JP2021105275A - Slab - Google Patents

Abstract

To easily form a through hole in a slab.SOLUTION: A slab 20 comprises: a slab main body 22; a plurality of vertical reinforcing bars 30 and horizontal reinforcing bars 40 embedded in the slab main body 22, arranged in a grid pattern as well; and a plurality of diagonal reinforcing bars 60A and 60B embedded in the slab main body 22, diagonally arranged in a grid pattern with respect to the vertical bars 30 and the horizontal bars 40 as well. In the slab main body 22, a plurality of unreinforced regions 50 surrounded by the vertical reinforcing bars 30 and horizontal reinforcing bars 40, and surrounded by the diagonal reinforcing bars 60A and 60B as well are formed.SELECTED DRAWING: Figure 3

Description

The present invention relates to slabs.

A slab having a plurality of unreinforced regions capable of forming through holes is known around a column and a joint between a girder and a girder (see, for example, Patent Document 1). Vertical and horizontal muscles are densely arranged around the unreinforced area. As a result, a through hole can be formed in the unreinforced region without burying a new reinforcing bar around the unreinforced region.

Japanese Unexamined Patent Publication No. 2005-314883

However, in the slab disclosed in Patent Document 1, reinforcement may be insufficient depending on the size of the through hole formed in the unreinforced region and the like. In this case, since it is necessary to newly bury a reinforcing bar or the like in the unreinforced area, it takes time and effort for construction.

In view of the above facts, an object of the present invention is to easily form a through hole in a slab.

The slab according to claim 1 is arranged in a grid pattern with the slab main body, and has a plurality of vertical bars and horizontal bars embedded in the slab main body in a grid pattern and in the vertical bars and the horizontal bars. The slab body is provided with a plurality of diagonal reinforcing bars that are diagonally arranged and embedded in the slab body, and the slab body is surrounded by the vertical bars and the horizontal bars and is surrounded by the diagonal reinforcing bars. Multiple unreinforced areas are formed.

According to the slab according to claim 1, a plurality of vertical and horizontal bars arranged in a grid pattern are embedded in the slab body. Further, in the slab main body, a plurality of diagonal reinforcing bars are embedded in a grid pattern and diagonally arranged with respect to the vertical and horizontal bars. A plurality of unreinforced regions are formed in the slab body. Each unreinforced area is surrounded by vertical and horizontal streaks and by diagonal reinforcements.

Here, the vertical reinforcement, the horizontal reinforcement, and the diagonal reinforcement are not arranged in the non-reinforced region. Therefore, a through hole can be formed in the unreinforced region without cutting the vertical streaks, the horizontal streaks, and the diagonal reinforcing streaks. Therefore, a through hole can be easily formed in the slab body.

Further, the unreinforced region is surrounded by diagonal reinforcing bars, and is reinforced by these diagonal reinforcing bars. Therefore, when forming a through hole in the unreinforced region, it is not necessary to bury a reinforcing bar or the like around the unreinforced region. Therefore, a through hole can be more easily formed in the slab body.

Further, in the present invention, by combining a plurality of vertical and horizontal reinforcing bars arranged in a grid pattern and a plurality of diagonal reinforcing bars arranged in a grid pattern, a through hole is formed over a wide range of the slab body. It is possible to form a plurality of muscleless regions that can be formed.

In the slab according to claim 2, in the slab according to claim 1, one or a plurality of the oblique reinforcing bars are arranged between the adjacent unreinforced regions.

According to the slab according to claim 2, one or a plurality of diagonal reinforcing bars are arranged between adjacent unreinforced regions. As a result, a larger through hole can be formed in the unreinforced region.

In the slab according to claim 1, in the slab according to claim 1 or 2, a plurality of the vertical bars or a plurality of the horizontal bars are arranged between the adjacent unreinforced regions.

According to the slab according to claim 3, a plurality of vertical bars or a plurality of horizontal bars are arranged between adjacent unreinforced regions. These vertical or horizontal streaks reinforce the unreinforced area. As a result, a larger through hole can be formed in the unreinforced region.

The slab according to claim 4 is the slab according to any one of claims 1 to 3, and the upper surface or the lower surface of the slab body has a plurality of criteria that serve as a reference for the position of the unreinforced region. A point is provided.

According to the slab according to claim 4, a plurality of reference points serving as a reference for the position of the unreinforced region are provided on the upper surface or the lower surface of the slab main body. Thereby, a plurality of unreinforced regions can be easily identified in the slab body. Therefore, a through hole can be more easily formed in the slab body.

The slab according to claim 5 is the slab according to any one of claims 1 to 4, wherein the vertical width and the horizontal width of the unreinforced region are 300 mm or less and the slab thickness of the slab body. It is said to be three times or less of.

According to the slab according to claim 5, the strength of the unreinforced region can be ensured by setting the vertical width and the horizontal width of the unreinforced region to 300 mm or less and three times or less the slab thickness of the slab body. can.

As described above, according to the slab according to the present invention, a through hole can be easily formed in the slab.

FIG. 1 is a plan view showing an installation state of the slab according to the embodiment. FIG. 2 is an enlarged plan view of FIG. FIG. 3 is a plan view showing a bar arrangement state of the slab shown in FIG. FIG. 4 is an enlarged plan view showing the crack prevention streaks shown in FIG.

Hereinafter, one embodiment will be described with reference to the drawings.

FIG. 1 shows a plurality of columns 10, girders 12, and girders 14 that support the slab 20 according to the present embodiment. The plurality of pillars 10 are arranged at intervals in two horizontal directions. Further, girders 12 are erected on the adjacent columns 10. Further, a small beam 14 is erected at the center of the pair of large beams 12 facing each other in the lumber axis direction.

Here, the girder 12 and the girder 14 are arranged in a rectangular frame shape in a plan view. The outer peripheral portion of the slab 20 (slab main body 22) is supported by these girders 12 and small beams 14. The columns 10, girders 12, and girders 14 can be made of reinforced concrete, steel-framed reinforced concrete, steel-framed, or the like.

As shown in FIG. 2, the slab 20 has a slab body 22. The slab body 22 is made of precast concrete, for example, in a factory or the like. The slab main body 22 is formed in a rectangular shape (rectangular shape) in a plan view. The slab body 22 may be made of cast-in-place concrete.

As shown in FIG. 3, a plurality of vertical bars 30, a plurality of horizontal bars 40, and a plurality of diagonal reinforcing bars 60A and 60B are embedded in the slab main body 22. The plurality of vertical bars 30, the plurality of horizontal bars 40, and the plurality of diagonal reinforcing bars 60A and 60B are formed by reinforcing bars.

(Vertical line)
The plurality of vertical bars 30 are arranged along the short side direction (arrow Y direction) of the slab main body 22. Further, the total length of the plurality of vertical bars 30 is longer than the short side 22Y of the slab main body 22. Both ends of these vertical bars 30 are projected from the end faces on the long side 22X side of the slab body 22.

Both ends of the vertical streaks 30 may be embedded in the slab main body 22 without protruding from the end faces on the long side 22X side of the slab main body 22. Further, the vertical bar 30 may be formed of a plurality of reinforcing bars connected via a joint or the like.

Further, the plurality of vertical stripes 30 are, for example, a predetermined number (4 in this embodiment) as a group (one set). Hereinafter, this group of vertical streaks 30 will be referred to as a vertical streak group 30G. The plurality of vertical streaks 30G are arranged at predetermined intervals (equal intervals) D in the long side direction of the slab main body 22. Further, in each vertical streak group 30G, the plurality of vertical streaks 30 are arranged at predetermined intervals (equal intervals) d in the long side direction of the slab main body 22. This interval d is narrower than the interval D of the plurality of vertical streaks 30G.

The predetermined number of vertical streaks 30G can be set to two or more.

At the end (outer peripheral portion) on the short side 22Y side of the slab main body 22, one vertical streak 30 that is less than a predetermined number of the vertical streak group 30G is arranged. Hereinafter, the vertical streaks 30 will be referred to as outer peripheral vertical streaks 32. Further, vertical reinforcing bars 34 are arranged at the ends of the slab main body 22 on the short side 22Y side. The vertical reinforcing bars 34 are arranged along the ends of the slab main body 22 on the short side 22Y side, and the entire vertical reinforcing bars 34 are embedded in the slab 20.

The outer peripheral vertical bar 32 and the vertical reinforcing bar 34 can be omitted as appropriate.

(Horizontal line)
The plurality of horizontal bars 40 are arranged along the long side direction (arrow X direction) of the slab main body 22. Further, the total length of the plurality of horizontal bars 40 is longer than the long side 22X of the slab main body 22. Both ends of these horizontal bars 40 are projected from the end faces on the short side 22Y side of the slab main body 22.

Both ends of the horizontal bar 40 may be embedded in the slab main body 22 without protruding from the end surface on the short side 22Y side of the slab main body 22. Further, the horizontal bar 40 may be formed of a plurality of reinforcing bars connected via a joint or the like.

Further, the plurality of horizontal streaks 40 are, for example, a predetermined number (4 in this embodiment) as a group (one set). In the following, this group of lateral muscles 40 will be referred to as a lateral muscle group 40G. The plurality of horizontal muscle groups 40G are arranged at predetermined intervals (equal intervals) T in the long side direction of the slab main body 22. Further, the horizontal streaks 40 of each horizontal streak group 40G are arranged at predetermined intervals (equal intervals) t in the short side direction of the slab main body 22. This interval t is narrower than the interval T of the plurality of lateral muscle groups 40G.

At the end (outer peripheral portion) of the slab main body 22 on the long side 22X side, horizontal streaks 40 that are less than a predetermined number of the horizontal streaks 40G are arranged. In the following, the horizontal streaks 40 will be referred to as outer peripheral horizontal streaks 42. The outer peripheral horizontal streaks 42 can be omitted as appropriate.

(Muscle area)
Here, the plurality of vertical streaks 30G and the plurality of horizontal streaks 40G are arranged in a grid pattern in a plan view. More specifically, the plurality of vertical muscle groups 30G and the plurality of horizontal muscle groups 40G are arranged so as to intersect (substantially orthogonally) with each other in a plan view. As a result, in a plan view, a plurality of unreinforced regions 50 surrounded by a plurality of vertical muscle groups 30G and a plurality of horizontal muscle groups 40G are formed.

The plurality of unreinforced regions 50 are formed in a rectangular shape in a plan view, and are arranged in the short side direction and the long side direction of the slab main body 22. Further, the plurality of unreinforced regions 50 are defined as regions in which a through hole 52 can be formed. These unreinforced regions 50 are reinforced by a plurality of oblique reinforcing bars 60A and 60B.

The vertical width (interval T) and horizontal width (gap D) of the unreinforced region 50 are, for example, 300 mm or less and three times or less the slab thickness of the slab main body 40. The vertical width and the horizontal width of the unreinforced region 50 may be the same or different.

(Diagonal reinforcement)
The plurality of diagonal reinforcing bars 60A and 60B are arranged diagonally with respect to the vertical bar 30 and the horizontal bar 40. In other words, the plurality of diagonal reinforcing bars 60A and 60B are arranged diagonally with respect to the short side direction and the long side direction of the slab main body 22.

Further, the plurality of diagonal reinforcing bars 60A and 60B are arranged or arranged over the end on the short side 22Y side and the end on the long side 22X side of the slab main body 22 while avoiding the plurality of unreinforced regions 50. Reinforcements are arranged over the opposite end on the long side 22X side. Further, the entire diagonal reinforcing bars 60A and 60B are embedded in the slab main body 22.

Both ends of the diagonal reinforcing bars 60A and 60B may be projected from the slab main body 22 without being embedded in the slab main body 22 as a whole. Further, the diagonal reinforcing bars 60A and 60B may be formed of a plurality of reinforcing bars connected via joints or the like.

The plurality of diagonal reinforcing bars 60A and 60B are arranged in a grid pattern in a plan view. More specifically, the slab main body 22 is provided with two types of diagonal reinforcing bars 60A and 60B that are inclined to the opposite sides of the vertical bar 30 (or the horizontal bar 40). As shown in FIG. 4, the oblique reinforcing bar 60A is tilted with respect to the vertical bar 30 at a predetermined angle θ1, and the diagonal reinforcing bar 60B is tilted with respect to the vertical bar 30 at a predetermined angle θ2.

As shown in FIG. 3, the two types of diagonal reinforcing bars 60A and 60B are arranged so as to intersect each other (in the present embodiment, substantially orthogonal to each other) in a plan view. A plurality of unreinforced regions 50 are surrounded by these oblique reinforcing bars 60A and 60B, respectively.

The predetermined angles (tilt angles) θ1 and θ2 of the reinforcing bars 60A and 60B are preferably 30 to 60 degrees, more preferably 45 degrees.

(Crack prevention muscle)
As shown in FIG. 3, a plurality of crack prevention bars 70 are arranged on the outer peripheral portion of the slab main body 22. The crack prevention bars 70 are provided at the ends of the slab main body 22 on the long side 22X side and the short side 22Y side, respectively.

The crack prevention bar 70 provided at the end of the slab body 22 on the long side 22X side and the crack prevention bar 70 provided at the end of the slab body 22 on the short side 22Y side have the same configuration. There is. Therefore, in the following, the configuration of the crack prevention bar 70 provided at the end of the slab main body 22 on the long side 22X side will be described, and the crack prevention bar 70 provided at the end of the slab main body 22 on the short side 22Y side will be described. The description of the configuration will be omitted as appropriate.

As shown in FIG. 4, the crack prevention bar 70 provided at the end of the slab main body 22 on the long side 22X side is formed by a reinforcing bar bent in a dogleg shape. The crack prevention bar 70 has a protruding portion 70A protruding from the slab main body 22 and a buried portion 70B embedded in the slab main body 22.

The protruding portion 70A protrudes from the central portion in the width direction of the unreinforced region 50 on the outer peripheral portion of the slab main body 22, and is arranged on the beam 14. Further, the protruding portion 70A is arranged substantially in parallel with the vertical streaks 30 (or the horizontal streaks 40). The protruding portion 70A is lap-joined with the protruding portion 70A of the crack prevention bar 70 of the other slab main body 22 on the beam 14. In this state, the adjacent slabs 20 and the beam 14 are joined to each other by placing concrete (not shown) on the beam 14.

Further, the protruding portion of the crack prevention bar 70 (see FIG. 3) provided at the end of the slab main body 22 on the short side 22Y side is attached to the slab main body of another slab (not shown) on the girder 12 (see FIG. 1). It is lap-jointed with the protruding portion of the crack prevention bar provided. In this state, by placing concrete (not shown) on the girder 12, the adjacent slabs 20 and the girder 12 are joined to each other.

The crack prevention bar 70 is not limited to the lap joint as described above. For example, the protrusion 70A is bent downward on the beam 14 or the beam 12, and the concrete placed on the beam 14 or the beam 12. It is also possible to fix it in.

As shown in FIG. 4, the buried portion 70B is bent with respect to the protruding portion 70A so as to avoid the central portion of the unreinforced region 50 and to follow the outer peripheral portion of the unreinforced region 50. As a result, the through hole 52 can be formed in the central portion of the unreinforced region 50. Further, the buried portion 70B is arranged substantially in parallel with the oblique reinforcing bars 60A and 60B. The crack prevention muscle 70 suppresses cracks in the outer peripheral portion of the slab main body 22.

(Reference point)
As shown in FIG. 2, the upper surface 22U of the slab main body 22 is provided with a plurality of (four in the present embodiment) reference points 24 that serve as a reference for the position of the unreinforced region 50. The reference point 24 is formed by, for example, a metal fitting (for example, a nut) embedded in the upper surface 22U of the slab main body 22. The position and range of the unreinforced region 50 can be specified by the distance from these reference points 24.

The reference point 24 can be provided on at least one of the upper surface 22U and the lower surface of the slab main body 22. Further, the number of reference points 24 may be at least two. Further, the reference point 24 can be omitted as appropriate.

(Action)
Next, the operation of this embodiment will be described.

As shown in FIG. 3, according to the slab 20 according to the present embodiment, a plurality of vertical streaks 30G and horizontal streaks 40G arranged in a grid pattern are embedded in the slab main body 22. Further, in the slab main body 22, a plurality of diagonal reinforcing bars 60A and 60B are embedded in a grid pattern and diagonally arranged with respect to the vertical bar group 30G and the horizontal bar group 40G. A plurality of unreinforced regions 50 are formed in the slab main body 22. Each muscleless region 50 is surrounded by a vertical muscle group 30G and a horizontal muscle group 40G, and is surrounded by diagonal reinforcing muscles 60A and 60B.

Here, the vertical bars 30, the horizontal bars 40, and the diagonal reinforcing bars 60A and 60B are not arranged in the non-reinforced region 50. Therefore, for example, after the construction of the slab 20, the through hole 52 can be formed in the unreinforced region 50 without cutting the vertical reinforcing bars 30, the horizontal reinforcing bars 40, and the diagonal reinforcing bars 60A and 60B. Therefore, a through hole can be easily formed in the slab main body 22.

Further, the non-reinforced region 50 is surrounded by a plurality of diagonal reinforcing bars 60A and 60B, and is reinforced by these diagonal reinforcing bars 60A and 60B. Therefore, when forming the through hole 52 in the unreinforced region 50, it is not necessary to bury a reinforcing bar or the like around the unreinforced region 50. Therefore, the through hole 52 can be more easily formed in the slab body.

Further, in the present embodiment, the slab main body 22 is formed by combining a plurality of vertical streaks 30G and horizontal streaks 40G arranged in a grid pattern and a plurality of diagonal reinforcing bars 60A and 60B arranged in a grid pattern. A plurality of unreinforced regions 50 capable of forming through holes 52 can be formed over a wide range of the above.

Further, a set of vertical muscle groups 30G or a set of horizontal muscle groups 40G are arranged between adjacent non-muscle regions 50. That is, a plurality of vertical streaks 30 or a plurality of horizontal streaks 40 are arranged between adjacent unreinforced regions 50. These vertical streaks 30 or horizontal streaks 40 reinforce the unreinforced region 50 with higher strength. As a result, a larger through hole 52 can be formed in the unreinforced region 50.

Further, as shown in FIG. 4, the unreinforced region 50 on the outer peripheral portion of the slab main body 22 is reinforced by the crack prevention bar 70. As a result, cracks in the outer peripheral portion of the slab main body 22 are suppressed.

Further, a plurality of reference points 24 are provided on the upper surface 22U of the slab main body 22. Each muscleless region 50 can be specified by the distance from these reference points 24. Thereby, for example, the through hole 52 can be easily formed in the slab main body 22 after the completion.

The strength of the unreinforced region 50 is ensured by setting the vertical width (interval T) and horizontal width (gap D) of the unreinforced region 50 to 300 mm or less and 3 times or less the slab thickness of the slab body 40. Can be done.

(Modification example)
Next, a modified example of the above embodiment will be described.

In the above embodiment, a plurality of vertical muscle groups 30G and a plurality of horizontal muscle groups 40G are arranged in a grid pattern, but the above embodiment is not limited to this. For example, a plurality of independent vertical streaks 30 and a plurality of horizontal streaks 40G may be arranged in a grid pattern, or a plurality of vertical streaks 30G and a plurality of independent horizontal streaks 40 may be arranged in a grid pattern. You may. Further, a plurality of independent vertical bars 30 and a plurality of independent horizontal bars 40 may be arranged in a grid pattern. That is, one or a plurality of vertical bars may be arranged, or one or a plurality of horizontal bars may be arranged between adjacent unreinforced regions.

Further, in the above embodiment, a plurality of diagonal reinforcing bars 60A and 60B are arranged in a grid pattern, but the above embodiment is not limited to this. For example, at least one of the diagonal reinforcements 60A and 60B may be a diagonal reinforcement group. That is, one or a plurality of diagonal reinforcing bars may be arranged between adjacent unreinforced regions.

Further, in the above embodiment, a plurality of unreinforced regions 50 are formed over substantially the entire surface of the slab main body 22, but the above embodiment is not limited to this. The plurality of unreinforced regions may be formed, for example, in a part (predetermined region) of the slab main body 22.

Although one embodiment of the present invention has been described above, the present invention is not limited to such an embodiment, and one embodiment and various modifications may be used in combination as appropriate. Of course, it can be carried out in various modes as long as it does not deviate.

20 Slab 22 Slab body 22U Top surface 24 Reference point 30 Vertical streaks 30G Vertical streaks (vertical streaks)
40 Lateral muscle 40G Lateral muscle group (horizontal muscle)
50 Unreinforced area 60A Diagonal reinforcement 60B Diagonal reinforcement

Claims (5)

With the slab body
A plurality of vertical and horizontal bars, which are arranged in a grid pattern and are embedded in the slab body,
A plurality of diagonal reinforcing bars that are lattice-shaped and are arranged diagonally with respect to the vertical bars and the horizontal bars and are embedded in the slab body.
With
In the slab body, a plurality of unreinforced regions surrounded by the vertical streaks and the horizontal streaks and surrounded by the diagonal reinforcing bars are formed.
Slab. One or more of the oblique reinforcing bars are arranged between the adjacent unreinforced regions.
The slab according to claim 1. A plurality of the vertical streaks or a plurality of the horizontal streaks are arranged between the adjacent unreinforced regions.
The slab according to claim 1 or 2. A plurality of reference points serving as a reference for the position of the unreinforced region are provided on the upper surface or the lower surface of the slab body.
The slab according to any one of claims 1 to 3. The vertical width and the horizontal width of the unreinforced region are 300 mm or less and three times or less the slab thickness of the slab body.
The slab according to any one of claims 1 to 4.

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