KR102810200B1 - Hybrid Beam Structure - Google Patents

Abstract

The present invention relates to a composite beam having an interior filled with concrete, and more specifically, to an asymmetric composite beam having an L-shaped folded reinforcing plate formed by folding a plate inside a U-shaped cross-section formed by a lower flange and a pair of side members, thereby forming a cross-section capable of reducing the floor height by reducing welding work and thereby increasing manufacturability, while lowering the manufacturing cost by forming the reinforcing plate by folding a thin plate.
A preferred embodiment of the present invention comprises: a lower flange in the shape of a plate; a vertical plate in the shape of a vertical plate; and a support plate that is bent and extended in a horizontal direction on one side from an upper end of the vertical plate, and a pair of side members configured such that the lower end of the vertical plate is joined to the lower flange so that the support plates face outward at both ends in the width direction of the lower flange; a bent reinforcing plate configured such that the vertical portion protrudes a certain height higher than the height of the vertical plate of the side member in the shape of a vertical plate, and the one-sided extension portion is bent and extended in one direction from the upper end of the vertical portion; and a plurality of balancing members configured such that the vertical plate and the vertical portion of the side member located in the other direction of the one-sided extension portion are connected, and the total weight of the balance members is the same as the weight of the one-sided extension portion of the bent reinforcing plate.

Description

Asymmetric composite beam {Hybrid Beam Structure}

The present invention relates to a composite beam having an interior filled with concrete, and more specifically, to an asymmetric composite beam having an L-shaped folded reinforcing plate formed by folding a plate inside a U-shaped cross-section formed by a lower flange and a pair of side members, thereby forming a cross-section capable of reducing the floor height by reducing welding work and thereby increasing manufacturability, while lowering the manufacturing cost by forming the reinforcing plate by folding a thin plate.

In conventional steel frame buildings, the overall story height increases because the floor plate is placed on top of the steel beam, but in the story height reduction method, the floor plate is inserted into the web of the steel beam and constructed, so the floor plate becomes thinner and the story height can be relatively reduced. The web-embedded composite beam method that enables story height reduction was first developed in Northern Europe for use in height restrictions on buildings and for extensions or renovations of existing buildings, and after being introduced to the UK, it has become an excellent floor system that has raised the competitiveness of steel frame buildings to the next level through research and development, and various cross-sectional shapes have been developed to date.

This method of reducing the height of a floor is very effective in reducing the height of a floor, but it has limitations in the span that can be constructed because the width of the composite beam is limited due to the limitations of the applicable floor slab system.

In the past, in order to reduce the floor height, a T-shaped section higher than the height of the U-shaped section was used inside the U-shaped section so that the floor plate was located within the beam, thereby reducing the floor height. However, in the case of the T-shaped section used in this case, since it was manufactured by welding a vertical plate to the support plate to have a T-shaped section, there was a problem of poor manufacturing efficiency due to welding problems, etc.

The background technology of the present invention is Patent Registration No. 0626542, "Composite beam structure using steel plate-formed beam and concrete" (Patent Document 1). The background technology comprises: (a) a bottom plate formed by horizontally installing thin steel plates to form the lower surface of the beam; a pair of side vertical plates formed to extend vertically from both ends of the bottom plate and form both side surfaces of the beam; a support wing part formed to extend horizontally from the upper end of the side vertical plates; a central vertical plate formed to be vertically erected from the upper center of the bottom plate and to have a length longer than the length of the side vertical plates; and an upper flange formed to extend horizontally from the upper end of the central vertical plate and to form a 'T' shape with the central vertical plate; (b) a floor plate unit formed to form a slab structure by having an end supported on the upper end of the composite beam support wing part; And, (c) a beam-slab concrete integrally poured on the inside of the composite beam and the upper part of the floor slab unit; a composite beam structure using a composite beam and concrete is proposed.

However, the above background technology was to weld the cross sections formed by a pair of vertical plates and an upper flange (18) extending from the upper end of the vertical plates so as to form a T-shaped cross section in the center of the beam, but this also had the problem that the welding work was very difficult and workability was low.

Patent registration No. 0626542 "Composite beam structure using composite beam and concrete"

The present invention is intended to solve the above problems, and the purpose of the present invention is to provide a composite beam that can reduce welding work while forming a cross-section for reducing the floor height, thereby increasing manufacturability and lowering the manufacturing cost.

The present invention provides an asymmetrical composite beam characterized by including: a lower flange in the shape of a plate; a vertical plate in the shape of a vertical plate; and a support plate that is bent and extended in the horizontal direction on one side from the upper end of the vertical plate, a pair of side members formed on both sides of the width direction of the lower flange so that the support plates face outward at both ends of the width direction of the lower flange, respectively; a bent reinforcing plate formed of a vertical portion that protrudes a certain height higher than the height of the vertical plate of the side member in the shape of a vertical plate and a one-sided extension portion that is bent and extended in one direction from the upper end of the vertical portion; and a plurality of balancing members formed in plurality so as to connect the vertical portion and the vertical plate of the side member located in the other direction of the one-sided extension portion, the total weight of which is the same as the weight of the one-sided extension portion of the bent reinforcing plate.

In addition, it is intended to provide an asymmetric composite beam characterized in that the balance member is formed of one of a plate of flat surface, an angle of L section, and a channel of T section.

In addition, it is intended to provide an asymmetric composite beam characterized in that one side extension of the bent reinforcing plate extends in a horizontal direction perpendicular to the vertical portion.

In addition, it is intended to provide an asymmetric composite beam characterized in that a spacing member is configured to connect a vertical portion and vertical plates on both sides at regular intervals in the longitudinal direction of a folded reinforcing plate.

In addition, it is intended to provide an asymmetric composite beam characterized in that a plurality of shear connecting members are formed so as to protrude from each side at a certain position from the upper part to the lower part of the vertical plate.

In addition, it is intended to provide an asymmetric composite beam characterized by having a lower flange and side members on both sides formed as one piece.

In addition, it is intended to provide an asymmetric composite beam characterized in that the lower flange and one side member are formed as one piece, and the other side member is manufactured as a separate member and then joined.

In addition, it is intended to provide an asymmetric composite beam characterized in that the lower flange and the side members on the other side are each made of individual members and are joined.

The asymmetric composite beam of the present invention has a very useful effect of forming a U-shaped cross-section by folding a plate inside a U-shaped cross-section formed by a lower flange and a pair of side members, thereby forming a cross-section capable of reducing the floor height by reducing welding work and increasing manufacturability, while also forming a reinforcing plate by folding a thin plate, thereby lowering the manufacturing cost.

The following drawings attached to this specification illustrate preferred embodiments of the present invention and, together with the detailed description of the invention, serve to further understand the technical idea of the present invention; therefore, the present invention should not be interpreted as being limited to the matters described in the attached drawings.
Figure 1 is a perspective view of the asymmetric composite beam of the present invention.
Figure 2 is a cross-sectional view of Figure 1.
FIG. 3 is a cross-sectional view illustrating various embodiments of the balance maintenance member of the present invention.
Figure 4 is a diagram illustrating another embodiment of Figure 2.
Figure 5 is a perspective view illustrating an embodiment in which a spacing maintaining member is configured in the present invention.

Below, the present invention is described in detail with reference to embodiments presented in the attached drawings, but the presented embodiments are exemplary for a clear understanding of the present invention and the present invention is not limited thereto.

The technical configuration of the present invention is described in detail according to the following preferred embodiments.

Fig. 1 is a perspective view of an asymmetric composite beam of the present invention, and Fig. 2 is a cross-sectional view of Fig. 1.

As shown in FIGS. 1 and 2, the asymmetric composite beam (1) of the present invention is configured to have a plate-shaped lower flange (10) and side members (20) having an L-shaped cross-section symmetrically formed on both ends in the width direction of the lower flange (10) to form a U-shaped cross-section, and a folded reinforcing plate (30) having an L-shaped cross-section is configured inside.

The lower flange (10) and the side members (20) on both sides are formed into a U-shaped cross section to facilitate filling of the interior with concrete.

As illustrated, the side member (20) is composed of a vertical plate (210) in the shape of a vertical plate and a support plate (220) that is bent and extended in a horizontal direction on one side from the upper end of the vertical plate (210), and is configured on both sides of the width direction of the lower flange (10) so that the support plates (220) face outward at each of the width direction ends of the lower flange (10).

At this time, as in Fig. 2b, the lower flange (10) and the side members (20) on both sides may be formed integrally by bending a single member, and as in Fig. 2c, the lower flange (10) and the side member (20) on one side may be formed integrally, and the side member (20) on the other side may be manufactured as a separate member and joined by a method such as welding.

In particular, when the width of the beam is large, as in Fig. 2a, the lower flange (10) and the side member (20) on the other side may be made of individual members and joined together.

The plate thicknesses of the lower flange (10) and the side members (20) on both sides may be configured to be the same, and as shown in Fig. 2a, the side members (20) may be formed by bending a thin plate thinner than the plate thickness of the lower flange (10).

In this way, a U-shaped cross-section formed by the lower flange (10) and side members (20) formed on both sides of the width direction of the lower flange (10) is formed inside a L-shaped cross-section folded reinforcing plate (30) so as to have an asymmetrical cross-section.

The folded reinforcing plate (30) is composed of a vertical portion (310) in the shape of a vertical plate and a one-sided extension portion (320) that is bent and extended in one direction from the upper portion of the vertical portion (310). The lower portion of the vertical portion (310) is welded to the width-wise central portion of the lower flange (10), so that the plate can be easily manufactured without welding work by folding the thin plate.

In addition, the one-side extension (320) of the bending reinforcing plate (30) may be extended diagonally from the vertical portion (310), and may also be extended in a right-angled horizontal direction, as illustrated. Such one-side extension (320) may be used as a working platform during construction, and its width is formed to be smaller than half of the width of the lower flange (10) to minimize interference when installing a deck or slab.

When configured in this manner, the one-sided extension (320) forms an asymmetrical cross-section formed only on one side of the cross-section of the composite beam (1), and at this time, by protruding a certain height higher than the height of the vertical plate (210) of the side member (20), the height of the vertical plate (210) of the side member (20) is positioned within the height of the vertical portion (310) so that a height difference exists, which allows a deck, slab, etc. to be placed on the support plate (220) above the vertical plate (210), and at this time, the deck, slab, etc. are positioned within the depth of the asymmetrical composite beam (1), so that the floor height can be reduced by the height located within the depth of the composite beam (1).

In particular, since the present invention has an asymmetrical cross-section, problems in installation such as twisting or tilting may occur during construction of the composite beam (1), so a plurality of balance-maintaining members (40) are configured to connect the vertical plate (210) and the vertical member (310) of the side member (20) located in the other direction of the one-sided extension (320).

At this time, the total weight of the plurality of balance members (40) is made to be the same as the weight of the one-sided extension (320) of the folded reinforcing plate (30), so that the weights on both sides are maintained equally at the center of the cross-section of the composite beam (1), thereby solving installation problems such as twisting or tilting, while also reinforcing the cross-section.

FIG. 3 is a cross-sectional view illustrating various embodiments of the balance maintenance member of the present invention.

In the case of such a balance maintenance member (40), since the total weight of the plurality of members only needs to be the same as the weight of one side extension (320) of the folded reinforcing plate (30), as shown in FIG. 3, it can be made of any one of a steel bar, a flat plate, an angle with a L section, and a channel with a T section.

Figure 4 is a diagram illustrating another embodiment of Figure 2.

In particular, as shown in Fig. 4, a plurality of shear connecting members (50) are formed to protrude from both sides at a certain position from the upper part to the lower part of the vertical plate (210), thereby reinforcing the folded reinforcing plate (30) made of a thin plate and at the same time acting as a shear connecting member for the concrete filled inside.

Such shear connecting member (50) can be made of various members such as studs, plates, angles, and channels.

Figure 5 is a perspective view illustrating an embodiment in which a spacing maintaining member is configured in the present invention.

As shown in Fig. 5, a plurality of spacing members (70) are configured to connect the vertical portion (310) and the vertical plates (210) on both sides at regular intervals in the length direction of the bending reinforcing plate (30), so that the spacing members (70) connect and restrain the vertical portion (310) and the vertical plates (210) on both sides during construction or after concrete pouring, thereby preventing the vertical plates (120) from spreading out and serving as spacing members while also serving as shear connectors during concrete pouring.

Such spacing maintenance members (70) may be placed at regular intervals, placed only in necessary areas, or placed at unequal intervals.

The asymmetric composite beam of the present invention as described above has an asymmetrical cross-section by forming a L-shaped folded reinforcing plate by folding a plate inside a U-shaped cross-section formed by a lower flange and a pair of side members, thereby forming a cross-section that enables reduction in floor height, thereby reducing welding work and increasing manufacturability, while also having the very useful effect of lowering the manufacturing cost by forming the reinforcing plate by folding a thin plate.

Although the present invention has been described in detail with reference to the presented embodiments, those skilled in the art will be able to make various modifications and variations without departing from the technical spirit of the present invention by referring to the presented embodiments. The present invention is not limited by such modifications and variations, but is only limited by the claims attached below.

1: Asymmetric composite beam
10 : Lower flange
20 : Side Absence
210 : Vertical plate
220 : Support plate
30: Folding reinforcement plate
310 : Vertical section
320 : One-sided extension
40: Absence of balance
50: Shear connection member
70: Absence of spacing maintenance

Claims (8)

A plate-shaped lower flange (10);
A vertical plate (210) in the shape of a vertical plate, and a support plate (220) that is bent and extended in a horizontal direction on one side from the upper end of the vertical plate (210), and a pair of side members (20) formed on both sides of the width direction of the lower flange (10) so that the support plates (220) face outward at each of the width direction ends of the lower flange (10);
A vertical portion (310) protruding a certain height higher than the height of the vertical plate (210) of the side member (20) in the shape of a vertical plate, and a one-sided extension portion (320) that is formed by being bent horizontally in one direction from the upper end of the vertical portion (310) and having a width smaller than half the width of the lower flange (10), the lower end of the vertical portion (310) being welded to the widthwise central portion of the lower flange (10), and a folded reinforcing plate (30);
An asymmetric composite beam characterized by comprising a plurality of balancing members (40) configured to connect a vertical plate (210) and a vertical member (310) of a side member (20) located in the other direction of a one-sided extension (320), and having a total weight equal to the weight of the one-sided extension (320) of the folded reinforcing plate (30). In claim 1,
An asymmetric composite beam characterized in that the balance member (40) is formed of one of a flat plate, an angle with a L section, and a channel with a T section. In claim 1,
An asymmetric composite beam characterized in that one side extension (320) of a bending reinforcing plate (30) extends in a horizontal direction at a right angle from a vertical portion (310). In claim 1,
An asymmetric composite beam characterized in that a spacing member (70) is configured to connect a vertical portion (310) and vertical plates (210) on both sides at regular intervals along the length of a bending reinforcing plate (30). In claim 1,
An asymmetric composite beam characterized in that a plurality of shear connecting members (50) are formed so as to protrude from each side at a certain position from the upper part to the lower part of a vertical plate (210). In claim 1,
An asymmetric composite beam characterized in that the lower flange (10) and the side members (20) on both sides are formed as one piece. In claim 1,
An asymmetric composite beam characterized in that the lower flange (10) and one side member (20) are formed as one piece and the other side member (20) is manufactured as a separate member and joined. In claim 1,
An asymmetric composite beam characterized in that the lower flange (10) and the side member (20) on the other side are each made of individual members and are joined.

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