KR20230144439A - Reinforcement apparatus for steel beams - Google Patents

Abstract

The present invention transfers the load applied to all the bolts and coupling plates connecting the connecting beam and the long-span beam directly to the column, allowing the column, which is the most stable and sturdy structure, to handle a large portion of the moment of the long-span beam, thereby almost all The load applied to the long-span beam can be distributed to the columns, making it possible to use smaller H-beams or I-beams than the existing long-span beams. This makes it possible to support the building more stably and solidly while reducing construction costs. By using H-beams or I-beams that are smaller than before, the ceiling height can be increased, ultimately increasing the floor height of the building.
In particular, the present invention is a very useful invention for the technology of preventing the long beam from sagging due to the load that increases after installing the concrete slab on the steel structure.

Description

Steel structure to reinforce the connection between the connecting beam and the long span beam {REINFORCEMENT APPARATUS FOR STEEL BEAMS}

The present invention relates to a steel structure for reinforcing the connection between a connecting beam and a long-spanning beam. More specifically, in a conventional steel structure, only the bolts and coupling plates connecting the connecting beam and the long-spanning beam directly carry the applied load. This relates to a steel structure to support long-span beams in a stable and sturdy state and prevent sagging by delivering them to the pillars and dispersing them.

In general, for structures such as self-propelled ground parking lots, factories, and large logistics warehouses, steel structures to support the load of the building are constructed by vertically constructing steel frames, mainly H-beams or I-beams, on the ground to form pillars, and H beams are also placed between adjacent pillars. Long span beams made of beam or I-beam steel frames are installed horizontally.

At this time, the H-beam and I-beam have a structure in which the upper flange formed at the top and the lower flange formed at the bottom are integrated with the vertical web at the center.

Therefore, it is not easy to directly connect the end of a long beam made of H-beam or I-beam to the side of the H-beam or I-beam column, so usually, as shown in Figure 1, the side of the column (1) is installed in advance at the factory. The connecting beam (2) for easy connection of the long-spanning beam (3) is manufactured by welding, and then the end of the long-spanning beam (3) is butted to the end of the connecting beam (2) at the site and the coupling plate (4) is made. The convenience of construction is promoted by fastening with bolts (B) and nuts (N).

However, in the case of these steel structures, they are designed based on the end portions of the columns and long-span beams where the load (moment) is most applied, so the size of the long-span beams becomes unnecessarily large, making it uneconomical, reducing construction costs, and increasing the floor height. It has inevitable disadvantages.

Figure 2 is a diagram illustrating the moments acting on the columns and long-span beams of a conventional steel structure. When a vertical load is applied in the direction of the arrow while the long-span beam is connected to the column, the long-span beams and columns bend as shown in the figure. A moment occurs.

In particular, the largest moment acts on the section (N) closest to the column among the long-span beams. The problem is that the weakest joint end of the long-span beams, that is, the end of the long-span beam connected to the connecting beam (2), is located in this area. The point is that it does.

In other words, this means that the self-load of the long-spanning beam and all finishing loads placed on it (including rebar, finishing mortar, access floor, ceiling, etc.) must be withstood by the connecting plates and bolts connecting the joint ends.

This not only creates a structurally very weak state, which poses a risk to the safety of the building, but also has the disadvantage of increasing construction costs because larger H-beams or I-beams than necessary must be used for long-span beams.

In particular, no technology has been developed to date to prevent long-span beams from sagging due to the ever-increasing load after installing a concrete slab on a steel structure.

[Prior art literature]

1. Republic of Korea Patent No. 10-2254052

2. Republic of Korea Patent No. 10-1926532

The purpose of the present invention is to transfer the load applied to all the bolts and coupling plates connecting the connecting beam and the long-span beam directly to the column so that the column, which is the most stable and sturdy structure, can handle a large portion of the moment of the long-span beam. By doing so, almost all of the load applied to the long-span beam can be distributed to the columns, making it possible to use smaller H-beams or I-beams than the existing long-span beams, which allows the building to be supported more stably and solidly. The goal is to reduce costs and increase floor height.

A steel structure for reinforcing the connection between a connecting beam and a long span beam according to an embodiment of the present invention to achieve the above-described object includes a connecting beam welded transversely to a column, and an end at the end of the connecting beam. In a steel structure consisting of a long-span beam that is coupled against the long-span beam, and a coupling plate and a fastener for combining the webs and flanges of the connecting beam and the long-span beam to connect the connection portion of the connecting beam and the long-spanning beam, wherein the coupling plate An upper coupling plate to be coupled to the upper flange of the connecting beam and the long-spanning beam, a pair of web coupling plates to be coupled to both sides of the web of the connecting beam and the long-spanning beam, and the lower flange of the connecting beam and the long-spanning beam. It consists of a lower coupling plate for coupling to the pillar, wherein the upper coupling plate is in close contact with one side of the pillar in the longitudinal direction of the pillar and has a plurality of through holes for fastening fasteners, and a lower part of the pillar coupling plate. An upper flange coupling plate that extends in one direction from the top and is in close contact with the upper flange of the connection beam and long span beam and has a plurality of through holes for joining the connecting beam and long span beam together by fasteners, and the column coupling plate. It consists of a reinforcing plate to prevent sagging of the upper flange coupling plate by being vertically installed and welded in the middle of the upper flange coupling plate, and the pair of web coupling plates are each positioned on one side of the pillar in the longitudinal direction of the pillar. The pillar coupling plate is in close contact with the right angle direction and has a plurality of holes for fastening the fastener. It extends in one direction from the side of the pillar coupling plate and is in close contact with the web of the connection between the connecting beam and the long span beam by the fastener. It is made of a web coupling plate with a plurality of holes for joining the connecting beam and the long span beam together, and the lower coupling plate is closely attached to one side of the pillar in the longitudinal direction of the pillar and has a plurality of through holes for fastening fasteners. A perforated column coupling plate and a plurality of through holes extend in one direction from the upper part of the column coupling plate and are in close contact with the lower flange of the connection between the connecting beam and the long-spanning beam to join the connecting beam and the long-spanning beam together by a fastener. It is characterized by being composed of a perforated lower flange coupling plate and a reinforcement plate to prevent sagging of the lower flange coupling plate by being vertically installed and welded in the middle of the column coupling plate and the lower flange coupling plate.

According to an embodiment of the present invention, a plurality of through holes are formed in the column coupling plate of the upper coupling plate and the reinforcing plate of the upper flange coupling plate, and a plurality of engaging members are passed through the holes so that the engaging members protrude on both sides of the reinforcing plate. By ensuring that the reinforcing plates and hanging members are buried and cured in the concrete slab poured on the connecting beam and long-spanning beam, the cured concrete slab holds the connecting beam and long-spanning beam to prevent sagging of the connecting beam and long-spanning beam. It is characterized by being configured to prevent it.

The effect of the present invention as described above is that the load applied to all the bolts and coupling plates connecting the connecting beam and the long-span beam is directly transmitted to the column, so that the column, which is the most stable and sturdy structure, absorbs a large portion of the moment of the long-span beam. By making it possible to handle almost all of the load that was applied to the long-span beam, it is possible to distribute it to the columns, allowing the use of smaller H-beams or I-beams than the existing long-span beams, which makes it possible to support the building more stably and solidly. This can reduce construction costs, and by using smaller H-beams or I-beams than before, the ceiling height can be increased, resulting in an increase in the floor height of the building.

In particular, after pouring concrete on a steel structure, a greater load is applied to the long span beam. The present invention allows the concrete slab to be cured with reinforcing plates and engaging members buried in it, so that after curing the concrete, the slab is reinforced with reinforcing plates and engaging members. It is a very useful invention that can prevent sagging of connecting beams and long span beams by holding them.

Figure 1 is an exploded perspective view showing a conventional steel structure.
Figure 2 is a diagram illustrating moments acting on columns and long-span beams of a conventional steel structure.
Figure 3 is an exploded perspective view showing a steel structure for reinforcing the connection between the connecting beam and the long span beam according to an embodiment of the present invention.
Figure 4 is a combined perspective view of Figure 1.
Figure 5 is a cross-sectional view of Figure 2.
Figure 6 is an exploded perspective view showing a steel structure according to another embodiment of the present invention.
Figure 7 is a combined perspective view of Figure 4.
Figure 8 is a reference diagram showing the state of use of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. The terminology used herein is only intended to refer to specific embodiments and is not intended to limit the invention. Also, as used herein, singular forms also include plural forms, unless phrases clearly indicate the contrary. As used in the specification, the meaning of "comprising" is to specify a specific characteristic, area, integer, step, operation, element and/or component, and to specify another specific property, area, integer, step, operation, element, component and/or group. It does not exclude the existence or addition of . Although not defined differently, all terms including technical and scientific terms used herein have the same meaning as those generally understood by those skilled in the art in the technical field to which the present invention pertains. Terms defined in commonly used dictionaries are further interpreted as having meanings consistent with the related technical literature and currently disclosed content, and are not interpreted as ideal or official meanings unless defined.

Embodiments of the present invention described with reference to the perspective view specifically represent ideal embodiments of the present invention. As a result, various variations in the illustrations, for example variations in manufacturing methods and/or specifications, are expected. Accordingly, the embodiments are not limited to the specific shape of the illustrated area and also include variations in shape due to manufacturing, for example. For example, areas shown or described as flat may generally have rough/rough and non-linear characteristics. Additionally, portions shown as having sharp angles may be rounded. Accordingly, the areas shown in the drawings are only approximate in nature, and their shapes are not intended to illustrate the exact shape of the areas, nor are they intended to narrow the scope of the present invention.

Hereinafter, preferred embodiments of a steel structure for reinforcing the connection between the connecting beam and the long span beam according to the present invention will be described in detail with reference to the attached drawings.

Figure 3 is an separated perspective view showing a steel structure for reinforcing the connection between the connecting beam and the long span beam according to an embodiment of the present invention, Figure 4 is a combined perspective view of Figure 1, Figure 5 is a cross-sectional view of Figure 2, and Figure 6 is an separated perspective view showing a steel structure according to another embodiment of the present invention, Figure 7 is a combined perspective view of Figure 4, and Figure 8 is a reference diagram for the state of use of the present invention.

First of all, it should be noted that in the drawings, identical components or parts are indicated by the same reference numerals whenever possible. Additionally, in describing the present invention, detailed descriptions of related well-known functions or configurations will be omitted in order to make the gist of the present invention unambiguous.

The steel structure for reinforcing the connection between the connecting beam and the long span beam according to an embodiment of the present invention includes a connecting beam 200 welded transversely to a column 100, and an end of the connecting beam 200. The long-span beam 300 is coupled with the ends facing each other, and the connecting beam 200 and the long-span beam 300 to connect the end of the connecting beam 200 and the long-span beam 300, that is, the connection portion (A). ) consists of coupling plates (400, 500, 600) and fasteners (700, 800) for combining the webs (210, 310) and flanges (220, 230, 320, 330).

Of course, the connecting beam 200 is manufactured in a pre-joined state at the factory so that the long span beam 300 can be easily connected to the pillar 100 in the field.

The pillar 100 is usually erected vertically on the foundation of the building, and the long beam 300 is installed horizontally between the pillars 100 to support the floor or slab (C) of the building. However, the pillar 100 and the long span beam 300 usually use H beams or I beams.

The coupling plate includes an upper coupling plate 600 for being coupled to the upper flange 220,230 of the connecting beam 200 and the long-spanning beam 300, and a web 210,310 of the connecting beam 200 and the long-spanning beam 300. ) It consists of a pair of web coupling plates 500 to be coupled to both sides of the beam, and a lower coupling plate 400 to be coupled to the lower flanges 320 and 330 of the connecting beam 200 and the long span beam 300.

The upper coupling plate 600 is a pillar coupling plate 610 that is in close contact with one side of the pillar 100 in the longitudinal direction of the pillar 100 and has a plurality of through holes 611 for fastening the fasteners 700 and 800. And, it extends in one direction from the lower part of the column coupling plate 610 and is in close contact with the upper flange 220, 230 of the connection part A of the connecting beam 200 and the long span beam 300 by the fasteners 700 and 800. The upper flange coupling plate 620 with a plurality of through holes 621 for coupling the connecting beam 200 and the long span beam 300 together, the column coupling plate 610, and the upper flange coupling plate 620. It consists of a reinforcement plate 630 that is installed vertically in the middle and welded to prevent sagging of the upper flange coupling plate 620.

The pair of web coupling plates 500 are each in close contact with one side of the pillar 100 in a direction perpendicular to the longitudinal direction of the pillar 100 and have a plurality of through holes 511 for fastening the fasteners 700 and 800. The column coupling plate 510 extends in one direction from the side of the pillar coupling plate 510 and is fastened in close contact with the webs 210 and 310 of the connection portion A of the connecting beam 200 and the long span beam 300. It consists of a web coupling plate 520 in which a plurality of through holes 521 are perforated to couple the connecting beam 200 and the long span beam 300 together by the spheres 700 and 800.

The lower coupling plate 400 is a pillar coupling plate 410 that is in close contact with one side of the pillar 100 in the longitudinal direction of the pillar 100 and has a plurality of through holes 411 for fastening the fasteners 700 and 800. And, it extends in one direction from the top of the column coupling plate 410 and is in close contact with the lower flange 320, 330 of the connection part A of the connecting beam 200 and the long span beam 300 by the fasteners 700 and 800. It consists of a lower flange coupling plate 420 in which a plurality of through holes 421 are perforated to couple the connecting beam 200 and the long span beam 300 together.

In addition, as shown in FIGS. 6 to 8, the present invention forms a plurality of through holes 631 in the reinforcement plate 630 of the upper coupling plate 600 and inserts a plurality of holding members 632 through the through holes 631. So that the locking members 632 protrude on both sides of the reinforcing plate 630, and the reinforcing plate 630 and the locking member ( 632) can also be buried and cured.

Therefore, the hanging member 632 in the cured concrete slab (C) holds the connecting beam 200 and the long spanning beam 300, thereby preventing the connecting beam 200 and the long spanning beam 300 from sagging. .

Of course, it goes without saying that the reinforcement plate can also be formed on the web bonded plate 500.

The present invention also applies to the upper flanges (220,230), webs (210,310), and lower flanges (320,330) of the connecting beam (200) and the long span beam (300) for coupling the coupling plates (400, 500, 600) and the fasteners (700,800). It is natural that the through holes (211, 221, 231, 311, 321, 331) corresponding to the through holes (411, 421, 511, 521, 611, 621) of the coupling plates (400, 500, 600) must be drilled.

As described above, although the present invention has been described in terms of limited embodiments, the present invention is not limited thereto, and the technical idea of the present invention will be described below by a person skilled in the art to which the present invention pertains. Various modifications and variations are possible within the scope of equivalency of the patent claims.

100: pillar
200: Connecting beam
300: Jangjiganbo
400: Lower coupling plate
500: Web coupling plate
600: Upper coupling plate
700: bolt
800: Nut
A: Connection

Claims (1)

A connecting beam welded to the column in the transverse direction, a long span beam coupled to the end of the connecting beam, and a web and flange of the connecting beam and the long span beam to connect the connection portion of the connecting beam and the long span beam. In a steel structure consisting of a coupling plate and fasteners for combining them,
The coupling plate includes an upper coupling plate for coupling to the upper flange of the connecting beam and the long-spanning beam, a pair of web coupling plates for coupling to both sides of the web of the connecting beam and the long-spanning beam, and a connecting beam and the long-spanning beam. It consists of a lower coupling plate to be coupled to the lower flange of,
The upper coupling plate is in close contact with one side of the pillar in the longitudinal direction of the pillar and extends in one direction from the lower part of the pillar coupling plate and the pillar coupling plate with a plurality of through holes for fastening fasteners to connect the connecting beam and the pole. An upper flange coupling plate that is in close contact with the upper flange of the beam connection section and has a plurality of through holes drilled for joining the connecting beam and the long span beam together by a fastener, and is installed vertically in the middle of the column coupling plate and the upper flange coupling plate. It is made of a reinforcing plate that is installed and welded to prevent sagging of the upper flange connection plate,
The pair of web coupling plates are in close contact with one side of the pillar in a direction perpendicular to the longitudinal direction of the pillar, and have a plurality of holes for fastening fasteners, and a pillar coupling plate is formed in one direction from the side of the pillar coupling plate. It is made up of a web joint plate with a plurality of holes for connecting the connecting beam and the long-spanning beam together by a fastener, which extends in close contact with the web of the connecting beam and the long-spanning beam,
The lower coupling plate is in close contact with one side of the pillar in the longitudinal direction of the pillar and extends in one direction from the top of the pillar coupling plate and the pillar coupling plate with a plurality of through holes for fastening fasteners to connect the connecting beam and the pole. A lower flange coupling plate that is in close contact with the lower flange of the beam connection part and has a plurality of through holes drilled for joining the connecting beam and the long beam together by a fastener, and is installed vertically in the middle of the column coupling plate and the lower flange coupling plate. A steel structure for reinforcing the connection between the connecting beam and the long span beam, which is composed of a reinforcing plate to prevent sagging of the lower flange joint plate by being installed and welded.