KR101415731B1 - Suspension device for vibration isolation swing slab - Google Patents

Abstract

The present invention relates to an anti-vibration swing slab support apparatus, comprising: a suspension member for suspending a slab in a relatively flat flowable manner at a lower portion of a beam structure; And flow coupling means for coupling the suspending member to the slab and the beam structure in a relative flow possible manner.
As a result, it is possible to effectively prevent the slab from rocking when the building vibrates.

Description

[0001] Suspension device for vibration isolation swing slab [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an anti-vibration swing slab supporting apparatus, and more particularly, to an anti-vibration swing slab supporting apparatus, Which can improve the construction of the slab so as not to be transmitted to the slab.

Generally, earthquake-resistant design of buildings that can cope with disasters such as earthquakes or strong winds or external forces transmitted from buildings to other buildings is structured to reinforce the joining areas of columns and beams, columns and beams. And the slab forming the space floor or ceiling of the building is installed in a form supported on the top of the beam structure.

At this time, the beam structure and the slab can be integrally constructed by pouring the concrete, but such a structure is poor in seismic performance, and in the case of a high-rise building, it is difficult to secure structural stability.

In the case of the earthquake-resistant construction method, there is a method of constructing the slab in the form of interposing an isolation device capable of absorbing vibration between the beam structure and the slab, while the slab is constructed on the beam structure.

However, since the conventional slab is constructed on the upper part of the beam structure, even if the beam-splitting device having a buffering function is interposed between the beam structure and the slab, The vibration and the impact are transmitted to the slab, and the slab is shaken.

If such a rocking motion of the slab is generated excessively, it is impossible to guarantee the safety of the residents and furniture of the inside of the building, and in the worst case, there is a problem that the slab collapse and the collapse of the building occur.

Since the slab is installed on the upper part of the beam structure, an isolation device having a buffering function is interposed between the beam structure and the slab.

Further, since an expensive seismic isolation device is used, the construction cost is increased.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an anti-vibration swing slab supporting apparatus capable of effectively preventing rocking of a slab during vibration of a building.

Another object of the present invention is to provide an anti-vibration swing slab supporting apparatus capable of minimizing the thickness of the building and reducing the construction cost.

This object is achieved in accordance with the invention by a suspension structure comprising: a suspension member for suspending a slab in a planar flow manner at a lower portion of a beam structure; And fluid coupling means for coupling the suspending member relative to the beam and the beam structure. ≪ RTI ID = 0.0 > [0002] < / RTI >

Here, the suspending member may have 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 is formed; 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 flow-combining member supported so as to be capable of flowing relative to the flow-combining member.

At this time, it is effective that the flow combining member has a spherical shape, and a depression spherical surface corresponding to the spherical surface of the flow combining member is formed at one side of the flow support toward the flow combining member.

Alternatively, the flow combining member may be formed in a partial sphere at one side toward the flow support, and a depression spherical surface corresponding to the partial spherical surface of the flow combining member may be formed at one side of the flow support toward the flow combining member .

Alternatively, it is effective that the flow support has a spherical shape, and one side of the flow combining member facing the flow support is formed with a depression spherical surface corresponding to the spherical surface of the flow support.

Alternatively, the flow support may be formed in a partial sphere at one side toward the flow combining member, and a depression spherical surface corresponding to the partial spherical surface of the fluid support may be formed at one side of the flow combining member toward the flow support desirable.

Here, it is effective that the engaging portion of the suspending member and the flow combining member are coupled to each other with a screw fastening structure.

At this time, it is preferable that the flow coupling member is formed with a fastening tool contact portion of a polygonal surface.

And a plurality of flow holes through which the suspending member is allowed to flow are formed at intervals in the lengthwise direction in both side regions of the slab and the beam structure corresponding thereto, It is more preferable that the suspending member has a diameter smaller than that of the flow hole and penetrates the flow hole.

At this time, it is more effective that the flow hole is formed as a long hole corresponding to the longitudinal direction or the width direction of the beam structure.

According to the present invention, there is provided an anti-vibration swing slab supporting apparatus capable of effectively preventing rocking of a slab when a building vibrates.

In addition, there is provided an anti-vibration swing slab supporting apparatus capable of minimizing the height of the floor of the building and reducing the construction cost.

1 is a perspective view of an anti-vibration swing slab support device according to the present invention,
Figure 2 is an exploded perspective view of the splined swing slab support device of Figure 1,
FIG. 3 is a perspective view showing the construction of the plain swing slab using the plain swing slab supporting apparatus of FIGS. 1 and 2. FIG.
Fig. 4 is an enlarged cross-sectional view of the mounting area of the plain swing slab supporting device of Fig. 3,
FIGS. 5 to 8 are enlarged cross-sectional views of an installation area of an anti-vibration swing slab supporting device according to another example of the present invention,
9 to 10 are plan views of slabs corresponding to the construction of a base swing slab support apparatus according to another example of the present invention.

1 to 4, an anti-vibration swing slab supporting apparatus 1 according to the present invention includes a suspension supporting a slab 110 in such a manner that the slab 110 can relatively float relative to a lower portion of the beam structure 120, And a flow coupling means (20) for coupling the suspension member (10) relative to the slab (110) and the beam structure (120).

The suspending member 10 has a bar shape having a length that allows the slab 110 and the beam structure 120 to flow therethrough and has a flow joint member 25 of the flow combining means 20 to be transferred to both longitudinal end regions. It is preferable that the engaging portion 11 is formed to be engaged with the engaging portion.

At this time, it is preferable that the engaging portion 11 of the suspending member 10 and the fluid engaging member 25 to be described later are coupled with each other by a screw fastening structure. It is possible to select a form in which a female thread portion is formed on the coupling member 25 or a coupling portion 11 of the suspending member 10 is a female thread portion and a male thread portion is provided on the flow coupling member 25. [

A flow hole 111 is formed in the slab 110 and the beam structure 120 to allow the suspending member 10 to flow therethrough for installation of the suspending member 10. This flow hole 111 has a larger inner diameter than the outer diameter of the suspending member 10 so that the suspending member 10 can flow inside the flow hole 111. At this time, the flow hole 111 is formed as a long hole in a direction corresponding to the longitudinal direction or the width direction of the beam structure 120, so that the relative plane flow of the slab 110 relative to the beam structure 120 is performed in one direction . Or the flow holes 111 may be formed in a circular shape having a larger inner diameter than the outer diameter of the suspension member 10 so as not to restrict the relative plane movement direction of the slab 110 relative to the beam structure 120 have.

The flow holes 111 may be formed in a plurality of spaces on both side regions of the slab 110 and the corresponding beam structure 120 along the longitudinal direction.

On the other hand, the flow coupling means 20 comprises a pair of flow supports 21 for allowing both side end regions of the suspending member 10 to flow over the slab 110 and the beam structure 120 respectively, (25) which are respectively coupled to both side engaging portions (11) of the suspending member (10) so as to be supported so as to be capable of relative flow with respect to the supporting member (21).

The flow support (21) is formed with a through hole (22) through which the end region of the suspending member (10) is allowed to flow.

The through hole 22 of the fluid support 21 has a larger inner diameter than the outer diameter of the suspending member 10 and at least corresponds to the fluid hole 111 formed in the slab 110 and the beam structure 120, It is preferable to have an inner diameter. Of course, the through hole 22 can be formed with a smaller inner diameter than the slab 110 and the flow hole 111 of the beam structure 120 in a range having a larger inner diameter than the outer diameter of the suspending member 10.

The flow support 21 is provided with a circumferential area of the through hole 22 having a larger circumference than the flow hole 111 of the slab 110 and the beam structure 120. As a result, when the suspending member 10 having passed through the through hole 22 of the fluid support 21 is engaged with the flow combining member 25, both side end regions of the suspending member 10 are respectively connected to the slabs 110 So as to flow over the beam structure 120.

In addition, on one side of the flow support 21 facing the flow coupling member 25, there is provided a depression spherical surface 23 (corresponding to the spherical surface 27 of the flow coupling member 25, which will be described later) Is formed.

The flow coupling member 25 has a spherical shape at least on the side facing the fluid support 21 and a female screw portion is formed as a coupling structure 26 in which a coupling portion 11 of the suspending member 10 is engaged .

The flow coupling member 25 is a spherical member having a larger outer diameter than the through hole 22 of the fluid support 21 and the partial spherical surface 27 on the side facing the fluid support 21 is connected to the fluid support 21 (23).

A fastening tool contact portion 28 is formed on the outer circumferential surface of the flow coupling member 25 to improve the workability of an operator to fasten the fluid coupling member 25 to the coupling portion 11 of the suspending member 10 . At this time, the fastening tool contact portion 28 may be formed in a polygonal shape or may be formed in various types of friction patterns.

The engaging structure 26 for engaging the suspending member 10 is formed by forming a female threaded portion on the flow combining member 25 when the engaging portion 11 of the suspending member 10 is made of a male or a female, When the engaging portion 11 of the member 10 is female-threaded, a configuration in which a male screw portion is provided on the flow engaging member 25 can be selected.

Here, as shown in Figs. 1 to 4, the flow coupling member 25 may have a semi-spherical shape, as shown in Fig. 8, in addition to the spherical sphere shape. That is, the fluid coupling member 25 can be formed in a partially spherical shape at one side which is supported so as to be able to flow relative to the recessed spherical surface 23 of the fluid support 21. At this time, the fastening tool contact portion 28 may be formed on the other side of the flow coupling member 25 at a polygonal surface, or as a protruding structure having a friction pattern as shown in Fig.

On the other hand, the fluid support 21 and the fluid coupling member 25 of the fluid coupling means 20 can be provided in various forms other than the above-described forms within a mutually flowable relationship.

For example, as shown in FIG. 7, the flow support 21 has a spherical shape, and the flow coupling member 25 is formed with a recessed spherical surface 23 which is in contact with the spherical surface 27 of the flow support 21 so as to be relatively fluid- Lt; / RTI > At this time, it is preferable that a fluid contact body 21a in contact with the fluid support 21 is interposed between the fluid support 21 and the slab 110.

Alternatively, as shown in Fig. 6, one side of the flow supporting body 21 facing the flow combining member 25 is provided in the form of a hemisphere formed in a partially spherical shape, and the flow combining member 25 is provided with a partial spherical surface And a depression spherical surface 23 corresponding to the depression 27 may be formed.

In addition, the shape of the fluid support 21 and the fluid coupling member 25 of the fluid coupling means 20 can be varied in such a manner as to be movable relative to each other.

The construction and seismic action of the slab 110 using the above-described seismic swing slab supporting apparatus 1 according to the present invention will be described below.

First, as shown in FIGS. 1 and 2, a slab 110 is disposed below a beam structure 120 in a construction process of a building. 9 and 10, the slab 110 includes a span slab corresponding to the area between the four pillars 130, or two span slabs corresponding to the area between the six pillars 130 And may be various types of slabs. At this time, the corner or peripheral region of the slab 110 corresponding to the column 130 is formed with a space in which the column 130 is located. At this time, it is preferable that the damping means 30 is installed on either one of the peripheral region of the slab 110 and the columnar structure 130 facing the slab 110, as shown in FIG. The damping means 30 may be a damper or a damping device of various types generally used for the construction of a building.

In this state, the suspension member 10 is inserted into the flow hole 111 formed in the beam structure 120 and the slab 110 so that both end portions of the suspension member 10 are connected to the upper portion of the beam structure 120 and the slab 110, .

The flow support 21 is then positioned such that both ends of the suspension member 10 pass through the bottom of the slab 110 and the through hole 22 of the flow support 21 at the top of the beam structure 120 To complete the construction of the seismic swing slab support apparatus 1 and the slab 110 by fastening the flow coupling member 25 to the both side engaging portions 11 of the suspending member 10. [

Thus, the weight of the slab 110 of the building in which the base swing slab supporting apparatus 1 according to the present invention is installed is subjected to a downward load on a self weight and a series of heavy objects existing on the slab 110.

On the other hand, when vibration or impact occurs in the building, the column structure 130 and the beam structure 120 are oscillated by vibration. At this time, the pivotal movement of the pillar structure 130 and the beam structure 120 is performed by the slab supporting apparatus 1 according to the present invention in a slab 110 supported in a suspended manner so as to be relatively flat relative to the beam structure 120 It is blocked from being transmitted.

4, the flow supporting body 21 and the flow combining member 25 are formed in a state in which the downward load is applied to the slab 110 even when the pillar structure 130 and the beam structure 120 swing. The relative flow structure of the spherical surface 27 and the recessed spherical surface 23 of the slab 110 and the beam structure 111 of the slab 110 through which the suspension member 10 is allowed to flow, The structure of the through hole 22 causes the slab 110 to flow relatively flat with respect to the beam structure 120 so that the slab 110 does not oscillate.

Thus, even if a vibration or an impact occurs in the building, the slab 110 does not swing, thereby ensuring the safety of various houses such as tenants and furniture in the building, and effectively preventing the collapse of the slab 110 and the collapse of the building can do.

Since a separate isolation device is not interposed between the slab 110 and the beam structure 120, the slab 110 can be brought into close contact with the beam structure 120 as much as possible. Thereby, the floor height of the building is not lowered.

Further, since an expensive seismic isolation device is not used, the construction cost can be reduced.

INDUSTRIAL APPLICABILITY As described above, according to the present invention, it is possible to effectively prevent the slab from swinging when the building vibrates.

In addition, there is provided an anti-vibration swing slab supporting apparatus capable of minimizing the height of the floor of the building and reducing the construction cost.

10: Suspension member 20: Flow coupling means
21: floating support 23: depressed spherical surface
25: fluid coupling member 27: spherical surface
110: Slab 111: Floating ball
120: beam structure

Claims (10)

A suspending member suspending the slab so as to freely oscillate at a lower portion of the beam structure;
And flow coupling means for coupling said suspending member relative to said beam and said beam structure in a relative flow manner;
Wherein the suspending member has a bar shape passing through the slab and the beam structure so as to flow therethrough, and is formed with a coupling portion to which the fluid coupling means is coupled to both longitudinal end regions,
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 flow coupling member supported so as to be capable of relative flow relative to the slab support member. delete The method according to claim 1,
Wherein the flow combining member has a spherical shape and a depression spherical surface corresponding to a spherical surface of the flow combining member is formed on one side of the fluid support facing the flow combining member. The method according to claim 1,
Wherein the flow combining member is formed with a partial sphere at one side toward the flow support and a depression spherical surface corresponding to a partial spherical surface of the flow combining member is formed at one side of the flow support toward the flow combining member Wherein the slab support device comprises: The method according to claim 1,
Wherein the fluid support has a spherical shape and a depression spherical surface corresponding to a spherical surface of the fluid support is formed on one side of the fluid coupling member toward the fluid support. The method according to claim 1,
Wherein the flow support is formed with a partial sphere at one side toward the flow combining member and a depression spherical surface corresponding to the partial spherical surface of the flow support is formed at one side of the flow combining member toward the flow support. Wherein the slab support device comprises: 7. The method according to any one of claims 3 to 6,
Wherein the coupling portion of the suspending member and the fluid coupling member are coupled together in a threaded engagement structure. 8. The method of claim 7,
Wherein the flow combining member is formed with a multifaceted fastening tool contact. 8. The method of claim 7,
Wherein a plurality of flow holes through which the suspending member is allowed to flow are formed at intervals in the longitudinal direction on the both side regions of the slab and the beam structure corresponding thereto;
Wherein the suspending member is installed to penetrate the flow hole with a smaller diameter than the flow hole. 10. The method of claim 9,
Wherein the flow hole is formed as a long hole corresponding to the longitudinal direction or the width direction of the beam structure.

Images