KR101329490B1 - Installation structure for controlling deflection of deck plate of slim floor with altering support point and construction method thereof - Google Patents

Abstract

The present invention provides an installation structure of a deck plate in a slim floor construction method and a construction method thereof capable of controlling deflection of the deck plate by changing a point in order to control the deflection of the deck plate due to a loaded weight or a worker. The installation structure of the deck plate in the slim floor construction method in which the deflection is controlled by changing the point according to an embodiment of the present invention includes an H-shape steel beam attached to a steel column by forming an asymmetry cross section in which the width of an upper flange is larger than the width of a lower flange; a shear connection ring installed on the upper surface of the upper flange of the H-shape steel beam in the longitudinal direction at regular intervals; the deck plate installed on the upper surface of the lower flange to be supported as both ends are inserted into webs of the H-shape steel beam facing each other; a connection support member arranged in a diagonal direction by passing through the deck plate in a position in which one end is connected to the shear support ring and the other end is far from the end of the deck plate at a fixed distance; a support mounting shoe supporting the deck plate by being connected to the connection support member passing through the deck plate; and a support mounting shoe support nut supporting the bottom of the support mounting shoe by being screwed to the end of the connection support member.

Description

Installation structure for controlling deflection of deck plate of slim floor with altering support point and construction method

The present invention relates to a deck plate deflection control structure and a construction method thereof applied to a slim floor method, in particular applicable to long span, the deflection is controlled by one point change to control the deflection of the deck plate during construction It relates to a deck plate installation structure of the slim floor method and its construction method.

A steel composite beam system is known in which a slab is placed on an upper flange of an H-beam, and the slab and an H-beam are integrated by a shear connecting member (shear stud) installed on the upper flange of the beam. In this case, since the slab is spread over the H-beams, there is a problem that the height of the entire floor system including the beams becomes very high compared to the reinforced concrete structure.

As an alternative to solve this problem, a slim floor method has been developed that can draw the maximum volume ratio within the limited height of the building. This slim floor method is a general term for the composite floor plate method in which a slab is inserted into a steel ball. Steel beams use asymmetric H-beams with a lower width than the width of the upper flange to increase the cross-section efficiency of the beam, and make the beam dance smaller than the conventional one. You can save a lot. In addition, since the slab is inserted into the web of the cheolgolbo can relatively reduce the floor height and improve the integrity of the bottom plate and the beam, there is no need for fireproof coating, it is a method that has a number of advantages such as the reduction of the exterior material due to the floor height reduction.

However, when the deck plate applied to the slab is applied to the worker or stacked material weight acts on the deck plate, the deck plate is difficult to implement the long span due to the large amount of deflection. In addition, to prevent sag, a separate copper bar must be installed, and a small beam must be installed in the middle, thereby degrading economic efficiency and constructability.

As a background technology of the present invention, Korean Laid-Open Patent Publication No. 10-2004-0009566, a combination structure of a steel plate reinforcement concrete beam and a bottom plate for a slim floor method is proposed. It is a long plate steel, consisting of a lower plate horizontally installed along the longitudinal direction of the beam, the main root and the frame, the prosthesis is installed in the upper direction of the lower plate, and on the long side end of the lower plate, It consists of a slab concrete mounted along the top of the bottom plate and the bottom plate mounted along the longitudinal direction of the slab concrete integrally on the top of the bottom plate.

However, the background art can be applied to reinforced concrete beams, and it is not proposed to implement the long span or reduce the amount of deflection due to the loading of workers or heavy materials during the construction of deck plates.

Korea Patent Registration No. 10-0957571 Korean Laid-Open Patent Publication No. 10-2010-0057995

The present invention is applicable to a long span, and provides a deck plate installation structure and a construction method of the slim floor method that sag is controlled by one point change to control the deflection of the deck plate even during construction or workers or stacked heavy objects. Has its purpose.

The deck plate installation structure of the slim floor method which sag is controlled by a point change according to an appropriate embodiment of the present invention,

H-beams are joined to the steel column to form asymmetrical cross section of the lower flange is larger than the width of the upper flange;

Shear connecting rings installed at regular intervals in the longitudinal direction on the upper surface of the upper flange of the H-beam;

A deck plate installed at both ends of the H-beams facing each other to be supported by the upper surface of the lower flange;

A connecting support member having one end connected to the shear connecting ring and the other end disposed in an oblique direction by inserting the deck plate at a position separated by a predetermined distance from the end of the deck plate;

A support saddle shoe connected to the end of the connecting support member through which the deck plate is inserted to support the deck plate; And

It is characterized in that it comprises a bearing saddle support nut for supporting the bottom surface of the supporting saddle is screwed to the end of the connection supporting member.

In addition, the shear connection ring is characterized in that any one of the stud bolt, eye bolt, U-shaped ring form.

In addition, the connection support member is characterized in that the steel bar or cable.

In addition, the support saddle is characterized in that it has any one of the form of a plate-like shape of both ends bent upwards or a square pipe of a square cross section having a predetermined length.

The construction method of the deck plate installation structure of the slim floor method which sag is controlled by the point change which concerns on appropriate embodiment of this invention,

Joining the H-beams to the steel column, the H-beams having an asymmetric cross-section having a larger width than that of the upper flange;

Installing shear linkages at regular intervals in the longitudinal direction on the upper surface of the upper flange of the H-beam;

Inserting both ends of the deck plate into the webs of the H-beams facing each other to support the upper surface of the lower flange;

Connecting one end of the connection supporting member to the shear linking ring and inserting the other end thereof in an oblique direction by inserting the deck plate at a position separated by a predetermined distance from the end of the deck plate; And

It is characterized in that the construction through the step of fixing the supporting saddle supporting the deck plate to the end of the connecting support member inserted through the deck plate.

The deck plate installation structure of the slim floor method and the construction method thereof, in which the deflection is controlled by the point change according to the present invention, is pointed by the connection support member when the worker climbs on the deck plate or the heavy material is placed on the deck plate during construction. As the distance between them becomes narrower, deflection can be controlled, which makes it possible to implement long spans.

In addition, the shear connection ring installed in the H-beams to secure the connection support member to perform the function of the shear connector to improve the synthesis of the concrete slab.

In addition, the deflection of the deck plate is controlled and the bearing capacity is increased to enable a span that can be applied without moving, and the construction of small beams can be omitted, thereby improving economical construction and construction efficiency.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is an installation state of the deck plate according to an embodiment of the present invention.
Figure 2 is an exploded view of the main part of Figure 1;
3 is a sectional view taken along the line AA in Fig.
4 is a sectional view taken along line BB of Fig.
Figure 5a is a view showing a state in which the various forms of the shear linkage applied to the present invention is welded to the H-beams.
Figure 5b is a view showing a state in which the various forms of the shear linkage applied to the present invention is fixed to the H-beam with a nut.
Figure 6 is a view showing another connection method of the connecting support member and the shear connecting ring applied to the present invention.
7a and 7b is an installation state according to a modification of the support saddle shoe applied to the present invention.
8 is a construction flowchart of the floor slab according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

1 to 4, the deck plate 16 is continuously installed on the H-beams 12 and 12 joined to the steel pillars 5 and 5.

The H-beams 12 and 12 have an asymmetric cross section in which the width of the lower flange 121 is larger than that of the upper flange 122.

Shear connecting rings 14 are installed at regular intervals in the longitudinal direction on the upper surfaces of the upper flanges 122 of the H-beams 12 and 12. Shear connecting ring 14 is arranged in one row in this embodiment, but in the case of H-beams supporting the deck plate 16 on both sides is installed in two rows.

The shear connection ring 14 may be any one of a stud bolt shape as shown in FIGS. 5A and 5B, an eyebolt shape as shown in (B), and a c-shaped ring shape as shown in (C). At this time, the shear connection ring 14 is used as a connection means with the connection support member 18 to be described later together with the function of the shear connector in the concrete floor plate. The shear link ring 14 may be fixedly attached to the H-beam by welding as shown in FIG. 5A, or fixedly installed by a nut N as shown in FIG. 5B. 6 illustrates an example of a connection method between the connecting support member 18 and the shear linking ring 14.

Deck plate 16 is installed so that both ends are respectively inserted into the web 123 of the H-beams 12 and 12 facing each other to be supported on the upper surface of the lower flange 121. The deck plate 16 is not limited to a specific kind, shape or cross-sectional structure.

The deck plate 16 is supported by the H-beams 12 and 12 via the connecting support member 18. The connecting support member 18 is diagonally connected by inserting a hole 161 penetrated into the deck plate 16 at a position where one end is connected to the shear link ring 14 and the other end is separated by a predetermined distance from the end of the deck plate 16. Are arranged in the direction. Connection support member 18 may be composed of a cable made by twisting a steel bar or strand. When the connection support member 18 is made of a steel bar, male threads are formed at both ends for fastening the fixing nuts 17 and 22. When the connection support member 18 is made of a cable, it can be connected to the shear link ring 14 through a well-known U-shaped clamp.

At the end of the connecting support member 18 through which the deck plate 16 is inserted, a supporting saddle shoe 20 for supporting the deck plate 16 is provided. The supporting saddle shoe 20 may be in a form in which both ends of the rectangular steel sheet are bent upward as shown in FIGS. 2 and 3, or may have a square pipe shape having a predetermined length as shown in FIGS. 7A and 7B. At this time, the supporting saddle shoe 20 has a hole 201 through which the end of the connecting support member 18 is inserted.

At the end of the connecting support member 18, a supporting saddle shoe support nut 22 for supporting the bottom surface of the supporting saddle shoe 20 is screwed.

The construction method of the slab to have the deck plate installation structure of the slim floor method that the deflection is controlled by such a point change.

First, as shown in FIG. 8 (a), the H-beams 12 and 12 having asymmetric cross sections having a larger width than the width of the upper flange are joined to the steel pillars 5 and 5.

Next, the shear connecting ring 14 is installed at regular intervals in the longitudinal direction on the upper flanges of the H-beams 12 and 12. The shear linkage 14 may be any of the illustrated forms of FIG. 5.

Then, both ends of the deck plate 16 are respectively inserted into the webs of the H-beams 12 and 12 facing each other as shown in FIG. 8B to be supported on the upper surface of the lower flange. At this time, the adjacent deck plates 16 and 16 are installed so that the bent ends overlap each other as shown in FIG.

Then, one end of the connection support member 18 as shown in Figure 8 (c) to the shear connection ring 14, for example, as shown in Figure 2 or 3 with a shear connection member fixing nut 17 and the other end of the deck plate A hole 161 formed at a position separated by a predetermined distance from the distal end of (16) is inserted through and arranged. Therefore, the connection support member 18 is disposed in an oblique direction.

Next, the supporting saddle shoe 20 supporting the deck plate 16 is connected to the lower end of the connecting support member 18 through which the deck plate 16 is inserted.

Then, the supporting saddle shoe support nut 22 supporting the bottom surface of the supporting saddle shoe 20 is screwed to the end of the connecting support member 18. Therefore, the supporting saddle 20 is in close contact with the lower surface of the deck plate 16.

As such, when the deck plate 16 supports the H-beams 12 and 12 through the connection supporting member 18, the rebar is added to the upper surface of the deck plate 16 as shown in FIG. Reinforcement is poured concrete is completed construction of the concrete slab (30).

In the deck floor installation structure of the slim floor method in which the deflection is controlled by such a point change, the connection member 18 when the operator climbs on the deck plate 16 or the heavy material is deposited on the deck plate 16 during the deck plate installation. By narrowing the distance (S) between the two points it is possible to control the deflection of the deck plate, thereby enabling the implementation of long span.

That is, reaction force is generated in the supporting saddle shoe 20 connected to the end of the connection support member 18 to support the deck plate 16. Therefore, the reaction force point of the deck plate 16 is moved further by L toward the center of the deck plate 16 from the flange side of the H-beams 12 and 12, the deflection is controlled and the long span can be implemented.

In addition, the shear connection ring installed in the H-beams improves the synthesis of the concrete slab by performing the function of the shear connector.

In addition, the deflection is controlled and the bearing capacity is increased to enable a span that can be applied without moving, and construction of small beams can be omitted, thereby improving economical construction and construction efficiency.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

5: pillar
12: H-beam
14: shear linkage
16: deck plate
18: connecting support member
20: stand saddle
22: support saddle support nut

Claims (5)

H-beams 12 and 12 joined to the steel column to have an asymmetric cross section with a larger width than that of the upper flange;
Shear connecting rings 14 installed at regular intervals in the longitudinal direction on the upper flanges of the H-beams 12 and 12;
A deck plate 16 having both ends respectively inserted into the webs of the H-beams 12 and 12 facing each other and supported on the upper surface of the lower flange;
A connection support member 18 having one end connected to the shear linking ring 14 and the other end disposed in an oblique direction by inserting the deck plate 16 at a position separated by a predetermined distance from the end of the deck plate 16;
A support saddle shoe 20 connected to an end of the connection support member 18 through which the deck plate 16 is inserted to support the deck plate 16; And
The deck plate installation structure of the slim floor construction method of controlling the deflection by the point change characterized in that it comprises a support saddle shoe support nut 22 which is screwed to the end of the connection support member 18 to support the bottom surface of the support saddle shoe. And his construction method. The method of claim 1,
The shear linkage 14 is
Deck plate installation structure and construction method of the slim floor method is controlled sag by changing point characterized in that the stud bolt, eye bolt, U-shaped ring form. The method of claim 1,
The connection support member 18 is a deck plate installation structure and a construction method of the slim floor method that sag is controlled by changing the point, characterized in that the steel bar or cable. The method of claim 1,
Supporting saddle shoe 20 is a deck plate of the slim floor method of the deflection is controlled by changing the point, characterized in that it has any one of the form of a plate or a square pipe of a square cross section having a predetermined length bent both ends upwards. Mounting structure and its construction method. Joining the H-beams 12 and 12 to the steel column to form an asymmetric cross section having a larger width than that of the upper flange;
Installing a shear linking ring (14) at regular intervals in the longitudinal direction on the upper flanges of the H-beams (12, 12);
Inserting both ends of the deck plate 16 into the webs of the H-beams 12 and 12 facing each other to support the upper surface of the lower flange;
Connecting one end of the connecting support member 18 to the shear linking ring 14 and placing the other end thereof in an oblique direction by inserting the deck plate 16 at a position away from the end of the deck plate 16 by a predetermined distance; ; And
Deflection is controlled by the point change characterized in that it is constructed through the step of fixing the bearing saddle 20 supporting the deck plate 16 to the end of the connection support member 18 through which the deck plate 16 is inserted. Deck plate installation structure of the slim floor method and its construction method.

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