KR20240036329A - Composite Beam - Google Patents

Abstract

The present invention relates to a tension-side cross-section reinforced composite beam. More specifically, the steel elements are minimized on the compression side of the structural member and are concentrated on the tension side to achieve an efficient cross-sectional arrangement, so that the inside is filled with concrete to reduce stress. This relates to a composite beam with cross-sectional reinforcement on the tension side that can have a cross-section that can effectively resist.
A preferred embodiment of the present invention includes a horizontal plate and a main reinforcing member formed in an inverted T shape, including a vertical plate formed perpendicular to the central portion of the horizontal plate in the width direction; It consists of a lower horizontal part in the shape of a horizontal plate, a vertical part extending vertically upward from one end of the lower horizontal part, and an upper horizontal part extending in the horizontal direction from the upper end of the vertical part to the other side, and the lower horizontal part is a horizontal plate on both sides of the vertical plate of the main stiffener. Z-beams are connected at the top with high-strength bolts so that the pair is symmetrical; It consists of a tie member configured at regular intervals in the longitudinal direction of the Z-beam to connect a pair of Z-beams.

Description

Tensile side cross-section reinforced composite beam {Composite Beam}

The present invention relates to a tension-side cross-section reinforced composite beam. More specifically, the steel elements are minimized on the compression side of the structural member and are concentrated on the tension side to achieve an efficient cross-sectional arrangement, so that the inside is filled with concrete to reduce stress. It relates to a composite beam with cross-sectional reinforcement on the tension side that can have a cross-section that can effectively resist.

Steel concrete composite beam is an efficient structural member that allows the steel beam and the reinforced concrete slab to behave as a single member, so that when receiving a bending moment, most of the compressive stress is borne by the concrete and the tensile stress is borne by the steel, reducing the beam's movement. It has the advantage of reducing the floor height of building structures, enabling long-span structures by increasing the resistance strength and resistance stiffness of the beam cross-section, and increasing ultimate performance and deformation performance.

Composite beams, like simple beams that receive a uniformly distributed load, have maximum tensile force at the bottom of the center and compressive force at the top. Since the compressive force at the top is shared by the concrete, considering H-beam steel as a standard, the minimum size of the upper flange is effective to maintain its shape. On the other hand, since the bottom of the central part receives a lot of tensile force, it is effective to increase the internal strength by making the overall cross section a tapered cross section or reinforcing the lower flange with a plate.

The technology behind the present invention includes Patent Registration No. 0851490, “Steel composite beam structure for floor height reduction” (Patent Document 1).

The background technology is that among I-type steel beams consisting of a web, an upper flange, and a lower flange, the width of the lower flange is manufactured to be larger than the upper flange, and the central portion of the web is placed at a certain distance from both the upper flange and the lower flange. A web hole is formed, an L-shaped support plate is installed at both ends of the lower flange extending along the longitudinal direction of the steel beam, and slab concrete is poured on a deck plate installed on the L-shaped support plate. Disclosed is a composite beam structure.

However, the composite beam structure proposed in the background technology had a problem in that the upper flange, the upper part of the web, and the concrete resisted the upper compressive force, so a lot of steel was used unnecessarily and the cross section was inefficient.

Patent Registration No. 0851490 “Steel composite beam structure to reduce floor height”

The present invention is intended to solve the above problems, by minimizing the elements arranged on the compression side of the structural member and concentrating them on the tension side to achieve an efficient cross-sectional arrangement, so that the interior can be filled with concrete to effectively resist stress. The purpose is to provide a composite beam with a cross section that can be used.

The present invention includes a main reinforcing member in an inverted T shape consisting of a horizontal plate and a vertical plate formed perpendicular to the center portion in the width direction of the horizontal plate; It consists of a lower horizontal part in the shape of a horizontal plate, a vertical part extending vertically upward from one end of the lower horizontal part, and an upper horizontal part extending in the horizontal direction from the upper end of the vertical part to the other horizontal direction, and the lower horizontal part is a horizontal plate on both sides of the vertical plate of the main stiffener. Z-beams are joined at the top with high-strength bolts so that the pair is symmetrical; The present invention seeks to provide a tension-side cross-sectional reinforced composite beam, characterized in that it consists of a tie member configured at regular intervals in the longitudinal direction of the Z-beam to connect a pair of Z-beams.

In addition, the aim is to provide a tension-side cross-section reinforced composite beam, wherein the tie member is made of any one of a plate, an angle, and a channel.

In addition, a pair of L-shaped shear connectors consisting of a horizontal reinforcement and a vertical reinforcement extending vertically upward from one end of the horizontal reinforcement are positioned so that the horizontal reinforcement is seated on the upper part of the lower horizontal part of the Z-beam and the vertical reinforcement is facing outward. Therefore, the object is to provide a tensile-side cross-sectional reinforced composite beam, characterized in that the horizontal plate, the lower horizontal portion, and the horizontal reinforcement portion are simultaneously coupled with high-tensile bolts.

In addition, it is intended to provide a tension-side cross-sectional reinforced composite beam, characterized in that a plurality of studs are formed on the upper horizontal portion of the Z-shaped steel.

In addition, a U-bar cage is composed of a pair of upper longitudinal bars that are arranged in parallel at a certain distance apart and an n-type reinforcing bar that is bent into an n-type and is seated and joined to a pair of upper longitudinal bars at regular intervals in the longitudinal direction of the upper longitudinal bars. An object is to provide a tension-side cross-sectional reinforced composite beam, characterized in that the upper longitudinal bar is positioned to protrude at a certain height above the upper horizontal part of the Z-shaped steel.

In addition, the n-type reinforcing bar of the U-bar cage is designed to provide a tension-side cross-sectional reinforced composite beam, characterized in that the lower end is bent outward to form a seating portion, and the seating portion is configured to be seated on the upper part of the lower horizontal part of the Z-shaped steel.

In addition, the column main reinforcement, which is made of a T shape and consists of a horizontal plate and a vertical plate formed as a vertical lower portion at the center of the horizontal plate in the width direction, is a length of a pair of Z-beams so that the lower surface of the horizontal plate is connected to the tie member. The purpose is to provide a tensile-side cross-sectional reinforced composite beam, which is characterized in that it is formed in the center of the width direction at a certain section inward from both ends of the direction.

The tension-side cross-section reinforced composite beam of the present invention minimizes the elements arranged on the compression side of the structural member and concentrates them on the tension side to ensure an efficient cross-section arrangement, so that the interior is filled with concrete to effectively resist stress. There is a very useful effect that can be had.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention along with the detailed description of the invention. Therefore, the present invention is limited to the matters described in the attached drawings. It should not be interpreted as limited.
Figure 1 is a perspective view of a tension-side cross-section reinforced composite beam of the present invention.
Figure 2 is a cross-sectional view of Figure 1.
3 to 5 are cross-sectional views showing various embodiments of the tension-side cross-section reinforced composite beam of the present invention.

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

Hereinafter, the technical configuration of the present invention will be described in detail according to preferred embodiments.

Figure 1 is a perspective view of the tension-side cross-section reinforced composite beam of the present invention, Figure 2 is a cross-sectional view of Fig. 1, and Figures 3 to 5 are cross-sectional views showing various embodiments of the tension-side cross-section reinforced composite beam of the present invention. .

As shown in Figures 1 and 2, the tension-side cross-section reinforced composite beam of the present invention includes a main reinforcing member 10 formed in an inverted T shape, and a Z-beam formed on both sides of the main reinforcing member 10 so that the pair is symmetrical. It consists of (20) and a tie member (30) configured to connect a pair of Z-beams (20).

In the present invention, the main reinforcement (10) is constructed at the lower part of the cross section of the composite beam, which receives a lot of tensile force, to reinforce the cross section. Since the compressive force at the top of the cross section of the composite beam is shared by concrete, the amount of unnecessary steel at the top of the cross section of the composite beam is reduced.

The main reinforcement 10 is made up of a horizontal plate 110 and a vertical plate 120 formed vertically in the center of the horizontal plate 110 in the width direction and has an inverted T shape, and is used by segmenting H-beam steel or using a separate The member may be welded and used. In this case, the main reinforcement (10) formed in the lower section of the composite beam of the present invention may be made of a member with the same thickness as the z-beam (20), but to increase the cross-sectional force, the z-beam (20) ) can also be used by cutting high-strength steel plates or thicker steel plates or H-beams.

The Z-beam 20 includes a horizontal plate-shaped lower horizontal portion 210, a vertical portion 220 extending vertically upward from one end of the lower horizontal portion 210, and a horizontal portion extending from the upper end of the vertical portion 220 to the other horizontal direction. It is made up of an extending upper horizontal portion 230 and has a z-shape.

The lower horizontal part 210 constitutes a joint surface for joining with the main reinforcement 10, and the vertical part 220 determines the dance of the composite beam, so it can be used as a beam of low dance as shown in Figures 2 and 3 or in Figure 4. And it can be configured at various heights as needed, such as a high dance beam as shown in Figure 5. Additionally, the upper horizontal portion 230 provides a mounting surface on which a truss deck, etc. are mounted.

In this Z-beam 20, the lower horizontal portion 210 is coupled to the upper part of the horizontal plate 110 on both sides of the vertical plate 120 of the main reinforcement 10 with high-tensile bolts 40 so that the pair is symmetrical. It is constructed so that concrete can be filled inside.

At this time, a plurality of studs 90 may be formed on the upper portion of the upper horizontal portion 230 of the Z-beam 20 to function as a shear connector with the concrete poured to form a slab on the upper portion.

The composite beam in the present invention is made up of a main reinforcement (10) and a Z-beam (20) formed on both sides of the main reinforcement (10) to allow concrete to be placed therein. At this time, the concrete pouring pressure or load during construction, etc. In order to prevent the pair of Z-beams 20 from spreading, tie members 30 are formed at regular intervals in the longitudinal direction of the Z-beams to connect the pair of Z-beams 20.

As such, the tie member 30 may be made of steel bars, reinforcing bars, etc., or may also be made of a flat plate, an angle with a cross-section, a channel with a cross-section, etc., and connects the vertical parts 220 or forms an upper part. The horizontal parts 230 can be connected.

As described above, a U-shaped cross section is formed with the main reinforcement 10 and a pair of Z-beams 20 so that the inside is filled with concrete. At this time, an L-type shear connector is used to increase the composite strength with the concrete filled inside. (50), such an L-shaped shear connector (50) serves as a shear connector with concrete and at the same time serves to reinforce the tension side of the lower section of the composite beam.

As shown, the L-shaped shear connector 50 consists of a horizontal reinforcement portion 510 and a vertical reinforcement portion 520 extending vertically upward from one end of the horizontal reinforcement portion 50 and has an L-shaped cross section. The horizontal reinforcing part 510 provides a joint surface and allows the horizontal plate 110, the lower horizontal part 210, and the horizontal reinforcing part 510 to be simultaneously coupled with high-tensile bolts 40 to form a three-layer tensile structure. This is to form a reinforcement part on the side.

In addition, the shear connector 50 is positioned so that each pair of horizontal reinforcement parts 510 is seated on the upper part of the lower horizontal part 210 of the Z-beam 20 and the vertical reinforcement parts 520 are facing outward, thereby providing vertical reinforcement. The portion 520 functions as a shear connector and at the same time serves to reinforce the horizontal reinforcement portion 510.

In particular, in the present invention, the U-bar cage 60 can be configured by a method such as simple mounting so that it protrudes to the top of the cross section of the composite beam to induce integration with the concrete inside the composite beam and the slab concrete at the top.

As shown, this U-bar cage 60 is bent in an n-shape with a pair of upper longitudinal bars 610 arranged in parallel and spaced apart at a certain distance, and is bent at regular intervals in the longitudinal direction of the upper longitudinal bars 610. It consists of n-type reinforcing bars 620 that are seated and joined to a pair of upper longitudinal bars 610, and are manufactured in units of a certain length (preferably approximately 1 m in length) and installed continuously over the entire length of the composite beam or only in necessary parts. You can also have it installed.

When installing the U-bar cage 60, as shown in FIG. 5, the slab concrete 80 is positioned so that the upper longitudinal bar 610 protrudes at a certain height above the upper horizontal portion 230 of the Z-beam 20. ) can also be simply mounted on the reinforcing bar 810, and as shown in Figure 3, the lower end of the n-type reinforcing bar 620 of the U-bar cage 60 is bent outward to form a seating portion 621. The seating portion 621 may be configured to be seated on the upper portion of the lower horizontal portion 210 of the Z-beam 20.

In particular, composite beams can be used in the form of simple beams or in the form of continuous beams, and when used in the form of continuous beams, they need to appropriately resist negative moments that occur at the ends in contact with the column.

Therefore, in the present invention, as shown in FIG. 5, the main reinforcement of the pillar portion is made of a T shape and consists of a horizontal plate 710 and a vertical plate 720 formed vertically below the width direction central portion of the horizontal plate 710. (70) is formed in the center of the width direction at a certain section inward from both longitudinal ends in contact with the pillars of the pair of Z-beams 20 so that the lower surface of the horizontal plate 710 is joined to the tie member 30. , Ensure an efficient cross-sectional configuration. At this time, a plurality of studs 730 may be formed on the upper surface of the horizontal plate 710 to function as a shear connector with the concrete poured to form a slab at the top.

The tension-side cross-section reinforced composite beam of the present invention as described above minimizes the elements arranged on the compression side of the structural member and concentrates them on the tension side to ensure an efficient cross-sectional arrangement, so that the inside is filled with concrete to effectively resist stress. There is a very useful effect of having a cross-section that can be used.

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

10: main reinforcement
110: horizontal plate
120: vertical plate
20: Z-shaped steel
210: lower horizontal part
220: vertical part
230: upper horizontal part
30: tie member
40: fixing force bolt
50: L-type shear connector

Claims (7)

A main reinforcement member 10 formed in an inverted T shape, consisting of a horizontal plate 110 and a vertical plate 120 formed perpendicular to the center portion in the width direction of the horizontal plate 110;
A horizontal plate-shaped lower horizontal portion 210 and a vertical portion 220 extending vertically upward from one end of the lower horizontal portion 210, and an upper horizontal portion extending from the upper end of the vertical portion 220 in the other horizontal direction ( 230), wherein the lower horizontal portion 210 is joined on both sides of the vertical plate 120 of the main reinforcement 10 with high-tensile bolts 40 at the top of the horizontal plate 110, so that the pair is symmetrical. Z Section steel (20) and;
A tension-side cross-sectional reinforced composite beam, characterized in that it consists of a tie member (30) configured at regular intervals in the longitudinal direction of the Z-beam to connect a pair of Z-beams (20). In claim 1,
The tie member 30 is a tension-side cross-section reinforced composite beam, characterized in that it is made of any one of a plate, an angle, and a channel. In claim 1,
An L-shaped shear connector 50 consisting of a horizontal reinforcement 510 and a vertical reinforcement 520 extending vertically upward from one end of the horizontal reinforcement 50,
Each pair of horizontal reinforcement parts 510 is seated on the upper part of the lower horizontal part 210 of the Z-beam 20 and the vertical reinforcement parts 520 are positioned so as to face outward,
A tensile-side cross-section reinforced composite beam, characterized in that the horizontal plate 110, the lower horizontal portion 210, and the horizontal reinforcement portion 510 are simultaneously coupled with high-tensile bolts (40). In claim 1,
A tensile-side cross-section reinforced composite beam, characterized in that a plurality of studs (90) are formed on the upper part of the upper horizontal portion (230) of the Z-beam (20). In claim 1,
A pair of upper longitudinal muscles 610 arranged in parallel and spaced apart at a certain distance,
A U-bar cage 60 made of n-type reinforcement bars 620 that are bent into an n-type and seated and joined to a pair of upper long bars 610 at regular intervals in the longitudinal direction of the upper long bars 610,
A tension-side cross-section reinforced composite beam, characterized in that the upper longitudinal bar 610 is positioned to protrude at a certain height above the upper horizontal portion 230 of the Z-beam 20. In claim 5,
The lower end of the n-type reinforcing bar 620 of the U-bar cage 60 is bent outward to form a seating portion 621 so that the seating portion 621 is seated on the upper part of the lower horizontal portion 210 of the Z-shaped steel 20. A tensile-side cross-section reinforced composite beam, characterized in that it consists of: In claim 1,
The pillar main reinforcement 70 is formed in a T shape and consists of a horizontal plate 710 and a vertical plate 720 formed vertically at the center portion in the width direction of the horizontal plate 710,
A tensile-side cross-sectional reinforcement type, characterized in that the lower surface of the horizontal plate 710 is formed in the widthwise central portion at a certain section inward from both longitudinal ends of a pair of Z-beams 20 so that the lower surface of the horizontal plate 710 is joined to the tie member 30. Composite beam.

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