KR20140077475A - Shock Absorber Type Vibro Breaker - Google Patents

Abstract

The present invention provides a shock-absorbing type vibro breaker comprising: an external bracket (100) which has an internal vibration space and a coupling hole (110) formed on one side thereof so as to be coupled to a boom of a heavy equipment; a vibration generating unit (200) arranged in the internal vibration space of the external bracket (100) so as to generate vibrations in the vertical direction; a nipper blade (300) arranged in the vibration generating unit (200) and extended downwardly; a lower link unit (400) one end of which is rotatably pin-coupled to one side of the nipper blade (300) and the other end of which is rotatably pin-coupled to the inner side of the external bracket (100), wherein the unit expands/retracts according to the vertical movement of the nipper blade (300); and an anti-vibration unit (500) arranged inside the external bracket (100) and on the vibration generating unit (200) so as to relieve the vibrations and shock delivered from the vibration generating unit (200).

Description

{Shock Absorber Type Vibro Breaker}

The present invention relates to a vibration breaker installed in a boom of a heavy equipment, and it provides a vibration breaker of a new structure that effectively absorbs vibration and impact and improves shredding efficiency.

Generally, excavators used in civil engineering and construction sites for the development of highways, harbors, bridges, dams, buildings, and cities are used to perform compaction, crushing, excavation, etc. of the ground in response to hitting operation, A severe noise is generated.

Particularly, excavation of rock, concrete structure, solid ground, etc., or the soil of soil is raked, the breaker or the nipper unit is attached to the boom of the excavator. The vibration generated from the breaker or nipper unit is directly transmitted to the boom. These vibrations generate noise, which is amplified and doubled in the process of being transmitted to the boom.

In view of this point, Japanese Patent Application Laid-Open No. 10-2006-0033893 discloses a nipper for an excavator. A nipper for an excavator is provided with a connection mount portion fixedly connected to a boom of an excavator, a blade main body rotatably mounted on the connection mount portion for excavating soil in the ground, and a blade main body mounted on the blade main body, And vibration means for providing power. The excavator nipper disclosed is mounted on a boom of an excavator in such a manner that the blade main body is rotatably mounted on the boom, and the vibration is transmitted to the boom through the blade main body. Thus, the vibration transmitted to the boom is amplified to make the adjustment of the excavator difficult, and further, the excavator is damaged.

In addition, in the case of Japanese Patent Application Laid-Open No. 10-2012-0051698, a hydraulic hammer ripper for a mechanical digger of a type used for breaking or lifting a hard object in the ground such as stone, concrete, asphalt, etc. 1. A hydraulic hammer ripper comprising a tooth 1 attached to a headstock 5 on an excavator by an array of attachment items 6, The hammer lipper includes at least a tooth portion 1, drive devices 2 and 3, and a power accumulator 4, and is provided with a tooth portion 1, driving devices 2 and 3 ), And the power accumulator 4 are firmly attached to the teeth. The nipper having such a structure has a problem in that the tooth part 1 does not form a straight striking line due to the pivot action of the anchoring rod 6 and draws an elliptical trajectory, thereby reducing the shredding efficiency.

In order to solve the above-mentioned problems, the object of the present invention is as follows.

First, it is an object of the present invention to provide a vibration breaker of a new structure in which the end portion of the nipper blade 300 can have a straight strike path.

Secondly, another object of the present invention is to provide a vibration breaker of a new structure that can effectively absorb vibrations and shocks generated during hitting.

Third, a vibration breaker having a new structure that supports the movement of the vibration generating part 200 on the front and rear sides to induce the upward and downward linear motion of the vibration generating part 200 and to improve the friction supporting force according to the vibration of the vibration generating part 200, Which is a further object of the present invention.

Technical features of the present invention are as follows.

An outer bracket 100 having an inner space and provided with a coupling hole 110 to be coupled to a boom of a heavy equipment on one side; A vibration generating unit 200 positioned in the inner space of the outer bracket 100 and generating vibration in a vertical direction; A nipper blade 300 mounted on the vibration generating part 200 and extending downward; One end of the nipper blade 300 is pivotally coupled to one end of the nipple blade 300 so that the other end of the nipple blade 300 is pivotally coupled to the inside of the outer bracket 100, 400); And an outer bracket 100 mounted on the inner side of the outer bracket 100 to closely contact the upper edge of the vibration generating part 200 in accordance with the movement of the vibration generating part 200, And an anti-vibration part 500 for relieving the vibration.

Technical effects of the configuration of the present invention are as follows.

First, the tip of the nipper blade 300 may have a straight strike path.

In other words, the entire length of the lower link 400 and the upper link 700 can be expanded and contracted, and the friction supporting portion 600 is brought into close contact with the vertical inner surface of the outer bracket 100, The nipper blade 300 can be guided by the nipper blade 300 in a straight line, and the nipper blade 300 can be guided by the nipper blade 300 in a straight line. The teeth 310 forming the direct impact point strike a straight line to hit the object to be crushed, thereby maximizing the crushing efficiency.

Second, it can effectively absorb vibrations and shocks generated during hitting.

In other words, the vibration-proof part 500 is mounted on the inner side of the outer bracket 100 and is brought into close contact with the upper part of the vibration-generating part 200 according to the movement of the vibration-generating part 200, And the impact is mitigated.

Third, the friction supporting part 600 is mounted on the side surface of the vibration generating part 200 to induce the up and down linear movement of the vibration generating part 200 and to improve the friction supporting force according to the vibration of the vibration generating part 200.

Figure 1 shows a conventional nipper structure.
Fig. 2 shows the structure of the outer bracket 100. Fig.
FIG. 3 illustrates a side structure of a concrete embodiment of the present invention, in which the shape of the outer bracket 100 is shown as a virtual line when the lower link 400 and the upper link 700 are provided.
Fig. 4 is a perspective view of Fig. 3, and the shape of the outer bracket 100 is omitted.
FIG. 5 is a perspective view showing an outer shape of the outer bracket 100 in FIG. 3.
FIG. 6 is a perspective view showing in detail the internal structure of the outer bracket 100 in FIG.
7 shows a side structure of another specific embodiment of the present invention, in which only the lower link 400 is provided, and the shape of the outer bracket 100 is shown by a virtual line.
8 is a sectional view showing a specific embodiment of the lower link 400 or the upper link 700. [

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

As shown in FIG. 2, the outer bracket 100 has a space for receiving the vibration generating unit 200 therein. At one side of the outer bracket 100, a coupling hole 110, which is coupled to a heavy equipment boom, Respectively.

In addition, inner side walls are provided on both sides of the front and rear sides so as to be inclined so that the anti-vibration rubber constituting the dustproof portion 500 is inclined.

The structure of the vibration generating part 200, the nipper blade 300, the lower link 400, the upper link 700, the vibration preventing part 500 and the friction supporting part 600 can be easily understood with reference to FIGS. 3 to 6 have.

The vibration generating unit 200 is located in the inner space of the outer bracket 100 and generates vibration in the vertical direction.

The internal structure of the vibration generating unit 200 is the same as or very similar to that used in a general vibration nipper, and a separate explanation will be omitted. For example, in the drawings of the Japanese Patent Application No. 10-0878296 4 to FIG. 7, and the detailed description of the invention related thereto, and any structure or device capable of vibrating the nipper blade 300 in the vertical direction is acceptable.

The nipper blade 300 is attached to the vibration generating part 200 and extends downward. The lower end of the nipper blade 300 is equipped with a teeth 310 forming a direct impact point.

One end of the lower link 400 is rotatably pinned to one side of the nipper blade 300 and the other end of the lower link 400 is rotatably pinned to the inside of the outer bracket 100.

The lower link 400 is not a bar structure having a fixed length but a structure in which the entire length is expanded and contracted according to the movement of the nipper blade 300.

One end of the upper link 700 is rotatably coupled to one side of the upper portion of the vibration generating unit 200 and the other end of the upper link 700 is rotatably coupled to the inside of the outer bracket 100.

The upper link 700 has a structure in which the entire length of the upper link 700 is expanded and contracted according to the movement of the vibration generating unit 200.

The lower link 400 and the upper link 700 may be various types of hydraulic cylinders using hydraulic oil. Alternatively, as shown in FIG. 8, a piston body 11 and a piston slidably coupled to the cylinder body 11 A first elastic body 33 provided inside the cylinder body 11 to elastically support the piston 22 in one direction and a second elastic body 33 provided inside the cylinder body 11 to move the piston 22 in the other direction And a second elastic body 44 for elastically supporting the elastic body. Here, the first elastic body 33 and the second elastic body 44 may be a spring or an elastic rubber.

If the entire length of the lower link 400 and the upper link 700 can be expanded and contracted and an appropriate guide means for guiding the vibration generating unit 200 and the nipper blade 300 to move up and down is provided, When the vibration generating unit 200 and the nipper blade 300 are lowered, the lower link 400 is gradually contracted, and when the upper link 700 is extended, when the vibration generating unit 200 and the nipper blade 300 are lowered, The link 400 is stretched and the upper link 700 is retracted.

When the nipper blade 300 draws a linear trajectory in the vertical direction, the teeth 310, which are attached to the lower end of the nipper blade 300 and form a direct impact point, strike the object to be crushed to strike the object to be crushed, can do.

In a specific embodiment of the present invention, a circular cross-section fastening portion is provided, and the fastening portion is inserted into the nipper blade 300, And then is fixed by using the connecting pin 311. [0051] Next, as shown in FIG.

The vibration preventing part 500 is mounted on the inner side of the outer bracket 100 and is brought into close contact with the upper part of the vibration generating part 200 in accordance with the motion of the vibration generating part 200 to generate vibration and shock transmitted from the vibration generating part 200 It is a role to mitigate.

The vibration generating portion 200 is formed at an upper edge thereof with an inclined surface 210 in which the vibration preventing portion 500 closely contacts the vibration preventing portion 500. The vibration preventing portion 500 has an inclined surface 210, Respectively.

The anti-vibration part 500 may be made of anti-vibration rubber or various types of synthetic resin.

The vibration damping part 500 may be coupled only to the outer bracket 100 and both sides of the vibration damping part 500 may be coupled to the outer bracket 100 and the vibration generating part 200, The structure may be configured such that contraction and relaxation are repeated according to the relative movement of the outer bracket 100.

The friction supporting part 600 is attached to the side surface of the vibration generating part 200 and supports the vibration generating part 200 while closely contacting the vertical inner surface of the outer bracket 100 according to the movement of the vibration generating part 200. And serves to guide the up and down movement of the vibration generating unit 200.

That is, the friction supporting part 600 is in close contact with the vertical inner surface of the outer bracket 100 in the process of moving the vibration generating part 200 up and down so that the vibration generating part 200 does not deviate from the linear locus, As shown in Fig. The upper link 700 and the lower link 400 are expanded and contracted to an appropriate length so that a linear locus of the vibration generating part 200 and the nipper blade 300 is possible.

In addition to the function of supporting the vibration generating part 200 and preventing the up and down movement of the vibration generating part 200 by an appropriate frictional force, the function of absorbing the vibration and impact is also performed. It can be manufactured from anti-vibration rubber or various kinds of synthetic resin.

7 shows an embodiment in which only the lower link 400 is provided, the other components are the same and only the upper link 700 is understood as a removed form.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Addition or deletion of a technique, and limitation of a numerical value are included in the protection scope of the present invention.

100: External bracket
110: coupling ball
200:
210:
300: Nipper blade
310: Teeth
311: connecting pin
400: Lower link
500:
600: Friction support
700: upper link
11: Cylinder body
22: Piston
33: First elastic body
44: second elastic body

Claims (8)

An outer bracket 100 having an inner space and provided with a coupling hole 110 which is coupled to a boom of a heavy equipment on one side;
A vibration generating unit 200 positioned in the inner space of the outer bracket 100 and generating vibration in a vertical direction;
A nipper blade 300 mounted on the vibration generating part 200 and extending downward;
One end of the nipper blade 300 is pivotally coupled to one end of the nipple blade 300 so as to be rotatable. The other end of the nipple blade 300 is pivotally coupled to the inside of the outer bracket 100. 400); And
The vibration generating unit 200 is mounted on the inner side of the outer bracket 100 and closely contacts the upper portion of the vibration generating unit 200 according to the motion of the vibration generating unit 200 to alleviate vibration and shock transmitted from the vibration generating unit 200 A dustproof portion 500;
And a shock absorption type vibration breaker. The method of claim 1,
A friction supporting part 600 mounted on a side surface of the vibration generating part 200 and supporting the vibration generating part 200 while closely contacting the side surface of the outer bracket 100 according to the movement of the vibration generating part 200;
Further comprising: a shock absorption type vibration breaker. The method of claim 1,
The vibration generating unit 200 includes a vibration generating unit 200 and a vibration generating unit 200. The vibration generating unit 200 includes a vibration generating unit 200, (700);
Further comprising: a shock absorbing vibration breaker. The method of claim 1,
The vibration generating part 200 is formed at an upper edge thereof with an inclined surface 210 to which the vibration damping part 500 closely contacts and the vibration damping part 500 is a vibration damping rubber provided so as to be inclined to correspond to the inclined surface 210 Shock absorber vibration breaker. 3. The method of claim 2,
Wherein the friction supporting part (600) is made of a vibration proof rubber. 4. The method of claim 3,
The lower link (400) and the upper link (700)
Characterized in that it is a hydraulic cylinder type. 4. The method of claim 3,
The lower link (400) and the upper link (700)
A cylinder body (11);
A piston (22) slidably coupled to the interior of the cylinder body (11);
A first elastic body 33 installed inside the cylinder body 11 to elastically support the piston 22 in one direction; And
A second elastic body (44) installed inside the cylinder body (11) and elastically supporting the piston (22) in the other direction;
Wherein the shock absorbing vibration breaker comprises: 8. The method according to any one of claims 1 to 7,
A teeth 310 having a circular cross-section fastening portion and replaceably coupled to a lower end of the nipper blade 300;
Wherein the shock absorbing vibration breaker comprises:

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