JP6173087B2 - Method for reinforcing concrete structures - Google Patents

Description

  The present invention relates to a method for reinforcing a concrete structure.

A box culvert buried in the ground that constitutes an underground tunnel for railways or roadways is known.
It is requested to enhance the earthquake resistance of box culvert triggered by the Great Hanshin-Awaji Earthquake and the Tohoku-Pacific Ocean Earthquake.
In Cited Document 1, as a method of reinforcing the box culvert, a technique is proposed in which a shear reinforcing material is inserted into a hole formed from the inner wall surface side of the side wall of the box culvert toward the inside of the wall, and the remaining void is filled and solidified with a filler. Has been.

Patent No. 3932094

However, in the above prior art, a hole is formed from the inner wall surface side of the side wall of the box culvert toward the inside of the wall, a shear reinforcing material is inserted into the hole portion from the inner wall surface side, and a filler is further filled in the hole portion. Therefore, it will be constructed from inside the box culvert.
Therefore, during construction, train cars and automobiles cannot pass, so construction time is limited. This necessitates construction hours at night, which increases the number of times equipment is loaded, prepared, and withdrawn, and construction efficiency is significantly reduced.
In addition, since the shear reinforcement material extends in the thickness direction of the inner wall of the box culvert, it is difficult to cover the shear failure line in various directions assumed at the time of an earthquake. There are disadvantages.
This invention is made | formed in view of such a situation, The objective is to provide the reinforcement method of a concrete structure advantageous in ensuring reinforcement performance, improving construction efficiency.

  In order to achieve the above-mentioned object, the present invention has a wall portion made of reinforced concrete having an elongated cross-sectional shape in the vertical direction and extending in the horizontal direction, and the wall portions are on both sides in the thickness direction. A reinforcing method for a concrete structure having a reinforcing bar embedded in the wall, wherein one surface in the thickness direction of the wall portion is embedded in the ground, and the wall portion is the one surface of the wall portion. A first step of excavating a working hole extending in the vertical direction along the one surface of the wall so as to expose a plurality of positions spaced in the extending direction of the In the hole portion, from the upper end to the lower end of one surface of the wall portion at the plurality of locations, the rebar embedded on the one surface side is exposed to the side of the one surface of the wall portion. In the second step of forming a groove portion extending in the vertical direction at each of the groove portions in the working hole portion, And a third step of arranging the reinforcing bars for the pillars extending in the vertical direction so that a part thereof is inside the groove, and the inside of each groove at the plurality of positions in the working hole. A fourth step of installing a concrete mold so as to partition the space extending over the entire length in the extending direction of the groove part, surrounding the reinforcing bar for the column, and the inside of each groove part and each concrete mold Including a fifth step of constructing a reinforcing column that protrudes outward from one surface of the wall portion and is integrally coupled to the wall portion by placing concrete inside the frame over the entire length of the groove portion. It is characterized by.

As described above, according to the present embodiment, so as to expose a plurality of locations spaced in the extending direction of the wall portion on one surface of the wall portion of the concrete structure embedded in the ground, The first step of excavating the working hole extending in the vertical direction along the one surface of the wall portion is performed, the second to fourth steps are performed in the working hole portion, and the one of the wall portions is performed. The concrete structure was reinforced by performing the fifth step from the ground.
Therefore, when reinforcing a concrete structure, it is sufficient to secure a working space on the side and upper side of the wall, so the reinforcement work can be completed without impairing the functions of the concrete structure, for example, the functions of the road and railway. it can.
Moreover, since the extending direction of the reinforcing column is a vertical direction, it is advantageous in covering the shear fracture line in various directions assumed at the time of an earthquake, and it is advantageous in securing the reinforcing performance of the concrete structure.

It is explanatory drawing of the reinforcement method of the underground tunnel 2 in 1st Embodiment. It is a perspective view of the perspective view of the box culvert 10 which comprises the underground tunnel 2 reinforced with the reinforcement support | pillar 30. FIG. It is explanatory drawing of the reinforcement method of the underground tunnel 2 in 1st Embodiment, (A) is explanatory drawing which shows a 1st, 2nd process, (B) is description which shows a 3rd, 4th process. FIG. 4C is an explanatory diagram showing the fifth step. It is explanatory drawing of the reinforcement method of the underground tunnel 2 in 2nd Embodiment, (A) is explanatory drawing which shows a 1st, 2nd process, (B) is description which shows a 3rd, 4th process. FIG. 4C is an explanatory diagram showing the fifth step. It is explanatory drawing of the reinforcement method of the digging road 4 in 3rd Embodiment. FIG. 3 is a perspective view showing a digging road 4 reinforced by reinforcing columns 30. It is explanatory drawing of the reinforcement method of the retaining wall 6 in 4th Embodiment. FIG. 5 is a perspective view showing a retaining wall 6 reinforced by a reinforcing column 30. It is explanatory drawing of the reinforcement method of the bridge abutment 8 in 5th Embodiment. FIG. 6 is a perspective view showing a bridge abutment 8 reinforced by a reinforcing column 30.

(First embodiment)
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
As shown in FIG. 1, in the first embodiment, a concrete structure is an underground for a railway constructed by being buried in the ground with a number of box culverts 10 connected in the axial direction. The case of the tunnel 2 will be described.
First, the box culvert 10 will be described.
A large number of box culverts 10 are buried in the ground in a state where they are connected in the axial direction, thereby forming an underground tunnel 2 for railway.
The internal space of the underground tunnel 2 composed of a large number of box culverts 10 is divided into two spaces, and the railway vehicle A is configured to travel in each space.
In the figure, symbol H indicates a road for an automobile provided on the ground located above the box culvert 10, and symbol B indicates an automobile traveling on the road H.

Each box culvert 10 includes a rectangular plate-shaped bottom wall 12, two side walls 14 rising from both ends in the width direction of the bottom wall 12, and a partition wall standing from the center in the width direction of the bottom wall 12 and parallel to the two side walls 14. 16 and a rectangular plate-like ceiling wall 18 connecting the two side walls 14 and the upper end of the partition wall 16.
And the two side walls 14 and the partition 16 comprise the wall part which has an elongate cross-sectional shape in the perpendicular direction, and extends in a horizontal direction.
As shown in FIG. 3A, reinforcing bars 20 are embedded in the side wall 14 on both sides in the thickness direction. The reinforcing bars 20 are configured, for example, by arranging a plurality of vertical bars 20V extending in the vertical direction and a plurality of horizontal bars 20H extending in the horizontal direction in a lattice pattern.
The bottom wall 12, the side wall 14, the partition wall 16, and the ceiling wall 18 are integrally formed of reinforced concrete.
The partition wall 16 divides the internal space of the underground tunnel 2 into two spaces, and a rail R for running a railway vehicle is laid on the bottom wall 12.

Next, a method for reinforcing the box culvert 10 constituting such an underground tunnel 2 will be described.
First, as shown in FIG. 3A, one surface of the side wall 14 is exposed so as to expose a plurality of locations spaced in the extending direction of the side wall 14 on one surface of the side wall 14 embedded in the ground. The working hole 22 extending in the vertical direction along the line is excavated (first step).
As shown in FIG. 1, excavation of the working hole 22 is performed from the ground corresponding to just above the two side walls 14 by using a construction machine 24 such as a back-for and a hammer grab, or by manual digging.
The working hole 22 may be provided at each of the plurality of locations, or may be extended in the horizontal direction so as to expose the plurality of locations simultaneously.

Next, in the work hole 22, the one surface of the side wall 14 is exposed so as to expose the reinforcing bars 20 embedded on the one surface side from the upper end to the lower end of the one surface of the side wall 14 at the plurality of locations. Grooves 26 that are open and extend in the vertical direction are formed on the sides (second step).
The operation of exposing the reinforcing bars is performed using a concrete suspension device such as a concrete hammer or a water jet cutting device.

Next, as shown in FIG. 3 (B), in the work hole 22, strut reinforcing bars 28 are arranged along the respective groove portions 26, and at this time, a part of the strut reinforcing bars 28 is partly formed in the groove portions 26. (Third step).
This strut reinforcing bar 28 includes a plurality of main reinforcing bars 28A extending in the vertical direction and a plurality of band reinforcing bars 28B surrounding the main reinforcing bars 28A.
Then, the portion of the support reinforcing bar 28 located in the groove 26 is joined to the reinforcing bar 20 embedded in the side wall 14.
For this connection, for example, a binding wire (wire) may be used, or welding may be used.
Positioning a part of the supporting bar 28 in the groove 26 in this way is advantageous in firmly integrating the reinforcing supporting column 30 with the side wall 14. Further, the supporting bar 28 is positioned in the groove 26. When the portion is coupled to a reinforcing bar embedded in the side wall 14, it is more advantageous to firmly integrate the reinforcing column 30 into the side wall 14.

Next, in the working hole portion 22, each groove portion 26 is connected to the inside of the groove portion 26 so as to divide the space portion extending over the entire length in the extending direction of the groove portion 26 so as to surround the support rod rebar 28. The concrete formwork 32 is installed in (4th process).
The space portion has a rectangular parallelepiped shape having a substantially rectangular cross section including the groove portion 26 and extending vertically.

Next, as shown in FIG. 3C, concrete 34 is placed inside each groove 26 and inside each concrete mold 32, protrudes to the outside of one surface of the side wall 14, and is integrated with the side wall 14. Reinforcing struts 30 composed of coupled RC pillars are constructed over the entire length of groove 26 (fifth step).
FIG. 2 shows a perspective view of the box culvert 10 constituting the underground tunnel 2 reinforced by the reinforcing column 30.
In addition, after the concrete 34 is hardened, the concrete mold 32 may be removed or left as it is, and FIG. 3C shows a state in which the concrete mold 32 is removed.

As described above, according to the present embodiment, so as to expose a plurality of locations spaced in the extending direction of the side wall 14 on one surface of the side wall 14 of the box culvert 10 embedded in the ground, The first step of excavating the working hole 22 extending in the vertical direction along the one surface of the side wall 14 is performed, the second to fourth steps are performed in the working hole 22, and the side wall 14 The underground tunnel was reinforced by performing the fifth step from the ground on the one side.
Therefore, it is not necessary to construct from the inside of the underground tunnel 2, and it is sufficient to secure a working space on the side and above the side wall 14, so that the reinforcement of the underground tunnel 2 can be performed while operating the vehicle in the same manner as in the past. Reinforcement work can be completed without impairing the function of the engine.
Further, since the reinforcement work can be performed while operating the vehicle as in the conventional case, the construction is not limited to the night when the vehicle does not travel, and can be performed during the day, which is advantageous in improving the construction efficiency.

In addition, since the extending direction of the reinforcing column 30 is a vertical direction, it is advantageous in covering the shear fracture line in various directions assumed at the time of the earthquake, and advantageous in securing the reinforcing performance of the underground tunnel 2. .
For example, when the shear fracture line extends in the thickness direction of the side wall 14, in the related art, the reinforcing member extends in the thickness direction of the side wall 14, and therefore, the extending direction of the reinforcing member and the shear fracture line hardly cross each other. The reinforcing member becomes difficult to function.
On the other hand, in the present invention, since the reinforcing column 30 extends in the vertical direction of the side wall 14, the extending direction of the reinforcing column 30 and the shear fracture line are surely crossed, and the reinforcing column 30 is easy to function. Become.
Further, in the prior art, because of the configuration in which the reinforcing member extends in the thickness direction of the side wall 14, the toughness reinforcement is the main effect especially as the shear reinforcement of the side wall 14, and the effect of bending reinforcement is not achieved.
On the other hand, in the present invention, since the reinforcing support 30 extends in the vertical direction of the side wall 14, it is advantageous in providing the effect of bending reinforcement as shear reinforcement of the side wall 14.

Further, in the prior art, since the hole 22 is excavated in the thickness direction of the side wall 14, when the side wall 14 of the culvert box is bent to form a corner, the hole 22 is excavated in the corner. It is difficult to reinforce the corners.
On the other hand, in the present invention, since the groove portion 26 is excavated in one surface of the side wall 14 along the vertical direction, the groove portion 26 can be excavated also in the corner portion. It will be advantageous.

(Second Embodiment)
Next, a second embodiment will be described.
In the following embodiments, the same members and portions as those in the first embodiment are denoted by the same reference numerals, description thereof is omitted, and differences are mainly described.
As shown in FIGS. 4A to 4C, the second embodiment is different from the first embodiment in that the reinforcing column 30 is composed of an SRC column.
That is, as shown in FIG. 4 (C), the reinforcing support 30 includes an SRC including a steel frame 32, a support reinforcing bar 28 attached around the steel frame 32, and a concrete 34 in which they are embedded. It is a pillar.
As shown in FIG. 4 (B), the supporting bar 28 is wound around and attached to a steel frame 32 in advance.
Therefore, in the second embodiment, the reinforcing bars 28 are arranged by arranging the steel frames 32 in the vertical direction along the grooves 26.
As the steel frame 32, various conventionally known steel shapes such as H-shape steel, I-shape steel, and steel pipe can be used.
In the present embodiment, the steel frame 32 is H-shaped steel having flanges F on both sides of the web W, and a large number of studs S project from the flanges F facing the groove portions 26.
Then, in the third step, the steel frame 32 is disposed so that a part of the reinforcing bar 28 for the support, the stud S, and the flange F on which the stud S is protruded are located in the groove portion 26. In this manner, by positioning a part of the reinforcing bar 28 for the strut, the stud S, and the flange F in the groove portion 26, it is advantageous in firmly integrating the reinforcing strut 30 with the side wall 14.
The first, second, fourth and fifth steps are the same as in the first embodiment.
According to the second embodiment, in addition to the operational effects of the first embodiment, the reinforcing support 30 includes the steel frame 32, which is advantageous in reinforcing the underground tunnel 2 more firmly.

(Third embodiment)
Next, a third embodiment will be described.
As shown in FIG. 5, in the third embodiment, a case where the concrete structure is a digging road 4 will be described.
The moat split road 4 is constructed by cast-in-place concrete or a precast member in a groove excavated in the ground G.
As shown in FIGS. 5 and 6, the moat split road 4 includes a bottom wall 36 that constitutes a roadbed, and two side walls 38 that stand from both ends of the bottom wall 36 in the width direction. The outer surface of 38 is buried.
The two side walls 38 constitute a wall portion having an elongated cross-sectional shape in the vertical direction and extending in the horizontal direction.
The bottom wall 36 and the side wall 38 are integrally formed of reinforced concrete.

Next, a method for reinforcing the digging road 4 will be described with reference to FIGS.
As shown in FIG. 3 (A), as in the first embodiment, a plurality of locations spaced in the extending direction of the side wall 38 are exposed on one surface of the side wall 38 embedded in the ground. Next, the working hole 22 extending in the vertical direction along one surface of the side wall 38 is excavated (first step).

  Next, in the work hole 22, the one surface of the side wall 38 is exposed from the upper end to the lower end of the one surface of the side wall 38 at the plurality of locations so as to expose the reinforcing bars 20 embedded on the one surface side. Grooves 26 that are open and extend in the vertical direction are formed on the sides (second step).

Next, as shown in FIG. 3 (B), reinforcing bar support rods 28 for reinforcement columns are arranged along the respective groove portions 26 in the working hole 22, and at that time, The part is positioned in the groove part 26 (third step).
Then, the portion of the reinforcing bar 28 for the column positioned in the groove 26 is coupled to the reinforcing bar embedded in the side wall 38.

  Next, in the working hole portion 22, each groove portion 26 is connected to the inside of the groove portion 26 so as to divide the space portion extending over the entire length in the extending direction of the groove portion 26 so as to surround the support rod rebar 28. The concrete formwork 32 is installed in (4th process).

Next, as shown in FIG. 3C, concrete 34 that is integrally coupled to the side wall 38 is placed inside each groove 26 and inside each concrete mold 32, and the outside of one surface of the side wall 38 is outside. Reinforcing struts 30 made up of RC pillars projecting over the entire length of the groove 26 are constructed (fifth step).
FIG. 6 shows a perspective view of the digging road 4 reinforced by the reinforcing columns 30.
Similar to the second embodiment, the reinforcing strut 30 includes an SRC including a steel frame 32, a strut rebar 28 attached around the steel frame 32, and a concrete 34 embedded with them. Of course, it may be a pillar.

According to the third embodiment, the side wall 38 is exposed so as to expose a plurality of locations spaced in the extending direction of the side wall 38 on one surface of the side wall 38 of the moat split road 4 buried in the ground. The first step of excavating the working hole 22 extending in the vertical direction along one surface is performed, the second to fourth steps are performed in the working hole 22, and the one side wall 38 is The moat split road 4 was reinforced by performing the fifth step from the ground surface.
Accordingly, it is sufficient to secure a working space on the side and upper side of the side wall 38, and it is not necessary to construct from the inside of the moat split road 4, that is, from the roadway side. The reinforcement work of the Horiwari road 4 can be performed without restricting the above, and the reinforcement work can be completed without impairing the function of the transportation system.
In addition, since the reinforcement work can be performed without restricting the traffic of the vehicle, the construction is not limited to the night when the vehicle travels less and can be performed during the day, which is advantageous in improving the construction efficiency.
Moreover, since the extending direction of the reinforcing column 30 is the vertical direction as in the first embodiment, it is advantageous in covering the shear fracture lines in various directions assumed at the time of the earthquake. This is advantageous for securing the reinforcing performance.

(Fourth embodiment)
Next, a fourth embodiment will be described.
As shown in FIG. 7, in the fourth embodiment, a case where the concrete structure is a retaining wall 6 will be described.
As shown in FIGS. 7 and 8, the retaining wall 6 includes a rectangular plate-like floor slab 40 and a vertical wall 42 erected from one side of the floor slab 40, and has a L-shaped cross section.
The vertical wall 42 constitutes a wall portion having an elongated cross-sectional shape in the vertical direction and extending in the horizontal direction.
The floor slab 40 and the vertical wall 42 are integrally formed of reinforced concrete.
Filling is performed on the upper surface of the floor slab 40 of the retaining wall 6 and the back surface of the vertical wall 42.
The retaining wall 6 is constructed by cast-in-place concrete, or is constructed by arranging precast members.
In the figure, reference numeral 44 denotes an automobile road or a railroad track provided in front of the vertical wall 42.

Next, a method for reinforcing the retaining wall 6 will be described with reference to FIGS.
As shown in FIG. 3 (A), as in the first embodiment, a plurality of locations spaced in the extending direction of the vertical wall 42 are exposed on one surface of the vertical wall embedded in the ground. As described above, the working hole 22 extending in the vertical direction along one surface of the vertical wall 42 is excavated (first step).

  Next, in the work hole 22, one of the vertical walls 42 is exposed so as to expose the reinforcing bars 20 embedded on the one surface side from the upper end to the lower end of the one surface of the vertical wall 42 at the plurality of locations. A groove 26 that is open and extends in the vertical direction is formed on the side of the surface (second step).

Next, as shown in FIG. 3 (B), reinforcing bar support rods 28 for reinforcement columns are arranged along the respective groove portions 26 in the working hole 22, and at that time, The part is positioned in the groove part 26 (third step).
And the part of the reinforcing bar 28 for pillars located in the groove part 26 is combined with the reinforcing bar embedded in the vertical wall 42.

  Next, in the working hole portion 22, each groove portion 26 is connected to the inside of the groove portion 26 so as to divide the space portion extending over the entire length in the extending direction of the groove portion 26 so as to surround the support rod rebar 28. The concrete formwork 32 is installed in (4th process).

Next, as shown in FIG. 3C, concrete 34 that is integrally coupled to the vertical wall 42 is placed inside each groove 26 and each concrete mold 32, and one surface of the vertical wall 42 is placed. Reinforcing struts 30 made of RC pillars projecting outside are constructed over the entire length of the groove 26 (fifth step).
FIG. 8 shows a perspective view of the retaining wall 6 reinforced by the reinforcing support 30.
Of course, as in the second embodiment, the reinforcing column 30 may be an SRC column.

According to the fourth embodiment, the vertical wall is exposed so as to expose a plurality of positions spaced in the extending direction of the vertical wall 42 on one surface of the vertical wall 42 of the retaining wall 6 embedded in the ground. The first step of excavating the work hole 22 extending in the vertical direction along the one surface of the work 42 is performed, the second to fourth processes are performed in the work hole 22, and the vertical wall 42 The retaining wall 6 was reinforced by performing the fifth step from the ground on the one surface.
Therefore, it is sufficient to secure a working space on the side and the upper side of the vertical wall 42, and it is not necessary to construct from the front of the vertical wall 42, that is, from the side of the automobile road (railway track) 44. Similarly to the form, the reinforcement work of the retaining wall 6 can be performed without restricting the passage of the vehicle, and the reinforcement work can be completed without impairing the function of the transportation facility.
In addition, since the reinforcement work can be performed without restricting the traffic of the vehicle, the construction is not limited to the night when the vehicle travels less and can be performed during the day, which is advantageous in improving the construction efficiency.
Moreover, since the extending direction of the reinforcing column 30 is the vertical direction as in the first embodiment, it is advantageous in covering the shear fracture lines in various directions assumed at the time of the earthquake. This is advantageous for securing the reinforcing performance.

(Fifth embodiment)
Next, a fifth embodiment will be described.
As shown in FIG. 9, in the fifth embodiment, a case where the concrete structure is a bridge abut 8 will be described.
As shown in FIGS. 9 and 10, the bridge abutment 8 constitutes a part of the bridge 9 on which the automobile travels, and includes an abutment frame 46 and an abutment wall portion 48.
The abutment housing 46 has a height and a width extending in the width direction of the bridge 9.
Filling is performed on the back of the abutment housing 46.
A seat surface 4602 on which an end portion of the bridge girder 50 is installed is formed on the upper portion of the abutment housing 46, and the abutment wall portion 48 is erected from a position adjacent to the seat surface 4602, and the upper end surface 4802 of the abutment wall portion 48. Is substantially the same height as the upper surface of the bridge girder 50.
The abutment wall portion 48 forms a wall portion having an elongated cross-sectional shape in the vertical direction and extending in the horizontal direction.
The back surfaces of these abutment housings 46 and abutment wall portions 48 are covered with embankment.

Next, a method for reinforcing such a bridge abut 8 will be described with reference to FIGS. 3 (A) to 3 (C).
As shown in FIG. 3A, as in the first embodiment, a plurality of locations spaced in the extending direction of the abutment wall 48 on one surface of the abutment wall 48 embedded in the ground. The work hole 22 extending in the vertical direction along one surface of the abutment wall 48 is excavated so as to be exposed (first step).

  Next, in the work hole 22, the rebar 20 embedded on the one surface side is exposed from the upper end to the lower end of one surface of the abutment wall portion 48 at the plurality of locations. A groove portion 26 that is open and extends in the vertical direction is formed on the side of one surface (second step).

Next, as shown in FIG. 3 (B), reinforcing bar support rods 28 for reinforcement columns are arranged along the respective groove portions 26 in the working hole 22, and at that time, The part is positioned in the groove part 26 (third step).
Then, the portion of the rebar for reinforcing rod 28 located in the groove 26 is joined to the reinforcing bar embedded in the abutment wall 48.

  Next, as shown in FIG. 3C, in the working hole portion 22, each groove portion 26 communicates with the inside of the groove portion 26 and surrounds the periphery of the supporting rod rebar 28, and extends in the extending direction of the groove portion 26. The concrete formwork 32 is installed so as to partition the space extending over the entire length (fourth step).

Next, concrete 34 that is integrally coupled to the wall portion is placed inside each groove portion 26 and inside each concrete formwork 32, and is composed of RC pillars that protrude outside one surface of the abutment wall portion 48. The reinforcing column 30 is constructed over the entire length of the groove 26 (fifth step).
FIG. 10 shows a perspective view of the bridge abutment 8 reinforced by the reinforcing column 30.
Of course, as in the second embodiment, the reinforcing column 30 may be an SRC column.

According to the fifth embodiment, so as to expose a plurality of positions spaced in the extending direction of the abutment wall portion 48 on one surface of the abutment wall portion 48 of the bridge abut 8 embedded in the ground, The first step of excavating the working hole 22 extending in the vertical direction along the one surface of the abutment wall portion 48 is performed, and the second to fourth steps are performed in the working hole 22. The bridge abutment 8 is reinforced by performing the fifth step from the ground on the one surface of the abutment wall 48.
Therefore, when the bridge 9 has a plurality of lanes, only the portion of the abutment wall portion 48 corresponding to a part of the lane of the abutment wall portion 48 is subjected to the traffic restriction and the traffic restriction is performed for the remaining lanes. If not, the reinforcement work can be completed without impairing the function of transportation.
In addition, since the reinforcement work of the bridge abutment 8 can be performed without completely prohibiting the passage of vehicles, the construction is not limited to the night when the vehicle travels less and can be performed even during the day, improving the construction efficiency. This is advantageous.
Further, as in the first embodiment, the extending direction of the reinforcing column 30 is the vertical direction, which is advantageous in covering the shear fracture lines in various directions assumed at the time of the earthquake. This is advantageous for securing the reinforcing performance.

  2 ... Underground tunnel, 4 ... Digging road, 6 ... Retaining wall, 8 ... Bridge abut, 9 ... Bridge, 10 ... Box culvert, 12 ... Bottom wall, 14 ... Side wall, 20 ... Rebar , 22... Hole for work, 26... Groove, 28 .. reinforcing bar for support, 30 .. reinforcing column, 32 .. steel frame, W .. web, F .. flange, S .. stud, 34. Concrete, 36 …… Bottom wall, 38 …… Side wall, 40 …… Floor slab, 42 …… Vertical wall, 46 …… Abutment frame, 48 …… Abutment wall, 50 …… Bridge girder.

Claims (7)

A wall portion made of reinforced concrete having an elongated cross-sectional shape in the vertical direction and extending in the horizontal direction, the wall portion having reinforcing bars embedded on both sides in the thickness direction, and the wall portion One surface in the thickness direction of the is a method of reinforcing a concrete structure embedded in the ground,
A working hole extending in the vertical direction along the one surface of the wall so as to expose a plurality of locations spaced in the extending direction of the wall on the one surface of the wall. A first step of drilling,
In the working hole, the side of the one side of the wall is exposed from the upper end to the lower end of the one side of the wall at the plurality of locations so as to expose the reinforcing bars embedded in the one side. A second step of forming a groove portion that is open and extends in the vertical direction;
A third step of arranging reinforcing bars for supporting pillars extending in the vertical direction along the respective groove portions and partly entering the inside of the groove portion in the working hole portion;
Within the working hole, a concrete formwork is installed so as to partition a space portion extending over the entire length in the extending direction of the groove portion so as to communicate with the inside of each groove portion at the plurality of locations and surround the reinforcing bar for the column. A fourth step;
Reinforcing struts that protrude outwardly from one surface of the wall portion and are integrally coupled to the wall portion by placing concrete in the groove portions and the concrete formwork over the entire length of the groove portion. A fifth step to build,
A method for reinforcing a concrete structure, comprising: In the third step, the portion of the supporting bar located inside the groove is combined with the reinforcing bar embedded on the one surface side of the wall,
The method for reinforcing a concrete structure according to claim 1. In the third step, in the work hole portion, a steel frame that extends in the vertical direction so that a part thereof enters the inside of the groove portion along the groove portion and the reinforcing bar for the support is wound is provided. Arranged,
The reinforcement of the reinforcing bar for the support is made by arranging the steel frame,
The method for reinforcing a concrete structure according to claim 1 or 2, characterized in that The concrete structure is an underground tunnel for railway constructed by being buried in the ground with a large number of box culverts connected in the axial direction thereof,
The box culvert has a rectangular plate-like bottom wall on which rails for running a vehicle are laid, two side walls rising from both ends in the width direction of the bottom wall, and a rectangular plate-like shape connecting the upper ends of the two side walls. With ceiling walls,
The wall portion is the two side walls.
The method for reinforcing a concrete structure according to any one of claims 1 to 3, wherein: The concrete structure includes a bottom wall constituting a roadbed and two side walls standing from both ends in the width direction of the bottom wall, and is a split road installed in a groove excavated in the ground,
The wall portion is the two side walls.
The method for reinforcing a concrete structure according to any one of claims 1 to 3, wherein: The concrete structure includes a rectangular plate-like floor slab and a vertical wall standing from one side of the floor slab, and is embanked on the floor slab on one surface side in the thickness direction of the vertical wall. A retaining wall,
The wall portion is the vertical wall.
The method for reinforcing a concrete structure according to any one of claims 1 to 3, wherein: The concrete structure includes an abutment housing in which an end portion of an abutment girder is installed, and an abutment wall portion erected from an upper portion of the abutment housing, and the abutment wall on one surface side in the thickness direction of the abutment wall portion. It is a bridge abut embanked on the frame,
The wall is the abutment wall.
The method for reinforcing a concrete structure according to any one of claims 1 to 3, wherein:

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