KR101383315B1 - Impact absorption type earthquake isolation device - Google Patents

Abstract

The present invention relates to a shock absorption type seismic isolation device which can be conveniently constructed due to the simple structure thereof and extend durability life by absorbing and reducing the shock against dynamic loads such as earthquakes and wind loads to buffer the shock applied to buildings and bridges. The shock absorption type seismic isolation device of the present invention comprises: a bottom plate; a top plate arranged on the bottom plate to be able to slide by an elastic body detaining member; an elastic body fitted on the elastic body detaining member to be installed inside the bottom plate and buffering lateral forces; and an auxiliary elastic body for connecting the bottom plate and the top plate to each other. According to the present invention, the durability life of buildings and bridges can be significantly extended since the elastic body can quickly absorb shock to prevent the shock from being transmitted to the buildings and the bridges even when the shock is applied from all directions.

Description

Isolation Device for Shock Absorption {Impact Absorption Type Earthquake Isolation Device}

The present invention relates to a seismic isolator is installed between the upper structure and the lower structure of the building and the bridge, more specifically, the structure is simple, convenient construction, used alone or applied to the existing bridge device earthquake and The present invention relates to a shock absorbing seismic isolator capable of buffering and reducing impacts on dynamic loads such as wind loads to alleviate the impacts on buildings and bridges, thereby extending the service life.

In general, important facilities such as power distribution facilities, gas tanks, bridges, and major buildings will be equipped with a seismic isolator on the lower structure to ensure vibration damping and stability against earthquakes.

As such, the seismic isolator is mainly used to perform the seismic isolation function using the coil spring, due to the characteristics of the coil spring is excellent shock-absorbing performance, but the shock absorbing power is low, there is little vibration absorption rate, there is a problem that the vibration lasts a long time. .

Such an isolation device using coil springs is not suitable for use in lightweight distribution facilities such as railroad bridges and lightweight structures such as gas tanks, as compared with weight structures such as railway bridges.

In addition, there is an isolator equipped with a hydraulic damper at the center of the polyurethane disc receiver, but this is a fundamental problem that it is difficult to make and maintain and manage because of using a viscous body.

As a seismic isolation device in which such a conventional problem is solved, Patent Registration No. 10-1162687 is disclosed in a patent publication.

Since the seismic isolator was developed to support light weight upper structures such as distribution facilities or gas tanks, the seismic isolation device was somewhat inadequate in supporting heavy structures such as bridges and buildings, and the number of components was relatively low. There was a significant difficulty in manufacturing, which was one of the factors that increase the manufacturing cost accordingly, there was a fundamental problem that is difficult to maintain and manage, especially due to the difficult structure.

The present invention has been devised to solve the above problems, and has a simple structure, which is convenient to manufacture, while buffering and reducing impacts on dynamic loads such as earthquakes and wind loads, thereby alleviating impacts to buildings and bridges. It is an object of the present invention to provide a shock absorbing seismic isolator that can extend the life.

It is another object of the present invention to provide a shock absorbing seismic isolator that can easily protect the bridge by buffering a sudden impact force in the horizontal direction with a unique function of the existing teaching device by easily applied to a variety of known teaching device I'm trying to.

According to an aspect of the present invention,

Bottom plate;

An upper plate slidably disposed on the lower plate via an elastic detaining member;

An elastic body inserted into the elastic detaining member and embedded in a lower plate to buffer a force in a transverse direction;

It characterized in that it comprises an auxiliary elastic body for interconnecting the lower plate and the upper plate.

The present invention for achieving the above another object,

A lower plate installed on a pier (or alternating); A top plate installed on the bridge top plate; An intermediate member disposed between the lower plate and the upper plate to transfer the load from the upper plate to the lower plate; In the seismic isolation device consisting of a movement control unit for controlling the movement and the reaction force on the lower plate or the upper plate,

The above-

A lower plate mounted on the intermediate member and connected to the lower plate through a movement control unit;

An upper plate slidably disposed on the lower plate via an elastic detaining member;

An elastic body inserted into the elastic detaining member and embedded in a lower plate to buffer a force in a transverse direction;

It characterized in that it comprises an auxiliary elastic body for interconnecting the lower plate and the upper plate.

In addition, in the present invention, the lower plate,

A housing having an accommodating portion accommodating the elastic body and a coupling portion through which an elastic bolt of the auxiliary elastic body is inserted;

It is characterized by consisting of a stainless steel plate built into the housing.

In addition, in the present invention, the coupling portion is characterized in that the expansion portion is further provided with reinforcement.

In addition, in the present invention, the lower plate,

A housing having an accommodating portion accommodating the elastic body, a coupling part through which the elastic bolt of the auxiliary elastic body is inserted, and a mounting part through which the connecting member of the movement control unit is inserted;

It is characterized by consisting of a stainless steel plate built into the housing.

Further, in the present invention,

The coupling portion is further provided with an extension portion;

The inner diameter of the mounting portion is characterized in that formed relatively larger than the outer diameter of the connecting member of the movement control unit.

In addition, in the present invention, the elastic member holding member,

A first fixing protrusion detachably fitted to the upper plate;

A mounting groove into which the fluorine resin plate is fitted is provided, and the second fixing protrusion is detachably coupled to the first fixing protrusion via a fastening means.

In addition, in the present invention, the auxiliary elastic body,

Fixture fixed to the upper plate via a fastening means;

An elastic bolt of one end material rotatably fitted to the fixture and the other end of which is inserted into a coupling part of the lower plate to pass therethrough;

A nut which is fastened to the other end of the elastic bolt to prevent separation from the coupling part;

It is characterized in that it comprises a pin member inserted into the other end of the elastic bolt to prevent the nut from being separated.

Further, in the present invention,

The lower plate on which the pad is placed is characterized in that the drain hole is formed.

In the present invention, the movement control unit,

A connection member inserted into a mounting portion of the lower plate and penetrating through a fixing portion of the lower plate;

An anchor coupled to the connection member exposed through the fixing part of the lower plate;

Characterized in that the fixing nut is fastened to the connection member to be disposed on the fixing portion of the lower plate.

Further, in the present invention,

The material of the elastic bolt is characterized in that the polyurethane.

According to the present invention, by increasing the intrinsic period of the bridge structure artificially long, the seismic load can be suppressed as much as possible to greatly improve the stability of the bridge structure, even if the impact force in all directions, the elastic body is quickly buffered This helps to prevent the transmission of shocks to buildings and bridges, which not only significantly extends the service life of buildings and bridges, but also makes them extremely simple in terms of cost, time, and cost. In addition, the manpower can be saved, and furthermore, since the elastic bolt assists the restoration of the upper plate and the elastic body, a side effect can be expected to reliably prepare for the next impact due to rapid restoration.

In addition, since it can be applied to a variety of known teaching devices, while maintaining the original functions (for example, rotation, vertical load, expansion and contraction) of the existing teaching device as it is, it can be used for dynamic loads such as earthquake or wind load. The shock force can be buffered and the vibration can be attenuated, so the durability of the bridge can be significantly extended.

1 is a perspective view showing a first embodiment of the shock absorbing seismic isolator according to the present invention.
2 and 3 are exploded perspective views of FIG.
4 and 5 are a plan sectional view and a front sectional view of FIG.
6 and 7 are an exploded perspective view and a cross-sectional view showing a second embodiment of the shock absorbing seismic isolator according to the present invention.
8 and 9 are an exploded perspective view and a cross-sectional view showing a third embodiment of the shock absorbing seismic isolator according to the present invention.
10 to 13 are a perspective view and an exploded perspective view and a sectional view showing a fourth embodiment of the shock absorbing seismic isolator according to the present invention.
14 and 15 are an exploded perspective view and a cross-sectional view showing a fifth embodiment of the shock absorbing seismic isolator according to the present invention.
16 and 17 is an exploded perspective view and a cross-sectional view showing a sixth embodiment of the shock absorbing seismic isolator according to the present invention.
18 and 19 is an exploded perspective view and a cross-sectional view showing a seventh embodiment of the shock absorbing seismic isolator according to the present invention.
20 and 21 are an exploded perspective view and a cross-sectional view showing an eighth embodiment of the shock absorbing seismic isolator according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a first embodiment of the shock absorbing seismic isolator according to the present invention, Figures 2 and 3 is an exploded perspective view of Figure 1, Figures 4 and 5 are a plan sectional view and a front sectional view of FIG. to be.

1 to 5, the first embodiment of the seismic isolator according to the present invention is composed of a lower plate 210 and an upper plate 220, an elastic body 230, and an auxiliary elastic body 240. It is installed on upper structures, buildings, bridges, etc. to stably support the structure, and functions to buffer and reduce impact force against dynamic loads such as earthquakes and wind loads, and to damp vibrations.

For reference, the seismic isolator of the first to third embodiments is installed between the building and the ground independently to perform the seismic isolation function, or is installed on the upper surface of the known bridge device installed between the bridge deck and the bridge (or alternating) It will perform the isolation function.

2, the lower plate 210 is composed of a housing 211 and a stainless steel plate 212.

The housing 211 has a receiving portion 211a and a coupling portion 211b.

The accommodating part 211a is a groove in which the stainless steel plate 212 and the elastic body 230 are opened in one direction so as to be accommodated therein, and the coupling part 211b is an elastic bolt 242 of the auxiliary elastic body 240. Is a hole formed in the flange protruding outward from the circumferential surface so that can be inserted through.

Meanwhile, referring to FIG. 5, the truncated conical portion 211b-1 is formed on the upper side of the coupling portion 211b and the insertion portion 211b-2 is formed on the lower side of the coupling portion 211b.

Here, when the elastic bolt 242 is elastically deformed (bending) by the lower plate 210 and the upper plate 220, the expansion part 211b-1 accommodates the deformation angle as much as possible and the elastic bolt 242 is It is used to prevent breakage (shear).

One end portion of the bush 243 constituting the auxiliary elastic body 240 is inserted into the insertion portion 211b-2.

2 and 3, the upper plate 220 is a plate having a predetermined thickness, and includes an elastic detaining member 221 and a fluorine resin plate 222, and is slidable on the lower plate 210. Is placed.

A coupling hole 220a is formed in the center of the upper plate 220.

An elastic detaining member 221 is inserted into and coupled to the coupling hole 220a.

The elastic detaining member 221 is divided into a first fixing protrusion 221a and a second fixing protrusion 221b to be mutually coupled through a fastening member (for example, a bolt), and to fix the elastic body 230. Function

The first fixing protrusion 221a includes a protrusion 221a-1, and is fitted into the coupling hole 220a of the upper plate 220 through the protrusion 221a-1 to be coupled to each other. And, if necessary, the first fixing protrusion 221a may be manufactured integrally with the upper plate 220.

The second fixing protrusion 221b includes a mounting groove 221b-1, and the fluorine resin plate 220 is installed in the mounting groove 221b-1.

The fluororesin plate 220 is made of polytetrafluoroethylene (PTFE), which is commonly known under the trade names Teflon and Pluon, and is slidable on the stainless plate 212 installed in the lower plate 210. Minimize friction when moving against each other.

On the other hand, when the elastic body 230 is pressed by the elastic body detaining member 221, the elastic body 230 is compressed and convexly protruded in the vertical direction in consideration of this, the elastic body 230 is the receiving portion (211a) of the lower plate 210 It is necessary to arrange in the middle, and furthermore, by limiting the movement (up and down movement) of the elastic body 230, the elastic body detaining member 221 can always press the pressure with a uniform force to the force according to the position movement of the elastic body 230 It is necessary to prevent breakage of the elastic retainer member 221 due to the imbalance.

To this end, in the present embodiment, the movement preventing portions 221a-2 and 221b-2 protruding outwards are formed in the first fixing protrusion 221a and the second fixing protrusion 221b, respectively.

2 and 3, the elastic body 230 is fitted to an elastic detaining member 221 formed between the upper plate 220 and the lower plate 210 to buffer the force in the horizontal direction (horizontal direction). Function

The material of the elastic body 230 is a synthetic resin material that can buffer the external impact, in the case of the present embodiment, a polyurethane (polyurethane) was applied, in addition to that if it can perform the same function in the field, Anything can be applied.

2 and 3, the auxiliary elastic body 240 includes a fixture 241, an elastic bolt 242, a bush 243, a washer 244, a nut 245, and a pin 246. While connecting the lower plate 210 and the upper plate 220 serves to assist this to be quickly restored when the upper plate 220 and the elastic body 230 is restored.

The fixture 241 is disposed on the lower surface of the upper plate 220 is fixed via a fastening member (for example, bolts and nuts).

In particular, the fastener 241 is formed with a head receiving portion 241a, the inside of the head receiving portion 241a is an elastic bolt (see Fig. 5) is accommodated so that the hemispherical head (see Fig. 5) of the elastic bolt 242 is rotated ( 242 is formed to correspond to the hemispherical head (refer to FIG. 5).

The elastic bolt 242 is a synthetic resin material of the elastic material, in the case of the present embodiment, a polyurethane (polyurethane) was applied, in addition to this, if it can perform the same function in the field, any of the well-known application is carried out It is possible.

The hemispherical head (see FIG. 5) formed at one end of the elastic bolt 242 is pivotally fitted to the aforementioned fixture 241, and the other end is fitted to the engaging portion 211b of the lower plate 210 to penetrate therethrough. do.

The bush 243 is inserted into the elastic bolt 242 to be inserted into the insertion portion 211b-2 of the lower plate 210 to support the lower end of the elastic bolt 242.

The washer 244 is fitted to the elastic bolt 242 is disposed on the lower surface of the bush (243).

The nut 245 is fastened to the elastic bolt 242 to prevent the bush 243 and the washer 244 fitted to the elastic bolt 242 to prevent the departure.

The pin member 246 is fitted to the elastic bolt 242 to prevent loosening and detachment of the nut 245.

The operation of the first embodiment of the shock absorbing seismic isolator according to the present invention having the configuration described above will be described.

As described above, the seismic isolator may be installed in buildings and bridges, and will be described below in detail by way of example.

First, the seismic isolation device according to the present invention may be installed between a known bridge device (not shown) and a bridge top plate (not shown) installed on a bridge (or shift; not shown), but more specifically, the lower plate 210. ) Is installed on the upper surface of the bridge device, the upper plate 220 is installed on the lower surface of the bridge upper plate.

When the earthquake load due to the earthquake is applied to the bridge in the above-described state, the earthquake load transmitted through the bridge and the bridge device is attenuated by the seismic isolation device installed between the bridge device and the bridge deck, whereby Seismic loads can be prevented from being transmitted, thereby reducing risks such as misalignment and falling of bridge decks.

In more detail, when the seismic load is transmitted to the pier, the pier and the bridge device are moved together in the transverse direction, and thus the lower plate 210 installed in the bridge device is also moved together.

At this time, the upper plate 220 does not move together when the lower plate 210 is moved without sliding only the lower plate 210 to the fluorine resin plate 222 via the stainless steel plate 212 as a bridge structure of the bridge structure. The seismic load is naturally attenuated by increasing the inherent period, thereby preventing the shaking (vibration) and twisting because the seismic load is not transmitted to the bridge deck.

In addition, in the case of the elastic body 230 embedded in the detaining member 221 and built into the lower plate 210, the shock in the lateral direction is buffered while being gradually pressed by the housing 211 of the lower plate 210 which is slidingly moved. If the load acts in the opposite direction, the elastic body 230 is quickly restored while quickly preparing for the next impact.

On the other hand, the auxiliary elastic body 240 for interconnecting the upper plate 220 and the lower plate 210 is also deformed due to the movement of the lower plate 210, which will be described in more detail, the head of the fixture 241 The head portion of the elastic bolt 242 accommodated in the receiving portion 241a is naturally rotated along the spherical surface of the head receiving portion 241a, and at the same time, the body portion of the elastic bolt 242 is gradually bent and the lower plate 210 is rotated. The expansion portion (211b-1) of the butt to limit the movement of the lower plate 220 while being inclined, if the force acts in the opposite direction the elastic bolt 242 is quickly restored while the lower plate 220 and the elastic body 230 Will assist in the restoration of).

Therefore, by artificially increasing the intrinsic period of the bridge structure through the above action, it is possible to suppress the induction of earthquake load as much as possible to greatly improve the stability of the bridge structure, even if an impact force in all directions is applied to the elastic body ( Since the shock absorber 230 quickly buffers and prevents shock from being transmitted to the bridge, the life span of the bridge can be significantly extended, and the elastic bolt 242 further includes the lower plate 210 and the elastic body 230. As a secondary aid in the restoration of), it is also possible to expect the side effects of being able to reliably prepare for the next impact of rapid restoration.

6 and 7 are an exploded perspective view and a cross-sectional view showing a second embodiment of the shock absorbing seismic isolator according to the present invention.

The second embodiment of the seismic isolator is substantially the same in structure as the first embodiment, except that the shape is rectangular and two pairs of elastic bodies 230 are different from the first embodiment. Since the operation is the same, a detailed description thereof will replace the description of the first embodiment described above.

8 and 9 are an exploded perspective view and a cross-sectional view showing a third embodiment of the shock absorbing seismic isolator according to the present invention.

The third embodiment of the seismic isolator is also substantially the same as the overall structure of the first embodiment mentioned above, except that the shape of the rectangular shape and the elastic body 230 is only four pairs, the first embodiment Examples and operations are the same, so a detailed description thereof replaces the description of the first embodiment mentioned above.

10 to 13 are a perspective view, an exploded perspective view and a cross-sectional view showing a fourth embodiment of the shock absorbing seismic isolator according to the present invention.

If the seismic isolator of the first to third embodiments is to perform the seismic isolation function in combination with the bridge device installed on the floor and the bridge of the building in an independent form, the seismic isolation device of the fourth to eighth embodiments to be described below is the existing It is applied to the bridge is integrally coupled to, and will be described in more detail below.

For reference, the seismic isolator according to the fourth embodiment is a known disk bearing, and the existing disk support has changed the structure of the upper plate installed in the bridge deck, which adds the seismic isolation function to the original function. It is worth noting.

10 to 12, the seismic isolator according to the present invention, the lower plate 100 and the upper plate 200, the intermediate member 300 and the movement control unit 400, the bridge (or alternating) and the bridge It is installed between the upper plates to absorb and receive the impact load by the superstructure, to accommodate the rotational load due to the use of the bridge at all times, and to cushion the impact force against dynamic loads such as earthquakes and wind loads and to damp vibrations. Function

The lower plate 100 and the upper plate 200 are interconnected by the movement control unit 400.

Referring to FIGS. 11 and 12, the lower plate 100 is a plate having a predetermined thickness as a whole, and a pad seating groove 110 in which the middle member 300 is seated is formed at the center of the upper surface, and a pad seating groove 110. The pin hole 120 is formed in the center of the shear pin 213 is inserted, the fixing portion 140 is inserted into the connecting member 410 is protruded outwardly.

In particular, it should be noted that the lower plate 100 is formed with a drain hole 130 in communication with the pad seating groove 110.

Here, the drain port 130 is used to discharge water to prevent the water from pooling in the pad seating groove 110, thereby preventing the pad seating groove 110 from corrosion, as well as the pad seating groove ( By preventing the damage of the intermediate member 300 due to the corrosion of the 110 as possible to maintain the optimum elastic state at all times, it can be expected a side effect to significantly lower the replacement cycle of the intermediate member (300).

11 to 13, the intermediate member 300 is installed between the lower plate 100 and the upper plate 200 to transfer the load from the upper plate 200 to the lower plate 100.

The intermediate member 300 is a polyurethane disk 310, the overall shape of the donut shape, the circumferential surface is formed in the V-shaped groove inward.

The intermediate member 300 is mounted on the upper plate 100 and is fixed by the shear pin 213 of the lower plate 210.

11 to 13, the upper plate 200 is composed of a lower plate 210, an upper plate 220, an elastic body 230, and an auxiliary elastic body 240, and is placed on the intermediate member 300. Fixing the 300, it is connected to the lower plate 100 via the movement control unit 400.

11 and 12, the lower plate 210 includes a housing 211, a stainless plate 212, and a shear pin 213.

The housing 211 includes a receiving portion 211a, a coupling portion 211b, and a mounting portion 211c.

The accommodating part 211a is a groove in which the stainless steel plate 212 and the elastic body 230 are opened in one direction so as to be accommodated therein, and the coupling part 211b is an elastic bolt 242 of the auxiliary elastic body 240. Is a hole formed in the flange projecting outward from the circumferential surface so that the insertion can be inserted, the mounting portion 211c is a flange protruding outward from the circumferential surface so that the connection member 410 of the movement control unit 400 can be inserted through It is a hole formed in.

Meanwhile, referring to FIGS. 12 and 13, the truncated conical portion 211b-1 is formed on the upper side of the coupling portion 211b and the insertion portion 211b-2 is formed on the lower side thereof.

Here, when the elastic bolt 242 is deformed (bending) by the lower plate 210 and the upper plate 220, the expansion part 211b-1 receives the deformation angle as much as possible and the elastic bolt 242 is broken. It is used to prevent losing.

One end portion of the bush 243 constituting the auxiliary elastic body 240 is inserted into the insertion portion 211b-2.

On the other hand, referring to Figure 12, the inner diameter of the hole of the mounting portion 211c is preferably formed relatively larger than the outer diameter (thickness) of the connecting member 410.

According to this embodiment, since the inner diameter of the hole of the mounting portion 211c is formed to be relatively larger than the outer diameter (thickness) of the connecting member 410, the lower plate (the plate at the corresponding point during the rotational load action due to the use of the bridge at all times) 210 is easily rotated to accommodate the rotational load via the intermediate member 300.

11 and 12, the upper plate 220 is a plate having a predetermined thickness, and includes an elastic detaining member 221 and a fluorine resin plate 222, and is slidable on the lower plate 210. Is placed.

A coupling hole 220a is formed in the center of the upper plate 220.

An elastic detaining member 221 is inserted into and coupled to the coupling hole 220a.

The elastic detaining member 221 is divided into a first fixing protrusion 221a and a second fixing protrusion 221b to be mutually coupled through a fastening member (for example, a bolt), and to fix the elastic body 230. Function

The first fixing protrusion 221a includes a protrusion 221a-1, and is fitted into the coupling hole 220a of the upper plate 220 through the protrusion 221a-1 to be coupled to each other. And, if necessary, the first fixing protrusion 221a may be manufactured integrally with the upper plate 220.

The second fixing protrusion 221b includes a mounting groove 221b-1, and the fluorine resin plate 220 is installed in the mounting groove 221b-1.

The fluororesin plate 220 is made of polytetrafluoroethylene (PTFE), which is commonly known under the trade names Teflon and Pluon, and is slidable on the stainless plate 212 installed in the lower plate 210. Minimize friction when moving against each other.

On the other hand, when the elastic body 230 is pressed by the elastic body detaining member 221, the elastic body 230 is compressed and convexly protruded in the vertical direction in consideration of this, the elastic body 230 is the receiving portion (211a) of the lower plate 210 It is necessary to arrange in the middle, and furthermore, by limiting the movement (up and down movement) of the elastic body 230, the elastic body detaining member 221 can always press the pressure with a uniform force to the force according to the position movement of the elastic body 230 It is necessary to prevent breakage of the elastic retainer member 221 due to the imbalance.

To this end, in the present embodiment, the movement preventing portions 221a-2 and 221b-2 protruding outwards are formed in the first fixing protrusion 221a and the second fixing protrusion 221b, respectively.

11 and 12, the elastic body 230 is fitted to an elastic detaining member 221 formed between the upper plate 220 and the lower plate 210 to cushion the force in the horizontal direction (horizontal direction). Function

The material of the elastic body 230 is a synthetic resin material that can buffer the external impact, in the case of the present embodiment, a polyurethane (polyurethane) was applied, in addition to that if it can perform the same function in the field, Anything can be applied.

11 to 13, the auxiliary elastic body 240 includes a fixture 241, an elastic bolt 242, a bush 243, a washer 244, a nut 245, and a pin 246. While connecting the lower plate 210 and the upper plate 220 serves to assist this to be quickly restored when the upper plate 220 and the elastic body 230 is restored.

The fixture 241 is disposed on the lower surface of the upper plate 220 is fixed via a fastening member (for example, bolts and nuts).

In particular, the fastener 241 is formed with a head receiving portion 241a, the inside of the head receiving portion 241a is a hemi-spherical head (see Fig. 13) of the elastic bolt 242 is accommodated elastic bolt ( 242 corresponding to the hemispherical head (see FIG. 13).

The elastic bolt 242 is a synthetic resin material of the elastic material, in the case of the present embodiment, a polyurethane (polyurethane) was applied, in addition to this, if it can perform the same function in the field, any of the well-known application is carried out It is possible.

The hemispherical head (see FIG. 13) formed at one end of the elastic bolt 242 is pivotally fitted to the aforementioned fixture 241, and the other end is fitted to the engaging portion 211b of the lower plate 210 to penetrate therethrough. do.

The bush 243 is inserted into the elastic bolt 242 and inserted into the insertion portion 211b-2 of the lower plate 210.

The washer 244 is fitted to the elastic bolt 242 is disposed on the lower surface of the bush (243).

The nut 245 is fastened to the elastic bolt 242 to prevent the separation of the bush 243 and the washer 244 fitted to the elastic bolt 242.

The pin member 246 is fitted to the elastic bolt 242 to prevent loosening and detachment of the nut 245.

The movement control unit 400 is composed of a connection member 410 and the anchor 420 and the fixing nut 430 to simultaneously perform the function of controlling the side reaction force while connecting the lower plate 100 and the upper plate 200. .

The connecting member 410 is a well-known bolt, is inserted into the mounting portion 211c of the lower plate 210 to penetrate the fixing portion 140 of the lower plate 100.

The anchor 420 is coupled (fastened) to the connection member 410 exposed through the fixing part 140 of the lower plate 100, the lower plate 100 via the anchor 420 is the pier (or alternation) Is fixed to.

The fixing nut 430 is fastened to the connection member 410 and is disposed on the fixing part 140 of the lower plate 100, where the fixing nut 430 is lowered to the upper surface of the anchor 420. Pressing the lower plate 100 so as to prevent the lower plate 100 to lift while functioning to prevent the loosening of the connection member 410.

The operation of the fourth embodiment of the base isolation device according to the present invention having the above configuration will be described.

First, a seismic isolator according to the present invention is installed between a bridge (or alternating; not shown) and a bridge deck (not shown).

When the vertical load is repeatedly generated in the bridge in the state as described above, the impact load by the bridge top plate is transmitted to the intermediate member 300 through the top plate 200, the intermediate member 300 absorbs the impact load And the buffer is accommodated, when the rotational force is applied to the lower plate 210 is rotated in the rotation direction to press the intermediate member 300, thereby causing the V-shaped groove portion of the intermediate member 300 to cause deformation To accommodate the rotation.

On the other hand, when an earthquake load due to an earthquake is applied to the bridge, the earthquake load transmitted through the bridge is attenuated by the seismic isolation device, which prevents the earthquake load from being transferred to the bridge deck, so that the bridge deck is displaced due to the earthquake load. And risks such as failing.

In more detail, when the seismic load is transmitted to the piers, the lower plate 210 of the seismic isolator fixed to the piers moves in the transverse direction.

At this time, the upper plate 220 does not move together when the lower plate 210 is moved without sliding only the lower plate 210 to the fluorine resin plate 222 via the stainless steel plate 212 as a bridge structure of the bridge structure. Since the natural period is increased, the seismic load is naturally attenuated so that the seismic load is not transmitted to the bridge deck to prevent shaking (vibration) and twisting.

In addition, in the case of the elastic body 230 embedded in the detaining member 221 and built into the lower plate 210, the shock in the lateral direction is buffered while being gradually pressed by the housing 211 of the lower plate 210 which is slidingly moved. If the load acts in the opposite direction, the elastic body 230 is quickly restored while quickly preparing for the next impact.

On the other hand, the auxiliary elastic body 240 for interconnecting the upper plate 220 and the lower plate 210 is also deformed due to the movement of the lower plate 210, which will be described in more detail, the head of the fixture 241 The head portion of the elastic bolt 242 accommodated in the receiving portion 241a is naturally rotated along the spherical surface of the head receiving portion 241a, and at the same time, the body portion of the elastic bolt 242 is gradually bent and the lower plate 210 is rotated. The expansion portion (211b-1) of the butt to limit the movement of the lower plate 220 while being inclined, if the force acts in the opposite direction the elastic bolt 242 is quickly restored while the lower plate 220 and the elastic body 230 Will assist in the restoration of).

Therefore, by artificially increasing the intrinsic period of the bridge structure through the above action, it is possible to suppress the induction of earthquake load as much as possible to greatly improve the stability of the bridge structure, even if an impact force in all directions is applied to the elastic body ( Since the shock absorber 230 quickly buffers and prevents shock from being transmitted to the bridge, the life span of the bridge can be significantly extended, and the elastic bolt 242 further includes the lower plate 210 and the elastic body 230. As a secondary aid in the restoration of), it is also possible to expect the side effects of being able to reliably prepare for the next impact of rapid restoration.

14 and 15 are an exploded perspective view and a cross-sectional view showing a fifth embodiment of the shock absorbing seismic isolator according to the present invention.

The seismic isolator of the fifth embodiment is a known port bearing, which is a structure of the upper plate installed on the bridge deck so as to buffer it when a horizontal shock such as an earthquake occurs. Since it is substantially the same as the embodiment will be described briefly.

The seismic isolator is composed of a lower plate 100 and the upper plate 200, the intermediate member 300 and the movement control unit 400.

A rubber pad accommodation groove 150 is formed in the lower plate 100, and a rubber pad 310 constituting the intermediate member 300 is accommodated in the rubber pad accommodation groove 150.

In addition, a fixing part 140 is formed on the flange protruding outward, and the connecting part 410 constituting the movement control unit 400 is inserted through the fixing part 140.

The intermediate member 300 is composed of a rubber pad 310, a sealing ring 320 and a ring member 330.

The rubber pad 310 is prevented from being separated by the sealing ring 320 that is accommodated in the rubber pad receiving groove 150 and inserted together.

Here, the rubber pad 310 not only gives the rotation angle of the upper plate 200 but also stably buffers the load transmitted from the upper plate 200 with an even vertical load distribution.

The ring member 330, as shown in Figure 15, is installed on the circumferential surface of the pressing protrusion 214 of the lower plate 210 that the infiltration water from the outside while supporting the lower plate 210 elastically To prevent it.

The upper plate 200 is composed of a lower plate 210, an upper plate 220, an elastic body 230 and an auxiliary elastic body 240 is mounted on the intermediate member 300 to fix the intermediate member 300, the movement control It is connected to the lower plate 100 via the unit 400.

The lower plate 210 and the upper plate 220, the elastic body 230 and the auxiliary elastic body 240 is substantially the same as the configuration of the fourth embodiment described above, but instead of the pressing pin 213 the pressing projection 214 Since only is integrally formed on the bottom surface of the lower plate 210, a detailed description thereof will be replaced by the fourth embodiment.

In addition, the movement control unit 400 is also substantially the same as the above-described fourth embodiment, a detailed description thereof will be replaced by the description of the fourth embodiment.

16 and 17 are an exploded perspective view and a cross-sectional view showing a sixth embodiment of the shock absorbing seismic isolator according to the present invention.

The seismic isolator of the sixth embodiment is a known pin bearing, and has a unique function of accommodating it when a rotational force is generated, and a structure of an upper plate installed on a bridge deck to buffer it when a horizontal shock such as an earthquake occurs. Will be changed.

The pin support is also well known in the art and thus will be briefly described.

16 and 17, the seismic isolator is composed of a lower plate 100, an upper plate 200, an intermediate member 300, and a movement control unit 400.

The lower plate 100 is provided with a pin seating groove 160, and the middle member 300 is seated in the pin seating groove 160.

Referring to FIGS. 16 and 17, the intermediate member 300 is a known pin 350. In this embodiment, the intermediate member 300 is mounted on the pin seating groove 160 to be pin pins 215 of the lower plate 210. Wrapped.

Both ends of the pin 350 are provided with a fastening protrusion 351 extending outwardly and having a thread tab formed on an outer circumferential surface thereof. The pin member is fitted to the

Referring to FIGS. 16 and 17, the movement control unit 400 is a circular cover 440 having a hole formed in the center thereof, and in this embodiment, the pin seating grooves 160 are opposed to each other based on the pin 350. And it is fitted to both ends of the pin fitting portion 215 serves to secure the pin seating groove 160 and the pin fitting portion 215 is not separated from each other.

After the cover 440 is coupled as described above, the nut and the pin member are inserted into the fastening protrusion 351 exposed through the cover 440 to prevent the cover 440 from being separated.

Referring to FIGS. 16 and 17, the upper plate 200 includes a lower plate 210, an upper plate 220, an elastic body 230, and an auxiliary elastic body 240, and is mounted on the intermediate member 300. The cover 440 of the movement control unit 400 is interconnected with the lower plate 100.

The lower plate 210 and the upper plate 220, the elastic body 230 and the auxiliary elastic body 240 is substantially the same as the configuration of the fourth embodiment described above, but instead of the front pin 213 pin seating groove 160 Since the pin-sensitive portion 215 having a structure corresponding to) is integrally formed on the bottom surface of the lower plate 210, the specific configuration and operation thereof will be replaced by the description of the fourth embodiment.

18 and 19 are exploded perspective and coupling cross-sectional view showing a seventh embodiment of the shock-absorbing base isolation device according to the present invention.

The seismic isolator of the seventh embodiment is a known spherical bearing, which is bidirectionally movable, and can also be applied to one-way fixed and bidirectional fixed.

The seismic isolator is to change the structure of the top plate is installed on the bridge top plate to cushion the sudden occurrence of a horizontal shock, such as earthquake, with a unique function that can accommodate the rotational force and expansion and contraction.

The spherical bearing is also well known in the art and thus will be briefly described.

18 and 19, the seismic isolator is composed of a lower plate 100 and an upper plate 200, an intermediate member 300, and a movement control unit 400.

The lower plate 100 is provided with a bearing seating groove 170 having a hemispherical cross section and a sealing receiving groove 180 formed along the circumference of the bearing seating groove 170.

Here, a bearing plate 360 is mounted on the bearing seating groove 170, and a sealing member S is inserted into the sealing receiving groove 180 to protrude upward.

In addition, the bearing seating groove 170 may be formed to be relatively larger than the diameter of the bottom surface of the bearing plate 360 so that the bearing plate 360 may be rotatable in the bearing seating groove 170.

18 and 19, the intermediate member 300 includes a bearing plate 360, a fluorine resin plate 370, and a sealing member S.

A resin plate seating groove 361 is provided on the upper surface of the bearing plate 360 so that the fluorine resin plate 370 is inserted and fixed, and a hemispherical shape corresponding to the bearing seating groove 170 of the lower plate 100 is provided on the lower surface of the bearing plate 360. The protrusions are integrally formed.

In addition, the bearing plate 360 transmits the load transmitted from the upper plate 200 to the lower plate 100 or rotates when sag.

The fluororesin plate 370 is manufactured by using polytetrafluoroethylene (PTFE), which is commonly known under the brand name 'Teflon', and the fluorine resin plate 370 is a mirror of the lower plate 210. It is in surface contact with the plate 216, which is for accommodating the stretching behavior in the sliding state.

The sealing member S is made of silicon or rubber material having excellent elastic restoring force. The sealing member (S) is installed in the sealing receiving groove 180 serves to block foreign matter inflow from the outside.

18 and 19, the movement control unit 400 is a known side block 450 having a 'b' shape, in this embodiment fastening means to the blocks formed on both sides of the lower plate 100 (For example, a bolt) is fixed as a medium to control the side reaction force of the upper plate (200).

Referring to FIGS. 18 and 19, the upper plate 200 includes a lower plate 210, an upper plate 220, an elastic body 230, and an auxiliary elastic body 240 mounted on the intermediate member 300. Movement in the axial direction and the perpendicular direction of the axial direction is limited by the blocks formed on both sides of the lower plate 100, the side reaction force is limited by the side block 450 of the movement control unit 400.

The above-mentioned mirror plate 216 is installed on the bottom of the lower plate 210.

Here, the mirror plate 216 is a known stainless plate.

The mirror plate 216 is in surface contact with the fluorine resin plate 370 installed on the bearing plate 360.

The upper plate 200 is different from the foregoing fourth to sixth embodiments in that the shape of the lower plate 210 is generally square, but the overall configuration is substantially the same as the above-described embodiments, Overlapping descriptions such as actions should be omitted.

20 and 21 are an exploded perspective view and a cross-sectional view showing an eighth embodiment of the shock absorbing seismic isolator according to the present invention.

The seismic isolator of the eighth embodiment is a known pivot bearing, which has a unique function of accommodating rotational force, and a structure of the upper plate installed on the bridge deck to cushion the horizontal impact such as an earthquake. Will be changed.

The pivot base is also well known in the art and thus will be briefly described.

20 and 21, the seismic isolator is composed of a lower plate 100 and an upper plate 200, an intermediate member 300 and a movement control unit 400.

The hemispherical head 380 constituting the intermediate member 300 is integrally formed at the upper center of the lower plate 100, and the head receiving portion 390 constituting the intermediate member 300 is formed at the bottom of the upper plate 200. It is formed integrally.

The hemispherical heads 380 and the head receiving portion 390 are respectively formed with dolthes 381 and 391.

The hemispherical head 380 is inserted into the head receiving portion 390 to receive the rotational force through the line or spherical contact between the hemispherical head 380 and the head receiving portion 390 when the rotation force is generated due to the sagging of the upper plate 200. In this embodiment, spherical contact is made.

The intermediate member 300 is composed of a hemispherical head 380 and the head receiving portion 390, as described above.

The movement control unit 400 is a port ring 460 consisting of a pair of semi-circular band, in the present embodiment is coupled to the dolje 381, 391 to surround the hemispherical head 380 and the head receiving portion 390 It is fixed via a member (for example, a bolt).

The upper plate 200 is composed of the lower plate 210 and the upper plate 220, the elastic body 230 and the auxiliary elastic body 240 is mounted on the intermediate member 300, the movement limiting member 400 through the It is connected to the lower plate 100.

The head receiving portion 390 of the intermediate member 300 described above is integrally formed on the bottom of the lower plate 210.

The head receiving portion 390 is coupled to the hemispherical head 380 of the lower plate 100 so as to be in surface contact.

Since the overall configuration of the top plate 200 is substantially the same as those of the fourth to seventh embodiments, redundant descriptions such as configuration and operation will be omitted.

According to the present embodiment, even when an impact force in all directions is applied, the elastic body quickly absorbs and relieves it, thereby preventing shock from being transmitted to the bridge, thereby significantly extending the durability life of the bridge, The cost, time and manpower required for maintenance activities can be saved, and furthermore, the elastic bolts assist the restoration of the upper plate and the elastic body, so that the side effects of the rapid restoration can be reliably prepared. Can be.

In the present embodiment, various embodiments such as pivot, spherical, port, disk support, and the like have been exemplified. In addition, the present invention may be applied to various known (bridge) bearings. Not desirable

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

100: bottom plate 110: pad seating groove 120: pin hole
130: drain port 140: fixing part 150: rubber pad receiving groove
160: pin seating groove 170: bearing seating groove 200: top plate
210: lower plate 211: housing 211a: receiving portion
211b: coupling portion 211b-1: extension portion 211b-2: insertion portion
211c: mounting portion 212: stainless steel plate 213: shear pin
214: pressure protrusion 215: pin fitting portion 216: mirror plate
220: upper plate 221: elastic body detaining member 221a: first fixing protrusion
221b: second fixing protrusion 221b-1: mounting groove 222: fluorine resin plate
230: elastic body 240: auxiliary elastic body 241: fastener
241a: head receiving portion 242: elastic bolt 243: bush
244: washer 245: nut 246: pin member
300: intermediate member 310: disk 320: rubber pad
330: sealing ring 340: ring member 350: pin
360: bearing plate 361: resin plate seating groove 370: fluorine resin plate
380: hemispherical head 381: dolte 390: head receiving portion
391: Dolte 400: movement control unit 410: connecting member
420: anchor 430: nut 440: cover
450: side block 460: port ring

Claims (11)

A lower plate having a receiving portion opened upward;
An upper plate which is inserted into the receiving portion of the lower plate and is slidably abutted, the upper plate being supported by the elastic retaining member and disposed above the lower plate;
And an elastic body surrounding the elastic body detaining member and embedded in the receiving portion of the lower plate to buffer the force in the transverse direction.
The elastic detaining member,
A first fixing protrusion detachably fitted to the upper plate;
A seismic isolator for shock absorption, comprising: a second fixing protrusion having a mounting groove into which a fluorine resin plate is inserted, and detachably coupled to the first fixing protrusion via a fastening means.
A lower plate installed on a pier (or alternating); A top plate installed on the bridge top plate; An intermediate member disposed between the lower plate and the upper plate to transfer the load from the upper plate to the lower plate; In the seismic isolator composed of a movement control unit for controlling the movement and the reaction force on the lower plate or the upper plate,
The above-
A lower plate mounted on the intermediate member and having a receiving portion opened upward;
An upper plate which is inserted into the receiving portion of the lower plate and is slidably abutted, the upper plate being supported by the elastic retaining member and disposed above the lower plate;
And an elastic body wrapped around the elastic body detaining member and installed in the receiving portion of the lower plate to buffer the force in the transverse direction.
A lower plate composed of a housing having an upper opening and a coupling portion, and a stainless plate embedded in the housing;
An upper plate which is inserted into the receiving portion of the lower plate and is slidably abutted, the upper plate being supported by the elastic retaining member and disposed above the lower plate;
An elastic body surrounding the elastic detaining member and embedded in the receiving portion of the lower plate to buffer the force in the transverse direction;
And an auxiliary elastic body connecting the lower plate and the upper plate to each other and having an elastic bolt inserted through the coupling part.
The method of claim 3,
The shock absorbing seismic isolator, characterized in that the coupling portion is further provided with an extension.
3. The method of claim 2,
Further comprising an auxiliary elastic body interconnecting the lower plate and the upper plate;
The lower plate,
A housing having an accommodating portion accommodating the elastic body, a coupling part through which the elastic bolt of the auxiliary elastic body is inserted, and a mounting part through which the connecting member of the movement control unit is inserted;
A shock absorbing seismic isolator, characterized in that consisting of a stainless steel plate in the housing.
6. The method of claim 5,
The coupling portion is further provided with an extension portion;
The inner diameter of the mounting portion is shock absorbing seismic isolation device, characterized in that formed larger than the outer diameter of the connecting member of the mobile control unit.
3. The method of claim 2,
The elastic detaining member,
A first fixing protrusion detachably fitted to the upper plate;
A seismic isolator for shock absorption, comprising: a second fixing protrusion having a mounting groove into which a fluorine resin plate is inserted, and detachably coupled to the first fixing protrusion via a fastening means.
The method according to claim 3 or 5,
The auxiliary elastic body,
Fixture fixed to the upper plate via a fastening means;
An elastic bolt of one end material rotatably fitted to the fixture and the other end of which is inserted into a coupling part of the lower plate to pass therethrough;
A nut which is fastened to the other end of the elastic bolt to prevent separation from the coupling part;
A shock absorbing seismic isolator characterized in that it comprises a pin member inserted into the other end of the elastic bolt to prevent the nut from being separated.
3. The method of claim 2,
A shock absorbing seismic isolator, characterized in that the drain plate is formed on the lower plate on which the intermediate member is placed.
3. The method of claim 2,
The movement control unit,
A connection member inserted into a mounting portion of the lower plate and penetrating through a fixing portion of the lower plate;
An anchor coupled to the connection member exposed through the fixing part of the lower plate;
A shock absorbing seismic isolator, characterized in that consisting of a fixing nut fastened to the connection member to be disposed on the fixing portion of the lower plate.
9. The method of claim 8,
The material for the elastic bolt is shock-absorbing base isolation device, characterized in that the polyurethane.

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