KR101606721B1 - Hybrid Vibration Isolation Structure for Easy Maintenance and Construction Method Thereof - Google Patents

Abstract

According to the present invention, there is provided a composite vibration damping structure embedded in the ground, comprising: a main body 100 formed with a hollow portion 200; And a vibration insulating material (300) mounted on the main body (100) and reducing the vibration transmitted to the main body (100), and a maintenance method therefor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a vibration isolation structure,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a construction field, and more particularly, to a composite vibration damping structure buried in the ground for reduction of ground vibration generated due to a traffic load such as railway vibration or road vibration.

Vibration generated by the operation of trains or cars spreads around the railroad or around the roads. Therefore, in the case of factories and power plant facilities that are sensitive to the influence of vibrations, they have to be built out of the influence of vibrations, resulting in a problem that the space utilization on the site and the facility arrangement efficiency are degraded.

Also, in the case of a general building, if it is built within the influence of vibration, long-term stability degradation due to vibration load, long-term durability degradation of pipeline connection, cracking problem and leakage problem may occur.

In order to solve the above-mentioned problems, various structures of dustproof structures buried in the ground have been devised.

Referring to FIG. 1, various conventional underground buried and dustproof structures can be grasped. 1 (a)), a crush pile for reflecting and refracting vibration is installed in the ground (FIG. 1 (b)), or a rigid member such as concrete is placed in the ground (Fig. 1 (c)), or a method of reducing the vibration by inserting a soft filler such as a waste tire to form a dustproof structure.

However, due to the characteristics of the anti-vibration structure, due to continuous vibration, deformation of the structure due to earth pressure, groundwater exposure, freezing in winter, etc., durability and deterioration due to property change occur. However, due to the characteristics of the anti-vibration structure buried in the ground, it has been difficult to perform maintenance.

In addition, since the vibration-damping mechanism of the installed vibration-damping structure depends on the primary vibration reduction of the member itself, a problem that the vibration-damping performance is not sufficient has also been raised. Therefore, it is necessary to develop dual composite dustproof structure to ensure sufficient dustproof performance.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the conventional anti-vibration structure, and it is an object of the present invention to maximize the site utilization by reducing the ground vibration generated and propagated from a vibration source such as a railway or a road, And a method of constructing the same.

Another object of the present invention is to provide a composite dustproof structure and a method of constructing the dustproof structure, which facilitates the maintenance and maintenance of the dustproof structure buried in the ground so as to maintain the performance of the dustproof structure.

Another object of the present invention is to provide a composite vibration damping structure capable of maximizing the vibration damping effect by adding a separate vibration insulation material as well as a primary vibration reduction of the vibration damping structure itself and a maintenance method thereof.

It is a further object of the present invention to provide a vibration damping structure that minimizes propagation of ground vibration by using a composite vibration damping structure maximizing vibration damping performance to ensure long-term durability of the facility, And a method of constructing the same.

According to an aspect of the present invention, there is provided a composite vibration damping structure embedded in the ground, comprising: a main body 100 having a hollow portion 200 formed therein; And a vibration insulating material (300) mounted on the main body (100) and reducing the vibration transmitted to the main body (100).

The main body 100 is formed by a plurality of precast segments 100a and 100b and the vibration insulating material 300 is bonded to the contact portions 110 of the plurality of precast segments 100a and 100b The dustproof structure can be a maintenance-resistant composite dustproof structure.

The vibration insulating member 300 may further include an insertion port 400 through which the vibration insulating member 300 is inserted.

The vibration insulating member 300 may include an elastic member 310; And a coupling member 320 for coupling the elastic member 310 to the main body 100. As shown in FIG.

The vibration insulating material 300 may include a first coupling member 320 coupled to the precast segment 100a of any one of the plurality of precast segments 100a and 100b; A second engagement member 330 coupled to the other precast segment 100b; And an elastic member 310 having one end coupled to the first engagement member 320 and the other end coupled to the second engagement member 330, A contact member 331 coupled with the member 310; And a clearance member (332) forming a clearance space between the precast segment (300b) and the contact member (331) coupled with the second engagement member (330) It may be a composite dustproof structure.

The insertion port 400 includes an insertion space 410 into which the vibration insulating material 300 is inserted; And a depressed space 420 formed below the first coupling member 320. [0034] The present invention is not limited to the above embodiments and various changes and modifications may be made without departing from the scope of the present invention.

The insertion port 400 is formed with an opening toward the hollow part 200 so that the inserted vibration insulating material 300 can be exposed to the hollow part 200. [ Structure.

The insertion port 400 is formed with an opening toward the outside of the hollow portion 400 and the main body 100 and an insertion port cap for closing the opening formed toward the outside of the main body 100 And it can be a maintenance-compatible composite dust-proof structure.

A through hole 340 is formed in the first coupling member 320 and the second coupling member 330 and the vibration insulating member 300 is inserted into the coupling bolt 350 And is installed in the main body 100 by means of a vacuum cleaner (not shown).

The pre-cast segments 100a and 100b are formed in a " C "shape, and the insertion port 400 is formed only in the precast segment 100a to which the first engagement member 320 is coupled Which can be maintenance-resistant.

According to another aspect of the present invention, there is provided a method of constructing a maintenance-resistant composite anti-vibration structure, comprising: a first step (S100) of excavating underground to form a digging section (1); A second step S200 of forming a main body 100 formed with a plurality of precast segments 100a and 100b on the excavation part 1 and having a hollow part 200 formed therein; A third step (S300) of mounting a vibration insulating material (300) for reducing vibration transmitted to the main body (100) to a contact portion (110) of the plurality of precast segments (100a, 100b); And a fourth step (S400) of backing up the excavation part (1) so that the main body (100) is buried in the ground (S400).

The fourth step S400 is a step of back filling the excavation part 1 so that the hollow part 200 can be connected to the ground in a state where the main body 100 is buried in the ground A method of constructing a maintenance-resistant composite anti-vibration structure.

In addition, the main body 100 may be provided with an insertion port 400 through which the vibration insulating material 300 is inserted and installed.

The vibration insulating material 300 may include a first coupling member 320 coupled to the precast segment 100a of any one of the plurality of precast segments 100a and 100b; A second engagement member 330 coupled to the other precast segment 100b; And an elastic member 310 having one end coupled to the first engagement member 320 and the other end coupled to the second engagement member 330, A contact member 331 coupled with the member 310; And a clearance member (332) forming a clearance space between the precast segment (300b) and the contact member (331) coupled with the second engagement member (330) It may be a method of constructing a composite dustproof structure.

The insertion port 400 includes an insertion space 410 into which the vibration insulating material 300 is inserted; And a recessed space (420) formed below the first coupling member (320). [5] The method of claim 1,

The insertion port 400 is formed with an opening toward the hollow part 200 so that the inserted vibration insulating material 300 can be exposed to the hollow part 200. [ Lt; RTI ID = 0.0 > structure. ≪ / RTI >

A through hole 340 is formed in the first coupling member 320 and the second coupling member 330 and the vibration insulating member 300 is inserted into the coupling bolt 350 The dust collecting structure may be installed in the main body 100 by means of a vacuum pump or the like.

According to another aspect of the present invention, there is provided a method of maintaining the composite vibration damping structure of claim 16, comprising: dismantling the coupling bolt (350); The vibrating insulator 300 may be formed by using a clearance space between the recessed space 420 exposed through the opening and the precast segment 300b formed by the clearance member 332 and the contact member 331. [ Compressing the vibration insulating material to be compressed; A step of discharging the vibration insulating material 300 which discharges the vibration insulating material 300 compressed in the vibration insulating material compressing step from the insertion space 410; Inserting the vibration insulating material (300) into the insertion space (410) by compressing the new vibration insulating material (300); A vibration isolation material decompression step of decompressing the vibration insulation material 300 inserted into the insertion space 410 at the step of inserting the vibration insulation material 300; And a vibration insulating material attaching step of attaching the vibration insulating material (300) decompressed in the vibration insulating material decompressing step to the main body (100) using the coupling bolt (350) There is a way to maintain the structure

According to the present invention, it is possible to maximize site utilization and reduce flexibility of facility layout change by reducing ground vibration generated and propagated in a vibration source such as a railway or a road.

According to the present invention, it is possible to facilitate the maintenance of the vibration-damping structure buried in the ground, and to maintain the performance of the vibration-damping structure.

According to the present invention, not only the vibration reducing force of the member itself of the anti-vibration structure but also the separate vibration insulating member is integrated with the member of the anti-vibration structure, thereby maximizing the dustproof effect.

According to the present invention, it is possible to reduce the propagation of ground vibration by using a composite dustproof structure maximizing dustproof performance, thereby securing long-term durability of the facility, and enabling construction of facilities such as semiconductor factories sensitive to vibration loads.

1 is a view showing various conventional dustproof structures
2 is a perspective view of a maintenance-resistant composite anti-vibration structure according to an embodiment of the present invention;
3 is a perspective view of a precast segment in accordance with one embodiment of the present invention.
4 is a perspective view of a vibration insulating material according to an embodiment of the present invention;
5 is a view showing a state in which a vibration insulating material according to an embodiment of the present invention is mounted on a main body.
6 is a view illustrating a method of constructing a maintenance-resistant composite vibration damping structure according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views, And redundant explanations thereof will be omitted.

It is also to be understood that the terms first, second, etc. used hereinafter are merely reference numerals for distinguishing between identical or corresponding components, and the same or corresponding components are defined by terms such as first, second, no.

In addition, the term " coupled " is used not only in the case of direct physical contact between the respective constituent elements in the contact relation between the constituent elements, but also means that other constituent elements are interposed between the constituent elements, Use them as a concept to cover each contact.

The composite vibration damping structure capable of maintenance according to an embodiment of the present invention performs a function of basically buried in the ground to reduce ground vibration propagated by using the ground as a medium.

The composite vibration damping structure according to an embodiment of the present invention may include a main body 100 having a hollow portion 200 formed thereon and a vibration damping portion (See Figs. 2 and 3).

Conventionally, the dustproof structure buried in the ground is difficult to perform maintenance and repair for faithful performance of the dustproof function after being buried in the ground. However, the composite dustproof structure according to the present invention is characterized in that the hollow portion 200 is formed in the main body 100 And the vibration insulating member 300 can be attached to the main body of the operator in the hollow portion 200 so that maintenance and repair of the vibration insulating member 300 can be performed as well as maintenance of the main body 100, So that it is possible to perform optimal management for the user.

In addition, the conventional anti-vibration structure depending on the vibration suppression force of the member itself forming the anti-vibration structure depends on the anti-vibration performance, while the composite vibration prevention structure according to the present invention is formed by the body 100 including the hollow portion 200, The vibration-proof performance exhibited by the flexible vibration insulating member 300 mounted on the main body 100 is added to the vibration-proof performance of the rigid member forming the vibration-absorbing member 100. Therefore, compared with the conventional vibration- .

The material forming the main body 100 may be any material capable of reducing vibration, but is preferably formed of concrete in consideration of ease of construction and maintenance.

When the main body 100 is formed of concrete, it is possible to form the main body 100 using a field installation method. More preferably, the main body 100 is formed by a plurality of precast segments 100a and 100b, .

In this case, the vibration insulating member 300 is preferably mounted on the contact portion 110 of the plurality of precast segments 100a and 100b in terms of dustproof effect, ease of construction, and ease of maintenance , Fig. 3).

The maintenance-resistant composite anti-vibration structure according to an embodiment of the present invention may further include an insertion port 400 for insertion insertion of the vibration insulation 300 (FIG. 2).

The insertion port 400 may be formed in the contact area 110 where the precast segments 100a and 100b contact and more particularly the plurality of precast segments 100a and 100b in contact with the contact area 110. [ The precast segment 100a may be formed on one of the two precast segments 100a.

In this case, the plurality of precast segments 100a and 100b forming the main body 100 are symmetrical. Therefore, the plurality of precast segments 100a and 100b forming the main body 100 are formed using a single die, , 100b can be fabricated.

For example, when the plurality of precast segments 100a and 100b are formed in a " C "shape, the contact portion 110 may have two contact portions of the lower contact portion 110a and the upper contact portion 110b In the lower contact portion 110a, an insertion port 400a is formed in only one precast segment 100a of the plurality of precast segments 100a and 100b, and another precast portion 100b is formed in the upper contact portion 110b. And the insertion port 400b may be formed only in the segment 110b (FIG. 2).

The vibration insulating member 300 according to an embodiment of the present invention may include an elastic member 310 for vibration reduction and a coupling member 320 for coupling the elastic member 310 to the main body 100 4).

In this case, the vibration isolator 300 may include a first coupling member 320 coupled to any one of the plurality of precast segments 100a and 100b, a second coupling member 320 coupled to the other precast segment 100b, The second engagement member 330 coupled to the first engagement member 320 and the elastic member 310 coupled to the first engagement member 320 at one end and the second engagement member 330 at the other end, .

The second engaging member 330 also has a gap space 333 between the contact member 331 coupled with the elastic member 310 and the precast segment 300b coupled with the second engaging member 330 and the contact member 331. [ (FIG. 4). As shown in FIG.

In this case, the insertion port 400 may include an insertion space 410 into which the vibration insulating material 300 is inserted and a recessed space 420 formed below the first coupling member 320 (FIG. 5).

Even when the vibration insulating member 300 is inserted into the insertion port 400, the clearance space between the second coupling member 330 and the main body 100 generated by the shorting member 332 is present The vibration insulating member 300 is compressed by using the compressor installed in the cavity space 420 and the recessed space 420 between the lower portion of the first coupling member 320 and the main body 100, It is easy to separate it from the main body 100. Fig.

Also, when the vibration insulating material 300 is installed in the main body 100, the vibration insulating material 300 is inserted into the insertion hole 400 together with the compressor while the vibration insulating material 300 is compressed using a compressor, 300), it is possible to obtain a structural advantage that the compressor can be taken out through the clearance space and the recessed space 420.

The vibration insulating member 300 according to an embodiment of the present invention is mounted to the main body 100 through the first coupling member 320 and the second coupling member 330.

The first and second coupling members 320 and 330 are formed with through holes 340 and the vibration insulating member 300 is fixed to the main body 310 by the coupling bolts 350 passing through the through holes 340. [ 100) (Fig. 4).

An opening may be formed in the insertion hole 400 according to an embodiment of the present invention toward the hollow portion 200 so that the inserted vibration insulating material 300 may be exposed to the hollow portion 200 (FIG. 2).

In the case of adopting such a configuration, an operator is positioned on the hollow portion 200, and the insertion and removal work of the vibration insulating material 300 can be easily performed, and the maintenance of the vibration insulating material is enabled.

It is preferable that the insertion port 400 is formed only in an opening toward the hollow portion 200 and that the insertion port 400 is closed toward the outside of the main body 100 to prevent foreign matter from penetrating into the insertion port 400 and the hollow portion 200 .

The insertion port 400 formed in the precast segments 100a and 100b according to an embodiment of the present invention may have an opening formed only toward the hollow portion 200 and a closed shape .

However, if the opening 400 is formed in both the hollow portion 200 and the outside of the main body 100, the composite dustproof structure capable of maintaining maintenance according to the embodiment of the present invention is formed in the upper surface (FIG. 5), which is inserted into the main body 100 and closes the opening to the outside of the main body 100.

The structure of the insertion port 400 that can facilitate the mounting and removal of the vibration insulating material 300 in the case of including the insertion port cap, the case of installing the composite vibration prevention structure and the maintenance thereof, It is possible to close the insertion port 400 to the outside.

A method of constructing a maintenance-resistant composite anti-vibration structure according to an embodiment of the present invention will be described below.

A method of constructing a maintenance-resistant composite anti-vibration structure according to an embodiment of the present invention includes a first step S100 of excavating the ground to form the excavation unit 1, A second step S200 of forming a body 100 in which the hollow portion 200 is formed by a plurality of pre-cast segments 100a and 100b, A third step S300 of mounting a vibration insulating material 300 for reducing the vibration transmitted to the main body 100 and a fourth step S400 of backing up the excavating part 1 such that the main body 100 is embedded in the ground (Fig. 6).

In this case, the fourth step S400 may be a step of backing up the excavation part 1 so that the hollow part 200 can be connected to the ground in a state where the main body 100 is buried in the ground.

That is, the hollow portion 200 is formed as an entrance through which the hollow portion 200 can be connected to the ground, thereby enabling maintenance and repair of the composite dustproof structure.

Hereinafter, a method of maintaining and maintaining a complex dustproof structure capable of maintenance according to an embodiment of the present invention will be described.

Maintenance of a maintenance-resistant composite anti-vibration structure according to an embodiment of the present invention is performed by an operator performing an operation by being positioned in the hollow part 200 and disassembling the coupling bolt 350, A vibration insulating material compression step of compressing the vibration insulating material 300 using a clearance space between the precast segment 300b formed by the exposed recessed space 420 and the clearance member 332 and the contact member 331, A step of discharging the vibration insulating material 300 that discharges the vibration insulating material 300 compressed in the insulating material compressing step from the insertion space 410; a step of compressing the vibration insulating material 300 to be inserted into the insertion space 410 300), a vibration isolation material decompression step of decompressing the vibration insulation material (300) inserted into the insertion space (410) in the vibration insulation material insertion step (300), and a vibration isolation material decompression step Can be a material 300 using the bolts 350 includes a vibration insulating material mounting step of mounting the body 100.

In order to prevent soil or water from flowing into the hollow part 200 through the joint part of the precast segments 100a and 100b and the insertion hole 400, a cover for closing the joint part of the pre- And a cover installing step for installing the cover.

Further, the method may further include an entrance forming step of forming an entrance on the pre-cast segment for each section so as to be able to enter and exit the body formed with the hollow part.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

100:
200: hollow
300: Vibration Isolation Material
400:

Claims (18)

In a composite vibration damping structure buried in the ground,
A main body 100 having a hollow portion 200 formed therein;
A vibration insulating material 300 attached to the main body 100 to reduce vibrations transmitted to the main body 100; And
And an insertion port 400 into which the vibration insulating material 300 is inserted,
The body 100 is formed by a plurality of precast segments 100a, 100b,
The vibration isolation member 300 is mounted on the contact portion 110 of the plurality of precast segments 100a and 100b,
The vibration insulating material (300)
A first engagement member (320) coupled to the precast segment (100a) of any one of the plurality of precast segments (100a, 100b);
A second engagement member 330 coupled to the other precast segment 100b; And
And an elastic member 310 having one end coupled to the first engagement member 320 and the other end coupled to the second engagement member 330,
The second engaging member (330)
A contact member 331 coupled with the elastic member 310; And
A clearance member 332 forming a clearance space between the precast segment 300b and the contact member 331 coupled with the second engagement member 330;
Wherein the dustproof structure comprises:
delete delete delete delete The method according to claim 1,
The insertion port (400)
An insertion space 410 into which the vibration insulating material 300 is inserted; And
A recessed space 420 formed below the first engagement member 320;
Wherein the dustproof structure comprises:
The method according to claim 6,
The insertion port (400)
Wherein an opening is formed toward the hollow portion 200 so that the inserted vibration insulating material 300 may be exposed to the hollow portion 200. [
The method according to claim 6,
The insertion port (400)
An opening is formed toward the outside of the hollow portion 400 and the main body 100,
Further comprising an insertion port cap for closing the opening formed toward the outside of the main body (100).
8. The method of claim 7,
The first coupling member 320 and the second coupling member 330 have through holes 340 formed therein,
Wherein the vibration insulating member 300 is mounted to the main body 100 by a coupling bolt 350 passing through the through hole 340.
9. The method of claim 8,
The precast segments 100a and 100b are formed in a "c" shape,
The insertion port (400)
Is formed only in the precast segment (100a) to which the first coupling member (320) is coupled.
A method of constructing a maintenance-resistant composite anti-vibration structure,
A first step S100 of excavating the ground to form the excavation part 1;
A second step S200 of forming a main body 100 formed with a plurality of precast segments 100a and 100b on the excavation part 1 and having a hollow part 200 formed therein;
A third step (S300) of mounting a vibration insulating material (300) for reducing vibration transmitted to the main body (100) to a contact portion (110) of the plurality of precast segments (100a, 100b);
And a fourth step (S400) of backing up the excavation part (1) so that the main body (100) is buried in the ground,
The main body 100 is formed with an insertion port 400 through which the vibration insulating material 300 is inserted,
The vibration insulating material (300)
A first engagement member (320) coupled to the precast segment (100a) of any one of the plurality of precast segments (100a, 100b);
A second engagement member 330 coupled to the other precast segment 100b; And
And an elastic member 310 having one end coupled to the first engagement member 320 and the other end coupled to the second engagement member 330,
The second engaging member (330)
A contact member 331 coupled with the elastic member 310; And
A clearance member 332 forming a clearance space between the precast segment 300b and the contact member 331 coupled with the second engagement member 330;
Wherein the method comprises the steps of:
12. The method of claim 11,
In the fourth step S400,
And a step of back filling the excavation part (1) so that the hollow part (200) can be connected with the ground in a state where the main body (100) is buried in the ground. How to.



delete delete 12. The method of claim 11,
The insertion port (400)
An insertion space 410 into which the vibration insulating material 300 is inserted; And
A recessed space 420 formed below the first engagement member 320;
Wherein the method comprises the steps of:
16. The method of claim 15,
The insertion port (400)
Wherein an opening is formed toward the hollow part 200 so that the inserted vibration insulating material 300 may be exposed to the hollow part 200. The method of claim 1,
17. The method of claim 16,
The first coupling member 320 and the second coupling member 330 have through holes 340 formed therein,
Wherein the vibration insulating member 300 is mounted to the main body 100 by a coupling bolt 350 passing through the through hole 340. The method of claim 1,
A method for maintaining the composite vibration damping structure according to claim 9,
An engaging bolt disassembling step of disassembling the engaging bolt 350;
The vibrating insulator 300 may be formed by using a clearance space between the recessed space 420 exposed through the opening and the precast segment 300b formed by the clearance member 332 and the contact member 331. [ Compressing the vibration insulating material to be compressed;
A step of discharging the vibration insulating material 300 which discharges the vibration insulating material 300 compressed in the vibration insulating material compressing step from the insertion space 410;
Inserting the vibration insulating material (300) into the insertion space (410) by compressing the new vibration insulating material (300);
A vibration isolation material decompression step of decompressing the vibration insulation material 300 inserted into the insertion space 410 at the step of inserting the vibration insulation material 300; And
A vibration insulating material mounting step of mounting the vibration insulating material 300 decompressed in the vibration insulating material decompressing step to the main body 100 using the coupling bolt 350;
Wherein the method further comprises the step of:

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