KR20150146154A - Device for preventing front head of breaker - Google Patents

Abstract

The present invention relates to an impact absorbing apparatus to protect a front head of a breaker and, more specifically, relates to an impact absorbing apparatus to protect a front head of a breaker, preventing the front head from being damaged by blank firing generated due to a frequent ripping work of the breaker. The impact absorbing apparatus to protect the front head of the breaker has a first impact absorbing member and a second absorbing member mounted on a front surface and a rear surface of the front head, respectively; and the first impact absorbing member and the second impact absorbing member supporting a tool pin to prevent the tool pin from escaping, and simultaneously absorbing an impact transferred from the tool pin. Even when the impact is exerted to the tool pin due to the blank firing when the ripping work is preformed, the first impact absorbing member and the second impact absorbing member absorbs the impact transferred from the tool pin, thus preventing damage to the front head.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a shock absorber for protecting a front end of a breaker,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shock absorber for protecting a front head of a breaker, and more particularly, to a shock absorber for protecting a front head of a breaker, in which a breaker, To a shock absorber for front head protection.

Generally, an excavator is equipped with a hydraulic breaker for crushing rocks and concrete as well as a bucket that carries sand or the like.

Referring to FIGS. 1 to 4, a hydraulic breaker according to the related art will now be described.

1 to 4, a conventional hydraulic breaker includes: a skeleton frame 10 connected to an excavator; A front head (12) mounted in a skeletal frame (10) as a cylinder structure in which a piston and a tool are housed; A piston (14) arranged at an upper portion in the front head (12) so as to be able to move up and down by hydraulic pressure or air pressure; A head 22 that is struck by the piston 14 and a crushing unit 24 that crushes the object to be crushed are integrally formed. The head 22 is embedded in the lower end of the front head 12, The part (24) comprises a shredding tool (20) protruding outward through the lower end of the front head (12).

At this time, curved concave restricting grooves 26 are formed on both sides of the boundary between the head 22 and the crushing portion 24 of the crushing tool 20.

A pair of tool pins 16 having an elliptical cross section are inserted and fixed along the front and rear directions of the front head 12. The tool pins 16 are inserted into the respective restricting grooves 26 of the shredding tool 20 So as to prevent the shredding tool 20 from being released in a downward direction.

A stop pin 18 for holding and holding the tool pin so as to keep the tool pin 16 in place is inserted into the front head 12 along the left and right direction of the front head 12. The stop pin 18 is inserted into the tool pin 16 So that the tool pin 18 can be prevented from slipping off.

The operation of the conventional hydraulic breaker constructed as described above will be described below.

The operation of crushing the crushing tool while the crushing tool 20 repeatedly ascends and descends instantaneously due to the striking force of the piston 14 is called a crushing operation.

To this end, the piston 14 is moved up to the top dead center in order to perform an operation of breaking the crushed material (rock, concrete, etc.) while the hydraulic breaker is mounted on the excavator as an initial state for the breaker work (See Fig. 1).

At the same time, the tip of the lower end of the crushing tool 24 of the crushing tool 20 is brought into close contact with the crushing object, so that the crushing tool 20 is pushed up to the highest position, The tool pin 16 is positioned on the lower side of the upper and lower sections of the upper and lower sections.

Subsequently, the piston 14 is lowered by hydraulic or pneumatic pressure to strike the head 22 of the shredding tool 20 (see FIG. 2).

The impact force of the piston 14 applied to the head 22 of the crushing tool 20 is transmitted to the crushing portion 24 of the crushing tool 20 to break the crushing material. However, as shown in FIG. 2, The breakage tool 20 does not descend and maintains the current state, so that the impact is not transmitted to the tool pin 18. [

That is, if the crushed material is not broken, the tip end of the crushing portion 24 of the crushing tool 20 is kept in close contact with the crushed material, and the crushing tool 20 is kept pushed up to the highest position And the tool pin 16 is continuously positioned on the lower side of the upper and lower sections of the restricting groove 26 of the disintegration tool 20. Eventually the impact applied to the disintegration tool 20 by the piston 14 is transmitted to the tool pin 18 ).

On the other hand, when the crushing tool is broken by the crushing tool 20, the crushing tool 20 hits the tool pin 16 while descending downward. At this time, the impact applied to the tool pin 16 by the crushing tool 20, And also to the stop pin 18, which serves to hold the base 16.

More specifically, as the striking force of the piston 14 charges the head 22 of the shredding tool 20 and the tip of the bottom of the shredding portion 24 breaks the shredded material, The crushing tool 20 is lowered and the upper surface of the upper and lower sections of the restraining groove 26 of the crushing tool 20 strikes the upper portion of the tool pin 16 when the crushing tool 20 is lowered Reference).

For reference, the upper surface side of the upper and lower sections of the restraining groove 26 of the shredding tool 20 strikes the upper portion of the tool pin 16 when the shredding tool 20 descends is referred to as a repelling phenomenon.

When the impact of the tool pin 16 occurs, the impact is also transmitted to the stop pin 18 which has been locked across the tool pin 16. [

In addition, when impact is transmitted to the stop pin 18 at the time of impact, the both ends of the stop pin 18 are assembled to the front head 12, so that the impact is also transmitted to the front head 12.

Therefore, as the impact transmitted to the stop pin 18 as described above is concentrated on the front head 12 in contact with both end portions of the stop pin 18, as shown in FIGS. 4A and 4B, the breakage of the stop pin 18 A crack is generated in the front head 12 adjacent to the stop pin 18, and the front head is damaged.

Korean Patent Publication No. 10-2009-0119614 (2009.11.19) Korean Patent Publication No. 10-2013-0123835 (Nov. 13, 2013)

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a shock absorber comprising a first shock absorbing member capable of absorbing shock transmitted from a tool pin, The second shock absorbing member can be mounted so that the impact transmitted from the tool pin can be absorbed by the first and second shock absorbing members even if the impact is applied to the tool pin due to the repulsion phenomenon during the burning operation, And a shock absorber for protecting the front head of the breaker.

According to an aspect of the present invention, there is provided an excavator comprising: a skeleton frame connected to an excavator; A front head mounted in a skeletal frame as a cylinder structure in which a piston and a tool are housed; A piston disposed on an upper portion of the front head so as to be able to move up and down by hydraulic pressure or air pressure; A tool pin inserted and coupled along the front-rear direction of the front head; A crushing tool having a structure in which a head part struck by a piston and a crushing part for crushing a crushing object are integrally formed, and a restraining groove is formed on both sides of a boundary between the head and the crushing part, A shock absorber for front head protection of a breaker,

A first shock absorbing member and a second shock absorbing member are provided on the front and rear surfaces of the front head to closely support the front end and the rear end of the tool pin so as to be capable of being separated from each other while absorbing impact applied to the tool pin The present invention provides a shock absorber for protecting a front head of a breaker.

Preferably, the first shock absorbing member has a structure in which a tool pin entry opening for inserting the tool pin 16 into the front head is formed on the front side, and a bolt fastening hole for assembling the skeleton frame is formed on both sides thereof A first support frame closely attached to the front surface of the front head; A cushioning cushion inserted into the tool pin entrance of the first support frame and brought into close contact with the front end of the tool pin; A cover plate which is tightly fixed to the front surface of the first support frame and pushes the buffer cushion inserted into the tool pin entry opening toward the front end of the tool pin; A bolt and a spring washer inserted into the first support frame from the front surface of the cover plate so as to fix and assemble the cover plate with respect to the first support frame; A first bolt protection bush inserted into the opening of the bolt fastener to protect the side joint bolt passing through the bolt fastener of the first support frame; And a control unit.

The second shock absorbing member may include: a cushioning pad closely contacted to the rear end of the tool pin exposed through the rear surface of the front head; A second support frame having bolt fastening holes for assembling the skeleton frame on both sides thereof, the second support frame closely assembled to the back surface of the front head and pushing the buffer pad toward the rear end of the tool pin; A second bolt protection bush inserted into the opening of the bolt fastener for protecting the side joint bolt passing through the bolt fastener of the second support frame; And a control unit.

Through the above-mentioned means for solving the problems, the present invention provides the following effects.

According to the present invention, the first shock absorbing member, which absorbs and absorbs the impact transmitted through the tool pin due to the throttle during the crushing operation, is attached to the front end of the front head of the breaker, Absorbing member that absorbs the impact transmitted through the tool pin is attached to the rear end of the tool pin so that the impact transmitted from the tool pin can be transmitted to the first and second impact absorbing members even if the impact is applied to the tool pin, The impact is not transmitted to the front head from the tool pin at all, so that breakage of the front head can be easily prevented.

1 to 4 are sectional views showing a conventional breaker structure and operation flow,
5 is an exploded perspective view showing a shock absorber for protecting a front head of a breaker according to the present invention,
6 is an exploded perspective view showing only a first shock absorbing member of a shock absorbing device for protecting a front head of a breaker according to the present invention,
7 is an exploded perspective view showing only the second shock absorbing member of the shock absorbing device for protecting the front head of the breaker according to the present invention,
8 is a perspective view showing a state after the first shock absorbing member of the shock absorbing device for protecting the front head of the breaker according to the present invention is assembled,
9 is a rear view showing a state after the second shock absorbing member of the shock absorbing device for protecting the front head of the breaker according to the present invention is assembled;
10 and 11 are sectional views showing a shock absorption process of the shock absorber for protecting the front head of the breaker according to the present invention,
12 is a cross-sectional view showing an example of increasing the contact area between the impact absorbing member and the tool pin according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As described above, the stop pin is fastened across the tool pin in a state where the tool pin passes through the respective restricting grooves of the breaking tool arranged in the front head, and the tool pin is locked so as to be prevented from being separated by the stop pin There is a problem that the impact of the tool pin is transmitted to the stop pin and a crack is generated in the front head around the stop pin.

Accordingly, it is an object of the present invention to provide an impact absorbing member which is provided on the front and rear surfaces of a front head, which absorbs and absorbs impact transmitted from a tool pin while closely supporting and supporting the tool pin, .

5 and 10, the breaker includes a skeleton frame 10 connected to an excavator; A front head (12) mounted in a skeletal frame (10) as a cylinder structure in which a piston and a tool are housed; A piston (14) arranged at an upper portion in the front head (12) so as to be able to move up and down by hydraulic pressure or air pressure; A tool pin (16) inserted and coupled along the front and rear direction of the front head (12); A head portion 22 struck by the piston 14 and a crushing portion 24 crushing the crushing object are integrally formed and a tool pin 16 is provided on both sides of a boundary portion between the head portion 22 and the crushing portion 24 And a shredding tool 20 having a restraining groove 26 to be inserted therethrough.

According to the present invention, the front and rear surfaces of the front head 12 are supported in such a manner that the front end and the rear end of the tool pin 16 can be separated from each other, and at the same time, 1 is characterized in that the first shock-absorbing member 40 and the second shock-absorbing member 40 are assembled.

Referring to FIGS. 5 and 6, the first shock absorbing member 40 has a first support frame 43, which is tightly assembled to the front surface of the front head 12, as a skeleton.

A tool pin entry opening 41 for inserting the tool pin 16 into the front head 12 and a rear surface of the cushioning cushion 44 in close contact with the front end of the tool pin 16 is formed on the front surface of the first support frame 43, And bolt fastening holes 42 are integrally formed on both sides of the first support frame 43 to assemble the first support frame 43 into the frame frame 10.

The side joint bolts 49 inserted from the outer surface of the skeleton frame 10 of the breaker are passed to the bolt fastening holes 42 of the first support frame 43 so that the first support frame 43 is inserted into the front head 12).

At this time, a first bolt protecting bush 48 for protecting the side joint bolt 49 is inserted into the opening of the bolt fastening hole 42 of the first supporting frame 43, And acts to protect the outer diameter of the side joint bolt 49 when fastened.

Particularly, a cushioning cushion 44 adhering to the front end of the tool pin 16 is press-fitted into the tool pin entry opening 41 of the first support frame 43, and the cushioning cushion 44 impacts, It is molded from absorbable material.

The buffer cushion 44 is inserted into the tool pin entry opening 41 of the first support frame 43 and is pressed against the tip end of the buffer cushion 44 in the state where the buffer cushion 44 is in close contact with the front end portion of the tool pin 16. [ The plate 45 is mounted.

That is, the bolt 46 and the spring washer 47 are inserted into the first support frame 43 from the outer surface of the cover plate 45 so that the cover plate 45 presses the buffer cushion 44 against the tool pin 16 So that the inner surface of the buffer cushion 44 is tightly adhered to the front end of the tool pin 16.

In this way, the first shock absorbing member 40, which is capable of supporting the front end of the tool pin 16 in a manner capable of being separated from the front end of the breaker, and capable of absorbing and absorbing the impact transmitted from the tool pin 16, When the front surface of the front head 12 is installed, the outer frame of the first support frame 43 and the cover plate 45 are visible as shown in FIG.

Referring to FIGS. 5 and 7, the second shock absorbing member 50 is a skeleton of the second support frame 53 closely attached to the rear surface of the front head 12.

Like the first support frame, a bolt fastener 52 for assembly with the skeleton frame 10 is formed on both sides of the second support frame 53.

The side joint bolts 49 inserted from the outer surface of the skeleton frame 10 of the breaker are passed to the bolt fastening holes 52 of the second support frame 53, And is fixedly assembled to the rear surface of the head 12.

A second bolt protection bush 54 for protecting the side joint bolt 49 is inserted into the opening of the bolt fastening hole 52 of the second support frame 53 so as to penetrate through the side joint bolt 49 And acts to protect the outer diameter of the side joint bolt 49 when fastened.

At this time, the buffer pad 51 is closely attached to the rear end of the tool pin 16 exposed through the rear surface of the front head 12 before the second support frame 53 is assembled to the rear surface of the front head 12.

Therefore, when the second support frame 53 is assembled to the rear surface of the front head 12, the buffer pad 51 is tightly supported by the rear end of the tool pin 16 by the urging force of the second support frame 53 State.

The second shock absorbing member 50 is provided on the rear surface of the front head 12 of the breaker to closely support the rear end of the tool pin 16 so as to prevent it from falling off and absorb the impact transmitted from the tool pin 16 When the rear surface of the front head 12 is viewed after installation, only the second support frame 53 is visible as shown in FIG.

Hereinafter, the shock absorbing device of the present invention having the above-described structure will be described as a buffering process for protecting the front head.

10 and 11 are cross-sectional views illustrating a shock absorption process of a shock absorber for protecting a front head of a breaker according to the present invention.

First, as an initial state for performing a breaker operation, after the piston 14 is moved up to the top dead center position in order to perform the operation of crushing the crushed material (rock, concrete, etc.) while the hydraulic breaker is mounted on the excavator, The piston 14 is lowered by hydraulic or pneumatic pressure to strike the head 22 of the shredding tool 20.

At this time, the striking force of the piston 14 applied to the head 22 of the shredding tool 20 is transmitted to the shredding part 24 of the shredding tool 20 so that the shredded material is broken. However, if the shredding material is not broken, 20 do not descend but maintain the current state, and the impact is not transmitted to the tool pin 16. [

If the hitting force of the piston 14 is applied to the head 22 of the crushing tool 20 and the tip of the crushing part 24 breaks the crushing object, The upper side of the upper and lower sections of the restraining groove 26 of the tool 20 strikes the upper portion of the tool pin 16 and an impact is transmitted to the tool pin 16. [

The shock absorbing cushion 44 of the first shock absorbing member 40 is firmly supported on the front end portion of the tool pin 16 and the second shock absorbing member 40 is attached to the rear end portion of the tool pin 16, The impact transmitted to the tool pin 16 is absorbed by the shock absorbing cushion 44 and the shock absorbing pad 51 and absorbed by the cushion pad 51 because the shock absorbing pad 51 of the member 50 is tightly supported.

Therefore, even if an impact is applied to the tool pin 16 due to a repulsive phenomenon during the crushing operation, the impact transmitted from the tool pin 16 is easily absorbed by the first and second impact absorbing members 40 and 50, The impact is not transmitted from the front head 12 to the front head 12 at all, so that breakage such as cracking of the front head 12 can be easily prevented.

The contact area between the buffer cushion 44 of the first shock absorbing member 40 and the front end portion of the tool pin 16 and the contact area between the buffer pad 51 of the second shock absorbing member 50, And the rear end portion of the tool pin 16 can be increased to maximize the buffering effect.

12, the protruding end 30 is integrally formed at the front end and the rear end of the tool pin 16 and the inner surface of the buffer cushion 44 and the inner surface of the buffer pad 51 Groove portion 32 into which the projecting end 30 is inserted is formed.

The contact area between the buffer cushion 44 of the first shock absorbing member 40 and the front end portion of the tool pin 16 and the contact area between the buffer pad 51 of the second shock absorbing member 50 and the rear end portion of the tool pin 16 The impact transmitted from the tool pin 16 can be absorbed more easily by the buffer cushion 44 and the buffer pad 51. [

On the other hand, the crushing portion 24 of the crushing tool 20 can be formed with a wear-resistant coating layer.

The reason why the crushed portion 24 of the shredding tool 20 is coated with a ceramic is to prevent corrosion and to prevent abrasion. Compared to chrome plating or nickel chrome plating, the ceramic coating is excellent in corrosion resistance, scratch resistance, abrasion resistance, impact resistance and durability.

The coating layer is coated on the periphery of the input shaft 110 and the output shaft 120 with a powder composed of 96 to 98% by weight of chromium oxide (Cr ₂ O ₃ ) and ₂ to 4% by weight of titanium dioxide (TiO ₂ ).

Chromium oxide (Cr ₂ O ₃ ) acts as a passivity layer to block oxygen entering the inside of the metal, thereby preventing rusting.

Titanium dioxide (TiO ₂ ) is a white pigment because it is very stable physicochemically and has high hiding power. And is also widely used for ceramics having high refractive index because of high refractive index. And has characteristics of photocatalytic property and superhydrophilic property. Titanium dioxide (TiO ₂ ) acts as an air purification function, an antibacterial function, a harmful substance decomposition function, a pollution prevention function, and a discoloration prevention function. This TiO ₂ ensures that the coating layer is surely covered around the crushing portion 24 of the crushing tool 20 and the foreign substance attached to the crushing portion 24 of the crushing tool 20 is decomposed and removed Thereby preventing the crushing tool 24 from being damaged.

Here, chromium oxide (Cr ₂ O ₃₎ and when using hayeoseo mixing titanium dioxide (TiO _2), the mixing ratio of these, chrome oxide (Cr ₂ O ₃₎ Titanium dioxide (TiO ₂₎ in 96-98% by weight 2 By weight to 4% by weight.

When the mixing ratio of chromium oxide (Cr ₂ O ₃ ) is less than 96 to 98% by weight, the coating of chromium oxide (Cr ₂ O ₃ ) is often broken in an environment such as a high temperature, 24) showed a sudden decrease in rust prevention effect.

When the mixing ratio of titanium dioxide (TiO ₂ ) is less than 2 to 4 wt%, the effect of titanium dioxide (TiO ₂ ) is insignificant so that the purpose of mixing it with chromium oxide (Cr ₂ O ₃ ) is discolored. That is, sikineunde prevent the titanium dioxide (TiO ₂₎ is decomposed foreign substances attached to the shredding unit 24, round the crushing tool 20, was removed a crushing section 24 for crushing tool 20 corroded or worn, When the mixing ratio is less than 2 to 4% by weight, there is a problem that it takes much time to decompose the attached foreign matters.

Therefore, since the coating layer having excellent oxidation resistance and abrasion resistance is formed around the crushing portion 24 of the crushing tool 20, the crushing portion 24 of the crushing tool 20 is prevented from being worn, (24) The life of the breaker is prolonged by the prevention of abrasion, thereby reducing the maintenance cost.

The buffer cushion 44 is made of a rubber material. To the buffer cushion 44 made of such a material, a polymerized trimethyl dihydroquinoline (RD) is added to increase the oxidation resistance. This RD increases ozone resistance and oxidation resistance and prevents corrosion and oxidation of the buffer cushion 44. [

The present invention preferably includes 0.4 to 1.2 parts by weight of RD in the material for producing the buffer cushion 44. [ This is because if the addition amount of RD is less than the above-mentioned range, it is difficult to obtain oxidation resistance, and if it exceeds the above-mentioned range, the density and firmness of the tissue are affected.

Since RD is further added to the buffer cushion 44 according to the present invention, the oxidation resistance is greatly improved, and thus the service life of the product can be maximized.

10: skeleton frame 12: front head
14: piston 16:
18: stop pin 20: crushing tool
22: head part 24: crushing part
26: restraint groove 30: protruding end
32: recessed groove 40: first shock absorbing member
41: Tool pin entry port 42: Bolt fastener
43: first support frame 44: buffer cushion
45: cover plate 46: bolt
47: spring washer 48: first bolt protection bush
49: side joint bolt 50: second shock absorbing member
51: buffer pad 52: bolt fastener
53: second support frame 54: second bolt protection bush

Claims (3)

A skeleton frame 10 connected to an excavator; A front head (12) mounted in a skeletal frame (10) as a cylinder structure in which a piston and a tool are housed; A piston (14) arranged at an upper portion in the front head (12) so as to be able to move up and down by hydraulic pressure or air pressure; A tool pin (16) inserted and coupled along the front and rear direction of the front head (12); A head portion 22 struck by the piston 14 and a crushing portion 24 crushing the crushing object are integrally formed and a tool pin 16 is provided on both sides of a boundary portion between the head portion 22 and the crushing portion 24 A shredding tool 20 having a restraining groove 26 to be inserted therethrough; A shock absorber for front head protection of a breaker,
A front end and a rear end of the front head 12 are closely contacted with and supported by the front end and rear end of the tool pin 16 so as to be separated from each other and a shock absorbing member 40) and the second shock absorbing member (50) are assembled to the shock absorbing device for front head protection of the breaker.
The method according to claim 1,
The first shock absorbing member (40) comprises:
A tool pin entry opening 41 for inserting the tool pin 16 into the front head 12 is formed on the front side and a bolt fastening hole 42 for assembling the skeleton frame 10 is formed on both sides thereof A first support frame 43 closely attached to the front surface of the front head 12;
A cushioning cushion 44 inserted into the tool pin entry opening 41 of the first support frame 43 and brought into close contact with the front end of the tool pin 16;
A cover plate 45 tightly fixed to the front surface of the first support frame 43 and pushing the cushioning cushion 44 inserted into the tool pin entry opening 41 against the front end of the tool pin 16;
A bolt 46 and a spring washer 47 to be inserted into the first support frame 43 from the front surface of the cover plate 45 to fix and assemble the cover plate 45 with respect to the first support frame 43 ;
A first bolt protection bush 48 inserted into the opening of the bolt fastener 42 to protect the side joint bolt 49 passing through the bolt fastener 42 of the first support frame 43;
And a shock absorber for protecting the front head of the breaker.
The method according to claim 1,
The second shock absorbing member (50) comprises:
A cushioning pad 51 tightly supported on the rear end of the tool pin 16 exposed through the rear surface of the front head 12;
And a bolt fastening hole 52 for assembly with the skeletal frame 10 is formed on both sides of the front head 12 so as to be closely attached to the rear surface of the front head 12, A second support frame (53) for pushing the first support frame
A second bolt protection bush 54 inserted into the opening of the bolt fastener 52 to protect the side joint bolt 49 passing through the bolt fastener 52 of the second support frame 53;
And a shock absorber for protecting the front head of the breaker.

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