KR102122417B1 - Seismic vibration isolation system for building, and method for constructing this same - Google Patents

Abstract

The present invention relates to an isolating facility for a building pillar and a construction method therefor, for the purpose of preventing the shaking of the pillar and the collapse of the building by preventing the behavior of the ground from propagating to the pillar through the smooth separation behavior of the ground and the pillar during an earthquake. do.
A seismic isolation facility for a pillar of a building according to the present invention is mounted on a ground and is fixed through an anchor settled in the ground, and a behavior plate 11 that behaves with the ground; A plurality of ball transfers (12) installed on the behavior plate to behave together with the behavior plate; A movement absorbing plate (13) fixed to the lower end of the pillar and mounted on the ball transfer to block the movement of the behavior plate and the ball transfer to the pillar; Both ends of the upper and lower ends include a link 14 that connects to the behavior absorbing plate and the behavior plate, respectively. The present invention includes a pillar installation groove 20 that is formed open toward the top on the ground and sealed through a cover, and the pillar is inserted into the pillar installation groove.

Description

Seismic isolation facilities for building pillars and their construction methods{SEISMIC VIBRATION ISOLATION SYSTEM FOR BUILDING, AND METHOD FOR CONSTRUCTING THIS SAME}

The present invention relates to a seismic isolation system of a building, and more specifically, a seismic isolation facility for a building pillar installed on the bottom of a pillar of a building (such as a rural house) so that the behavior of the ground due to the earthquake does not propagate to the pillar and a construction method therefor It is about.

This part provides background information related to the contents of the present application, but is not necessarily prior art.

In general, in order to reduce the damage caused by earthquakes in buildings, from design to earthquake preparations, this is called seismic design, and the seismic design method of buildings largely includes methods such as seismic isolation, seismic isolation, vibration isolation, and vibration isolation. These methods can increase the earthquake resistance of the building, thereby reducing the damage caused by the earthquake.

Seismic isolation reduces earthquake damage between buildings and ground. In other words, by using laminated rubber, dampers, and bearings between the basement and the ground of the building, the impact of an earthquake is reduced to some extent to reduce the damage to the actual building.

Seismic resistance is a method that reinforces vulnerable structures and flexibly designs them to prevent buildings from collapsing even when damaged by an earthquake, thereby minimizing human damage.

Vibration damping is a method of offsetting vibration by installing a weight or damper that is a certain level of the total weight of the building inside the building and moving it in the opposite direction of the vibration of the building when an earthquake occurs.

And vibration is the ultimate way to prevent damage from earthquakes. It is a structure that completely separates the ground from the building using air bearings, magnetic forces, buoyancy, etc. so that they are not affected by earthquakes at all.

As a seismic reinforcing technology related to the present invention, the patent document (Public Patent No. 10-2015-0101673) processes the stone to complete the appearance of the cornerstone, and then processes the incision groove in the shape of a ㅁ in the center of the top surface of the cornerstone and fixes the center Insertion groove is provided by digging deeply, and the foundation stone is horizontally seated on the foundation concrete prepared in advance in the pit.

Next, the lower part is buried with cement, and a pillar is made to stand temporarily on the top of the foundation. Then, a marking line is displayed at the same height as the top surface of the foundation on the bottom surface of the pillar. After marking a square tip in the center of the bottom, removing the remaining part leaving the tip, and making the pillar vertically while inserting the tip into the insertion groove while building the pillar, the movement of the cornerstone even if an earthquake occurs As such, the pillars can move at the same time, and accordingly, each pillar is firmly inverted with beams, purlins, rafters, etc., so it can move together as a whole, thus minimizing the damage of the earthquake, but the seismic isolation effect is weak by conventional methods.

Patent Publication No. 10-2015-0101673 Patent No. 10-0384977

The present invention is to solve the problems as described above, seismic facilities for building pillars to prevent the shaking of the pillars and collapse of the building by preventing the movement of the ground to the pillars through the smooth separation behavior of the ground and pillars during an earthquake And it is intended to provide a method for its construction.

A seismic isolation facility for a pillar of a building according to the present invention is mounted on a ground and is fixed through an anchor settled in the ground, and a behavior plate that moves together with the ground; A plurality of ball transferers installed on the behavior plate to behave together with the behavior plate; A behavior absorbing plate fixed to the lower end of the pillar and mounted on the ball transfer to block the movement of the behavior plate and the ball transfer to the pillar; It characterized in that both ends of the upper and lower ends include a link for connecting to the behavior absorbing plate and the behavior plate, respectively.

The seismic isolation facility for a pillar of a building of the present invention is characterized in that it is installed together with the bottom of the pillar in a pillar installation groove that opens to the upper part on the ground.

The present invention is characterized by integrally synthesizing the pillars to which the behavior absorbing plate is fixed by connecting the bottoms of adjacent pillars.

According to the seismic isolation facility for a building pillar according to the present invention and its construction method, the ground and the behavior plate and ball transfer are fixed, and the pillar and the behavior absorption plate are fixed to absorb behavior when the behavior plate and the ball transfer move together with the ground during an earthquake The plate does not behave or behaves at a smaller width than the beating plate, thereby reducing the shaking of the pillars due to the earthquake, thereby preventing shaking and collapse of buildings (such as rural houses).

1 is a cross-sectional view of the installation state of the seismic isolation facilities for buildings according to the present invention.
2 is an exploded perspective view of a seismic isolation facility for a building pillar according to the present invention.
Figure 3 is an operational state diagram of the seismic isolation facility for a building pillar according to the present invention.
Figure 4 is a cross-sectional view showing an example in which the connecting beam is applied to the seismic isolation facilities for building pillars according to the present invention.
Figure 5 is a view showing an example of the protection box of the pillar installation groove is applied to the seismic isolation facility for a building pillar according to the present invention.
Figure 6 is a perspective view showing the connection of the foundation plate and the pillars applied to the seismic isolation facilities for buildings according to the present invention.
7 is a plan view showing the connection of the pillars by connecting beams applied to the seismic isolation facilities for building pillars according to the present invention.

In the following description of the present invention, when it is determined that a detailed description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or practice. Therefore, the definition should be made based on the contents throughout this specification.

As shown in Figures 1 and 2, the seismic isolation facility 10 for building pillars according to the present invention is fixed to the ground and the pillars, while absorbing it so that it does not propagate to the pillars when the ground is behaving. It is configured to prevent transmission by the movement of the pillars), the method installed on the ground, the method of installing the pillar installation grooves (20) that open toward the top in the ground is installed in the pillar installation grooves (20) It is possible, hereinafter, it will be described as an example that is installed in the pillar installation groove (20).

The pillar installation groove 20 is formed to open toward the upper side of the ground, and is preferably larger in size than the outer diameter of the pillar 1 and the outer diameter of the seismic isolation means 20, and the outer shape of the pillar 1 and the seismic isolation system 10 Depending on the plane, it is formed in a circular or rectangular cross section.

Seismic isolation facilities 10 for the pillars of the building are fixed to the ground and behaved together with the ground (11), a plurality of ball transfers (12) installed on the movable plate (11) to behave together with the movable plate (11), pillars (1) fixed to (1) ball transfer (ball transfer, ball castor) (12) is mounted on the behavior plate (11) and the ball transfer (12) when the behavior of the behavior absorbing plate to absorb the behavior to protect the pillar (1) (13), it is composed of a plurality of links (14) that is connected to the behavior absorbing plate (13) and the behavior plate (11) to prevent separation of the behavior absorbing plate (13).

The behavior plate 11 is the base of the seismic isolation system 10 and is settled on the ground through the anchor 15.

For example, the behavior plate 11 is a flat plate, and the insertion groove 11a is fixed by welding or the like after the bottom of the ball transfer 12 is inserted so that the ball transfer 12 is stably fixed to the upper surface. , Anchor hole 11b through which the anchor 15 penetrates is provided.

The behavior plate 11 is preferably a steel sheet.

At the bottom of the behavior plate 11, one or more buffer pads 16 for buffering the vertical movement of the ground and leveling the behavior plate 11 are interposed.

The buffer pad 16 has the same outer shape as the behavior plate 11 and is provided with an anchor hole.

Since the movable plate 11 is fixed to the ground through the anchor 15 in order to behave together with the ground, the anchor 15 must be firmly settled on the ground, and for this purpose, the concrete foundation part at the bottom of the pillar installation groove 10 During construction, a part of the anchor 15 can be buried in the concrete foundation to settle. That is, the anchor 15 is a structure having a horizontal portion at the bottom and a vertical portion at the top, the horizontal portion is embedded in the concrete base portion, and the vertical portion penetrates the buffer pad 16 and the behavior plate 11 to form the behavior plate 11. It is fixed by fastening the nut from the top.

The ball transfer 12 is fixed to the insertion groove 11a of the behavior plate 11 by inserting and welding, etc., so that it is erected on the behavior plate 11 and the ball 12a is at the top so that the bottom surface of the behavior absorption plate 13 By minimizing and frictional resistance, even if the behavior plate 11 behaves, the behavior absorbing plate 13 is maintained (or small behavior).

The behavior absorbing plate 13 has a larger cross-sectional area than the pillar 1 and is fixed to the lower end of the pillar 1 by welding or the like.

The behavior absorbing plate 13 is made of a steel plate to increase bending rigidity, etc., for example, by forming a groove in the bottom surface of the base plate 2 fixed to the lower end of the pillar 1, inserting and welding into the groove, etc. Can be used as fixed. At this time, the behavior absorbing plate 13 is composed of a large area in consideration of the behavior distance of the behavior plate 11.

The surface of the behavior absorbing plate 13 may be treated with a fluorine resin or the like to minimize friction with the ball 12a of the ball transfer 12.

The base plate 2 has a hole through which the rod 14b of the link 14 passes, and this hole is preferably in the form of a long hole through which the rod 14b can move. In this case, when the movable plate 11 is moved, the link 14 can move without changing the angle as much as the width of the long hole, thereby increasing the seismic isolation effect.

The upper side of the link 14 is fixed to the behavior absorbing plate 13 (or described as being fixed to the foundation plate 2 of the pillar, hereinafter referred to as being fixed to the foundation plate 2), and the lower side is fixed to the behavior plate 11 and the behavior plate When the behavior of (11), the behavior absorbing plate 13 is a combination method of a link ball and a rod whose angle is different so as not to behave, and of course, a change in distance due to an angle change can be compensated through a buffer member described below.

The link 14 is a link ball 14a fixed to the behavior plate 11, a rod 14b connected to the link ball 14a while penetrating through the hole of the base plate 2, and an upper portion of the base plate 2 It consists of a ring-shaped shock absorbing member (14c) coupled to the rod (14b), a nut (14d) that is fastened at the upper end of the rod (14b) and fixes the shock absorbing member (14c) and the rod (14b).

The link balls 14a and the rods 14b connect the behavior plate 11 and the behavior absorption plate 13 and can use a variety of products known to compensate for the position change due to the behavior of the behavior plate 11.

The shock absorbing member 14c is an elastic body that contracts or expands during vertical motion to cushion up and down vibrations and protects the link balls 14a and rod 14b, and also when the angle of the link balls 14a and rod 14b changes. It compensates for the displacement that occurs, and one or more pads and springs (coil springs) are possible, and the pads and springs can use one or more pads alone, springs alone, or a combination of pads and springs. The combination of the pad and the spring is shown in the drawing as the pad and the coil spring are stacked up and down, but is not limited thereto, and the up and down position may be reversed.

When the column installation groove 20 is formed, a contaminant penetrates into the interior of the column installation groove 20 through the opening portion of the column installation groove 20 so that the cover 21 is applied to prevent this.

The cover 21 is detachably installed in the upper opening of the pillar installation groove 20, and is configured in two divisions for convenient and easy operation, and is preferably installed on both sides of the pillar 1.

The cover 21 may be formed of an elastic material capable of shrinking or expanding or having wrinkles so as not to be destroyed when the ground is behaving (all or part).

According to the present invention, an isolating action is made between the seismic isolation system 10 on the ground side and the base plate 2 on the side of the pillar 1, and thus, the connection strength between the pillar 1 and the base plate 2 is on the seismic effect. It can have a great influence, and as shown in FIG. 6 for the high connection strength between the pillar 1 and the base plate 2, the pillar fixing bracket 3 is used. Of course, the pillar 1 and the base plate 2 may be fixed together by welding or fasteners suitable for the type of material.

The pillar fixing bracket 3 is formed to extend from the lower portions of the pillar supporting surfaces 3a and the pillar supporting surfaces 3a while being supported (fixing holes, welding, etc.) while being supported on the circumferential surface of the pillar 1 and the base plate 2 It consists of a structure having a base plate support surface (3b) that is fixed (fastening, welding, etc.) to the upper surface of the.

As shown in Fig. 6, the pillar fixing brackets 3 are respectively installed on two opposite sides of the quadrangular pillars 1, and both sides of the pillar supporting surfaces 3a are adjacent to each other so that connection is made on the other two sides. A pair of wing portions 3c covering the surface is made. That is, each of the two pillar fixing brackets 3 supports the other two surfaces together with each wing 3c.

The pillar fixing bracket 3 is preferably fixed to the pillar 1 and the base plate 2 through screw assembly, and it is also possible to omit the fitting of the heat treatment plate on the friction surface, and it is also possible to assemble directly by heat treatment on carbon steel.

The construction method of the seismic isolation facilities for the pillars of the building constructed as above is as follows.

1. Formation of pillar mounting groove.

The pillar installation grooves 20 are formed on the ground in accordance with the position of the pillars 1 of the building, and soil or the like is spread out using known equipment to form the pillar installation grooves 20 in a square or circular shape when viewed from a plane. It is also possible to construct concrete protectors by pouring concrete or the like on the bottom and periphery of the pillar installation groove 20 to prevent collapse.

This process is selectively applied if necessary, that is, it is also possible to install the seismic isolation system 10 on the ground without forming a pillar installation groove. Of course, the seismic isolation system 10 is preferably applied with a protective box for protection from the outside.

2. Seismic isolation system installation.

end. Anchor settlement.

A plurality of anchors 15 are fixed to the bottom of the pillar installation groove 20, and the head (upper part) of the anchor 15 protrudes upwards of the behavior plate 11.

I. Installation of the copper plate.

The behavior plate 11 is laid on the floor so that the head of the anchor 15 is fitted into the anchor hole, and the nut is fastened to the head of the anchor 15 to be installed.

When the cushioning pad 16 is applied, the cushioning pad 16 is installed in the same manner as the behavioral plate 11 prior to the installation of the behavioral plate 11.

The ball transfer 13 is fixed to the behavior plate 11 in advance and is installed together with the behavior plate 11, and of course, it is not limited to this, and after fixing the behavior plate 11 with the anchor 15, it is also installed in a subsequent process. It is possible.

In addition, it is preferable for convenience of a subsequent process to install the behavior plate 11 by fixing one side of the link 14 and the link ball 14a to the behavior plate 11.

All. Behavior absorbing plate and pillar installed.

Prepare by installing the behavior absorbing plate 13 at the bottom of the pillar 1 first.

The pillar (1) is erected so that the behavior absorbing plate (13) is placed on the ball transfer (13).

la. Link link.

When installing the behavior absorbing plate (13), the rod (14b) of the link (14) with one side fixed to the behavior plate (11) is erected and penetrated through the hole of the base plate (2), and after inserting the buffer member (14c), the nut The link 14 is connected by fastening (14d).

la. Cover finish.

The cover 21 is closed by closing the upper opening of the pillar installation groove 20.

The operation of the seismic isolation facility for a building pillar according to the present invention will be described.

1 is a state in which there is no behavior of the ground due to an earthquake.

In the state of FIG. 1, when an earthquake occurs, the ground behaves, and as shown in FIG. 3, the action plate 11 and the cushioning pad 16 behave in the same direction as the ground.

In this process, by the ball 12a of the ball transfer 12 fixed to the movement plate 11, the movement absorption plate 13 maintains the installation position together with the pillar 1, and the ball transfer 12 and the movement plate ( 11) and only the buffer pad 16 will behave.

Therefore, the vibration due to the earthquake does not propagate to the pillar 1 or only minimal vibration propagates, thereby protecting the building safely.

In addition, when the behavior plate 11 moves, the link 14 maintains the connection between the behavior plate 11 and the behavior absorbing plate 13 so that the ground side {buffer pad 16, behavior plate 11, ball transfer ( 12)} and the pillar side (behavior absorbing plate (13), pillar (1)) are prevented from being separated, thereby preventing the collapse of the pillar (1) due to their departure and protecting the building.

The present invention can be configured as follows to increase the seismic isolation effect by integrally synthesizing the pillars 1 in consideration of the design of a plurality of pillars 1 in a building.

As shown in Figure 4, the adjacent pillars (1) are connected to the connecting beam (22).

The connecting beam 22 can be a beam, a tube (angle tube, round tube, etc.), a rod, etc., and both sides of the longitudinal direction are fixed by bolting or welding to the circumferential surface of the adjacent pillar 1, respectively.

The connecting beam 22 is preferably installed at the base or bottom of the pillar 1 in order to prevent the pillar 1 from shaking due to vibration generated in the ground during an earthquake. A groove 23 is formed to install the connection beam 22 in the connection beam installation groove 23.

The connecting beam installation groove 23 is a groove having a depth lower than the ground between neighboring pillar installation grooves 10 and is formed so that both sides communicate with the neighboring pillar installation grooves 10, but isolating system 10 It is formed to a depth shallower than the pillar installation groove 20 so as not to interfere with the installation and operation of.

The connecting beam 22 is inserted into the connecting beam installation groove 23, and both sides are fixed to the pillar 1 and installed. The connecting beam installation groove 23 is closed through the cover 24 at the upper opening.

The connecting beam 22 may connect the adjacent pillars 1 regardless of the direction, that is, they may be installed in a straight direction along the pillars 1 or may be installed in a cross direction across the building.

When the pillars 1 are connected through the connecting beam 22 as described above, the pillars 1 are integrally synthesized to exert a great support force, and thus the vibration propagated to the pillar 1 is minimized when the ground moves due to an earthquake. To protect buildings more stably.

In addition, as shown in FIG. 7, two or more connecting beams 22 are installed to be fixed to two or more of the four circumferential surfaces of the pillar 1 in order to integrally synthesize the pillars 1.

In addition, in the present invention, a protection box may be applied to protect the seismic isolation system 10 within the pillar installation groove 20.

As shown in FIG. 5, the protection box 50 is a structure that blocks the circumference of the pillar installation groove 20 or a structure that blocks the circumference and the bottom, so that the seismic isolation system 10 is installed inside.

The protection box 30 has a different structure depending on the application of the connecting beam 22.

The protective box 30 may be added with one or more studs 31 on the circumference.

The stud 31 is useful when pouring concrete on the outside of the protection box 30, and is embedded in the concrete to effectively prevent collapse of the ground during an earthquake, thereby preventing malfunction due to the burial of the seismic isolation system 10.

1: Pillar 2: Base Plate
10: seismic isolation system, 11: copper plate
12: ball transfer, 13: behavior absorbing plate
14: link, 15: anchor
16: buffer pad, 20: pillar mounting groove
21: cover, 22: connecting beam

Claims (9)

A behavior plate 11 seated on the ground and fixed through an anchor anchored in the ground to behave together with the ground;
A plurality of ball transfers (12) installed on the behavior plate to behave together with the behavior plate;
A motion absorbing plate (13) fixed to the lower end of the pillar and mounted on the ball (12a) of the ball transfer to block the behavior of the behavior plate and the ball transfer from propagating to the pillar;
Both ends of the upper and lower ends include a link 14 that connects to the behavior absorbing plate and the behavior plate, so that during an earthquake, the ball transporter behaves together with the behavior plate while the behavior absorbing plate and the pillar do not move through the ball. Support,
The behavior plate includes an insertion groove 11a that is fixed by welding or the like after the bottom portion of the ball transfer is inserted so that the ball transfer is stably fixed to the upper surface while being a flat plate.
The link is a link ball 14a fixed to the movable plate, a rod 14b connected to the link ball, and a rod 14b penetrating the hole of the base plate 2 fixed to the lower end of the column through a column fixing bracket, a ring It is coupled to the rod from the top of the base plate in a shape and is contracted or expanded when the angle of the base plate changes, cushioning the up and down vibrations and protecting the link ball and the rod (14c), fastened at the top of the rod Seismic isolation facility for a building pillar, characterized in that it comprises a nut (14d) for fixing the buffer member (14c) and the rod (14b). The method according to claim 1, Is formed open toward the top on the ground and includes a pillar installation groove closed through a cover, the pillar is a seismic isolation facility for a building pillar, characterized in that the bottom is inserted into the installation groove. The method according to claim 2, It is formed lower than the surface of the surface so as to communicate with each other adjacent column installation grooves, the connection beam installation groove is sealed through the cover, installed in the connection beam installation groove, both sides of the longitudinal direction adjacent column or the behavior absorbing plate Seismic isolation facility for a building pillar, characterized in that it comprises a connecting beam that is fixed to each of the adjacent pillars integrally combined. The method according to claim 2 or claim 3, Seismic facilities for buildings pillars, characterized in that it is inserted into the installation groove of the pillar, and includes a protective box in which the seismic facilities are installed. delete delete As a construction method of the seismic isolation facilities for building pillars according to claim 1,
A first step of anchoring the anchor in the ground;
A second step of fixing the behavior plate to the anchor;
A third step of installing the behavior absorbing plate fixed to the bottom of the pillar on a ball transfer installed on the behavior plate while erecting the pillar;
And a fourth step of connecting the behavior absorbing plate and the behavior plate with a link. The method according to claim 7, The first step is to form a pillar installation groove that opens toward the top on the ground where the pillar is installed, and the building pillar characterized in that the anchor plate is fixed to the bottom of the pillar installation groove with the anchor. Construction method of dragon seismic isolation facilities. The method according to claim 8, Forming a connecting beam lower than the ground surface between the adjacent column installation grooves, inserting the connecting beams into the connecting beam installation grooves and the pillars installed in adjacent column installation grooves on both sides of the connecting beam in the longitudinal direction or And a third step of integrally synthesizing the pillars by fixing them to the behavior absorbing plate, respectively.

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