KR101355249B1 - Vibration isolation unit to protect building against earthquake - Google Patents

Abstract

The present invention relates to a seismic isolation system for preventing a building from collapsing and being damaged by earthquake wave and, more specifically, to a seismic isolation system for protecting a building by preparing for earthquake capable of absorbing the effect of earthquake wave having directivity by making the building to link and move as much as the predetermined distance by a seismic isolation unit so as to correspond to the effect of earthquake wave resulting in the largest damage in physical when the earthquake wave is generated and also capable of smoothly returning to the original location by the weight potential energy of a building which is increased by earthquake. Further, the present invention relates to a seismic isolation system for protecting a building by preparing for earthquake capable of easily absorbing and recovering from the effect of earthquake wave which is generated in the entire directions by being formed of a ground plate, a linking and moving plate, and an upper plate and having a two-stage impact alleviation method of inserting a separate linking and moving connector into between the plates when the seismic isolation unit is operated.

Description

Vibration isolation unit to protect building against earthquake

The present invention relates to a seismic isolator system for preventing the phenomenon that the building collapses or breaks due to the earthquake. Particularly, the present invention absorbs the influence of directional seismic waves and smoothly returns them to a proper position by allowing the building to be interlocked by a certain distance in response to the influence of surface waves that cause the greatest physical damage in the event of seismic waves. A seismic isolation system is used to protect buildings against earthquakes that can be restored.

Furthermore, the present invention has a two-stage impact mitigation method formed by the ground plate and the interlocking plate and the upper plate, sandwiching the interlocking medium between the plate, in the implementation of the base isolation unit, can be generated in all directions The present invention relates to a seismic isolation system that protects a building against an earthquake so that it can be easily absorbed and restored.

An earthquake is an imbalance of forces caused by an explosion or crust in the basement that is transmitted to the ground, causing cracks. This earthquake causes cracks. This earthquake is one of the natural phenomena that can cause excessive discomfort in human life on earth.

Although human beings are greatly benefited from nature, the comfort of their lives is being increased, but sometimes humans suffer and suffer great disasters due to natural phenomena. Especially in the case of earthquakes, due to the effects of seismic waves, the land splits, the settlements collapse, and many lives are damaged, which is considered a serious disaster.

Human beings have a separate seismic isolation system corresponding to the effects of seismic waves in the process of designing and building a building to overcome such natural phenomena, but there are many problems in the conventional seismic isolation system. Therefore, we look at the conventional simple isolation system.

1 illustrates a conventional seismic isolation system, which is a circular rolling ball 3 or a sliding pendulum inside the upper plate 1 and the lower plate 2 formed in a spherical shape as shown. By inserting a pendulum) according to the rolling motion of the ball, or the pendulum of the sliding pendulum, the upper plate (1) can be interlocked in all directions. The lower plate 2 is integral with the ground 5, and the upper plate 1 is integrated with the lower end of the support pillar 4 for supporting the building. In fact, since the upper plate 1 and the lower plate 5 are separated, they can be interlocked in all directions. The phenomenon that the upper plate 1 and the lower plate 2 are completely dismantled by a separate housing treatment or packing treatment is blocked, but it is possible to interlock according to the rotation of the rolling ball 3 to some extent. A peculiar point is that a concave groove having a constant radius of curvature is formed in the bottom of the upper plate 1 or the bottom of the lower plate 2 to accommodate the cloud ball 3. That is, when the rolling ball 3 rolls up to the outer part of the concave cloud groove 6, after the influence of the seismic wave, the direction of natural movement to restore to the center of the concave cloud groove 6 by gravity again This is what happens. This is how conventional seismic isolation systems have responded to seismic waves.

When a seismic wave is generated and the surface wave which is transmitted last among the seismic waves strikes the building, the building is subject to a strong blow according to the direction of the surface wave, and the rolling roll 3 of the base isolation system is moved upward in the direction of the force transmission by the blow. Roll between the plate 1 and the lower plate (2). The upper plate 1 and the lower plate 2 do not have positions overlapped with each other, but the upper plate 1 and the lower plate 2 are positioned in a staggered state to absorb the support wave. Then, in order to balance the force, the rolling groove 6 of the lower groove 2 and the rolling groove 3 of the upper groove 1 of the rolling groove 6 are naturally rolled to find the center point and return to the proper position. Restoration takes place. Of course, this is to minimize the damage caused by the seismic wave by absorbing the seismic wave in the form of interlocking and restoring every time the seismic wave is generated.

These have the following problems. The load received vertically is too large because the contact between the rolling groove 6 of the plate and the rolling ball 3 is achieved by the point. There is a risk that the rolling ball 3 and the plates 1 and 2 of strong hardness may be damaged by long use, and the small interlocking movement is continued even in an environment where the wind hits the building strongly because of the ball rolling.

As a result, conventional seismic isolation systems have many problems, and efforts to find other alternatives have always been reconsidered.

The present invention is to provide a seismic isolator system for preventing the phenomenon that the earthquake is generated collapse or damage due to the earthquake wave.

That is, in the present invention, the four basic performances required for the seismic isolation system, that is, the insulation function to insulate the vibration of the earthquake from being transmitted to the building, the support function to always support the weight of the building stably even when the earthquake is vibrated, and the vibration width of the earthquake is reduced. It aims to provide a simple, high performance isolation system with attenuation function and restoration function to return the building to its original location after an earthquake.

In particular, the present invention by allowing the building to be interlocked by a certain distance by the base isolation unit in response to the influence of the surface wave that causes the physically the greatest damage when the seismic wave is generated, absorbs the influence of the directional support wave and smoothly again It is intended to provide a seismic isolation system that can protect buildings against earthquakes that can be restored to location and efficiently reduce both deformation and earthquake acceleration.

Furthermore, the present invention has a two-stage impact mitigation method formed by the ground plate and the interlocking plate and the upper plate, sandwiching the interlocking medium between the plate, in the implementation of the base isolation unit, can be generated in all directions It is to provide a seismic isolation system that protects buildings against earthquakes that can easily absorb and restore the effects of possible seismic waves.

A seismic isolation system for protecting a building against an earthquake according to the present invention includes: a ground plate 20 embedded in the ground B or integrated with the ground B; An upper plate 10 embedded or integrated in the lower end of the support pillar A of the building; An interlocking plate 40 installed between the ground plate 20 and the upper plate 10 to be interlocked in all directions; And a two-stage linkage interposed between the ground plate 20 and the interlocking plate 40 and between the interlocking plate 40 and the upper plate 10 to interlock each plate in all directions with respect to the horizontal plane. Through the base isolation unit 100 including the intermediate unit 30, in the event of an earthquake, the upper plate fixed to the support pillar, the ground plate fixed to the ground, and the interlocking plate transmitted by the interlocking plate in the forward and backward directions Interlock with each other to be able to detail the force transmitted.

In addition, the ground plate 20, the interlocking plate 40 and the upper plate 10 according to the seismic isolation system that protects the building against the earthquake of the invention invention, respectively, when the virtual axis x and y axis relative to the horizontal plane The influence of the support wave can be absorbed or supported according to the interlocking action in the x- and y-axis directions of the interlocking mediar 30 sandwiched between the plates. The interlocking mediar 30 maintains a long rectangular parallelepiped shape. The upper and lower surfaces have the same radius of curvature and have a long, round-shaped contact surface which protrudes convexly into the upper and lower portions. : Interlocking medium 30 is composed of rolling rolls (30-3) to maintain the shape of the long cylindrical rod, the upper plate 10 to correspond to the rolling rolls (30-3) bottom, the interlocking plate (40) On the top and bottom and the upper surface of the ground plate 20 The rolling rolls 30-3 are mounted in two stages with respective rolling surfaces 11, 41, 42, and 21 in the form of concave grooves that allow the rolling rolls 30-3 to rotate while being constrained in a certain area according to the rolling to absorb shocks. The roll rolls (30-3) are rolled in the x- and y-axis directions arranged at 90 ° angles, respectively, to absorb or support the effects of seismic waves.

In addition, according to the seismic isolation system that protects the building against the earthquake of the present invention, the rolling rolls (30-3) mounted in a state having a phase difference of 90 ° in two stages have a plurality of rolling rolls (30-3) at each end. Mounted in the same direction, but the plurality of rolling rolls (30-) on the bottom of the upper plate 10, the upper and lower surfaces of the interlocking plate 40 and the upper surface of the ground plate 20 to correspond to the plurality of rolling rolls (30-3) 3) is inserted at regular intervals to have a concave-shaped cloud surface (11, 41, 42, 21) to be able to absorb the shock of the seismic waves transmitted by the cloud action: the base isolation unit 100 is a building One each installed in each support pillar (A) to form: the x-axis and the side of the upper plate 10, the interlocking plate 40 and the ground plate 20 to form the base isolation unit 100 and the horizontal plane Guide portion 50 for guiding movement in the y-axis direction is formed .

In addition, according to the seismic isolation system for protecting the building against the earthquake of the present invention, the guide unit 50, the guide rail 54 protruding from the corresponding left and right sides of the ground plate 20 and the interlocking plate 40 and corresponding thereto It consists of a stopper block (51) protruding the stopper protrusion 53 to allow the guide rail (54) to be interlocked while limiting the interlocking level and the length of the interlocking, the interlocking in one direction of the x-axis y-axis direction Permissible and corresponding to the guide rail 52 protruding from the left and right sides of the interlocking plate 40 and the upper plate 10 and the corresponding level and the length of the interlocking while allowing the interlocking of the guide rail 52 corresponding thereto. It consists of a stopper block 51 protruding the stopper projection 53 to apply a restriction to allow the interlocking in the other direction: the upper surface and the ground plate of the interlocking plate 40 for rolling the rolling roll 30-3 ( In the concave cross-section of the cloud 41, 21 formed on the upper surface of the 20) in the rolling direction of the rolling roll (30-3) is formed in the rolling direction of the rolling roll (30-3) is formed in the fitting groove ( The lead plate 62 is inserted into the lead plate 61 to allow a smoother interlocking motion.

According to the present invention has a very simple structure, it has a great advantage in that it is possible to distribute a large force to protect the building through interlocking mediation means separated in two stages when an earthquake wave occurs.

According to the present invention, since the interlocking mediating means and each plate are in line contact with each other by the rotational movement of the interlocking mediating means, each plate absorbs the surface wave in a manner of accommodating the displacement of the seismic waves while generating a phase difference, which is safe against seismic waves. At the same time, there is an advantage in improving the durability of the building.

In addition, according to the present invention, the rotational movement of the interlocking mediation means separated into two stages is separated into the components of the x-axis and y to accommodate the displacement difference generated in the seismic wave, so that it can flexibly cope with the seismic waves in all directions. There is an advantage in that.

1 is a view showing an embodiment of a conventional isolation unit;
Figure 2 is an exploded perspective view showing an interlocking unit carried out by the first embodiment interlocking mediation of the present invention,
Figure 3 is a perspective view showing a combination of the interlocking unit carried out by the first embodiment interlocking mediation of the present invention,
4 is a view showing a state in which the interlocking unit carried out by the first embodiment of the present invention interlocking unit is mounted and operated;
5A is an exploded perspective view showing an interlocking unit implemented as a second embodiment interlocking medium of the present invention;
Figure 5b is a cross-sectional view showing a coupling unit implemented by the second embodiment of the interlocking media of the present invention,
Figure 5c is a perspective view showing a combination of the interlocking unit carried out by the second embodiment of the interlocking media of the present invention,
6 is a view showing a state of operation of the building is equipped with an interlocking unit carried out by the second embodiment interlocking medium of the present invention,
Figure 7 is an exploded perspective view showing an embodiment equipped with a plurality of rolling rolls of the second embodiment interlocking mediation of the present invention,
8 is a perspective view showing an embodiment equipped with a plurality of rolling rolls of the second embodiment interlocking mediation of the present invention,
9 is a view showing a state in which a second embodiment of the interlocking unit equipped with an interlocking medium is operated;
10 is a view illustrating an operating state of an interlocking unit equipped with a first embodiment interlocking media unit of the present invention;
11 is a view showing a state in which the interlocking unit on which the second embodiment of the present invention is interlocked is mounted and operated on each support pillar of the building;
12 is a plan view showing a form in which the plate of the present invention is moved forward in the horizontal direction,
13 is a view showing a basic cross-sectional view of the base isolation unit of the present invention,
14 is a cross-sectional view showing a state that the plate of the base isolation unit of the present invention interlocked,
15 is a view showing a state where the lead plate is applied to the base isolation unit of the present invention.

The present invention relates to an isolating system for absorbing seismic waves and mitigating shocks. Therefore, the structure of the present invention and its operation will be described in detail with reference to the drawings.

As shown in the present invention, there is a ground plate 20 embedded in the ground (B) or integrated with the ground (B), there is an upper plate (10) embedded or integrated in the lower support pillar (A) of the building, There is an interlocking plate 40 installed between the ground plate 20 and the upper plate 10 to be interlocked in all directions. In addition, a two-stage interlocking media between the ground plate 20 and the interlocking plate 40 and between the interlocking plate 40 and the upper plate 10 to interlock each plate in all directions with respect to the horizontal plane. Through the base isolation unit 100 including the unit 30, in the event of an earthquake, the upper plate fixed to the support pillar, the ground plate fixed to the ground, and the interlocking plate interlocked according to the influence of the seismic wave transmitted by the interlocking plate is interlocked in the front and rear directions And detail the force transmitted.

That is, the present invention is a seismic isolator system for absorbing seismic waves and alleviating shock to preserve the building. To this end, the present invention integrates the ground plate 20 to the ground, integrates the upper plate 10 at the bottom of the support pillar A of the building, and separates the upper plate 10 from the interlocking of the ground plate 20. ) Is an invention that has its own interlocking range. The main feature of the present invention is that the ground plate 20 is firmly integrated with the ground, a method of embedding in the ground (B) may be used, and the ground plate (20) by placing a separate concrete mortar on the ground (B) It is also possible to use a way to be more firmly integrated with the ground. Between the upper plate 10 and the ground plate 20, a separate interlocking plate 40 is built as shown in Figs. 2 and 5 and a unique interlocking medium 30 on the upper and lower portions of the interlocking plate 40. Is inserted.

When the present invention absorbs seismic waves, when the seismic waves are generated, P waves, S waves, and surface waves are transmitted from the epicenter. Among these wavelengths, the wavelength that directly causes damage to the building is transmitted most recently. It is a surface wave that comes. This surface wave destroys the earth's crust and interlocks the building in the horizontal direction because there is a transmission area with a certain wavelength. This interlocking effect, in fact, has a weak effect on the formation of a crack in the building, but it also has a big effect on the collapse of the supporting column or the wall, causing the building itself to collapse. In order to prevent such effects, it is most preferable to absorb the seismic waves by flexibly interlocking with the range of the interlocking force when the seismic waves reach the building and forcibly interlock the building by a certain range or interval in the form of the force.

According to the present invention, when a building is affected by seismic waves, it firmly abandons to secure and maintain its position, and absorbs the seismic waves in a horizontal direction by an appropriate range according to the magnitude of the seismic waves, and the influence of the seismic waves After passing is to provide a base isolation unit 100 that can be restored to the original position again. The interlocking medial portion 30 formed in two stages of the base isolation unit 100 serves to interlock each plate in the horizontal direction and the vertical direction of the base isolation unit 100 of the present invention. It responds to seismic waves, but allows a certain degree of interlocking, but plays a role in allowing the natural waves to revert back to their original position when the seismic effects pass.

Elements that enable this role are the ground plate 20, the interlocking plate 40 and the upper plate 10 connected by the interlocking medium 30 of the present invention. That is, the ground plate 20, the interlocking plate 40 and the upper plate 10 of the present invention, the interlocking medium portion 30 is sandwiched between each plate when the virtual in the x-axis and y-axis relative to the horizontal plane The influence of the support wave can be absorbed or supported by the interlocking action of the x- and y-axis directions.

In the present invention, in forming the interlocking medium 30, it is composed of two stages and each of the interlocking medium 30 is arranged in a layer at a 90 ° angle for the following reason. In the case of seismic waves, the force is changed in such a way that the P wave, the longitudinal wave, the transverse wave, and the surface wave are transmitted first. At this time, the earthquake wave that causes the most physical damage to the residents living on the building or the ground is the surface wave. This surface wave substantially causes cracks in the earth's crust, forms a crustal linkage in the left and right directions, and causes a crack in the walls of the building. Accordingly, due to the influence of the surface waves, the buildings are actually suffering from various disasters such as collapse or burial into the ground.

In order to escape these influences, the present invention abandons the method of maintaining the building in a form that can firmly secure its position even when the seismic waves are transmitted, and in the same direction depending on the influence of the seismic waves flexibly transmitted. Adopted flexibility to interlock buildings and absorb the effects of seismic waves. In this case, the seismic wave does not always have a constant direction in transmitting power to the building. Because the epicenter always changes and the magnitude of the force is different, the building does not know in which direction the effects of the seismic waves will be transmitted.

In the present invention, such a concern is completely excluded by forming the two-step interlocking medium 30 as described above. Force is a vector component of direction and magnitude. Seismic waves are thus transmitted in the form of force and produce displacement. Since displacement is also a component of a vector having a magnitude and direction, the present invention divides the displacement into two stages and flexibly copes with the effects of seismic waves. When the interlocking medium unit 30 of the first stage allows the interlocking unit unit 30 in the "x" axial direction when the "x" axis and the "y" axis directions are set based on the horizontal plane, the second stage interlocking unit unit 30 is "y". "Allow the linkage in the axial direction. When the displacement is divided into components in the directions of the "x" axis and the "y" axis, and the displacement of the seismic wave is accommodated, the base isolation unit 100 of the present invention is interlocked in that direction even if the seismic wave influence is transmitted in any direction. In addition, it can recover from the shock of seismic waves by restoring again.

A more detailed embodiment of the present invention will now be described. As described above, the present invention has a main feature in that the interlocking medium 30 and the interlocking medium 30 are formed in a long shape. 2 and 3 illustrate the convex interlocking roll 30-2 as a first embodiment of the interlocking mediation unit 30 of FIGS. 2 and 3, and FIGS. 5, 7 and 8 illustrate the second of the interlocking mediation unit 30. As an example, a rolling roll 30-3 is shown. Therefore, first, the convex interlocking roll 30-2 of the first embodiment will be described, and then the second embodiment will be described.

The first embodiment of the present invention interlocking medium 30 is a long and has a long rectangular parallelepiped shape, but the upper and lower surfaces maintain the same radius of curvature and have a rounded interview surface protruding convexly to the upper and lower sides and a plurality of Insert the convex interlocking rolls 30-2 into two stages at an angle of 90 ° to each other. In other words, the interlocking medium 30 is a condition that the ground plate 20, the interlocking plate 40 and the upper plate 10 can be restored to its original position while allowing a certain amount of interlocking freely from one another. It is a configuration to provide. The block interlocking roll 30-2 shown in FIGS. 2 and 3 is a long rectangular parallelepiped having one long side in the shape of a rectangular parallelepiped. And the upper and lower surfaces are shaped like protruding interviews like bread. The convex interlocking roll 30-2, which is the first embodiment of the present invention, is sandwiched between the upper surface of the ground plate 20 and the lower surface of the interlocking plate 40, which are already described, and the upper and upper surfaces of the interlocking plate 40. A large number is interposed between the bottom surfaces of the plates 10. At this time, if the convex interlocking roll 30-2 sandwiched between the ground plate 20 and the interlocking plate 40 is called the interlocking medium unit 30 of one stage, the upper surface of the interlocking plate 40 and the bottom of the upper plate 10 The convex interlocking roll 30-2 fitted in the two-stage interlocking medial part 30 becomes. As shown in the above description and the illustrated figure, the convex interlocking roll 30-2 and the two-stage ball roll interlocking roll 30-2, which are the first interlocking medial portion 30, are the same in shape, size, and shape, but are the same. The mounting position is arranged at an angle of 90 °. The purpose of this is to be able to easily absorb the direction of the force transmitted in the two-stage interlocking media (30).

The state of this operation is shown in detail in FIG. If the building is located as shown in (a) of FIG. 10 and the influence of the seismic wave is transmitted, the building is interlocked in the transmitted and pushed direction to absorb the shock. The convex interlocking roll 30-2 absorbs the seismic wave through an operation of rotating at an angle through the protruding convex interface and restores it to its original position.

On the contrary, the interlocking medium 30 of the second embodiment of the present invention is constructed and operated as shown in FIGS. That is, the interlocking medium 30 is composed of a rolling roll 30-3 that maintains the shape of a long cylindrical rod, but the bottom of the upper plate 10 so as to correspond to the rolling roll 30-3, the interlocking plate ( The upper and lower surfaces of the 40 and the upper surface of the ground plate 20 each rolling surface in the form of a concave groove that can be absorbed by rotating the rolling roll (30-3) in a certain area constrained according to the cloud to absorb the impact (11, 41, 42, 21) with two-stage rolling rolls (30-3) to absorb or support the effects of seismic waves by rolling in the x- and y-axis directions arranged at 90 ° angles, respectively. To help.

" 형의 오목한 각각의 구름면(11, 41, 42, 21) 형성하는 것이다. 이에 따라 2단으로 장착된 구름롤(30-3)이 각기 90°각도 배열된 x축과 y축 방향의 구름운동을 하여 지진파의 영향을 흡수하거나 지지한다. Cylindrical rods are formed so that they can rotate freely between the plates. Unlike the conventional form in which the force is transmitted to the point to be interlocked with the plate by the line, the endurance to the load is large. However, in the case of the rolling roll 30-3, unlike the convex interlocking roll 30-2 described above, there is no separate means for restoring the 360 ° angle. In order to solve this problem, in the present invention, the same effect was obtained by tapering the contact surface of the plate. That is, the rolling surface (11, 41, 42, 21) is formed on the surface of the plate to be interviewed with the rolling roll (30-3), the level difference may occur "

To form the concave rolling surfaces 11, 41, 42, and 21. Thus, the rolling rolls 30-3 mounted in two stages are rolled in the x- and y-axis directions each having a 90 ° angle. Exercise to absorb or support the effects of seismic waves.

" 형의 구름면(21, 42) 로 형성하는 것이다. 물론 2단의 구름롤(30-3)이 끼워지는 연동플레이트(40)의 상면과 상부플레이트(10)의 하면도 중심부가 오목하게 패인 "

" 형의 구름면(41, 11)으로 형성한다. 따라서 지진파가 전달되어 구름롤(30-3)이 회전하여 충격을 흡수한 후에는 다시 구름롤(30-3)이 구름면(21, 41, 42, 11)을 타고 복원하여 정위치를 확보한다.
To explain the operation again, as shown in Figures 5 and 6, the interlocking medium formed in two stages 30 is formed in the form of a cylindrical rod, the ground plate 30 is fitted with the rolling roll 30-3 of the first stage The upper surface of the 20 and the lower surface of the interlocking plate 40 are recessed in the center thereof.

The upper surface of the interlock plate 40 and the lower surface of the upper plate 10 to which the two-stage rolling rolls 30-3 are fitted are concave in the center. "

Form the rolling surfaces 41 and 11. Therefore, after the seismic waves are transmitted and the rolling rolls 30-3 rotate and absorb the impact, the rolling rolls 30-3 again form the rolling surfaces 21 and 41. , 42, 11) to restore the correct position.

On the other hand, the rolling roll 30-3 of the present invention can achieve the same purpose by performing a plurality of rolling rolls 30-3 as the interlocking medium 30 as shown in 7 and 8. That is, the rolling rolls 30-3 mounted in a state having a phase difference of 90 ° in two stages are equipped with a plurality of rolling rolls 30-3 at each end in the same direction, but a plurality of rolling rolls 30-3 are provided. In order to correspond to the bottom surface of the upper plate 10, the upper and lower surfaces of the interlocking plate 40 and the upper surface of the ground plate 20, a plurality of rolling rolls (30-3) are inserted at regular intervals and delivered according to the rolling action It is to have a concave-shaped cloud surface (11, 41, 42, 21) to be able to absorb the shock of the seismic waves.

A plurality of rolling rolls (30-3) to support a larger load for the line contact, while receiving the effects of seismic waves in two stages to each other in the direction of the shock displacement so that it can be restored again. . Unlike the embodiment of FIG. 5 described above, a plurality of rolling rolls 30-3 may be used as the interlocking medium 30 of the first stage and the second stage, and thus may have more durability and have a stable fastening structure. There is this.

As a result, the base isolation unit 100 of the present invention is an interlocking medium 30 sandwiched between the three plates 10, 20, 40 and the three plates 10, 20, 40. These are composed of one base isolation unit 100 in combination with each other, this base isolation unit 100 is installed on each support pillar (A) to form a building to protect the building from the influence of seismic waves.

It is the support pillar (A) that is actually standing on the ground to support the load of the building. The influence of the seismic wave may have a difference in the direction and the difference in the force transmitted to each support pillar (A). In order to cope with this organically, in the present invention, the base isolation unit 100 is installed in each support pillar A as shown in FIG. 11. The ground and all support pillars (A) are to achieve a solid fastening.

On the other hand, in the present invention, the guide plate for guiding the movement in the x-axis and y-axis direction on the horizontal surface on the side of the upper plate 10, the interlocking plate 40 and the ground plate 20 to form the base isolation unit 100 It is preferable that 50 is formed.

The guide part 50 may be applied to the base isolation unit 100 to which the interlocking medium 30 of the first embodiment is applied as well as the interlocking medium 30 of the second embodiment. As shown in Fig. 5 and Fig. 5, the guide part 50 of the present invention prevents the plates from being dismantled greatly while allowing the plates to be interlocked with each other in the horizontal direction. In some cases, interlocking in the vertical direction is allowed to some extent, but too large displacement is generated to prevent the plates 10, 20, and 40 from being disassembled from each other. It also allows horizontal interlocking and vertical interlocking, but also serves as a guide for straight horizontal and vertical interlocking.

This form of operation is illustrated in detail in FIGS. 5, 12 and 16, which are mounted on the side of each plate to allow horizontal peristaltic motion.

Looking at this guide portion in more detail, the guide portion 50, the guide rail 54 protruding from the corresponding left and right sides of the ground plate 20 and the interlocking plate 40 and the corresponding of the guide rail 54 It consists of a stopper block (51) on which the stopper protrusion (53) protrudes so as to allow interlocking and limit the interlocking level and the length of interlocking. The guide rails 52 protruding from the left and right sides of the 40 and the upper plate 10 and the corresponding stopper protrusions to allow the linkage of the guide rails 52 to correspond to the guide rail 52 and to limit the interlocking level and the length of the linkage. 53 is made of a stopper block 51 protruding to allow the interlock in the other direction.

If the interlocking direction of the interlocking medial portion 30 fitted to the first surface of the ground plate 20 and the lower surface of the interlocking plate 40 is the same as the direction of the "x" axis, the ground plate 20 is horizontal to this "x" direction. And guide portion 50 is mounted on the side of the interlocking plate 30. The stopper protrusion 53 of the stopper block 51 attached to the guide rail 52 protruding from the side of the ground plate 20 and the interlocking plate 40 is correspondingly coupled. When the plate is pushed in one direction by the seismic wave, interlocking over a certain range while blocking the seismic isolation unit 100 is prevented from being disassembled while allowing straight horizontal motion. This is achieved in the form of an organic bond between the protrusion and the groove.

In addition, if the interlocking direction of the interlocking medial portion 30 fitted to the upper surface of the interlocking plate 40 and the lower plate 10 of the two stages is the same as the direction of the "y" axis, the interlocking plate 40 horizontal to this "y" direction And guide portion 50 is mounted on the side of the upper plate (10). The guide rails 52 protruding from the side surfaces of the interlocking plate 40 and the upper plate 10 and the stopper protrusion 53 of the stopper block 51 attached to each other are correspondingly coupled. When the plate (10, 20, 40) is pushed in one direction by the seismic wave, it is possible to be a straight horizontal movement while preventing the interlocking over a certain range so that the seismic isolation unit 100 is not dismantled. This is achieved in the form of an organic coupling between the protrusion and the groove in the same way as the guide section 50 of the first stage described above.

In addition, as shown in Figs. 15 and 16, the rolling surface (41, 21) of the concave cross-sectional shape formed on the upper surface of the interlocking plate 40 and the upper surface of the ground plate 20 for rolling roll rolling (30-3) In the central part, the rolling groove (30-3) of the rolling direction in the direction of rolling is formed in the form of the fitting groove 61 is inserted and the lead plate 62 in the fitting groove 61 can be a smoother peristaltic movement Make sure When rolling rolls (30-3) to the cloud surface (41, 21), it is to prevent excessive force from being transmitted to the cloud surface (41, 21) and to absorb a certain load pressure.

As shown in the drawing, when the lead plate 62 using a soft metal lead is inserted into the fitting groove 61, and the rolling rolls 30-3 rotate and climb up the rolling surfaces 41 and 21, the lead plate 62 ) Is pressed to support the load. Even if the volume is pressed and the volume is changed, the lead plate 62 adheres to the inner side of the pressing surface and is applied onto the rolling surfaces 41 and 21 so that the high hardness rolling rolls 30-3 form the rolling surfaces 41 and 21. You can also reduce the noise produced when It can also be a means of examination to determine how much interlocking has occurred due to seismic waves later.

10; Upper plate 20; Ground plate
30; Interlocking medium 40; Interlocking Plate
11, 41, 42, 21; Cloud surface 50; Guide portion
100; Isolation Unit

Claims (9)

A ground plate 20 embedded in the ground B or integrated with the ground B;
An upper plate 10 embedded or integrated in the lower end of the support pillar A of the building;
An interlocking plate 40 installed between the ground plate 20 and the upper plate 10 to be interlocked in all directions; And
Two-stage interlocking unit interposed between the ground plate 20 and the interlocking plate 40 and between the interlocking plate 40 and the upper plate 10 so that each plate can be interlocked in all directions with respect to the horizontal plane. Through the seismic isolation unit 100 including the 30, when the earthquake occurs, the upper plate fixed to the support pillar and the ground plate fixed to the ground and the interlocking plate interlocked according to the influence of the seismic waves transmitted to the front and rear and left and right directions Offsets the transmitted force,
The ground plate 20, the interlocking plate 40 and the upper plate 10, and the x-axis of the interlocking medium portion 30 that is fitted between each plate when the virtual to the x-axis and y-axis relative to the horizontal plane absorb or support the influence of the support wave according to the interlocking action in the y-axis direction,
Guide parts 50 for guiding movement in the x-axis and y-axis directions with respect to a horizontal plane on the side of the upper plate 10, the interlocking plate 40, and the ground plate 20 forming the base isolation unit 100. Is formed,
The guide part 50 may be interlocked with the guide rails 54 protruding from the corresponding left and right sides of the ground plate 20 and the interlocking plate 40, and corresponding to the guide rails 54. And a stopper block 51 protruding from the stopper protrusion 53 so as to limit the length of the linkage, allowing the linkage in one direction in the x-axis y-axis direction, and correspondingly, the linkage plate 40 and the upper plate ( 10) a stopper block protruding from the left and right sides of the guide rail 52 and the stopper protrusion 53 protruding from the guide rail 52 corresponding to the guide rail 52 so as to restrict the interlocking level and the length of the linkage. A seismic isolation system for protecting a building against an earthquake, characterized in that it is composed of (51) to allow interlocking in the other direction.
delete The method of claim 1,
The interlocking medium 30 has a long rectangular parallelepiped shape, and the upper and lower surfaces maintain the same radius of curvature and have a long, convex interlocking roll having convex protrusions protruding upward and downward. A seismic isolation system that protects the building against earthquakes, characterized in that 2) is inserted in two stages at 90 ° to each other.
The method of claim 1,
Interlocking medium 30 is composed of a rolling roll (30-3) to maintain the shape of the long cylindrical rod, the lower surface of the upper plate 10 to correspond to the rolling roll (30-3), the interlocking plate 40 Each cloud surface 11 in the form of a concave groove to the upper surface and the bottom and the upper surface of the ground plate 20 and the rolling roll 30-3 is rotated in a certain area constrained by the cloud to absorb the impact. , 41, 42, 21) so that the two-stage rolling rolls (30-3) can perform the rolling motion in the x-axis and y-axis directions arranged to have a 90 ° angle so that they can absorb or support the effects of seismic waves A seismic isolation system that protects the building against earthquakes characterized in that one.
5. The method of claim 4,
The rolling rolls 30-3, which are mounted with two phases having a phase difference of 90 °, are equipped with a plurality of rolling rolls 30-3 at each end in the same direction, but on the plurality of rolling rolls 30-3. Seismic waves are inserted into the upper surface of the lower plate 10, the upper surface and the lower surface of the interlocking plate 40 and the upper surface of the ground plate 20 and a plurality of rolling rolls (30-3) are inserted at regular intervals and transmitted according to the cloud action. A seismic isolation system for protecting a building against an earthquake, characterized in that it has a concave cloud surface (11, 41, 42, 21) to absorb the impact of.
The base isolation system of claim 1, wherein the base isolation unit (100) is installed at each support pillar (A) that forms a building.
delete delete 5. The method of claim 4,
The rolling rolls 30-3 are formed in the concave cross-sectional rolling surfaces 41 and 21 formed on the upper surface of the interlocking plate 40 and the upper surface of the ground plate 20 for rolling the rolling rolls 30-3. Building according to the earthquake, characterized in that the insertion groove 61 of the form of the date is formed in the rolling direction of the) and the lead plate 62 is inserted into the fitting groove 61 to be a smoother interlocking movement. Isolation system to protect the.

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