JP2013194487A - Method for reinforcing road - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for reinforcing a road capable of preventing cavities from forming in spaces between reinforcement bodies when reinforcing a road by a method of arranging reinforcement bodies.SOLUTION: The method for reinforcing a road is a method for reinforcing a road 100 by laying reinforcement bodies 21 extending in a fixed direction, under the road. The method comprises: a concavity recess forming step, forming a concavity recess 131 in a ground 130 under the road 100; a bag bodies installing step, installing a plural of long and narrow bag bodies 21a in the concavity recess 131 with the bag bodies arranged generally in parallel; a fluid filler pouring step, pouring a first curable material 122 into the concavity recess 131 from above the long and narrow bag bodies 21a installed in the concavity recess 131 in the bag bodies installing step; a bag bodies filling step, filing the long and narrow bag bodies 21a with a second curable material 121 after the fluid filler pouring step and before the first curable material 122 cures; and a roadbed forming step, putting a roadbed material in the concavity recess 131 and forming a roadbed 7 under the road 100 after the bag bodies filling step.

Description

  The present invention relates to a road reinforcement method.

  On roads (including on-site roads such as factory facilities), securing emergency vehicles such as fire engines and ambulances is extremely important at the time of an earthquake, especially immediately after the earthquake, in order to prevent the spread of earthquake damage. is there. However, in past earthquakes, steps and irregularities are generated on the road surface, and a situation that hinders emergency vehicle traffic has occurred. In order to prevent the occurrence of such a road step or unevenness, it is effective to provide a reinforcing body having bending rigidity below the road surface. As the reinforcing body having bending rigidity, for example, the technique of Patent Document 1 below can be used. In Patent Document 1, it is proposed that a flexible hose is attached to a flexible sheet and laid on the ground, and a mortar is filled in a cloth hose to form a cylindrical rigid reinforcement. Yes.

Japanese Patent No. 3729169

  Reinforcement as an earthquake countermeasure for roads requires higher strength than reinforcement of soft ground, so if the above-mentioned method of arranging reinforcements is adopted, reinforcement is performed at a higher density and with smaller intervals. The body needs to be arranged. The gap between the reinforcing bodies needs to be filled with some filler, but since the gap is small, the filler may not be properly filled. When the cylindrical reinforcing bodies are arranged with a small gap, it is difficult to properly fill the lower half of the gap with the filler from above. In addition, the gap may not be properly filled and a cavity may be generated. Due to this cavity, there is a problem that the adhesion between the reinforcing body and the ground is weak and sliding is likely to occur, and there is a problem that the integrity of the reinforcing bodies is lost and the reinforcing effect is reduced.

  In view of these problems, an object of the present invention is to provide a road reinforcement method capable of suppressing the generation of a cavity in a gap between reinforcement bodies in reinforcement of a road in which reinforcement bodies are arranged. .

  The road reinforcing method according to the present invention includes a reinforcing body having a bag body extending in a predetermined direction and a compression resistor formed by filling the bag body with a fluid filler and embedded under the road. A method of reinforcing a road for reinforcing a road, a recess forming step for forming a recess in the ground below the road, and a bag body installation step for installing the plurality of bag bodies in the recess in a state of being arranged substantially in parallel, From the top of the bag body set in the recess in the bag body setting step, after the flowable filler charging step of charging the curable first fluid filler into the recess, and after the fluid filler charging step, A bag body filling step in which the second fluid filler is filled in the bag before the first fluid filler is hardened, and a roadbed material under the road after the bag body filling step is filled with the roadbed material. And a roadbed forming step of forming

  In the reinforcing method, a compression resistor is formed inside the bag body by filling the second fluid filler into the bag body arranged substantially in parallel under the road. A road is reinforced by embedding a plurality of reinforcing bodies composed of such bag bodies and compression resistors substantially in parallel under the road. In the reinforcing method, the bag body is installed in the recess in the bag body installation process, the first fluid filler is introduced from above the bag body in the fluid filler introduction process, and then the second fluid filling process in the bag body filling process. The fluid filler is filled into the bag body. In the bag filling process, the first fluid filler in the recesses flows while following the shape of the bag as the bag expands due to the filling of the second fluid filler. The first fluid filler then flows into the space below the gap between the bags, and the space is filled with the first fluid filler. After that, the first fluid filler is finally cured, and the space below the gap between the bags (the gap between the reinforcing bodies) is filled, thereby suppressing the formation of a cavity in the gap between the reinforcing bodies. can do.

  Further, the first fluid filler may include a curing retarder. According to this configuration, since the hardening of the first fluid filler introduced into the recess in the fluid filler filling step is delayed, time can be afforded in the next bag filling step.

  The specific gravity of the second fluid filler may be larger than the specific gravity of the first fluid filler. According to this configuration, when the second fluid filler is filled in the bag body in the bag filling step, the bag body can be prevented from being lifted by the buoyancy from the first fluid filler. Therefore, the space below the gap between the bags is smoothly filled with the first fluid filler.

  Further, the road reinforcing method of the present invention is such that the first fluid filler is applied from above the bag body filled with the second fluid filler after the bag body filling step and before the roadbed forming step. You may further provide the fluid filler addition process which carries out additional injection in a recessed part.

  According to the road reinforcement method of the present invention, it is possible to suppress the formation of cavities in the gaps between the reinforcement bodies in the road reinforcement in which the reinforcement bodies are arranged.

It is sectional drawing which shows an example of the reinforcement structure of the road constructed | assembled by the reinforcement method of this invention. FIG. 2 is a perspective view showing a positional relationship between a reinforcing layer and a box culvert in the reinforcing structure of FIG. 1. (A) is a top view of the reinforcement part in the recessed part formation process and bag body installation process of the reinforcement method which concerns on embodiment of this invention, (b) is the sectional drawing. (A) is sectional drawing of the reinforcement part in the flowable filler injection | throwing-in process of the reinforcement method which concerns on embodiment of this invention, (b) is sectional drawing seen from the side. It is sectional drawing of the reinforcement part in the bag body filling process of the reinforcement method which concerns on embodiment of this invention. It is sectional drawing of the reinforcement part in the fluid filler addition process of the reinforcement method which concerns on embodiment of this invention. It is sectional drawing of the reinforcement part after the roadbed formation process of the reinforcement method which concerns on embodiment of this invention. It is sectional drawing of the reinforcement part in the modification of the reinforcement method which concerns on embodiment of this invention. (A) is a top view of the reinforcement part in the modification of the reinforcement method which concerns on embodiment of this invention, (b) is the sectional drawing.

  Hereinafter, embodiments of a road reinforcement method according to the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a cross-sectional view of a road reinforcing structure 1 of a road 100 reinforced by the reinforcing method of the present invention. The direction orthogonal to the paper surface of FIG. 1 is the traveling direction of the road 100. The road 100 passes over the box culvert 103 buried underground. An embankment layer 3 by backfilling is provided on the box culvert 103, and a reinforcement layer 5 for reinforcing the road 100 is provided on the embankment layer 3. Further, a roadbed 7 is provided on the reinforcing layer 5, and an asphalt pavement 9 is provided on the roadbed 7.

  As shown in FIG. 2, the road 100 extends across the box culvert 103. In FIG. 2, illustration of a part of the reinforcing layer 5, the embankment layer 3, the roadbed 7, and the asphalt pavement 9 is omitted for easy understanding of the positional relationship between the road 100 and the box culvert 103. In the underground structure under the road 100, the underground structure portion without the box culvert 103 and the underground structure portion with the box culvert 103 are discontinuously changed in the traveling direction of the road 100. As in this example, a boundary line between discontinuous underground structures is called a “discontinuous structure boundary line”. In the present embodiment, the edge portion 103a of the box culvert 103 corresponds to a discontinuous structure boundary line.

  The subsidence of the underground structure portion without the box culvert 103 and the underground structure portion with the box culvert 103 are different in the ground subsidence state at the time of the earthquake. Steps and irregularities are likely to occur along the edge portion 103a. In this way, when the road 100 exists across the discontinuous structure boundary line, it is necessary to suppress the steps and unevenness of the road 100 that occur along the discontinuous structure boundary line during an earthquake. Therefore, the reinforcing layer 5 described above has a function of suppressing the generation of a road 100 step and unevenness particularly in the edge portion 103a. Here, it is assumed that the road 100 extends in a direction orthogonal to the edge portion 103a.

  Hereinafter, a specific structure of the reinforcing layer 5 will be described. As shown also in FIG. 2, the reinforcing layer 5 is embedded in the basement of the road 100 so as to extend in the traveling direction of the road 100. The reinforcing layer 5 has a plurality (five in the present embodiment) of reinforcing bodies 21 extending substantially parallel to each other in the traveling direction of the road 100. For example, the reinforcing bodies 21 have a cylindrical shape with a diameter of about 20 cm extending in the traveling direction of the road 100 and are arranged in the transverse direction of the road 100 at intervals of about 0 to 20 cm. The reinforcing body 21 has an elongated bag body 21a elongated in the traveling direction and a compression resistor 21b formed inside the elongated bag body 21a. The elongate bag body 21a is selected from a material that allows air to pass through without passing through a second fluid filler described later, and is made of, for example, a polyester woven fabric. The compression resistor 21b is formed by injecting and filling a second fluid filler into the elongated bag 21a.

  The reinforcing layer 5 includes a cured body 22 formed so as to fill the gaps between the plurality of reinforcing bodies 21. The cured body 22 is formed by injecting and filling a first fluid filler, which will be described later, into the gaps between the reinforcing bodies 21 and curing. The hardened body 22 functions as a compression resistor while fixing the positional relationship in the arrangement direction of the reinforcing bodies 21 (cross direction of the road 100).

  The “compressive resistor” means an object made of a material that resists compressive stress. For example, examples of the compression resistor include hardened mortars. As the second fluid filler forming the compression resistor 21b and the first fluid filler forming the cured body 22, a fluid curable material (for example, mortars) may be employed. You may employ | adopt the filler (For example, the mixture of sand and water) which does not contain a solidification material. Further, the first fluid filler and the second fluid filler may be the same or different from each other.

  Below, the case where curable materials, such as mortars, are used as an example is demonstrated as a 1st and 2nd fluid filler. That is, the compression resistor 21b is formed by injecting, filling, and curing a fluid curable material (referred to as “second curable material 121”) inside the elongated bag body 21a. The cured body 22 is formed by filling and curing a fluid curable material (referred to as “first curable material 122”) in the gaps between the reinforcing bodies 21.

  Then, the reinforcement method of the road 100 which builds the above reinforcement layers 5 is demonstrated.

(Recess formation process)
First, as shown in FIGS. 3A and 3B, at the stage where the embankment layer 3 is provided on the box culvert 103 in the ground 130 below the location to be reinforced of the road 100, above the embankment layer 3. A concave portion 131 having a rectangular shape in plan view is formed on the top. When the reinforcing layer 5 is provided under the existing road 100, the recess 131 is formed by excavating the roadbed 7 or the like.

(Bag body installation process)
Subsequently, a plurality (five in this embodiment) of elongated bag bodies 21 a are laid inside the recess 131. In this case, the elongated bag bodies 21a extend in the traveling direction of the road 100 and are arranged substantially parallel to each other. At this time, an introduction nozzle 21c (see FIG. 4B) for introducing the curable material into the bag is attached to one end portion in the longitudinal direction of the elongated bag body 21a. The other end side of the elongated bag 21a is closed. The elongate bag 21a before the curable material is injected is crushed by its own weight and forms a flat sheet as a whole. The elongated bag bodies 21a may be joined to each other by a method such as stitching, stringing, bonding, or binding in order to prevent positional displacement.

  In order to reduce the number of introduction nozzles 21c, a branch tube that distributes the fluid filler supplied from the introduction nozzle 21c to the plurality of elongated bags 21a may be further provided. The branch tube is interposed between one introduction nozzle 21c and the end of each of the plurality of elongated bags 21a, and may be made of the same material as the elongated bags 21a, for example. In this case, the curable material introduced from one introduction nozzle 21c passes through the branch tube and branches to be distributed to the plurality of elongated bags 21a.

(Flowable filler input process)
Subsequently, as shown in FIGS. 4A and 4B, the first curable material (first fluid filler) 122 in a fluid state from above the elongated bag body 21 a installed in the recess 131. Into the recess 131. The first curable material 122 includes a curing retarder. Here, when the first curable material 122 is mortar or fluidized soil, examples of the curing retarder include oxycarboxylic acid-based retarders “Floric T” “Geoliter” manufactured by Floric Co., Ltd. An organic carboxylic acid retarder “Jet Setter” manufactured by Oniko Chemico Co., Ltd. can be used. The first curable material 122 accumulates in the recess 131 using the recess 131 as a mold, and the elongated bag body 21 a is submerged under the liquid surface of the first curable material 122. However, the tip of the introduction nozzle 21 c protrudes upward from the liquid surface of the first curable material 122.

(Bag filling process)
Then, as shown in FIG. 5, before the 1st curable material 122 in the recessed part 131 hardens | cures, the 2nd hardening of a fluid state is carried out inside each elongate bag body 21a via the introduction nozzle 21c (FIG. 4). Material (second fluid filler) 121 is injected under pressure. Here, a material having a specific gravity greater than that of the first curable material 122 is used as the second curable material 121. By injecting the second curable material 121, each elongated bag body 21a swells in a cylindrical shape. Further, since air remaining inside the elongated bag body 21a passes through the elongated bag body 21a and is discharged to the outside, the entire elongated bag body 21a is filled with the second curable material 121. When the injection is completed, it is preferable that at least the lower half of the elongated bag body 21a is submerged under the liquid surface of the first curable material 122. In addition, as shown in FIG. 5, the upper portion of the elongated bag body 21 a may protrude above the liquid surface of the first curable material 122. After the injection of the second curable material 121 into the elongated bag body 21a is completed, the introduction nozzle 21c is closed.

Here, since the specific gravity of the second curable material 121 is larger than the specific gravity of the first curable material 122, it is avoided that the elongated bag body 21a during the filling operation is lifted by buoyancy from the first curable material 122, The state where the elongated bag body 21a is grounded to the bottom surface of the recess 131 is maintained. For this purpose, a foaming agent (for example, “Terfoam” manufactured by Ternite Co., Ltd.) is mixed with the first curable material 122 to reduce the specific gravity, and the buoyancy acting on the elongated bag body 21a is reduced. It may be lowered.
In this bag body filling step, the first curable material 122 in the recess 131 flows while following the shape of the bag body as the elongated bag body 12a expands due to the filling of the second curable material 121. Then, the first curable material 122 flows into the space below the gap between the elongated bag bodies 21 a and the space is filled with the first curable material 122.

  Then, the 2nd curable material 121 inject | poured into each elongate bag body 21a and the 1st curable material 122 in the recessed part 131 are hardened by leaving still for predetermined time. When the second curable material 121 in each elongated bag 21a is cured, the compression resistor 21b is formed, and the reinforcing body 21 is formed.

(Flowable filler addition process)
Subsequently, as shown in FIG. 6, the first curable material 122 is further charged into the recess 131 from the elongated bag body 21 a filled with the second curable material 121. At this time, the entire reinforcing body 21 may be immersed under the liquid surface of the first curable material 122. Thereafter, the cured body 22 is formed by allowing to stand for a predetermined time and curing the first curable material 122 in the recess 131. This fluid filler addition step may be performed before the first curable material 122 previously charged in the fluid filler loading step is cured. Moreover, this fluid filler addition step may be performed before the second curable material 121 in each elongated bag body 21a is cured. Finally, the first curable material 122 in the recess 131 and the second curable material 121 in the elongated bag body 21a are cured, whereby the reinforcing layer 5 is completed.

(Roadbed formation process)
Thereafter, as shown in FIG. 7, the roadbed material is put into the recess 131 from above the reinforcing layer 5 and laminated to form the roadbed 7. And the asphalt pavement 9 is formed on the roadbed 7, and the reinforcement structure of the road 100 is completed. As the roadbed material forming the roadbed 7, for example, a granular material such as crushed stone, gravel, slag, recycled aggregate, sand, or a mixture of these materials with a stabilizing material such as cement, lime, asphalt, or the like is employed.

  Then, the effect by the reinforcement supplement method of the road 100 mentioned above is demonstrated.

  In the reinforcing method described above, the second curable material 121 is filled in the elongated bag body 21a arranged substantially in parallel under the road 100, whereby the compression resistor 21b is formed inside the elongated bag body 21a. The road 100 is reinforced by embedding a plurality of reinforcing bodies 21 composed of the elongated bag bodies 21a and the compression resistance bodies 21b under the road 100 substantially in parallel. In the reinforcing method, the elongate bag body 21a is installed in the recess 131 in the bag body installation process, the first curable material 122 is introduced from above the elongate bag body 21a in the flowable filler charging process, and then the bag body filling. In the process, the second curable material 121 is filled into the elongated bag body 21a.

  In the bag body filling step, the first curable material 122 in the recess 131 flows while following the shape of the elongated bag body 21a as the elongated bag body 21a expands due to the filling of the second curable material 121. . Then, the first curable material 122 flows into the space below the gap between the elongated bag bodies 21 a and the space is filled with the first curable material 122. After that, the first curable material 122 is finally cured, and the space below the gap between the elongated bag bodies 21a (the gap between the reinforcement bodies 21) is filled with the cured body 22, so that the gap between the reinforcement bodies 21 It is possible to suppress the formation of cavities.

  In particular, when the reinforcing bodies 21 are arranged so as to contact each other as illustrated in FIG. 1 or the like, or when the reinforcing bodies 21 are arranged at a narrow interval, the lower half of the gap between the reinforcing bodies 21. It is difficult to fill the filler from above. On the other hand, according to the above-described reinforcing method, the first curable material 122 can be appropriately distributed in the gap between the reinforcing bodies 21.

  By appropriately filling the gaps between the reinforcing bodies 21 with the cured body 22, after the reinforcement layer 5 is completed, the reinforcing bodies 21 move in the horizontal direction, or the reinforcing bodies 21 bite into the ground below and the road surface is The possibility that the ground sinks or the ground above the reinforcing layer 5 such as the roadbed 7 sinks and the road surface collapses is reduced. Moreover, in the reinforcement layer 5, since the bending rigidity resulting from the compressive strength of the hardening body 22 is added to the bending rigidity of the reinforcement body 21 itself, the reinforcement effect of the road 100 improves.

  In addition, since the main purpose of the formation of the cured body 22 is to eliminate the gap between the reinforcing bodies 21, the first curable material 122 has a lower quality than the second curable material 121 (compressive strength and compression rigidity are lower). Small). However, a high quality material may be used as the first curable material 122. In this case, the above-described effect of improving the bending rigidity of the reinforcing layer 5 can be further enhanced.

  As a result, according to the reinforcing structure 1 and the reinforcing method of the road 100, in the reinforcement of the method in which the reinforcing bodies 21 are arranged, the granular material constituting the roadbed 7 is prevented from dropping, and the reinforcing body 21 is prevented from biting into the ground. Integration of the reinforcing bodies 21 can be achieved.

  Moreover, since the 1st curable material 122 thrown in by a fluid filler introduction process contains a hardening retarder, the hardening rate of the 1st curable material 122 in a recessed part becomes slow, and it is in the bag body filling process of the next process. Can afford time.

  Although one embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and may be modified without changing the gist described in each claim. For example, the fluid filler addition step may be omitted. In this case, the space above the gap between the reinforcing bodies 21 is filled with the roadbed material introduced in the roadbed forming process.

  In addition, as shown in FIG. 8, a sheet 133 (for example, a water-impervious sheet) is laid on the inner surface 131a of the recess 131 in the recess forming step, and in the fluid filler charging step, The space may be filled with the first curable material 122. According to this configuration, it is possible to suppress the first curable material 122 from penetrating from the inner surface of the recess 131 into the lower ground (for example, the embankment layer 3).

  Further, as shown in FIG. 9, the reinforcing bodies 21 at the time of completion may be bound together by a belt-like member 24. In this case, in the bag body installation step, the belt-like member 24 is previously installed so as to be bridged over the plurality of elongated bag bodies 21a, and in the bag body filling step, the elongated bag body 21a filled with the second curable material 121. It will be in the state where they were united. According to this configuration, positional deviation between the plurality of reinforcing bodies 21 can be suppressed, and the reinforcing effect of the road 100 is improved. In FIG. 9, the illustration of the first curable material 122 in the recess 131 is omitted.

  DESCRIPTION OF SYMBOLS 1 ... Road reinforcement structure, 7 ... Roadbed, 21 ... Reinforcement body, 21a ... Elongate bag body, 21b ... Compression resistor, 100 ... Road, 121 ... 2nd curable material (2nd fluidity filler), 122 ... first curable material (first fluid filler), 130 ... ground, 131 ... concave.

Claims (4)

Road reinforcement for reinforcing the road by embedding a reinforcing body having a bag body extending in a predetermined direction and a compression resistor formed by filling the bag body with a flowable filler under the road. A method,
A recess forming step of forming a recess in the ground below the road;
A bag body installation step of installing the plurality of bag bodies in the recess in a state of being arranged substantially in parallel;
From the top of the bag body installed in the recess in the bag body installation step, a fluid filler injection step of introducing a curable first fluid filler into the recess;
A bag filling step of filling the bag body with a second fluid filler after the fluid filler filling step and before the first fluid filler is cured;
A road reinforcing method comprising: a roadbed forming step of forming a roadbed under the road by introducing a roadbed material into the recess after the bag filling step.   The road reinforcing method according to claim 1, wherein the first fluid filler includes a curing retarder.   The road reinforcing method according to claim 1 or 2, wherein a specific gravity of the second fluid filler is greater than a specific gravity of the first fluid filler. After the bag body filling step and before the roadbed forming step, the first fluid filler is additionally charged into the recess from above the bag body filled with the second fluid filler. The method for reinforcing a road according to any one of claims 1 to 3, further comprising a step of adding a fluid filler.

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