KR20160098632A - Chisel structure equipment of excavator - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a chisel device for an excavator, and more particularly, to a chisel device for an excavator that is filled with a material having silicone, resin, or elasticity in a space portion formed inside a chisel case.
To this end, the chisel device of the excavator of the present invention comprises a cylinder, a chisel case provided inside the cylinder, which is driven by a piston to transmit an impact force of the piston and has an insertion groove formed at one side thereof, A chisel for crushing the object to be crushed by an impact force of a piston transmitted to the chisel case, and a chisel part including a space part formed in the inside of the chisel case, Thereby forming an injection hole.

Description

{Chisel structure equipment of excavator}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a chisel device for an excavator, and more particularly, to a chisel device for an excavator that fills a hollow space formed in a chisel case with a material having silicone, resin or elasticity.

The excavator is a construction machine that performs works such as excavation work for digging the ground in civil engineering, construction, construction site, loading work for carrying earthworks, crushing work for dismantling the building, and political work for organizing the ground. It is a kind of construction equipment that is used for destroying most buildings, digging roads or removing rocks such as hills.

1, the excavator is composed of a lower traveling body 1 and an upper rotating body 2, an operator 3 for carrying the operator on the upper rotating body 2, A boom 5 and an arm 6 connected to the front end of the boom 5. The attachment 6 is detachably attached to the front end of the arm 6. [ There are buckets, typical of attachments, which are suitable for excavating soil. There are various kinds of attachments other than the buckets, and an optimum attachment is attached to the arm 6 depending on the kind of work to be performed.

Further, in order to crush the crushed material such as a large rock or a concrete lump, a breaker 7 is attached to the tip of the arm 6 as an attachment of the hydraulic excavator. The breaker 7 is constructed such that a chisel 8 composed of a steel bar or the like having a sharp end is driven by a breaker cylinder 9. [ Therefore, by supplying the hydraulic pressure from the hydraulic pump to the breaker cylinder 9 of the breaker 7, the chisel 8 is reciprocally operated to crush it by striking the crushed material.

Here, the chisel 8 is provided inside a cylinder 9 for guiding a piston (not shown) that is moved up and down by hydraulic pressure, and crushes the crushed material using the impact force of the piston. As a result, the piston reciprocates upward and downward to strike the top surface of the chisel 8, thereby generating a strong impact force on the tip of the chisel 8, thereby crushing the crushed material.

Meanwhile, in order to restrict the movement of the chisel 8, a key groove 11 having a predetermined length with a small diameter of a top end portion of a chisel inside the cylinder is formed, and a key 10 is provided around the key groove 11. That is, when the upper end of the key groove 11 of the chisel 8 contacts the key 10, the lowering of the chisel 8 stops and the lower end of the key groove 11 of the chisel 8 presses the key 10 The movement of the chisel 8 is stopped by the stop of the rising of the chisel 8, thereby restricting the movement of the chisel 8.

Generally, the inside of the chisel forms an empty space to reduce weight. However, in the case of forming an empty space in the inside of the chisel, when the piston is used to hit the chisel, vibration or noise is generated.

When the piston strikes the chisel, the vibration or noise is generated, which is transmitted to the entire cylinder. If vibration or noise is generated in the cylinder, the cylinder may be damaged, which causes a decrease in the working efficiency.

Korean Patent Publication No. 2010-0075299 Korean Patent Publication No. 2001-0051858 Korean Patent No. 10-1355134

A problem to be solved by the present invention is to provide a method in which vibration does not occur in a chisel even if the piston strikes the chisel.

Another problem to be solved by the present invention is to propose a method in which noise is not generated in the chisel even if the piston strikes the chisel.

Another problem to be solved by the present invention is to reduce vibrations and noise of a chisel to thereby increase the working efficiency.

To this end, the chisel device of the excavator of the present invention comprises a cylinder, a chisel case provided inside the cylinder, which is driven by a piston to transmit an impact force of the piston and has an insertion groove formed at one side thereof, A chisel for crushing the object to be crushed by an impact force of a piston transmitted to the chisel case, and a chisel part including a space part formed in the inside of the chisel case, Thereby forming an injection hole.

The chisel device of the excavator according to the present invention is advantageous in that vibration or noise generated when the piston hits the chisel case is reduced by filling silicon, resin, or elastic material into the space formed in the chisel case.

In addition, the present invention forms an injection hole connecting the space portion from the upper surface of the chisel case for injecting silicon, resin, or elastic material into the space portion formed inside the chisel case, so that silicone, resin or elasticity There is an advantage in that the material having a high strength can be injected into the space portion.

1 is a schematic view showing an excavator equipped with a conventional chisel,
FIG. 2 is a cross-sectional view of a conventional chisel, showing a chisel structure of an excavator according to an embodiment of the present invention,
FIG. 3 is a view showing a detailed structure of a chisel according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and further aspects of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

2 shows a chisel apparatus according to an embodiment of the present invention. Hereinafter, a chisel apparatus according to an embodiment of the present invention will be described in detail with reference to FIG.

According to Fig. 2, the chisel structure device includes a chisel part, a support device, a bushing, a stroke space part, a cylinder cover, and a seal. The chisel part includes a chisel case, a chisel, an insertion groove and a space part, and the supporting device includes a supporting key and a supporting cover.

As described above, the chisel structure device of an excavator is installed in an excavator, an excavator, or the like, which is a kind of construction equipment used for breaking down a building, digging a road, or removing a rock such as a hill.

The chisel part 200 is installed inside the cylinder 700 and is driven by a piston (not shown) to directly crush the object to be crushed. The chisel part 210 includes a chisel case 210 and a chisel 220.

The chisel case 210 is installed inside the cylinder 700 and is driven by the impact force of the piston to transmit the impact force to the chisel 220 so that the chisel 220 is inserted into the insertion groove 230 And the impact force of the piston is transmitted to the opposite side.

The inside of the chisel case 210 is filled with a heavy weight so that the impact force of the piston is transmitted to the chisel 220. When the chisel case 210 is heavy in weight, A space 240 is formed for lightening the weight as much as possible.

However, when the piston hits the chisel case 210 in a state where the space 240 has the shape of an empty hole, vibration or noise is generated in the chisel case 210. Therefore, the present invention fills the space 240 with another member. This will be described later with reference to FIG.

At this time, the cylinder 700 and the piston are part of the hydraulic breaker and are not described in the prior art. However, in the present invention, a plurality of bushings 500 for closely sealing between the cylinder 700 and the chisel case 210 are installed.

2, the cylinder 700 and the chisel case 210 are spaced apart from each other in the drawing between the upper side and the lower side, and the upper side bushing 500 and the lower side Between the bushings 500, protrusions formed on the outer periphery of the chisel case 210 are disposed in the stroke space portion 600.

The chisel case 210 is driven by an interval of the stroke space part 600 and the stroke space part 600 is filled with oil for minimizing friction between the stroke space part 600 and protrusions driven by the driving of the chisel case 210 .

A cylinder cover 710 is further provided at the end of the cylinder 700 by a coupling member such as a bolt to prevent the bushing 500 from being disengaged by driving the chisel case 210.

A plurality of sealing rings 720 are further formed on the inner circumference of the cylinder cover 710 so as to come into close contact with the outer circumference of the chisel case 210 to prevent leakage of oil or penetration of foreign substances.

Here, a crushing portion (not shown) having a pointed shape is provided at the lower end of the chisel 220. The crushing part is a part directly impacting the crushed material such as a rock mass to be crushed and should be relatively harder than the other parts.

Even if the chisel 220 is made of a material that improves abrasion resistance and impact resistance, there is a limit to the use period. That is, after a certain period of use, the blunt end must be forged again. In this case, the support device 400 can be easily removed and the substrate 220 can be separated. The attachment / detachment structure of the support device 400 will be described below.

A through hole (not shown) is formed in the outer periphery of the chisel 220 to penetrate the support key 410 of the supporting device 400. The through hole is horizontally penetrated and formed at a right angle to the chisel 220.

The supporting device 400 is installed on the chisel part 200 and is a device for preventing the chisel from separating from the chisel case 210 and firmly supporting the chisel. The supporting device 400 is composed of a supporting key 410 and a supporting cover 420.

The support key 410 is protruded from both sides of the outer periphery of the chisel 220 at a predetermined distance through the through hole formed in the outer periphery of the chisel 220 and the support key 410 is supported on the support cover 420, The chisel 220 is prevented from being detached from the insertion groove 230 of the chisel case 210. However, when the support key 410 is removed, the chisel 220 is easily separated.

The support cover 420 is coupled to an end of the chisel case 210. The support cover 420 has a structure in which a chisel 220 is provided at a central portion of the support cover 420, When crushing the crushed material, it is shaken to the left or right and firmly supports the crushed material.

The support cover 420 is formed in a shape of "∪" in the vertical section and is screwed to the end of the chisel case 210 to be easily detachable and attachable to the support key 420. The support key 420 penetrates the chisel 220, So that the chisel 220 is prevented from being detached.

3 shows a structure of a chisel part according to an embodiment of the present invention. Hereinafter, the structure of the chisel part according to one embodiment of the present invention will be described in detail with reference to FIG.

According to Fig. 3, the chisel part includes a chisel case, a chisel, an insertion groove, a space part, and an injection hole. Of course, other configurations than those described above may be included in the chisel part proposed in the present invention.

The chisel case 210 forms a protrusion 250 disposed in the stroke space portion as described above. In addition, the chisel case forms an injection hole 260 at the upper end of the chisel case 210 for injecting silicon, resin, or elastic material.

The injection hole 260 is connected from the upper end of the chisel case to the space 240, and a material having silicon, resin, or elasticity is injected from the outside. In FIG. 3, although the injection holes have the same diameter, the diameter of the lower end may be relatively larger than that of the upper end. That is, the diameter of the injection hole 260 formed at the upper end of the chisel case where the piston is struck is relatively small, and the diameter of the injection hole 260 is increased to the lower part so that the material having silicone, resin or elasticity is easily injected into the space.

The space 240 is formed of silicon, resin, or elastic material injected into the injection hole 260 as described above. When the space 240 is stacked with silicon, resin, or elastic material, vibration or noise can be reduced when the piston strikes the chisel case. In addition, since the material of silicone, resin, or elasticity is relatively small in weight as compared with a metal material constituting the chisel case, the impact of the piston can be effectively transmitted to the object to be crushed. In other words, as described above, if the chisel case 210 is of a heavy weight, the entirety of the hydraulic breaker is burdened. However, the invention forms a space 240 inside the chisel case, And is made of silicon, resin, or a material having elasticity.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the scope of the present invention .

200: Chisel part 210: Chisel case
220: Chisel 230: Insertion groove
240: space part 250:
260: injection hole 400: support device
410: Support key 420: Support cover
500: bushing 600: stroke space part
700: Cylinder 710: Cylinder cover
720: Sealing

Claims (4)

cylinder;
A chisel case provided in the cylinder and driven by the piston to transmit the impact force of the piston and having an insertion groove formed at one side thereof; a crushing device for crushing the crushed material by the impact force of the piston installed in the insertion groove of the chisel case; And a chisel part including a space part formed inside the chisel case,
Wherein the chisel case forms an injection hole for injecting silicon, resin or elastic material into the space portion.
The chisel device of claim 1, wherein a protrusion protruding by a predetermined length is formed on the outer circumference of the chisel case.
3. The method of claim 2,
Wherein the injection hole is formed from the upper surface of the chisel case to the space portion, and the diameter of the injection hole is relatively larger as the distance from the space portion is relatively closer.
The method of claim 3,
Wherein a plurality of bushings are provided between the cylinder and the chisel case for sealing the chisel case, and a stroke space portion is formed between the bushing and the bushing to arrange the protrusions formed on the outer periphery of the chisel case, Is driven, and the stroke space portion is filled with oil.

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