KR101966828B1 - Anti-vibration structure having enclosed deformation space and vibration ripper having the same - Google Patents

Abstract

The present invention provides an anti-vibration structure and a vibration ripper having the same which can improve impact-absorbing effects. The anti-vibration structure comprises: a base having a fixed shape; an impact-absorbing unit having a preset length, made of a stretchable material to allow one side thereof to be laminated on one surface of the base, and having a sealed deformation space formed therein in a longitudinal direction; and a cover separated from the base, coupled to the other side of the impact-absorbing unit, and sealing the deformation space. If the separation distance between the base and the cover is decreased by an external force, the internal pressure of the deformation space increases, and a side of the impact-absorbing unit expands in the longitudinal direction by elasticity to expand the circumference of the impact-absorbing unit and increase the cross sectional thickness of the impact-absorbing unit by compression. In the absence of a load, the pressure in the deformation space decreases by a restoring force, and the side is reduced to be restored to a tension state to absorb an impact between the cover and the base.

Description

TECHNICAL FIELD [0001] The present invention relates to an anti-vibration structure using a closed deformation space and an anti-vibration structure having an enclosed deformation space and a vibration ripper having the same.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an anti-vibration structure using a closed deformation space and a vibration ripper having the same. More particularly, the present invention relates to a vibration deformation preventive structure using a closed deformation space Structure and a vibration ripper having the same.

Vibration models have been proposed and put into practical use in various forms such as construction machines, excavators, vibration rippers, compaction machines, and the like.

By using vibration in a construction machine, an excavator hydraulic breaker, a vibration ripper, etc., it is possible to perform the operation relatively easily. However, since the vibration is transmitted from the vibration source to the boom belt or the body, problems may occur in the equipment itself.

For solving such a problem, a metal spring, an air spring, a vibration proof rubber, a shock absorber, or the like is used as a vibration-proof unit for preventing transmission of vibration from a vibration source to the equipment.

In particular, a vibrating body used in a vibration ripper or a compaction machine supports the vibrating body and prevents the vibration generated from the vibrating body from being transmitted to a boom or a vibrating body supporting the vibrating body.

Japanese Unexamined Patent Publication (Kokai) No. 4-119238 discloses an anti-vibration device made of rubber. The anti-vibration device of the rubber has a structure in which the entire upper surface of the body is covered with a metal fitting, A plurality of protrusions of a predetermined size are protruded and large and small cylinders protrude from the upper surface of the rubber body in contact with the metal fittings.

Korean Patent No. 10-0331934 discloses a vibration mechanism using a magnetic spring, and Korean Patent No. 0161564 discloses a hydraulic breaker shock absorber.

As described above, the conventional vibration damping device and shock absorber are configured to simply damp vibration by using rubber, spring, air shovel, or the like.

However, in such a conventional shock absorber, when the compression load is generated, there is a limit of shrinkage depending on the structure, and the permissible frequency itself is also limited.

Particularly, in the case of the air shaw bar, the shrinkable distance itself is very limited because it is basically formed in the form of a cylinder, and there is a problem that it is damaged by the rapid vibration due to the structural characteristic.

In addition, in the case of a shock absorber having a shape such as a rubber or a spring, fatigue failure easily occurs when a compressive load continuously acts, and the buffer effect itself is relatively inferior.

Therefore, a method for solving such problems is required.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art. And a vibration ripper having the vibration damper structure.

The problems of the present invention are not limited to the above-mentioned problems, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a dustproof structure using a closed deformation space, the dustproof structure including a base having a fixed shape and a stretchable material having a predetermined length, one side of which is laminated on one side of the base, And a cover that is spaced apart from the base and is coupled to the other side of the shock absorber unit and hermetically seals the deformable space, wherein the shock absorber unit is fixed to the base and the cover The inner pressure of the deformation space is increased and the side surface along the longitudinal direction is expanded by the elasticity to enlarge the circumference and the sectional thickness of the buffer unit is increased by the compression, The pressure inside the deformation space is reduced and the side surface is reduced and restored to the tensile state, And buffering between the bases.

The shock absorbing unit may be made of a stretchable rubber material. The shock absorbing unit may include a vibration preventing part formed in the longitudinal direction of the deforming space and a fixed shape. The supporting part may be coupled to the other side of the vibration preventing part, . ≪ / RTI >

In addition, the dustproof portion may be coupled to the base and the support portion on both sides in the longitudinal direction, and the engagement region to be compressed when the gap between the base and the cover is reduced, and the gap between the base and the cover, And may include an expanded region where the perimeter expands and expands.

The dustproof portion may include a plurality of elastic members having a predetermined length and disposed along the longitudinal direction, and at least one intermediate plate provided between the elastic members for mutually coupling and forming the deformation space together with the elastic member, .

Further, the dust-proofing portion may be characterized in that the elastic member and the intermediate plate are integrally formed.

The buffer unit may be integrally formed in a state of being in contact with the base.

The gas hole may be formed in at least one of the base and the cover so as to communicate with the inside of the deformation space and selectively allow gas to be introduced into and discharged from the deformation space.

According to another aspect of the present invention, there is provided a vibration ripper comprising: a ripper main body coupled to a spring; a vibration generating module provided inside the ripper main body to selectively generate vibrations; And a dustproof structure provided between the vibration generating module and the inner surface of the ripper main body to buffer vibration, wherein the shock absorbing unit is fixed to the base and the cover by an external force, The inner pressure of the deformation space is increased and the side surface along the longitudinal direction is expanded by the elasticity to enlarge the circumference and the sectional thickness of the buffer unit is increased by the compression, The pressure inside the deformation space is reduced and the side is reduced and restored to the tensile state, And buffering between the bases.

The vibration damping structure may include a base having a fixed shape, a shock absorbing unit having a predetermined length, one side of which is laminated on one surface of the base, And a cover spaced apart from the base and coupled to the other side of the buffer unit to seal the deformation space.

The vibration damping structure using the closed deformation space of the present invention and the vibration ripper having the vibration damping structure according to the present invention for solving the above problems have the following effects.

First, when a compressive load acts along the longitudinal direction by forming a closed deformation space in the buffering unit of the rubber material, a part of the circumference is expanded by the pressure increase in the deformation space, and the overall length is contracted to increase the buffer effect There is an advantage that can be made.

Second, when the compression load is removed, the buffer unit is restored to a predetermined length along the longitudinal direction by the pressure of the deformation space, and the pressure inside the deformation space is reduced, thereby providing additional restoring force This has the advantage of being able to be used continuously.

Thirdly, since the shock absorber is divided into a plurality of elastic members along the longitudinal direction, it is advantageous in that it can prevent expansion concentration concentration on the side surface in the action of the compressive load and can expand uniformly by increasing the durability.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 schematically shows a configuration of a vibration ripper according to an embodiment of the present invention; FIG.
FIG. 2 is a view showing the internal structure of the vibration ripper of FIG. 1; FIG.
3 is a side cross-sectional view showing the internal configuration of the vibration ripper of FIG. 1;
Fig. 4 is a view showing the structure of the anti-vibration structure in the vibration ripper of Fig. 1 (exploded perspective view)
5 is an internal cross-sectional view showing the configuration of the anti-vibration structure of FIG. 4;
6 is a view showing a state in which the dustproof portion is constituted by one elastic member in the dustproof structure of FIG. 4; And
Fig. 7 is a view showing a state in which the anti-vibration structure of Fig. 1 shrinks and expands; Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

The vibration damping structure according to the present invention and the vibration ripper having the vibration damping structure according to the present invention are devices installed in spring for performing excavation, crushing and compaction through vibration, minimizing the transmission of vibration to spring or other equipment Lt; / RTI >

Hereinafter, the present invention will be described with reference to a vibration ripper having a dustproof structure using a closed deformation space.

First, a vibration ripper according to the present invention will be described with reference to FIGS. 1 to 5 as follows.

FIG. 1 is a view schematically showing the construction of a vibration ripper according to an embodiment of the present invention, FIG. 2 is a view showing the internal structure of the vibration ripper of FIG. 1, Fig.

FIG. 4 is a view showing the construction of the anti-vibration structure in the vibration ripper of FIG. 1, and FIG. 5 is an internal sectional view showing the construction of the anti-vibration structure of FIG.

The vibration ripper according to the present invention is mounted on a spring of an excavator to perform an operation and includes a ripper main body 100, a vibration generating module 200 for generating vibration in the ripper main body 100, And a damper structure 400 installed between the vibration generating module 200 and the ripper main body 100. The damper structure 400 includes a vibration damper 300,

The ripper main body 100 is formed in a case shape including a vibration generating module 200 and a dustproof structure 400 to be described later and has a connection bracket 110 connected to the boom at one side thereof.

Specifically, a separate space is formed in the interior of the ripper main body 100 to provide the vibration generating module 200, and a lower portion thereof is opened to expose a part of the ripper blade 300 to the outside.

At this time, the ripper blade 300 is long and one side is coupled with the vibration generating module 200 to be described later, and vibrates together to perform the operation.

The shape of the ripper main body 100 may be variously formed. In this embodiment, the bottom of the ripper main body 100 is open. However, the ripper main body 100 may have various shapes.

Meanwhile, the vibration generating module 200 is configured to generate vibration in the inside of the ripper main body 100, and the ripper blade 300, which will be described later, is fixed to the lower portion and vibrates together.

Specifically, the vibration generating module 200 according to the present invention has a housing 210, and a plurality of eccentric rotators 220 are provided therein, and up and down vibrations are generated through rotation thereof.

Here, it is preferable that a plurality of the eccentric rotating bodies 220 are arranged in the same direction so as to maximize the vertical vibration generated by the rotation of the eccentric rotating body 220.

In this embodiment, the eccentric rotation body 220 is provided with a pair of parallel rotation shafts, and gears that are mutually engaged with the rotation shafts are provided.

In addition, at least one motor may be connected to the housing 210 to rotate the eccentric rotation body 220 through the rotation axis.

Such a configuration is disclosed in Patent Registration No. 0878296 filed and registered by the present invention.

The vibration generating module 200 configured as described above is not limited to the above embodiment, and the eccentric rotation body 220 may be arranged in a vertical direction rather than a horizontal state.

Meanwhile, the ripper blade 300 protrudes downward from the ripper main body 100 and vibrates and vibrates the ground by the vibration generating module 200.

Specifically, the ripple blade 300 is long and one side of the ripple blade 300 is at least partially disposed inside the ripper main body 100 and is coupled to the vibration generating module 200.

Here, when the other end of the ripper blade 300 is in contact with the ground and performs crushing and excavating operations, the ripper blade 300 can receive the vibration generated in the vibration generating module 200 and vibrate together to smoothly perform the operation.

At this time, as shown in the figure, one side of the ripper blade 300 is coupled to the vibration generating module 200 and is configured to vibrate together.

The vibration damping structure 400 according to the present invention is provided between the vibration generating module 200 and the inner surface of the ripper main body 100 to damp vibrations generated in the vibration generating module 200.

3, the dustproof structure 400 is formed to be long along the vertical direction, and both ends thereof are connected to the vibration generating module 200 and the ripper main body 100, respectively, The vibration of the vibration generating module 200 is buffered.

Here, the dust-proof structure 400 is formed long, and at least a part of the dust-proof structure 400 is made of a rubber material and has elasticity, and a deformation space 440 sealed in the longitudinal direction is formed therein.

Here, the deformation space 440 is structured such that the size of the deformation space 440 is maintained while being blocked from the outside.

If a compressive load acts on the anti-vibration structure 400 along the longitudinal direction, the inner space is compressed while maintaining the deformation space 440, thereby increasing the inner pressure. Accordingly, This expansion expands the circumference.

Accordingly, the dustproof structure 400 is shrunk in its entire length to buffer vibrations between the ripper main body 100 and the vibration generating module 200.

In other words, in the vibration-proof structure 400, as the size of the deformation space 440 is maintained, a part of the area expands due to a contraction or expansion of a part of the circumference at the time of expansion.

Accordingly, the anti-vibration structure 400 can have a relatively larger shrinkage range than the general elastic material or cylinder shape, thereby increasing the buffering effect and controlling the expansion length along the longitudinal direction to a certain level or less.

The specific structure and principle of the anti-vibration structure 400 according to the present invention will be described later.

The vibration ripper according to the present invention includes the above-described ripper main body 100, the vibration generating module 200, the ripper blade 300, and the dustproof structure 400, The vibration can be effectively buffered by the dustproof structure 400.

In addition, the vibration ripper according to the present invention may include a support unit 500 for vibratably supporting the ripper main body 100 to the housing 210 of the vibration generating module 200 or the ripper blade 300 .

Specifically, the support unit 500 is configured to indirectly connect the vibration generating module 200 or the ripper blade 300 on the ripper main body 100, and the ripper main body 100 So that the vibration can be transmitted to and supported by the support member.

2, the support unit 500 includes at least one support link 510 having both ends thereof rotatably mounted to the ripper main body 100 and the vibration generating module 200. As shown in FIG. When the support links 510 are formed of two or more pieces, it is preferable that the support links 510 are installed parallel to each other.

The support link 510 supports the ripper main body 100 without being detached from the housing 210, and is supported so as to be oscillatable within a predetermined range.

As described above, the vibration ripper according to the present invention is constructed so that vibration of the vibration generating module 200 is prevented from being transmitted to the ripper main body 100 by the vibration insulating structure 400, It is possible to prevent the user from increasing more than a predetermined level.

The construction and effect of the dustproof structure 400 according to the present invention will be described in detail with reference to FIGS. 4 and 5. FIG.

As described above, the anti-vibration structure 400 according to the present invention is provided with both ends between the ripper main body 100 and the vibration generating module 200, so that the vibration is buffered so that the load on the ripper main body 100 and spring Thereby reducing occurrence.

The dustproof structure 400 mainly includes a base 410, a buffer unit 420, and a cover 430.

The base 410 has a configuration fixed to support the buffer unit 420 and is integrally formed with the buffer unit 420 described later.

Specifically, the base 410 may be formed of metal, synthetic resin, or the like, and is formed in a flat plate shape.

In this embodiment, the base 410 is formed in the shape of a circular metal plate, and the buffer unit 420 is provided on one side and the other side is fixedly coupled to the inner surface of the ripper main body 100.

Meanwhile, the buffer unit 420 has a predetermined length, and one side of the buffer unit 420 is stacked on one side of the base 410 to be stretchable by an external force.

A separate deformation space 440 is formed at the center along the longitudinal direction and is fixedly coupled to the base 410.

Specifically, the buffer unit 420 is made of a material having elasticity along at least a part along the longitudinal direction, and contracts and expands along the longitudinal direction, so that a buffering effect is generated between the vibration generating module 200 and the ripper main body 100 .

In the present invention, the shock absorber unit 420 mainly includes a dustproof portion 422 and a support portion 424.

The vibration-proofing portion 422 is made of rubber, which is an elastic material, and is formed in a columnar shape along the longitudinal direction. The vibration-proofing portion 422 is configured to be capable of contraction and expansion by itself. The deformation space 440, .

When the dustproof portion 422 is pressed along the longitudinal direction, a part of the side surface expands, and at the same time, the overall length decreases.

At this time, the deformation space 440 formed inside the dustproof portion 422 is sealed and is cut off from the outside, and only its shape is deformed.

In this case, when the compressive load is applied along the longitudinal direction of the dustproof portion 422, the distance between the opposite end portions decreases, but the internal pressure of the deformation space 440 increases, Lt; / RTI >

Accordingly, the vibration-proofing portion 422 can expand the part of the rubber material, thereby reducing the overall length of the vibration-proofing portion 422 and buffering the vibration generated by the vibration-generating module 200 from being transmitted to the ripper main body 100 .

Here, the expression of the overall length of the dustproof portion 422 does not mean the length of the dustproof portion 422 itself, but refers to a straight line distance between both end portions along the length direction.

The support portion 424 is provided at the other end of the dustproof portion 422 so that the cover 430 to be described later can be coupled to seal the deformation space 440 and has a fixed shape And is integrally coupled with the dustproof portion 422. [

The support portion 424 has a hole formed at the center thereof corresponding to the deformation space 440 to allow the deformation space 440 to communicate with the outside.

In the present embodiment, the support portion 424 is made of a metallic material and has a donut-shaped plate shape and is coupled to the dustproof portion 422.

The supporting portion 424 is integrally formed together with the vibration-proofing portion 422 so that a hole is formed in the supporting portion 424 so that the deformation space 440 is communicated with the outside.

The base 410 and the support portion 424 may be provided at the time of forming the vibration prevention portion 422 so that the base 410 and the support portion 424 are integrally formed Lt; / RTI >

Here, the dustproof portion 422 is formed through a separate mold, and in order to form the deformation space 440 at the time of molding, the shape of the mold must also be formed to correspond thereto.

A hole is formed in the supporting portion 424 so that the deforming space 440 can be formed together when the vibration-proofing portion 422 is formed, and the hole is formed in the inside of the mold.

Alternatively, the anti-vibration part 422 may be integrally formed with the support part 424 of the base 410, but may be separately secured by various methods such as press or bolt tightening.

However, as in the present invention, the base 410 and the support portion 424 are integrally joined when the dustproof portion 422 is molded, thereby stably maintaining the coupled state and at the same time, I can do it.

As described above, the shock absorber 420 according to the present invention includes the dustproof portion 422 and the support portion 424, and the deformation space 440 having a penetration shape along the longitudinal direction is formed therein.

At this time, the dustproof portion 422 is composed of a plurality of elastic members having predetermined lengths and is formed continuously along the longitudinal direction, and a separate intermediate plate 426 is provided on each of the plurality of elastic members.

Specifically, the anti-vibration unit 422 may be formed of a single elastic member, and may be coupled to the base 410 and the support unit 424 at both ends thereof. However, when the length of the anti-vibration unit 422 is excessive If it is lengthened, expansion may concentrate in some area, which may cause breakage.

Therefore, as shown in the present embodiment, the dustproof portion 422 is divided into a plurality of elastic members, and the intermediate plate 426 is provided on each of the elastic members 422, so that when the pressure acts on the dustproof portion 422 And the peripheries are expanded and expanded independently in each of the monofilament members.

That is, the dustproof portion 422 is divided into a plurality of elastic members by the intermediate plate 426, whereby each of the elastic members is independently inflatable, so that the dustproof portion 422 is inflated And can be evenly dispersed.

In this embodiment, the intermediate plate 426 has a ring shape in the form of a metal plate and is interconnected between the elastic members.

Preferably, the intermediate plate 426 is integrally formed with the elastic member when the vibration-proofing portion 422 is molded. Accordingly, the vibration-proofing portion 422 is divided into a plurality of elastic members It is possible to prevent excessive expansion in a specific region at the same time.

As described above, the shock absorber 420 according to the present invention includes the vibration-proof part 422 made of a rubber material and the support part 424 provided on the other side of the vibration-proof part 422. When the compressive load acts on the vibration- The pressure inside the deformation space 440 increases.

At the same time as the pressure in the deformation space 440 increases, at least a part of the side surface of the dustproof portion 422 expands and compresses along the longitudinal direction by a compression load acting in the longitudinal direction.

Meanwhile, the cover 430 is detachably coupled to the other side of the shock absorber 420 and seals the deformation space 440.

The cover 430 is formed in the shape of a metal plate and is disposed on the other side of the buffer unit 420 so as to be spaced apart from the base 410. The cover 430 is fastened to the support unit 424 provided on the buffer unit 420, do.

At this time, the cover 430 has one surface relatively larger than the hole formed in the support portion 424, and is coupled to the other side of the buffer unit 420 through various methods such as bolt welding.

The cover 430 may have a separate seal (not shown) so that the fluid may not be introduced into the deformation space 440 when the cover 430 is coupled with the support portion 424.

The cover 430 is coupled with the support portion 424 to seal the deformation space 440 so that the gas inside the deformation space 440 maintains the internal space of the buffer unit 420 when it is deformed .

As described above, the dustproof structure 400 according to the present invention is constituted, and the base 410 and the cover 430 are installed at different installation targets, and mutual spacing distances are deformed by vibration, The vibration can be buffered by the vibration isolator 420.

In this embodiment, the base 410 is fixedly coupled to the inner surface of the ripper main body 100, and the cover 430 is fixedly coupled to the vibration generating module 200, The vibration generated by the module 200 can be buffered in the buffer unit 420. [

The cover 430 may be installed between the vibration generating module 200 and the inner surface of the ripper main body 100 when installed in the inside of the ripper main body 100, A mounting bracket 432 may be further provided.

The mounting bracket 432 is made of metal or synthetic resin and extends along the longitudinal direction of the shock absorbing unit 420 so that the distance between the vibration absorbing module 200 and the ripper main body 100 is reduced, Even if they are disposed longer than the length of the second housing 400.

As described above, the anti-vibration structure 400 according to the present invention can receive a compressive load through the elastic member made of rubber and the anti-vibration portion 422 having the intermediate plate 426, and the deformation space 440, The vibration generated in the vibration generating module 200 can be buffered.

More specifically, the vibration-proofing structure 400 maintains the deformation space 440 when no load is applied due to the deformation space 440 hermetically sealed therein, so that the buffer unit 420 itself maintains the predetermined length, And when the vibration is compressed by the vibration, the dustproof portion 422 expands along the circumference by the air inside the deformation space 440, and the length of the dustproof portion 422 expands to decrease the length and receive the compressive load.

On the other hand, in comparison with conventional air showers and cylinders, in the case of air springs, the problem of exceeding the tensile limit occurs when a gas layer is added to the inside.

However, according to the present invention, even if a gas is injected into the deformation space 440 at a high pressure, the shape change is limited due to the characteristics of the rubber.

Further, even when compared with a conventional anti-vibration rubber, it is not simply compressed when a compressive load is applied, but a compression and an expansion are deformed at the same time as the deformation space 440 is maintained. The buffering effect can be maximized.

Particularly, since the inside of the deformation space 440 is in a hermetically sealed state, the dustproof portion 422 itself is evenly expanded evenly along the longitudinal direction of the dustproof structure 400 of the present invention, It is possible to prevent concentration.

In addition, the dustproof structure 400 according to the present invention is configured such that the dustproof portion 422 is made of a rubber material, so that the dustproof structure 422 can perform a buffering action with a relatively large frequency and a relatively large vibration frequency.

In the case of a typical air shoe bar, it is constituted by a mesh-like material around it and has a frequency of about 9 Hz and is configured to buffer vibration. However, in the case of the present invention, it is composed of a rubber material and can be applied to frequencies up to 200 Hz.

As a result, it has a wider application range than conventional airshow bars and can have a superior buffering effect compared with simple anti-vibration rubber.

That is, since the dust-proof structure 400 according to the present invention includes the deformation space 440 that is sealed inside the dust-proof portion 422 of the rubber material, the vibration range of the relatively large frequency is higher than that of the air- Not only the range of application is expanded but also the dustproof effect can be increased by contracting easily corresponding to the compression load.

As described above, in the vibration-proof structure 400 according to the present invention, the gas is filled in the deformation space 440, and when the compressive load along the longitudinal direction acts, the side surface expands as the internal pressure increases, .

In addition, in the dustproof structure 400 according to the present invention, at least one of the cover 430 and the base 410 is provided with a gas hole 402 for injecting gas into the deformation space 440 , The gas inside the deformation space 440 may be selectively injected or discharged to adjust the internal pressure.

In the present embodiment, the gas hole 402 is formed on the base 410, but may alternatively be provided on the cover 430.

Accordingly, the initial pressure inside the deformation space 440 can be easily adjusted according to the user's use to adjust the buffering degree.

6 and 7, a specific operation of the dustproof structure 400 according to the present invention will now be described.

6 is a view showing a state in which the dustproof portion 422 is composed of one elastic member in the dustproof structure 400 of FIG. 3, FIG. 7 is a view showing a state of shrinking and expanding the dustproof structure 400 of FIG. 3 to be.

Referring to the drawings, the vibration-proofing structure 400 according to the present invention is a modification of the vibration-damping structure 400 according to the present invention, in which the vibration-proofing portion 422 is made of one elastic member, and both ends thereof are connected to the base 410, They are integrally joined.

The cover 430 is coupled to the support portion 424 to seal the deformation space 440.

Here, the dustproof portion 422 is formed in a cylindrical shape with a rubber material as described above, and the deformation space 440 having a penetration shape along the longitudinal direction is formed.

At this time, the dustproof portion 422 is divided into a coupling region A1 and an extended region A2 along the longitudinal direction.

Specifically, the coupling region A1 is located at both ends of the dust-proof portion 422 along the longitudinal direction and is joined to the base 410 and the support portion 424, (A2). ≪ / RTI >

The extension region A2 is not simply compressed by the deformation space 440 when the interval between the base 410 and the cover 430 is reduced between the engagement regions A1, Expand to the side and expand.

At this time, as shown in the drawing, when the vibration-proofing part 422 is compressed, the vibration-proofing part 422 made of a rubber material has the deformation space 440 therein, do.

As a matter of course, when the gas is filled in the deformation space 440 and the external force acts, the internal pressure increases and the force acts uniformly in the external direction.

Accordingly, the coupling region A1 is partially expanded and expanded to the outside, but is relatively less extended because it is adjacent to the base 410 and the support portion 424.

When the compressive load acts on the vibration-proofing portion 422 along the longitudinal direction, the internal pressure of the deformation space 440 increases and the internal pressure becomes relatively larger than the elastic force of the rubber material, .

7A shows a state in which a compressive load acts along the longitudinal direction of the vibration insulating structure 400 according to the present invention. The distance between the base 410 and the support 424 The distance is L1.

In this case, the inside of the deformation space 440 is sealed and filled with gas, and accordingly the internal pressure is increased by the action of the compressive load.

Accordingly, a relatively larger pressure acts on the vibration-proofing portion 422 than the elasticity of the rubber, so that the side surface expands and the circumference is expanded.

At this time, the degree of expansion may be adjusted depending on the thickness of the dustproof portion 422, the characteristics of the rubber, or the pressure inside the deformation space 440, which can be adjusted by the user depending on the application.

Here, the side wall of the dustproof portion 422 expands, and at the same time, a pressure acts on the compressive load acting along the longitudinal direction due to its own restoring force.

That is, when a compressive load acts on the vibration-proofing portion 422, the compressive load is buffered as the internal pressure of the deformation space 440 increases, and at the same time, the compressive load .

Since the deformation space 440 sealed inside the dustproof portion 422 according to the present invention is formed by merely the elasticity of the dustproof portion 422 or the structure of the deformation space 440 in the form of the air chamber, The elasticity of the vibration-proof part 422 itself can be used together with the elasticity of the vibration-proof part 422 to buffer the tensile load.

In particular, when the dustproof portion 422 is made of rubber as in the present embodiment, vibrations can be actively buffered against vibration in a high frequency region (0 to 200 Hz) and a small compression load, and a large compression load and low frequency Can be buffered through the pressure change of the deformation space 440. [

Accordingly, when a compressive load is applied to the vibration-proofing portion 422, the rubber, which is an elastic body, compresses and inflates at the same time to differentiate the load, and can also be used in high frequency vibration through the characteristics of rubber.

In addition, in the present invention, when the compressive load acting on the dustproof portion 422 is very large, the inner pressure of the deformation space 440 increases and the thickness of the dustproof portion 422 increases. Specifically, when the dustproof portion 422 is compressed, the dust is protruded outward as the pressure of the deformation space 440 increases, but the pressure applied to the dustproof portion 422 increases, If the pressure inside the space 440 is larger than the pressure increase, the dustproof portion 422 itself expands in the width direction.

Accordingly, when the compressive load acting on the dust-proofing portion 422 is higher than a certain level, the dust-proofing portion 422 itself is compressed to increase the cross-sectional thickness, And some penetrate into the deformation space 440.

At this time, the volume of the deformation space 440 decreases and the internal pressure increases, but it is maintained at a level corresponding to the thickness expansion due to the compression of the vibration-proof portion 422 itself.

If the compressive load acts on the dustproof portion 422, the circumference of the dustproof portion 422 itself is enlarged by a pressure increase of the deformation space 440 at a certain level, but the thickness of the dustproof portion 422 itself is maintained. The cross-sectional thickness of the dust-proof portion 422 is increased and partially expanded into the deformation space 440.

7B, when the compression load acting on the anti-vibration structure 400 is released, the anti-vibration unit 422 is pulled by the elasticity of the anti-vibration unit 422, (424) is restored to L2.

At this time, the internal pressure of the deformation space 440 in the dustproof part 422 also decreases, and provides the restoring force so that the dustproof part 422 can be pulled to the initial set length.

That is, when the compressive load acts on the anti-vibration part 422, the pressure inside the deformation space 440 increases and the side surface can expand. When the acting load is removed, the internal pressure decreases, Tension is applied so as to have an initial set length in addition to the restoring force of the material.

Here, the dustproof portion 422 expands along the longitudinal direction in the process of reducing the pressure inside the deformation space 440 to P0, which is the initial state, and the dustproof portion 422 is not expanded beyond a certain level due to its own elasticity .

Accordingly, even if the restoring force of the anti-vibration unit 422 is reduced, the pressure inside the deformation space 440 can be reduced by the elasticity of the anti-vibration unit 422, As it returns to P0, it expands and assists in restoring the dustproof portion 422. [

The dustproof structure 400 according to the present invention includes the base 410, the cover 430 and the shock absorber 420 and the enclosed deformed space 440 inside the shock absorber 420, So that vibration and vibration can be effectively buffered.

In this embodiment, the vibration-proof structure 400 is applied to a vibration ripper. Alternatively, the vibration-absorbing structure 400 may be applied to various facilities by changing the pressure inside the deformation space 440 or deforming the rubber material of the vibration- can do.

It will be apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is obvious to them. Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100: Ripper main body
200: vibration generating module
210: Housing
220: Eccentric rotation body
300: Ripper blade
400: anti-vibration structure
410: Base
420: dustproof unit
422:
424: Support
426: intermediate plate
430: cover
440: Variation space
500: support unit

Claims (8)

A base 410 having a fixed shape;
A dustproof portion 422 having a predetermined length as a stretchable material and passing through the center along the longitudinal direction and having one side integrally joined with the base 410 and formed with a deformation space 440 opened to the other side, And a support part (424) integrally formed on the other side of the dustproof part (422) in a fixed plate shape and having a hole formed at the center so that the deformation space (440) communicates with the outside. And
A cover 430 which is spaced apart from the base 410 and is coupled to the support portion 424 at the other side of the buffer unit 420 to seal the deformation space 440; / RTI >
The vibration preventing portion 422 is disposed in a state in which the base 410 is disposed on one side and the support portion 424 is disposed on the other side so that the deforming space 440 can be molded together in a separate mold at the time of molding And is integrally combined with the base 410 and the support portion 424,
When the distance between the base 410 and the cover 430 is reduced due to an external force, the buffer unit 420 increases the internal pressure of the deformation space 440, The sectional area of the buffer unit 420 is increased by compression and the pressure inside the deformation space 440 is reduced due to the restoring force when no load is applied and the side is reduced and restored to the tensile state, (430) and the base (410). delete The method according to claim 1,
The anti-vibration portion 422,
A coupling region that is engaged with the base 410 and the support portion 424 on both sides along the longitudinal direction and is compressed when the interval between the base 410 and the cover 430 is reduced; And
An enlarged region in which a circumference is expanded and expanded when an interval between the base 410 and the cover 430 is reduced between the coupling regions;
. The method according to claim 1,
The anti-vibration portion 422,
A plurality of elastic members having a predetermined length, arranged along the longitudinal direction,
And at least one intermediate plate (426) is provided between the elastic members and coupled to each other to form the deformation space (440) together with the elastic member. 5. The method of claim 4,
The anti-vibration portion 422,
Wherein the elastic member and the intermediate plate (426) are integrally formed. The method according to claim 1,
A gas hole 402 is formed in at least one of the base 410 and the cover 430 so as to communicate with the inside of the deformation space 440 to selectively introduce and discharge gas into the deformation space 440 Wherein the vibration damping structure is formed in a substantially rectangular shape. A ripper main body 100 coupled with the spring;
A vibration generating module 200 provided inside the ripper main body 100 and selectively driven to generate vibration;
A ripper blade 300 connected to the vibration generating module 200 to vibrate together to break and excavate the ground; And
A dustproof structure provided between the vibration generating module 200 and the inner surface of the ripper main body 100 to buffer vibrations; / RTI >
The dust-
A base 410 having a fixed shape;
A dustproof portion 422 having a predetermined length as a stretchable material and passing through the center along the longitudinal direction and having one side integrally joined with the base 410 and formed with a deformation space 440 opened to the other side, And a support part (424) integrally formed on the other side of the dustproof part (422) in a fixed plate shape and having a hole formed at the center so that the deformation space (440) communicates with the outside. And
A cover 430 which is spaced apart from the base 410 and is coupled to the support portion 424 at the other side of the buffer unit 420 to seal the deformation space 440; / RTI >
The vibration preventing portion 422 is disposed in a state in which the base 410 is disposed on one side and the support portion 424 is disposed on the other side so that the deforming space 440 can be molded together in a separate mold at the time of molding And is integrally combined with the base 410 and the support portion 424,
When the distance between the base 410 and the cover 430 is reduced due to an external force, the buffer unit 420 increases the internal pressure of the deformation space 440, The cross-sectional thickness of the cushioning unit 420 is increased by the compression, the pressure inside the deformation space 440 is reduced by the restoring force when no load is applied, the side is reduced and is restored to the tensile state, (430) and the base (410).
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