KR100955706B1 - Structural and seismic damper and its strengthening techniques using multi-layered elastic-plastic castellated plates and elastic rubbers - Google Patents

Abstract

PURPOSE: A lateral damper in which elasto-plastic boards are set in parallel and a structure reinforcing method using the same are provided to enable efficient design and application by using a damper with various damping capabilities. CONSTITUTION: A lateral damper comprises an elastic absorption finishing board(130), an impact absorber, a fixture(200), an end elasto-plastic board, and an end spacer. The impact absorber comprises parallel elasto-plastic boards(110) with energy absorption holes, which are attached to the elastic absorption finishing board, and elastic spacers(120) with through holes, which are installed between the parallel elasto-plastic boards. The end elasto-plastic board is placed in contact with the side surfaces of the elastic absorption finishing board and the end elasto-plastic board. The end spacer is installed between the end elasto-plastic board and the elastic absorption finishing board.

Description

Horizontal dampers with multiple sets of carbon plates in parallel and structural seismic reinforcement methods using the same

The present invention relates to a horizontal damper having a plurality of plastic plates set in parallel, and a method for earthquake resistance using the same. More specifically, it relates to a damper used for seismic reinforcement of new or existing structures, and a structure reinforcement method using the same.

1 illustrates a conventional wall damper in contrast to the present invention.

That is, the slit seismic steel plate 11 having a plurality of slits 13 formed at equal intervals along the longitudinal direction while being formed in the height direction of the wall, and reinforcement plates attached to the upper and lower surfaces of the slit seismic steel plate, respectively ( Slit seismic steel plate structure composed of 12) is introduced.

In addition, the slit earthquake resistant steel plate 11 has a predetermined thickness, height, and length, and has a thickness such that initial deformation does not occur in constructing the wall, and the slit earthquake resistant steel plate 11 has a slit in the height direction of the wall. (13) is formed. The slits 13 are formed in plural at equal intervals along the longitudinal direction of the wall.

Thus, the slit seismic steel sheet 11 having a plurality of slits 13 can minimize the effects of shear buckling of the steel sheet and can be said to be advantageous in terms of energy absorbing ability due to improved plastic deformation ability due to bending behavior. have.

As a result, it can be seen that the slit earthquake resistant steel plate structure is formed to have an H-shaped cross section as a whole.

However, since the slit seismic steel plate structure uses one slit seismic steel plate 11 and the reinforcing plate 12, a method of installing a plurality of slit earthquake resistant steel plate structures having a constant damping capacity without manufacturing the damping ability can be controlled. There was a problem that the damping capacity can not be adjusted.

Accordingly, the present invention is to provide a damper that can be designed and applied more efficiently, even if one damper can function as a damper having a variety of damping ability to be the technical problem to be solved.

The present invention to achieve the above technical problem

First, the use of elasto-plastic plates acting as a damper against loads such as earthquakes, but many of these elasto-plastic plates can be spaced apart in parallel.

 At this time, the carbonaceous plate is used in particular, the elastic spacer in order to maintain the spaced apart state, the carbonaceous plate installed by the elastic spacer in parallel, such as fastening bolts and nuts to secure the integrity of each other It was pressed into a fixture.

Second, the elastic absorbing closing plate is installed at both side ends of the carbonaceous plate is a plurality of spaced apart in parallel to be integrated by the elastic spacer, the working load transmitted from the elastic absorbing closing plate is distributed to the entire elastic plate The end-elastic plate may be further installed to be in contact with the entire cross-section of the elastic spacer and the elastic plate at right angles to the end side of the elastic spacer and the elastic plate. Accordingly, the end carbonaceous plate was able to efficiently cope with the setting and impact of the position by the elastic absorbing closing plate and also the end spacer.

Third, the housing can be further installed to surround and protect the damper exterior of the present invention by the elastic spacer and the carbonaceous plate and the end carbonaceous plate and the end spacer.

The damper according to the present invention can be adjusted freely by the number of installation of the carbonaceous plate that can offset or absorb the working load, it is possible to adjust the damping capacity, it is possible to construct a very efficient and economical damper, overall horizontally Since it is extended, it can be easily applied between the structures to be reinforced.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

2 is an assembled perspective view of a horizontal damper 100 in which a plurality of elastic plates are set in parallel.

The damper 100 is largely composed of a parallel carbonaceous plate 110, an elastic spacer 120, an elastic absorbing closing plate 130, and a fixture 200.

First, the parallel carbonaceous plate 110 is installed in the form of a plurality of rectangular plate material using an elastic steel sheet or the like spaced apart in parallel, preferably using a steel plate having a length extending in the longitudinal direction greater than the height. .

It can be seen that each of the carbonaceous plates 111, 112, 113, 114, and 115 constituting the parallel carbonaceous plate 110 are spaced apart from each other in parallel. In other words, each of the elasto-plastic plates are integrated with each other, but the damping capacity can be naturally adjusted when the number of installed elasto-plastic plates is spaced apart from each other.

When the damping ability of one carbonaceous plate is determined, it can be seen that the integrated parallel carbonaceous plate 110 is installed by spaced apart a plurality of parallel ones so that the damping capacity is determined by the number of installations.

It can be seen that at least one energy absorbing hole A is formed in each of the carbonaceous plates 111, 112, 113, 114, and 115.

The energy absorption hole (A) is installed because it can minimize the effects of shear buckling of the carbonaceous plate, similar to the conventional damper, and is advantageous in terms of energy absorption capacity due to the improved plastic deformation capacity due to the bending behavior. In the case of the present invention, the energy absorbing holes A are formed so that their mounting positions are formed in each of the carbonaceous plates in the same manner, so that they can communicate with each other in a plurality of parallel carbonaceous plates.

This is because the parallel carbonaceous plate 110 is integrated with each other, so that the energy absorption holes A are also formed at the same position so that plastic deformation of the parallel carbonaceous plate can be predictably generated.

The elastic spacer 120 is such that the parallel carbonaceous plate 110 is spaced apart from each other by a predetermined interval.

The elastic spacer 120 may be used by using a rubber plate having a constant thickness and having the same length and height as each parallel carbonaceous plate 110, and between each carbonaceous plate 111, 112, 113, 114, and 115. Elastic spacers 121, 122, 123, and 124 are provided.

In addition, the elastic spacer 120 is formed so that the through hole (B) is formed at the same position and size as the energy absorbing hole (A) of the parallel carbonaceous plate 110, the energy absorbing hole (A) and the through hole ( B) allows communication with each other.

In addition, the energy absorption hole A and the through hole B may be formed in plural in various shapes and shapes, respectively.

The parallel carbonaceous plate 110 and the elastic spacer 120 described above are components that play an important role in canceling or absorbing the working load as a damper, and they must be acted integrally.

Therefore, it is necessary to bind the parallel carbonaceous plate 110 and the elastic spacer 120 to each other. This function is a fixture 200 including a fastening bolt and a nut.

First, bolt holes 210 and 220 are respectively formed on the parallel carbonaceous plate 110 and the elastic spacer 120 so as to be integrated by compressing the parallel elastomeric plate 110 and the elastic spacer 120 to each other. After forming a plurality, the fastening bolts 230 are inserted into the bolt holes 210 and 220, and then the fastening bolts are fastened to the outer carbonaceous plate 115 with nuts 240.

The bolt holes 210 and 220 are preferably formed around the energy absorbing hole A and the through hole B formed in the substantially central portion of the parallel carbonaceous plate 110 and the elastic spacer 120. desirable.

In addition, horizontal elliptical bolt holes 240 and 250 are formed at the end sides of the parallel carbonaceous plate 110 and the elastic spacer 120. The reason for forming the horizontal elliptical bolt holes 240 and 250 in such a shape will be described later in parallel. Since the side ends of the elastic plate 110 and the elastic spacer 120 is a portion that is connected to the elastic absorbing closing plate 130 and the fastener 200 by the fastening bolt and nut, the elastic absorbing closing plate 130 The coupling bolt 230 fixed by the nut 240 can be slightly slipped in the horizontal oval bolt holes 240 and 250 while allowing the connection with the nut 240 to be more easily distributed. .

Also, the horizontal elliptical bolt holes 240 and 250 may also be formed in a plurality of parallel carbonaceous plates 110 and elastic spacers 120.

In this case, since the parallel carbonaceous plate 110 and the elastic spacer 120 is mainly responsible for offsetting or absorbing the working load, it will be referred to as a shock absorber in the present invention.

Next, both side end surfaces of the parallel parallel elastic plate 110 and the elastic spacer 120 are integrated using the elastic absorbing closing plate 130. The elastic absorbing finish plate 130 serves to transfer the working load to the integrated parallel elastic plate 110 and the elastic spacer 120 as a member in contact with the structure to be reinforced.

Therefore, since it is preferable to distribute the working load to the integrated parallel carbonaceous plate 110 and the elastic spacer 120, the outer plate 131 and the connecting plate 132 are largely formed.

The outer plate 131 is a plate made of a size that can cover the entire side end surfaces of both the parallel carbonaceous plate 110 and the elastic spacer 120 integrated with the same material as the parallel carbonaceous plate 110 What is necessary is to use a member of the form, so that the connection hole 133 to which the connection member 300, such as an anchor bolt, can be mounted so as to be fixed to the structure to be reinforced.

The connecting plate 132 extends at right angles with the outer plate 131 in a position spaced apart from each other so that both side end surfaces of the integrated parallel carbonaceous plate 110 and the elastic spacer 120 can be inserted therebetween. However, it is also a member in the form of a plate made of the same material as the parallel carbonaceous plate 110.

A plurality of horizontal elliptical bolt holes 134 corresponding to the horizontal elliptical bolt holes 240 and 250 of the parallel carbonaceous plate 110 and the elastic spacer 120 integrated therein are formed.

Accordingly, the fastening bolt 230 is a horizontal elliptical bolt hole 134 of the connecting plate 132 of the elastic absorbing closing plate 130 and the parallel elliptical bolt hole 110 and the elastic spacer 120 of the horizontal elliptical bolt hole (240,250) By allowing it to be fixed to the connecting plate 132 by the nut 240, the parallel elastic plate 110 and the elastic spacer 120 integrated with each other to be connected with the elastic absorbing finish plate 130 To help.

In addition, the outer side plate 131 between the integrated parallel carbonaceous plate 110 and the connecting plate 132 in contact with both side end surfaces of the elastic spacer 120, the end spacer 410 and the end bomb The fired plate 420 may be further formed.

The end spacer 410 and the end carbonaceous plate 420 serves to primarily cancel or absorb the load transmitted from the elastic absorbing finish plate 130, while the working load is more effectively integrated in parallel elastic plate ( 110 to be transmitted to both end surfaces of the elastic spacer 120, it can be installed on one side end surface of the parallel parallel elastic plate 110 and the elastic spacer 120, but both It does not matter even if it installs in a side end surface.

Since the integrated parallel carbonaceous plate 110 and the elastic spacer 120 and the elastic absorbing finish plate 130 described above are exposed to the outside as it is, the housing 500 may be further installed for maintenance of contamination.

The housing 500 is installed to surround the integrated parallel carbonaceous plate 110 and the elastic spacer 120, the elastic absorbing finish plate 130, the parallel parallel carbonaceous plate 110 of the rectangular parallelepiped form. After installing the c-shaped upper housing 510 and the lower housing 520 in contact with the upper and lower sides so as to surround the elastic spacer 120, the upper housing 510 and the lower part may also be formed by the c-shaped connecting housing 530. The end of the housing 520 is wrapped and fixed to allow protection of the integrated parallel carbonaceous plate 110 and the elastic spacer 120 by the housing 500.

3A illustrates an example in which the damper 100 of the present invention is installed in a structure requiring reinforcement.

That is, first, a new or existing structure is to be seen as a reinforcement target structure 600 to be reinforced, and a plurality of support structures such as H-shaped steel frame 610 is installed around the column structure, one side of the support structure 620 The damper 100 of the present invention may be mounted between the one side of the structure 600 and the reinforcement target structure 600.

This mounting is to use the elastic absorbing closing plate 130 constituting the damper 100 of the present invention, as shown in Figure 2 the elastic absorbing closing plate 130, the connection member 300, such as anchor bolts are to be mounted Since the connecting hole 133 is formed, first, an anchor hole is formed in the reinforcement target structure 600, and the connecting member 300 reinforces through the connecting hole 133 of the elastic absorption finishing plate 130. It can be seen that the fixed installation of one end of the damper 100 of the present invention is made simple by being inserted into the anchor hole of the target structure 600.

Also in the support structure 610 to form an anchor hole, the connecting member 300 is inserted into the anchor hole of the support structure 610 through the connection hole 133 of the elastic absorption closing plate 130 by a nut It can be seen that the fixed installation of the other end of the damper 100 of the present invention is made simple by being fixed.

In this case, in the case of a structure such as a wall made of masonry by reinforcing the target structure 600, the end reinforcement 700 is further installed in the reinforcement target structure 600, the damper 100 of the present invention Can be installed.

Of course, the damper 100 of the present invention may be installed directly between the reinforcement target structures 600 without the support structure 610.

That is, the wall made by masonry is very susceptible to earthquake load, so first install the end of the wall using the U-shaped end reinforcement 700 as shown in Figure 3b, and then reinforced with the end reinforcement 700 Although not shown between the target structure 600 or between the separate support structure to be installed to the damper 100 of the present invention.

Therefore, the damper 100 of the present invention is mainly used as a damper is installed horizontally, the damper is installed between the structure located to the left and right.

3c shows a state in which the damper according to the present invention is variously installed in a frame structure (a structure to be reinforced) of a building, the bracket-type damper 100a of another modification of the present invention is a column structure 610a, a slab structure The state 620a and the beam structure 630a are installed together.

1 is a front view of a conventional wall damper.

2 is an assembled perspective view of the damper according to the present invention.

3a and 3b is an exploded perspective view of the installation examples of the damper according to the present invention.

Figure 3c is a perspective view of the installation of the damper according to the present invention.

<Brief description of the major reference numerals>

100: horizontal damper with multiple elastic plates set in parallel

110,111,112,113,114,115: Parallel elastoplastic plates

120, 121, 122, 123, 123, 1 Water 24: Elastic spacer

130: elastic absorption finish plate

200: fixed ball

300: connector

410: outer plate

420: connecting plate

500: housing

Claims (10)

Both sides elastic absorbing closing plate 130; A plurality of parallel elasto-plastic plates 110 fixed between the elastic absorption finishing plates 130 and formed to penetrate at least one or more energy absorption holes A, each of which is spaced apart in parallel; And an elastic spacer disposed between the spaced parallel carbonaceous plates 110 and having a through hole B formed at a position and a size corresponding to the energy absorbing hole. And And a fastener 200 including fastening bolts and nuts installed to integrate the parallel carbonaceous plate 110 and the elastic spacer 120 through the same. The both sides elastic absorbing closing plate 130 is composed of both the outer plate 131 and the connecting plate 132 formed spaced apart from the side of the outer plate, the shock absorber integrated with each other by a fixture between the connecting plate End portions of both sides are inserted, and a fastening bolt is inserted into a horizontal elliptical bolt hole formed in each of the connecting plates, the parallel carbonaceous plate, and the elastic spacer, so as to be fastened to the connecting plate by a nut. To allow parallel elasto-plastic plates to be fixed, An end carbonaceous plate installed to contact the entire side of the elastic absorbing closing plate and the carbonaceous plate on one side; And an end spacer disposed between the end carbonaceous plate and the elastic absorption finishing plate. delete delete According to claim 1, wherein the shock absorbers integrated with each other by the fastener is fastened to the bolt hole formed so that the fastening bolt is in communication with the parallel carbonaceous plate and the spacer is fastened by a nut to the outer carbonaceous plate to the parallel elastic plate A horizontal damper in which a plurality of elastic plates are set in parallel to allow the elastic spacer to be integrated with each other. 5. The horizontal damper of claim 4, further comprising a housing set to surround the parallel carbonaceous plate and the elastic spacer so as not to be exposed to the outside. Between the reinforcement target structure and the reinforcement target structure to be reinforced, install a horizontal damper in which a plurality of elastic plates are set in parallel directly. Elastic absorbing closing plates on both sides; A plurality of parallel elastoplastic plates fixed between the elastic absorption finishing plates and formed to penetrate at least one or more energy absorption holes, each of which is spaced apart in parallel; And an elastic spacer disposed between the spaced parallel carbonaceous plates and having a through hole formed at a position and a size corresponding to the energy absorbing hole. And a fastener including a fastening bolt and a nut installed to integrate the parallel carbonaceous plate and the elastic spacer through and integrated therein, so that at least one carbonaceous plate is installed as a horizontal damper having a plurality of parallel sets. And a step of fixing the elastic absorption finishing plates to the reinforcement target structure with a connector, wherein the horizontal dampers in which the plurality of elastic plates are set in parallel are installed to contact the entire sides of the elastic absorption finishing plates and the elastic plates on one side. End carbonaceous plate; And an end spacer disposed between the end carbonaceous plate and the elastic absorptive finishing plate. A method of reinforcing a structure using a horizontal damper in which a plurality of elastic plates are set in parallel. Install a support structure separately outside the reinforcement target structure to be reinforced, Between the supporting structure and the structure to be reinforced, a horizontal damper having a plurality of elastic plates set in parallel is installed, and the damper is Elastic absorbing closing plates on both sides; A plurality of parallel elastoplastic plates fixed between the elastic absorption finishing plates and formed to penetrate at least one or more energy absorption holes, each of which is spaced apart in parallel; And an elastic spacer disposed between the spaced parallel carbonaceous plates and having a through hole formed at a position and a size corresponding to the energy absorbing hole. And a fastener including a fastening bolt and a nut installed to integrate the parallel carbonaceous plate and the elastic spacer by integrally. And fixing the elastic absorbing closing plates to the reinforcement target structure and the support structure with the connector. The horizontal damper in which the plurality of elastic plates are set in parallel, the elastic damping closing plate of one side and the end of the elastic plate is installed to contact the entire side of the elastic plate; And an end spacer disposed between the end carbonaceous plate and the elastic absorptive finishing plate. A method of reinforcing a structure using a horizontal damper in which a plurality of elastic plates are set in parallel. The method according to claim 6 or 7, wherein in the case where the reinforcement target structure is an masonry structure such as a wall made of brick, an end reinforcement is formed first to surround the end of the masonry structure, and then the end reinforcement and the support structure. Or a horizontal damper having a plurality of elastic plates set in parallel to install a horizontal damper having a plurality of elastic plates set in parallel between the structures to be reinforced. delete The structure reinforcement method according to claim 6 or 7, wherein the parallel carbonaceous plate and the elastic spacer further comprise a housing set so as not to be exposed to the outside.

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