KR101814754B1 - Built-Up Beam - Google Patents

Abstract

In the present invention, a transverse buckling compression reinforcement is formed on the upper part, and a high-strength die and a lattice material are connected to the lower part to increase the buckling strength with respect to the compressive force of the upper part, And a cross-section compression buckling is reinforced.
A preferred embodiment of the present invention relates to a transverse buckling compression reinforcement comprising a rectangular steel pipe or an elliptical steel pipe formed of a steel material; A high strength die of a plate shape having a predetermined length and width; A lattice material joined at both sides in the width direction of the transverse buckling compression reinforcement to connect the transverse buckling compression reinforcement and the high strength formwork tensile body; A branch bridge rod which is connected to one side or two sides of an upper portion of both sides in the longitudinal direction of the high-strength formwork so as to project at one end thereof from the longitudinal end of the high-strength formwork tensile body by a predetermined length, And a point shear reinforcement bridge including a point transverse bar formed in the width direction of the high strength formwork tensile member at the end portion and a point shear truss connected to connect the lower bridge surface of the point bridge rod and the lower surface of the high strength formwork tension member.

Description

Built-Up Beam with reinforced cross-section compression buckling

The present invention relates to a slim assembled beam reinforced by transverse section compression buckling, more particularly to a transverse buckling compression reinforcement at the top, a high strength die and a lattice material connecting the same, In the case of a slim assembly beam reinforced with cross - section compression buckling which can increase the buckling strength with respect to the compressive force of the upper element for the longitudinal moment and concretes simultaneously at the time of construction of the bottom plate slab, will be.

It is a structural member which supports the load by the bending and shearing. It is also called the bending material because the bending moment dominates the structural behavior. The stresses and deformations caused by the bending and shearing are mainly seen, but the torsion is accompanied if the working loads do not coincide with the shear center of the section. Therefore, sufficient bending strength and shear strength (or torsional strength) should be maintained, and as it is used as a horizontal member, usability for sagging should be ensured.

Particularly, as the section of the steel beam member, the H-shaped section is mainly used, and the box-shaped, I-shaped, and C-shaped sections are used, and a built-up beam manufactured by bonding is used. A box section may be used if the buckling length is very long. In particular, since the steel beam member generally supports the bottom plate on the section of the upper element, the height of the bottom plate and the height of the steel beam member It is an exposed structure that needs to be secured and it is difficult to reduce the thickness.

In addition, the existing beam member has a problem in that the cross section increases or the amount of steel used increases in order to increase the buckling strength with respect to the compressive force of the upper element corresponding to the longitudinal moment at the center portion generated in the construction step. There is a problem that the torsion resistance performance is deteriorated because the compression section of the upper element is small in relation to the horizontal force or the asymmetric load as well as the vertical load during construction.

As a background technique of the present invention, there is Korean Patent Registration No. 0626542 entitled " Composite Beam Structure Using Steel Sheet Formed Beams and Concrete "(Patent Document 1). (A) a bottom plate horizontally provided with a thin plate-like steel plate so as to form a lower surface of the beam; A pair of side vertical plates extending from both side ends of the bottom plate in the vertical direction and forming both side surfaces of the beam; A support wing extending horizontally from an upper end of the side vertical plate; A central vertical plate extending in a vertical direction at an upper center of the bottom plate and having a longer length than the length of the side vertical plates; And an upper flange extending horizontally from an upper end of the central vertical plate and formed in a 'T' shape with the central vertical plate. (b) a bottom plate unit provided on the upper part of the steel plate formed-by-support bobbin to form a slab structure; And (c) a beam-slab concrete integrally installed in the inside of the steel plate formed beam and the upper part of the bottom plate unit, wherein the steel plate molding is formed by continuously bending one steel plate member A side vertical plate is formed by upwardly bending one end of the bottom plate to horizontally bend the upper end of the side vertical plate to form a support wing and the other side of the bottom plate is bent upward to form a central vertical plate, Wherein a half steel plate formed by forming an upper flange by horizontally bending the upper end of the vertical plate is provided and a pair of the half steel plates are attached to each other so that the central vertical plates are interposed between the steel plate and the concrete. Composite beam structure '.

However, the background art also has a problem in that the cross section increases or the amount of steel used increases in order to increase the buckling strength with respect to the compressive force of the upper element corresponding to the longitudinal moment generated in the construction step.

Korea Patent No. 0626542 "Composite beam structure using steel plate formed beam and concrete"

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a transverse buckling compression reinforcement structure having a cross section specific to the compressive resistance of the upper element corresponding to the longitudinal moment generated in the construction step, (I, Z value), thereby improving the compressive force and buckling strength. Further, the improvement of the cross-sectional characteristics of the lattice material or the transverse buckling compression reinforcement at the side is effective not only for the vertical load during the construction but also for the horizontal force and asymmetric load It is possible to use the concrete at the same height as the bottom slab at the time of construction of the bottom slab and to expose a part of the bottom of the slab to the bottom of the slab The crossing that can realize the RC system in the slim beam type which can reduce the floor height that can be constructed It is an object of the present invention to provide a slim assembly beam with reinforced buckling on the surface.

The present invention relates to a transverse buckling compression reinforcement having a tubular shape formed of a steel material and having an empty interior; A high strength die of a plate shape having a predetermined length and width; A lattice material joined at both sides in the width direction of the transverse buckling compression reinforcement to connect the transverse buckling compression reinforcement and the high strength formwork tensile body; A branch bridge rod which is connected to one side or two sides of an upper portion of both sides in the longitudinal direction of the high-strength formwork so as to project at one end thereof from the longitudinal end of the high-strength formwork tensile body by a predetermined length, And a point shear reinforcement bridge formed by a point transverse bar formed in the width direction of the high-strength die in the end portion and a point shear truss joined to connect the lower bridge surface of the point bridge rod and the lower surface of the transverse buckling compression reinforcement body. It is intended to provide a slim assembly beam with reinforced buckling.

Also, the transverse buckling compression reinforcement body is filled with a filler made of high-strength mortar or concrete, and the present invention provides a slender assembly beam reinforced with cross-sectional compressive buckling.

In addition, the transverse buckling compression reinforcement is formed such that the upper surface thereof is cut to have a constant width.

In addition, a lateral compression strengthening member is further coupled to both lateral sides of the transverse buckling compression reinforcement member in the longitudinal direction.

Also, one or more tensile reinforcement members are coupled to the upper surface of the high-strength die to provide a slender assembly beam reinforced with cross-sectional compression buckling.

Also, it is desired to provide a slimly assembled beam reinforced by cross-sectional compression buckling, wherein the lattice reinforcement is coupled to the outer side surface of the lattice material at a predetermined height in the longitudinal direction.

The high tensile formwork tensile body is formed with side portions extending in the width direction at both ends in an upper direction and horizontal portions extending respectively inward in width direction or extending outward at the upper end portion of the side portion. .

In addition, in the upper part of the horizontal part, at least one gap bridge consisting of a horizontal plate and a lower plate extending downward from both ends in the width direction of the horizontal plate is formed so that the lower part of the side plate is coupled to the upper part of the horizontal part. And to provide a slim assembly beam with reinforced buckling.

In addition, the n-shaped bars bent into n-bars of the reinforcing bars are disposed at both sides of the high-strength formwork tensile body at regular intervals inwardly, and the shear members formed by joining the longitudinal roots to the both sides of the upper portions of the plurality of n- And a longitudinal section of the high tensile form tensile body is formed such that the lower end of the n-shaped section is joined to the upper part of the high strength formwork tensile body.

When the transverse buckling compression reinforcement is constructed on the upper part of the slim assembly, the cross-sectional compression buckling of the present invention is reinforced. (I, Z value), thereby improving the compressive force and the buckling strength. Further, the improvement of the sectional characteristics of the lattice material or the lateral buckling compression reinforcement at the side is not only a vertical load during construction, It is possible to use the concrete at the same height as that of the bottom plate slab at the same time when the bottom plate slab is constructed and to expose a part of the bottom surface of the bottom plate to the lower part of the slab It is very possible to implement the RC system in slim beam type which can reduce the construction height There is a usable effect.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a perspective view of a slim assembled beam reinforced with transverse compression buckling of the present invention.
2 is a side view of the above Fig.
3 is a cross-sectional view taken along line AA of FIG.
4 is a view showing various embodiments of the cross-section of a transverse buckling compression reinforcement according to the present invention.
FIGS. 5 to 7 are cross-sectional views illustrating various embodiments according to the present invention, in which the cross-sectional compression buckling is reinforced.
8 is a perspective view of FIG.
FIG. 9 is a perspective view showing an embodiment in which a shear stress net is added to a slim assembly beam reinforced by cross-sectional compressive buckling 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.

Hereinafter, the technical structure of the present invention will be described in detail with reference to the preferred embodiments.

FIG. 1 is a perspective view of a slim assembled beam reinforced by cross-sectional compression buckling according to the present invention, FIG. 2 is a side view of FIG. 1, and FIG. 3 is a sectional view taken along the line A-A of FIG.

1 to 3, the slim assembly beam 1 reinforced by the transverse section compression buckling according to the present invention comprises a transverse buckling compression reinforcement 10 at the upper portion, a high-strength die tensile body 20 at the lower portion, A lattice material 30 connecting the buckling compression reinforcement 10 and the high strength die 20 and a point shear reinforcement bridge 40 each formed at both ends in the longitudinal direction, So that the buckling strength with respect to the compressive force of the upper element is increased.

4 is a view showing various embodiments of the cross-section of the transverse buckling compression reinforcement according to the present invention.

1 and 2, the transverse buckling compression reinforcement 10 of the present invention is constructed in the longitudinal direction of the slim assembly beam 1 reinforced by the transverse section compression buckling, and the longitudinal momentum So as to increase the buckling strength with respect to the compressive force of the upper element.

The transverse buckling compression reinforcement 10 is made of a steel material and has a tubular shape with an empty interior. As shown in Fig. 4 (a), a rectangular steel pipe such as a square or a rectangle, The cross-sectional shape of the lateral buckling compression reinforcement 10 is formed such that its horizontal axis is about 1.5 times larger than the vertical axis with respect to the horizontal axis (cross-sectional width) and the vertical axis (cross-sectional height) Sectional secondary moment with respect to the horizontal axis is larger than the secondary moment of inertia with respect to the vertical axis.

The transverse buckling compression reinforcement 10 may be reinforced by filling a filler 16 made of high-strength mortar or concrete into the transverse buckling compression reinforcement 10, The transverse buckling compression reinforcement 10 may be formed such that the upper surface thereof is cut to have a constant width so as to facilitate filling of the filler 16 so that the U-shaped cross section is opened.

4 (a) and 4 (c), the rectangular buckling compression reinforcement 10 may be formed to have a rectangular square cross-section, as shown in FIG. 4 (d) It may be formed in a trapezoidal shape so as to be inclined.

This is also intended to increase the contact surface with the lattice material 30 coupled to the transverse buckling compression reinforcement 10.

FIGS. 5 to 7 are cross-sectional views illustrating various embodiments according to the present invention. FIG. 8 is a perspective view of FIG. 7. FIG.

As shown in FIG. 3, the high-strength formwork tensile member 20 may be formed of a plate-like high-strength steel having a predetermined length and width. When the high-strength formwork tensile member 20 is formed in the shape of a flat plate, It is easy to mount a known flat bottom plate such as a hollow floor plate, and the floor plate can be installed in the same manner as the dancing of the beam.

6 and 7, the high-strength formwork tensile member 20 has a side surface portion 21 extending in the width direction at both ends and an upper end portion of the side surface portion 21 in the width direction outside as shown in FIG. 6 The horizontal portion 22 may be extended or the horizontal portion 22 extending inwardly as shown in Figure 7 may be formed so that the deck plate or the PC floor Such as a plate or a hollow bottom plate, so that the bottom plate can be installed at a certain height of the dancing of the slim assembly beam 1. [

When the side surface portion 21 and the horizontal portion 22 are formed, a horizontal plate 81 and a side plate 82 extending downward from both ends of the horizontal plate 81 in the width direction are formed on the horizontal portion 22, So that the gap bridge 80 composed of the horizontal portion 22 and the lower portion of the side plate 82 can be coupled to the upper portion of the horizontal portion 22 as shown in FIG. The buckling length of the compression buckling can be stably maintained in the compressive force acting on the upper transverse buckling compression reinforcement 10 due to the bending moment even when the concrete is poured, It can serve as a supporting element and is effective in stabilizing the cross-sectional structure.

1 and 2, the lattice material 30 is welded to the transverse buckling compression reinforcement 10 at both sides in the width direction of the transverse buckling compression reinforcement 10 so as to connect the transverse buckling compression reinforcement 10 and the high- Are combined in various ways known in the art.

6 (a), 6 (b) and 6 (c), the lattice material 30 may be joined to the side surface of the transverse buckling compression reinforcement 10 by various methods known by welding or the like. And may be coupled to the lower surface of the transverse buckling compression reinforcement member 10 as shown in Fig. 6 (a), 6 (b), and 6 (c), the lattice material 30 may be coupled so as to be symmetrical with respect to the center in the width direction, .

The lattice material 30 is formed by using a round bar or an oblique muscle, and the shape of the lattice material 30 may be repeatedly formed so as to be inclined at a predetermined angle (typically 60 degrees) repeatedly, or a vertical and inclined shape such as a saw tooth shape may be repeatedly formed It is possible.

As shown in Fig. 6 (a), the side-by-side compression reinforcement member 50 is attached to both sides in the width direction of the lateral buckling compression reinforcement member 10 by a method such as welding So that the cross section of the transverse buckling compression reinforcement 10 can be reinforced. As shown in the figure, the lateral buckling compression reinforcement 10 may be coupled to both sides of the transverse buckling compression reinforcement 10 by welding or the like. Although not shown, when the lattice material 30 is coupled to the lateral side of the transverse buckling compression reinforcement 10 It may be connected to the outside of the lattice material 30 by welding or the like.

6 (b) and (d), one or more tensile reinforcing members 60 are coupled to the upper surface of the high-strength die 10 to reinforce the high-strength die 10 6 (b) and 6 (d), the lattice reinforcement 70 is coupled to the outer surface of the lattice material 30 at a predetermined height in the longitudinal direction, so that the height of the cross section of the slim assembly beam 1 is increased The lattice material 30 can be further reinforced without increasing the sectional area of the lattice muscle 30, thereby preventing compression buckling.

The side compression stiffening member 50, the tensile stiffening member 60 and the lattice stiffening reinforcement 70 may be made of various wires such as a reinforcing bar, a square bar, a round bar, and a pipe.

Since the slender assembly beam 1 of the present invention is provided with the point shear reinforcing bridges 40 at both ends in the longitudinal direction and is provided over the columns or the beam members at the end portions thereof, (Work load and self-weight of concrete and reinforcing steel), the bending moment becomes smaller and shear force increases toward the end portion, and the lattice material (30) at the fulcrum portion buckles against shear deformation or large compressive force So that a separate point shear reinforcement bridge 40 is formed at the fulcrum portion.

The point shear reinforcement bridge 40 is connected to the upper surface of both ends of the high-strength formwork tensile body 20 by a known method such as welding so that the point bridge rods 41 are respectively protruded from both ends of the high- Lt; / RTI >

The point bridge rods 41 are made of a wire rod such as a reinforcing bar, a square bar, and a round bar having a predetermined length, and may be joined in two rows as shown in the first row or as shown in Figs.

The point transverse bar 42 is formed at the outer end of the point bridge rod 41 in the width direction of the high strength die 20. The point transverse bar 42 may be formed of various materials such as a round bar, a square bar, a pipe, etc., and the point transverse bar 42 may be fixed to the column or the beam member when the end of the slim assembly beam 1 is mounted. .

In addition, the point front truss 43 is joined to the point bridge rods 41 in a zigzag fashion so as to connect the lower surface of the transverse buckling compression reinforcement 10 at a predetermined angle.

Since the installation length of the point shear reinforcement bridge 40 is set to be longer than the section that can sufficiently resist the shear force dominant influence zone but should be installed up to the influence section on the sine tension in the future, Fold.

FIG. 9 is a perspective view showing an embodiment in which a shear stressed net 90 is added to a slim assembly beam reinforced by cross-sectional compression buckling of the present invention.

As shown in FIG. 9, the shear stiffening net 90 may be formed on both sides of the lengthwise ends of the slim assembly beam 1 reinforced by the cross-sectional compression buckling of the present invention, It is possible to resist the sine field or the shear crack which may occur later in the concrete web of the end portion.

As shown in FIG. 9, the shear-struck strand 90 is formed by arranging n-shaped ropes 91 bent in n-folds of reinforcing bars at regular intervals inwardly in the longitudinal direction at both side ends of the high-strength formwork tensile body 20, and the lower ends of the n-shaped rods 92 are fastened to the upper portions of the high-strength workpiece pulling members 20 by simple fastening, welding And the like.

When the transverse buckling compression reinforcement of the present invention is constructed as a transverse buckling compression reinforcement at the upper part of the slender assembly reinforced with the transverse section compression buckling of the present invention, (I, Z value), thereby improving the compressive force and buckling strength. Further, the improvement of the cross-sectional characteristics of the lattice material or the lateral buckling compression reinforcement at the side is not only a vertical load during construction, And the bending strength of the section can be used without reduction by buckling. When the bottom plate slab is constructed, the concrete is simultaneously laid so that it is installed at the same height as the bottom plate slab, The RC system can be implemented in a slim beam type that can reduce the floor height that can be constructed to be exposed to There is a very useful effect.

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.

1: Slim assembly bolt reinforced with cross-section compression buckling
10: transverse buckling compression reinforcement
20: High tensile formwork tensile
21:
22:
30: Lattice material
40: Branch shear reinforcement bridge
41: Branch bridge rod
42: Point transverse
43: Branch shear truss
50: side compression reinforcing member
60: tensile reinforcement member
70: Lattice Rebar
80: Spacing bridge
90: Shearing Strap

Claims (9)

A transverse buckling compression reinforcement 10 formed of a steel material and having an inner hollow shape and filled with a filler 16 made of high strength mortar or concrete;
A high strength formwork tensor 20 having a predetermined length and width;
A lattice material 30 coupled to both sides of the transverse buckling compression reinforcement 10 in the width direction so as to connect the transverse buckling compression reinforcement 10 and the high strength die 10;
The wire rod having a predetermined length is connected to one of the upper and lower ends of the high-strength die 20 in the longitudinal direction so as to protrude from the longitudinal end of the high-strength die 20 by a predetermined length, A point bridge rod 41 and a point transverse bar 42 formed at the outer end of the point bridge rod 41 in the width direction of the high strength formwork tension member 20 and a point transverse bar 42 extending in the width direction of the point bridge rod 41 and the transverse buckling compression reinforcement And a point shear truss (43) coupled to connect the lower surface of the point shear reinforcement (10)
The n-shaped rods 91 bent in n-folds of the reinforcing bars are arranged inward at the respective side ends of the high-strength formwork tensor body 20, and are connected to both sides of the upper portions of the plurality of n-shaped roots 91 in the longitudinal direction The shear stern strand 90 formed by joining the longitudinal roots 92 is connected to the upper end of the high-strength workpiece tensile body 20 such that the longitudinal end portions of the high- Wherein the cross-sectional compression buckling is reinforced. delete The method according to claim 1,
Characterized in that the transverse buckling compression reinforcement (10) is formed such that its upper surface is cut to a constant width. The method according to claim 1,
Characterized in that lateral compression stiffening members (50) are additionally coupled to both lateral sides of the transverse buckling compression reinforcement (10) in the longitudinal direction. The method according to claim 1,
Characterized in that one or more tensile reinforcement members (60) are coupled to the upper surface of the high strength die (20). The method according to claim 1,
And a lattice reinforcing bar (70) is coupled to an outer side surface of a predetermined height of the lattice material (30) in the longitudinal direction. The method according to claim 1,
The high-strength formwork tensile member 20 includes a side portion 21 extending in the width direction at both ends thereof and a horizontal portion 22 or 22 extending inward in the width direction or extending outwardly from the upper end portion of the side portion 21 Wherein the cross-sectional compression buckling is reinforced. The method of claim 7,
A gap bridge 80 composed of a horizontal plate 81 and a side plate 82 extending downward from both end portions in the width direction of the horizontal plate 81 is provided on the upper portion of the horizontal portion 22, And the lower portion is coupled to an upper portion of the horizontal portions (22). delete

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