JPH11117232A - Reinforcing structure for floor board - Google Patents

Abstract

PROBLEM TO BE SOLVED: To sufficiently guarantee the strength of a floor board with excellent long- term reliability by arranging reinforcing beams in the perpendicular direction to girders over nearly the whole width of the lower face between the girders of the floor board, and fixing the end sections of the reinforcing beams with anchor bolts reaching the upper section than the neutral plane of the floor board. SOLUTION: Both ends of a floor board 10 are formed thicker than an intermediate section 11 as thick sections 12, and thickness slant sections 13 changed with thickness in sequence are formed between the intermediate section 11 and the thick sections 12. Girders 2 supporting the floor board 10 along the longitudinal direction of the floor board 10 are erected on the lower faces of the thick sections 12. Multiple reinforcing beams 3 are fitted to the lower face of the intermediate section 11 via reinforcing members 4 at prescribed intervals. The reinforcing beams 3 are arranged in the perpendicular direction to the girders 2 over nearly the whole width of the lower face of the intermediate section 11, and both ends of the reinforcing beams 3 are fitted to the lower face of the intermediate section 11 by fitting members 5 made of a T-shape steel. The size of a long anchor bolt 6 is set to reach an upper section than the stress neutral plane 14 of the floor board 10 from the lower face of the intermediate section 11.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reinforcing structure for reinforcing a concrete slab used for a highway or a building.

[0002]

2. Description of the Related Art Generally, on an elevated road or the like, FIG.
As shown in (a), a concrete floor slab 50 is supported by girders 51 at both ends. This floor slab 50 is
The intermediate portion 50a where the 2 etc. travels is formed of a concrete slab having a constant thickness, and the portions supported by the girders 51 at both ends are thickened portions 50b formed with a large thickness.
a between the middle part 50a and the thick part 5b.
The haunch portion 50c has a thickness gradually increasing in the 0b direction.

[0003] The floor slab 50 having the above-described structure always receives the load caused by the running of the heavy vehicle 52 or the like.
3 receives a compressive load on the upper side, and receives a tensile load on the lower side of the neutral surface 53. Therefore, when used for a long time, its strength is reduced, and a crack is formed in the extension direction of the haunch portion 50c.
There is a problem that stress fracture occurs. Therefore, as a countermeasure, a conventional reinforcing method is to inject an epoxy resin into the crack portion in advance, or
As shown in FIGS. 8B to 8C, a method of attaching a reinforcing material 54 to the lower surface of the intermediate portion 50a with an adhesive 55 has been performed.

[0004]

However, the above-mentioned conventional method of injecting an epoxy resin into a crack portion is as follows.
Although it could be injected into a large crack, it could not be injected into a small crack, and thus lacked reliability. In addition, there is a problem that the reinforcing strength after the repair merely returns to the design load at the time of installation, and cannot be reinforced beyond the initial design load. Also, as shown in FIG.
The method in which the reinforcing member 54 is attached only to the lower surface has a disadvantage that the end 54a of the reinforcing member 54 is easily peeled off, and if the end 54a is separated, the reinforcing effect at this portion is lost. Was. FIG. 8 (c)
As shown in FIG.
Even when is attached, a force for peeling off the bent portion 54b in the direction of arrow B is generated, and there is a possibility that the reinforcing effect at this portion may be lost. In the method of attaching the reinforcing member 54 to the lower surface of the intermediate portion 50a, the strength immediately after the reinforcing work is guaranteed, but the adhesive 5
5 deteriorated, and the reinforcing material 54 peeled off.

Further, since the reinforcing member 54 is a flat steel plate, the reinforcing work cannot be performed unless the lower surface of the intermediate portion 50a is flat. For example, the floor slab 50 is damaged and the intermediate portion 50a is damaged.
There is also a problem that the work cannot be performed when the lower surface of a is uneven. Furthermore, this method of attaching the reinforcing member 54 requires applying the adhesive 55 to the entire lower surface of the intermediate portion 50a, which requires a large amount of the adhesive 55 and takes time and effort to apply the adhesive. There was also a problem that it became high. This problem also occurs in a flat slab where no thick portion is formed on the slab 50. Therefore, if reinforcement work is performed when the lower surface of the intermediate portion 50a is not flat, it is necessary to fill a large amount of expensive epoxy resin into the gap between the uneven surface and the reinforcing member 54, which has increased the cost. Further, when a light and strong carbon fiber reinforced synthetic resin is used for the reinforcing member 54, it is adapted to large irregularities over the entire surface,
The peeling at the end was weak as in the case of the reinforcing member 54 of the steel plate. Furthermore, although an anchor bolt was sometimes used to prevent peeling at the end of the reinforcing member 54, the concrete was peeled off together with the concrete because it was relatively short.

The present invention has been made in view of such a situation. Therefore, a concrete slab with sufficient strength is ensured with sufficient strength and long-term reliability is excellent. provide.

[0007]

In order to achieve the above-mentioned object, the present invention relates to a floor slab made of a concrete slab having both ends supported by a spar, wherein the slab extends over substantially the entire lower surface between the slabs of the slab. A reinforcing beam is disposed in a direction perpendicular to the direction of the slab, and an end of the reinforcing beam is fixed by an anchor bolt reaching above a neutral surface of the floor slab. According to this configuration, the lower surface between the girders of the floor slab is reinforced by the reinforcing beams, and it is possible to prevent the girders of the floor slab from breaking. Further, an intermediate portion in which the thickness of the concrete slab is formed uniformly, a thick portion formed at both ends of the intermediate portion to be thicker than the intermediate portion and supported by a girder, and the intermediate portion and the thick portion In between, a thickness inclined portion formed so that the thickness changes sequentially,
In the concrete floor slab, a reinforcing beam is disposed in a direction orthogonal to the beam over substantially the entire width of the lower surface of the intermediate portion, and an end of the reinforcing beam reaches an upper portion than a neutral surface of the floor slab. It is characterized by being fixed by bolts. According to this configuration, the middle portion of the floor slab is reinforced by the reinforcing beam, and the middle portion of the thin slab can be prevented from being broken.

Further, a plurality of reinforcing members are provided between the floor slab and the reinforcing beams so as to extend over the plurality of reinforcing beams in the longitudinal direction of the floor slab. According to this configuration, the load applied to the floor slab can be distributed to the plurality of reinforcing beams via the reinforcing members. Further, the reinforcing member is made of an aluminum alloy and has a truss structure in cross section. According to this configuration, the reinforcing member can be a lightweight reinforcing member with improved strength. Further, between the floor slab and the reinforcing beam, the reinforcing member is attached to the reinforcing beam via a bracket,
The gap between the floor slab and the reinforcing beam can be adjusted by an elongated hole formed in a bracket. According to this configuration, even if the lower surface of the floor slab has irregularities, the height of the bracket can be adjusted in accordance with the irregularities, so that the floor slab can be supported by the reinforcing member without any gap.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing the reinforcing structure of the floor slab according to the present invention, FIG. 2 is a cross-sectional view showing the reinforcing structure of the floor slab of FIG.
3 is a cross-sectional view taken along line AA in FIG. 2, FIG. 4 is a cross-sectional view using a reinforcing member having a cross-sectional truss structure, and FIG. FIG. 6 is an exploded perspective view showing a bracket for attaching a reinforcing member.

In the floor slab reinforcement structure according to the present invention, as shown in FIG. 1, a concrete floor slab 10 forming an elevated road 1 is supported by steel beam girders 2 erected at predetermined intervals. It has a structure. In the floor slab 10, the intermediate portion 11 is formed of concrete having a predetermined thickness, and both ends thereof are thick portions 12, 12 formed thicker than the intermediate portion 11, and the intermediate portion 11 and the thick portions 12, 12 are formed. Between 12, there are thickness inclined portions 13, 13 whose thickness changes sequentially. And the thick part 1
On the lower surfaces of the slabs 2 and 12, a spar 2 supporting the slab 10 is provided upright along the longitudinal direction of the slab 10.

To reinforce the floor slab 10, a plurality of reinforcing beams 3 are attached to the lower surface of the intermediate portion 11 at predetermined intervals via reinforcing members 4. The reinforcing beam 3 is formed of an aluminum alloy and is disposed in a direction perpendicular to the beam 2 over substantially the entire width of the lower surface of the intermediate portion 11. Both ends of the reinforcing beam 3 are made of T-shaped steel. Are attached to the lower surface of the intermediate portion 11 by the attaching members 5 and 5. This mounting member 5
Is attached to a floor slab 10 with long anchor bolts 6 and short anchor bolts 7, as shown in FIG. The dimensions of the long anchor bolt 6 reach from the lower surface of the intermediate portion 11 to a position higher than the neutral surface 14 of the stress of the floor slab 10, and prevent the intermediate portion 11 from breaking along the breaking lines 15, 15 with stress. It is to prevent. Further, the short anchor bolts 7 are intended to reinforce the attachment of the attachment member 5 to the lower surface of the intermediate portion 11 and to temporarily fix them during reinforcement work.

The attachment of the long anchor bolt 6 is called a chemical anchor. As shown in FIG. 3, an insertion hole 16 is formed from the lower surface of the intermediate portion 11.
The insertion hole 16 is filled with an adhesive 17 and the anchor bolt 6 is inserted and fixed. Then, an insertion hole 5 a formed in the mounting member 5 of the T-shaped steel mold is inserted into the anchor bolt 6, and is fixed by the nut 8. Further, a reinforcing beam 3 of C-shaped channel steel is fixed to the mounting member 5 by a mounting bolt 9. With this structure, the reinforcing beam 3 is firmly fixed to the lower surface of the intermediate portion 11.

In this manner, the reinforcing beam 3 and the intermediate portion 11 attached to the lower surface of the intermediate portion 11 by the attaching member 5 are provided.
Between them, a reinforcing member 4 made of an aluminum alloy is attached across the plurality of reinforcing beams 3 in the longitudinal direction of the floor slab 10. The reinforcing member 4 may be made of a rectangular aluminum alloy material, but in order to reduce the weight and improve the strength,
A reinforcing member 20 having a truss structure in cross section as shown in FIG. 4 may be used. 5, the L-shaped bracket 21 is fixed to the reinforcing beam 3 attached to the lower surface of the intermediate portion 11 with mounting bolts 22. The reinforcing member 20 having the structure is attached with a plurality of tapping screws 23.

As shown in FIG. 6, the L-shaped bracket 21 has a bolt hole 21a formed in a vertically long hole so that the mounting height can be adjusted within the range of the long hole. I have. Even if the lower surface of the intermediate portion 11 has irregularities, the mounting height of the reinforcing member 20 can be adjusted according to the irregularities by the elongated bolt holes 21a. Therefore, even if the intermediate portion 11 is already distorted, necessary reinforcement is required. Construction becomes possible.

According to such a configuration, the anchor bolt 6 is inserted deeply and fixed until it reaches a position above the neutral surface 14 in the floor slab 10, so that the reinforcing beam 3 is interposed between the reinforcing members 4 and 20. Firmly fixed to the floor slab 10
Can be prevented from being broken by stress. Further, since the reinforcing members 4 and 20 straddle the plurality of reinforcing beams 3, the load on the floor slab 10 by the vehicle or the like is dispersed, and the floor slab 1
The load does not concentrate on a specific portion of the floor slab 0, and the life of the floor slab 10 can be extended. In addition, since the reinforcing beams 3 and the reinforcing members 4 and 20 are made of an aluminum alloy, they are light in weight and do not put an extra burden on the floor slab 10.

Further, in the embodiment of the present invention, the reinforcing structure of the floor slab 10 using the reinforcing members 4 and 20 for the floor slab 10 has been described, but if the lower surface of the intermediate portion 11 is flat without irregularities, It is not necessary to use the reinforcing members 4 and 20, and as shown in FIG.
The same effect can be obtained by attaching the device to the lower surface of the first device. Furthermore,
Although the floor slab 10 has been described as having the thick inclined portion 13, the intermediate portion 11 and the thick portions 12 at both ends do not have the thick inclined portion 13.
7 can be applied to a floor slab having only
As shown in (b), it is needless to say that the floor slab 10 can be applied to a flat slab having no thick portion 12. In any of the slabs, the anchor bolts 6 for fixing the reinforcing beams 3 are inserted above the neutral surface of the slab.

[0017]

As described above, the present invention relates to a floor slab made of a concrete slab whose both ends are supported by a girder, and the reinforcing girder extends in a direction orthogonal to the girder over substantially the entire lower surface between the girder of the floor slab. Since the reinforcing beam is fixed at the end of the reinforcing beam by an anchor bolt reaching above the neutral surface of the floor slab, the lower surface between the girders of the floor slab is strongly reinforced by the reinforcing beam. The destruction of the plate can be prevented. Further, an intermediate portion in which the thickness of the concrete slab is formed uniformly, a thick portion formed at both ends of the intermediate portion to be thicker than the intermediate portion and supported by a girder, and the intermediate portion and the thick portion In the concrete floor slab consisting of a thick-sloping portion formed so that the wall thickness changes sequentially, a reinforcing beam is disposed in a direction orthogonal to the beam over substantially the entire width of the lower surface of the intermediate portion. The ends of the reinforcing beams are fixed by anchor bolts reaching above the neutral surface of the floor slab, so that the lower surface of the middle portion, which is thin and weak in the floor slab, is reinforced by the reinforcing beams. Therefore, the destruction of the floor slab can be prevented, and since the reinforcing beams are merely fixed with the anchor bolts, the cost can be significantly reduced as compared with the conventional reinforcing work.

[0018] Further, a plurality of reinforcing members straddling a plurality of reinforcing beams in the longitudinal direction of the floor slab are interposed between the floor slab and the reinforcing beam, so that the intermediate member of the floor slab is provided. The load can be dispersed in the longitudinal direction of the floor slab by the plurality of reinforcing members, and a concentrated load that adversely affects the floor slab can be prevented. Further, since the reinforcing member is made of an aluminum alloy and has a truss structure in cross section, the reinforcing member can be reduced in weight and improved in strength. Further, the interval between the floor slab and the reinforcing beam is such that the reinforcing member is attached to the reinforcing beam via a bracket, and the interval between the floor slab and the reinforcing beam can be adjusted by a long hole formed in the bracket. Even if unevenness occurs on the lower surface of the floor slab, the floor slab can be supported by the reinforcing member in accordance with the unevenness, so that the best reinforcing structure can be obtained.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a reinforcing structure of a floor slab according to the present invention.

FIG. 2 is a sectional view showing a reinforcing structure of the floor slab of FIG.

FIG. 3 is a sectional view taken along line AA of FIG. 2;

FIG. 4 is a sectional view of a reinforcing structure of a floor slab using a reinforcing member having a sectional truss structure.

FIG. 5 is an enlarged cross-sectional view of a main part showing a mounting state of a reinforcing member of FIG. 4;

FIG. 6 is an exploded perspective view showing a bracket for attaching a reinforcing member.

FIG. 7A is a sectional view showing an embodiment of the present invention, and FIG.
FIG. 7 is a sectional view showing another embodiment.

8A and 8B are explanatory views of a conventional slab, in which FIG. 8A is a cross-sectional view showing a broken state of the slab, and FIGS. 8B and 8C are cross-sectional views showing reinforcement of the slab.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Elevated road 2 girder 3 Reinforcement beam 4 Reinforcement member 5 Mounting member 6 Anchor bolt 7 Anchor bolt 8 Nut 9 Mounting bolt 10 Floor slab 11 Intermediate part 12 Thick part 13 Thick inclined part 14 Neutral surface 15 Break line 16 Insertion hole 17 adhesive 20 reinforcing member 21 bracket 21a long hole 22 mounting bolt 23 tapping screw

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[Procedure amendment]

[Submission date] January 30, 1998

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of the Invention] Floor slab reinforcement structure

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reinforcing structure for reinforcing a concrete slab used for a highway or a building.

[0002]

2. Description of the Related Art Generally, on an elevated road or the like, FIG.
As shown in (a), a concrete floor slab 50 is supported by girders 51 at both ends. This floor slab 50 is
The intermediate portion 50a where the 2 etc. travels is formed of a concrete slab having a constant thickness, and the portions supported by the girders 51 at both ends are thickened portions 50b formed with a large thickness.
a between the middle part 50a and the thick part 5b.
The haunch portion 50c has a thickness gradually increasing in the 0b direction.

[0003] The floor slab 50 having the above-described structure always receives the load caused by the running of the heavy vehicle 52 or the like.
3 receives a compressive load on the upper side and a tensile load on the lower side of the neutral surface 53. Therefore, when used for a long period of time, its strength is reduced and a crack is formed in the extension direction of the haunch portion 50c.
There is a problem that stress fracture occurs. Therefore, as a countermeasure, a conventional reinforcing method is to inject an epoxy resin into the crack portion in advance, or
As shown in FIGS. 8B to 8C, a method of attaching a reinforcing material 54 to the lower surface of the intermediate portion 50a with an adhesive 55 has been performed.

[0004]

However, the above-mentioned conventional method of injecting an epoxy resin into a crack portion is as follows.
Although it could be injected into a large crack, it could not be injected into a small crack, and thus lacked reliability. In addition, there is a problem that the reinforcing strength after the repair merely returns to the design load at the time of installation, and cannot be reinforced beyond the initial design load. Also, as shown in FIG.
The method in which the reinforcing material 54 is attached only to the lower surface has a disadvantage that the end 54a of the reinforcing material 54 is easily peeled off. If the end 54a is peeled off, the reinforcing effect at this portion is lost. Was. FIG. 8 (c)
As shown in FIG.
Even when is attached, a force for peeling off the bent portion 54b in the direction of arrow B is generated, and there is a possibility that the reinforcing effect at this portion may be lost. In the method of attaching the reinforcing member 54 to the lower surface of the intermediate portion 50a, the strength immediately after the reinforcing work is guaranteed, but the adhesive 5
5 deteriorated, and the reinforcing material 54 peeled off.

Further, since the reinforcing member 54 is a flat steel plate, the reinforcing work cannot be performed unless the lower surface of the intermediate portion 50a is flat. For example, the floor slab 50 is damaged and the intermediate portion 50a is damaged.
There is also a problem that the work cannot be performed when the lower surface of a is uneven. Furthermore, this method of attaching the reinforcing member 54 requires applying the adhesive 55 to the entire lower surface of the intermediate portion 50a, which requires a large amount of the adhesive 55 and takes time and effort to apply the adhesive. There was also a problem that it became high. This problem also occurs in a flat slab where no thick portion is formed on the slab 50. Therefore, if reinforcement work is performed when the lower surface of the intermediate portion 50a is not flat, it is necessary to fill a large amount of expensive epoxy resin into the gap between the uneven surface and the reinforcing member 54, which has increased the cost. Further, when a light and strong carbon fiber reinforced synthetic resin is used for the reinforcing member 54, it is adapted to large irregularities over the entire surface,
The peeling at the end was weak as in the case of the reinforcing member 54 of the steel plate. Furthermore, although an anchor bolt was sometimes used to prevent peeling at the end of the reinforcing member 54, the concrete was peeled off together with the concrete because it was relatively short.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has a concrete floor slab that has sufficient strength to ensure long-term reliability and that is inexpensive for reinforcement work. I will provide a.

[0007]

In order to achieve the above-mentioned object, the present invention relates to a floor slab made of a concrete slab having both ends supported by a spar, wherein the slab extends over substantially the entire lower surface between the slabs of the slab. A reinforcing beam is disposed in a direction perpendicular to the direction of the slab, and an end of the reinforcing beam is fixed by an anchor bolt reaching above a neutral surface of the floor slab. According to this configuration, the lower surface between the girders of the floor slab is reinforced by the reinforcing beams, and it is possible to prevent the girders of the floor slab from breaking. Further, an intermediate portion in which the thickness of the concrete slab is uniformly formed, a thick portion formed at both ends of the intermediate portion to be thicker than the intermediate portion and supported by a girder, and the intermediate portion and the thick portion. In the concrete floor slab consisting of a thick-sloping portion formed so that the wall thickness changes sequentially, a reinforcing beam is disposed in a direction orthogonal to the beam over substantially the entire width of the lower surface of the intermediate portion. An end of the reinforcing beam is fixed by an anchor bolt reaching above a neutral surface of the floor slab. According to this configuration, the middle portion of the floor slab is reinforced by the reinforcing beam, and the middle portion of the thin slab can be prevented from being broken.

Further, a plurality of reinforcing members are provided between the floor slab and the reinforcing beams so as to extend over the plurality of reinforcing beams in the longitudinal direction of the floor slab. According to this configuration, the load applied to the floor slab can be distributed to the plurality of reinforcing beams via the reinforcing members. Further, the reinforcing member is made of an aluminum alloy and has a truss structure in cross section. According to this configuration, the reinforcing member can be a lightweight reinforcing member with improved strength. Further, between the floor slab and the reinforcing beam, the reinforcing member is attached to the reinforcing beam via a bracket,
The gap between the floor slab and the reinforcing beam can be adjusted by an elongated hole formed in a bracket. According to this configuration, even if the lower surface of the floor slab has irregularities, the height of the bracket can be adjusted in accordance with the irregularities, so that the floor slab can be supported by the reinforcing member without any gap.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing the reinforcing structure of the floor slab according to the present invention, FIG. 2 is a cross-sectional view showing the reinforcing structure of the floor slab of FIG.
3 is a cross-sectional view taken along the line AA of FIG. 2, FIG. 4 is a cross-sectional view using a reinforcing member having a cross-sectional truss structure, and FIG. FIG. 6 is an exploded perspective view showing a bracket for attaching a reinforcing member.

As shown in FIG. 1, the reinforcing structure of a floor slab according to the present invention is such that concrete floor slabs 10 forming an elevated road 1 are connected to steel beams 2 and 2 erected at predetermined intervals. It has a structure that can be supported. This floor slab 10 has an intermediate portion 11
Are formed of concrete having a predetermined thickness, and both ends thereof become thicker portions 12 and 12 formed thicker than the intermediate portion 11, and the thickness changes between the intermediate portion 11 and the thicker portions 12 and 12 sequentially. Thickness inclined portions 13, 13. And, on the lower surface of the thick portions 12, 12, the girders 2, 2 which support the floor slab 10 along the longitudinal direction of the floor slab 10, are erected.

To reinforce the floor slab 10, a plurality of reinforcing beams 3 are attached to the lower surface of the intermediate portion 11 at predetermined intervals via reinforcing members 4. The reinforcing beam 3 is made of an aluminum alloy material, and is disposed in a direction perpendicular to the beams 2 over substantially the entire width of the lower surface of the intermediate portion 11. Both ends of the reinforcing beam 3 are T-shaped. It is attached to the lower surface of the intermediate portion 11 by the attachment members 5 and 5 made of a mold steel. The attachment members 5 and 5 are attached to the floor slab 10 by long anchor bolts 6 and 6 and short anchor bolts 7 and 7, as shown in FIG. The dimensions of the long anchor bolts 6, 6 extend from the lower surface of the intermediate portion 11 to the upper portion of the neutral surface 14 of the stress of the floor slab 10, and
1 prevents stress fracture along the breaking lines 15, 15. Further, the short anchor bolts 7, 7 are intended to reinforce the attachment of the attachment members 5, 5 to the lower surface of the intermediate portion 11 and to temporarily fix them during reinforcement work.

The attachment of the long anchor bolts 6, 6 is called a chemical anchor, and as shown in FIG.
The holes 17 are filled with adhesives 17 and the anchor bolts 6 are inserted and fixed. And to these anchor bolts 6,6,
An insertion hole 5a formed in the mounting member 5 of the T-shaped mold steel,
5a is inserted and fixed by nuts 8,8. Further, a reinforcing beam 3 of C-shaped channel steel is fixed to the mounting member 5 by a mounting bolt 9. With this structure, the reinforcing beam 3 is firmly fixed to the lower surface of the intermediate portion 11.

In this manner, the reinforcing beam 3 and the intermediate portion 11 attached to the lower surface of the intermediate portion 11 by the attaching member 5 are provided.
Between them, a reinforcing member 4 made of an aluminum alloy is attached across the plurality of reinforcing beams 3 in the longitudinal direction of the floor slab 10. This reinforcing member 4 may use a rectangular aluminum alloy material, but in order to reduce the weight and improve the strength,
The cross-section as shown in FIG.
0,... May be used. The reinforcing members 20, 2
.. Are attached to the middle part 1 as shown in FIG.
An L-shaped bracket 21 is fixed to the reinforcing beam 3 attached to the lower surface of the bracket 1 with mounting bolts 22.
1, a reinforcing member 20 having a truss structure in cross section is attached by a plurality of tapping screws 23, 23,.

As shown in FIG. 6, the L-shaped bracket 21 has a bolt hole 21a formed in a vertically long hole so that the mounting height can be adjusted within the range of the long hole. I have. Even if the lower surface of the intermediate portion 11 has irregularities, the mounting height of the reinforcing member 20 can be adjusted according to the irregularities by the elongated bolt holes 21a. Therefore, even if the intermediate portion 11 is already distorted, necessary reinforcement is required. Construction becomes possible.

According to such a configuration, the anchor bolt 6 is inserted deeply and fixed until it reaches a position above the neutral surface 14 in the floor slab 10, so that the reinforcing beam 3 is interposed between the reinforcing members 4 and 20. Firmly fixed to the floor slab 10
Can be prevented from being broken by stress. Further, since the reinforcing members 4 and 20 straddle the plurality of reinforcing beams 3, the load on the floor slab 10 by the vehicle or the like is dispersed, and the floor slab 1
The load does not concentrate on a specific portion of the floor slab 0, and the life of the floor slab 10 can be extended. In addition, since the reinforcing beams 3 and the reinforcing members 4 and 20 are made of an aluminum alloy, they are light in weight and do not put an extra burden on the floor slab 10.

Further, in the embodiment of the present invention, the reinforcing structure of the floor slab 10 using the reinforcing members 4 and 20 for the floor slab 10 has been described, but if the lower surface of the intermediate portion 11 is flat without irregularities, It is not necessary to use the reinforcing members 4 and 20, and as shown in FIG.
The same effect can be obtained by attaching the device to the lower surface of the first device. Furthermore,
Although the floor slab 10 has been described as having the thick inclined portion 13, the intermediate portion 11 and the thick portions 12 at both ends do not have the thick inclined portion 13.
7 can be applied to a floor slab having only
As shown in (b), it is needless to say that the floor slab 10 can be applied to a flat slab having no thick portion 12. In any of the slabs, the anchor bolts 6 for fixing the reinforcing beams 3 are inserted above the neutral surface of the slab.

[0017]

As described above, the present invention relates to a floor slab made of a concrete slab whose both ends are supported by a girder, and the reinforcing girder extends in a direction orthogonal to the girder over substantially the entire lower surface between the girder of the floor slab. Since the reinforcing beam is fixed at the end of the reinforcing beam by an anchor bolt reaching above the neutral surface of the floor slab, the lower surface between the girders of the floor slab is strongly reinforced by the reinforcing beam. The destruction of the plate can be prevented. Further, an intermediate portion in which the thickness of the concrete slab is uniformly formed, a thick portion formed at both ends of the intermediate portion to be thicker than the intermediate portion and supported by a girder, and the intermediate portion and the thick portion. In the concrete floor slab consisting of a thick-sloping portion formed so that the wall thickness changes sequentially, a reinforcing beam is disposed in a direction orthogonal to the beam over substantially the entire width of the lower surface of the intermediate portion. The end of the reinforcing beam is anchored by an anchor bolt reaching above the neutral surface of the floor slab, so that the lower surface of the middle portion of the floor slab which is thin and has low strength is reinforced by the reinforcing beam. As a result, the floor slab can be prevented from being destroyed, and the reinforcement beams can be simply fixed with anchor bolts, so that the cost can be significantly reduced as compared with the conventional reinforcement work.

[0018] Further, a plurality of reinforcing members straddling a plurality of reinforcing beams in the longitudinal direction of the floor slab are interposed between the floor slab and the reinforcing beam, so that the intermediate member of the floor slab is provided. The load can be dispersed in the longitudinal direction of the floor slab by the plurality of reinforcing members, and a concentrated load that adversely affects the floor slab can be prevented. Further, since the reinforcing member is made of an aluminum alloy and has a truss structure in cross section, the reinforcing member can be reduced in weight and improved in strength. Further, the interval between the floor slab and the reinforcing beam is such that the reinforcing member is attached to the reinforcing beam via a bracket, and the interval between the floor slab and the reinforcing beam can be adjusted by a long hole formed in the bracket. Even if unevenness occurs on the lower surface of the floor slab, the floor slab can be supported by the reinforcing member in accordance with the unevenness, so that the best reinforcing structure can be obtained.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a reinforcing structure of a floor slab according to the present invention.

FIG. 2 is a sectional view showing a reinforcing structure of the floor slab of FIG.

FIG. 3 is a sectional view taken along line AA of FIG. 2;

FIG. 4 is a sectional view of a reinforcing structure of a floor slab using a reinforcing member having a sectional truss structure.

FIG. 5 is an enlarged cross-sectional view of a main part showing a mounting state of a reinforcing member of FIG. 4;

FIG. 6 is an exploded perspective view showing a bracket for attaching a reinforcing member.

FIG. 7A is a sectional view showing an embodiment of the present invention, and FIG.
FIG. 7 is a sectional view showing another embodiment.

8A and 8B are explanatory views of a conventional slab, in which FIG. 8A is a cross-sectional view showing a broken state of the slab, and FIGS. 8B and 8C are cross-sectional views showing reinforcement of the slab.

[Description of Signs] 1 elevated road 2 girder 3 reinforcing beam 4 reinforcing member 5 mounting member 6 anchor bolt 7 anchor bolt 8 nut 9 mounting bolt 10 floor slab 11 intermediate portion 12 thick portion 13 thick inclined portion 14 neutral surface 15 Breaking line 16 Insertion hole 17 Adhesive 20 Reinforcing member 21 Bracket 21a Long hole 22 Mounting bolt 23 Tapping screw

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Kazuo Hashimoto 3-21-18 Igusa, Suginami-ku, Tokyo Inside EEN

Claims (5)

[Claims] 1. A floor slab made of a concrete slab whose both ends are supported by a girder, wherein a reinforcing beam is arranged in a direction orthogonal to the girder over substantially the entire width of a lower surface between the girder of the floor slab. The reinforcement structure of the floor slab, wherein the part is fixed by anchor bolts reaching above the neutral surface of the floor slab. 2. An intermediate portion having a uniform thickness of the concrete slab, a thick portion formed at both ends of the intermediate portion to be thicker than the intermediate portion, and supported by a girder; Between the section and the wall of the concrete floor slab, the thickness of which is formed so that the wall thickness is sequentially changed.In the concrete slab, a reinforcing beam is provided in a direction orthogonal to the beam over substantially the entire width of the lower surface of the intermediate section. The reinforcing structure of a floor slab, wherein an end of the reinforcing beam is disposed and fixed by an anchor bolt reaching above a neutral surface of the floor slab. 3. A plurality of reinforcing members spanning a plurality of reinforcing beams in a longitudinal direction of the slab, between the slab and the reinforcing beams. Item 3. A slab reinforcement structure according to Item 2. 4. The floor slab reinforcement structure according to claim 3, wherein the reinforcement member is made of an aluminum alloy and has a truss structure in cross section. 5. A space between the floor slab and the reinforcing beam, wherein the reinforcing member is attached to the reinforcing beam via a bracket, and a gap between the floor slab and the reinforcing beam can be adjusted by an elongated hole formed in the bracket. The reinforcing structure for a floor slab according to any one of claims 3 and 4, wherein the reinforcing structure is provided.