KR100957571B1 - Anti-buckling reinforcing structure for asymmetric steel beam at slim floor system and its construction method - Google Patents

Abstract

PURPOSE: An anti-buckling reinforcing structure for an asymmetry steel frame beam in a slim floor system, and a construction method thereof are provided to prevent buckling and damage by using a reinforcing member. CONSTITUTION: A slim floor system comprises an asymmetry steel frame beam, a holder(20), a floor plate, and reinforcing members(30). The width of the lower flange(14) of the asymmetry steel frame beam is the upper flange(12). A floor plate is a deck plate or a half slab, and is placed on the holder. The reinforcing members are formed in the bent parts of the holder.

Description

Anti-buckling Reinforcing Structure For Asymmetric Steel Beam At Slim Floor System And Its Construction Method}

In the present invention, when constructing a floor plate in an asymmetric steel beam (Asymmetric Steel Beam) combined with a cradle commonly used as a structural material in a slim floor system (Slim Floor System), buckling and damage due to load and moment using a reinforcement The present invention relates to an anti-buckling reinforcement structure for asymmetric steel beams and its construction method in an economical and structurally safe slim floor system that does not require support and can quickly create an appropriate level of construction quality for unskilled workers.

In recent years, steel-framed skyscrapers have been newly built based on the rapidly developing technology.

Steel-frame buildings generally consist of pillars and beams, which are structural members of the building, made of steel, such as H-beams or I-beams, and include deck plates, pre-fabricated PC slabs, or half slabs (hereinafter referred to as 'deck plates'). Etc.) is mounted on the cheolgolbo and reinforced concrete construction as necessary to construct a beam and floor slab.

The conventional steel frame building is installed by horizontally joining a plurality of symmetrical H-beams or I-beams with the same width of the upper flange and the lower flange between the column and the pillar or between the cheolgolbo and cheolgolbo, the upper portion of the symmetrical H-beams or I-beams Install the deck plate on the flange.

As described above, the conventional steel frame structure has a deck plate or the like installed on the upper flange of the steel frame and a slab is formed. Therefore, since the cheolgolbo is exposed as it is under the floor slab, the height of the building increased, there was an uneconomical problem compared to the unit cost, such as the increase in the demand for exterior materials and the reduction of the volume ratio per unit area.

In order to solve the above problems, a slim floor method or a slim floor system has appeared.

The slim floor method is different from the conventional method of forming a slab by installing a deck plate or the like on the upper flange of the symmetrical H-shaped steel or I-shaped steel, asymmetric H-shaped steel or I-shaped steel (hereinafter, 'the wider width of the lower flange than the upper flange) Asymmetrical steel ball is used to mount a deck plate and the like on the lower flange using a method for constructing a slab.

That is, a method of lowering the height of a layer by embedding a portion of the asymmetrical cheolgolbo used as a beam into the slab without exposing it under the slab as it is.

1 is a perspective view showing an asymmetrical cheolgolbo for a conventional slim floor system having a leveler (leveler), Figures 2a to c is a perspective view showing asymmetrical cheolgolbo for a conventional slim floor system is already installed a cradle. 3 is a cross-sectional view briefly illustrating the asymmetrical cheolgolbo for the conventional slim floor system is installed leveler or cradle.

The leveler shown in FIG. 1 is for adjusting and maintaining the level of the slab required in the design or construction stage, and is generally manufactured and installed flexibly in the field with a C channel or a pipe as illustrated. . The deck plate is mounted on the leveler or lower flange, and then concrete is poured after formwork and reinforcement to form a slab.

Figures 2a to c is a perspective view showing asymmetric cheolgolbo for a variety of improved slim floor systems already disclosed or patented in the prior art. Although the name is different, the asymmetrical cheolgolbo is formed with a pedestal or cradle perpendicular to both ends of the lower flange. The pedestal serves to mount the deck plate, etc., and further serves as a formwork or tension member of the concrete to be placed on cheolgolbo. Therefore, it can be concluded that the asymmetric steel ball beams provided with the pedestal and the like have different manufacturing methods and names of members, but their functions and shapes are similar.

Accordingly, the asymmetrical steel ball beams for the slim floor system having the leveler shown in FIG. 1 or the pedestal shown in FIG. 2 are all largely shown in FIG. 3, such as the upper flange 12, the web 16, and the lower flange. 14 and the cradle 20 can be divided.

The conventional asymmetrical steel beams for levelers (leveler) or pedestal is installed when the deck plate or the like, a plurality of supports should be installed under the asymmetrical steel beams.

In general, when using H-beam as a horizontal member, when the load is applied, the overall deflection of the H-beam occurs, and when the bending moment exceeds the limit, the upper flange sags and twists. This is called transverse buckling or transverse torsional buckling (hereinafter referred to as buckling). Therefore, due to the buckling, the strength and rigidity of the member is drastically reduced and the stability of the building is also threatened.

In the steel frame construction of the symmetrical cheolgolbo using a conventional H-shaped steel plate is installed on the upper flange, such as deck plate can be seen the restraining effect on the buckling. Therefore, no support is necessary under the H-beams.

However, since the asymmetrical steel ball used in the slim floor system, the bottom plate of the deck plate is installed on a cradle such as a leveler or a pedestal connected to the lower flange rather than the upper flange, so it is vulnerable to buckling, so that the separate support is asymmetrical steel ball. It must be installed below to prevent buckling.

The present invention is proposed to solve the conventional problems as described above.

The purpose is to prevent buckling and damage caused by loads and moments by using reinforcement when installing the floor plate on the Asymmetric Steel Beam, which is commonly used as a structural material in the Slim Floor System. It is to provide an anti-buckling reinforcement structure for asymmetric steel beams and its construction method in an economical and structurally safe slim floor system that does not require and requires unskilled workers to quickly create an appropriate level of construction quality.

In order to solve the above technical problem, the present invention provides a slim floor system.

The lower flange 14 installed between the steel pillars or cheolgolbo is asymmetrical cheolgolbo 10 for a number of conventional slim floor system wider than the upper flange 12; A pair of cradles 20 joined vertically to both side ends of the lower flange 14 of the asymmetric steel ball 10 and bent at an upper end thereof; Bottom plates 40 such as a plurality of deck plates (half slab), such as a deck plate (half slab) is mounted on both ends of the cradle 20; And a plurality of stiffeners 30 joined and installed between the upper flange 12 of the asymmetrical cheolgolbo 10 and the bent top of the cradle 20; and asymmetrical in the slim floor system, comprising a Provides a buckling prevention reinforcement structure for the cheolgolbo and its construction method.

In addition, the reinforcing material 30 is joined between one end of the upper flange 12 of the asymmetrical cheolgolbo 10 and the top of the cradle 20 in the shape of a bar or plate (bar), or a bar (bar) ) Is bent in the shape of ∩ wrapped around the upper surface of the upper flange 12 of the asymmetrical cheolgolbo 10 and both ends are bonded and installed between the bent top of the cradle 20 Provides buckling prevention reinforcement structure and construction method for asymmetric steel golbo in slim floor system.

In addition, the reinforcing material 30 is installed in the shape of a plate (plate), the upper end is vertically bonded to the lower surface of the upper flange 12 of the asymmetrical cheolgolbo 10 and both ends of the web 16 and the cradle 20 Buckling for asymmetrical steel ball in a slim floor system, characterized in that it is vertically bonded to the inner surface of, or in addition to the bottom of the reinforcement 30 is further vertically bonded to the upper surface of the lower flange (14). Provides a preventive reinforcement structure and its construction method.

According to the present invention, the following effects are expected.

First, since the bottom plate and the asymmetrical cheolgolbo such as deck plate using the reinforcing material is integrated into the structure to provide a buckling prevention reinforcement structure for asymmetrical cheolgolbo in the buckling prevention system to provide a construction method.

Secondly, since the buckling of the entire asymmetric cheolgolbo is not induced, support is not necessary, and therefore, it provides an buckling preventing reinforcement structure and construction method for the asymmetric steel golbo in an economical and structurally safe slim floor system.

Third, the reinforcement can be installed freely at any stage, such as factory manufacturing or field installation of asymmetric steel beams, and unskilled workers can install the deck plate with the precision of the required quality. Provides a buckling prevention reinforcement structure and construction method for the asymmetric steel ball.

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

Figures 4a to e is a cross-sectional view and a perspective view of each embodiment of the anti-buckling reinforcement structure for asymmetrical cheolgolbo in the slim floor system of the present invention, Figures 5a to e is completed by applying the respective embodiments to finish the concrete It is a cross section.

In the slim floor system of the present invention, the buckling prevention reinforcement structure for the asymmetric steel frame beam is a slim floor system.

The lower flange 14 installed between the steel pillars or cheolgolbo is asymmetrical cheolgolbo 10 for a number of conventional slim floor system wider than the upper flange 12; A pair of cradles 20 joined vertically to both ends of the lower flange 14 of the asymmetrical cheolgolbo 10 and bent at an upper end thereof; Bottom plates 40 such as a plurality of deck plates (half slab), such as a deck plate (half slab) is mounted on both ends of the cradle 20; And a plurality of reinforcing members 30 bonded and installed between the upper flange 12 of the asymmetrical cheolgolbo 10 and the bent top of the cradle 20.

The asymmetric cheolgolbo 10 is commonly used in the slim floor system when installed between the steel column and the steel column and between the steel beam and the steel beam, respectively behaves as a large beam and small beam.

The cradle 20 is a concept including all of the above-described leveler 11 of FIG. 1 or various conventional technology plate pedestals of FIG. 2.

The reinforcing material 30 serves to prevent buckling because the bottom plate 40 and the upper flange 12 are restrained from each other to operate integrally after the bottom plate 40 such as a deck plate is mounted.

Therefore, unlike the conventional case in which support is required under the asymmetrical cheolgolbo, the buckling of the entire asymmetric cheolgolbo is not induced, so support is economical and structurally safe.

The reinforcing material 30,

As shown in Figure 4a and Figure 5a, as a bar (bar) shape, such as the reinforcement as a whole, it can be to be joined between one end of the upper flange 12 of the asymmetrical cheolgolbo 10 and the top of the cradle 20. 4B and 5B, in the shape of a plate using a piece of iron plate as a whole, between one end of the upper flange 12 of the asymmetric steel ball 10 and the upper end of the cradle 20. Can be bonded to

In addition, as shown in Figures 4c and 5c, the bar (bar) as a whole bent in the shape of ∩, bonded to surround the upper surface of the upper flange 12 of the asymmetric cheolgolbo 10 and both ends are Can be bonded to the top of the cradle 20,

As shown in Figure 4d and 5d, in the shape of a plate (plate) as a whole, the upper end is installed vertically bonded to the lower surface of the upper flange 12 of the asymmetrical cheolgolbo 10 and both ends of the web (16) And it may be to be vertically bonded to the inner surface of the cradle 20, and as shown in Figure 4e and 5e, the lower end of the reinforcing material 30 is further perpendicular to the upper surface of the lower flange 14 Can be bonded.

5 to 8 is a flow chart showing each embodiment of the construction method of the anti-buckling reinforcement structure for asymmetrical cheolgolbo in the slim floor system of the present invention.

A first embodiment shown in Figure 6 of the construction method of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system of the present invention is as follows.

In the slim floor system,

(A) a pre-production step of bonding the cradle 20 and the reinforcing material 30 to the asymmetrical cheolgolbo 10 for the slim floor system; (b) asymmetrical to install the asymmetrical steel ball 10 for a slim floor system in which the cradle 20 and the reinforcing material 30 are joined at predetermined intervals between the steel columns or steel beams during the construction of the structure of the steel frame building; Cheolgolbo installation step; And, (c) a bottom plate for mounting both ends between the pedestal 20 of the asymmetrical cheolgolbo 10 adjacent to the bottom plate 40, such as a plurality of deck plate (half slab) or half slab (half slab) Installation step; characterized in that comprises a. Unlike the other embodiment, the first embodiment is characterized in that the reinforcing material 30 is prefabricated in the factory, not on-site.

A second embodiment shown in Figure 7 of the construction method of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system of the present invention is as follows.

In the slim floor system,

(A) a pre-fabrication step of bonding the cradle 20 to a plurality of asymmetric cheolgolbo 10 for a slim floor system; (b) asymmetric steel golbo installation step of installing asymmetric steel golbo 10 for a slim floor system to which the cradle 20 is bonded between the steel pillars or golgolbo in the course of the frame construction of the steel frame building; (c) reinforcing material installation step of bonding the reinforcing material 30 between the upper flange 12 and the cradle 20 of the asymmetrical cheolgolbo 10; And, (d) a bottom for mounting both ends between the pedestal 20 of the asymmetric cheolgolbo 10 adjacent to the bottom plate 40, such as a plurality of deck plate (half slab) or a half slab (half slab) Plate installation step; characterized in that comprises a.

A third embodiment shown in Figure 8 of the construction method of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system of the present invention is as follows.

In the slim floor system,

(A) pre-production step of bonding the cradle 20 to the asymmetrical cheolgolbo 10 for the slim floor system; (b) asymmetric steel golbo installation step of installing asymmetric steel golbo 10 for a slim floor system to which the cradle 20 is bonded between the steel pillars or golgolbo in the course of the frame construction of the steel frame building; (c) a bottom plate mounting step of mounting both ends between the pedestals 20 of the asymmetrical cheolgolbo 10 adjacent to the bottom plate 40, such as a plurality of deck plates (half slab) or a half slab (half slab) ; And, (d) the upper flange 12 and the cradle of the asymmetrical cheolgolbo 10 so that the reinforcing material 30 does not overlap the bottom plate 40, such as deck plate or half slab (half slab) Characterized in that it comprises a; reinforcing material installation step to bond between (20).

As described above, the second and third embodiments of the construction method of the buckling prevention reinforcement structure for the asymmetric steel golbo beam in the slim floor system of the present invention, unlike the first embodiment, the reinforcing material 30 is asymmetric steel golbo (in advance) in the factory 10) is characterized in that it is installed in parallel with the installation work, such as steel frame work and deck plate in the field.

As such, the reinforcement material 30 can be freely installed at any stage, such as a factory production step or a site installation step of the asymmetric steel ball, and an unskilled worker can install a deck plate or the like with a certain quality of precision required. Has excellent workability and provides a buckling prevention reinforcement structure and construction method for asymmetric steel ball in a slim floor system.

Although the present invention has been described in connection with the preferred embodiment as mentioned above, various modifications and variations are possible without departing from the gist of the present invention, and can be used in various fields.

For example, it is possible to apply not only to asymmetric steel beams, but also to conventional symmetrical steel beams that form cradles that are often used in slim floor systems.

Therefore, the claims of the present invention include modifications and variations that fall within the true scope of the invention.

1 is a perspective view showing an asymmetrical cheolgolbo for a conventional slim floor system having a leveler (leveler) installed.

Figures 2a to c is a perspective view showing asymmetrical cheolgolbo for the published conventional slim floor system installed with a cradle.

Figure 3 is a simplified cross-sectional view showing a characteristic asymmetric cheolgolbo for the conventional slim floor system installed leveler (leveler) or cradle.

Figure 4a is a cross-sectional view and a perspective view of a first embodiment of the anti-buckling reinforcement structure for asymmetrical cheolgolbo in the slim floor system of the present invention.

Figure 4b is a cross-sectional view and a perspective view of a second embodiment of the anti-buckling reinforcement structure for asymmetrical cheolgolbo in the slim floor system of the present invention.

Figure 4c is a cross-sectional view and a perspective view of a third embodiment of the anti-buckling reinforcement structure for asymmetrical cheolgolbo in the slim floor system of the present invention.

Figure 4d is a sectional view and a perspective view of a fourth embodiment of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system of the present invention.

Figure 4e is a cross-sectional view and a perspective view of a fifth embodiment of the anti-buckling reinforcement structure for asymmetrical cheolgolbo in the slim floor system of the present invention.

Figure 5a is a cross-sectional view of the concrete finishing work by applying the first embodiment of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system of the present invention.

5b is a cross-sectional view of completing a concrete placing operation by applying a second embodiment of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system of the present invention.

Figure 5c is a cross-sectional view of the concrete finishing work by applying a third embodiment of the anti-buckling reinforcement structure for asymmetrical cheolgolbo in the slim floor system of the present invention.

5d is a cross-sectional view of completing a concrete placing operation by applying a fourth embodiment of the anti-buckling reinforcement structure for the asymmetric steel ball beam in the slim floor system of the present invention.

FIG. 5E is a cross-sectional view of completing a concrete placing operation by applying a fifth embodiment of a buckling preventing reinforcement structure for an asymmetric steel ball beam in the slim floor system of the present invention.

Figure 6 is a flow chart showing a first embodiment of the construction method of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system of the present invention.

Figure 7 is a flow chart showing a second embodiment of the construction method of the buckling prevention reinforcement structure for the asymmetrical cheolgolbo in the slim floor system of the present invention.

Figure 8 is a flow chart showing a third embodiment of the construction method of the anti-buckling reinforcement structure for the asymmetric cheolgolbo in the slim floor system of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: asymmetric steel ball

11: leveler

12: upper flange

14: lower flange

16: web

20: stand

30: Stiffener

Claims (8)

In the slim floor system, The lower flange 14 installed between the steel pillars or cheolgolbo is asymmetrical cheolgolbo 10 for a number of conventional slim floor system wider than the upper flange 12; A pair of cradles 20 joined vertically to both ends of the lower flange 14 of the asymmetrical cheolgolbo 10 and bent at an upper end thereof; Bottom plates 40 such as a plurality of deck plates (half slab), such as a deck plate (half slab) is mounted on both ends of the cradle 20; And, A plurality of reinforcing members 30 that are bonded and installed between the upper flange 12 of the asymmetrical cheolgolbo 10 and the bent top of the cradle 20; Buckling prevention reinforcement structure for asymmetrical cheolgolbo in the slim floor system, characterized in that comprises a. In claim 1, The reinforcement 30 is formed in the shape of a bar (bar) or plate (plate) as a whole, to be joined between one end of the upper flange 12 of the asymmetrical cheolgolbo 10 and the bent top of the cradle 20 is installed Anti-buckling reinforcement structure for asymmetric steel beams in slim floor system. In claim 1, The reinforcing material 30 is a bar (bar) as a whole bent in the shape of ∩, bonded while wrapping the upper surface of the upper flange 12 of the asymmetrical cheolgolbo 10 and both ends are bent of the cradle 20 Anti-buckling reinforcement structure for asymmetric steel golbo in a slim floor system, characterized in that the installation is bonded between the top. In claim 1, The reinforcing material 30 is a plate (plate) as a whole, the top is vertically bonded to the lower surface of the upper flange 12 of the asymmetrical cheolgolbo 10 is installed, both ends of the web 16 and the cradle 20 Buckling prevention reinforcement structure for asymmetrical cheolgolbo in the slim floor system, characterized in that installed vertically bonded to the inner surface of the. In claim 4, The lower end of the reinforcing material 30 is further vertically bonded to the upper surface of the lower flange 14 is installed in the slim floor system, characterized in that the buckling prevention reinforcement structure for asymmetric steel ball. In the slim floor system, (A) Pre-production step of joining the cradle 20 and the reinforcing material (30) of any one of claims 1 to 5 to the asymmetrical steel ball 10 for any one of claims 1 to 5 for the slim floor system. ; (b) asymmetrical to install the asymmetrical steel ball 10 for a slim floor system in which the cradle 20 and the reinforcing material 30 are joined at predetermined intervals between the steel columns or steel beams during the construction of the structure of the steel frame building; Cheolgolbo installation step; And, (c) the cradle 20 of the asymmetrical cheolgolbo 10 adjacent to the bottom plate 40, such as a deck plate or a half slab of any one of claims 1 to 5 A bottom plate installation step of mounting both ends therebetween; Construction method of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system characterized in that comprises a. In the slim floor system, (A) a pre-manufacturing step of joining the cradle 20 of any one of claims 1 to 5 to the asymmetrical cheolgolbo 10 for any one of claims 1 to 5; (b) asymmetric steel golbo installation step of installing asymmetric steel golbo 10 for a slim floor system to which the cradle 20 is bonded between the steel pillars or golgolbo in the course of the frame construction of the steel frame building; (c) reinforcing material installation step of bonding a plurality of reinforcing material 30 of any one of claims 1 to 5 between the upper flange 12 and the cradle 20 of the asymmetrical cheolgolbo 10; And, (d) the cradle 20 of the asymmetrical cheolgolbo 10 adjacent to the bottom plate 40, such as a deck plate or a half slab of any one of claims 1 to 5 A bottom plate installation step of mounting both ends therebetween; Construction method of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system characterized in that comprises a. In the slim floor system, (A) a pre-manufacturing step of joining the cradle 20 of any one of claims 1 to 5 to the asymmetrical cheolgolbo 10 for any one of claims 1 to 5; (b) asymmetric steel golbo installation step of installing asymmetric steel golbo 10 for a slim floor system to which the cradle 20 is bonded between the steel pillars or golgolbo in the course of the frame construction of the steel frame building; (c) the cradle 20 of the asymmetrical cheolgolbo 10 adjacent to the bottom plate 40, such as a deck plate or a half slab of any one of claims 1 to 5 A bottom plate installation step of mounting both ends therebetween; And, (d) The asymmetric steel ball so as not to overlap the plurality of reinforcement (30) of any one of claims 1 to 5 with the bottom plate 40, such as deck plate or half slab ( Reinforcing material installation step of bonding between the upper flange 12 and the cradle 20 of 10); Construction method of the anti-buckling reinforcement structure for the asymmetrical cheolgolbo in the slim floor system characterized in that comprises a.

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