KR101476728B1 - Concrete floor of the building process to increase - Google Patents

Abstract

The present invention relates to a floor increase method of a concrete building, which integrally forms beams and a slab on the top of columns in a horizontal line by forming beam frames between the lower and upper frames of the slab, thereby reducing construction time and the amount of required materials, and enabling cost-efficient construction. The floor increase method of the concrete method comprises: a column frame forming step (S10); a slab lower frame forming step (S20); a beam frame forming step (S30); a slab upper frame forming step (S40); a mold forming step (S50); and a curing step (S60).

Description

[0001] The present invention relates to a concrete building,

The present invention relates to a method of making a concrete building, and more particularly, to a method for forming a beam structure between a lower frame and an upper frame of a slab so that a beam and a slab are integrally formed on a horizontal line, The height of the floor height is lower than that of the conventional floor, and the overall height of the building is formed to be low, so that the construction air can be saved by reducing the amount of air and the material required for construction, The present invention relates to a method of building a concrete building in which the lower skeleton is formed, the steel plate is formed at the center, and the upper skeleton is formed at the upper part.

Generally, a process of continuously depositing layers in a process of building a concrete building includes a first step of forming a skeleton of a column, a second step of stacking a skeleton of the beam on an upper layer of the skeleton of the column, A third step of forming a frame of a slab by laminating a lower reinforcing bar woven in a lattice form on the upper layer of the skeleton and an upper reinforcing bar woven in a lattice form on the upper part of the lower reinforcing bar, and a third step of forming a frame on the outer side of the pillar skeleton and the beam skeleton and the slab skeleton And a concrete layer is cured into the mold to form a column, a beam and a slab, and a layer is formed by a fourth step.

However, the conventional multi-layer method has a structure in which the column 1, the beam 3 and the slab 2 are sequentially stacked as shown in FIG. 1, The height of the building is designed to be high and the height of the building is designed to be high.

Furthermore, as the height of the building floor increases, there is a problem that the construction is uneconomical due to a large amount of materials used.

In addition, if the building is designed to be high, the depth of the underground where the foundation of the building is constructed must be designed to be deep for the safety of the building, so that not only the air required for the earthworks is long, but also the material required for the foundation structure is wasted There was a problem.

The slab 2 and the beam 3 are formed at different heights in the structure in which the column 1 supports the beam 3 vertically and the beam 3 supports the slab 2 vertically, The impact applied to the slab 2 can not be effectively transmitted to the beam 3 and the impact applied to the slab 2 can not be easily removed so that the structure of the layer is not stable.

The present invention has been made in order to solve all of the above problems, and it is an object of the present invention to provide a method for forming a beam frame between a lower frame and an upper frame of a slab, wherein a beam and a slab are integrally formed on a horizontal line , The floor height of one floor is lower than that of the conventional floor, and the overall height of the building is formed to be low, so that the construction air can be reduced and the amount of material required can be reduced, And the durability of the boslab can be enhanced by forming a lower skeleton at the inner lower part of the boslab, an iron plate at the center, and an upper skeleton at the upper part.

Since the beam and slab formed on the upper part of the column are designed to be connected to the same horizontal line, the impact applied to the slab can be effectively transmitted to the column through the beam, And to provide a multi-layered method.

In addition, by designing the beam frame as a horizontal and vertical steel plate, it is possible to provide a method of constructing a concrete building by which the material can be reduced in comparison with a reinforcing bar used as a beam frame in the prior art, thereby achieving more economical construction.

According to another aspect of the present invention, there is provided a method of forming a pillar of a concrete building, the method comprising: forming a pillar skeleton forming a plurality of pillar skeletons by vertically arranging a plurality of pillar reinforcing bars functioning as a pillar skeleton; (S20) for forming a lower skeleton of the slab in a lattice shape with a plurality of reinforcing bars at an upper portion of the columnar reinforcing bars of the column, the slab lower skeleton being connected and fixed to the column skeleton, Wherein the skeleton of the beam comprises at least one horizontal steel plate orthogonal to the column steel in a horizontal direction and at least one vertical steel plate orthogonal to the horizontal steel plate, (S30) for forming a plurality of reinforcing bars in the upper part of the column, (S40) for forming an upper skeleton of the slab in a shape of a slab, wherein the slab upper skeleton is positioned at an upper portion of the skeleton and connected and fixed to the column skeleton, And a curing step (S60) of forming a mold on the outside of the beam frame (S50); and a curing step (S60) for easily building a column, a beam, and a slab by placing and curing concrete into the mold,

And an iron plate of the skeleton is connected to the lower skeleton and the upper skeleton of the slab.

Further, the steel plate of the beam frame further includes a friction part for increasing frictional force with concrete to be cured,

The friction portion may be any one selected from a concavo-convex portion formed concavely and convex on the surface of the steel plate or a bolt portion including a nut fastened to the bolt passing through the steel plate.

Further, a connecting steel plate for interconnecting the steel plate constituting the skeleton of the beam and the steel plates constituting the skeleton of the other beam is further formed, and the skeletons of the plurality of beams are integrally connected through the connecting steel plate, Thereby enhancing the structural safety of the beam.

The reinforcing steel plate may further include a reinforcing steel plate coupled to the column reinforcing bars of the column and being fixed to the outer side of the steel plate, which is a skeleton of the beam, to strengthen the connection structure between the column and the beam.

Further, if two or more horizontal steel plates and vertical steel plates are formed respectively in the beam frame,

At least one reinforcing steel plate is provided between the horizontal steel plates and between the vertical steel plates to enhance the durability of the steel plates.

Further, if two or more horizontal steel plates and vertical steel plates are formed respectively in the beam frame,

Wherein the steel plate is welded to the inner surface of the stationary reinforcing bar so that the steel plate is stably coupled to the stationary steel bar, Thereby enhancing structural safety.

As described above, according to the present invention, a beam frame is formed between the lower frame and the upper frame of the slab, so that beams and slabs are integrally formed on the horizontal line at the upper part of the column, The height of the floor height is lower than that of the conventional floor, and the overall height of the building is formed to be low, so that the construction air can be saved by reducing the amount of air and the material required for construction, The bottom skeleton is formed at the lower part, the iron plate is formed at the center, and the upper skeleton is formed at the upper part.

Since the beam and the slab formed on the upper part of the column are designed to be connected to the same horizontal line, the impact applied to the slab can be effectively transmitted to the column through the beam, thereby securing the structural safety of the layer .

In addition, since the skeleton of the beam is designed as the horizontal and vertical steel plates, the material is reduced in comparison with the reinforcing bars used as the beam frames in the past, thereby achieving a more economical construction.

1 is a cross-sectional view of a column and a beam and a slab,
FIG. 2 is a conceptual view of the method of the multi-layered construction of a concrete building according to an embodiment of the present invention.
3 is a view for explaining the method of making the concrete structure of the concrete building shown in FIG.

The method of making a concrete building according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Detailed descriptions of well-known functions and constructions that may be unnecessarily obscured by the gist of the present invention will be omitted.

FIG. 2 is a conceptual view of a concrete building method of a concrete building according to an embodiment of the present invention. FIG. 3 is a cross- Respectively, to illustrate the method of making the concrete building.

As shown in the drawing, the concrete building method of a concrete building 100 according to an embodiment of the present invention includes a column skeleton forming step S10, a slab lower skeleton forming step S20, a beam forming step S30, A slab upper skeleton forming step S40, a form forming step S50, and a curing step S60.

As shown in FIGS. 2 and 3A, the column skeleton forming step S10 includes vertically arranging a plurality of columnar bars 11, which function as a skeleton 10 of the column 1, To form a skeleton (10).

Here, the step of forming the skeleton 10 of the column 1 in the column skeleton formation step S10 is the same as the process of forming the skeleton of the column with a plurality of reinforcing bars in order to construct a building, .

As shown in FIGS. 2 and 3B, the slab lower frame forming step S20 includes crossing a plurality of reinforcing bars in the form of a lattice at the upper portion of the pillar reinforcing bars 11 of the pillar 1, And the lower frame 21 of the slab 2 is connected and fixed to the frame 1.

As shown in FIGS. 2 and 3C, in the beam forming step S30, the beam 30 of the beam 3 is formed on the upper part of the columnar bar 11 of each column 1, The skeleton 30 of the frame 3 includes at least one horizontal steel plate 31 installed in a horizontal direction orthogonal to the columnar reinforcement 11 and at least one vertical steel plate 32 crossing the horizontal steel plate 31 at right angles And is located above the lower skeleton 21 of the slab 2.

3K, the iron plates 31 and 32 of the skeleton 30 are connected to the lower skeleton 21 of the slab 2 and the upper skeleton 22, respectively, The beam 3 and the slab 2 are integrally connected horizontally through the curing step S60 so that the cured beam 3 and the slab 2 are integrally formed on the horizontal line, The structure is connected to each other, so that the structural safety can be secured.

The upper skeleton 22 is located at the upper part of the steel plate 31 and the upper skeleton 22 at the center of the lower skeleton 21 at the lower part of the beam 3 and the slab 2, Of course, the safety is enhanced.

3 (k), since the beam 3 and the slab 2 are connected to each other on the same horizontal line, the impact applied to the slab 2 is effectively transmitted to the column 1 And thus the structural safety of the layer can be secured.

3, the iron plates 31 and 32 of the beam 3 further include a friction part 40 for increasing frictional force with concrete to be cured, It is possible to secure a structural safety by inducing a firm connection between the frame 30 and the frame 30.

3D, the rubbing portion 40 may be formed by a concave / convex portion 41 formed concavely and convexly on the surface of the iron plates 31 and 32 or a bolt passing through the iron plates 31 and 32 It is preferable that the bolt portion 42 be used by being fixed to the steel plates 31 and 32 through welding.

3E, the iron plates 31 and 32 constituting the frame 30 of the beam 3 and the iron plates 31 and 32 constituting the frame 30 of the beam 3 other than the beam 3, The structural steel of the present invention further includes a connecting steel plate 50 connecting the skeletons 30 of the plurality of beams 3 to each other through the connecting steel plate 50, It is preferable to strengthen it.

3F, the pillar 3 is coupled to the pillar 11 of the column 1 and is fixedly coupled to the outside of the steel plates 31 and 32, which are the skeletons 30 of the beam 3, (60) reinforcing the connection structure of the beam (1) and the beam (3)

The steel plates 31 and 32, which are the skeletons 30 of the beam 3 which are positioned close to the column 1 where loads or forces are concentrated and are exposed to a high load or force, The structural stability of the beam 3 can be further enhanced by enhancing durability.

As shown in FIG. 3G, when two or more horizontal steel plates 31 and vertical steel plates 32 are formed on the skeleton 30 of the beam 3,

At least one reinforcing steel plate 70 is provided between the steel steel plates 31 and between the steel steel plates 32 to strengthen the durability of the steel plates 31 and 32 so that the structural It is desirable to ensure safety.

3H, when two or more horizontal steel plates 31 and vertical steel plates 32 are formed on the skeleton 30 of the beam 3,

One or more "fixed" reinforcing bars 80 are provided on the transverse steel plates 31 and the longitudinal steel plates 32. The steel plates 31 and 32 are welded to the inner surface of the fixed reinforcing bars 80 It is preferable that the structural stability of the iron plates 31 and 32 is enhanced by inducing the iron plates 31 and 32 to be stably bound to the stationary reinforcing bars 80.

2 and 3i, the slab upper skeleton forming step S40 is performed by forming a plurality of reinforcing bars in an upper layer of the columnar reinforcing bars 11 of the column 1, The upper skeleton 22 of the slab 2 is positioned above the skeleton 30 and connected to the skeleton 10 of the slab 2.

That is, due to the structure in which the steel plates 31 and 32, which are the skeletons 30 of the beam 3, are positioned between the lower and upper skeletons 21 and 22 of the slab 2, And the beam 3 are integrally formed on the horizontal line.

3J, the die forming step S50 is performed on the outer side of the frame 1, the slabs 2, 21 and 22, and the frame 3, Thereby forming the mold 4.

Here, the form forming step S50 and the curing step S60 are the same as the general processes for building a building, and a detailed description thereof will be omitted.

As shown in FIGS. 2 and 3J, the curing step S60 is performed by placing the concrete into the mold 4 and curing the concrete into the column 1, the beam 3, and the slabs 2) is easily constructed to grow one layer.

Here, it is needless to say that when the deposition is completed, the installed mold 4 is removed and collected.

The concrete building method 100 of the present invention having the above-described process forms the skeletons 31 and 32 between the lower skeleton 21 and the upper skeleton 22 of the slab 2 So that the beam 3 and the slab 2 are integrally formed on the horizontal line at the upper part of the column 1 so that the height of one layer is lower than that of the conventional layer, (3) The slab (2) is formed with a lower skeleton (21) at its inner lower part, and an iron plate ( The durability of the slab 2 can be enhanced by forming the upper skeleton 22 on the upper part of the slab 2. [

Since the beam 3 and the slab 2 formed on the upper part of the column 1 are designed to be connected to the same horizontal line, the impact applied to the slab 2 is effectively transmitted to the column through the beam 3. [ So that the structural safety of the layer can be secured.

In addition, since the skeletons 31 and 32 of the beam 3 are designed as the horizontal and vertical steel plates 31 and 32, materials can be saved in comparison with the reinforcing bars used as the beam frames in the past, It is effective.

The concrete building method 100 according to an embodiment of the present invention having the above-described structure is performed in the following process.

First, as shown in FIG. 3A, a plurality of column bars 11 serving as a frame 10 of a column 1 are vertically arranged to form a frame 10 of a plurality of columns 1. (S10)

Here, the process of designing the frame 10 of the column 1 is a general process, and a detailed description thereof will be omitted.

Then, as shown in FIG. 3B, a plurality of reinforcing bars are cross-coupled in a lattice-like manner to the upper portion of the columnar reinforcing bars 11 of the column 1 to arrange the lower reinforcing bars 21 of the slab 2. [ (S20)

At this time, the lower frame 21 of the slab 2 is welded to the frame 1 to fix its position.

Thereafter, as shown in FIG. 3C, one or more horizontal steel plates 31 are installed on the upper part of the columnar reinforcing bars 11 of each column 1 in a horizontal direction orthogonal to the column reinforcing bars 11, (30) of the beam (3) by arranging at least one vertical steel plate (32) orthogonal to the longitudinal axis (31) of the slab (2) ). (S30)

Here, the skeleton 30 of the beam 3 is welded and fixed firmly to the pillar 11 of the column 1 and the skeletons 21 and 22 of the slab 2. [

3D, a frictional portion 40 is formed on the steel plates 31 and 32 of the beam 3 to increase the frictional force with concrete to be cured, so that the beam 3 and the skeleton 30) can be induced,

The beams 3 and the beams 3 constituting the skeleton 30 of the beam 3 are connected to each other so that the skeletons 30 of the beams 3 are connected to each other as shown in FIG. The connecting steel plate 50 connecting the steel plates 31 and 32 constituting the frame 30 of the frame 3 is reinforced so that the structural safety of the beam 3 can be enhanced,

3F, in order to strengthen the portions of the steel plates 31 and 32, which are the frame 30 of the beam 3 positioned close to the column 1 and exposed to a high load or force, Is connected to the columnar reinforcement 11 of the column 1 and fixed to the outside of the steel plates 31 and 32 which are the skeletons 30 of the beam 3 so that the connection structure between the column 1 and the beam 3 Reinforced steel plate 60 reinforcing the structural strength of the beam 3,

As shown in FIG. 3G, when two or more horizontal steel plates 31 and vertical steel plates 32 are formed respectively in the skeleton 30 of the beam 3, One or more reinforcing steel plates 70 may be installed between the steel plates 32 to enhance the durability of the steel plates 31 and 32 to ensure the structural safety of the beams 3,

3H, when at least two horizontal steel plates 31 and vertical steel plates 32 are formed in the skeleton 30 of the beam 3, the horizontal steel plates 31 and the vertical steel plates 32 ), One or more fixed reinforcing bars (80) for reinforcing and fixing the steel sheets can be provided to enhance the structural safety of the steel sheets (31, 32).

3I, the upper skeleton 22 of the slab 2 is formed in a lattice shape with a plurality of reinforcing bars at the upper part of the pillar 11 of the pillar 1, The skeleton (22) is located above the skeleton (30) of the beam (3). (S40)

At this time, the upper skeleton 22 is fixedly connected to the frame 10 and the steel plates 31 and 32.

3J, a mold 4 is formed on the outside of the frame 1, the slab 2, and the skeleton 30 of the beam 3, as shown in FIG. 3J. And concrete is placed and cured into the formwork 4 to easily construct the pillars 1, the beams 3 and the slabs 2 to increase one layer. (S50), (S60)

Here, the process of forming the mold 4 and curing the concrete is the same as a general process for building a building, and a detailed description thereof will be omitted.

The layer formed through the above process is formed by forming the skeletons 31 and 32 between the lower skeleton 21 and the upper skeleton 22 of the slab 2 as shown in FIG. Since the beam 3 and the slab 2 are integrally formed on the horizontal line at the upper part of the column 1, the height of one layer is lower than that of the conventional layer, The lower skeleton 21 is formed in the inner lower part of the slab 2 and the steel plates 31 and 32 are formed at the center of the slab 2. In addition, The slab 2 having the upper skeleton 22 is formed on the upper portion of the slab 2 and the durability of the slab 2 is improved.

Furthermore, as shown in Fig. 3K, the integral beam 3 cured by the structure in which the skeleton 30 of the beam 3 is connected to the skeleton 20 of the slab 2 has a durability Of course.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. You will understand the point. It goes without saying that variations can be made by those skilled in the art without departing from the spirit of the present invention. Accordingly, the scope of claim of the present invention is not limited within the scope of the detailed description, but will be defined by the following claims and technical ideas thereof.

1. Columns 2. Slabs
3. beam 4. mold
10, 30. Skeleton 11. Column Reinforcement
21. Lower skeleton 22. Upper skeleton
31. Side reinforcement 32. Vertical reinforcement
40. Friction part 41. Uneven part
42. Bolt portion 50. Connection plate
60. Reinforced steel plate 70. Reinforced steel plate
80. Fixed reinforcing bars
S10. Column skeleton formation step
S20. Slab Lower Skeleton Formation Stage
S30. Beam forming step
S40. Step of formation of upper slab skeleton
S50. Form formation step
S60. Curing step
100. Multiplication method of concrete building

Claims (6)

A column skeleton forming step (S10) of vertically arranging a plurality of columnar bars (11) functioning as a skeleton (10) of the column (1) to form a skeleton (10) of a plurality of columns (1);
Wherein a lower frame 21 of the slab 2 is formed in a lattice shape with a plurality of reinforcing bars at an upper portion of a columnar reinforcing bar 11 of the column 1. The lower frame 21 of the slab 2 is supported by the column 1, A step (S20) of forming a slab bottom skeleton to be connected and fixed to the skeleton (10);
The frame 30 of the beam 3 is formed on the upper part of the columnar reinforcing bars 11 of each column 1. The frame 30 of the beam 3 is horizontally And at least one vertical iron plate (32) intersecting the horizontal steel plate (31) at a position above the lower frame (21) of the slab (2) Forming step S30;
The upper skeleton 22 of the slab 2 is formed in a lattice shape with a plurality of reinforcing bars at the upper part of the pillar reinforcement 11 of the column 1, Forming a slab upper skeleton (S40), which is located at an upper portion of the skeleton (30) and is connected and fixed to the skeleton (10) of the column (1);
A forming step S50 of forming a mold 4 outside the frame 1, the slabs 2, 21 and 22, and the frame 3; And
And a curing step (S60) in which the concrete is laid and cured into the mold (4) to easily construct the column (1), the beam (3) and the slab (2)
Wherein the steel plates 31 and 32 of the beam 3 are connected to the lower and upper skeletons 21 and 22 of the slab 2, respectively.
The method according to claim 1,
The steel plate (31, 32) of the beam (3) skeleton (30) further includes a friction part (40) for increasing frictional force with concrete being cured,
The rubbing portion 40 may include a concave and convex portion 41 formed concavely and convex on the surface of the iron plates 31 and 32 or a bolt portion 42 including a nut to be fastened to the bolts passing through the iron plates 31 and 32 ) Is used as the reinforced concrete structure of the concrete building.
The method according to claim 1,
An interconnecting iron plate 50 interconnecting the iron plates 31 and 32 constituting the framework 30 of the beam 3 and the iron plates 31 and 32 constituting the framework 30 of the other beam 3; Further,
Wherein a plurality of beams 3 of the beams 3 are integrally connected through the connecting steel plate 50 so that the structural safety of the beam 3 is enhanced.
The method according to claim 1,
And is fixed to the outside of the steel plates 31 and 32 which are the skeletons 30 of the beam 3 so as to be fixed to the column 1 and the beam 3 And a reinforcing steel plate (60) for reinforcing the connection structure.
The method according to any one of claims 1 to 4,
If two or more horizontal steel plates 31 and vertical steel plates 32 are formed on the skeleton 30 of the beam 3,
Wherein at least one reinforcing steel plate (70) is provided between the steel plate (31) and the steel plate (32) to enhance the durability of the steel plates (31, 32) .
6. The method of claim 5,
If two or more horizontal steel plates 31 and vertical steel plates 32 are formed on the skeleton 30 of the beam 3,
One or more "fixed" reinforcing bars 80 are installed on the transverse steel plate 31 and the vertical steel plate 32,
The steel plates 31 and 32 are welded to the inner surface of the stationary reinforcing bar 80 to induce the steel plates 31 and 32 to be stably coupled to the stationary reinforcing bars 80, And reinforcing the structural safety of the concrete building.

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