlet 111 ′ formed therein. Is coupled to the upper portion of the frame 200, the piston 120 is fitted in such a way that the outer periphery is in contact with the inner edge of the cylinder 110 and the inner periphery is in contact with the outer periphery of the hollow guide tube 140 The lock post 130 is fitted into the hollow guide tube 140 and the lower portion penetrates through the screw groove 201 formed in the top cell frame 200 and is coupled to the top cell 210. ) Is formed so that the upper portion of the piston 120 is locked by pressing the locking projection 131 by the oil pressure of the oil supply unit 150, the oil supply unit 150 is an oil tank 151 Of the first valve 153 on the discharge side of the oil pump 152 to suck, compress and discharge the oil of The inlet side is coupled to the oil supply pipe 154, one side of the first check valve 155 is coupled to the discharge side of the first valve 153, and the other side of the first check valve 155 is the cylinder ( Coupled to the oil inlet 111 of 110, The cylinder 110 is formed by the first male screw portion 112 on the upper side is coupled to the first female screw portion 114 formed on the lower portion of the cylinder cap 113, The piston 120 has a locking jaw 121 surrounding the hollow guide tube 140 is formed on the upper portion, the inner diameter of the locking jaw 121 is formed to be the same as the outer diameter of the rock post 130, A seating jaw 122 is formed at a lower portion of the piston 120 to be coupled to an upper portion of the oil guide portion 123. The oil guide portion 123 is hollow in a lower portion of the outer periphery of the cylinder 110. Opposed to the periphery and forming a pressing groove jaw (123a) in the lower portion of the inner periphery, the pressing groove jaw (123a) is opposed to the pressing projection (141) formed in the lower portion of the hollow guide tube 140, which is the center portion of the outer periphery Where the oil inlet 111 and the oil outlet 111 'is formed inclined portion (123b) is narrowed to the upper side by forming the oil pressure acts on the inclined portion (123b) so that the hollow guide tube 140 is the top cell frame Pressurized to the top of 200, The top frame 300 is supported by the support frame 400, the stepped groove 411 is formed perpendicular to the convex flange 410 of the support frame 400, so that the lower end of the stepped guide pin 420 The stepped guide pin 420 is intermediately fitted to the slide groove 310 by forming a slide groove 310 facing the stepped groove 411 in the top frame 300 and coupled with an interference fit. Lock post clamp for compactors characterized by being coupled. delete delete The method of claim 1, A second male screw portion 132 is formed at the lower end of the lock post 130 and a second female screw portion 211 is formed at the top cell 210 to be screwed together, and is formed on the rock post 130. The locking protrusion 131 is a lock post clamp for the crasher, characterized in that formed in a polygon. delete

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