KR101070217B1 - Earthquake-resistant system - Google Patents

Abstract

The present invention is a system for earthquake resistance of the structure, the reinforcing bar is installed to be inclined to reinforce the structure; First dampers installed at both ends of the reinforcing rod to absorb seismic energy by friction; And an oil damper for absorbing seismic energy by using oil between the first and second fixing members installed below the reinforcing rod and a second damper having springs for absorbing seismic energy by elasticity. It is about a seismic system.
According to the present invention, it is easy to construct a system suitable for earthquake according to the displacement of the building, easy to design according to the load, can increase the seismic efficiency, and economical installation by reducing the cost of replacement and change And maintenance is possible.

Description

Earthquake-resistant system {EARTHQUAKE-RESISTANT SYSTEM}

The present invention relates to an earthquake resistant system, and more particularly, to a seismic system for easily constructing a system suitable for earthquake resistance according to an interlayer displacement of a building, easy to design according to load, and to increase seismic efficiency.

In general, seismic structures increase the strength of the frame to withstand earthquakes, while absorbing vibration energy from the frame itself in consideration of the ductility, thereby preventing the overall collapse even if the partial destruction of the structure such as the building is recognized. Say

The seismic structure is to improve and secure the occupancy, functionality and stability of the structure, to absorb and dissipate seismic energy acting on the structure, and to minimize the damage to life and property due to the destruction of the structure.

Conventional seismic systems should be installed where significant displacements occur in the structure, reduce the response acceleration of the structure below the limit level, and further reduce both acceleration, displacement, and base shear forces before and after installation, Absorb vibration energy to suppress displacement and reduce load.

However, in the conventional seismic system, dampers must be installed according to the inter-layer response of the building, and the response of the earthquake varies according to the height of the building, the number of pillars of the building, the material of the building, etc. It was difficult to develop an economical and effective system for earthquake resistance, and there was a problem that an expensive cost occurred in replacing a damper when an earthquake occurred.

In order to solve the conventional problems as described above, the present invention is easy to configure the appropriate system according to the inter-floor displacement of the building, to increase the seismic efficiency, and to save cost and time due to replacement and change, economical Ensure installation, maintenance and management.

Other objects of the present invention will be readily understood through the following description of the embodiments.

In order to achieve the object as described above, according to an aspect of the present invention, a system for earthquake resistance of the structure, the reinforcing bar is installed to be inclined to reinforce the structure; First dampers installed at both ends of the reinforcing rod to absorb seismic energy by friction; And an oil damper for absorbing seismic energy using oil between the first and second fixing members installed below the reinforcing rod and a second damper having springs for absorbing seismic energy by elasticity. An earthquake resistant system is provided.

The reinforcing rods may be installed on both sides of the structure so as to be symmetrical to both sides, and the second dampers may be installed at portions divided into both sides.

The first damper may include a first connecting member to which one end of the reinforcing rod is connected; A pair of second connection members positioned at both sides with the other end of the first connection member interposed therebetween; A pair of friction members respectively disposed between the first connection member and the second connection member; A first fastening member fastened through the first and second connection members and the friction member such that the first and second connection members and the friction member are in close contact with each other; And a plurality of second fastening members penetrating both ends of the second connection member and fixed to the structure or the second damper.

The second damper, the first and the second fixing member is formed in a plate shape, the oil damper and the spring is installed to be stretched in the direction of each other, the spring is installed in the center, the oil damper A plurality of springs may be installed along the circumference of the spring.

According to the seismic system according to the present invention, it is easy to configure a system suitable for the earthquake according to the displacement of the building, the customized design according to the load, the seismic efficiency is increased, and the cost of replacement and change is low Economical installation, maintenance and management are possible.

1 is a perspective view showing a seismic system according to an embodiment of the present invention,
2 is a perspective view showing a friction damper of the seismic system according to an embodiment of the present invention,
3 is a perspective view showing the multi-damper of the seismic system according to an embodiment of the present invention,
4 to 6 are graphs showing displacements, speeds, and accelerations for buildings during an earthquake, respectively.
7 to 9 are graphs showing the displacements, speeds and accelerations of buildings in which only reinforcing bars are installed during an earthquake.
10 to 12 are graphs showing displacements, speeds, and accelerations during earthquakes of buildings with earthquake resistance systems according to the present invention, respectively.

As the inventive concept allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, but should be understood as including all changes, equivalents, and substitutes included in the spirit and scope of the present invention, and may be modified in various other forms. It is to be understood that the scope of the present invention is not limited to the following examples.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like or corresponding elements are denoted by the same reference numerals, and redundant explanations thereof will be omitted.

1 is a perspective view showing a seismic system according to an embodiment of the present invention.

As shown in FIG. 1, the seismic system 100 according to an embodiment of the present invention includes a reinforcement stand 110, a first damper 120 installed at both ends of the reinforcement stand 110, and a lower side of the reinforcement stand 110. It may include a second damper 130 is installed.

The reinforcing rod 110 is installed to be inclined for the reinforcement to the structure 2 to support the structure 2, for example, both ends of the structure 2 by the first damper 120 or the structure of the ground (3) It can be fixed so as to be supported. Here, the structure 2 may be, for example, a pillar provided in the building 1.

The reinforcement 110 may be installed on the structure 2 so as to be symmetrical to both sides, and may be installed in a plurality of spaced apart up and down on the structure 2, as in the present embodiment the second damper 130 in the middle That is, it may be additionally installed in the part divided into both sides.

The first dampers 120 are installed at both ends of the reinforcing rod 110 to absorb seismic energy by frictional force, for example, a first connection member 121 to which one end of the reinforcing rod 110 is connected, and a first A pair of second connecting members 123 positioned on both sides with the other end of the connecting member 121 interposed therebetween, and a pair of second connecting members 121 and the second connecting member 123 disposed between the first connecting member 121 and the second connecting member 123, respectively. First friction through the friction member 122, the first and second connection members 121 and 123 and the friction member 122 are fastened through the first and second connection members 121 and 123 and the friction member 122. A plurality of second fastening members 125 may be provided to penetrate both ends of the fastening member 124 and the second connection member 123 to be fixed to the structure 2 or the second damper 130.

The first connection member 121 may be connected to one end of the reinforcing rod 110 by a bolt and a nut.

The second connection member 123 may be coupled in a pair to be inclined to the first connection member 121 by the first fastening member 124.

The friction member 122 is made of a material for causing friction by being located between them when the second connection member 123 is rotated from the first connection member 121, thereby absorbing seismic energy due to such friction.

The first and second fastening members 124 and 125 may be formed of bolts and nuts, and may further include washers installed between the second and second connecting members 123.

The second damper 130 is seismic energy by the elasticity and the oil damper 133 to absorb the seismic energy using oil between the first and second fixing members (131, 132) installed on the lower side of the reinforcing rod 110. Springs 134 for absorbing are provided respectively.

The second damper 130 has a first and second fixing members 131 and 132 having a plate shape, and an oil damper 133 and a spring 134 are installed to expand and contract in the interval direction of each other. It is installed in the center, the oil damper 133 may be installed in a plurality along the circumference of the spring (134).

The first and second fixing members 131 and 132 are members to be fixed to the fixing object such as the first damper 120 or the structure 3 installed in the ground or the ground or the ends of the reinforcing rods 120 divided into both sides. For example, as in the present embodiment may be formed in a plate shape for being arranged side by side with each other, a fixing portion for fixing to the fixed object on one side, that is, the surface facing outward may be provided. Here, the fixing part may be formed of, for example, a hinge connection structure, a shaft joint structure, a support structure, or various other connection or installation structures.

Both ends of the oil damper 133 may be fixed to the first and second fixing members 131 and 132 by bolts, welding, or other joining methods, and the first and second fixing members 131 and 132 may be spaced apart from each other. It is installed and absorbs seismic energy by using oil filled inside, for example, oil is filled inside the cylinder, a flow path is formed in the piston installed inside the cylinder, and the piston is applied by external forces applied through both ends. When moving, the oil in the cylinder passes through the passage of the piston to convert the kinetic energy into thermal energy, etc., thereby absorbing the vibration energy due to the earthquake. Here, the oil damper 133 may be installed so that the direction of movement of the piston coincides with or corresponds to the distance direction between the first and second fixing members 131 and 132.

Both ends of the oil damper 133 are inserted into the through holes (not shown) formed in the first and second fixing members 131 and 132 and screwed to the bolts, thereby being fixed to the first and second fixing members 131 and 132. And damping by external forces through the second fixing members 131 and 132, and the number of the first and second fixing members 131 and 132 may be adjusted by separating and fastening the bolts according to the load.

The spring 134 may be formed of a compression coil spring as in the present embodiment, and may be installed so that both ends contact the first and second fixing members 131 and 132, respectively.

Thus, according to the seismic system 100 according to an embodiment of the present invention, when the earthquake energy applied to the building 1 or the structure 2 during the earthquake, the first damper 120 and the second damper 130 It is absorbed with different behavior to have excellent seismic efficiency.

4 to 6 are graphs showing displacements, speeds, and accelerations of the building during an earthquake, respectively, in which the reinforcing bar 110 and the dampers 120 and 130 are not installed. 7 to 9 are graphs showing displacements, speeds, and accelerations of the buildings in which only the reinforcing rods 110 are installed during an earthquake, respectively. 10 to 12 is a graph showing the displacement, speed and acceleration during the earthquake of the building in which the seismic system is installed according to the present invention. Dampers 120 and 130 are installed at both ends thereof. In addition, the criterion is that the bedrock is soft rock, the seismic force is transmitted to the lower part of the bedrock, and the seismic condition is magnitude 6.0.

As can be seen from Figures 4 to 12, when the reinforcement is installed on the building based on the building without the reinforcement and the damper, it can be seen that the displacement, speed and acceleration is reduced by 30%, the reinforcement and the damper is installed If the reinforcement and dampers are installed on the building, the displacement, speed and acceleration are reduced by 90%.

In addition, according to the seismic system according to the present invention, it is possible to facilitate the construction of a proper system according to the inter-layer displacement of the building, to withstand vertical and torsional loads, to adopt a high degree of freedom damper, to compensate for fatigue failure Can be.

In addition, according to the seismic system according to the present invention, it is possible to manufacture a variety of dampers in the shape of the coil-type carbonaceous damper, for example, the number of revolutions, linear diameter, coil diameter, pitch, etc. Partial replacement is possible, and the use of low-capacity multi-dampers and springs are economical, and the construction cost can be reduced during seismic reinforcement, and the number of dampers used can be reduced.

As described above, the present invention has been described with reference to the accompanying drawings, but various modifications and changes can be made without departing from the spirit of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the following claims.

110: reinforcing rod 120: first damper
121: first connecting member 122: friction member
123: second connecting member 124: first fastening member
125: second fastening member 130: second damper
131: first fixing member 132: second fixing member
133: oil damper 134: spring

Claims (4)

As a system for earthquake resistance of structures,
A reinforcing bar installed to be inclined to reinforce the structure;
A first damper installed between the upper end of the reinforcing rod and the structure and at the lower end of the reinforcing rod to absorb seismic energy by frictional force; And
An oil damper for absorbing seismic energy by using oil and a spring for absorbing seismic energy by elasticity are installed between the first and second fixing members installed below the first damper installed below the reinforcing rod. Second damper
Earthquake resistance system comprising a.
The method of claim 1, wherein the reinforcing bar,
The seismic system is installed on both sides of the structure so as to be symmetrical, and the second damper is installed in a portion divided into both sides.
The method of claim 1, wherein the first damper,
A first connecting member to which one end of the reinforcing rod is connected;
A pair of second connection members positioned at both sides with the other end of the first connection member interposed therebetween;
A pair of friction members respectively disposed between the first connection member and the second connection member;
A first fastening member fastened through the first and second connection members and the friction member such that the first and second connection members and the friction member are in close contact with each other; And
A plurality of second fastening members penetrating both ends of the second connecting member and fixed to the structure or the second damper;
Earthquake resistance system comprising a.
The method of claim 1, wherein the second damper,
The first and second fixing members are formed in a plate shape, and the oil damper and the spring are installed to expand and contract in a distance direction from each other, and the spring is installed at the center, and the oil damper is formed around the spring. A seismic system, characterized in that installed in plurality according to.

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