KR102702361B1 - Shear reinforcement system for interior column of Non-Limited plate slab by thought structural support - Google Patents

Abstract

The present invention discloses a technical idea of a shear reinforcement system that is arranged in a column provided to stand vertically in a building and reinforces the column, the system including: an angle unit that protrudes from the column at a predetermined angle; a supporting unit that is formed horizontally orthogonal to the angle unit, protrudes from the column, and supports the lower part of the ceiling of the building; and a pressure reinforcement unit that is arranged orthogonal to the angle unit, is arranged orthogonal to the supporting unit, has one side of its body fixedly attached to the outer surface of the column to fix the column, and supports the angle unit and the supporting unit.

Description

{Shear reinforcement system for interior column of Non-Limited plate slab by thought structural support}

The present invention relates to shear reinforcement of a flat plate slab column joint, and more specifically, to a technical field of a shear reinforcement system of a flat plate slab column joint through structural support for external shear reinforcement to easily perform shear reinforcement after concrete pouring and ensure structural safety, in order to perform post-shear reinforcement of a slab from the outside.

A flat-plate structure is a type of building structure in which there are no beams (girders), which are horizontal structural members that support the load, and slabs are directly connected to columns (cores), which are vertical members that support the building's load.

The flat plate structure was originally used in bridge construction, and is also called a flat floor structure or flat slab structure.

A slab is a reinforced concrete floor structure, and the load generated on the slab is directly transferred to the floor through the columns and lowered to the ground.

The flat-panel structure has the advantage of being free of wall constraints, allowing flexibility in design changes, and providing a sense of openness due to aesthetics, sound, and light diffusion.

However, the flat plate structure is vulnerable to horizontal loads because there are no beams, and cracks can occur in all areas where the load is applied due to extreme local shear stress, and the slab can be damaged. This damage is likely to lead to progressive collapse.

Recently, the collapse of an underground parking lot in an apartment building in a new city and the loss of rebar in some apartment buildings have emerged as serious social problems, and concerns about flat plate structures, which are vulnerable to horizontal loads, are growing due to speculation that the cause of the accident was the flat plate structure.

Although the flat-plate structure is an officially recognized safe construction method, accidents can be caused by problems in the design or construction process rather than problems with the flat-plate method itself. In the event of a problem during construction, shear reinforcement must be implemented through post-reinforcement.

Various reinforcing construction methods and reinforcing materials for shear reinforcement are continuously being developed. As an example of a prior art document on reinforcing materials, there exists "Joint structure and joint construction method of precast column and field-cast slab using connecting shear reinforcing iron with tendon chair function (Registration No. 10-1460559, hereinafter referred to as "Patent Document 1")."

In the case of patent document 1, a connecting shear reinforcing iron having a tendon chair function is placed at a slab-column joint where a precast column and a slab are joined, so that the slab is constructed as an integral part of the precast column using cast-in-place concrete, and another precast column is firmly and integrally connected above the cast-in-place slab, thereby shortening the construction period and forming a structurally strong and stable slab-column joint, which relates to a "joint structure and a joint construction method between a precast column and a cast-in-place slab using a connecting shear reinforcing iron having a tendon chair function."

In addition, there exists a “slab-column joint shear reinforcement structure (registration number 10-0659471, hereinafter referred to as patent document 2).”

In the case of patent document 2, an improved technology is disclosed regarding a shear reinforcement structure that increases resistance to shear failure in a slab-column joint of a reinforced concrete structure.

The invention according to patent document 2 relates to a joint shear reinforcement structure that can effectively increase the strength and ductility of a slab-column joint while ensuring constructability and economy by using a plurality of shear reinforcements manufactured in a truss shape. The invention for this purpose is a slab-column joint shear reinforcement structure that can reinforce shear strength by installing a plurality of shear reinforcements at a joint where a slab and a column of a reinforced concrete structure are joined, wherein the shear reinforcements include at least one upper chord; at least one lower chord arranged in parallel with the upper chord at a predetermined interval; and an inclined member installed between the upper chord and the lower chord to have a continuous wave shape; thereby having a truss shape as an overall feature in terms of configuration. At this time, it is particularly preferable that the shear reinforcements use a truss-type steel wire obtained by removing a metal plate portion from a conventional truss-type deck plate.

In addition, there is also a “vertical hanging shear reinforcement for column-slab joint (registration number 10-1177316, hereinafter referred to as patent document 3).”

In the case of Patent Document 3, the vertically hanging shear reinforcement of a column-slab joint is improved by forming separate reinforcing bars on the upper and lower heads of the first and second subframes constituting the vertically hanging shear reinforcement, thereby increasing the bonding surface area with the poured concrete and improving the bonding strength thereof, and in addition, by mutually connecting and fixing the first shear reinforcement bar of the first subframe and the second shear reinforcement bar of the second subframe, shaking is prevented during construction, thereby improving the convenience of construction.

In the case of the existing flat plate design, there are advantages for the purpose of beautification and space utilization, but it is structurally very vulnerable, and shear reinforcement is essential to supplement the structural vulnerability. Therefore, technological development is needed to simultaneously satisfy the convenience of construction for shear reinforcement and structural stability.

Registration No. 10-1460559 Registration No. 10-0659471 Registration No. 10-1177316

The shear reinforcement system for a flat plate slab column joint using structural support according to the present invention has been devised to solve the above-mentioned conventional problems, and presents the following tasks to be solved.

First, in cases where the slab's shear reinforcement is missing or the joint is incorrect, making the structure vulnerable, shear reinforcement is provided externally for post-reinforcement purposes.

Second, we want to ensure structural safety by easily reinforcing the shear from the outside after pouring the concrete.

The problems to be solved by the present invention are not limited to those mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the description below.

The shear reinforcement system for a flat plate slab column joint using structural support according to the present invention has the following problem-solving means to solve the above-mentioned problem.

The shear reinforcement system of a column joint of a flat plate slab using structural support according to the present invention is characterized in that it is a shear reinforcement system that is arranged in a column that is provided to stand vertically in a building and reinforces the column, and includes: an angle unit that protrudes from the column at a predetermined angle; a supporting unit that is formed horizontally orthogonal to the angle unit, protrudes from the column, and supports the lower end of the ceiling of the building; and a pressure reinforcement unit that is arranged orthogonal to the angle unit, is arranged orthogonal to the supporting unit, has one side of its body fixedly attached to the outer surface of the column to fix the column, and supports the angle unit and the supporting unit.

The shear reinforcement system of a flat plate slab column joint using structural support according to the present invention is characterized by including: a reinforcement part formed by extending and protruding on both sides from the compression reinforcement unit and fixed to the column; an angle part formed by protruding from one side of the reinforcement part and forming a predetermined angle from the column; and a supporting part arranged orthogonally to the angle part and protruding from an upper portion of the reinforcement part to support the lower end of the building ceiling.

The shear reinforcement system of a flat plate slab column joint using structural support according to the present invention is characterized by including a connecting portion that is formed to be horizontally spaced apart from the angle portion, protrudes from the reinforcement portion, is formed orthogonally to the supporting portion, and has a bolt passing through a predetermined opening.

The compression reinforcement unit of the shear reinforcement system of a flat plate slab column joint using structural support according to the present invention is characterized in that it has an insertion hole formed through the body, an anchor penetrates the insertion hole so that one side of the compression reinforcement unit is fixed to the column, and a shear load from the ceiling is transmitted as a shear flow through the anchor.

The supporting unit of the shear reinforcement system for a flat plate slab column joint using structural support according to the present invention is characterized in that it is provided with the second inserting hole formed by penetrating the supporting unit, and the upper surface of the supporting unit is fixedly pressed against the lower end of the ceiling through the second inserting hole.

The shear reinforcement system of a flat plate slab column joint using structural support according to the present invention having the above-described configuration provides the following effects.

First, the shear failure line is enlarged to increase the shear support load.

Second, it ensures that the slab shear force is transmitted to the column over a large area.

Third, the frame is divided into two pieces and can be easily assembled by bolting the steel frame together, allowing the shear load to be transmitted to the column.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

FIG. 1 is a perspective view of a shear reinforcement system for a flat plate slab column joint with structural support according to one embodiment of the present invention.
FIG. 2 is a plan view of a shear reinforcement system for a flat plate slab column joint using structural support according to one embodiment of the present invention.
FIG. 3 is a front view of a shear reinforcement system for a flat plate slab column joint with structural support according to one embodiment of the present invention.
FIG. 4 is a side view of a shear reinforcement system for a flat plate slab column joint with structural support according to one embodiment of the present invention.
FIG. 5 shows the magnitude of shear force of a shear reinforcement system for a flat plate slab column joint using structural support according to one embodiment of the present invention.
FIG. 6 illustrates a signal sensing unit of a shear reinforcement system for a flat plate slab column joint using structural support according to one embodiment of the present invention.

The shear reinforcement system of a flat plate slab column joint using structural support according to the present invention can have various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, but should be understood to include all modifications, equivalents, or substitutes included in the technical spirit and technical scope of the present invention.

FIG. 1 is a perspective view of a shear reinforcement system for a flat slab column joint with structural support according to an embodiment of the present invention. FIG. 2 is a plan view of a shear reinforcement system for a flat slab column joint with structural support according to an embodiment of the present invention. FIG. 3 is a front view of a shear reinforcement system for a flat slab column joint with structural support according to an embodiment of the present invention. FIG. 4 is a side view of a shear reinforcement system for a flat slab column joint with structural support according to an embodiment of the present invention. FIG. 5 shows the magnitude of a shear force of a shear reinforcement system for a flat slab column joint with structural support according to an embodiment of the present invention. FIG. 6 illustrates a signal sensing unit of a shear reinforcement system for a flat slab column joint with structural support according to an embodiment of the present invention.

The shear reinforcement system for a flat plate slab column joint using structural support according to the present invention comprises an angle unit (100), a supporting unit (200), and a pressure reinforcement unit (300).

The shear reinforcement system of the flat plate slab column joint of the present invention is a shear reinforcement system that is placed on a column provided to stand vertically in a building and reinforces the column.

The angle unit (100) is formed to protrude from the column at a predetermined angle.

In the case of the angle unit (100), as shown in Fig. 1, the first angle portion (110) and the second angle portion (120) are formed by protruding from the columns on both sides.

The supporting unit (200) is formed horizontally, orthogonal to the angle unit (100), protrudes from the column, and supports the lower part of the ceiling of the building.

The pressure reinforcing unit (300) is arranged orthogonally to the angle unit (100) and orthogonally to the supporting unit (200), and one side of the body is fixedly attached to the outer surface of the column to fix the column and support the angle unit (100) and the supporting unit (200).

In the case of the angle unit (100), the supporting unit (200), and the pressure reinforcing unit (300), they may be formed of stainless steel, but there is no limitation on the material and material thereof.

In addition, the angle unit (100), the supporting unit (200), and the pressure reinforcement unit (300) may be formed with different thicknesses. Compared to the case where the supporting unit (200) is fixed to the ceiling and the column, the supporting unit (200) may be provided with a thicker thickness. However, it is preferable that the thickness is not limited in this case.

As shown in Fig. 1, the angle unit (100) is provided protruding from a column.

The angle unit (100) can be provided in a predetermined shape, and the upper part of the angle unit (100) can be formed to have the same length as the supporting unit (200), and the protruding length can be formed to be shorter as it extends to the lower part.

In addition, it is desirable that the shape of the angle unit (100) is not limited as shown in the drawing.

The supporting unit (200) is fixed to the ceiling connected to the column and the ceiling surrounding the column, and is formed by extending from the angle unit (100).

In addition, the supporting unit (200) is fixed to the ceiling and supports the angle unit (100) while also reinforcing the external force applied to the angle unit (100).

The shear reinforcement system for a flat plate slab column joint using structural support according to the present invention comprises a reinforcing member (400), an angle member (500), and a supporting member (600).

The reinforcing part (400), the angle part (500), and the supporting part (600) are formed on both sides from the angle unit (100), the supporting unit (200), and the pressure reinforcing unit (300), and it is preferable that they are provided in multiple units on both sides.

The reinforcing member (400) is formed by extending and protruding on both sides from the pressure reinforcing unit (300) and is fixed to the column.

As illustrated in FIG. 1, the angle unit (100), the supporting unit (200), and the pressure reinforcement unit (300) are provided in a form that fixes all of a part of the column, and the reinforcement part (400), the angle part (500), and the supporting part (600) are provided in a form that fixes to a part of one side of the column.

In the case of the angle portion (500), it is formed by protruding from one side of the reinforcing portion (400) and forms a predetermined angle from the column.

In addition, in the case of the angle portion (500), as shown in FIG. 2, it may be formed by a second angle portion (520) that extends from the first angle portion (110) and protrudes at a predetermined angle, and a first angle portion (510) that extends from the second angle portion (120) and protrudes at a predetermined angle.

The supporting part (600) is arranged orthogonally to the angle part (500) and is formed to protrude from the upper part of the reinforcing part (400) to support the lower part of the building ceiling.

In the case of the supporting part (600), a plurality of supporting holes (601) are provided so that anchors can be introduced through the holes and fixed to the bottom of the ceiling.

As shown in Fig. 1, the reinforcing member (400) is extended and protruded from both sides from the pressure reinforcing unit (300) so as to be fixed to the column, and is formed to protrude in a direction corresponding to the angle unit (100).

The supporting unit (200) and the supporting member (120, 130) are provided in a spaced form and are formed to protrude from the fixed wall and are parallel to the wall. Accordingly, as shown in the plan view illustrated in Fig. 2, they protrude from both sides of the wall and support the wall from each side.

This shear reinforcement system for a flat plate slab column joint using structural support according to the present invention comprises an angle unit (100), a supporting unit (200), a pressure reinforcement unit (300), and reinforcement parts (400), angle parts (500), and supporting parts (600) formed on both sides of the pressure reinforcement unit (300) are installed to the column as a single piece, and two pieces of column joint shear reinforcement are installed on both sides of the column.

In addition, when the shear reinforcement system of a flat plate slab column joint through structural support according to the present invention is installed in a column as a single piece, non-shrink grout or silicone may be provided between the angle unit (100), the supporting unit (200), the compression reinforcement unit (300), and the reinforcement portion (400), the angle portion (500), the supporting portion (600) formed on both sides of the compression reinforcement unit (300) and the column.

The angle unit (100) and the angle portion (500) can form a predetermined angle.

In the case of the angle unit (100), it protrudes from both sides of the column fixed to the pressure reinforcement unit (300) and protrudes parallel to both sides of the column.

The angle portion (500) is also formed by protruding from one side of the column to which the reinforcing portion (400) is fixed, and the angle unit (100) and the angle portion (500) can be formed by protruding at a predetermined angle from the corner of the column.

The shear reinforcement system for a flat plate slab column joint using structural support according to the present invention is configured to include a connecting portion (700).

The connecting portion (700) is formed horizontally spaced from the angle portion (500), protrudes from the reinforcing portion (400), and is formed orthogonally to the supporting portion (600) to allow a bolt to pass through a predetermined opening.

In the case of the connecting portion (700), a plurality of first connecting portions (710) extending from the first angle portion (510) and second connecting portions (720) extending from the second angle portion (520) may be formed in the body of the reinforcing system.

As shown in Fig. 1, the connecting portion (700) is provided in a form that extends from the reinforcing portion (400) and the supporting portion (600), but is formed by extending at a predetermined angle.

In addition, when two pieces of column joint shear reinforcement are connected, they are connected and fixed to a connecting part (700') that is in contact with the connecting part (700) through a connecting hole (701) formed in the connecting part (700) through mutual contact of the connecting parts (700), thereby providing a form that surrounds the column.

In the case of the connecting part (700), as shown in Fig. 1, it may be provided in a form that extends from the reinforcing part (400) and protrudes at a predetermined angle, and may be provided so as not to exceed the length of the reinforcing part (400).

The compression reinforcement unit (300) of the shear reinforcement system of a flat plate slab column joint using structural support according to the present invention is provided with an insertion hole formed through a body, and an anchor penetrates the insertion hole so that one side of the compression reinforcement unit (300) is fixed to the column, and a shear load from the ceiling is transmitted as a shear flow through the anchor.

In the case of the inserting hole, it is also formed in the pressure reinforcing unit (300) and the reinforcing part (400), and in the case of the reinforcing part (400), an anchor penetrates through one side of the inserting hole (first inserting hole, 301) and is fixed to the column.

For anchors, the size and length of the anchor may be provided differently depending on the load transmission capacity.

For example, an anchor used to secure a pressure reinforcing unit (300) to a column may be an anchor with a diameter of about 32 mm among high-load anchors of HILTI HSL-M24.

The supporting unit (200) of the shear reinforcement system for a flat plate slab column joint using structural support according to the present invention is provided with a second inserting hole (201) formed through the second inserting hole (201), and an anchor penetrates the second inserting hole (201) to pressurize the upper surface of the supporting unit (200) to fix the lower part of the ceiling.

The anchor used to secure the supporting unit (200) to the ceiling is a HILTI M16 HSL, and an anchor with a diameter of approximately 24 mm can be used.

The first inserting hole (301) and the second inserting hole (201) may be provided in multiple numbers, and as shown in FIGS. 1 and 2, multiple holes may be formed so that an anchor may penetrate through them and be fixed to the ceiling and column.

An example of flat plate shear reinforcement work for a flat plate slab column joint shear reinforcement system using structural support according to the present invention is as follows.

1. Mushroom steal installation work

- Increase the shear support load by enlarging the shear failure line.

- Allows the slab shear force to be transmitted to the column over a wide area.

- Made of two pieces of stainless steel frame.

1) Use materials that are easy to handle,

2) Easy to assemble, it is assembled by joining steel frames using high strength bolts.

3) The shear load is transmitted to the column through HSL-M24.

4) To properly transmit the shear flow of the slab and plate, HSL-M24 is installed at the bottom of the slab.

The above construction flow and characteristics are exemplary and the numbers and materials are not limited.

The shear length (L') of the shear reinforcement system of a flat plate slab column joint using structural support according to the present invention is increased by a width equal to the difference between L' and L before reinforcement.

That is, as shown in Fig. 5, the shear force transfer increases as it increases from L to L'.

In the case of the signal sensing unit (800), as shown in Fig. 6, it is composed of a current-conducting wire.

The signal sensing unit (800) is intended to detect abnormal signals from walls and columns by intermittently flowing current through the wire.

In the case of the signal sensing unit (800), it is composed of a horizontal sensing unit (801) and a vertical sensing unit (802).

In the case of the horizontal sensing unit (801), the conductor is provided in a horizontal longitudinal direction, and in the case of the vertical sensing unit (802), the conductor is provided vertically.

The horizontal sensing unit (801) and the vertical sensing unit (802) are arranged in a grid shape in the pressure reinforcement unit (300), the supporting unit (200), the reinforcement unit (400), and the supporting unit (600).

The signal sensing unit (800) corresponding to the grid-shaped conductor is in the form in which current flows intermittently, and each conductor can have a positive or negative pole.

In the case of the horizontal sensing unit (801) and the vertical sensing unit (802), if an abnormality occurs in the pressing force in some areas, contact pressure occurs in some sections, and due to the excessive pressure formed in some areas, the horizontal sensing unit (801) and the vertical sensing unit (802) press each other, causing a change in the resistance value.

In addition, if a change occurs in the resistance value, this can be reported to a person in charge or manager, and the current flow in some of the horizontal sensing unit (801) or vertical sensing unit (802) can be cut off.

The column signal sensing unit (810) of the signal sensing unit (800) is provided between the column and the shear reinforcement system. In addition, the loop signal sensing unit (820) is provided between the ceiling and the shear reinforcement system.

The first column sensing unit (811) of the column signal sensing unit (810) is provided between the pressure reinforcement unit (300) and the column.

The second column sensing unit (812) is provided between the first reinforcing unit (410) and the column, and the third column sensing unit (813) is provided between the second reinforcing unit (420) and the column.

The first loop sensing unit (821) of the loop signal sensing unit (820) is provided between the supporting unit (200) and the ceiling.

The second loop sensing unit (822) is provided between the first supporting unit (610) and the ceiling, and the third loop sensing unit (823) is provided between the second supporting unit (620) and the ceiling.

The scope of the rights of the present invention is determined by the matters described in the claims, and the parentheses used in the claims are not described for optional limitation, but are used to indicate clear elements, and the description within the parentheses should also be interpreted as essential elements.

100: Angle Unit
110: 1st angle section
120: 2nd angle section
200: Supporting Unit
201: 2nd insertion hall
300: Pressure Reinforcement Unit
301: The first insertion hall
400: Reinforcement
410: 1st Reinforcement Division
420: Second Reinforcement Unit
500: Angle section
510: 1st angle section
520: 2nd angle section
600: Supporting Department
601: Supporting Hall
610: 1st Supporting Division
620: 2nd Supporting Department
700: Connecting part
701: Connecting hole
710: First connecting section
720: Second connecting section
800: Signal sensing unit

Claims (5)

In a shear reinforcement system that is arranged on a column provided to stand vertically in a building and reinforces the column,
An angle unit formed by protruding at a predetermined angle from the above column;
A supporting unit formed horizontally perpendicular to the angle unit, protruding from the column, and supporting the lower part of the ceiling of the building;
A pressure reinforcing unit arranged orthogonally to the angle unit and orthogonally to the supporting unit, one side of the body of which is fixedly attached to the outer surface of the column to fix the column, and which supports the angle unit and the supporting unit;
A reinforcing member formed by extending and protruding on both sides from the above pressure reinforcing unit and fixed to the column;
An angle portion protruding from one side of the reinforcing portion and forming a predetermined angle from the column;
A supporting part that is arranged perpendicular to the angle part and protrudes from the upper part of the reinforcing part to support the lower part of the building ceiling; and
It is formed in a grid shape and includes a pressure reinforcement unit, a supporting unit, and a signal sensing unit that is arranged on the reinforcement unit and the supporting unit to detect an abnormal signal from the wall and the column.
The above signal sensing unit,
A horizontal sensing unit in which a conductor is provided in a longitudinal direction; and
Includes a vertical sensing unit in which the conductor is provided vertically,
A column signal sensing unit provided between the column and the shear reinforcement system; and
Including a loop signal sensing unit provided between the above ceiling and the above shear reinforcement system,
The above column signal sensing unit,
A first column sensing unit provided between the above pressure reinforcing unit and the column;
A second column sensing unit provided between the first reinforcing unit and the column; and
Including a third column sensing unit provided between the second reinforcing unit and the column,
The above loop signal sensing unit,
A first loop signal sensing unit provided between the above supporting unit and the ceiling;
A second loop sensing unit provided between the first supporting unit and the ceiling; and
Includes a third loop sensing unit provided between the second supporting unit and the ceiling,
The above signal sensing unit,
In the form where current flows intermittently, each conductor has a positive or negative pole.
The above horizontal sensing unit and the above vertical sensing unit,
A shear reinforcement system for a flat plate slab column joint using structural support, characterized in that when an abnormality in the pressing force occurs in a part, the horizontal sensing part and the vertical sensing part are pressurized against each other due to excessive pressure formed in the part, causing a change in the resistance value.
delete In the first paragraph, the system,
A shear reinforcement system for a flat plate slab column joint using structural support, characterized in that it includes a connecting portion formed horizontally spaced apart from the angle portion, protruding from the reinforcing portion, and formed orthogonally to the supporting portion and penetrating a bolt through a predetermined opening.
In the third paragraph, the pressure reinforcement unit,
A shear reinforcement system for a flat plate slab column joint using structural support, characterized in that an insertion hole formed by penetrating the body is provided, an anchor penetrates the insertion hole so that one side of the pressure reinforcement unit is fixed to the column, and a shear load from the ceiling is transmitted as a shear flow through the anchor.
In the fourth paragraph, the supporting unit,
A shear reinforcement system for a flat plate slab column joint using structural support, characterized in that a second inserting hole formed by penetrating the supporting unit is provided, and the upper surface of the supporting unit is fixedly pressed against the lower part of the ceiling through the second inserting hole.