KR20210081102A - Chisel for Impact Hammer - Google Patents

Abstract

The present invention relates to a chisel for an impact hammer device, which is installed on an impact hammer device mounted on an arm or the like of an excavator to crush a target object such as bedrock, concrete or the like by repetitively striking the same through a striking force provided through a hammer piston. According to the present invention, the chisel for an impact hammer device includes: a lifting rod part placed on a cylinder of an impact head device in a lifting structure to be struck by a hammer piston falling along the cylinder; and a striking head part formed separately from the lifting rod part, and stacked and assembled with a lower part of the lifting rod part to directly strike a target object while being lifted together with the lifting rod part, wherein the lifting rod part and the striking head part, which are stacked above and below, are formed to be assembled while kept supported to an outer circumference surface by a support sleeve part inserting a lower part of the lifting rod part and an upper part of the striking head part into a hollow part and fixing the same.

Description

Chisel for Impact Hammer

The present invention relates to a chisel for an impact hammer device, and more particularly, it is installed in an impact hammer device mounted on the arm of an excavator, and repeatedly strikes a crushed object such as rock or concrete through a striking force provided through a hammer piston. It relates to a chisel for crushing impact hammer device.

In general, an impact hammer device used for crushing work is a device for crushing objects to be crushed, such as rock or concrete, by transferring kinetic energy generated during reciprocating motion of a hammer piston to a chisel by hitting.

The impact hammer device includes a cylinder that is divided into a main body, a hammer piston movably installed in the cylinder, a chisel installed in the lower part of the cylinder to be hit by the hammer piston, and a cylinder chamber and a cylinder chamber. It is composed of a hydraulic system consisting of a valve device for reciprocating the piston by supplying it to the

Accordingly, the hammer piston is driven by hydraulic pressure to reciprocate between the rising position and the striking position, and is configured to strike the chisel at the striking position to apply an impact to the crushed object through the chisel.

Here, the chisel converts the kinetic energy of the hammer piston into impact energy and transfers it to the crushed object, and when the hammer piston descends from the rising position to the striking position, it is struck by the hammer piston.

By the way, the conventional chisel is disposed in an elevating structure in the impact head device and includes an elevating rod portion struck by a hammer piston; Since the striking head part is formed at the lower end of the lifting rod and directly strikes the crushed object such as rock or concrete integrally, when the wear or deformation of the striking head is caused by repeated striking of the crushed object, the lifting rod part and the A problem arises in that the entire cheese including the striking head has to be replaced.

Therefore, in the conventional chisel in which the elevating rod part and the striking head part are integrally formed, an unnecessary exchange of the lifting rod part is required when the striking head part is damaged. The problem of excessive consumption is pointed out.

KR 10-1420696 B1 KR 10-2019-0008517 A

An object of the present invention devised to solve the above problems is, in configuring the striking head portion formed in the lower portion of the lifting rod portion to be separately configured to enable replacement installation of the striking head portion, between the lifting rod portion and the striking head portion An object of the present invention is to provide a chisel for an impact hammer device that enables simple and inexpensive maintenance while securing improved striking performance by providing a unique fixing structure and standardized assembly therebetween.

The above object is achieved by the following configuration provided in the present invention.

A chisel for an impact hammer device according to the present invention,

a lifting rod portion disposed in a lifting structure on the cylinder of the impact head device and struck by a hammer piston descending along the cylinder; It is configured separately from the lifting rod part, and is assembled by stacking on the lower part of the lifting rod part, and includes a striking head part that directly strikes the crushed object while ascending and descending together with the lifting rod part,

The vertically stacked lifting rod portion and the striking head portion is configured to be assembled in a state supported on the outer diameter surface by the support sleeve portion for inserting and fixing the lower half of the lifting rod portion and the upper half of the striking head portion into the hollow portion.

Preferably, an assembling block is formed to protrude downward from the lower end of the elevating rod, and an assembling socket is formed on the upper portion of the striking head facing downwards to enter the assembling block to be assembled, so that the elevating rod and the striking head are assembled It is configured to be assembled by assembling through blocks and assembling sockets.

More preferably, an annular assembly groove is formed by concave inwardly on the outer diameter surface of the lower half of the lifting rod part facing the inner diameter surface of the support sleeve part, and the outer diameter surface of the upper half part of the striking head part,

At the upper and lower portions of the support sleeve, shoulder stoppers for restraining the lower half of the lifting rod part and the lower half of the striking head part stacked up and down through the annular assembly grooves are respectively disposed,

The shoulder stopper includes a forward and backward path formed in a radial structure on the upper and lower portions of the support sleeve, respectively; a shoulder attachment member which advances horizontally along the advancing and retreating path and has an end shoulder attached to the annular assembly groove; and a support bolt for advancing along the advancing and retreating path by pressing the shoulder attachment member.

In addition, a fastening hole to which a support bolt is fastened is formed orthogonally in the second half of the advancing and retreating path to which the shoulder attaching member advances, and the support bolt fastened along the fastening hole interferes with the shoulder attaching member disposed in the advancing and retreating path in the orthogonal direction to advance and retreat. configured to advance according to

As described above, in the present invention, by providing a unique fixing structure for assembling the separately configured elevating rod and striking head in a standardized manner, a standardized assembly between them is sought.

That is, in the present invention, without directly fixing between the elevating rod portion and the striking head portion through fastening, etc., adding a support sleeve for supporting the annularly supporting these stacked lifting rod portions and the striking head portion in a stacked state, the support sleeve By providing a fixing structure between the unit and the elevating rod unit and between the support sleeve and the striking head unit, a phenomenon in which the assembly state of the elevating rod unit and the striking head unit is deteriorated due to an impact generated in the repeated striking process is prevented.

Therefore, according to the present invention, stable durability and striking performance can be secured by a fixed structure including a support sleeve, and in case of deformation or damage of the striking head, simple and inexpensive maintenance is possible through replacement installation of the striking head. possible specificity.

In addition, in the present invention, a cooling structure interlocking with the hammer piston is provided between the lifting rod and the striking head to suppress the deterioration of the striking head by the cooling structure, and thus the durability of the striking head can be improved. have specificity.

1 is an overall configuration diagram of an excavator equipped with a chisel for an impact hammer device proposed as a preferred embodiment of the present invention;
Figure 2 shows the installation state of the chisel for the impact hammer device proposed as a preferred embodiment in the present invention,
3 is a view showing the overall configuration of the chisel for the impact hammer device proposed as a preferred embodiment in the present invention,
Figure 4 shows the detailed configuration of the shoulder stopper in the chisel for the impact hammer device proposed as a preferred embodiment in the present invention,
5 is a view showing the cooling state of the striking head portion through the cooling structure in the chisel for the impact hammer device proposed as a preferred embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, it is to provide a chisel for an impact hammer device proposed as a preferred embodiment of the present invention.

1 is an overall configuration diagram of an excavator equipped with a chisel for an impact hammer device proposed as a preferred embodiment of the present invention, and FIG. 2 shows the installation state of the chisel for an impact hammer device proposed as a preferred embodiment of the present invention. 3 shows the overall configuration of a chisel for an impact hammer device proposed as a preferred embodiment in the present invention, and FIG. 4 is a chisel for an impact hammer device proposed as a preferred embodiment in the present invention. It shows the detailed configuration of the stopper, and FIG. 5 shows the cooling state of the striking head through the cooling structure in the chisel for the impact hammer device proposed as a preferred embodiment in the present invention.

As shown in FIGS. 1 and 2, the chisel 1 for an impact hammer device proposed as a preferred embodiment of the present invention has an elevating structure in the cylinder 120 of the impact head device 100 fixed to the arm of the excavator, etc. a lifting rod portion 10 which is disposed as and struck by a hammer piston 120 descending along the cylinder 120; It is formed in the lower portion of the lifting rod portion 10 and includes a striking head portion 20 for directly striking the crushed object while ascending and descending together with the lifting rod portion (10).

In this embodiment, when damage to the striking head unit 20 that directly strikes the object to be shredded is caused by separating the lifting rod unit 10 and the striking head unit 20, the simplicity of the striking head unit 20 Maintenance is possible through replacement.

That is, in the present invention, as shown in FIGS. 2 and 3, the lifting rod 10 and the striking head 20 are configured separately to remove the damaged striking head 20 when the striking head 20 is damaged. By separating the part 10 and mounting the new striking head part 20 through assembly, the chisel 1 including the lifting rod part 10 can be reused.

To this end, in the present embodiment, by adding a support sleeve 30 for fixing the lifting rod portion 10 and the striking head portion 20 configured to be separated in an upright manner, the striking head portion is formed by the support sleeve portion 30 . (20) is assembled to be erect at the lower end of the lifting rod part 10, the striking head part 20 by the lifting rod part 10 hit downward by the hammer piston 120 while descending directly strikes the crushed object to shred it.

Here, the support sleeve 30 is composed of an annular tube body that annularly supports the outer diameter surface of the lifting rod part 10 assembled by stacking the upper and lower parts and the outer diameter surface of the striking head part 20, and the lifting rod part (10) and the striking head portion 20 are annularly supported by the circumscribing support sleeve portion 30 and assembled in a vertically stacked state.

At this time, the lifting rod part 10 is assembled in a state that the lower half enters downwardly into the upper part of the support sleeve 30 to insert the lower half into the hollow part of the support sleeve 30, and the striking head part supports the upper half By entering the lower part of the sleeve upwards, it is assembled with the upper half inserted into the hollow of the support sleeve 30 .

In this embodiment, an assembly block 11 is formed to protrude downwardly at the lower end of the elevating rod part 10, and the assembly block 11 enters downward to the upper portion of the striking head unit 20 facing it. By forming the socket 21 , the lifting rod 10 and the striking head 20 are assembled to be assembled through the assembling block 11 and the assembling socket 21 .

And, the inner diameter surface of the support sleeve 30, the outer diameter surface of the lifting rod portion 10 facing the inner diameter surface of the support sleeve 30, and the outer diameter surface of the striking head portion 20, spline projections 12, 22) and the spline groove 31 are formed to correspond to each other in the vertical direction.

Accordingly, the lower half of the lifting rod portion 10 that enters downward into the support sleeve 30 and the upper half of the striking head portion 20 that enters upward of the support sleeve 30 are spline protrusions 12 and 22) and the support sleeve 30 by the spline structure including the spline groove 31 and thus have improved durability together with suppression of the occurrence of play between them.

And, in this embodiment, the lower half of the lifting rod portion 10 and the upper half of the striking head portion 20 inserted into the hollow portion of the support sleeve 30 and stacked up and down are fixed to the support sleeve 30 to be standardized. By providing a fixing structure to the shredded object, even if the impact is repeatedly applied to the striking head portion 20, the assembly state of the lifting rod portion 10 and the striking head portion 20 by the support sleeve 30 to remain stable.

The fixing structure according to this embodiment is an annular assembly groove 13 formed on the outer diameter surface of the lower half of the lifting rod part 10 facing the inner diameter surface of the support sleeve part 30 as shown in FIGS. 3 to 4, and the An annular assembly groove 23 formed by inwardly indenting on the outer diameter surface of the upper half of the striking head 20; And formed on the upper and lower portions of the support sleeve portion 30, respectively, constraining the lower half of the lifting rod portion 10 and the lower half of the striking head portion 20 stacked up and down through the annular assembly grooves 13 and 23 and a shoulder attachment stopper (32).

Here, the shoulder stopper 32 includes a forward and backward path 33 formed in a radial structure on the upper and lower portions of the support sleeve 30, respectively; a shoulder attachment member 34 which advances horizontally along the advancing and retreating path 33 and has an end shoulder attached to the annular assembly grooves 13 and 23; and a support bolt 35 for advancing along the advancing and retreating path 33 by pressing the shoulder attachment member 34 .

In the present embodiment, the shoulder stoppers 32 configured as described above are formed in a radial structure on the upper and lower portions of the support sleeve 30, respectively, and the lifting rod portion 10 disposed in external contact within the support sleeve portion 30. The annular assembly groove 13 of the and the annular assembly groove 23 of the striking head part 20 are each shoulder-attached in a radial structure to be restrained.

In particular, in the present invention, the support bolt 35 interfering with the rear of the shoulder attachment member 34 is disposed orthogonally to the shoulder attachment member 34, so that the shoulder attachment member 34 is orthogonal to the falling support bolt 35 orthogonally. It is configured to advance inward along the advance and retreat path 33 to be interfered with.

A fastening hole 36 to which a support bolt 35 is fastened is formed orthogonally in the second half of the advancing and retreating path 33 through which the shoulder member 34 advances and retreats, and a support bolt 35 fastened along the fastening hole 36. is configured to advance along the advancing and retreating path 33 by interfering with the shoulder attachment member 34 disposed in the advancing and retreating path 33 in the orthogonal direction.

With this configuration, the fastening state of the support bolt 35 is poor due to the action force provided through the shoulder attachment member 34 supporting the lifting rod 10 and the striking head 20 in the process of crushing the object to be crushed. A phenomenon in which the restraint state of the lifting rod part 10 and the striking head part 20 by the shoulder attachment member 34 is deteriorated is prevented.

Thus, the lifting rod 10 and the striking head 20 assembled by inserting and stacking the upper end and the lower end in the support sleeve 30 have a spline structure, an assembly structure, and an annular assembly groove and a shoulder stopper 32 ) through the constraint structure to form a stable assembly state.

As a result, the assembly state of the striking head unit 20 assembled at the lower end of the lifting rod unit 10 through the supporting sleeve unit 30 in the crushing process of the object to be crushed becomes poor, and is separated from the supporting sleeve unit 30 . The phenomenon of shaking or shaking can be stably prevented.

In addition, in the present invention, as shown in FIG. 5 , between the elevating rod part 10 and the striking head part 20 that are repeatedly hit by the hammer piston 120 , the striking head part causes a direct collision with the crushed object. (20) by providing a cooling structure for cooling, to suppress the occurrence of deterioration of the striking head portion 20 to have improved durability.

The cooling structure of the striking head unit 20 according to the present embodiment includes: an elevating pipe 14 formed to penetrate vertically in the elevating rod unit 10; an elevating rod 24 disposed in the elevating structure in the elevating pipe 14; and a cooling conduit 26 formed in the striking head 20 and communicating with the elevating conduit 14 of the elevating rod 10 .

In this embodiment, by disposing a support spring 25 for upwardly pushing the lifting rod 24 in the lifting pipe 14, the upper end of the lifting rod 24 is not pressurized by the hammer piston 120. The lower surface is configured to rise along the hoistway 14 by being tanned upward.

Accordingly, the elevating rod 24 disposed on the elevating rod unit 10 descends along the elevating conduit 14 by a blow by the head piston 120 of the descending impact head device 100 while descending the elevating conduit 14 ), the remaining air is exhausted along the cooling pipe path 26 of the striking head unit 20 .

Then, when the blow of the head piston 120 is released, the external air flows along the cooling pipe 26 while ascending along the hoisting pipe 14 into the cooling pipe 26 and the hoisting pipe 14 .

Thus, the chisel 1 for the impact hammer device according to the present embodiment repeatedly hits the lifting rod 10 downward through the hammer piston 120 provided in the impact hammer device 100, the lifting rod 24 Through the exhaust of residual air through the descending of the and the inflow of external air through the rise of the lifting rod 24, continuous cooling of the striking head 20 heated by repeated striking of the crushed object is promoted, and as a result, the striking The occurrence of deterioration of the head portion 20 can be suppressed.

1. Chisel for impact hammer device
10. Lifting rod part 11. Assembling block
12. Spline projection 13. Annular assembly groove
14. hoistway
20. Strike Head 21. Assembling Socket
22. Spline protrusion 23. Annular assembly groove
24. Lifting rod 25. Support spring
26. Cooling Pipe Furnace
30. Support sleeve 31. Spline groove
32. Shoulder stopper 33. Retreat
34. Shoulder member 35. Support bolt
36. Fastener
100. Impact hammer device 110. Cylinder
120. Hammer Piston 130. Hydraulic Cylinder

Claims (4)

a lifting rod portion disposed in a lifting structure on the cylinder of the impact head device and struck by a hammer piston descending along the cylinder; It is configured separately from the elevating rod part, is laminated on the lower part of the elevating rod part and assembled to include a striking head part that directly strikes the crushed object while ascending and descending together with the elevating rod part,
The vertically stacked lifting rod portion and the striking head portion are configured to be assembled in a state supported by the outer diameter surface by the support sleeve portion for inserting and fixing the lower half of the lifting rod portion and the upper half of the striking head portion into the hollow portion Impact, characterized in that Chisel for hammer device. According to claim 1, wherein the assembly block is formed to protrude downward from the lower end of the lifting rod part, and the assembly socket is formed by entering the assembly block downward and assembled on the upper part of the striking head facing it, the lifting rod part and the striking head The chisel for impact hammer device, characterized in that it is configured to assemble and assemble through the assembling block and the assembling socket. According to claim 1, wherein the outer diameter of the lower half of the lifting rod part facing the inner diameter of the support sleeve, and the outer diameter of the upper half of the striking head is formed by an annular assembly groove recessed inward,
On the upper and lower portions of the support sleeve, shoulder stoppers for restraining the lower half of the lifting rod part and the lower half of the striking head part stacked up and down through the annular assembly grooves are respectively disposed,
The shoulder stopper may include advancing and retreating paths formed in a radial structure on upper and lower portions of the support sleeve, respectively; a shoulder attachment member which advances horizontally along the advancing and retreating path and has an end attached to the annular assembly groove; and a support bolt for pressing the shoulder attachment member to advance along the advancing and retreating path. The method of claim 3, wherein a fastening hole to which a support bolt is fastened is formed perpendicularly to the second half of the advancing and retreating path to which the shoulder attaching member advances and retreats, and the support bolt fastened along the fastening hole is orthogonal to the shoulder attaching member disposed in the advancing and retreating path. A chisel for an impact hammer device, characterized in that it is configured to advance along a forward and backward path by interfering.

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