KR100878296B1 - Nipper - Google Patents

Abstract

A vibration nipper is provided to prevent the vibration generated from a vibration generator for vibrating a nipper blade from being transferred to a boom or a vehicle body and to prevent the breaking of equipment when a nipper blade is applied with bending moment and turning moment. A vibration nipper includes a main body(13) having a vibration space and a joint(12) to couple with a fixed bracket of a boom or heavy equipment, a housing(21) located in the vibration space of the main body and attached with a vibrator(30), a plurality of support devices(50) supported to two sides of the housing and the main body corresponded to the two sides of the housing to support the housing to vibrate against the main body, a nipper blade(100) installed to the housing and extended downward, and a vibration-proof device installed to the main body on the upper part of the vibration space to disperse vibration when the housing collides with the main body by the ascent of the housing.

Description

Vibration nippers

The present invention relates to a vibrating nipper, and more particularly, to a vibrating nipper having improved vibration and support structure of a nipper unit installed in heavy equipment.

In general, excavators used in civil engineering and construction sites for highways, harbors, bridges, dams, buildings, urban development, etc. are the process of compacting, crushing, excavating, etc. Severe noise is generated from the

In particular, in order to scrape the soil, such as rock, concrete structures, solid ground or scraping the soil of the excavator is used to install a breaker or nipper unit in the boom of the excavator, the vibration generated from the breaker or nipper unit is transmitted directly to the boom. These vibrations generate noise, which is amplified and doubled in the course of delivery to the boom.

In view of this point, Korean Laid-Open Patent Publication No. 2006-0033893 discloses an excavator nipper.

The disclosed excavator nipper is connected to the boom of the excavator fixedly mounted, rotatably mounted to the connection mount, a blade body for excavating soil of the ground, and is mounted on the blade body, the blade body Vibration means for providing power.

In the disclosed excavator nipper, the blade main body is rotatably mounted to the boom of the excavator, and the vibration means is installed in the blade main body so that the vibration is transmitted to the boom through the blade main body. As such, the vibration transmitted to the boom is amplified to make the adjustment of the excavator difficult, and further, the excavator is damaged.

An object of the present invention is to provide a vibration nipper that can prevent the vibration generated from the vibration generating means for vibrating the nipper blade to be transmitted to the boom or the vehicle body.

Another object of the present invention is to provide a vibrating nipper which can prevent damage to the equipment when the bending moment and the rotation moment are applied to the nipper blade.

Another object of the present invention is to provide a vibrating nipper that can increase the frictional support force due to the vibration of the vibrator with respect to the body and the housing during the action of the bending moment and the rotation moment.

Vibration nipper of the present invention for achieving the above object,

A main body having a vibration space portion and a coupling portion for coupling with a fixed bracket of a boom or heavy equipment on an upper side thereof;

A vibration unit located in the vibration space of the main body and having a vibrator installed therein, a plurality of supporting means supported on both sides of the vibration unit and a corresponding body to vibrately support the vibration unit with respect to the main body;

A nipper blade installed in the vibration unit and extending downward;

It is characterized in that it is provided in the upper body of the vibration space portion includes a dust-proof means for dispersing the vibration in the collision of the housing and the main body by the rise of the housing.

In the present invention, the housing for supporting the nipper blade oscillating with respect to the main body further includes a plurality of friction support means for supporting the housing with respect to the main body when the bending moment and the rotation moment act.

The friction support means includes a first member having a friction surface, a second member installed on a side corresponding to the friction surface of the first member, a friction member supported by the second member and having a lubricating oil storage space, and It is characterized in that it comprises an elastic member for wrapping and supporting the first and second members. The apparatus may further include lubricating oil supply means installed on at least one side of the first member or the second member to supply lubricating oil to the lubricating oil storage space.

The friction support means includes guide rollers installed on both sides of the body corresponding to the housing, and guide rails installed on both sides of the housing corresponding to the guide roller and in contact with the rollers to guide the rollers.

 The anti-vibration means is formed with the inclined portion on the corresponding both sides of the housing and the shock absorbing member is installed in the body corresponding to the inclined portion in the body of the vibration space corresponding to this.

When the vibration nipper of the present invention is mounted on the arm of heavy equipment, that is, an excavator, payloader, etc., the boom or the browser, the vibration generated from the vibration nipper can be minimized and the rotation or bending of the nipper blade is performed. When the moment is acting can increase the support force of the housing to the body, it is possible to prevent the damage of the dust-proof rubber which is a support means for supporting the housing against the body.

 Vibrating nippers according to the present invention is to be installed on the arm or booms such as excavators, bulldozers and payloaders used for civil engineering and construction, etc. to excavate or break concrete, asphalt and soft ground, etc. An example is shown in FIGS.

Referring to the drawings, the vibrating nipper 10 has a vibrating space portion 11 and a main body 13 having a coupling portion 12 for engaging with the boom 200 or the arm of heavy equipment on the upper side, and the vibrating space Vibration unit 20 is located in the vibration unit 20, the vibration unit 20, the vibration unit 20 is supported on both sides of the housing 21 of the vibration unit 20 and the corresponding body 13 corresponding to the vibration unit 20 It is provided with a plurality of support means 40 for supporting the vibration. In addition, the nipper braid 100 installed downward in the housing 21 and the upper main body 13 of the vibration space 11 are installed to raise the vibration unit 20 so that the housing 21 and the main body ( 13 when the bending moment and the rotation moment are applied to the dustproof means 70 for dispersing the vibration in the collision with the 13 and the housing 21 supporting the nipper braid 100 vibrating with respect to the main body 13. And a plurality of friction support means (50) for supporting the housing (21).

The vibration nipper unit 10 according to the present invention configured as described above will be described in more detail for each component as follows.

The fixing bracket 12 formed on the upper portion of the main body 13 of the vibrating nipper unit 10 is for fixing to the boom 200 or the arm of the heavy equipment, a plurality of coupling holes for pin coupling with the boom 200 12a are formed. And vibrating space portion formed in the main body 12

11 is formed by extending the first and second support portions 14 and 15 to both sides from the base portion 13a of the fixing bracket 12 is installed, the lower side is the nipper blade 100 is drawn out downward Is opened to help. And the front and rear sides formed by the first and second support parts 14 and 15 are formed with support frames 16, respectively, as shown in FIG. 3 to support the front and rear portions of the vibration space part 11. It is desirable to be able to. The main body is not limited to the above-described embodiment and may be any structure as long as the vibration unit 20 provided with the nipper blade 100 can vibrate smoothly.

The support means 40 suspends the vibration unit 20 in the vibration space portion 11 of the body 13 so that the vibration unit 20 can be smoothly supported, and the first support portion 14 of the body and Anti-vibration members 41, 42, 43, 44 supported between one side surface of the housing 21 of the vibration unit 20 and between the second support portion 15 and the other side surface of the housing 21 corresponding to the vibration unit 20. ). The anti-vibration members 41-44 are provided at both ends thereof with supporting plates 45 for fixing to the side surfaces of the housing 21 or the first and second support parts 14 and 15, respectively. Here, the vibration isolator 41-44 may be made of a rubber material, but is not limited thereto, and any structure may be used as long as it can elastically support the vibration unit. For example, it may be made of a coil spring, a link, and the like, in the case of the link, a cushioning member may be installed at a portion to be hinged to absorb a distance difference between the main body and the housing according to the rotation of the link.

11 to 12 show another embodiment of the dustproof member.

Referring to the drawings, the anti-vibration member 46 of the support means is provided with a support plate 47 for fixing the anti-vibration member on both sides, the anti-vibration rubber 48a and the support plate 48b between the support plate 47. ) Is provided with a dustproof part 48 which is alternately installed. The support plate 48b may be formed with irregularities in order to increase the coupling force with the anti-vibration rubber.

The vibration unit 20 is suspended in the main body 13 to vibrate, the vibrator 30 is installed in the housing 21, and the nipper blade 100 is installed in the housing 21 and protrudes below the vibration space portion It is provided.

As shown in FIGS. 4 to 7, the vibrator 30 includes a pair of rotation shafts 31 and 32 installed on the housing 21 and drive gears 33 installed on the respective rotation shafts and engaged with each other. 34, eccentric weight members 35 and 36 respectively installed on the rotary shafts 31 and 32, and a hydraulic motor 37 installed on the housing 21 to drive the rotary shaft 31 on one side. ). The eccentric weights 35 and 36 are eccentric weights 35 and 36 which are rotated by being formed in the same direction as the eccentricity with respect to the axis of rotation so that vibration can be generated in the up and down direction during rotation, as shown in FIGS. 5 to 7. 6 is preferably overlapped between the rotational shafts 31 and 32, as shown in FIG.

The vibrator 30 is not limited to the above-described embodiment and may be any structure as long as it can vibrate the nipper blade 100 of the vibration unit in the vertical direction.

The friction support means 50 is to support the housing with respect to the main body 13 when the bending moment and the rotation moment of the nipper braid 100 oscillating with respect to the main body 13 to the housing 21. Examples are shown in FIGS. 2 and 8.

Referring to the drawings, the friction support means 50 are installed between the first support portion 14 and the housing 21 and between the second support portion 15 and the housing 21, each having a friction surface 51. The first member 52, the second member 53 is provided on the side corresponding to the friction surface of the first member 52, and the second member 53 is supported by the lubricant storage space 54a The branch is provided with a friction member 54 and an elastic member 55 to surround and support the first and second members 52 and 53. Here, the first member 52 may include a first fixing part 52a fixed to the first support part or the second support part, and the second member may include a housing or a housing corresponding to the first support part 14. A second fixing part 53a fixed to the housing corresponding to the second supporting part 15 may be provided. The fixing of the friction member 54 with respect to the first member 52 is a support protrusion 56 is formed stepwise at the end of the first member 52, the support protrusion 56 of the friction member 55 It is made by inserting into the hollow part 54b.

Further, at least one side of the first member 52 and the second member 53 is further provided with lubricating oil supply means 57 for supplying lubricating oil to the lubricating oil storage space 54a. The lubricant oil supply means passes through the elastic member and communicates with the space between the lubricating oil storage space, that is, the first and second members 52 and 53, in the first member 52 or the second member 53. 57a and a grease nipple 57b provided at the inlet side of the passage part 57a.

On the other hand, Figure 8 shows another embodiment of the friction support means according to the present invention.

Referring to the drawings, the friction support means 60 may include guide parts 61 installed on both sides of the vibration unit 20, that is, the housing 21 corresponding to the first and second support parts 14 and 15. And the first and second support parts 14 and 15 are respectively installed in contact with the guide part 61 of the housing 21 when the rotation and bending moments are applied to the vibration unit 20. The support roller 62 is provided. The support roller 62 is rotatably supported by a bracket 63 installed on the first support 14 or the second support 15. Here, the support roller 62 is preferably rubber coated on the outer circumferential surface so as to reduce the impact when in contact with the guide portion 61.

Meanwhile, as shown in FIG. 3, the support frame 16 positioned at the front side and the support frame positioned at the housing and the rear side by connecting the first and second support portions 14 and 15 of the main body 13 are not shown. Auxiliary friction support means 80 is installed between the and the housing 21 to guide the vibration in the front and rear direction of the housing 21. The auxiliary friction support means 80 is substantially the same as the friction support means will not be described again.

In addition, the vibration isolator 70 is a vibration of the vibration unit 20 when the housing 21 of the vibration unit 20 is in contact with the upper body of the vibration space portion 11 when excavation by the vibration or the niper blade of the vibration unit 20 It can be prevented from being delivered to the boom 100 or the arm side, and the inclined portions 71 and 72 are formed at both upper edge portions of the housing 21, and both side edges of the main body 13 corresponding thereto. The dustproof members 73 and 74 are formed in the portion. As illustrated in FIG. 13, the dustproof member 70 of the dustproof means may be inclined at the corners at the front, rear, left, and right sides of the upper side of the housing.

 The dustproof members 73 and 74 may be made of rubber or synthetic resin. Here, the vibration isolator 70 is not limited to the above-described embodiment and may be any structure as long as it can disperse the vibration acting in the upward direction so as not to act vertically.

Referring to the operation of the movable nipper according to the present invention configured as described above are as follows.

       The vibration nipper according to the present invention minimizes the noise during the work by performing the crushing and excavation work of concrete, asphalt, soft rock, and wind rock having higher strength than general soil in civil engineering, building construction site, and demolition site, and vibration is boom or It can be prevented from being delivered to the arm.

That is, in the state where the vibration nipper 10 according to the present invention is mounted on the boom 100 of the excavator

When the hydraulic motor 37 of the vibrator 30 is driven, the rotary shafts 31 and 32 are rotated and the eccentric weights 35 and 36 installed therein are rotated to generate vibrations. Eccentric direction of the (36) is formed in the radial direction corresponding to the axis of rotation, so that it is located between the axis of rotation (31, 32) in the process of being rotated or located on the corresponding outside of the axis of rotation (31, 32) (See FIGS. 5 and 6) Accordingly, the main vibration direction of the vibration unit, that is, the housing 21 and the nipper plate 100 connected thereto is made up and down.

In this process, the housing 21 of the vibration unit 20 is suspended by the dustproof member 41-44 of the support means 40, that is, the dustproof member 41-44 made of a rubber material having elastic force. It will not be interfered with by vibration in the direction. In particular, when the housing 21 of the vibration unit 20 oscillating in the vertical direction is raised and collides with the main body 13, the vibration force is connected to the main body 13 because the impact force due to the collision is dispersed by the dustproof means 70. It can be prevented from being delivered directly to the boom. The dustproof member 70 is provided with inclined portions 71 and 72 at both corners of the housing 21, and is dustproof at the corners of the upper main body 13 of the vibration space 11 of the main body corresponding thereto. Since the members 73 and 74 are provided, the inclined portions 71 and 72 of the rising housing 21 collide with the dustproof members 73 and 74, and the impact force is dispersed. That is, the impact force in the collision with the dustproof member 74 having the inclined surface corresponding to the inclined portions 71 and 72 formed in the housing 21 is generated in the normal direction with respect to the vertical direction and the inclined surface, The main impact force by this acts substantially in the normal direction to prevent the impact from being transmitted directly to the boom.

  On the other hand, in the process of excavating or crushing concrete, asphalt, soft ground, etc. by the housing of the vibration unit 20, that is, the nipper blade 10, the bending or rotation moment acts on the nipper blade 10, wherein Both sides of the housing 21 may support the housing with respect to the first and second support parts 14 and 15 without affecting the vibration of the housing 21 by the friction support means 50. That is, as shown in FIGS. 10 and 10, the first member 52 and the second member 53 of the friction support means 50 are supported by the housing and the first or second member 14, 15, respectively. Since the friction member 54 supported by the second member 53 is in contact with the friction surface of the first member 52, the friction surface 51 and the friction member 54 are in sliding contact with the vibration of the housing. The housing can be supported without being indirectly received.

In addition, the support frames 16 and 17 installed on the main body 13 are provided with auxiliary friction support means 80 for guiding vibration in the front and rear directions to support the housing in the front and rear directions.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

The vibrating nipper unit of the present invention can prevent the vibration from being transmitted to the boom or the arm during the excavation or the shredding operation by the nipper blade, so it can be widely used in heavy equipment for civil engineering and construction.

1 is a perspective view of a vibration nipper according to the present invention,

2 is an exploded perspective view of the vibration nipper according to the present invention;

Figure 3 is an exploded perspective view showing another embodiment of the vibration nipper according to the present invention,

4 is a perspective view schematically showing a varactor,

5 to 7 is a view showing an operating state of the vibrator according to the present invention,

8 is a cross-sectional view showing an excerpt of the support means;

Figure 9 is an exploded perspective view showing another embodiment of the vibration nipper according to the present invention.

10 is a side view showing an operating state of the vibration nipper according to the present invention,

Figure 11 is an exploded perspective view showing another embodiment of the vibration nipper according to the present invention,

12 is a partial ablation perspective view showing the dustproof member of the support means,

Figure 13 is a cross-sectional view showing another embodiment of a vibration nipper according to the present invention.

Claims (7)

A main body having a vibration space and an engaging portion for coupling with a fixed bracket of a boom or heavy equipment on an upper side thereof; A housing located in the vibration space of the main body and having a vibrator installed therein, a plurality of supporting means supported on both sides of the housing and a corresponding main body to support the main body in a vibrating manner; A nipper blade installed in the housing and extending downward; Vibration nippers, characterized in that provided in the upper body of the vibration space and the dust-proof means for dispersing the vibration in the collision of the housing and the main body by the rise of the housing.  The method of claim 1, And a plurality of friction support means for supporting the housing with respect to the main body when the bending moment and the rotation moment are applied to the housing for supporting the nipper blade vibrating with respect to the main body. The method of claim 2, The friction support means includes a first member having a friction surface, a second member installed on a side corresponding to the friction surface of the first member, a friction member supported by the second member and having a lubricating oil storage space, and An oscillating nipper, characterized by comprising an elastic member for wrapping and supporting the first and second members. The method of claim 3, wherein Vibrating nippers, characterized in that it is provided on at least one side of the first member or the second member further comprises a lubricating oil supply means for supplying lubricating oil to the lubricating oil storage space. The method of claim 1, The vibration isolator vibrating nippers characterized in that the shock absorbing member is formed on the corresponding both sides of the housing to the inclined portion corresponding to the inclined portion in the main body inside the vibration space corresponding thereto. The method of claim 1, The support means is a vibration nipper characterized in that it comprises a support plate spaced apart a predetermined interval, and the dust-proof unit is installed between the dust-proof rubber and the support plate between the support plate. The method of claim 1, And a support frame installed on the main body so as to correspond to the front and rear surfaces of the housing, and auxiliary friction support means installed on the housing and the support member to prevent the housing from swinging with respect to the main body.

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