KR200446592Y1 - Reinforced long steel beam for stiffness - Google Patents

Abstract

The object of the present invention is to provide a long span beam with reinforced cross section stiffness by fixedly attaching a reinforcement plate to the upper and lower flanges of the steel attached to the support.

According to the present invention as described above, it is possible to exclude the internal pillar in the space of the lower slab, there is an effect that can effectively utilize the space of the structure. In addition, the bending stiffness and the buckling resistance capacity of the beam is increased, the overall cross-sectional rigidity is increased, thereby structurally improving the durability of the beam, the long span of the beam, and the low solidification.

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Description

Jangji Ganbo with reinforced section stiffness {REINFORCED LONG STEEL BEAM FOR STIFFNESS}

The present invention relates to a long span beam reinforced with a cross-sectional stiffness capable of supporting the slab while excluding the inner pillar from the space under the slab and a construction method thereof.

A conventional self-propelled ground parking lot constructs an outer column (or an outer column) vertically in the ground and an H-type or I-type steel frame, and constructs an inner column, which is also an H-type or I-type steel frame, between the outer column. Next, two inner pillars are installed between the two pillars.

A short steel beam is provided between the outer column and the inner column (or inner column), and a long steel beam is provided between the two inner column.

The upper and lower spaces, which are usually divided by steel beams installed between the outer and inner supports, are used as parking spaces in which the driver parks the vehicle directly, and the upper and lower spaces, which are divided by steel beams installed between the inner and inner supports, It is used as a moving space for a driver to enter and leave a vehicle.

However, the inner circumference may not only be an obstacle for the driver, but also the parking space is limited because the inner circumference is installed, so that additional costs for constructing the inner circumference are added. there was.

The present invention is devised to solve the above problems, and more specifically, to provide a long-term beam reinforced with a cross-sectional rigidity by fixing the reinforcing plate fixed to the upper and lower flanges of the steel attached to the support. It is done.

Long-term beams reinforced with cross-sectional rigidity of the present invention for achieving the above object, in the long-term beams attached to the support (2) supporting the load of the structure, the upper and lower flanges (12, 14) and Among the steels 10 formed of the web 16, one end of the first steel (10a) is fixedly attached to the top or side of the support (2); A second steel material (10b) of the steel material 10, one end of which is in contact with the other end of the first steel material (10a); An upper coupling plate 20 integrally welded or bolted to each of the upper flanges 12 on the upper or lower surface of the upper flange 12 of each of the first and second steels 10a and 10b; Side coupling plates 30 which are integrally welded or bolted to the respective webs 16 at both sides of the webs 16 of the first and second steels 10a and 10b; A lower coupling plate 40 integrally welded or bolted to each of the lower flanges 14 on the upper or lower surface of each of the lower flanges 14 of the first and second steels 10a and 10b; The first reinforcing plate is formed smaller than the length of the first steel (10a), one end is positioned at one end of the first steel (10a), and is fixed while being inserted between the upper and lower flanges (12, 14) ( 50a); And is formed smaller than the length of the second steel (10b), one end is positioned apart from the one end of the second steel (10b) by a predetermined length, and fixed while being inserted between the upper and lower flanges (12, 14) It characterized in that it comprises a; the second reinforcing plate (50b).

Each of the first and second reinforcing plates 50a and 50b further includes an auxiliary reinforcing plate 52 fixedly attached to each of both side surfaces thereof.

The cross-sectional thickness of the first reinforcing plate (50a) is characterized in that it is formed larger than the cross-sectional thickness of the second reinforcing plate (50b).

One end is welded or bolted to the other end of the first reinforcing plate (50a); The other end further comprises a cover plate 60 for welding or bolting to one end of the second reinforcing plate 50b.

At least one or more of the first reinforcing plate (50a), the second reinforcing plate (50b) or the cover plate 60 is characterized in that it further forms a wire pipe hole.

According to the present invention as described above, it is possible to exclude the internal pillar in the space of the lower slab, there is an effect that can effectively utilize the space of the structure.

In addition, the bending stiffness and the buckling resistance capacity of the beam is increased, the overall cross-sectional rigidity is increased, thereby structurally improving the durability of the beam, the long span of the beam, and the low solidification.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

1 is an exploded perspective view of a long span beam reinforced with cross-section stiffness, an embodiment of the present invention, Figure 2 is a perspective view of a long span beam reinforced with cross-sectional rigidity, an embodiment of the present invention, Figure 3 Example is a front view of the long-term beams reinforced with the cross-sectional stiffness, Figure 4 is a side view of the long-term beams reinforced with the cross-sectional rigidity of an embodiment of the present invention, Figure 5 is a section of the cross-sectional rigidity reinforced one embodiment of the present invention It is a state diagram of use of the beam.

2 to 5, the present invention, in the long-term beams attached to the support (2) supporting the load of the structure, the steel formed of the upper and lower flanges (12, 14) and the web (16) Of the 10, one end of the first steel (10a) is fixedly attached to the top or side of the support (2); A second steel material (10b) of the steel material 10, one end of which is in contact with the other end of the first steel material (10a); An upper joining plate integrally welded or bolted to each of the upper flanges 12 on either or both of the upper and lower surfaces of the upper flange 12 of each of the first and second steels 10a and 10b. 20); Side coupling plates 30 which are integrally welded or bolted to the respective webs 16 at both sides of the webs 16 of the first and second steels 10a and 10b; A lower coupling plate integrally welded or bolted to each of the lower flanges 14 on one or both of the upper and lower surfaces of the lower flanges 14 of the first and second steels 10a and 10b ( 40); The first reinforcing plate is formed smaller than the length of the first steel (10a), one end is positioned at one end of the first steel (10a), and is fixed while being inserted between the upper and lower flanges (12, 14) ( 50a); And is formed smaller than the length of the second steel (10b), one end is positioned apart from the one end of the second steel (10b) by a predetermined length, and fixed while being inserted between the upper and lower flanges (12, 14) It characterized in that it comprises a; the second reinforcing plate (50b).

The present invention, as shown, may be constructed as described above to be constructed to support the slab in the ground parking lot.

The strut 2 may be mobilized with a conventional H beam, and various steels may be mobilized without being limited thereto.

The steel 10 may be provided with steel frames having an H- or I-shaped cross section, and the upper and lower flanges 12 and 14 and the web 16 may be provided.

The first steel (10a) may be attached to be fixed horizontally as shown in the support (2).

The second steel (10b) is preferably provided with the same size as the cross-sectional size of the first steel (10a), it is preferable to facilitate the coupling with the first steel (10a).

The width of the first upper coupling plate 20a of the upper coupling plate 20 is formed to correspond to the width of the upper surfaces of the first and second steels 10a and 10b, and the length of the upper coupling plate 20a is It is preferable that the second steel material 10b is provided to such an extent that it can sufficiently cover the contact portion. In this case, as illustrated, the first upper coupling plate 20a may be integrally coupled with the first and second steels 10a and 10b through a plurality of bolting or welding treatments.

In addition, the width of the first upper coupling plate 20b of the upper coupling plate 20 is formed to correspond to the distance from the web 16 to the free end of the upper flange 12, the length is the first It is preferable that the steel 10a and the second steel 10b are provided to such an extent that they can sufficiently cover the contact portion. In this case, as illustrated, the second upper coupling plate 20b may be integrally coupled with the first and second steels 10a and 10b through a plurality of bolting or welding treatments.

The width of the side coupling plate 30 is formed to correspond to the dance of the web 16, the length is provided to the extent enough to cover the contact portion between the first steel material (10a) and the second steel material (10b). Is preferred. In this case, as shown, the side coupling plate 30 may be integrally coupled with the first and second steels 10a and 10b through a plurality of bolting or welding treatments.

The width of the first lower coupling plate 40a of the lower coupling plate 40 is formed to correspond to the width of the upper surface of the lower flange 16, as shown. In addition, the length of the lower coupling plate 40 is preferably provided to the extent that the first steel (10a) and the second steel (10b) is sufficiently covered with the contact portion. In this case, as shown, the first lower coupling plate 40a may be integrally coupled with the first and second steels 10a and 10b through a plurality of bolting or welding treatments.

In addition, the width of the second lower coupling plate 40b of the lower coupling plate 40 is formed to correspond to the bottom width of the web 16, the length is the first steel (10a) and the second steel ( It is preferable to be provided to such an extent that 10b) can fully cover the part to contact. In this case, as shown, the second lower coupling plate 40b may be integrally coupled with the first and second steels 10a and 10b through a plurality of bolting or welding treatments.

At this time, the upper coupling plate 20, the side coupling plate 30 and the lower coupling plate 40 is formed of a steel, the contact portion of the first and second steel (10a, 10b) of the joint portion It is preferable to make rigidity fully exhibited.

The width of the first and second reinforcing plate (50a, 50b) is preferably formed to correspond to the dance of the web (16) to be in close contact between the upper and lower flanges (12, 14).

As such, while the first and second reinforcing plates 50a and 50b are inserted between the upper and lower flanges 12 and 14, cross-sectional stiffness of the first and second steels 10b may be further increased. There is an advantage.

That is, as the first and second reinforcing plates 50a and 50b are installed, when the load transmitted from the upper flange 12 is transferred to the lower flange 14, the first and second reinforcing plates ( Since 50a and 50b are provided in the longitudinal direction of the first and second steels 10a and 10b, the load is evenly distributed over the entire length of the lower flange 14 so that the cross-sectional rigidity of the steel 10 can be increased. There are advantages to it.

By distributing and distributing the load, it is possible to secure the strength and rigidity required by the cross-sectional area less than the cross-sectional reinforcement of the first and second steels 10a and 10b due to the concrete pouring, thereby enabling the efficient design of the steel. have.

In addition, the first and the second reinforcing plate (50a, 50b) exhibits a support force for the shear force dedicated to most of the web 16 to compensate for the structural strength of the shear force of the web 16 There is this.

In addition, since the first and second reinforcing plates (50a, 50b) are respectively installed on each side of each of the first and second steel (10a, 10b), to support the buckling of the web (16). There are advantages to it.

Each of the first and second reinforcing plates 50a and 50b may further include an auxiliary reinforcing plate 52 fixedly attached to each of both side surfaces thereof.

The auxiliary reinforcing plate 52 may be fixedly attached to both sides of each of the first and second reinforcing plates 50a and 50b to form a "-" shape.

When the first and second reinforcing plates 50a and 50b are formed in the “c” shape, the first steel material 10a or the second steel material 10b is twisted by the load. And buckling of the second reinforcing plates 50a and 50b.

Of course, the auxiliary reinforcing plate 52 is preferably made of a steel material such as the first and second reinforcing plate (50a, 50b).

The cross section thickness of the first reinforcing plate 50a may be greater than the cross section thickness of the second reinforcing plate 50b.

Since the shear force by the load acts at the portion where the support 2 and the first steel 10a are connected to each other, the thickness of the second reinforcing plate 50b is smaller than that of the first reinforcing plate 50a. It is preferable to form to correspond to the maximum shear force through the first reinforcing plate (50a). In addition, there is an advantage that can reduce the load of the present invention through this.

One end is welded or bolted to the other end of the first reinforcing plate (50a); The other end may further include a cover plate 60 for welding or bolting to one end of the second reinforcing plate 50b.

Width of the cover plate 60 is formed to correspond to the width of the first and second reinforcing plate (50a, 50b), the length of the other end of the first steel (10a) and the second steel (10b) of It is preferable to cover the distance away from one end and to form both ends of the cover plate 60 to be sufficiently combined with the first and second reinforcing plates 50a and 50b.

As shown, the cover plate 60 may be integrally coupled with the first and second reinforcing plates 50a and 50b through a plurality of bolting or welding processes.

At least one or more of the first reinforcing plate 50a, the second reinforcing plate 50b, or the cover plate 60 may further form a wire piping hole.

The wire piping hole may be formed to facilitate the introduction and withdrawal of the wires disposed in the first and second steels 10a and 10b.

The present invention has been described for the preferred embodiment as described above, but is not limited to the above embodiment, it should be interpreted by the appended utility model claims. In addition, it is a matter of course that various modifications and variations can be made by those of ordinary skill in the art within the equivalent scope of the technical concept of the present invention and the appended utility model claims.

1 is an exploded perspective view of a long span beam reinforced with cross-sectional stiffness of one embodiment of the present invention.

Figure 2 is a perspective view of a long span beam reinforced section stiffness which is an embodiment of the present invention.

3 is a front view of the long-term beams reinforced with the cross-sectional rigidity of one embodiment of the present invention.

Figure 4 is a side view of the long span beam reinforced with the cross-sectional rigidity of one embodiment of the present invention.

5 is a state diagram of the use of the long-term beams reinforced with the cross-sectional rigidity of one embodiment of the present invention.

<Brief description of symbols for the main parts of the drawings>

2: prop 10: steel

10a: first steel 10b: second steel

20: upper coupling plate 30: side coupling plate

40: lower coupling plate 50a, 50b: first and second reinforcing plate

60: cover plate

Claims (5)

In the long-term beam attached to the support (2) supporting the load of the structure, A first steel (10a) of which one end is fixedly attached to the upper or side surface of the support (2), among steels (10) formed of upper and lower flanges (12, 14) and web (16); A second steel material (10b) of the steel material 10, one end of which is in contact with the other end of the first steel material (10a); An upper joining plate integrally welded or bolted to each of the upper flanges 12 on either or both of the upper and lower surfaces of the upper flange 12 of each of the first and second steels 10a and 10b. 20); Side coupling plates 30 welded or bolted integrally with each of the webs 16 at both sides of the webs 16 of the first and second steels 10a and 10b, respectively; A lower coupling plate integrally welded or bolted to each of the lower flanges 14 on either or both of the upper and lower surfaces of the lower flanges 14 of the first and second steels 10a and 10b, respectively. 40; The first reinforcing plate is formed smaller than the length of the first steel (10a), one end is positioned at one end of the first steel (10a), and is fixed while being inserted between the upper and lower flanges (12, 14) ( 50a); And It is formed smaller than the length of the second steel (10b), one end is positioned apart from the one end of the second steel (10b) by a predetermined length, while being fixed while being inserted between the upper and lower flanges (12, 14) It includes; the second reinforcing plate (50b), One end is welded or bolted to the other end of the first reinforcing plate (50a); The other end is further provided with a cover plate 60 for welding or bolting to one end of the second reinforcing plate (50b), Jangji Ganbo reinforced with cross-sectional rigidity. The method of claim 1, Each of the first and second reinforcing plates (50a, 50b), Jangji ganbo reinforced with cross-sectional rigidity, characterized in that it further comprises a secondary reinforcing plate 52 is fixedly attached to each side. The method of claim 1, The cross-sectional thickness of the first reinforcing plate (50a) is longer than the cross-sectional thickness of the second reinforcing plate (50b) is characterized in that the janggi ganbo reinforced reinforced section. delete The method of claim 1, At least one or more of the first reinforcing plate (50a), the second reinforcing plate (50b) or the cover plate (60) further comprises a wire pipe hole, characterized in that the stiffness of the cross section is reinforced.

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