KR101935522B1 - Oscillation buffer structure - Google Patents

Abstract

The present invention relates to a vibration damping type structure and, more specifically, to a vibration damping type structure, which can compensate for elasticity generated from a support structure and stress in accordance with the elasticity when a support is installed and enables a buffering function for buffering impacts even when the impacts are generated from the outside.

Description

[0001] OSCILLATION BUFFER STRUCTURE [0002]

The present invention relates to a vibration-damping structure.

More specifically, the present invention relates to a vibration-damping structure capable of compensating for stress caused by elasticity and elasticity generated in the strut structure and capable of absorbing shock even when an external shock is generated .

Generally, road facilities such as fences, median separators, reflectors, street lights, traffic lights, guide boards, and bollards all have a holding structure.

Particularly, the bollard and the fence having the above-mentioned holding structure are installed at the entrance of a sidewalk, a park, a playground or the like partitioned so that the pedestrian can pass, thereby preventing the entrance of the vehicle and securing the passage and safety of the pedestrian , And is usually installed through a cylindrical or prismatic column (column).

However, the conventional bollard or fence is buried in the ground through a single column-shaped column structure and easily collapsed due to a large impact force like a collision of a vehicle, or when a pedestrian can not confirm whether the pedestrian is installed or not , Injuries to pedestrians, and the like.

In order to solve such a conventional problem, there has been disclosed a bollard to which a column structure that is elastically operated so as to be able to be restored to its original position by absorbing an external impact force by using a spring.

However, the conventional column structure using such a spring has a disadvantage in that the spring is externally exposed, or the connection portion of the spring is fixed by welding or the like, so that the corrosion easily occurs. This causes problems such as shock and injury to the vehicle and pedestrian due to repetitive flow caused by the elastic force during the restoration operation by the spring.

As a technique for solving this problem, Japanese Patent Application Laid-Open No. 10-1035152 discloses a shock absorber for a column structure.

The present invention relates to a shock absorber for a column structure, which is constructed between an upper main pipe and a lower main pipe and absorbs an external impact force on the upper main pipe,

An upper plate fixed to a lower end of the upper main pipe; A lower plate fixed to an upper end of the lower main pipe; Spring means comprising a plurality of springs connected between the upper and lower plates; Elastic adjusting means installed on the lower plate to support the upper plate with respect to the lower plate and adjust the elastic force of the spring means by setting a distance between the upper plate and the lower plate according to the amount of fastening to the lower plate; And a cover formed to surround the outer circumferential surface of the connection portion between the upper and lower main pipes.

As another technique, Japanese Patent Application Laid-Open No. 10-1793200 discloses a guard rail supporting force reinforcing structure having a buffer structure.

The present invention relates to a guard rail supporting force reinforcing structure having a buffer structure and has a buffer structure that is coupled to a guard rail strut which is installed at regular intervals along the road side of the road to reinforce the supporting force of the strut and mitigate the impact A guiding structure for a supporting rail for supporting a guard rail, comprising: a reinforcing plate having a plate thickness of a predetermined thickness; a guiding groove coinciding with a cross-sectional size of the prism and having a predetermined length so as to sandwich the prism at one end of the reinforcing plate; And at least one buffer stage formed by an elliptical through-hole formed at a predetermined interval on the reinforcing plate on which the additional reinforcing plate is placed.

As another technique, a regulator for a road signboard support is disclosed in Registration Practical Utility Model No. 20-0220490.

The present invention relates to a shock absorber of a guide panel provided on the side of a road, in which a shock absorber is mounted on a fastening portion at the lower end of a large or small display panel support to reduce damage caused by an external impact.

The guide plate 1 is vertically arranged so that the flanges of the lower end of the guide plate 1 and the flanges of the anchors 2 embedded in the bases are aligned and the flanges are fastened to the axle bolts 3 by a plurality of bolts, The spring 4 is screwed into the threaded hole 6 of the anchor through the fastening hole 5 of the column so as to press the flange of the column to press the spring of the column.

However, the above-described techniques have a structural difference from the invention proposed by the present applicant.

On the other hand, as another technique for reducing the impact of the support by using the spring, Japanese Patent Application Laid-Open No. 10-1170330 discloses a guard rail for a center separator provided with a shock absorbing structure for shock absorption.

In the above technique, members for shock absorption or dispersion are inserted into the joints of the pillars fixedly mounted on both sides of the pillars and the pillars, so that the members effectively absorb or disperse the impact force even when a vehicle or a heavy object collides The present invention relates to a guardrail for a center separator having a shock absorbing structure for shock absorption,

And a cushioning bracket inserted between the rail and the rail. The cushioning bracket has a rail joint surface to be fastened to the rail at both ends of the cushioning bracket, A bracket body formed by bending a cross section in a " C " shape inward to form a column joint surface having the same shape as the outer surface of the column and having a slot formed in the column joint surface; And a supporting member having an elongated hole formed at one end of the supporting member and a supporting member at the other end of the supporting member, The support members of the buffer brackets respectively fastened to the opposite direction are overlapped with each other at the outer surface of the support, and are fastened with one fastening bolt passing through the support through a slot formed in the support member and a bolt hole formed in the support member, And a cushioning member is inserted and disposed on both sides of the support between the rail joint surfaces which are respectively fixed to both sides of the support.

Although the technique has similarities with respect to the purpose of reducing the vibration of the strut using a spring, the structural form and its effect will be different.

Patent Registration No. 10-1035152 (issued on May 17, 2011) Registered Patent Publication No. 10-1793200 (Announcement of November 2, 2017) Registration Practical Utility Model No. 20-0220490 (issued on April 16, 2001) Patent Registration No. 10-1170330 (published on August 1, 2012)

It is an object of the present invention to provide a vibration damping structure capable of compensating for stress caused by elasticity and elasticity generated in the strut structure and capable of buffering a shock even when an external shock is generated, .

In order to achieve the above object, a vibration-damping structure according to the present invention comprises concrete (1) serving as a base to be buried or exposed on the ground,

A plurality of first holes 21 are formed on one side of the concrete 1 so that the bolts 11 protruding from the upper surface of the concrete 1 are inserted into the concrete 1, (2)

The support base 31 is formed on the upper side of the cushion pad 2 and has a plurality of second holes 32 formed on one side thereof and is inserted into the bolt 11 through the second hole 32 (3) to be joined,

By further including the plate 1a between the concrete 1 and the cushioning pad 2, it is possible to facilitate the horizontal holding at the time of construction and prevent the cushioning pad 2 and the concrete 1 from being separated, .

At this time, a nut 111 is fastened to the bolt 11 penetrating to the second hole 32 of the support base 31 so that the joint of the concrete 1, the buffer pad 2, And,

And the upper side of the nut 111 is fastened by the bolt cap 113 to finish.

A buffer plate 112 is inserted into the first hole 21 of the buffer pad 2 to allow the bolt 11 to pass therethrough.

Further, the buffer plate 112 may be formed,

And a spring 1122 coupled to the body 1121 and the body 1121,

The body 1121 may be,

A helical groove 11211 formed to have a size larger than that of the spring 1122 or larger than the spring 1122 is concavely formed to be engaged with the spring 1122,

A bolt hole 11212 through which the bolt 11 passes is formed,

And the material thereof is a porous compressed plastic which is compressed by using a porous foamed synthetic resin.

According to the vibration-damping structure of the present invention,

It is possible to compensate for the stress due to the elasticity and elasticity generated in the support structure and to provide the buffering function for mitigating the impact even when an external impact is generated.

1 shows the structure of a vibration-damping structure according to the present invention.
1A shows a structure of a vibration-damping structure according to another embodiment of the present invention.
2 is a cross-sectional view illustrating a coupling structure of a vibration-damping structure according to the present invention.
3 shows the structure of the buffer plate in the vibration-damping structure according to the present invention.
FIG. 4 shows a vibration damping structure inside a strut in the vibration damping structure according to the present invention.
5 shows a vibration damping structure inside a strut in a vibration damping structure according to another embodiment of the present invention.
FIG. 6 illustrates a decomposition structure of a damper in a vibration damping structure inside a strut in a vibration damping structure according to the present invention.
FIG. 7 illustrates the operation of the damper in the vibration damping structure inside the strut in the vibration damping structure according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor can properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents And variations are possible.

Before describing the present invention with reference to the accompanying drawings, it should be noted that the present invention is not described or specifically described with respect to a known configuration that can be easily added by a person skilled in the art, Let the sound be revealed.

The present invention relates to a vibration-damping structure.

More specifically, the present invention relates to a vibration-damping structure capable of compensating for stress caused by elasticity and elasticity generated in the strut structure and capable of absorbing shock even when an external shock is generated .

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described with reference to FIG. 1 of the accompanying drawings.

1 shows the structure of a vibration-damping structure according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification,

A plurality of first holes 21 are formed on one side of the concrete 1 so that the bolts 11 protruding from the upper surface of the concrete 1 are inserted into the concrete 1, (2)

The support base 31 is formed on the upper side of the cushion pad 2 and has a plurality of second holes 32 formed on one side thereof and is inserted into the bolt 11 through the second hole 32 And a strut 3 to be joined.

However, by further including the plate 1a between the concrete 1 and the cushioning pad 2, it is possible to facilitate horizontal maintenance during construction and to separate the cushioning pad 2 and the concrete 1, It is possible to prevent corrosion.

At this time, since the plate 1a is formed as a set with the bolts 11, it is possible to easily adjust the height of the bolts or the like when the concrete is embedded.

1A, a through hole having a predetermined diameter is formed in the plate 1a, and the elastic member 1c is passed through the through hole, and the elastic member 1c is provided on the lower side of the elastic member 1c By inserting the fixed pipe 1b, the effect of vibration reduction transmitted to the support can be improved.

1A shows a structure of a vibration-damping structure according to another embodiment of the present invention.

In this case, the plate 1a, the fixed pipe 1b, and the elastic member 1c may be installed, and the concrete 1 may be embodied.

More specifically, FIG. 2 of the accompanying drawings can be referred to.

2 is a cross-sectional view illustrating a coupling structure of a vibration-damping structure according to the present invention.

2 of the accompanying drawings shows a sectional structure in which the bolts 11 are inserted and joined to the concrete base 1, the cushioning pad 2 and the support base 31 of the column 3, respectively.

The nut 111 is fastened to the bolt 11 penetrating to the second hole 32 of the support base 31 so that the coupling of the concrete 1, the buffer pad 2, .

The nut 111 may include a washer on the lower side, wherein the washer can be prevented from unwinding through a swash washer or a pp washer, and can be effective for vibration damping.

The diameter of the first hole 21 of the buffer pad 2 is larger than that of the hole formed in the concrete 1 or the strut 3 so that the buffer plate 112 is inserted.

One side of the buffer plate 112 is formed with a hole penetrating in the upward and downward directions so that the bolt 11 is passed therethrough.

Further, the upper part of the upper side of the nut 111 is fastened by the bolt cap 113 to be finished.

According to the design conditions, the bolt cap 113 is configured such that the lower end of the bolt cap 113 touches the upper surface of the support base 31, the lower end of the bolt cap 113 extends in the form of a wing, A frictional member for increasing frictional force is formed on the lower surface of the lower end of the front end and a plurality of projections are formed on the lower surface of the lower end of the frictional member for increasing frictional force, It may have the effect of confidentiality.

The structure of the buffer plate 112 described above will be described with reference to FIG. 3 of the accompanying drawings.

3 shows the structure of the buffer plate in the vibration-damping structure according to the present invention.

The buffer plate 112 includes a body 1121 and a spring 1122 coupled to the body 1121.

For this, a helical groove 11211, which is the same size as the spring 1122 or slightly larger than the spring 1122, is formed in the body 1121, and a spring 1122 is inserted into the helical groove 11211, ≪ / RTI >

On the other hand, the region where the helical groove 11211 starts on the uppermost surface of the body 1121 can be easily coupled to the spring 1122 by opening the upper direction.

A bolt hole 11212 penetrating the bolt 11 in the upward and downward directions and through which the bolt 11 can pass may be formed in the body 1121.

At this time, the body 1121 of the buffer plate 112 can be made of a porous compressed plastic compressed by using porous foamed synthetic resin, and the spring 1122 uses a steel spring.

Accordingly, when an impact or vibration is applied to the support, the body 1121 primarily emits vibration or the like to the outside by the porous structure, and the spring 1122 reduces the vibration or the like, thereby performing the buffering function .

In addition, the cushioning pad 2 described above can be made of EPDM, NR, BR, CR, NBR, SNR, or the like to increase the elasticity or buffering function.

On the other hand, according to other design conditions, an extension made of the same material as the spring 1122 is formed to be bent and extended to the center of the spring 1122 at the end of the spring 1122, Can be configured to have the form " '".

The spiral groove 11211 of the body 1121 includes a groove into which the extension portion can be inserted at one side where the spiral groove 11211 starts. The upper surface of the body 1121, on which the groove is formed, Can be configured to be an opening that is smaller than the widest area of the end portion '∇'. The length of the groove may be formed by the length of the extended portion and the end of the extended portion.

Accordingly, when the extension portion is inserted into the groove, it is possible to prevent the extension portion from being depressed by the shape of the end portion when the external force is forcibly inserted by applying a predetermined external force.

Further, the inner wall of the groove can be coated with a film of a flexible material such as silicon.

And a bundle of wire rods which are twisted by twisting a thin iron core into the inside of the groove.

According to this structure, when the extension portion and the end portion of the extension portion are introduced into the groove, the end portion of the extension portion is inserted into the bundle of barbs due to the load of the spring 1122 while the end portion of the extension portion is adjacent to the bar- The ends of the bundle and the extension part are bundled together and the bundle of ribs is organically operated with the silicon formed on the inner wall of the groove to enhance the frictional force and finally fix the spring 1122 securely while the spring 1122 spirals It is possible to have an elastic force against the upward / downward movement generated in the state of being coupled to the groove 11211, so that it can be effective for mitigating vibration or impact.

Further, the inside of the column 3 may further include a vibration damping structure.

This will be described with reference to FIG. 4 of the accompanying drawings.

FIG. 4 shows a vibration damping structure inside a strut in the vibration damping structure according to the present invention.

A vibration damping structure is constituted inside the strut 3 according to Fig. 4 of the accompanying drawings,

A fixed blade 3a having a wing shape extending in all directions;

A fixed angle (3b) for fixing the fixed blade (3a) to the inner wall of the strut (3);

A column 3c extending downward through the fixed blade 3a and formed with threads on the outer surface thereof;

An upper nut 3d coupled to the upper end of the column 3c;

A through-hole 3e formed from the upper side of the upper nut 3d to the lower side of the fixed blade 3a and formed on the outer surface of the pillar 3c;

A damper 3g having a shape suspended from the lower end of the column 3c and having upper and lower sides fixed through a nut; And

And a cushion 3f inserted into one side of the upper surface of the damper 3g and fixed through the column 3c.

With this structure, the vibration or shock generated in the column 3 can be expected to be attenuated or buffered inside the column 3, and depending on the design conditions, It can be composed of two or more.

5 shows a vibration damping structure inside a strut in a vibration damping structure according to another embodiment of the present invention.

Thereby, there is an advantage that durability is provided even with greater impact or vibration.

6, the upper side of the damper cylinder 3ga is closed by the upper plate 3gb, the lower side is closed by the lower plate 3gc, the insertion plate 3gd is inserted into the damper 3g, .

In addition, the insertion spring S may be inserted upward and downward with respect to the insertion plate 3gd to improve the effect of shock reduction or vibration reduction.

FIG. 6 illustrates a decomposition structure of a damper in a vibration damping structure inside a strut in a vibration damping structure according to the present invention.

As described above, the damper 3g is fixed by nuts on the upper and lower sides as described above, so that the height of the damper 3g can be adjusted by adjusting the nut in the upward and downward directions as shown in FIG.

Accordingly, not only the vibration buffering effect can be enhanced, but also the damper 3g, which has been moved downward by gravity or vibration, can be moved upward again.

FIG. 7 illustrates the operation of the damper in the vibration damping structure inside the strut in the vibration damping structure according to the present invention.

It is apparent that the present invention is not limited to the configuration of the drawings, as described above with reference to the drawings, only the main points of the present invention are described, and various designs can be made within the technical scope thereof.

1: Concrete
1a: plate
1b: Fixed pipe
1c: elastic member
11: Bolt
111: Nut
112: buffer plate
1121: Body
11211: Spiral groove
11212: Bolt hole
1122: Spring
113: Bolt cap
2: buffer pad
21: 1st hole
3: Holding
31: holding base
32: second hole
3a: Fixed blade
3b: Fixed Angle
3c: Column
3d: upper nut
3e: through spring
3f: Cushion
3g: Damper
3ga: damper bucket
3gb: top plate
3gc: bottom plate
3gd: Insertion plate
S: Insertion spring

Claims (4)

A concrete (1) serving as a foundation formed to be buried or exposed on the ground,
A plurality of first holes 21 are formed on one side of the concrete 1 so that the bolts 11 protruding from the upper surface of the concrete 1 are inserted into the concrete 1, (2)
The support base 31 is formed on the upper side of the cushion pad 2 and has a plurality of second holes 32 formed on one side thereof and is inserted into the bolt 11 through the second hole 32 (3) to be joined,
By further including the plate 1a between the concrete 1 and the cushioning pad 2, it is possible to facilitate the horizontal holding at the time of construction and prevent the cushioning pad 2 and the concrete 1 from being separated, In the vibration-damping structure,
The nut 111 is fastened to the bolt 11 penetrating to the second hole 32 of the support base 31 so that the coupling of the concrete 1, the buffer pad 2, And,
The upper side of the nut 111 is fastened by the bolt cap 113,
The buffer plate 112 is inserted into the first hole 21 of the buffer pad 2 to penetrate the bolt 11,
The buffer plate (112)
And a spring (1122) coupled to the body (1121) and the body (1121)
The body 1121 may be,
A helical groove 11211 formed to have a size larger than that of the spring 1122 or larger than the spring 1122 is concavely formed to be engaged with the spring 1122,
A bolt hole 11212 through which the bolt 11 passes is formed,
The material is a porous compression plastic which is compressed using a porous foamed synthetic resin,
An extension made of the same material as the spring 1122 is bent and extended to the center of the spring 1122 at the end of the spring 1122 so that the end of the extension 1122 has a shape of ' ,
The body 1121 includes a groove through which the extension portion can be inserted at one side where the helical groove 11211 starts, and the upper surface of the body 1121, on which the groove is formed, Is formed to be an open groove smaller than the widest area of the " V " shape,
The inner wall of the groove is coated with a silicon material and the end portion of the extended portion and the extended portion are introduced into the groove by including a bundle of the bundled ribs formed by twisting a thin iron core into the groove, The ends of the extended portions are inserted into the bundles of the ribs due to the load of the spring 1122 while the ends of the bundles are adjacent to each other. The elasticity of the spring 1122 against the upward / downward movement generated in a state where the spring 1122 is engaged with the spiral groove 11211 is obtained while firmly fixing the spring 1122 while improving the frictional force, Or a shock-absorbing effect is imparted to the vibration-absorbing structure. delete delete delete

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