KR20180114678A - earth-quake-resistant construction between the slabs and Wall in Buildings - Google Patents

Abstract

The present invention relates to an earthquake-proof structure between a slab and a wall in a building. The present invention is to secure earthquake resistance while supporting a wall constituting a prefabricated building structure built by assembly between a vertical H-beam and an earthquake-proof block and a slab bottom surface provided on the upper surface of a horizontal H-beam for lattice-form inter-wall partitioning and story height formation. The present invention is provided with wall bumper means for resiliently connecting and supporting each of one side of the earthquake-proof block and the lower surfaces of both ends of the horizontal H-beam and slab buffer means for resiliently connecting and supporting the slab provided on the upper surface of the horizontal H-beam by being connected to and supported by each of regions intersecting with each other in the form of a lattice in the horizontal H-beam forming the story height while partitioning the walls formed by the earthquake-proof block. Transmission of vibration and swing forces attributable to an earthquake and transmitted from the walls to the slab is buffered and offset by earthquake resistance being secured for the prefabricated building structure. The building is provided with the wall bumper means between the slab and the wall. Also, resilient support is performed by the slab buffer means at the lower end of the slab. As a result, the vibration force transmitted from the wall in the event of an earthquake is offset by the buffer means, and thus transmission of a swing force attributable to the earthquake to the slab side through the wall is blocked. As a result, the earthquake-proof structure between a slab and a wall in a building is capable of securing earthquake resistance so that shaking of the entire building attributable to an earthquake can be prevented.

Description

Earth-quake-resistant construction between slabs and walls in buildings.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a seismic structure of a building, and more particularly, to a slab structure for obtaining a structure having excellent vibration resistance when a slab installed across a wall composed of a building block is formed by using a building block, It is about the seismic structure between walls.

It is usual that the earthquake-resistant design of buildings is designed to be able to cope with disasters such as earthquakes and strong winds, and external forces transmitted from buildings to other buildings.

The structure to be constructed by this general seismic design is structured to reinforce the joint between the column structure, the beam structure and the column and the beam, and the slab which forms the space floor or ceiling of the building is supported on the top of the beam structure .

Here, in many cases, the beam structure and the slab are integrally constructed by pouring concrete. In such a construction, the seismic performance is poor, and in the case of a high-rise building, it is difficult to ensure structural safety, .

On the other hand, there is a slab construction method having a structure in which a slab is installed on the upper part of a beam structure and another type of structure is interposed between the beam structure and the slab, .

However, in the conventional method of installing the earthquake-proof slab, since the slab is constructed on the beam structure, even when the earthquake-proof apparatus having a buffer function is interposed between the beam structure and the slab, Vibration and impact are transmitted to the slab through the slab, so that the swinging phenomenon of the slab can not be prevented.

In addition, since the slab is installed on the upper part of the beam structure, if the vibration isolation device having the buffering function is provided between the beam structure and the slab, there is a problem that the thickness of the building is lowered.

In view of the above problems, Korean Patent Registration No. 10-1404814 (published on Apr. 20, 2014) discloses a method of constructing an anti-seismic swing slab. The patent discloses a slab- And a supporting device installation step of installing a suspending member for supporting the suspension member in a fluidizable manner and providing fluid coupling means for coupling the suspending member to the slab and the beam structure in a relative flowable manner; Wherein the suspending member has a bar shape passing through the slab and the beam structure so as to flow therethrough and a coupling portion to which the fluid coupling means is coupled to both longitudinal end regions of the slab; Wherein said flow combining means comprises a pair of flow supports each having a through hole through which both side end regions of said suspending member are allowed to flow, respectively, and a plurality of flow supports, coupled to said engagement portion of said suspending member, And a fluid coupling member supported so as to be capable of relative flow relative to the fluid coupling member.

In the case of the above-mentioned patent, it is possible to minimize the decrease of the bedding height of the building and to support the slab to be suspended in a relatively flat flowable manner. However, there is a problem that the vibration resistance due to the vertical vibration can not be secured.

In the basic structure of a beam and a beam, this technique is applied to a structure between a side surface of a slab installed on the beam and a side surface of the pillar member. Wherein the elastic member is made of rubber, plastic, wood, or styrofoam, and is provided along the periphery of the column member, and is provided between the slab and the beam .

However, in the case of the above-described technique, it is impossible to sufficiently secure the impact resistance and the vibration resistance by the vibration of the slab by using the elastic member which is selected from the rubber, plastic, wood and styrofoam specified by the elastic member .

In addition, in the case of a building using a PC slab in addition to the above-mentioned technology, a composite construction method of making a PRC (Precast Reinforced Layer Construction Method) using a half slab (Half PC Slab) is being carried out in order to secure the earthquake resistance.

The above-mentioned PRC composite method is a method of making PC (Precast Concrete) of reinforced concrete Rahmen structure, and PC materials such as PC columns, PC beams, and half slabs manufactured at factories are transported to the field, It is a method to integrate the structure by putting overburden concrete on site at the junction between the following members and the upper part of the half slab.

However, there is a case in which construction is carried out by constructing a building using a building block by using a construction method by putting in place, or by transferring a PC member from a factory to a site after transferring it to a site, many.

Korean Patent Registration No. 10-1365486 entitled " Method of Manufacturing a Molded Exterior Block Unit for Internal Use ", Korean Patent Registration No. 10-1365487, " Rubber Molded Block Unit ", and Korean Patent Registration 10-1365485 discloses a construction of a dustproof building block unit and a method of constructing a seismic wall structure using the same, and unlike a construction method in which only a conventional PC member is used or a construction is put on the spot, the construction construction air is remarkably shortened and construction In consideration of the completeness and stability, the disclosed construction method and the like are gradually developed and adopted as a practical construction method.

However, even if the wall of the building is constructed by using the prefabricated earthquake-proof block, it is difficult to secure the earthquake-resistance against the slab. To compensate for this, it is conceivable to apply the beam structure and the slab- , It is inevitable that the height of the floor is lowered as indicated in the above-mentioned problems.

On the other hand, the preceding data and prior arts do not provide a sufficient structure for securing the seismic resistance between the slab and the wall. Instead of the seismic design to obtain the interlocking between the wall and the slab, the wall and the slab are separately seismically- So that the construction is difficult and the construction cost is increased.

Korea Patent No. 10-1404814 Korean Patent Publication No. 10-2008-005717 Korean Patent No. 10-1365486 Korea Patent No. 10-1365487 Korea Patent No. 10-1365485

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a slab damping means in which a slab and a wall are brought into contact with each other by using a wall cushion means provided with an elastic spring, And the vibration force transmitted from the wall in the event of an earthquake is canceled by the buffer means so that the swing force due to the earthquake is prevented from being transferred to the slab side through the wall to secure the safety of the building.

Another object of the present invention is to secure the safety of the slab by offsetting the upward and downward flow phenomenon and the left and right swinging force which can be transmitted to the slab by adopting the buffer means provided with the lubrication spring even in the lower end side of the slab in the building .

Another object of the present invention is to provide a relatively simple and convenient facility and construction by being constructed to be suitable for implementation according to seismic design in a prefabricated building structure.

According to an aspect of the present invention,

A wall 100 constituting a prefabricated building structure constructed by assembling between the vertical H-beam 120 and the earthquake-proof block 110, and a wall 100 partitioning the wall 100 and the wall 100 in a lattice form, In a seismic structure between a slab and a wall in a building for supporting a bottom surface of a slab 400 installed on an upper surface of a horizontal H-beam 200,

A wall bumper means for resiliently connecting and supporting the one side face of the vibration-isolating block and the lower both ends of the horizontal H-beam,

Beam is divided into a wall 100 and a wall 100 formed by the earthquake-proof block 110 and connected to a region intersecting in a lattice form in a horizontal H-beam forming a stratum, And the slab damping means for supporting the slab damping means to elastically connect and support the slab, thereby ensuring the vibration resistance of the prefabricated building structure and buffering and canceling the transmission of the swinging force and the swinging force due to the earthquake transmitted from the wall. To provide a seismic structure between the slab and the wall.

According to the present invention, it is possible to provide a wall-structure buffering means between a slab and a wall in a building, and to be elastically supported on the lower end of the slab by means of a slab buffering means so that the vibration force transmitted from the wall during the earthquake is offset by the buffer means, It is possible to secure an earthquake-proof property to prevent shaking of the entire building due to the occurrence of an earthquake by blocking transmission of the force from the slab side through the wall.

In addition, according to the present invention, it is possible to construct a prefabricated building structure suitable for construction according to a seismic design for securing an earthquake-proof property, thereby enabling a relatively simple and convenient construction, thereby reducing costs due to construction construction.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic front sectional view of an example of a building structure installed and installed according to the present invention; Fig.
FIG. 2 is a cross-sectional view showing a wall buffering means for buffering the H-beam between the lower end of the wall and the lower end of the wall in the present invention
Fig. 3 is a view showing a state in which the wall buffer means adopted in the present invention is shown separately
4 is a view showing a state in which the wall buffering means in a separated state according to FIG.
Fig. 5 is a perspective view of a coupled state in which the wall buffering means according to Fig. 4 is coupled between the wall and the slab
Fig. 6 is a schematic front sectional view showing the state of coupling between the wall and the slab using the wall buffering means of Fig.
7 is a schematic plan view showing a state in which the slab damping means are respectively installed in the intersecting regions of the H-beams supporting the slabs
FIG. 8 is a partial enlarged view showing a combined state of the slab damping means installed and installed in the intersection region between the H-beams supporting the slab according to FIG. 7
Fig. 9 is a view showing the slab damping means according to Fig.
Fig. 10 is a perspective view of a pair of slab damping means combined with the slab damping means according to Fig. 9
FIG. 11 is a perspective view of a joint installation perspective view showing an example in which the H-beam is installed in a lattice-like form by using the slab damping means of FIG.

It is to be understood that the specific structural or functional descriptions of embodiments of the present invention disclosed herein are only for the purpose of illustrating embodiments of the inventive concept, It is intended to include all changes, equivalents, or alternatives falling within the spirit and scope of the present invention, as various changes can be made and have various forms, and terms and words used in the specification and claims are to be understood to be either conventional The inventor of the present invention is not limited to the meaning of the present invention and the inventor can define the concept of the term appropriately in order to explain his invention in the best way. . Therefore, the embodiments described in the specification of the present invention and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. It should be understood that various equivalents and modifications are possible or possible.

Also, unless otherwise defined in the description of the present invention, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs I have. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the meaning of the context in the relevant art and, unless explicitly defined herein, are to be interpreted as ideal or overly formal Do not.

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

In the present invention, an H-beam installed in a vertical line is called a vertical H-beam, an H-beam installed in a horizontal line is called a horizontal H-beam to distinguish each other, a vertical H- And a floor material installed on the upper surface of the horizontal H-beam by a horizontal H-beam interconnection horizontally installed on the wall made up of the earthquake-proof block is called a slab.

The means for buffering the swinging force at the time of occurrence of an earthquake is called a wall buffering means and the buffering means provided at the lower end of the horizontal H-beam is provided between the wall and the horizontal H-beam end portion. This means is called a slab buffering means.

The present invention relates to a structure, particularly, a wall structure constituting a building structure, and a buffer means between the slab to prevent vibrations and impact forces from being transmitted to the slab when an earthquake occurs. A horizontal H-beam 200 traversing the wall 100 and a wall buffering means 300 provided between the horizontal H-beam 200 and the wall 100 constitute a horizontal H-beam 200 The slab damping means 400 has a structure in which the slab damping means 400 is formed at an intersection area between the slab dampers 400a and 400b.

The wall 100 is constructed by joining the earthquake-proof block 110, and the vertical H-beam 120 is installed long in the hollow portion of the earthquake-proof block 110.

In addition, an elastic sphere unit (not shown in the drawing) is provided in the earthquake-proof block 110. The elastic sphere unit can be used as an elastic sphere unit of Patent No. 10-1365485 registered by the present applicant and inventor The structure of the 'elastic ball' adopted in the 'construction method of the block unit structure and the method of constructing the seismic wall using the same' or the domestic patent application No. 10-2015-0121463 'Elastic Sphere', Domestic Design Registration No. 30-0856237 and No. 30-0856254 'Elastic Sections for Building Blocks of Seismic Building', which are the cause of this problem, can be adopted.

The coupling structure between the elastic ball unit and the vibration-proof block 110 is deviated from the technical idea of the present patent, and a detailed description thereof will be omitted.

The vertical H-beam 120 is inserted into the earthquake-proof block 110 through holes selected as shown in the drawing, and the earthquake-proof block 110 is vertically stacked along the vertical H- 100).

The exterior material is installed on the outside of the wall 100, and the external structure for installing the exterior material is also disclosed in Korean Patent Application No. 10-2015-0161039. It can be installed and installed by adopting.

As described above, the present invention can be said as an invention on a continuous line for solving problems and improvements in installation and construction in a prefabricated building which is continuously developed and disclosed by this cause.

As described above, according to the present invention disclosed in the present invention, the seismic impact force with the slab 400 is further cushioned and supplemented in the course of the construction of the earthquake-proof block 110, the elastic sphere unit and the exterior material, So as to propose the buffer means 300, 500.

The buffering means 300 may be divided into a wall buffering means 300 and a slab buffering means 500. The wall buffering means 300 may be constructed in such a manner that the inner side of the wall 100 and the slab 400 Beam H-beams 200 that support the horizontal H-beams 200 are connected to each other.

The wall buffering means 300 has a structure shown in FIGS. 3 to 4. The wall buffering means 300 includes a wall surface support 310 having a through hole 311 formed at its center, a fixed angle 320 spaced from the wall surface support 310, A bolt 340 inserted through the through hole 322 at the center of the vertical piece 321 of the fixed angle 320 and a bolt 340 formed on the outer circumferential surface of the bolt 340 to contact with the outer surface of the wall surface support 310 A nut 341 fastened to the bolt 340 at the other surface of the wall support 310 so as to uniformly provide a compressive force to the spring 330, A fixing bolt 350 and a fixing nut 351 for fixing the fixed angle 320 through a guide hole 210 formed in the horizontal H-beam 200 through a long hole 324 formed in the slit 323, ).

The wall support 310 of the wall cushioning means 300 constitutes a spring piece 312 which is bent in both directions and contacts the inner side of the wall 100 as shown in FIG. And the through hole 311 is punched at the center of the protruding piece 313. The protruding piece 313 is protruded from the protruding piece 313 in the center outward direction.

Meanwhile, the plate 360 fixed to the boss piece 312 is provided as shown in FIG. 5 so as to contact the inner surface of the wall body 100.

The wall buffering means 300 having such a structure forms a coupled state as shown in FIG. 4, so that the wall surface support 310 provides a strong repulsive force toward the wall 100 by the elastic force of the spring 330 Even if the swing force generated by the earthquake is applied to the wall 100, the effect of canceling the swing force by the spring 330 can be obtained.

The swing force is also applied by the slab damping means 500 to be described later to cancel the swing force due to the earthquake.

On the other hand, one surface of the bobbin piece 312 comes into contact with the wall body 100.

The present invention does not provide a coupling means between the bolt piece 312 and the wall body 100. [

That is, when the wall 100 and the wall buffering means 300 are coupled to each other when a swing force due to an earthquake occurs, the wall 100 and the wall buffering means 300 are interlocked with the slab 400 by the swing force It is difficult to secure the vibration proof because there is a possibility that the wall 100 and the wall cushioning means 300 are not joined together.

The slab damping means 500 divides the wall 100 and the wall 100 by the earthquake-proof block 110 and divides the horizontal H-beam 200 in the lattice form And supports the slab 400 supported on the upper surface of the horizontal H-beam 200 by elastic connection.

8 to 11, the H-beam fixing part 510 and the slab supporting part 520 are spaced apart from each other, and the H-beam fixing part 510 and the slab supporting part 520 are separated from each other. Beam fixing unit 510 is fixed to one side of the H-beam 200 and the slab supporting unit 520 is supported on the upper side of the slab 400 So as to be supported.

As shown in the drawing, the H-beam fixing unit 510 includes a spring-loaded fixing member 511 having a through-hole 512 formed at its center, and a spring-loaded fixing member 511 bent toward one side of the spring- Beam grasping piece 513 and a fixing hole 514 is formed in the center of the H-beam grasping piece 513. The H-

As shown in FIG. 11, the H-beam fixing unit 510 having such a structure is fixed to the fixing bolt 540 and the fixing nut 541 by the H- And fixed via the fixing hole 514. [

9, the slab supporter 520 includes a protruding piece 522 formed at the center thereof with a through hole 523 formed therethrough, and a horizontal extending piece 522 extending horizontally from the bent end of the protruding piece 522, A vertical bent piece 521a is formed which is vertically bent in a vertical line at an end of the horizontal extending piece 521. [

8, the plate 560 held by the vertical bent piece 521a is provided on the lower surface side of the slab 400 so that the vertical bent piece 521a The plate 560 and the slab support 520 are not supported by the fixing means and are held in contact with each other at the bottom surface of the slab 400. [

The spring 550 of the slab damping means 500 is disposed on the outer circumferential surface of the bolt 530 passing through the H-beam fixing unit 510 and the slab supporting unit 520, So that a strong repulsive force is provided in the direction of the slab 400 in a state of being compressed as the spring 330 of the slab 400 and the vertical vibration of the slab 400 when the up and down swing force is generated Respectively.

The slab damping means 500 is installed in a horizontal H-beam 200 which separates between the wall 100 and the wall 100. The horizontal H-beam 200 has a lattice shape And the horizontal H-beams 200 are connected and supported to the intersecting regions, respectively.

When the vibrating force and the swinging force transmitted by the earthquake are transmitted to the wall 100, the wall buffering means 300 may be installed on the wall structure 100, The swing force transmitted from the wall 100 is canceled by the repulsive force of the compressed spring 330.

The upward and downward swing force transmitted to the slab 400 side is canceled by the repulsive force of the compressed spring 55 of the slab buffering means 500 when the force due to the upward and downward vibrations is transmitted to the slab 400, The vibration force and swing force due to the earthquake can be buffered and offset from being transmitted to the slab 400.

Even if there is a person inside the building by securing the earthquake-proof earthquake like this, it is possible to maintain the safe condition of the thing that can fall down inside the building, so that it is possible to prevent personal injury caused by falling objects. It will be possible to do.

While the present invention has been described with reference to the particular embodiments and drawings, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Various modifications and changes may be made.

Accordingly, it is to be understood that the technical idea of the present invention is to be understood by the following claims, and all of its equivalents or equivalents fall within the technical scope of the present invention.

100; Wall 110; Earthquake proofing block
120; Vertical H-beam 200; Horizontal H-beam
210; Guide ball 300; Wall buffering means
310; Wall support 311; Passage
312; Reorganization 313; Projecting pieces
320; Fixed angles 321; Vertical
322; Through hole 323; Horizontal
324; Elongated hole 330; spring
340; Bolts 341; nut
350; A fixing bolt 351; Fixed nut
360; plate
400; Slab 500; Slab buffering means
510; An H-beam determination unit 511; Spring flange fixing member
512; Through hole 513; H-beam holding fixture
514; A fixing hole 520; Slab support
521; A horizontal extension piece 521a; Vertical bending piece
522; A protruding piece 523; Passage
530; Bolts 531; nut
540; A fixing bolt 541; Fixed nut
550; Spring 560; plate

Claims (8)

A wall 100 constituting a prefabricated building structure constructed by assembling between the vertical H-beam 120 and the earthquake-proof block 110, and a wall 100 partitioning the wall 100 and the wall 100 in a lattice form, In a seismic structure between a slab and a wall in a building for supporting a bottom surface of a slab 400 installed on an upper surface of a horizontal H-beam 200,
A wall buffering means 300 for elastically connecting and supporting both lower ends of the horizontal H-beam 200 in contact with the inner side of the wall 100,
Beam 200 and the horizontal H-beam 200, which partition the wall 100 by the earthquake-proof block 110 and the wall 100, The slab damping means 300 is provided to elastically connect and support the slab 400 installed on the upper surface of the slab 400 so as to secure the vibration-proof property of the prefabricated building structure. The vibration force and the swinging force, And the earthquake-proof structure between the slab and the wall in the building.
The method according to claim 1,
The wall buffering means 300 includes a wall surface support 310 having a through hole 311 formed at its center, a fixed angle 320 spaced from the wall surface support 310, A bolt 340 inserted through a central through hole 322 of the bolt 340 and a spring 330 provided on an outer circumferential surface of the bolt 340 to contact and protrude from the outer surface of the wall supporting member 310, A nut 341 fastened to the bolt 340 at the other surface of the wall support 310 so as to uniformly provide a compressive force to the horizontal support member 310 and a long hole 324 formed in the horizontal piece 323 of the fixed angle 320, And a fixing bolt (350) and a fixing nut (351) for fixing the fixed angle (320) through a guide hole (210) formed in the horizontal H-beam (200) Seismic structure between walls.
3. The method of claim 2,
The wall supporting member 310 in the wall buffering means 300 constitutes an opening piece 312 that is bent in both directions and is in contact with the inner side surface of the wall body 100, And a through hole (311) is formed in the center of the protruding piece (313), thereby forming a protruding piece (313) protruding in the shape of "∩".
The method of claim 3,
And a plate (360) fixed to the bobbin piece (312) so as to be in contact with an inner surface of the wall body (100).
The method according to claim 1,
The slab buffering means 500 includes a bolt 530 and a nut 530 which are spaced apart from the H-beam fixing portion 510 and the slab supporting portion 520 and are fastened between the H-beam fixing portion 510 and the slab supporting portion 520, Beam fixation unit 510 is fixed to one side of the stretchable H-beam 200 and the slab support unit 520 is fixed to the other side of the bolt 530, Comprises a slab (400) and a slab (400) in an upward direction.
6. The method of claim 5,
The H-beam fixing part 510 includes a spring end fixing part 511 having a through hole 512 formed at the center thereof, an H-beam fixing part 511 bent to one side of the spring end fixing part 511, (513), and a fixing hole (514) is formed in the center of the H-beam holding fixture (513).
6. The method of claim 5,
The slab supporter 520 is formed with a protruding piece 522 formed at the center thereof with a through hole 523 formed therein and a horizontal extending piece 521 extending horizontally at the bent end of the protruding piece 522, And forming a vertical bent piece (521a) perpendicularly bent in a vertical line at the end of the horizontal extension piece (521).
8. The method of claim 7,
And a plate (560) held by the vertical bent piece (521a) of the slab supporting part (520) on the lower surface side of the slab (400).

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