KR20200097397A - Stress dispersion type structure - Google Patents

Abstract

Disclosed is a stress dispersion type structure. The stress dispersion type structure of the present invention includes: a slab extended in a horizontal direction and forming a plate-shaped structure; a column part positioned in a lower side of the slab and extended in a vertical direction; an original beam positioned between the slab and the column part and extended in the horizontal direction to support the slab; and a plate-shaped expanded reinforcement part positioned on an upper side of the original beam and supporting the slab with the original beam. Therefore, the stress dispersion type structure can disperse stress concentrated on a column supporting the slab to improve durability of the structure.

Description

Stress dispersive structure {STRESS DISPERSION TYPE STRUCTURE}

The present invention relates to a stress-dispersive structure, and more particularly, to a stress-dispersive structure capable of improving the durability of the structure by dispersing the stress concentrated in the column supporting the slab.

In general, in concrete structures, the force due to compression and tension is transmitted to the structure, and in principle, the bottom protects the top. Of these structures, the underground parking lot includes pillars, original beams, reinforcement beams and slabs.

Structures such as buildings and parking lots are constructed by subdividing the structure, and consists of foundations, columns, beams, slabs, and external finishes. If any of these subdivided structures are inadequate or do not function properly, this will reduce the durability of the building.

Looking at the structure of the building, the basement floor is determined by necessity for tall buildings, and foundation work is performed accordingly. After the foundation work, the pillars are installed, and the original beam, which is a reinforcing structure, is installed between the pillars and the pillars. The length of the original beam installed between the pillars is called the span, and a reinforcing beam connecting between the original beam and the original beam may be additionally installed.

On the upper side of the circular beam connected to the column, a slab is formed to make the floor surface of the upper floor. As you go upstairs, there is a possibility of column flow, and when an earthquake occurs, the column flows and the durability of the building decreases, so the column is the first important element of the building.

When the distance between the pillars is determined, reinforcing bars are erected, the pillars are constructed, and the original beams are installed between the pillars as a second priority. Since the distance between the pillars is determined, the length of the original beam is also determined, and both sides of the original beam are connected to the pillar and support the lower part of the slab.

Reinforcing beams are not thick, so install reinforcing beams at an appropriate distance to prevent the slab from bending.

If there is a crack in the beam or there is a lot of debris on the bottom of the slab, the durability of the building is deteriorated.If the reinforcing bar that forms the basis of the frame comes into contact with air through the gap in the cracked area, rust may occur on the rebar. It is very likely that it will not function.

When cracks are generated near the pillars, the slab itself weighs a lot because the span, which is the distance between the pillars, is long, or the object loaded on the upper side of the slab is heavy.

Conventionally, when supporting the lower part of the slab by using columns and beams, there is a problem in that the stress is not easily distributed and the durability of the structure is deteriorated due to concentration in any one place. Therefore, there is a need to improve this.

The background technology of the present invention is published in Korean Patent Application Publication No. 2018-0094671 (published on Aug. 24, 2018, title of invention: underground parking lot frame and underground parking lot frame assembly construction method).

The present invention was created to improve the above problems, and an object of the present invention is to provide a stress-dispersive structure capable of improving the durability of the structure by dispersing the stress concentrated on the pillar supporting the slab.

The stress-distributing structure according to the present invention includes: a slab extending in a horizontal direction and forming a plate-shaped structure, a column part located under the slab and extending in a vertical direction, and located between the slab and the column part, and in the horizontal direction. It is characterized in that it comprises a circular beam extending to support the slab and a plate-shaped enlarged reinforcing part located above the circular beam and supporting the slab together with the original beam.

In addition, the plurality of circular beams are characterized in that they intersect at the upper side of the column.

In addition, the original beam is characterized in that it includes a base portion that supports the lower portion of the enlarged reinforcing portion and is connected to the column portion, and a support portion that extends from the base portion and supports the lower portion of the slab.

In addition, the thickness of the support portion is characterized in that at least twice the thickness of the base portion.

In addition, the enlarged reinforcing part is located on the upper side of the base part, and the side surface is characterized in that it is a plate-shaped structure facing the end of the support part.

In addition, the present invention is installed in a shape crossing the original beam, characterized in that it further comprises a reinforcing beam for supporting the lower portion of the slab or the enlarged reinforcing portion.

In the stress-distributing structure according to the present invention, since an enlarged reinforcing part is additionally installed between the column and the slab, the stress concentrated in the column and the original can be dispersed, thereby improving the durability of the structure.

1 is an exploded perspective view schematically showing the structure of a stress-dispersive structure according to an embodiment of the present invention.
2 is a perspective view showing an original and a pillar according to an embodiment of the present invention.
3 is a plan view of a stress dispersive structure according to an embodiment of the present invention.
4 is a cross-sectional view of a stress-dispersive structure according to an embodiment of the present invention.
5 is a perspective view showing a state in which a reinforcing beam is connected to an enlarged reinforcing part according to an embodiment of the present invention.
6 is a perspective view showing an original beam, a reinforcing beam, and a column part according to an embodiment of the present invention.
7 is a plan view showing a state in which a reinforcing beam is connected to an enlarged reinforcing part according to an embodiment of the present invention.
8 is a plan view showing a state in which different types of reinforcing beams are connected to an enlarged reinforcing unit according to an embodiment of the present invention.
9 is a perspective view showing the structure of an enlarged reinforcing part according to an embodiment of the present invention.

Hereinafter, a stress-dispersive structure according to an embodiment of the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

1 is an exploded perspective view schematically showing the structure of a stress-distributing structure according to an embodiment of the present invention, FIG. 2 is a perspective view showing an original beam and a pillar according to an embodiment of the present invention, and FIG. A plan view of a stress-dispersive structure according to an embodiment of the present invention, FIG. 4 is a cross-sectional view of a stress-dispersive structure according to an embodiment of the present invention, and FIG. 5 is an enlarged reinforcement part according to an embodiment of the present invention. It is a perspective view showing a state in which the beams are connected, FIG. 6 is a perspective view showing an original beam, a reinforcing beam, and a column part according to an embodiment of the present invention, and FIG. 7 is a reinforcing beam connected to an enlarged reinforcing part according to an embodiment of the present invention. Fig. 8 is a plan view showing a state in which different types of reinforcement beams are connected to an enlarged reinforcement unit according to an embodiment of the present invention, and Fig. 9 is a structure of an enlarged reinforcement unit according to an embodiment of the present invention It is a perspective view showing.

1 to 4, the stress-distributing structure 1 according to an embodiment of the present invention includes a slab 10 extending in a horizontal direction and forming a plate-shaped structure, and the slab 10 The circular beam 30 and the circular beam located at the lower side of the column and extending in the vertical direction, and located between the slab 10 and the column part 20 and extending in the horizontal direction to support the slab 10 It is located on the upper side of (30) and characterized in that it comprises a plate-shaped enlarged reinforcement portion 40 for supporting the slab 10 together with the original (30).

The slab 10 is a structure that extends in a horizontal direction and forms a plate-shaped structure.

The pillar portion 20 is located under the slab 10 and extends in the vertical direction. Between the column part 20 and the slab 10, an enlarged reinforcing part 40, an original beam 30, and a reinforcing beam 50 are installed.

The original beam 30 is located between the slab 10 and the column part 20 and extends in the horizontal direction to support the slab 10. The original beam 30 connects the pillar portion 20 and the pillar portion 20 and supports the lower portion of the slab 10 together with the pillar portion 20.

In addition, the plurality of circular beams 30 are installed in a direction crossing in a cross shape from the upper side of the column part 20. The original 30 according to an embodiment supports the lower portion of the enlarged reinforcing portion 40 and extends from the base portion 32 and the base portion 32 connected to the column portion 20 to the lower portion of the slab 10 It includes a support portion 34 for supporting.

The base portion 32 supports the lower portion of the enlarged reinforcing portion 40 and is connected to the column portion 20. This base portion 32 crosses in various shapes including a cross or "ㅗ" on the upper side of the column portion 20.

The support part 34 is connected to the base part 32 and an end of the support part 34 faces the side surface of the enlarged reinforcing part 40. In addition, the thickness of the support portion 34 is characterized in that more than twice the thickness of the base portion 32. Since the thickness of the support part 34 in the vertical direction is greater than the thickness of the base part 32 in the vertical direction, the support part 34 together with the enlarged reinforcing part 40 can stably support the lower part of the slab 10.

The enlarged reinforcing part 40 is located on the upper side of the original beam 30 and is a plate-shaped structure supporting the slab 10 together with the original beam 30. The enlarged reinforcing part 40 according to an embodiment is located on the upper side of the base part 32, and the side surface is a plate-shaped structure facing the end of the support part 34.

The load transmitted to the lower side through the slab 10 is concentrated on the circular beam 30 close to the column part 20, and the stress is not properly distributed, so that the circular beam 30 close to the column part 20 or the column part 20 ), etc. Therefore, by installing the enlarged reinforcing section 40 in the region including the circular beam 30 and the reinforcing beam 50 close to the pillar section 20, including the pillar section 20, to facilitate stress distribution. This prevents the structure from cracking.

The installation of the enlarged reinforcing part 40 does not change the cross-sectional area of the column part 20. The enlarged reinforcing part 40 is installed above the middle of the circular beam 30 in connection with the circular beam 30 located on the upper side of the column part 20.

When explaining the relationship between the enlarged reinforcement part 40 and the original 30, the base part 32, which is the lower part of the original 30, supports the enlarged reinforcement part 40, and the large area of the enlarged reinforcement part 40 Since these beams are tensioned, they complement each other's structural rigidity.

That is, the circular beam 30 installed in the horizontal direction is installed on the upper side of the column part 20 erected in the vertical direction, and the enlarged reinforcing part 40 is installed on the upper side of the base part 32 of the circular beam 30. Therefore, the enlarged reinforcing part 40 and the original beam 30 support the lower part of the slab 10 together.

Therefore, even if an excessive stress is transmitted to the lower side through the slab 10, the stress is dispersed by the enlarged reinforcing portion 40 and the original beam 30 with an increased support area, and relatively little stress is transmitted to the column portion 20. The durability of the pillar portion 20 can be further improved.

In addition, the present invention is installed in a shape that crosses the original beam 30, as shown in FIGS. 5 to 7, and further includes a reinforcing beam 50 supporting the lower part of the slab 10 or the enlarged reinforcing part 40. Include. The reinforcing beam 50 is installed in the horizontal direction together with the original beam 30, and is installed vertically crossing the original beam 30 or is installed in parallel with the original beam 30, so that the enlarged reinforcing part 40 together with the original beam 30 Support.

In the case of additionally installing reinforcing beams 50 on both sides of the original beam 30, after dividing the span, which is the length of the original beam 30, into three, install the reinforcing beams 50 at the portions located on the pillars 20 respectively. do. Since the reinforcing beam 50 supports the lower portion of the enlarged reinforcing portion 40 together with the original beam 30, the stress is easily distributed through the enlarged reinforcing portion 40, the original beam 30, and the reinforcing beam 50. .

Looking at the relationship between the enlarged reinforcement part 40 and the original beam 30 and the reinforcement beam 50, the lower part of the original beam 30 and the reinforcement beam 50 supports the enlarged reinforcement part 40, and the enlarged reinforcement part ( 40) is a mutually complementary relationship because it tensions the lower portion of the original beam 30 and the reinforcing beam 50. Due to this structure, the area in which the original beam 30 protects the slab 10 is reduced, and the stress concentration is reduced by the installation of the enlarged reinforcing part 40 in the part where cracking occurs frequently. Therefore, the reinforcement of the pillar portion 20 can be made more reliably.

The reinforcing beam 50 is installed side by side on the left and right sides of the original beam 30, and supports the lower portion of the enlarged reinforcing part 40 together with the original beam 30.

The reinforcing beam 50 according to an embodiment supports the lower portion of the enlarged reinforcing portion 40 and extends from the support member 52 and the support member 52 connected to the original beam 30 to the lower part of the slab 10 It includes a support body 54 for supporting.

The support member 52 supports the lower portion of the enlarged reinforcing portion 40 and is connected to the original beam 30. The support body 54 is connected to the support member 52 and an end of the support body 54 faces the side surface of the enlarged reinforcing portion 40. In addition, the thickness of the support body 54 is characterized in that more than twice the thickness of the support member 52.

The structure of the circular beam 30 and the reinforcing portion are installed in the horizontal direction on the upper side of the pillar portion 20 of the present invention, and the circular beam 30 and the reinforcing portion support the enlarged reinforcing portion 40. Since the enlarged reinforcement part 40, the original beam 30, and the upper side of the reinforcement part form the same plane, the slab 10 can be simultaneously supported, and the stress distribution is also made.

As shown in FIG. 8, the shape of the reinforcing beam 60 connected to the original beam 30 can be variously modified. The reinforcement beam 60 may be transformed into various shapes according to the installation and design environment of the column portion 20 and the original beam 30. Since the reinforcing beam 60 shown in FIG. 8 supports the lower side of the enlarged reinforcing part 40 in a'ㅁ' shape, the lower side of the enlarged reinforcing part 40 can be more firmly supported, and the enlarged reinforcing part 40 ) It is possible to improve the durability of the structure by dispersing the stress transmitted more easily.

Meanwhile, as shown in FIG. 9, a separate core part 44 may be additionally installed inside the enlarged reinforcing part 40 of the present invention. The enlarged reinforcing portion 40 according to an embodiment includes a plate-shaped reinforcing body 42 having a set thickness and a core portion 44 installed inside the reinforcing body 42.

The core portion 44 includes a plate-shaped core plate 45 extending in the horizontal direction, a hollow portion 46 having a hole in the center of the core plate 45 facing the column portion 20, and a core plate. It includes a connecting hole 47 forming a plurality of holes in 45 and an extension piece 49 installed in a curved shape along the edge of the core plate 45.

The reinforcing bar of the column part 20 can be extended to the inside of the reinforcing body 42 through the hollow part 46, and the concrete on the upper side and the lower side of the reinforcing body 42 through the connection hole 47 are connected to each other. It can strengthen structural rigidity. In addition, the installation of the extension piece 49 may improve the lateral coupling force between the core portion 44 and the reinforcing body 42.

Hereinafter, the operating state of the stress-dispersive structure 1 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figs. 1 to 4, the stress transferred downward through the slab 10 is transferred to the enlarged reinforcing part 40 and the original beam 30, so that the stress is dispersed and then transferred to the column part 20. The stress transmitted to the pillar portion 20 and the circular beam 30 adjacent to the pillar portion 20 is reduced. Therefore, the durability of the structure including the pillar portion 20 and the original beam 30 is improved, and cracking of the structure can be prevented.

As shown in FIGS. 5 to 7, the stress transferred to the lower side through the slab 10 is transferred to the enlarged reinforcing portion 40, the original beam 30, and the reinforcing beam 50, so that the stress is dispersed, and then the column portion ( Since it is transmitted to 20), the stress transmitted to the column portion 20 and the circular beam 30 adjacent to the column portion 20 is reduced.

As the enlarged reinforcing part 40 and the reinforcing beam 50 are connected, the original beam 30 is tensioned, and the reinforcing beam 50 is close to the column part 20 and inherits the force of the enlarged reinforcing part 40 to the left and right slabs. It supports (10). Therefore, the original beam 30, the enlarged reinforcing part 40, and the reinforcing beam 50 are made of an integral type connected to each other to facilitate stress distribution, and the durability of the structure can be improved.

That is, since the original beam 30, the enlarged reinforcing part 40, the reinforcing beam 50, and the slab 10 are all formed at one time in a concrete pouring furnace, construction is easy, and stress distribution can be easily achieved.

As described above, according to the present invention, since the enlarged reinforcing part 40 is additionally installed between the pillar and the slab 10, it is possible to improve the durability of the structure by dispersing the stress concentrated on the pillar and the original beam 30. . In addition, an enlarged reinforcing part 40 and a reinforcing beam 50 are additionally installed to increase the area supporting the slab 10, and the original beam 30, the reinforcing beam 50 and the enlarged reinforcing part 40 are integrated. It is formed as a stress dispersion, so that the durability of the structure can be improved. In addition, since the enlarged reinforcing portion 40 supports a large area of the slab 10 and tensions the original beam 30 and the reinforcing beam 50, durability of the structure can be improved.

The present invention has been described with reference to the embodiments shown in the drawings, but these are only exemplary, and those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. will be. Therefore, the true technical protection scope of the present invention should be determined by the following claims.

1: stress dispersive structure
10: slab 20: column
30: original document 32: base portion
34: support portion 40: enlarged reinforcement portion
42: reinforcing body 44: core
45: core plate 46: hollow part
47: connector 49: extension
50,60: reinforcement beam 52: support member
54: support body

Claims (6)

A slab extending in a horizontal direction and forming a plate-shaped structure;
A pillar portion located under the slab and extending in a vertical direction;
A circular beam positioned between the slab and the pillar portion and extending in a horizontal direction to support the slab; And
And a plate-shaped enlarged reinforcing part positioned above the original beam and supporting the slab together with the original beam.
The method of claim 1,
A stress-dispersive structure, characterized in that the plurality of circular beams intersect at the upper side of the column.
The method of claim 2, wherein the original,
A base portion supporting a lower portion of the enlarged reinforcing portion and connected to the pillar portion; And
And a support portion extending from the base portion to support a lower portion of the slab.
The method of claim 3,
The thickness of the support portion is a stress-dispersive structure, characterized in that at least twice the thickness of the base portion.
The method of claim 3, wherein the enlarged reinforcing part,
It is located on the upper side of the base portion, a stress-dispersive structure, characterized in that the side surface is a plate-shaped structure facing the end of the support.
The method according to any one of claims 1 to 5,
A reinforcing beam installed in a shape intersecting the original beam, and supporting a lower portion of the slab or the enlarged reinforcing part.

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