JP2001336116A - Reinforcing structure of floor slab - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the reinforcing structure of a floor slab capable of stably and surely supporting the floor slab and superior in construction. SOLUTION: The reinforcing structure S is provided with a main girder 1 provided on the lower face of a concrete floor slab C, a lateral girder 2 connecting both the ends on the main girder 1, and a plurality of support parts 3 provided between the concrete floor slab C and the lateral girder 2. In the case that the reinforcing structure S is constructed, since each member is a divided constitution, efficient working can be performed even during transport or during installation in a narrow place. In addition, since the support part 3 can be easily installed at an arbitrary position, a reinforcing place can be set in response to the deterioration state of the floor slab C. Thus, since excessive reinforcement can be performed, the improvement of workability and the reduction of a cost can be realized.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a slab reinforcement structure such as a reinforced concrete slab.

[0002]

2. Description of the Related Art Reinforced concrete slabs forming bridges and the like may become aging due to long-term use and cracks may occur inside the slabs. Therefore, it is necessary to reinforce the slabs.

Conventionally, when reinforcing an aging slab, a plurality of main girders are provided below the slab at predetermined intervals so as to extend in the bridge axis direction, and And a steel plate which is adhered to the lower surface of the steel sheet with an adhesive or the like and is disposed so as to extend in the bridge axis direction. However, in such a reinforcing structure, there is a possibility that the steel plate is peeled off along with the deterioration of the floor slab. In order to solve this problem, for example, there is a reinforcing structure disclosed in JP-A-06-101212. This is because the steel plate abuts on a flat part except the haunch part directly supported by the main girder on the lower surface of the reinforced concrete floor slab, and this steel plate is supported by a reinforcing cross girder connected via a bracket between the main girder and the upper surface of the bracket It has a structure in which a notch is formed on the upper surface of both ends of the reinforcing cross beam to form a gap with the haunch portion.

[0004]

SUMMARY OF THE INVENTION
The entire flat part of the reinforced concrete floor slab, excluding the haunch part,
Since the main girder is supported via the steel plate and the reinforcing cross girder, even if the reinforced concrete slab is deteriorated and cracks occur, the reinforced concrete slab does not fall off or sink, which is effective. However, each member used for this reinforcing structure is large and workability under a narrow floor slab was poor. Furthermore, there are many welding points and bolting points, and workability was poor from such a viewpoint.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a slab reinforcement structure which can stably and reliably support a slab and has good workability. .

[0006]

In order to solve the above-mentioned problems, a reinforcing structure for a floor slab according to the present invention is characterized in that a reinforcing member for a floor slab is provided between main slabs installed at predetermined intervals on a lower surface of the floor slab. A horizontal girder, which is disposed apart from each other and has both ends connected to the main girder, and an upper end connected to the floor slab and a lower end connected to the horizontal girder to support the floor slab, And a plurality of support portions whose distance can be adjusted.

[0007] According to the present invention, the floor slab is stably supported and reliably reinforced by the plurality of support portions provided between the floor slab and the cross beam. At this time, the support portion may be installed at an arbitrary position between the floor slab and the cross beam, so that the workability is good. Each member such as the main girder, the cross girder, and the support portion is configured to be separable, so that the work can be efficiently performed even during transportation or installation in a narrow place such as under a floor slab. In addition, since the installation position of the support portion can be set to an arbitrary position between the floor slab and the cross beam, for example, when the deterioration of the floor slab is not progressing, the number of installation portions of the support portion is reduced, On the other hand, if the deterioration has progressed, it is sufficient to increase the number of places where the support portions are installed. As described above, the reinforcing portion can be easily set in accordance with the deterioration state, so that excessive reinforcement is not performed. Therefore, workability at the time of construction can be improved, and cost can be reduced. In addition, since the distance between the upper end connected to the floor slab and the lower end connected to the cross beam is adjustable, the force (stretching force) on the floor slab can be adjusted. Therefore, the tension force can be arbitrarily set according to the load received by the floor slab, and stable reinforcement can be realized. Further, the reinforcing structure of the floor slab of the present invention is a structure which may be installed between the existing main girders which are installed at predetermined intervals on the lower surface of the floor slab, and can achieve good workability.

Since the main girder and the horizontal girder are connected via the link mechanism, even if the floor slab is bent, the bent part can be absorbed by the action of the link mechanism. Therefore, stress concentration acting on the floor slab and the reinforcing structure itself can be reduced, so that cracks and the like in the floor slab can be prevented, and deterioration of the reinforcing structure can be prevented.

By providing a support plate having an area larger than the plane section of the support portion between the support portion and the floor slab, the floor slab can be supported more stably. Then, by arbitrarily setting the installation position and size of the support plate according to the location of crack occurrence and the degree of deterioration, the stability of reinforcement is further improved.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a reinforcing structure of a floor slab according to the present invention will be described with reference to the drawings. FIG. 1 is a front view for explaining an embodiment of a floor slab reinforcement structure of the present invention, and FIG. 2 is a plan view of FIG. 1 as viewed from above. Further, the reinforcing structure of the floor slab in the present embodiment is for reinforcing a bridge provided with the reinforced concrete floor slab C, and is installed below the concrete floor slab C.

In FIGS. 1 and 2, the reinforcing structure S extends in the Y direction at a predetermined angle (X direction) perpendicular to the bridge axis direction (Y direction) on the lower surface of the concrete floor slab C. (Two in the figure), a cross girder 2 arranged between the main girder 1 so as to extend in the X direction, and a girder between the concrete floor slab C and the cross girder 2 And a plurality of support portions 3 formed. The cross beams 2 are arranged apart from the concrete floor slab C, and both ends thereof are connected to the upper ends of the respective main beams 1 via link mechanisms 4.

In the drawing, a main girder 1 installed so as to extend in the Y direction is formed to have an I-shaped cross section, and a plurality of main girders 1 are provided at predetermined intervals in the X direction. The upper end of the main girder 1 supports the lower surface of the concrete floor slab C. In addition,
The main girder 1 can be an existing one that has been installed in advance, and a new main girder can be installed if necessary.

Link mechanism 4 for connecting main girder 1 and horizontal girder 2
A first hinge portion 6 for rotatably connecting the connecting shaft 5, an end of the cross beam 2 and one end of the connecting shaft 5 by a pin, a second hinge portion of the connecting shaft 5 and a plate portion 1 a of the main beam 1. And a second hinge portion 7 that rotatably connects the two with a pin. The cross beam 2 is separated from the lower surface of the concrete slab C by being connected to the main beam 1 via the link mechanism 4.

A plurality of support portions 3 installed between the concrete floor slab C and the cross beam 2 are connected at their upper ends to the lower surface of the concrete slab C via support plates 3a, while their lower ends are connected to the substrate 3b. And is connected to the upper surface of the cross beam 2 via. Therefore, the concrete floor plate C is supported by the surfaces of the plurality of support plates 3a. The support part 3 is constituted by a turnbuckle. That is, a right-hand screw is provided at the upper end (or lower end), and a left-handed screw is provided at the lower end (or upper end), and the distance between the upper end and the lower end can be adjusted by rotating. Therefore, the upper end of the support portion 3 formed of the turnbuckle is connected to the concrete floor plate C and the lower end thereof is connected to the cross beam 2, and by rotating the support portion 3, the lower surface side of the concrete floor slab C is formed. A predetermined force (stretching force) according to the rotation can be applied.

The location and number of the support portions 3 between the concrete floor slab C and the cross beam 2 can be arbitrarily set. That is, both ends of the support portion 3 are fixed to the concrete floor slab C and the cross beam 2 via the support plate 3a and the substrate 3b, respectively. It may be installed and fixed.
Similarly, the installation position of the support plate 3a can be set arbitrarily. In addition, in this embodiment, the support part 3 is
It is installed in the upper two places.

The upper end of the support 3 and the support plate 3a are connected via a hinge 3c by pin connection. on the other hand,
The lower end of the support part 3 and the board 3b are connected via a hinge part 3d by pin connection. Therefore, the rotation of the first and second hinge portions 6 and 7 of the link mechanism 4 is not prevented.

As shown in FIG. 2, the main girder 1 has a link mechanism 4
Are connected at a plurality of places with a predetermined interval in the Y direction. Also, a plurality of support portions 3 are provided at predetermined positions on each of the cross beams 2.

The support plate 3a has a belt-like shape extending in the Y direction while abutting on the lower surface of the concrete floor slab C.
It is supported by a plurality of support parts 3 arranged in the Y direction. The support plate 3 a has an area larger than the cross-sectional area of the upper end of the support 3. Therefore, the concrete floor slab C can be supported with a wide contact area.

When reinforcing the concrete floor slab C of the bridge by the reinforcing structure S having the above-described structure, the cross beam 2 is linked to the existing main beam 1 provided at a predetermined position in advance. 4 and connected. And
The support part 3 is installed at a predetermined position on the cross beam 2. At the same time, the support plate 3 is placed between the concrete slab C and the support portion 3.
a is arranged. At this time, the support portion 3 formed of a turnbuckle is rotated to adjust the tension (pressing force) of the support portion 3 against the lower surface of the concrete floor slab C. At this time, the strength of the tension force acting on the concrete floor slab C can be arbitrarily set by rotating the support portion 3 formed of a turnbuckle a predetermined number of times.

The location of the support portion 3 can be set arbitrarily according to the position of the crack or the deterioration of the concrete floor slab C. Specifically, the support 3 may be provided near the crack or the deteriorated position. In addition, if the number of cracks and deterioration positions is small, the number of the support portions 3 to be installed can be set correspondingly small. On the other hand, if the deterioration has progressed, the setting location and the number of the supporting portions 3 are set accordingly. The support portion 3 includes a support plate 3a and a substrate 3 between the concrete floor slab C and the cross beam 2.
Since it is a configuration that can be easily installed via b, the installation location can be arbitrarily selected.

When the concrete floor slab C is bent after the reinforcing structure S is installed, the reinforcing structure S follows the bending by the action of the link mechanism 4. Accordingly, the support for the concrete slab C is stabilized, and the concentration of stress acting on the concrete slab C can be reduced. At this time, since the operation of the link mechanism 4 is not hindered by the hinge portions 3c and 3d provided on the support portion 3, stress concentration does not act on the reinforcing structure S itself.

As described above, the concrete slab C
And a plurality of support portions 3 provided between the cross beam 2 and
The concrete floor slab C can be reliably reinforced.
At this time, the support portion 3 can be easily installed at an arbitrary position between the concrete floor slab C and the cross beam 2, so that the workability is good. Each member such as the cross beam 2 and the support portion 3 is configured to be constructed at the construction site in a divided state, so that the work can be efficiently performed even during transportation or installation in a narrow place.

Further, since the installation position of the support portion 3 can be set at an arbitrary position between the concrete floor slab C and the cross beam 2, for example, when the deterioration of the concrete slab C is small, the support portion 3 is provided. May be reduced, and if the deterioration is progressing, the number of the mounting portions of the support portion 3 may be increased. Or you may make it provide the support part 3 intensively in the part which has deteriorated. As described above, the reinforcing portion can be easily set in accordance with the deterioration state, so that excessive reinforcement is not performed. Therefore, workability at the time of construction can be improved, and cost can be reduced.

The support portion 3 is formed by a turnbuckle, and the tension force on the concrete floor slab C can be adjusted. Therefore, the tension force can be arbitrarily set according to the load received on the concrete floor slab C. it can. Therefore, the concrete floor slab C can be reliably and stably reinforced.

Even if the distance between the concrete slab C and the cross beam 2 differs depending on the location due to the warp of the cross beam 2 or uneven thickness of the concrete slab C, the concrete slab C and the cross beam 2 can be used. Since the distance between the upper end and the lower end of the supporting portion 3 can be adjusted, the supporting portion 3 can be stably installed at an arbitrary position between the concrete floor slab C and the cross beam 2. In other words, the support portion 3 is configured by a turnbuckle capable of adjusting the distance between the upper and lower ends, so that the support portion 3 can easily cope with site construction errors. Therefore, workability can be improved.

Since the main girder 1 and the horizontal girder 2 are connected via the link mechanism 4, even if the concrete floor slab C bends, the amount of the bending can be absorbed by the action of the link mechanism 4. it can. Therefore, the concentration of stress acting on the concrete floor slab C can be reduced, so that the occurrence of cracks or the like in the concrete floor slab C can be prevented. Further, since the operation of the link mechanism 4 is not hindered by the action of the hinge portions 3c and 3d of the support portion 3, it is possible to stably absorb the deflection of the concrete floor slab C and to concentrate the stress on the reinforcing structure S itself. Thus, stable support for the concrete floor slab C can be realized. Further, the reinforcing structure S
Is a structure which may be installed between the existing main girders installed at predetermined intervals on the lower surface of the floor slab, and can achieve good workability.

By providing a support plate 3a having a larger contact area between the support section 3 and the lower surface of the concrete slab C than the plane section of the upper end of the support section 3 with respect to the concrete slab C, the concrete slab is provided. C can be more stably supported. Then, by arbitrarily setting the installation position and the size of the support plate 3a according to the location of the crack and the degree of deterioration, the stability of reinforcement is further improved. That is, for example, when the range of deterioration of the concrete floor slab C is wide,
A support plate 3a having a large area may be used. Alternatively, when the cracks are generated obliquely in the plane direction, the support plate 3a may be disposed so as to extend diagonally. As described above, the installation position, the installation direction, the size, and the like of the support plate 3a may be arbitrarily set according to the cracked portion or the deteriorated portion of the concrete floor slab C.

[0028] Since it is a configuration using existing mold steels and devices such as I-beams and turnbuckles, it can be manufactured at low cost and cost can be reduced.

In the present embodiment, the support portion 3 is described as being constituted by a turnbuckle, but a journal jack, a hydraulic jack, or the like may be used. That is, any configuration may be used as long as the distance between both ends can be adjusted and the pressing force (stretching force) on the concrete slab C can be set arbitrarily.

[0030]

The reinforcing structure for a floor slab according to the present invention has the following effects. The floor slab is stably supported and reliably reinforced by the plurality of support portions provided between the floor slab and the cross beam. At this time, the support portion may be installed at an arbitrary position between the floor slab and the cross beam, so that the workability is good. Each member such as the main girder, the cross girder, and the support portion is configured to be separable, so that the work can be efficiently performed even during transportation or installation in a narrow place such as under a floor slab. In addition, since the installation position of the support portion can be set to an arbitrary position between the floor slab and the cross beam, for example, when the deterioration of the floor slab is not progressing, the number of installation portions of the support portion is reduced, On the other hand, if the deterioration has progressed, it is sufficient to increase the number of places where the support portions are installed. As described above, the reinforcing portion can be easily set in accordance with the deterioration state, so that excessive reinforcement is not performed. Therefore, workability at the time of construction can be improved, and cost can be reduced.

The distance between the upper end connected to the floor slab and the lower end connected to the cross beam is adjustable.
The force (stretching force) on the floor slab can be adjusted. Therefore, the tension force can be arbitrarily set according to the load received by the floor slab, and stable reinforcement can be realized.

The reinforcing structure of the floor slab according to the present invention is a structure which can be installed between the existing main girders which are installed at a predetermined interval on the lower surface of the floor slab, and can realize good workability. .

Since the main girder and the horizontal girder are connected via the link mechanism, even if the floor slab is bent, the bent part can be absorbed by the action of the link mechanism. Therefore, stress concentration acting on the floor slab and the reinforcing structure itself can be reduced, so that cracks and the like in the floor slab can be prevented, and deterioration of the reinforcing structure can be prevented.

By providing a support plate having an area larger than the plane section of the support between the support and the floor slab, the floor slab can be more stably supported. Then, by arbitrarily setting the installation position and size of the support plate according to the location of crack occurrence and the degree of deterioration, the stability of reinforcement is further improved.

[Brief description of the drawings]

FIG. 1 is a front view for explaining an embodiment of a floor slab reinforcement structure of the present invention.

FIG. 2 is a plan view of FIG. 1 as viewed from above.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Main girder 2 Cross girder 3 Support part 3a Support plate 3b Substrate 4 Link mechanism 5 Connecting shaft 6 First hinge part 7 Second hinge part C (Concrete) Floor slab S Reinforcement structure

 ────────────────────────────────────────────────── ─── Continuing from the front page (72) Inventor Takayuki Nishichi 1-19-10 Mori, Koto-ku, Tokyo 1-19-10 Ishikawajima-Harima Heavy Industries, Ltd. Koto Office F-term (reference) 2D059 AA14 GG40 2E176 AA03 BB29

Claims (3)

[Claims] 1. A horizontal girder, which is spaced apart from said floor slab between main girder installed at predetermined intervals on a lower surface of the floor slab, and both ends of which are connected to the main girder; A reinforcing structure for a floor slab, comprising: a plurality of support portions connected to a floor slab and a lower end connected to the cross beam to support the floor slab and capable of adjusting a distance between the upper end and the lower end. . 2. The slab reinforcement structure according to claim 1, wherein the main girder and the cross girder are connected via a link mechanism. 3. The slab reinforcing structure according to claim 1, further comprising a support plate between the support portion and the floor slab, the support plate having an area larger than a plane cross section of the support portion. The floor slab reinforcement structure.