KR101750244B1 - Underground embedded seismically Isolated panel - Google Patents

Abstract

The present invention relates to an anti-vibration panel adapted to be applied to existing buildings and structures, or to a wall of a new building or structure, and more particularly, to an underground embedded anti-vibration panel capable of complementing or operating alone with existing anti- Wherein the vibration isolation panel has a plurality of intermediate walls spaced from each other in the both side walls and a vibration absorbing layer is formed between the walls and the intermediate wall, By forming the space portion,
It is possible to embed in the ground in a state of being attached to the wall of the building with the depth of 2 ~ 3 times the depth of penetration depth of the ground structure regardless of the existing construction structure and the new building structure. And the vibration absorbing layer and the buffering space of the multilayer absorb various earthquake waves and attenuate and cancel the earthquake waves to greatly reduce the seismic waves acting on the building structure, thereby minimizing the loss of material, human loss and damage. And it is possible to exert an even better seismic effect when it is operated together with existing seismic means applied to the foundation part of the building structure.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to an underground embedded seismically isolated panel applied to a wall of a building and a structure,

The present invention relates to an anti-vibration panel adapted to be applied to existing buildings and structures, new buildings and structures, and more particularly to an anti-vibration panel comprising a plurality of intermediate walls spaced from each other in a double- And a buffer space in which a strut and a spring fixed from the closed wall are formed are formed between the intermediate walls.

As the frequency of earthquakes increases worldwide, collapse of structures such as buildings and bridges causes serious economic loss as well as serious economic loss.

Accordingly, structures for buildings, bridges, towers, and landscapes (hereinafter referred to as "building structures" as well as buildings and structures) for residential and living, work and convenience, and the like, And it should be designed and constructed so that the function and safety of the building structure will not be affected even if an external shock or an earthquake occurs.

In addition, seismic design through foundation buried structure or interlayer joint structure is performed in comparison with seismic design, which is required to take a certain amount of loss on the exterior appearance of the building and the invasion of the available space of the building, The seismic waves transmitted to the building structure can be reduced, and the damage caused by the earthquake can be minimized.

That is, the seismic isolation device for a building such as the registered patent No. 10-0456286 has found a seismic isolation device for a building capable of effectively seizing the relative vibration generated between the upper structure and the lower structure, A small projection is formed on the contact surface so that the upper member and the lower member can accurately perform rolling motion by contact with the moving member so that there is no vertical displacement of the structure, and urethane or the like having elasticity is filled in the inner space of the peripheral wall, Of the structure is prevented.

In addition, in the case of the registered patent No. 10-1247149, there is a seismic structure of a building that is easy to construct and has a simple structure but can absorb and absorb the shock before the seismic wave reaches the foundation of the structure, so that the structure can be safely maintained , Registration Practical Utility Model No. 20-0466913, the air is moved through the air vent groove provided in the housing base to remove moisture and moisture from the inside of the house, thereby improving the life and efficiency, The foundation floor mat for building floors has been developed.

However, the seismic isolation means and the seismic isolation structure applied to the existing architectural structure have a problem that the seismic effect is limited only to the vertical vibration acting on the building structure, because the seismic isolation means and the seismic isolation structure are located between the bottom of the architectural structure will be.

That is, when an earthquake occurs, a seismic wave is generated. The seismic wave is divided into a body wave and a surface wave. The actual wave is divided into a primary wave and a secondary wave. And the surface wave is divided into a rayleigh wave and a love wave.

Here, it is known that the P wave of the above-described actual wave changes the density of the material and can pass through both solid and liquid and gas by moving, but it is known that the amplitude is small and the degree of damage is small. On the other hand, It is known that the damage is very large because it is very large. It has been reported that the Love wave, which is a type of surface wave, vibrates left and right in a horizontal plane perpendicular to the direction of the seismic wave, It is well known that it vibrates in the vertical plane of the surface layer and the damage is relatively weak due to the slow movement speed compared with the love wave.

The seismic wave generated by the earthquake generates the vibration sequentially and complexly in the upward, downward direction, leftward and rightward direction, and forward direction with respect to the building structure. In the case of the existing seismic isolation device and the seismic isolation structure, The effect of seismic isolation was limited because it was applied only to the upward and downward vibration.

Therefore, although S waves with the greatest damages caused by earthquakes can be effectively countermeasured and seismicized, they have a deterioration effect on the building structure when the P waves, the S waves, and the surface waves are operated simultaneously or sequentially .

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an underground embedded type earthquake-resistant panel that can be supplemented or operated alone with existing canopy means, A vibration absorbing layer is formed between the closed wall and the intermediate wall, and a buffer space in which a strut and a spring fixed from the closed wall are formed is formed between the intermediate walls,

The present invention provides an underfill-type seismic panel applied to a wall of a building and a structure that can effectively cope with various seismic waves by being fixedly installed on an outer surface of an underground wall of an existing building structure or an outer surface of an underground wall of an expandable building structure. There is purpose.

According to an aspect of the present invention, there is provided a wall structure comprising a plurality of closed walls spaced apart from each other, a plurality of intermediate walls spaced from each other between the closed walls, A plurality of strut bosses are inserted through the intermediate wall and a pressing plate is fixed to an end of the strut boss protruding through the intermediate wall and a spring is inserted into a middle portion of the strut boss exposed through the intermediate wall The finishing wall and the intermediate wall are spaced apart from each other by the strut and spring,

A vibration absorbing layer made of soft elastic material is formed between the closed wall and the intermediate wall, and a buffer space is formed between the intermediate walls.

The present invention can be applied to a building structure with a depth of 2 to 3 times the depth of the ground structure of a building, irrespective of an existing building structure and a new building structure. The vibration absorption layer and the buffer space of the multi-layer structure absorb various earthquake waves and attenuate and cancel the earthquake waves, thereby greatly reducing the seismic waves acting on the building structure, It is possible to minimize the damage and to exert an even better seismic effect when it is operated together with existing seismic means applied to the foundation part of the building structure.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an overall perspective view of an anti-
FIG. 2 is a partially enlarged perspective view of a seismic panel according to the present invention. FIG.
Fig. 3 is an overall side sectional view of a seismic panel according to the present invention
Fig. 4 is an exemplary installation view of the spliced panel according to the present invention
Fig. 5 is an explanatory view of the operation of the seismic panel according to the present invention
Figure 6 is a perspective view of another embodiment of the seam panel according to the present invention
7 is a perspective view of another embodiment of the seam panel according to the present invention
8 is a perspective view of another embodiment of the seam panel according to the present invention
Figure 9 is a perspective view of another embodiment of the seam panel according to the present invention

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

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

FIG. 2 is a partially enlarged perspective view of a spliced panel according to the present invention, and FIG. 3 is a side sectional view of a spliced panel according to the present invention.

As shown in the drawings, the base panel according to the present invention includes finishing wall bodies 10 and 10 'positioned at both ends and a plurality of intermediate walls 20 and 20' positioned between the finishing wall bodies 10 and 10 ' (30 ') inserted through the intermediate walls (20) and (20') from the closed walls (10) and (10 ') and inserted into the struts Which is a spring 40,

The vibration absorbing layers 50 and 50 'are formed between the closed walls 10 and 10' and the intermediate walls 20 and 20 ', and between the intermediate walls 20 and 20' And the space portion 60 is formed.

Here, the closed walls 10 and 10 'are suitable for a steel panel such as a metal or a synthetic resin, a rigid panel such as a glass fiber panel and a gypsum board which does not cause warping, and the intermediate wall 20 ) May be of a type in which warpage occurs due to an external force such as a synthetic resin panel, a soft steel plate, a geotextile grid or a rubber sheet.

In addition, it is ideal that the strut 30 (30 ') is formed of a metal seal. One end of the strut 30 (30') is connected to one side of the closed wall 10 (10 ' The strands 30 and 30 'are fixed to the opposite surfaces of the finished wall bodies 10 and 10' and the struts 30 and 30 'penetrate the intermediate walls 20 and 20' And circular or square pressing plates 31 and 31 'are fixedly formed at the ends of the strut brackets 30 and 30', which are exposed through the through-holes 30 and 30 '.

Particularly, a spring 40, which is separately provided, is inserted into the strut 30 (30 ') exposed between the intermediate walls 20 and 20' which are spaced apart from each other. By the reaction force of the spring 40, A buffer space 60 having a predetermined width is formed between the intermediate walls 20 and 20 'and a space between the intermediate walls 20 and 20' adjacent to the closed wall 10 ' A vibration absorbing layer 50 or 50 'made of a soft resilient material is formed between the closed walls 10 and 10' and the adjacent intermediate walls 20 and 20 ' .

In this case, the vibration absorbing layers 50 and 50 'are formed by mixing powdered borax and liquid polyvinyl alcohol, and injecting and curing the mixture. When the borax and the polyvinyl alcohol are mixed, the vibration absorbing layer 50 ) 50 'is made in the form of a gel to fill the gap between the wall 10' 10 'and the wall 20'.

Here, the vibration absorbing layers 50 and 50 'are formed of a soft resilient material commonly called a borax gel, and the shock absorption and vibration reduction can be expected due to the excellent elasticity.

The buffer space 60 serves to separate the vibration absorbing layer 50 and the other vibration absorbing layer 50 'from each other. The vibration acting on the one vibration absorbing layer 50 is transmitted to the other vibration The vibration absorbing layer 50 can be prevented from being directly transmitted to the absorbing layer 50 ', and the vibration space acting on the vibration absorbing layer 50 can be ensured to absorb a shock caused by a seismic wave.

Particularly, in the case of the finishing wall bodies 10 and 10 ', it is made of a steel plate or the like, so that when a seismic wave or the like acts, a seismic wave is transmitted to a large area without deformation and the whole of the finishing wall body 10' And the seismic waves transmitted to the vibration absorbing layers 50 and 50 'are absorbed by the vibration absorbing layers 50 and 50' and absorbed by the vibration absorbing layers 50 and 50 ' The seismic waves attenuated by the one vibration absorbing layers 50 and 50 'are transmitted to the other side through the buffering space portion 60, As the seismic waves are transmitted to the vibration absorbing layers 50 and 50 'and at the same time, the seismic waves are transmitted in a wide area through the other finishing walls 10 and 10' tightly attached to the building structure, the attenuation, .

Accordingly, the base panel of the present invention is fixed firmly to the outer surface of the underground wall of the building structure by using an anchor bolt as shown in FIG. 4, and the base panel is fixed to the entire wall surface of the building structure, Is constructed to have a length of two to three times longer than the depth of the underground wall of the building structure so that it can be embedded sufficiently to cope with seismic waves acting in various directions to the side and the lower portion of the building structure more effectively.

At this time, the above-mentioned seismic panel is continuously connected through welding or the like depending on the area and height of the building structure in a state of being manufactured with a certain height and width, or connected and fixed to each other through various mutual fastening structures, Including the entire wall, than the wall.

Particularly, in the case of an existing building structure, the insulation panel of the present invention can be tightly fixed to the underground wall after the treading operation is performed around the building. If the building structure is to be stretched or shrunk, It is only necessary to introduce an expansion and contraction process to perform backfilling after closely fixing the base panel of the present invention. In the case of a building structure to be stretched or shrunk, a better isolation effect can be obtained by applying an existing base structure to the base portion .

Therefore, when a strong seismic wave acts on the building as shown in FIG. 5, the wavelength of the seismic wave is primarily attenuated through the one-side finishing wall 10, the vibration absorbing layer 50 and the middle wall 20, The closed wall 10, the vibration absorbing layer 50 and the intermediate wall 20 which flow due to the seismic wave absorb the impact from the buffer space 60 and deform and spread the seismic waves due to the buffer space 60 The transmission of the seismic waves by the strut 30 and 30 'is transmitted to the other vibration absorbing layer 50' through the pressing plates 31 and 31 ' Attenuation can be achieved.

In other words, the seismic structure is a principle that reduces the energy received by the building by changing the cycle of vibration caused by the earthquake, or canceling or attenuating it. The energy of the wave is larger as the period is shorter.

In the case of the S wave, the liquid or gas can not pass, which means that the transferring material must move perpendicular to the direction of the S wave. Since the shape of the liquid or gas changes easily and does not return to the initial state, The vibration absorbing layers 50 and 50 'in the present invention serve as a medium for absorbing and suppressing the vibration of the S wave due to the excellent elastic deformation force, And the direction, speed and size of the material changes depending on the nature of the material.

Since the springs 30 and 30 'transmit the seismic wave over a larger area through the pressing plates 31 and 31' at the end, diffusion or dispersion for the seismic wave is performed, And the pressing plates 31 and 31 'are embedded in the vibration absorbing layers 50 and 50' so that the seismic waves are transmitted through the entire surfaces of the pressing plates 31 and 31 ' It will be delivered.

Therefore, the present invention can be applied to both existing and new constructional structures, and it is possible to effectively perform the seismic action on the side of the building structure from the conventional isolation structure, which has been limitedly applied to the foundation portion. It is very innovative and can perform more excellent seismic action in parallel with existing seismic structure which is limited to foundation part, so it can minimize material loss and human damage.

As shown in FIG. 6, a partition wall 70 separately provided between the closed wall 10 and the intermediate wall 20 on one side of the cushioning space 60 may be used as another embodiment of the present invention. A rigid vibration absorbing layer 51 is formed in the space between the finishing wall 10 and the partition wall 70 and a soft vibration absorbing layer 52 is formed between the partition wall 70 and the middle wall 20 The oscillation absorbing layer having different soft elasticity also changes the oscillation period of the seismic wave to obtain a more effective buffering effect.

7, a partition wall 70 (see FIG. 7) is provided between the closed walls 10 and 10 'located on both sides of the buffer space 60 and the intermediate walls 20 and 20' 70 'are spaced apart from each other and rigid vibration absorbing layers 51, 51' are formed between the walls 10, 10 'and the partition walls 70, 70' The flexible vibration absorbing layers 52 and 52 'are formed between the upper and lower walls 70 and 70' and the intermediate walls 20 and 20 'so that the impact due to the seismic waves can be minimized It is.

Since the order and arrangement of the rigid vibration absorbing layers 51 and 51 'and the soft vibration absorbing layers 52 and 52' are not determined, it is preferable that the rigid vibration absorbing layers 51 and 51 ' It can be applied variably.

Also, the number of individuals of the partition walls 70 'and 70' may be variously varied to diversify the numbers of the rigid vibration absorbing layers 51 'and the flexible vibration absorbing layers 52 and 52' Change will be possible.

The rigid vibration absorbing layers 51 and 51 'are prepared by mixing borax powder and liquid polyvinyl alcohol and curing them in the form of a gel. The borax powder is contained in an amount of 60 to 65 wt% And 40 to 50 wt% of borax powder and 50 to 60 wt% of liquid polyvinyl alcohol are mixed with each other to form soft vibration absorbing layers 51 and 51 ' The absorbent layers 52 and 52 'can be formed, and the content of the borax and the liquid polyvinyl alcohol can be appropriately adjusted.

In addition, as shown in FIG. 8, the waterproof panel of the present invention may be formed by inserting a large or small water bag 80 (80 ') in the buffer space 60 as shown in FIG. 8, The airbags 90 and 90 'may be inserted instead of the waterbags 80 and 80' as shown in FIG. 9, as shown in FIG. 9, This can also be applied in order to perform an effective seismic action on seismic waves.

At this time, the water bags 80 and 80 'and the air tubes 90 and 90' can buffer the waves due to the seismic waves acting on the vibration absorbing layers 50 and 50 ' This is because it is possible to perform a more efficient role.

Accordingly, the present invention can be applied to both existing and new constructional structures, as well as to be installed close to the underground portion of the building structure, so that the construction can be carried out simply and quickly. It is very effective because it minimizes the physical loss of the building structure itself and minimizes the damage of people or lives in the building structure.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the present invention as defined by the appended claims. Examples should be understood.

10,10 ': Finishing wall
20,20 ': intermediate wall
30, 30 ': strut 31, 31': pressing plate
40: spring
50, 50 ': vibration absorbing layer 51, 51': rigid vibration absorbing layer
52, 52 ': flexible vibration absorbing layer
60: buffer space
70, 70 ': partition wall
80, 80 ': Water bag
90,90 ': air tube

Claims (8)

A plurality of intermediate walls 20 and 20 'are spaced apart from each other between the finishing walls 10 and 10', and the finishing walls 10 'and 10' A plurality of strut bosses 30 and 30 'having one end fixed to the mutually opposing faces of the intermediate wall 20 and 20' are inserted through the intermediate wall 20 and 20 ' A pressing plate 31 or 31 'is fixed to the end of the strand 30 or 30' protruding through the intermediate wall 20 or 20 ' 30 ', a spring 40 is inserted into the intermediate portion of the intermediate wall 20' (20 ') by the spring bracket 30 (30') and the spring 40, 'Are spaced apart from each other,
The vibration absorbing layers 50 and 50 'made of soft resilient material are formed between the closed walls 10 and 10' and the intermediate walls 20 and 20 ', and the intermediate walls 20 and 20' And a cushioning space (60) is formed between the upper and lower walls of the building.
The method according to claim 1,
Wherein the vibration absorbing layers (50) and (50 ') are gelled by mixing borax powder and liquid polyvinyl alcohol, wherein the vibration absorbing layers (50) and (50') are applied to a wall of a building and a structure.
The method according to claim 1,
A partition wall 70 is further formed between one side finishing wall 10 and the middle wall 20 of the buffer space 60 and a rigid vibration absorbing layer 70 is formed between the finishing wall 10 and the partition wall 70. [ And a soft vibration absorbing layer (52) is further formed between the partition wall (70) and the intermediate wall (20) in comparison with the rigid vibration absorbing layer (51) In-ground embedded seismic panels.
The method of claim 3,
The rigid vibration absorbing layer 51 is made of a mixture of 60 to 65 wt% of borax powder and 35 to 40 wt% of liquid polyvinyl alcohol. The soft vibration absorbing layer 52 is composed of 40 to 50 wt% borax powder and a liquid polyvinyl And 50 to 60% by weight of an alcohol is mixed with the mixture to form a gelled body.
The method according to claim 1,
The partition walls 70 and 70 'are further formed between the closed walls 10 and 10' of the buffer space 60 and the intermediate walls 20 and 20 ' The rigid vibration absorbing layers 51 and 51 'are formed between the partition wall bodies 70 and 70' and the partition walls 70 and 70 ' Wherein a soft vibration absorbing layer (52) (52 ') is further formed between the rigid vibration absorbing layer (51) and the rigid vibration absorbing layer (51').
6. The method of claim 5,
The soft vibration absorbing layers 51 and 51 'are gelled by mixing 60 to 65% by weight of borax powder and 35 to 40% by weight of liquid polyvinyl alcohol. The soft vibration absorbing layers 52 and 52' To 50% by weight of a liquid polyvinyl alcohol and 50 to 60% by weight of a liquid polyvinyl alcohol.
The method according to claim 1,
Wherein the buffer space (60) is formed with a water bag (80) (80 ') inserted into the buffer space (60).
The method according to claim 1,
Wherein the buffer space (60) is formed with air tubes (90) and (90 ') inserted therein.

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