JP2019019590A - Reinforcement method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique capable of using a reinforcing bar embedded in one side of a concrete layer as a reinforcing material for reinforcing the reinforcing bar from the other side opposite to the one side. SOLUTION: Reinforcing bars 4a buried on the first surface 3a side of the first surface 3a and the second surface 3b located on opposite sides of the concrete layer 3 are constructed from the second surface 3a side. A method of reinforcing a reinforcing bar by reinforcing the concrete layer 3 from the second surface 3b side to form an arcuate hole 6 warping to the first surface 3a side, and reinforcing inside the arcuate hole 6 A step of introducing the material and a step of fixing the reinforcing material introduced into the arcuate hole 6 to the concrete layer 3 are provided. [Selection diagram] Figure 2

Description

  The present invention relates to a reinforcing bar reinforcing method, and more particularly to a technique effective when applied to a reinforcing bar reinforcing method for reinforcing a reinforcing bar embedded in a concrete layer.

Known civil engineering structures include bridges, jetty beams, floor slabs, bridge piers, concrete covering tunnels and vertical holes, box culverts, retaining walls, caissons, and the like. As building structures, for example, floor slabs, beams, columns, chimneys, silos, etc. of buildings and buildings are known. Many of these structures are constructed by reinforced concrete structures in which reinforcing bars are embedded in concrete layers.
And in recent years, for the purpose of ensuring the safety against an enormous earthquake that is expected, and for the load exceeding the initial assumed load due to the increase in vehicle traffic due to the widening and expansion of roads along with the increase in vehicle weight Reinforcing work to reinforce existing reinforced concrete structures is increasing for the purpose of ensuring safety.

  In existing reinforced concrete structures, the stress acting on the reinforcing bars in the concrete layer is allowed by increasing the earth pressure, water pressure, vehicle weight and load capacity, seismic force, etc. acting on the concrete layer from the beginning of the design. (Allowable stress level) is exceeded. For this reason, in the reinforcement of the existing reinforced concrete structure, it is effective to reinforce the existing reinforcing bar with a new reinforcing material to reduce the stress acting on the existing reinforcing bar.

  By the way, in the box culvert buried in the ground, the outer surface side of the top plate, the bottom plate, and the side wall is covered with soil or the like, so that the outer surface located on the opposite side of the concrete layer when reinforcing the reinforcing bars of such a reinforced concrete structure And construction from the inner surface side of the inner surface is a condition. In construction from the inner surface side, it is sufficiently possible to reinforce the reinforcing bars on the inner surface side, and many techniques have been put into practical use.

  On the other hand, a technique for reinforcing a reinforcing bar on the outer surface side by construction from the inner surface side has also been proposed. In Patent Document 1, an upper introduction hole and a lower introduction hole formed by drilling from one surface side to the other surface side of two surfaces located on opposite sides of the reinforced concrete structure are provided. And the accommodation hole formed by drilling so that this upper introduction hole and the lower introduction hole may be connected is provided. And the technique which enables reinforcement | strengthening of the reinforcement of an outer surface side (natural ground side) by the construction from the inner surface side (inside air side) of a reinforced concrete structure by providing a reinforcement part inside this accommodation hole is disclosed. .

JP 2017-2514 A

However, since the technology disclosed in Patent Document 1 extends in the direction in which the accommodation hole is orthogonal to the upper introduction hole and the lower introduction hole, flexibility (flexibility) is low as a reinforcing material for existing reinforcing bars. It is difficult to introduce a general material such as a reinforcing bar which is difficult to bend into the accommodation hole. That is, it has been difficult to use a general material such as a reinforcing bar as a reinforcing material for an existing reinforcing bar.
Therefore, the present inventors made the present invention by paying attention to the shape of the hole into which the reinforcing material is introduced.
An object of the present invention is to provide a technique capable of using a reinforcing bar as a reinforcing material for reinforcing a reinforcing bar embedded on one side of a concrete layer from the other side opposite to the one side. .

  In order to achieve the above object, a reinforcing bar reinforcing method according to an aspect of the present invention is a reinforcing bar embedded on a first surface side of a first surface and a second surface located on opposite sides of a concrete layer. Is a reinforcing steel reinforcing method in which the steel is constructed and reinforced from the second surface side. Then, the step of forming the arc-shaped hole which is constructed from the second surface side and warps the first surface side in the concrete layer, the step of introducing the reinforcing material into the arc-shaped hole, and the inside of the arc-shaped hole are introduced. Fixing the formed reinforcing material to the concrete layer.

  According to the reinforcing bar reinforcing method of one aspect of the present invention, a reinforcing bar can be used as a reinforcing material that reinforces a reinforcing bar embedded on one side of a concrete layer from the other side opposite to the one side.

It is a figure for demonstrating the reinforcing bar reinforcement method which concerns on Embodiment 1 of this invention, Comprising: It is sectional drawing which shows the state by which the box culvert was embed | buried under the ground. It is a principal part expanded sectional view which expands and shows the corner | angular part vicinity which the bottom plate and side wall of the box culvert of FIG. 1 were connected. It is a principal part perspective view which shows partially the reinforcement arrangement | positioning state of the reinforcing bar in the side wall of the box culvert of FIG. It is a figure which shows the stress state which acts on the outer side reinforcement of the box culvert of FIG. It is a figure which shows the stress state which acts on the outer side reinforcement of the side wall of the box culvert of FIG. It is principal part sectional drawing for demonstrating the reinforcing bar reinforcement method which concerns on Embodiment 1 of this invention. It is principal part sectional drawing for demonstrating the reinforcing bar reinforcement method which concerns on Embodiment 1 of this invention. It is principal part sectional drawing for demonstrating the reinforcing bar reinforcement method which concerns on Embodiment 1 of this invention. It is a figure which shows the modification of the reinforcing bar which concerns on Embodiment 1 of this invention. It is a figure for demonstrating the reinforcing bar reinforcement method which concerns on Embodiment 2 of this invention, Comprising: It is principal part sectional drawing which shows schematic structure of the floor slab of a bridge. It is a figure which shows the stress state which acts on the floor slab of the bridge of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiments of the invention, and the repetitive description thereof is omitted.
(Embodiment 1)
In this Embodiment 1, the reinforcing bar reinforcement method which reinforces the reinforcement embed | buried on the outer surface side of a concrete layer by the construction from an inner surface side in the side wall of the box culvert embed | buried in the ground, using a reinforcement reinforcement as a reinforcing material Will be described.

<Structure of box culvert>
First, before explaining the reinforcing bar reinforcing method, the structure of the box culvert will be explained.
As shown in FIG. 1, the box culvert 1 is buried in the ground, for example, to construct an underground tunnel for vehicle traffic. On the box culvert 1, a road for vehicle passage is constructed.
The box culverts 1 are spaced apart from each other in the height direction 1H as the first direction and are opposed to each other in the height direction 1H and the bottom plate 2b, and in the width direction 1W as the second direction orthogonal to the first direction. And two side walls 2c and 2d connected to each of the top plate 2a and the bottom plate 2b. Each of the top plate 2a, the bottom plate 2b, and the two side walls 2c and 2d has first and second surfaces positioned on opposite sides in the thickness direction, as shown in FIGS. A concrete layer 3 having an outer surface 3a and an inner surface 3b, and reinforcing bars 4a and 4b (hereinafter referred to as outer reinforcing bars 4a and 4b) embedded on the outer surface 3a side of the concrete layer 3, and an inner surface 3b of the concrete layer 3 It is constructed of a reinforced concrete structure comprising reinforcing bars 5a, 5b (hereinafter referred to as inner reinforcing bars 5a, 5b) embedded on the side.

In the two side walls 2c and 2d, each of the outer reinforcing bar 4a and the inner reinforcing bar 5a extends in the height direction 1H and has a depth direction 1L as a third direction orthogonal to the first direction and the second direction (see FIG. 3) are arranged at a predetermined arrangement pitch. Each of the outer reinforcing bar 4b and the inner reinforcing bar 5b extends in the depth direction 1L and is arranged in a plurality in a predetermined arrangement pitch in the height direction 1H. And the outer reinforcing bar 4a and the outer reinforcing bar 4b are assembled so that each part overlaps each other and three-dimensionally intersects. Also, the inner reinforcing bar 5a and the inner reinforcing bar 5b are assembled so that each part thereof overlaps each other and three-dimensionally intersects. At the intersection where these reinforcing bars cross three-dimensionally, they are fixed by thin binding bars or welding.
In the top plate 2a and the bottom plate 2b, the outer reinforcing bars 4a and the inner reinforcing bars 5a extend in the width direction 1W, and a plurality of outer reinforcing bars 4b and inner reinforcing bars 5b are arranged at a predetermined arrangement pitch in the width direction 1W.

  Each of the outer reinforcing bar 4a and the inner reinforcing bar 5a plays a role of resisting tensile stress generated by a bending moment acting on the concrete layer 3. In each of the top slab 2a, bottom slab 2b, and side walls 2c and 2d of the box culvert 1, the load in the short side direction with a short span is large, so the short side direction is the main bar, and the long side direction is the distribution bar (secondary bar). . In the first embodiment, as an example, each of the outer reinforcing bar 4a and the inner reinforcing bar 5a extending in the height direction 1H and the width direction 1W constitutes a main reinforcing bar, and each of the outer reinforcing bar 4b and the inner reinforcing bar 5b extending in the depth direction 1L is arranged. Make strength.

<Reinforcement structure>
Next, the reinforcing bar reinforcing structure will be described with reference to FIGS.
As shown in FIGS. 2 and 3, the outer reinforcing bar 4 a of the side wall 2 c of the box culvert 1 is reinforced by a reinforcing bar reinforcing structure 9. The reinforcing bar reinforcing structure 9 includes an arc-shaped hole 6 provided in the concrete layer 3 so as to be constructed from the inner surface 3b side of the concrete layer 3 and warped to the outer surface 3a side. In addition, the reinforcing bar reinforcing structure 9 is introduced into the arc-shaped hole 6 and fixed to the concrete layer 3 by the filler 8 to reinforce the reinforcing bar 7 (hereinafter referred to as reinforcing reinforcing bar) as a reinforcing material for reducing the tensile stress acting on the outer reinforcing bar 4a. 7). That is, the outer reinforcing bar 4a of the side wall 2c of the box culvert 1 is reinforced by the reinforcing reinforcing bar 7 fixed to the concrete layer 3, and the tensile stress acting on the outer reinforcing bar 4a is reduced.

  The arc-shaped hole 6 has one end side and the other end side positioned on the inner surface 3b side than the outer surface 3a side of the concrete layer 3, and an intermediate portion between the one end side and the other end side is an outer surface than the inner surface 3b side of the concrete layer 3 Located on the 3a side. And the one end side and other end side of the arc-shaped hole 6 are spaced apart in the extending direction of the outer reinforcing bar 4a. One end side of the arc-shaped hole 6 is connected to the inner surface 3 b of the concrete layer 3, and the other end side of the arc-shaped hole 6 is terminated inside the concrete layer 3. The shape of the arc-shaped hole 6 is preferably an arc-shaped cylindrical shape in order to avoid stress concentration.

  The reinforcing reinforcing bar 7 has an arc shape that warps from the inner surface 3 b side to the outer surface 3 a side of the concrete layer 3 inside the arc-shaped hole 6. The reinforcing reinforcing bar 7 has a fixing portion 7a on each of one end side and the other end side, and has a reinforcing portion 7b on an intermediate portion between the one end side and the other end side. The fixing portions 7a on the one end side and the other end side are located closer to the inner surface 3b than the intermediate line 3s having the thickness of the concrete layer 3, and the reinforcing portion 7b in the intermediate portion is closer to the outer surface 3a than the intermediate line 3s. positioned. Then, the fixing portion 7a on one end side of the reinforcing reinforcing bar 7 and the fixing portion 7a on the other end side are separated from each other in the extending direction of the outer reinforcing bar 4a. The reinforcing reinforcing bars 7 are formed in the same arc shape as that of the arc-shaped holes 6. The reinforcing reinforcing bar 7 is preferably an arc columnar shape in order to avoid stress concentration. In addition, as the reinforcing reinforcing bar 7, a smooth curved reinforcing bar whose outer peripheral surface has no irregularities may be used. However, in order to improve the fixing property with the concrete layer 3, the outer peripheral surface is a rib or a rib like an existing deformed reinforcing bar. Curved reinforcing bars having irregularities such as nodes may be used.

As the filler 8, it is preferable to use a material having fluidity and curability. For example, non-shrink mortar, concrete, organic material, cement-based inorganic material, etc. can be used.
In order to effectively reduce the tensile stress acting on the outer reinforcing bar 4 a by the reinforcing reinforcing bar 7, the fixing portion 7 a of the reinforcing reinforcing bar 7 is placed on the concrete layer 3 on the inner surface 3 b side of the intermediate line 3 s of the thickness of the concrete layer 3. It is important to fix and fix the reinforcing portion 7b of the reinforcing reinforcing bar 7 on the outer surface 3a side than the intermediate line 3s of the thickness of the concrete layer 3.

  In addition, in this Embodiment 1, the case where the reinforcing steel bar 7 is used as a reinforcing material is demonstrated. However, although the present invention enables the use of the reinforcing bar 7 as a reinforcing material, the present invention is not limited to this reinforcing bar 7. As the reinforcing material, in addition to the reinforcing rebar 7, a material having flexibility when introduced into the arc-shaped hole 6, such as a steel wire, a steel stranded wire, a carbon fiber, an aramid fiber, and a glass fiber can be used. The reinforcing material may be a material having a tensile strength higher than that of the concrete layer 3, preferably a material having a tensile strength equal to or higher than that of the outer reinforcing bar 4a. In the reinforcing bar reinforcing method of the present invention, a reinforcing bar that is low in flexibility and difficult to bend can be used as a reinforcing material for reinforcing an existing reinforcing bar.

<Stress acting on outer reinforcing bar>
Next, the stress which acts on the outer reinforcing bar 4a of the box culvert 1 will be described with reference to FIG.
In the box culvert 1 buried in the ground, the amount of vehicles passing along the road for vehicle passage on the top plate 2a increases, and the amount of vehicle traffic increases as the width of the road expands and roads increase. As a result, a load exceeding the assumed load at the beginning of construction is applied. When the load applied to the box culvert 1 exceeds the assumed load at the beginning of construction, the tensile stress acting on the reinforcing bar in the concrete layer 3 exceeds the allowable value (allowable stress level).
FIG. 4 is a diagram showing a stress state acting on the outer reinforcing bar 4a of the box culvert 1 of FIG. In the figure, A is a stress acting on the outer reinforcing bar 4a at the beginning of construction in which the tunnel is constructed by burying the box culvert 1. In the figure, B is a stress acting on the outer reinforcing bar 4a when the load applied to the box culvert 1 exceeds the assumed load at the time of construction.

  As shown in FIGS. 1 and 4, the top plate 2 a and the bottom plate 2 b and the two side walls 2 c and 2 d are connected to each other at each end. For this reason, as shown in FIG. 4, the stress A and the stress B acting on the outer reinforcing bar 4a are the end portions of the top plate 2a, the bottom plate 2b, and the two side walls 2c, 2d, in other words, the box culvert 1. Tensile stress is generated at the corner portion side, and compressive stress is generated at the center of each of the top plate 2a, the bottom plate 2b, and the two side walls 2c and 2d. In both the tensile stress and the compressive stress, the stress B after the load increase is greater than the stress A at the beginning of construction.

  In a reinforced concrete structure, the concrete mainly plays a role of resisting compressive stress, and the rebar plays a role of resisting tensile stress. Therefore, when reinforcing an existing reinforcing bar with a reinforcing material, it is preferable to reinforce a portion of the existing reinforcing bar on which a tensile stress acts. In the first embodiment, as shown in FIG. 2, the tensile stress acting portion of the outer reinforcing bar 4 a is reinforced by the reinforcing reinforcing bar 7 on the side wall 2 c of the box culvert 1 to reduce the tensile stress acting on the outer reinforcing bar 4 a. .

<Reduction effect of tensile stress acting on outer reinforcing bar>
Next, the effect of reducing the tensile stress acting on the outer reinforcing bar 4a on the side wall 2c of the box culvert 1 will be described with reference to FIG.
FIG. 5 is a view showing a state of tensile stress acting on the outer reinforcing bar 4a of the box culvert 1 of FIG. In the figure, A1 is a tensile stress acting on the outer reinforcing bar 4a at the beginning of construction in which the tunnel is constructed with the box culvert 1 buried. In the figure, B1 is a tensile stress acting on the outer reinforcing bar 4a when the load applied to the box culvert 1 exceeds the assumed load at the time of construction. In the figure, C1 is a tensile stress acting on the outer reinforcing bar 4a after being reinforced with the reinforcing reinforcing bar 7. In the figure, M1 is the allowable stress level, and N1 is the stress zero standard.

As shown in FIG. 5, the initial tensile stress A1 acting on the outer reinforcing bar 4a is lower than the allowable stress level M1 of the outer reinforcing bar 4a. And the tensile stress B1 after the load increase which acts on the outer side reinforcement 4a exceeds the allowable stress degree of the outer side reinforcement 4a. And the tensile stress C1 which acts on the outer reinforcing bar 4a after reinforcement has a peak value lower than the allowable stress degree M1 of the outer reinforcing bar 4a, and the peak value is lower than the tensile stress A1 at the beginning of construction. Yes.
Therefore, it can be seen that the tensile stress acting on the outer reinforcing bar 4 a can be reduced by the reinforcing reinforcing bar 7. This is because the total cross-sectional area of the lower reinforcing bar 4a is increased by the installation of the reinforcing reinforcing bar 7, and the tensile stress acting on the lower reinforcing bar 4a is reduced due to the effect.

<Reinforcement method>
Next, a reinforcing bar reinforcing method for reinforcing and reinforcing the outer reinforcing bar 4a embedded on the outer surface 3a side of the concrete layer 3 from the inner surface 3b side on the side wall 2c of the box culvert 1 will be described with reference to FIGS. .
First, as shown in FIG. 6, in the side wall 2c of the box culvert 1, an arc-shaped hole 6 is formed in the concrete layer 3 from the inner surface 3b side of the concrete layer 3 and warps to the outer surface 3a side. The arc-shaped hole 6 is formed in the vicinity of the portion where the tensile stress acts on the outer reinforcing bar 4a. The arc-shaped hole 6 can be easily formed by cutting the concrete layer 3 by a known technique such as a core boring machine or a water jet. For example, Japanese Patent Application Laid-Open No. 2006-28751 discloses a curved hole drilling device capable of drilling a curved hole in a side wall of a tunnel.

  In this arc-shaped hole forming step, the arc-shaped hole 6 has one end side and the other end side positioned on the inner surface 3 b rather than the outer surface 3 a side of the concrete layer 3, and an intermediate portion between the one end side and the other end side is the concrete layer 3. It is located on the outer surface 3a side rather than the inner surface 3b side. And the one end side and other end side of the arc-shaped hole 6 are spaced apart in the extending direction of the outer reinforcing bar 4a. One end side of the arc-shaped hole 6 is connected to the inner surface 3 b of the concrete layer 3, and the other end side of the arc-shaped hole 6 is terminated inside the concrete layer 3.

Next, as shown in FIG. 7, a reinforcing reinforcing bar 7 is introduced into the arc-shaped hole 6 as a reinforcing material that reduces the tensile stress acting on the outer reinforcing bar 4 a. The reinforcing reinforcing bars 7 are formed with an outer diameter smaller than the inner diameter of the arc-shaped hole 6. The reinforcing reinforcing bars 7 are formed in the same arc shape as that of the arc-shaped holes 6.
In this reinforcing steel bar introduction step, the reinforcing steel bars 7 are formed in the same arc shape as that of the arc-shaped holes 6 so that the reinforcing steel bars 7 can be easily introduced into the arc-shaped holes 6.

Next, the reinforcing reinforcing bars 7 introduced into the arc-shaped holes 6 are fixed to the concrete layer 3. For example, as shown in FIG. 7, the reinforcing bar 7 is fixed by filling the arc-shaped hole 6 with a filler 8 in a state where the reinforcing bar 7 is introduced into the arc-shaped hole 6, and then filling the filler 8 with the filler 8. This is done by curing.
Thereby, the reinforcing bar reinforcement structure 9 for reinforcing the outer reinforcing bar 4a of the side wall 2c of the box culvert 1 is almost completed.

<Effect of Embodiment 1>
As described above, according to the reinforcing bar reinforcing method of the first embodiment, the arc-shaped hole 6 is formed in the concrete layer 3 from the inner surface 3a side of the concrete layer 3 and warped to the outer surface 3a side. By introducing reinforcing reinforcing bars 7 as reinforcing materials into the concrete layer 3 and fixing them to the concrete layer 3, the outer reinforcing bars 4a embedded on the outer surface 3a side of the outer surface 3a and the inner surface 3b located on the opposite sides of the concrete layer 3 are provided. Can be reinforced from the inner surface 3b side.
Further, like the embedded box culvert 1, the top plate 2a, the bottom plate 2b, and the side walls 2c, 2d are covered with soil and the like, and it is difficult to reinforce the outer reinforcing bar 4a from the outer surface 3a side of the side wall 2c. In addition, the outer reinforcing bar 4a embedded on the outer surface 3a side of the concrete layer 3 can be reinforced from the inner surface 3b side of the concrete layer 3.

Further, by using the arc-shaped reinforcing bar 7 having the same curvature as that of the arc-shaped hole 6, the reinforcing bar 7 can be easily introduced into the arc-shaped hole 6. Accordingly, the reinforcing reinforcing bars 7 can be used as a reinforcing material for reinforcing the outer reinforcing bars 4a embedded on the outer surface 3a side of the concrete layer 3 from the inner surface 3b side opposite to the outer surface 3a.
In addition, since the reinforcing steel bars 7 can be used as the reinforcing material, it is not necessary to use a special material, and a large amount of material can be procured at low cost, so that construction management is easy.

Further, since the reinforcing bar reinforcing structure 9 can be constructed by forming one arc-shaped hole 6 in the concrete layer 3, three holes (upper introduction hole, lower introduction hole, and accommodation hole) are formed as in the conventional case. Compared with the case where a reinforcing steel bar structure is constructed, the construction period and cost required for reinforcing the outer steel bar 3a can be reduced.
Moreover, since the arc-shaped hole 6 which is constructed from the inner surface 3b side of the concrete layer 3 and warps to the outer surface 3a side is used, the reinforcement of the outer reinforcing bar 4a can be partially performed.
Moreover, since the other end side of the arc-shaped hole 6 is terminated inside the concrete layer 3, it is possible to suppress the leakage of the filler 8 and to prevent the reinforcing reinforcing bar 7 from coming off after fixing.

(Modification of Embodiment 1)
In the first embodiment, the case where the arc-shaped columnar reinforcing bar 7 is used has been described. However, as illustrated in FIG. 9, the reinforcing bar 7 may be provided with a protrusion 7 c. In FIG. 9A, protrusions 7 c are provided at both ends of the reinforcing bar 7. In FIG. 9B, protrusions 7 c are provided on both end sides of the reinforcing steel bar 7. In any case, the protrusion 7 c is preferably provided on the fixing portion 7 a of the reinforcing steel bar 7.
In the first embodiment, the reinforcing bar reinforcing method for reinforcing the outer reinforcing bar 4a of the side wall 2c of the box culvert 1 embedded in the ground has been described. However, the present invention is not limited to the reinforcing bar reinforcing method for reinforcing the outer reinforcing bar 4a of the side wall 2c. For example, the present invention can also be applied to a reinforcing bar reinforcing method for reinforcing the outer reinforcing bars 4a of the top plate 2a and the bottom plate 2b of the box culvert 1.

Moreover, in the above-mentioned Embodiment 1, the reinforcing bar reinforcement method of constructing and reinforcing the outer reinforcing bar 4a embedded on the outer surface 3a side of the concrete layer 3 from the inner surface 3b side was described. However, the present invention is not limited to the reinforcing bar reinforcing method in which the outer reinforcing bar 4a embedded on the outer surface 3a side of the concrete layer 3 is constructed and reinforced from the inner surface 3b side. For example, in the present invention, when construction from the inner surface 3b side of the concrete layer 3 is difficult and construction from the outer surface 3a side of the concrete layer 3 is possible, the concrete layer 3 is embedded on the inner surface 3b side. The present invention can also be applied to a reinforcing method in which the inner reinforcing bar 5a is reinforced by construction from the outer surface 3a side.
The present invention can also be applied to the reinforcement of the outer reinforcing bar 4b and the inner reinforcing bar 5b.

(Embodiment 2)
In the second embodiment, a reinforcing bar reinforcing method for reinforcing a lower reinforcing bar of a bridge floor slab will be described with reference to FIGS. 10 and 11.
<Bridge structure>
First, before describing the reinforcing bar reinforcing method, the structure of the bridge will be described.
As shown in FIG. 10, the bridge 10 includes a floor slab (floor slab) 11, a beam 12 that supports the floor slab 11, and a bridge pier (not shown) that supports the beam 12.
The floor slab 11 includes a concrete layer 13 having a first surface and a lower surface 13a and an upper surface 13b as second surfaces located on opposite sides in the thickness direction 11T as a first direction, and the concrete layer 13 Reinforcing bars 14a and 14b (hereinafter referred to as lower reinforcing bars 14a and 14b) embedded in the lower surface 13a side and reinforcing bars 15a and 15b (hereinafter referred to as upper reinforcing bars 15a and 15b) embedded in the upper surface 13b side of the concrete layer 13 It is constructed with a reinforced concrete structure.

  Each of the lower rebar 14a and the upper rebar 15a extends in the width direction 11W as a second direction orthogonal to the first direction, and as a third direction orthogonal to the first direction and the second direction. Are arranged at a predetermined arrangement pitch in the depth direction (not shown). Each of the lower rebar 14b and the upper rebar 15b extends in the depth direction, and a plurality of the lower rebar 14b and the upper rebar 15b are arranged at a predetermined arrangement pitch in the width direction 11W. And the lower rebar 14a and the lower rebar 14b are assembled so that each of them partially overlap each other and three-dimensionally intersect. Also, the upper rebar 15a and the upper rebar 15b are also assembled so that each part overlaps each other and three-dimensionally intersects. At the intersection where these reinforcing bars cross three-dimensionally, they are fixed by thin binding bars or welding.

  Each of the lower reinforcing bar 14a and the upper reinforcing bar 15a plays a role of resisting a tensile stress generated by a bending moment acting on the concrete layer 3. In the floor slab 11, since the load in the short side direction with a short span is large, the short side direction is the main bar and the long side direction is the distribution bar (sub-bar). In the second embodiment, as an example, each of the lower rebar 14a and the upper rebar 15a extending in the width direction 11W is a main rebar, and each of the lower rebar 14b and the upper rebar 15b extending in the depth direction is a distribution bar. Eggplant.

<Reinforcement structure>
Next, the reinforcing bar reinforcing structure will be described with reference to FIG.
As shown in FIG. 10, the lower reinforcing bar 14 a of the floor slab 11 of the bridge 10 is reinforced by a reinforcing bar reinforcing structure 19. The reinforcing bar reinforcing structure 19 includes an arc-shaped hole 16 provided in the concrete layer 13 so as to be constructed from the upper surface 13b side of the concrete layer 13 and warped to the lower surface 13a side. Further, the reinforcing bar reinforcing structure 19 is introduced into the arc-shaped hole 16 and fixed to the concrete layer 13 by the filler 18, and the reinforcing bar 17 (hereinafter referred to as a reinforcing member) is used as a reinforcing material for reducing the tensile stress acting on the lower reinforcing bar 14a. (Referred to as a reinforcing bar 17). That is, the lower rebar 14a of the floor slab 11 of the bridge 10 is reinforced by the reinforcing rebar 17 fixed to the concrete layer 13, and the tensile stress acting on the lower rebar 14a is reduced.

  One end side and the other end side of the arc-shaped hole 16 are located on the upper surface 13b side than the lower surface 13a side of the concrete layer 13, and an intermediate portion between the one end side and the other end side is a lower surface than the upper surface 13b side of the concrete layer 3. It is located on the 13a side. And the one end side and other end side of the arc-shaped hole 16 are spaced apart in the extending direction of the lower rebar 14a. One end side of the arc-shaped hole 16 is connected to the upper surface 13 b of the concrete layer 13, and the other end side of the arc-shaped hole 16 is terminated inside the concrete layer 13. As the shape of the arc-shaped hole 16, an arc-shaped cylindrical shape is preferable in order to avoid stress concentration.

  The reinforcing reinforcing bar 17 has an arc shape that warps from the upper surface 13 b side to the lower surface 13 a side of the concrete layer 13 inside the arc-shaped hole 16. The reinforcing reinforcing bar 17 has a fixing portion 17a on each of one end side and the other end side, and has a reinforcing portion 17b on an intermediate portion between the one end side and the other end side. The fixing portions 17a on one end side and the other end side are positioned on the upper surface 13b side with respect to the intermediate line 13s of the thickness of the concrete layer 13, and the fixing portion 17a on the intermediate portion is on the lower surface 13a side with respect to the intermediate line 13s. positioned. The fixing portion 17a on one end side of the reinforcing reinforcing bar 17 and the fixing portion 17a on the other end side are separated from each other in the extending direction of the lower reinforcing bar 14a. The reinforcing reinforcing bars 17 are formed in the same arc shape as that of the arc-shaped holes 16. The reinforcing reinforcing bar 17 is preferably an arc columnar shape in order to avoid stress concentration. Further, as the reinforcing reinforcing bar 17, a smooth curved reinforcing bar whose outer peripheral surface has no irregularities may be used. However, in order to improve the fixing property with the concrete layer 3, the outer peripheral surface is rib or You may use the curved-surface-shaped reinforcing bar which provides a node etc. and has an unevenness | corrugation.

As the filler 18, it is preferable to use a material having fluidity and curability. For example, non-shrink mortar, concrete, organic material, cement-based inorganic material, etc. can be used.
In order to effectively reduce the tensile stress acting on the lower reinforcing bar 14 a with the reinforcing reinforcing bar 17, the fixing portion 17 a of the reinforcing reinforcing bar 17 is placed on the concrete layer 13 on the upper surface 13 b side of the intermediate line 13 s of the thickness of the concrete layer 13. It is important that the reinforcing portion 17b of the reinforcing reinforcing bar 17 is fixed on the lower surface 13a side than the intermediate line 13s of the thickness of the concrete layer 13.

  In addition, in this Embodiment 2, the case where the reinforcing steel bar 17 is used as a reinforcing material is demonstrated. However, although the present invention enables the use of the reinforcing bar 17 as a reinforcing material, the present invention is not limited to this reinforcing bar 17. As the reinforcing material, in addition to the reinforcing reinforcing bar 17, a material having flexibility when introduced into the arc-shaped hole 16, such as a steel wire, a steel stranded wire, a carbon fiber, an aramid fiber, and a glass fiber can be used. The reinforcing material may be a material having a higher tensile strength than the concrete layer 13, preferably a material having a tensile strength equal to or higher than that of the lower rebar 14a. In the reinforcing bar reinforcing method of the present invention, a reinforcing bar that is low in flexibility and difficult to bend can be used as a reinforcing material for reinforcing an existing reinforcing bar.

<Reduction effect of tensile stress acting on outer reinforcing bar>
Next, the effect of reducing the tensile stress acting on the lower rebar 14a in the floor slab 11 of the bridge 10 will be described with reference to FIG.
The floor slab 11 of the bridge 10 is loaded with a load that exceeds the assumed load at the beginning of construction due to an increase in the weight and load of the vehicle passing through the vehicle traffic road on the floor slab 11. When the load applied to the floor slab 11 exceeds the assumed load at the beginning of construction, the tensile stress acting on the reinforcing bars in the concrete layer 13 exceeds the allowable value (allowable stress level).

  FIG. 11 is a view showing a state of stress acting on the lower rebar 14a of the floor slab 11 of FIG. In the figure, A2 is a stress acting on the lower rebar 14a at the beginning of construction of the bridge 10. In the figure, B2 is a stress acting on the lower reinforcing bar 14a when the load applied to the floor slab 11 exceeds the assumed load at the beginning of construction. In the figure, C2 is a stress acting on the lower reinforcing bar 14a after being reinforced with the reinforcing reinforcing bar 17. In the figure, M2 is the allowable stress level, N2 is the zero stress reference, G1 is the assumed load at the beginning of construction, and the load exceeds the assumed load at the beginning of G2 construction.

  As shown in FIGS. 10 and 11, in the floor slab 11, two fulcrum portions that are separated from each other in the width direction 11 </ b> W are supported by the beams 12. For this reason, as shown in FIG. 11, the stress A2 and the stress B2 acting on the lower reinforcing bar 14a become compressive stress in the vicinity of the two fulcrum portions of the floor slab 11, and the tensile stress in the intermediate portion between the two fulcrum portions. A2a and B2a. In both the tensile stress and the compressive stress, the stress B2 after the load increase is greater than the stress A2 at the beginning of construction.

  In a reinforced concrete structure, the concrete mainly plays a role of resisting compressive stress, and the rebar plays a role of resisting tensile stress. Therefore, when reinforcing an existing reinforcing bar with a reinforcing material, it is preferable to reinforce a portion of the existing reinforcing bar on which a tensile stress acts. In the second embodiment, as shown in FIG. 10, in the floor slab 11, the tensile stress acting portion of the lower reinforcing bar 14a is reinforced by the reinforcing reinforcing bar 17, and the tensile stress acting on the lower reinforcing bar 14a is reduced.

As shown in FIG. 11, the initial tensile stress A2a acting on the lower rebar 14a is lower than the allowable stress level M2 of the lower rebar 14a. And the tensile stress B2a after the load increase which acts on the lower rebar 14a exceeds the allowable stress degree M2 of the lower rebar 14a. The tensile stress C2 acting on the lower reinforcing bar 14a after reinforcement has a peak value lower than the allowable stress degree M2 of the lower reinforcing bar 14a, and is lower than the tensile stress A2a at the beginning of construction. It has become.
Therefore, it can be seen that the tensile stress acting on the lower reinforcing bar 14 a can be reduced by the reinforcing reinforcing bar 17. This is because the total cross-sectional area of the lower reinforcing bar 14a is increased by the installation of the reinforcing reinforcing bar 17, and the tensile stress acting on the lower reinforcing bar 14a is reduced due to the effect.

<Reinforcement method>
Next, a reinforcing bar reinforcement method for constructing and reinforcing the lower rebar 14a embedded on the lower surface 13a side of the concrete layer 13 from the upper surface side in the floor slab 11 of the bridge 1 will be described with reference to FIG.
First, as shown in FIG. 10, in the floor slab 11 of the bridge 10, an arc-shaped hole 16 that is constructed from the upper surface 13 b side of the concrete layer 13 and warps to the lower surface 13 a side is formed in the concrete layer 13. The arc-shaped hole 16 is formed in the vicinity of the portion where the tensile stress acts on the lower reinforcing bar 14a. The arc-shaped hole 16 can be easily formed by cutting the concrete layer 13 by a known technique such as a core boring machine or a water jet.

  In this arc-shaped hole forming step, one end side and the other end side of the arc-shaped hole 16 are located on the upper surface 13 b rather than the lower surface 13 a side of the concrete layer 13, and an intermediate portion between the one end side and the other end side is the concrete layer 13. It is located on the lower surface 13a side than the upper surface 13b side. And the one end side and other end side of the arc-shaped hole 16 are spaced apart in the extending direction of the lower rebar 14a. One end side of the arc-shaped hole 16 is connected to the upper surface 13 b of the concrete layer 13, and the other end side of the arc-shaped hole 16 is terminated inside the concrete layer 13.

Next, as shown in FIG. 10, a reinforcing reinforcing bar 17 is introduced into the arc-shaped hole 16 as a reinforcing material that reduces the tensile stress acting on the lower reinforcing bar 14 a. The reinforcing reinforcing bar 17 is formed with an outer diameter smaller than the inner diameter of the arc-shaped hole 16. Further, the reinforcing reinforcing bars 7 are formed in an arc shape having the same curvature as that of the arc-shaped hole.
In this step, the reinforcing reinforcing bars 17 are formed in the same arc shape as that of the arc-shaped holes 16 so that the reinforcing reinforcing bars 17 can be easily introduced into the arc-shaped holes 16.

Next, the reinforcing reinforcing bar 17 introduced into the arcuate hole 16 is fixed to the concrete layer 13. For example, as shown in FIG. 10, the reinforcing reinforcing bar 17 is fixed by filling the arc-shaped hole 16 with the filler 18 in a state where the reinforcing reinforcing bar 17 is introduced into the arc-shaped hole 16, and then using the filler 18. This is done by curing.
Thereby, the reinforcing bar reinforcement structure 19 for reinforcing the lower reinforcing bar 14a of the floor slab 11 of the bridge 10 is almost completed.

<Effect of Embodiment 2>
As described above, according to the reinforcing bar reinforcing method of the second embodiment, the arc-shaped hole 16 which is constructed from the upper surface 13b side of the concrete layer 13 and warps to the lower surface 13a side is formed in the concrete layer 13. By reinforcing the reinforcing bar 17 as a reinforcing material and fixing it to the concrete layer 13, the lower reinforcing bar 14 a embedded on the lower surface 13 a side of the concrete layer 13 can be reinforced from the upper surface 13 b side of the concrete layer 13. it can.

  Further, in the floor slab 11 of the bridge 10, when reinforcing the lower rebar 14a embedded on the lower surface 13a side of the concrete layer 13 from the lower surface 13a side, it is necessary to assemble a scaffold. On the other hand, in this Embodiment 2, since the lower rebar 14a embed | buried under the lower surface 13a side of the concrete layer 13 can be reinforced from the upper surface 13b side of the concrete layer 13, it is not necessary to assemble a scaffold. Therefore, the construction period and cost required for reinforcement of the lower rebar 14a can be reduced.

Further, by using the reinforcing bar 17 having the same curvature as that of the arc-shaped hole 16, the reinforcing bar 17 can be easily introduced into the arc-shaped hole 6. Therefore, the reinforcing reinforcing bar 17 can be used as a reinforcing material for reinforcing the lower reinforcing bar 14a embedded on the lower surface 13a side of the concrete layer 13 from the upper surface 13b side opposite to the lower surface 13a.
Further, since the reinforcing steel bars 17 can be used as the reinforcing material, it is not necessary to use a special material, and a large amount of material can be procured at a low cost, so that construction management is easy.

Moreover, since the reinforcing bar reinforcement structure 19 can be constructed by forming one arc-shaped hole 16 in the concrete layer 13, three holes (upper introduction hole, lower introduction hole, and accommodation hole) are formed as in the conventional case. Thus, compared with the case of constructing a reinforcing reinforcing bar structure, the construction period and cost required for reinforcing the outer reinforcing bar 13a can be reduced.
Moreover, since the arc-shaped hole 16 which constructs from the upper surface 13b side of the concrete layer 13 and warps to the lower surface 13a side is used, reinforcement of the lower rebar 14a can be performed partially.
Moreover, since the other end side of the arc-shaped hole 16 is terminated inside the concrete layer 13, it is possible to suppress the leakage of the filler 18, and it is possible to suppress the arc-shaped hole 16 from being fixed after fixing.

In the second embodiment, the reinforcing steel bar 7 shown in FIG. 9 can be used.
Further, in the above-described second embodiment, the reinforcing bar reinforcing method in which the lower reinforcing bar 14a embedded on the lower surface 13a side of the concrete layer 13 is constructed and reinforced from the upper surface 13b side has been described. However, the present invention is not limited to a reinforcing bar reinforcing method in which the lower reinforcing bar 14a embedded on the lower surface 13a side of the concrete layer 13 is constructed and reinforced from the upper surface 3b side. For example, in the present invention, when construction from the upper surface 13b side of the concrete layer 13 is difficult and construction from the lower surface 13a side of the concrete layer 13 is possible, the concrete layer 13 is embedded on the upper surface 13b side. The present invention can also be applied to a reinforcing method in which the upper reinforcing bar 15a is reinforced by construction from the lower surface 14a side.
The present invention can also be applied to reinforcement of the lower reinforcing bar 14b and the upper reinforcing bar 15b.

The present invention has been specifically described above based on the above embodiment, but the present invention is not limited to the above embodiment, and it is needless to say that various changes can be made without departing from the scope of the invention.
For example, the present invention is applied to the reinforcement of reinforced concrete structures such as bridges, jetty beams, floor slabs, bridge piers, tunnel and streak lining concrete, box culverts, retaining walls, caissons, etc. as civil engineering structures. be able to.
In addition, the present invention can be applied to reinforcing reinforced concrete structures such as floor slabs, beams, columns, chimneys, and silos of buildings and buildings as building structures.

1 ... Box culvert (concrete structure)
1H: Height direction (first direction)
1W: width direction (second width direction)
1L: Depth direction (third direction)
2a ... Top plate 2b ... Bottom plate 2c, 2d ... Side wall 3 ... Concrete layer 3a ... Outer surface (first surface)
3b ... Inner surface (second surface)
4a, 4b ... Outer bar 5a, 5b ... Inner bar 6 ... Arc hole 7 ... Reinforcing bar (reinforcing material)
7a ... Fixing part 7b ... Reinforcement part 7c ... Protrusion 8 ... Filler 9 ... Reinforcement structure 10 ... Bridge 11 ... Slab (concrete structure)
11T ... thickness direction (first direction),
11W: width direction (second direction)
12 ... Beam 13 ... Concrete layer 13a ... Lower surface (first surface)
13b ... Upper surface (second surface)
14a, 14b ... lower rebar 15a, 15b ... upper rebar 16 ... arc-shaped hole 17 ... reinforcing steel (reinforcing material)
18 ... Filler 19 ... Reinforcement structure

Claims (8)

It is a reinforcing bar reinforcing method in which a reinforcing bar embedded on the first surface side of the first surface and the second surface located on the opposite sides of the concrete layer is constructed and reinforced from the second surface side. And
In the concrete layer, a step of forming an arc-shaped hole that is constructed from the second surface side and warps the first surface side;
Introducing a reinforcing material into the arcuate hole;
Fixing the reinforcing material introduced into the arcuate hole in the concrete layer;
Reinforcing bar reinforcement method characterized by comprising.   One end side and the other end side of the arc-shaped hole are located on the second surface side with respect to the first surface side, and an intermediate portion between the one end side and the other end side is on the second surface side. The reinforcing bar reinforcing method according to claim 1, wherein the reinforcing bar is positioned on the first surface side.   The reinforcing bar reinforcing method according to claim 2, wherein the one end side and the other end side of the arc-shaped hole are separated from each other in the extending direction of the reinforcing bar.   The reinforcing bar reinforcement according to claim 2 or 3, wherein the one end side of the arc-shaped hole is connected to the second surface, and the other end side of the arc-shaped hole is terminated inside the concrete layer. Method. One end side and the other end side of the reinforcing material are located on the second surface side with respect to the middle line of the thickness of the concrete layer,
The intermediate part between the said one end side and the said other end side of the said reinforcing material is located in the said 1st surface side rather than the said intermediate line, The any one of Claim 1 to 4 characterized by the above-mentioned. Reinforcing bar reinforcing method according to item.   6. The reinforcing bar reinforcing method according to claim 5, wherein the one end side and the other end side of the reinforcing material are separated from each other in the extending direction of the reinforcing bar.   The reinforcing material reinforcing method according to claim 5, wherein the reinforcing material has protrusions on the one end side and the other end side.   The reinforcing material reinforcing method according to any one of claims 1 to 7, wherein the reinforcing material is a reinforcing bar formed in the same arc shape as the arc-shaped hole.

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