KR101916871B1 - Haunch type earthquake-proof device - Google Patents

Abstract

Disclosed is a haunch type earthquake-resistant device. At least one haunch type earthquake-resistant device is installed to a column-beam joint portion with a Rhamen structure. Moreover, the haunch type earthquake-resistant device comprises: an attachment member including a side plate portion attached to the side surface of the column, a bottom plate portion attached to the bottom surface of the beam, and a curved plate portion connecting the side plate portion to the bottom plate portion; a connecting member including a side attaching plate portion attached to the side plate portion, a bottom attaching plate portion attached to the bottom plate portion, and a connecting plate portion connecting the side attaching plate portion to the bottom attaching plate portion; and a recovery member interposed between the attachment member and the connecting member and inducing deformation in the longitudinal direction of the connecting member. Accordingly, partial replacement is possible even when deformation occurs by vibration energy of an earthquake so that maintenance can be easily performed. Furthermore, external forces can be uniformly dispersed even when the fracture behavior of a structure occurs skewed to one side based on the column.

Description

[0001] HAUTCH TYPE EARTHQUAKE-PROOF DEVICE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a quake-resistant type earthquake-proof apparatus, and more particularly, to a quake type earthquake-proof apparatus installed in a column-to-beam connection of a ramen structure to reduce deformation of a structure due to earthquake vibration and earthquake load.

The earthquake of 5.8 magnitude occurred in Gyeongju on September 12, 2016 and 5.4 magnitude earthquake in Pohang on November 15, 2017 caused damage to existing buildings. Especially, the damage to the old buildings which had not enough seismic design was bigger.

According to the meteorological data, the occurrence of earthquakes in Korea is gradually increasing. In addition, the magnitude of the damage caused by the earthquake will increase from 5.0 to 1 in 2014, 3 in 2016, and 1 in 2017 (up to now).

As a result of the earthquake that occurred in 2016, seismic design of 200m ² or more is required for seismic design of Korea, and seismic performance is improved for most new buildings. However, existing buildings that were not required to have earthquake-resistant design are expected to suffer from continuous damage due to the earthquake.

Damage to buildings caused by earthquakes can occur in many ways. Particularly, in the piloti structure, which is used as a parking space by placing a space at the lower part, the load and the displacement of the upper structure are concentrated on the column in the event of an earthquake, leading to serious column failure. In the pilotty structure, the earthquake damage is concentrated on the column, especially where the column and the beam (or slab) meet can be destroyed first.

In this connection, Korean Patent Laid-Open Publication No. 2003-0002541 discloses an earthquake-proof reinforcement tool. Japanese Laid-Open Patent Publication No. 2003-0002541 discloses an earthquake-proof reinforcement for reinforcing an orthogonal joint of a structural structural member, wherein a steel holder is welded to a steel plate and integrally formed, and the free end of the steel holder is curved A pair of metal brackets and a fastening portion for connecting the pair of metal brackets to each other, and connecting portions are provided at the free ends of the steel holders of the metal bracket body, And the orthogonal joint portion is reinforced by earthquake.

Open Patent Publication No. 2003-0002541 discloses a structure in which a wooden house is not collapsed due to an earthquake or a typhoon so that it is not collapsed to improve the seismic performance and the volume is not increased so that it can be easily transported to a construction site The transportation cost is low, and there is an advantage that it is easy to construct.

However, as disclosed in Japanese Patent Application Laid-Open No. 2003-0002541, vibration energy caused by an earthquake or a typhoon is concentrated in a steel holder of a curved shape, so that it is troublesome to replace a plastic holder that is plastically deformed every time an earthquake or a typhoon occurs . Since steel holders are welded to plates made of steel, there is a disadvantage that most of the seismic reinforcement tools must be replaced every time an earthquake or a hurricane occurs.

Actual fracture phenomenon of the structure due to external force is caused by biasing toward one side of the hexahedral column. Therefore, even if the seismic strengthening tool disclosed in JP-A-2003-0002541 is installed on each of the four surfaces of the hexahedron column, the vibration energy due to the earthquake and the typhoon can be concentrated on any one seismic strengthening tool.

Korean Patent Publication No. 2003-0002541 (published on 2003.01.09)

It is an object of the present invention to provide a method and an apparatus for separating an external force evenly even if deformation occurs due to vibration energy of an earthquake, And to provide a spiral type earthquake-resistant apparatus.

According to the present invention, the above object can be attained by providing a laminate structure comprising at least one side plate portion attached to a side surface of a column, the bottom plate portion being attached to a bottom surface of the beam, An attachment member including a curved plate portion connecting the plate portion; A connection member including a side attachment plate attached to the side plate, a bottom attachment plate attached to the bottom plate, and a connection plate connecting the side attachment plate and the bottom attachment plate; And a recovery member interposed between the attachment member and the connection member and inducing a longitudinal deformation of the connection member.

The recovery member includes: a side coupling plate portion attached to the side plate portion; A bottom joint plate portion attached to the bottom plate portion; And a deforming plate portion connecting the side connecting plate portion and the bottom surface connecting plate portion and attached to the connecting plate portion. Both ends of the connecting plate portion and the deforming plate portion may be bent in directions away from each other.

The connecting plate portion and the deforming plate portion may have grooves formed at the through holes or at the edges thereof so that the sectional area decreases.

Further comprising a reinforcing member formed of two or more curved surfaces having both ends joined to the attachment member and the recovery member and having an inflection point, wherein the two or more curved surfaces are compressed Or stretched.

And a pipe-shaped reinforcement member that is compressed or elongated between the attachment member and the recovery member upon deformation of the recovery member, and the diametrically opposite ends are coupled to the attachment member and the recovery member.

Further comprising a dispersing member connecting the reinforcing members provided on the column-to-beer joining portion to each other, wherein the dispersing member includes: a reinforcing pipe inserted into the reinforcing member; And a bending pipe type coupling pipe coupled to the reinforcing pipe and the openings.

According to the present invention, there is provided a spiral type earthquake-resistant device comprising a mounting member, a connecting member, a recovery member, and a reinforcing member so that partial replacement is possible even if deformation occurs due to vibration energy of an earthquake, .

Also, it is possible to provide a spiral type earthquake-resistant device in which two or more reinforcing members provided on a column-to-beam joint are connected to each other so that the external force is evenly distributed and dissipated even if the fracture behavior of the structure occurs on either side of the column .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a spiral type earthquake-proof apparatus according to an embodiment of the present invention; FIG.
Fig. 2 is an exploded perspective view of the spiral seismic device of Fig. 1; Fig.
3 is a perspective view of a spiral seismic device according to another embodiment of the present invention;
4 is a perspective view of a spiral seismic device according to another embodiment of the present invention;
5 is a perspective view of a spiral seismic device according to another embodiment of the present invention.
6 is an exploded perspective view of the spiral seismic device of Fig.
FIG. 7 is a perspective view of a spiral type earthquake-proof apparatus according to another embodiment of the present invention; FIG.
Fig. 8 and Fig. 9 are perspective views showing the installed state of the spiral seismic device of Fig. 5;
10 is a perspective view showing an installation state of a spiral type earthquake-proof apparatus according to still another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions are not described in order to simplify the gist of the present invention.

Even if deformation occurs due to the vibration energy of the earthquake, the quake-resistant type earthquake-proof device of the present invention can be partly replaced and can be easily maintained, and even if the fracture behavior of the structure is biased to one side with respect to the column, Dissipation.

FIG. 1 is a perspective view of a horn type earthquake-proof apparatus according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the horn type earthquake-proof apparatus of FIG. 1, 5 is a perspective view of a quake-resistant type earthquake-proof apparatus according to another embodiment of the present invention, and Fig. 6 is a perspective view of a horn type earthquake-proof apparatus according to another embodiment of the present invention, FIG. 7 is a perspective view of a horn type vibration isolator according to still another embodiment of the present invention, FIGS. 8 and 9 are perspective views showing an installed state of the horn type vibration isolator of FIG. 5, 10 is a perspective view showing an installation state of a spiral type earthquake-proof apparatus according to another embodiment of the present invention.

As shown in Figs. 1 and 2, the quake-resistant type earthquake-proof apparatus 10 according to the embodiment of the present invention is installed in a column-to-beam joint of a ramen structure (see Fig. 8) And includes a mounting member 100, a connecting member 200, and a recovery member 300. The connecting member 200 and the recovering member 300 are made of a metal.

8 and 9 are perspective views showing the installation state of the horn-type vibration isolator 40 according to another embodiment of the present invention. 8 and 9 has a difference in which the reinforcing member 400 is further coupled to the spiral seismic device 10 shown in Fig. Referring to Fig. 8, the installation state of the spiral seismic device 10 shown in Fig. 1 can be easily understood.

1 and 2, the attachment member 100 is attached to the surfaces of the column 1 and the beam 2 at the column-to-beam junction, and includes a side plate portion 110, a bottom plate portion 120, And a curved plate portion 130.

The attachment member 100 forms a frame to which the connecting member 200 and the recovery member 300 are attached and at the same time absorbs the vibration energy of the earthquake partly through self-deformation (bending deformation of the curved plate portion 130) . The attachment member 100 is manufactured in such a manner that an integral plate is bent at 90 degrees.

The side plate portion 110 is a portion attached to the side 1a of the column 1 and the bottom plate portion 120 is a portion attached to the bottom surface 2a of the beam 2. The curved plate portion 130 is a portion of the side plate portion 110, (110) and the bottom plate portion (120).

The curved plate portion 130 connects the side plate portion 110 and the bottom plate portion 120 with a constant curvature at a portion where the side 1a of the column 1 and the bottom surface 2a of the beam 2 intersect. The side plate portion 110, the bottom plate portion 120, and the curved plate portion 130 are formed to have a constant width.

The side plate portion 110 and the bottom plate portion 120 are attached to the column 1 and the beam 2 by anchor bolts AB. As shown in FIG. 2, the side plate portion 110 and the bottom plate portion 120 are formed with a plurality of anchor holes Ha into which the anchor bolts AB are inserted.

1 and 2, the connecting member 200 is configured to connect the side plate portion 110 and the bottom plate portion 120 and includes a side attachment plate portion 210, a bottom attachment plate portion 220, (230).

The connecting member 200 partially absorbs the vibration energy of the earthquake through self-deformation (mainly tensile, compressive and bending deformation of the connecting plate 230) in the event of an earthquake. The connecting member 200 is manufactured by bending an integral plate.

The side attachment plate portion 210 is attached to the side plate portion 110 and the bottom plate attachment portion 220 is attached to the bottom plate portion 120. The connection plate portion 230 is a portion attached to the side attachment plate portion 210, And the bottom surface attachment plate portion 220 are connected to each other. The side attachment plate portion 210, the bottom surface attachment plate portion 220, and the connection plate portion 230 are formed to have a constant width.

The intermediate portion of the connection plate portion 230 (hereinafter, referred to as 'linear connection portion 231') is formed in a straight plate shape, and a portion adjacent to the side attachment plate portion 210 and the bottom surface attachment plate portion 220 ') At a certain curvature.

The connecting member 200 absorbs the vibration energy of the earthquake through the longitudinal deformation of the straight connecting portion 231 and the bending deformation of the curved connecting portion 232. The rectilinear connection portion 231 is prevented from being warped by the linearly deformable portion 331.

The side surface attachment plate portion 210 and the bottom surface attachment plate portion 220 are part of anchor bolts AB (attaching the side plate portion 110 and the bottom plate portion 120 to the column 1 and the beam 2) (First anchor bolt ') to the side plate portion 110 and the bottom plate portion 120, respectively.

As shown in FIG. 2, a plurality of anchor holes Ha are formed in the side attachment plate portion 210 and the bottom surface attachment plate portion 220 to insert the first anchor bolts.

As shown in Figs. 1 and 2, the recovery member 300 is interposed between the attachment member 100 and the connection member 200, which is a configuration for inducing a longitudinal deformation of the connection member 200. As shown in Fig. The recovery member 300 includes a side coupling plate portion 310, a bottom coupling plate portion 320, and a deforming plate portion 330.

The recovery member 300 partially absorbs the vibration energy of the earthquake through self-deformation (mainly tensile, compressive and bending deformation of the deforming plate 330) when an earthquake occurs. The recovery member 300 is fabricated in the form of a bent plate.

The side plate portion 310 is attached to the side plate portion 110 and the bottom plate portion 320 is attached to the bottom plate portion 120. The deformed plate portion 330 is a portion of the side plate portion 310, And the bottom surface coupling plate 320 are connected to each other. The side surface coupling plate portion 310, the bottom surface coupling plate portion 320, and the deforming plate portion 330 are formed to have a constant width.

The intermediate portion of the deforming plate 330 (hereinafter referred to as the 'linearly deforming portion 331') is formed in a straight plate shape, and a portion adjacent to the side surface engaging plate portion 310 and the bottom surface engaging plate portion 320 332) ') with a predetermined curvature. The recovery member 300 absorbs the vibration energy of the earthquake through the longitudinal deformation of the rectilinear deformation portion 331 and the bending deformation of the curved deformation portion 332. [

As shown in Fig. 1, the linearly deformed portion 331 is attached to the straight connecting portion 231 by a plurality of bolts B and a nut (N). The straight connecting portion 231 and the curved connecting portion 232 form a curved shape in a direction away from each other. Therefore, when the attachment member 100 is deformed due to the earthquake energy, the curved connecting portion 232 suppresses the flexural deformation of the linear connecting portion 231. [

That is, when the deformation (the deformation in the first direction D1) occurs in the direction in which the attachment member 100 is broken due to the earthquake energy, a warping deformation in which the curvature of the curved connecting portion 232 becomes small is generated in the connecting plate portion 230 It happens. Then, the deforming plate 330 is bent and deformed so that the curvature of the curved deforming portion 332 increases.

The linear connecting portion 231 is pressed toward the linearly deformed portion 331 by the bending deformation of the curved connecting portion 232 and the linearly deformed portion 331 is deformed toward the linear connecting portion 231 by the bending deformation of the curved deformation portion 332 Lt; / RTI >

However, the straight connecting portion 231 and the linearly deforming portion 331 are not deformed to be convex but compressively deformed in the longitudinal direction. That is, the straight connecting portion 231 and the linearly deforming portion 331 form a boundary which interferes with the bending deformation, thereby inducing longitudinal deformation of each other.

Buckling refers to a deformation in which a bending is caused by a load less than a proportional limit of a material when a compressive load is applied in a longitudinal direction to a flat plate. The recovery member 300 prevents buckling of the connecting member 200 and induces longitudinal deformation. Therefore, the strength and stability of the earthquake-proof apparatus 10 are improved, and the ability to return to the original state after the earthquake energy dissipation is improved.

On the other hand, when the deformation (deformation in the second direction D2) of the attachment member 100 due to the earthquake energy occurs, the connection plate portion 230 undergoes a bending deformation that increases the curvature of the curved connecting portion 232 . Then, the deforming plate 330 is bent and deformed so that the curvature of the curved deforming portion 332 is reduced.

Since the straight connecting portion 231 and the linear deforming portion 331 are attached to each other by the plurality of bolts B and the nuts N, the warping deformation is suppressed and the tensile deformation in the longitudinal direction occurs.

The side joint plate portion 310 and the bottom joint plate portion 320 are part of anchor bolts AB (to attach the side plate portion 110 and the bottom plate portion 120 to the column 1 and the beam 2) To the side plate portion 110 and the bottom plate portion 120 by a second anchor bolt '. 2, a plurality of anchor holes Ha are formed in the side joint plate portion 310 and the bottom joint plate portion 320 to insert the second anchor bolts.

As shown in FIGS. 3 and 4, a through hole Ht may be formed in the connecting plate portion 230 and the deforming plate portion 330, or a groove G may be formed at the edge.

The connecting plate portion 230 and the deforming plate portion 330 are easily deformed by an external force because the sectional area decreases at the portion where the through hole Ht and the groove G are formed. The through holes Ht and the grooves G may be formed in the connecting plate portion 230 and the deforming plate portion 330 in order to advance the breaking point of the connecting plate portion 230 and the deforming plate portion 330, .

5 and 6, the horn type vibration isolator 40 according to another embodiment of the present invention further includes a reinforcement member 400 installed between the attachment member 100 and the recovery member 300 .

The reinforcing member 400 is formed in the shape of a pipe as a structure to lower the stiffness of the recovery member 300 by the beam 2 and both ends in the radial direction are coupled to the attachment member 100 and the recovery member 300.

6, the reinforcing member 400 is attached to the curved plate portion 130 and the straight-line deforming portion 331 by a plurality of bolts B and a nut N. As shown in Fig. The reinforcing member 400 and the curved plate portion 130 are formed with a plurality of bolt holes Hb into which the bolts B are inserted.

The reinforcing member 400 is compressed or elongated between the attachment member 100 and the recovery member 300 upon deformation of the recovery member 300. [

That is, when deformation (deformation in the first direction D1) occurs in the direction in which the attachment member 100 is broken due to the earthquake energy, a curved deformation that curvature decreases occurs in the curved connecting portion 232, The reinforcing member 400 is stretched between the attachment member 100 and the recovery member 300 while the flexure deformation is caused to increase the curvature of the attachment member 100. [

On the other hand, when the deformation (the deformation in the second direction D2) in the direction in which the attachment member 100 is widened due to the earthquake energy occurs, the curved connection portion 232 undergoes flexural deformation that increases in curvature, The reinforcing member 400 is compressed between the attachment member 100 and the recovery member 300 while the bending deformation that reduces the curvature occurs.

The reinforcing member 400 is required to have a constant external force to elongate and compressively deform the reinforcing member 400. Therefore, when the reinforcing member 400 is further provided between the attachment member 100 and the recovery member 300, do.

As shown in FIG. 7, the reinforcing member 400 may be formed of two or more curved surfaces having inflection points. Two or more curved surfaces are compressed or elongated between the attachment member 100 and the recovery member 300 upon deformation of the recovery member 300. [

The reinforcing member 400 is required to have a constant external force to elongate and compressively deform the reinforcing member 400. Therefore, if the reinforcing member 400 is further provided between the attachment member 100 and the recovery member 300, do.

10, the hitting type earthquake-proof apparatus 60 according to another embodiment of the present invention further includes a dispersing member 500 for connecting two or more reinforcing members 400 provided at the column- And the like. The dispersion member 500 includes a reinforcing pipe 510 and a joint pipe 520.

The reinforcement pipe 510 is inserted into the reinforcement member 400 and has an outer diameter equal to or smaller than the inner diameter of the reinforcement member 400. Both ends of the reinforcing tube (510) protrude outside the opening of the reinforcing member (400).

The joint pipe 520 connects the reinforcement pipe 510 along the periphery of the column 1 and is formed into a bent pipe shape and is coupled to the reinforcement pipe 510 through openings. 10, when the seismic retrofitting device 60 is installed only on two side surfaces 1a of the four side surfaces 1a of the column 1, the two reinforcing pipes 510 are connected to the reinforcing member 400 It can be used in the form of connecting the coupling pipe 520 without being inserted.

Actual fracture phenomenon of the structure due to external force is caused by biasing toward one side of the hexahedral column. Therefore, even if the seismic strengthening tool disclosed in JP-A-2003-0002541 is installed on each of the four surfaces of the hexahedron column, the vibration energy due to the earthquake and the typhoon can be concentrated on any one seismic strengthening tool.

The quake-resistant seismic device 60 according to still another embodiment of the present invention is constructed by connecting the reinforcing members 400 having two or more of the dispersing members 500 at the column-to-beam joint portions along the periphery of the column 1, Thereby solving the problems of the prior art.

That is, even if an external force is concentrated on any one of the seismic equipments 60 installed on the periphery of the column 1 due to the earthquake, the destruction of the structure due to typhoon, etc., The external force concentrated on one of the reinforcing members 400 is dispersed and dissipated by the other reinforcing members 400 by connecting the reinforcing members 400 installed on the beam joints.

According to the present invention, there is provided a spiral type earthquake-resistant device comprising a mounting member, a connecting member, a recovery member, and a reinforcing member so that partial replacement is possible even if deformation occurs due to vibration energy of an earthquake, .

Also, it is possible to provide a spiral type earthquake-resistant device in which two or more reinforcing members provided on a column-to-beam joint are connected to each other so that the external force is evenly distributed and dissipated even if the fracture behavior of the structure occurs on either side of the column .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have. Accordingly, it should be understood that such modifications or alterations should not be understood individually from the technical spirit and viewpoint of the present invention, and that modified embodiments fall within the scope of the claims of the present invention.

10: Horn type earthquake
100: attachment member 300: recovery member
110: side plate portion 310: side coupling plate portion
120: bottom plate part 320: bottom plate joint plate part
130: curved plate portion 330:
Ha: Anchor hole 331: Linear deformation part
Hb: Bolt hole 332: Curved deformation part
D1: first direction 400: reinforcing member
D2: second direction 500: dispersing member
200: connecting member 510: reinforcing pipe
210: side attachment plate 520: joint pipe
220: Bottom mounting plate 1: Column
230: connecting plate part 1a: side
231: straight line connection 2: beam
232: Curved connecting portion 2a:
Ht: Through hole B: Bolt
G: Groove N: Nut
AB: Anchor bolt

Claims (6)

At least one column-to-beam connection is installed in the laminated structure,
A mounting plate including a side plate attached to a side surface of the column, a bottom plate attached to a bottom surface of the beam, and a curved plate connecting the bottom plate and the bottom plate;
A connection member including a side attachment plate attached to the side plate, a bottom attachment plate attached to the bottom plate, and a connection plate connecting the side attachment plate and the bottom attachment plate; And
And a recovery member interposed between the attachment member and the connection member for inducing a longitudinal deformation of the connection member,
The recovery member
A side coupling plate portion attached to the side plate portion;
A bottom joint plate portion attached to the bottom plate portion; And
And a deforming plate portion connecting the side joint plate portion and the bottom surface joint plate portion and attached to the connection plate portion,
Both ends of the connecting plate portion and the deforming plate portion are bent away from each other,
Wherein the connecting plate portion includes a linear connecting portion in the form of a straight plate as an intermediate portion and a curved connecting portion adjacent to the side mounting plate portion and the bottom surface mounting plate portion,
Wherein the deforming plate portion includes a linear deforming portion in the form of a straight plate as an intermediate portion and a curved deforming portion adjacent to the side connecting plate portion and the bottom surface connecting plate portion,
The curved connecting portion and the curved deforming portion are bent in directions away from each other,
The straight connecting portion is pressed toward the linearly deformed portion by the bending deformation of the curved connecting portion when the attachment member is deformed in the direction of being disturbed by the earthquake energy and the linearly deformed portion is deformed by the bending deformation of the curved deformation portion, Wherein the linear connection portion and the linear deformation portion form a boundary interfering with the bending deformation to induce the longitudinal deformation of each other. delete The method according to claim 1,
Wherein the connecting plate portion and the deforming plate portion are formed with a through hole or a groove at an edge thereof so as to reduce a cross-sectional area thereof. The method according to claim 1,
Further comprising a reinforcing member formed of two or more curved surfaces, both ends of which are joined to the attachment member and the recovery member,
Wherein the at least two curved surfaces are compressed or elongated between the attachment member and the recovery member upon deformation of the recovery member. The method according to claim 1,
Further comprising a reinforcing member in the form of a pipe which is compressed or elongated between the attachment member and the recovery member upon deformation of the recovery member and whose diametrically opposite ends are coupled to the attachment member and the recovery member, Device. 6. The method of claim 5,
Further comprising a dispersing member connecting the reinforcing members provided on the column-to-beer joining portions to each other,
Wherein the dispersing member comprises:
A reinforcing tube inserted into the reinforcing member; And
And a bending pipe type joint pipe connected to the reinforcing pipe and the openings.

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