JP2003321839A - Reinforced earth structure, fill reinforcing material and reinforced earth block - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a reinforced earth structure excellent in execution efficiency, stability or the like, a reinforced earth block used for a wall surface block and a bearing block to the reinforced earth structure and a fill reinforcing material for fixing the reinforced earth block. <P>SOLUTION: A plurality of wall surface blocks 1 are laminated to constitute a wall A. The back of the wall A is filled with fill 2. The fill reinforcing material 3 and the bearing block 4 as a pulling resistance member of the fill reinforcing material 3 are buried in the fill 2. The wall surface block 1 and the bearing block 4 are formed of dry blocks. Fixed gutters 1d and fixed holes 4a are respectively formed in the wall surface block 1 and the bearing block 4. A hook formed in one end 3a of the fill reinforcing material 3 inserted into each fixed gutter 1d, the other hook formed in the other end 3b is inserted into each fixed hole 4a, and both of them are filled with solidifier 6. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reinforced soil structure constructed as a retaining wall, etc., a reinforced soil block used as a wall block and a bearing block, and an embankment reinforcement, and is particularly excellent in workability and stability. ing.

[0002]

2. Description of the Related Art Up to now, a wall material such as a plurality of wall blocks and wall panels has been laminated as a reinforced soil structure constructed as a retaining wall facing a road or a residential land, for example, and a constant embankment on the back of the wall material. Each layer thickness is rolled out and compressed by each layer thickness, and reinforcing bars, strip steels, geotextiles, wire mesh, etc. are placed at regular intervals as embankment reinforcement between each layer and the tip side is fixed to the wall material. ,
A reinforced earth structure constructed by attaching a bearing plate to the other end is known.

FIG. 21 (a) shows an example thereof, in which concrete wall panels 30 are laminated in a plurality of stages,
The embankment 31 is sprinkled on the back of the embankment, and after compaction, a reinforcing bar 32 (FIG. 21 (b)) or a steel strip or a wire mesh with a pressure plate 33 attached to the other end of each embankment 31 as a embankment reinforcement material. (Hereinafter referred to as “reinforcing bar 32”) are embedded in a plurality of layers, and the tip end side 32a of each reinforcing bar 32 is connected to the wall panel 30.

In this case, especially the reinforcing bar 32 is the embankment 31.
The stability and strength of the entire embankment structure are enhanced by the restraining effect of the frictional force with the wall surface panel 30 and the embankment 31 and the reinforcing bar 32 are integrated.

The tip side 32a of each reinforcing bar 32 is
In general, it is fixed by bolts and nuts 34 to fixing fittings provided on the back surface of the wall panel 30.

Further, the bearing plate 33 attached to the other end of the reinforcing bar 32 is formed of a thin steel plate or a concrete panel, has a thin shape that is not self-supporting, and penetrates the end of the reinforcing bar 32. It is fixed by the fixing nut 35.

[0007]

However, it is difficult for the bearing plate 33 to be self-supporting by itself, and the fixing nut 35 is screwed to the end of the reinforcing bar 32 to fix it, so that the wall surface and the bearing plate 33 are stable. It is difficult to screw it while keeping the wall surface, and the wall surface tends to incline, which causes a large displacement wall surface.

Further, although it is desired to use a site-generated material as a reinforcing earthwork method, the rebar bar 32 which is usually used is galvanized.

However, although zinc plating has excellent corrosion resistance to soil having a PH of about 5 to 9, the corrosion resistance to soil on the acidic side and the alkaline side is lower than that. In order to prevent this, it is preferable to cover the reinforcing bar 32 with a synthetic resin, but in the connection method by the screwing method, the synthetic resin is broken in the thread groove and corrosion resistance cannot be obtained.

Further, even after the galvanizing, the groove is clogged with the galvanizing, and a problem is likely to occur when screwing.

In the reinforced earth construction method, the wall panel 3
The concrete panel used as 0 generally has a thickness of about 18 cm, and the area per panel is usually about 1.5 × 1.5 = 2.25 m ² , and at least four rebar bars 32 are provided on the back side. Each of the wall panels 30 stacked in a plurality of stages has at least four reinforcing bar bars 3 as a basic form, which are connected as embankment reinforcements.
It is fixed in the embankment 31 by 2.

For this reason, since the wall panel 30 of this type generally requires sufficient strength (rigidity) to withstand earth pressure, reinforcing bars are laid in the formwork, and then cement, aggregate, and It is molded by a so-called wet manufacturing method in which a curable material having sufficient fluidity made of water is poured and cured as it is.

Further, when this type of concrete panel is used as the wall panel 30, heavy equipment is required for handling such as transportation due to its large size and the like, so that it is difficult to handle at a construction site and it is wet. There is a problem that molding by the manufacturing method takes time, and that the panel is easily cracked or deformed due to the relative displacement between the compressible embankment material and the panel and the inhomogeneous wall earth pressure.Recently, dry block and geotextile Reinforced earthwork methods that combine the above have come to be used.

By the way, the size of one block used in the block-type reinforced earth method is generally 20 c in height.
It has m, width of 45 cm, and depth of about 30 cm, and the wall area per piece is about 0.92 cm ² , and 25 blocks correspond to one conventional concrete panel.

Further, since it is necessary to economically supply a considerable number of blocks of this type to the site, a curable powder having almost no fluidity is added while vibrating in the mold. It is formed by a so-called dry manufacturing method in which it is cured after being compressed and removed from the mold.

By the way, as an advantage of the block type reinforced earth method, A large number of blocks can be continuously molded by the dry method described above, the curing period is short, and the manufacturing cost is low. ． Blocks are smaller and lighter than concrete panels, so they do not require heavy equipment for transportation and are easy to handle at construction sites. Etc.

On the other hand, when the dry block thus formed is used as a wall material by the reinforced soil method, it is an excessively large design to connect the embankment reinforcement material to each block both in terms of design and economy. A wall surface is constructed by combining a block where the embankment reinforcement is connected and a block where the embankment reinforcement is not connected, or a block layer where the embankment reinforcement is connected and a block layer where the embankment reinforcement is not connected, Therefore, there are the following problems. ． Stability of unconnected blocks or block layers of embankment reinforcement. Since the block has no tensile strength, if the embankment reinforcement such as a reinforcing bar is directly connected to the wall block or the bearing block, the connecting portion of the block is easily broken. ． For the same reason as described above, when a tensile force or a compressive force acts on the block to cause bending, the block is easily broken, so that the block has to be small in size to prevent bending. ． Not only can it not be used in a state where it will be pulled, but it is also easily broken during an earthquake.

In addition, the reinforcing bar 32 is the embankment 31 that has been compacted.
Since it is only embedded between each layer of the rebar bar 3 and the rebar bar 32 and the embankment 31 in order to expect a restraining effect,
2 has to be made considerably longer, and if necessary, for example, as shown in FIG.
Although a bearing plate 33 made of a thin steel plate or a concrete panel is attached to the end of the free end side of 2, the pull-out resistance of the reinforcing bar 32 is increased, but the bearing plate 33 is tilted during and after the installation. Therefore, there is a problem in that the pullout resistance of the reinforcing bar 32 is reduced, and the wall block 30 is displaced during an earthquake.

Further, since the bolts and nuts 34 are used as the fixing metal fittings for the reinforcing bar 32, there are problems that tightening of the bolts and nuts 34 is very troublesome and the cost increases. In addition, there is a problem that pullout resistance cannot be obtained because the bolt does not function due to rusting.

In the case of the reinforced earth method using concrete panels as wall panels, the area of one panel is usually 1.5 × 1.5 = 2.25 m ² , and at least four reinforcing materials are provided therein. It is based on being connected.
Therefore, all concrete panels are anchored in the embankment by at least four.

However, in the block-type reinforced earthwork method, one block has, for example, a height of 20 cm, a width of 45 cm, and a depth of 30 cm, and the wall surface is approximately 0.09 m ^2. Therefore, one conventional panel is It corresponds to 25 blocks.

For this reason, in the block-type reinforced earthwork method, the reinforcing material is not connected to each block, but the block to which the reinforcing material is connected and the block to which the reinforcing material is not connected are combined to form the wall surface. ing.

The present invention has been made to solve the above problems, and in particular, a reinforced soil structure excellent in workability and stability, and a reinforced soil block and embankment used as wall blocks and bearing blocks. The purpose is to provide a reinforcing material.

[0024]

The embankment reinforcement material according to claim 1, wherein the embankment reinforcement material is embedded in the embankment filled in the back portion of the reinforced earth wall surface formed by laminating a plurality of wall surface blocks. The fixing is performed by inserting one end into a fixing hole or a fixing groove provided in the wall surface block.

The embankment reinforcing material according to claim 2 is a embankment reinforcing material embedded in the embankment filled in the back portion of the reinforcing earth wall surface formed by laminating a plurality of wall surface blocks, and is provided on the wall surface block. Further, the fixing is performed by inserting one end into the fixing hole or the fixing groove and filling the fixing material.

The embankment reinforcement according to claim 3 is the embankment reinforcement according to claim 1 or 2, wherein the other end is inserted into a fixing hole or a fixing groove provided in a bearing block embedded in the embankment. And is fixed by filling with a solidifying material.

The embankment reinforcement according to claim 4 is the embankment reinforcement according to claim 1 or 2, characterized in that the other end of the embankment reinforcement is fixed to the ground.

The embankment reinforcing material according to claim 5 is the embankment reinforcing material according to claim 1.
The embankment reinforcing material according to any one of 4 above is characterized in that at least one end is formed in a hook shape, an L shape, or a T shape.

The embankment reinforcing material according to claim 6 is a embankment reinforcing material that is embedded together with a bearing block in the embankment filled in the back portion of the reinforcing earth wall surface formed by stacking a plurality of wall surface blocks. And / or the other end is connected to the wall block and / or the bearing block via a fitting, and the fitting is fixed in a fixing hole or a fixing groove provided in the wall block and / or the bearing block. It is characterized by being fixed by a binder.

The embankment reinforcing material according to claim 7 is the embankment reinforcing material according to claim 1.
The embankment reinforcing material according to any of 6 is characterized in that the surface is galvanized or coated with a synthetic resin, or a zinc-plated surface is coated with a synthetic resin.

The reinforced soil block according to claim 8 is a reinforced soil block used as a wall block for holding an embankment and / or a bearing block for resisting withdrawal of an embankment reinforcement embedded in the embankment, A fixing hole or a fixing groove for fixing the embankment reinforcing material is formed, and a block reinforcing material that resists withdrawal of the embankment reinforcing material is embedded.

A reinforcing soil block according to a ninth aspect is the reinforcing soil block according to the eighth aspect, characterized in that the block reinforcing material is embedded in the embedding hole or the embedding groove by a solidifying material. .

The reinforced soil block according to a tenth aspect is the reinforced soil block according to the eighth or ninth aspect, characterized in that it is formed of a dry block.

The reinforced soil block (wall surface block and bearing block) according to the present invention, especially super-concrete concrete with zero or very few slumps, is compacted in a form using a powerful vibrator or compactor. can do.

That is, after super-compacting concrete is compacted by strong vibration and pressure, it is immediately removed from the mold, and accelerated curing is performed by steam curing or autoclave curing, whereby it is standard cured in about 8 to 20 hours. It is possible to obtain a reinforced soil block having a strength close to that of the case of 25 days. Therefore, the dry block according to the present invention may be restated as a block obtained by instant demolding.

The super-mixed concrete in this case has no slump consisting of cement, aggregate and water, or is very close to zero (almost zero). For example, the water-cement ratio is 39% and the amount of cement is 400 kg. , Coarse aggregate (10
(0 m or less) is 50%, the fine aggregate is (2 mm or less), and the slump is zero, a dry block having a strength of 400 Kg / cm ² can be obtained.

As the embankment reinforcing material, a rebar bar such as round steel or deformed bar, or a strip steel material can be used.
Further, the embankment reinforcing material may be fixed to the reinforcing soil block when forming the reinforcing soil block (wall surface block and bearing block), or may be fixed during the construction.

As the block reinforcing material (resistive member), a rod-shaped member such as a reinforcing bar, a plate-shaped member such as a steel plate, or a mesh member such as wire mesh can be used. Metal fibers, synthetic resin fibers, carbon fibers or glass fibers may be mixed as a block reinforcing material at the positions where they occur.

Further, as the solidifying material filled in the fixing holes or fixing grooves, high-strength and early-strength mortar, resin mortar, or the like can be used, and the solidifying material is basically filled at the time of construction.

The reinforced earth structure according to claim 11 is a reinforced earth structure in which a reinforced earth material having a bearing block is embedded in an embankment filled in a back portion of a reinforced earth wall surface. And an embedding hole or an embedding groove is formed in the embedding hole, and a resistance member that resists withdrawal of the embankment reinforcement is embedded in the embedding hole or embedding groove by a solidifying material. In this case, a rod-shaped member such as a reinforcing bar or a plate-shaped member such as a steel plate may be embedded as the resistance member.

The reinforced soil structure according to claim 12 is reinforced by installing a reinforced soil block as a wall block for holding the embankment and / or a bearing block for resisting pulling out of the embankment reinforcement embedded in the embankment. In the soil structure,
A fixing hole or a fixing groove is formed in the reinforced soil block,
The embankment reinforcing material is fixed in the fixing hole or the fixing groove by a solidifying material.

The reinforced earth structure according to claim 13 is a reinforced earth structure in which a back wall of a reinforced earth wall surface formed by stacking wall blocks is filled with an embankment, and an embankment reinforcement material is embedded in the embankment. A fixing hole or a fixing groove is formed in the wall surface block, and one end of the embankment reinforcing material or a connecting member for connecting the embankment reinforcing material is fixed by a solidifying material in the fixing hole or the fixing groove. It is what

The reinforced soil structure according to claim 14 is a reinforced soil structure in which a plurality of wall blocks for retaining embankment are laminated, and the wall blocks are connected by a connecting member, and the connecting member is connected to the wall block. It is characterized in that it is inserted into the formed fixing hole or fixing groove or fixed by a solidifying material.

The reinforced soil structure according to claim 15 is the reinforced soil structure according to any one of claims 11 to 14,
A plurality of wall blocks are laminated as the reinforced soil wall surface, and wall blocks to which the embankment reinforcement is fixed and wall walls where the embankment reinforcement are not fixed are laminated as the wall blocks adjacent to each other in the lateral direction. To do.

The reinforced earth structure according to claim 16 is the reinforced earth structure according to any one of claims 11 to 14.
A plurality of wall blocks are laminated as the reinforced soil wall surface, and the wall blocks to which the embankment reinforcement is fixed and the wall blocks where the embankment reinforcement is not fixed are laminated as the wall blocks vertically adjacent to each other. Is.

A reinforced earth structure according to claim 17 is the reinforced earth structure according to any one of claims 11 to 16, wherein
A cavity is provided between the wall blocks laminated as the reinforced soil wall surface and / or the wall blocks adjacent to each other in the lateral direction, and the cavity is filled with crushed stone or gravel, a solidifying material, or a block between the left and right wall blocks. It is characterized by being integrated.

The reinforcing earth structure according to claim 18 is the reinforcing earth structure according to any one of claims 11 to 17,
The reinforced soil wall surface is characterized in that wall surfaces are formed by stacking wall surface blocks while combining them by interlocking.

A reinforced earth structure according to claim 19 is the reinforced earth structure according to any one of claims 11 to 18,
The wall block has a front flange, a rear flange and a web,
Alternatively, it is characterized by being formed from a surface flange and a web.

The reinforced earth structure according to claim 20 is the reinforced earth structure according to any one of claims 11 to 19, wherein
The embankment reinforcement is characterized by being a rod-shaped reinforcement, a strip-shaped reinforcement, a mesh material or a geotextile.

The reinforced earth structure according to claim 21 is the reinforced earth structure according to any one of claims 11 to 20.
It is characterized by being filled with styrofoam, blocks, foam mortar or soil cement as embankment.

In this case, in particular, styrofoam, block, foam mortar or soil cement as the embankment may be filled in a certain range on the back of the wall surface of the reinforced soil, and a locally generated material or the like may be filled behind it as the embankment. By doing so, the earth pressure acting on the reinforced soil wall surface can be reduced.

The reinforced soil structure according to claim 22 is the reinforced soil structure according to any one of claims 11 to 21, wherein
Crushed stone on the back of the reinforced soil wall surface, which is made by stacking wall blocks.
It is characterized by being filled with gravel, sandy soil, or solidified soil.

In this case, in particular, crushed stone, gravel, sandy soil or solidified soil as embankment may be filled in a certain range on the back of the wall surface of the reinforced soil, and a locally generated material or the like may be filled behind it as embankment. . By doing this, crushed stones and gravel are less likely to sink, so deformation of the embankment reinforcement due to settlement of the embankment,
Further, it is possible to significantly reduce the occurrence of bending stress associated therewith, and it is possible to prevent breakage of the embankment reinforcement due to excessive deformation and bending stress.

[0054]

1 (a) to 1 (c) show an example of a reinforced earth structure constructed as a retaining wall facing a road or a site. In the drawings, reference numeral 1 is a wall of the retaining wall. Wall blocks stacked in a plurality of stages to form the body A, 2 are embankments filled in the back portion of the wall A, 3 are stable embankments 2 while increasing the strength of the embankments 2 and fixing the wall blocks 1 Therefore, the embankment reinforcement material embedded in the embankment 2 in a plurality of layers, and a reference numeral 4 is a bearing block embedded in the embankment 2 as a resistance member (anchor member) that resists pulling out of the embankment reinforcement material 3.

The wall block 1 has a front surface flange 1a, a rear surface flange 1b and a web 1c, and is integrally formed into a substantially flat H-shape (or I-shape) which can be very stably self-supporting even as it is from a dry block. .

The front surface flange 1a and the rear surface flange 1
b and a fixing groove 1d are formed at the upper ends of the web 1c, and the fixing groove 1d includes the surface flange 1a and the web 1c.
At the upper end of the back flange 1b is continuous in the longitudinal direction, and at the upper end of the back flange 1b is continuous in the width direction,
The fixing groove 1d of each portion is formed continuously with one groove. A protrusion 1e is formed on the upper end of the web 1c.

The wall block 1 in this case is generally 20 to 150 cm in height h, 30 to 100 cm in width w, and 20 to 60 cm in depth d in consideration of ease of handling such as transportation and workability. And the weight is about 20 to 150 kg.

The wall surface blocks 1 thus formed are laterally adjacent to each other and stacked in a plurality of stages.
In this case, the wall blocks 1, 1 adjacent to each other in the lateral direction
A cavity 5 composed of the front surface flange 1a, the back surface flange 1b, and the web 1c is formed between them, and the embankment 2 is filled in each cavity 5.

In this case, the wall portions 1, 1 on the left and right sides can be integrated with each other by filling the hollow portion 5 with a gravel, a solidifying material, or a block.

Further, the wall surface blocks 1 of the respective steps are, for example, as shown in FIG. 1, surface flanges 1 which are laterally adjacent to each other.
The vertical joints a between a and 1a are stacked so as to be so-called "blurred joints", which are not continuous in the vertical direction and are alternately shifted to the left and right. 5 between adjacent wall blocks 1 and 1 of
The wall blocks 1 that are vertically and laterally adjacent to each other are interlocked with each other by interlocking in which the protrusions 1e of the wall blocks 1 and the cavities 5 are fitted to each other.

The embankment reinforcement material 3 is horizontally embedded in the embankment 2, one end side (wall block side) of which is fixed to the wall block 1 and the other end side (bearing block side) of which is fixed to the bearing block 4. ing.

The embankment reinforcement 3 is formed of a steel bar or the like in addition to a reinforcing bar such as round steel or deformed steel bar. The surface of the embankment reinforcement 3 is galvanized, seal-coated with a synthetic resin, or coated. . In particular, when the surface of the embankment reinforcement 3 is galvanized or seal-coated, the anticorrosion effect is extremely large. Not only when using a field generating material with high acid soil as the embankment 2, but also when using alkaline soil such as calcareous soil. Either case can be dealt with.
If the surface of the embankment reinforcement 3 is galvanized and then coated with a seal, its anticorrosion effect is further enhanced.

Further, a hook 3a having a substantially L-shape in plan view is formed as a fixing portion on one end side of the embankment reinforcement 3, and the hook 3a is a surface flange 1 of the wall block 1.
a and the web 1c are inserted into the fixing groove 1d, and the fixing groove 1d is fixed by filling the fixing material 6 such as concrete, mortar, or epoxy resin.

In this way, the hook 3a of the embankment reinforcement 3
Is fixed to the fixing groove 1d of the wall surface block 1, the hook 3a is restrained by the weight of the upper wall surface block 1, and there is no concern that the hook 3a will be pulled out by friction with the peripheral surface in the fixing groove 1d. The hook 3a of the embankment reinforcement 3 is securely and firmly fixed between the upper and lower wall blocks 1,1.

In this case, in particular, the hook 3a of the embankment reinforcement 3
Is fixed across 2 or 3 or more fixing grooves 1d of the wall surface block 1 that are laterally adjacent to each other, so that a plurality of laterally adjacent embankment reinforcements 3 are provided. Since the wall block 1 can be fixed at the same time, it is extremely economical and the workability is significantly improved.

Further, since the hook 3a of the embankment reinforcing member 3 is stable in the fixing groove 1d, even if the wall surface block 1 located thereabove is displaced forward due to stress concentration due to earth pressure, its lower side The hooks 3a in the fixing groove 1d of the wall block 1 are not broken while being connected, but rather the wall block 1 moves forward, so that the stress concentration due to earth pressure is relieved and the earth retaining wall is stable. Can be kept.

On the other hand, the other end side (bearing block side) of the embankment reinforcing member 3 extends horizontally in the embankment 2 and is a fixing hole formed at a predetermined depth substantially at the center of the upper end of the bearing block 4. Four
It is fixed to a. In this case, a hook 3b is formed on the other end side of the embankment reinforcement 3 as a fixing portion that projects right below at a substantially right angle, and the hook 3b is inserted into the fixing hole 4a and is surrounded by concrete, mortar, or A solidifying material 6 such as an epoxy resin is filled.

Further, as shown in FIG. 1C, for example, a reinforcing bar is horizontally embedded as a resistance member 4b against the pull-out force P of the embankment reinforcement 3, in the vicinity of the fixing hole 4a of the bearing block 4, for example. The resistance member 4b strongly resists the pull-out force P of the embankment reinforcement 3 acting via the hook 3b.

The resistance member 4b in this case is also a solidified material such as a resin mortar which is inserted into a pre-formed embedding hole or embedding groove (not shown) near the fixing hole 4a and filled later. Is buried by.

Further, the embankment reinforcement 3 needs to be laid in every step or every row as long as a sufficient pull-out resistance against earth pressure from the embankment 2 acting on the wall block 1 at each step can be obtained. Instead, they may be laid in every plural stages or every plural rows. Rather, it is more economical if the amount of the embankment reinforcement 3 is small, and it does not hinder the filling and rolling of the embankment 2 and is desirable in construction.

In this case, as an example of the wall blocks adjacent to each other in the lateral direction, the wall blocks 1 to which the embankment reinforcements 3 are connected and the wall blocks 3 to which the embankment reinforcements 3 are not connected are alternated. It may be laminated every few layers.

As the wall blocks adjacent to each other in the vertical direction, the wall block 1 to which the embankment reinforcement material 3 is connected.
In some cases, the wall blocks 1 to which the embankment reinforcements 3 are not connected are stacked every other row or every other row.

FIG. 2 shows another example of a method for fixing one end side of the embankment reinforcement 3 to the wall surface block 1, particularly, the fixing groove 1d.
Is linearly formed continuously from the center of the front surface flange 1a to the web 1c and further between the back surface flange 1b. Further, a fixing hole 1f is formed at the tip of the fixing groove 1d (the center of the surface flange 1a).

On the other hand, on one end side of the embankment reinforcement 3, an L-shaped hook 3a is formed as a fixing portion so as to project substantially vertically downward. Then, one end side of the embankment reinforcement 3 is inserted into the fixing groove 1d, the hook 3a is inserted into the fixing hole 1f, and the fixing groove 6 is filled in the fixing groove 1d and the fixing hole 1f. It has been established.

In the example shown in FIG. 3, in particular, the wall surface block 1 is formed by the surface flange 1a and a plurality of webs 1c, 1c protruding in parallel on the back side thereof, and the upper end portion of the surface flange 1a is formed. A fixing hole 1f is formed in the approximate center.

On the other hand, on the tip end side of the embankment reinforcing member 3, an L-shaped hook 3a is formed as a fixing portion so as to project substantially vertically downward. Then, the hook 3a is inserted into the fixing hole 1f, and the fixing hole 1f is filled with the solidifying material 6, whereby the tip end side of the reinforcing material 3 is fixed to the wall surface block 1.

Further, in the example shown in FIG. 4, a hook 3a having a substantially T-shaped plane is formed on one end side of the embankment reinforcement 3, and projections 3c, 3c projecting directly downward are provided at both ends thereof. Has been done. On the other hand, a small hole 1g is provided in the fixing groove 1d of the wall surface block 1.

Then, the hook 3a is inserted into the fixing groove 1d, the projections 3c and 3c at both ends are inserted into the small holes 1g and 1g, respectively, and the fixing groove 1d and the small holes 1g and 1g are filled with the solidifying material 6. Then, one end side of the embankment reinforcement 3 is fixed to the wall surface block 1. It should be noted that FIG. 4D shows an example in which a rectangular block is used as the wall block.

Further, in the example shown in FIG. 5, the hook 3a of the embankment reinforcement 3 is formed in a rod shape which is separate from the extension 3d, and is formed on the ring portion 3e formed at the tip of the extension 3d. By being inserted, it is connected to the tip of the extension 3d. If this embankment reinforcement 3 is used, the hook 3a
Even when the length is considerably long, the hook 3a and the extension 3d can be separated from each other for transportation, so that it is not bulky and is easy to handle. It should be noted that FIG. 5D shows an example in which a rectangular block is used as the wall block.

Further, in the example shown in FIG. 6, the wall surface block 1 has the front surface flange 1a, the rear surface flange 1b and the web 1c, respectively, and is integrally formed into a substantially flat H shape which can be very stably self-standing as it is. Is
A projection 1e is formed on the upper end of the web 1c.

On the other hand, the embankment reinforcement 3 is made of steel strip,
Hooks 3a and 3b are formed as fixing portions on one end side (wall surface block side) and the other end side (pressure bearing block side), respectively. The hook 3a is formed in a recessed groove shape that can be fitted to the projection 1e projectingly provided on the upper end of the web 1c of the wall surface block 1, and the hook 3b is formed of, for example, an L-shaped bent reinforcing bar. It is formed by welding to the ends.

By fitting the hook 3a to the protrusion 1e, one end of the embankment reinforcement 3 (wall block side)
Is fixed to the wall surface block 1 and the hook 3b is inserted into the fixing hole 4a of the pressure bearing block 4 to fix the other end side (bearing block side) of the embankment reinforcement 3 to the pressure bearing block 4. .

Further, in particular, as shown in FIGS. 6D and 6E, the hook 3a is provided at one end of the embankment reinforcement 3 and the L-shaped projection located right below the hook 3a is formed at a substantially right angle. While forming the hook 3c, the fixing hole 1g is formed in the upper end portion of the wall surface block 1, and the hook 3c is inserted into the fixing hole 1o, so that the embankment reinforcement 3 is more reliably fixed to the wall surface block 1 on one end side. It can be anything.

The hook 3c in this case is shown in FIG.
As shown in (d) and (e) respectively, it is easy to weld an L-shaped bent reinforcing bar or the like to the end of the steel strip, or directly bend the end of the steel strip into an L shape. Can be formed.

The hook 3a in this case may be formed when the embankment reinforcing material 3 is manufactured, but it is formed by bending the tip of the embankment reinforcing material 3 when the embankment reinforcing material 3 is laid on site. May be. Further, the hook 3b may also be formed by welding a reinforcing bar or the like locally bent into an L shape to the end of the strip steel.

FIGS. 7 (a) to 7 (e) show an example of a reinforcing material. For example, FIG. 7 (a) shows a bar-shaped member such as a reinforcing bar which is bent at its tip end into a substantially L-shaped plane, and another bar-shaped member. By welding the member 3c, the hook 3a is formed in a substantially T shape in a plane.

Further, particularly, the reinforcing member 3 shown in FIG. 7 (c).
Has a hook 3a formed of a rod-shaped member and an extension 3d formed of a strip steel. Furthermore, FIG. 7 (d), (e)
Shows a modified example of the hook 3a formed as a fixing portion on the other end side (wall surface block side) of the reinforcing member 3. The hook 3a shown in FIG. 7D is a rod-shaped member such as a reinforcing bar. By forming the other end of the hook 3 by double bending, the resistance against the pulling force of the hook 3a is increased.

Also, the hook 3a shown in FIG. 7 (e).
The adhesive strength of the solidifying material is increased by bending the tip end side of the embankment reinforcing material 3 made of a reinforcing bar or the like into an L shape and projecting ribs 3g on the surface thereof. The embankment reinforcement 3 in this case is made of deformed steel bar.

Other examples of the wall block are shown in FIGS. 8 (a) to 8 (h), respectively.
Each of the wall blocks has a front surface flange 1a, a rear surface flange 1b and a web 1c, and in particular, FIG.
In the case illustrated in (a) and (b), the flange 1
A connecting key 1h made of a reinforcing bar, a stud bolt, or the like is provided at the upper end of a at a predetermined interval in the longitudinal direction of the flange 1a (lateral direction of the wall A), and a surface flange 1a corresponding to this connecting key 1h. Has a key hole 1i into which the connecting key 1h can be inserted.

Then, when the plurality of wall surface blocks 1 are stacked in a plurality of layers, the connecting keys 1h and the key holes 1i of the vertically adjacent wall surface blocks 1, 1 are engaged with each other (the connecting key 1h is inserted into the key hole 1i. The upper and lower retaining wall blocks 1 are combined with each other by interlocking.

In addition, in the structure shown in FIG. 8C, a connecting groove 1j is formed continuously in the longitudinal direction of the surface flange 1a, especially at the upper end of the surface flange 1a. Then, when the plurality of wall surface blocks 1 are laminated in a plurality of layers, the connecting recessed grooves 1j, 1j of the wall surface blocks 1, 1 adjacent in the horizontal direction of each step are continuous in the horizontal direction of the wall body A, and Groove 1 for connection between a plurality of wall surface blocks 1 adjacent in the direction
By inserting the connecting rod 7 across j and 1j, the wall blocks 1 that are laterally adjacent to each other are joined to each other.

Further, in the drawing shown in FIG. 8 (d), in particular, the upper end portion and the lower end portion of the surface flange 1a are formed with a protrusion 1k and a recess 1m which are continuous in the longitudinal direction of the surface flange 1a.
Are formed respectively. Then, when the plurality of wall surface blocks 1 are stacked, the wall surface blocks 1, which are vertically adjacent to each other,
The upper and lower wall surface blocks 1 are joined to each other by the engagement of the projecting portion 1k and the recessed portion 1m.

Further, in the drawing shown in FIG. 8 (e), since the opening 1n penetrating downward is formed in the web 1c, the weight of the retaining wall block 1 is reduced and the material is saved. After being laminated, by filling gravel in the opening 1n, the shear resistance between the upper and lower wall blocks 1, 1 is increased to prevent deformation of the wall body A due to earth pressure and drainage is enhanced. ing.

Further, the wall surface block 1 shown in FIG. 8 (f) is formed by the front surface flange 1a and a plurality of webs 1c, 1c protruding in parallel on the rear surface side thereof.
An opening 1n for filling the embankment is formed between c and 1c.

Further, the wall surface block 1 shown in FIG. 8 (g) is formed in a plane T shape from the surface flange 1a and the web 1c protruding from the back surface side thereof. Further, the wall surface block 1 shown in FIG.
A planting recess 1o is formed at the upper end of a.

The pressure bearing block 4 is formed in a rectangular parallelepiped shape that can be stably self-supporting even as it is, and ribs are projectingly provided on the back surface side in order to enhance self-supporting property and maintain sufficient weight. Further, a fixing hole 4a for fixing the hook 3b on the other end side of the reinforcing member 3 is formed at a predetermined depth in the center of the upper end portion.

9 and 10 show a pulling force P of the embankment reinforcement 3 by horizontally embedding the resistance member 1p in the concrete of the wall block 1 as a resistance member against the pulling force P of the embankment reinforcement 3. It is designed to be able to resist strongly.

In the examples of FIGS. 9 (a) to 9 (c), the surface flange 1a of the wall surface block 1 and the corner portion of the fixing groove 1d formed continuously in the plane L shape on the upper ends of the webs 1c. The resistance member 1p is vertically embedded.

Further, in the example of FIGS. 10A and 10B, the resistance member 1 is provided inside the fixing hole 1f vertically formed in the center of the surface flange 1a of the wall surface block 1 (on the rear flange side).
p is buried horizontally. In this case, the resistance member 1p is embedded in the fixing hole or the fixing groove 1q formed in advance.

11 (a) and 11 (b) show a modification of the embankment reinforcement 3 and the bearing block 4 in particular. As shown in the figure, the embankment reinforcement 3 is formed substantially in the shape of a groove, and the tip portion thereof is formed. Is a fixing portion corresponding to the hook 3a. In addition, hooks 3b each having a substantially L-shaped side surface are formed at the ends on the free end side. The pressure bearing block 4 is horizontally long, and fixing holes 4a, 4a are formed at predetermined depths at both ends in the longitudinal direction.

Then, the hook 3a of the embankment reinforcement 3 is fixed by being inserted across the fixing grooves 1d, 1d of the adjacent wall surface blocks 1, 1 and fixed by the hooks 3b, 3b. Inserted in holes 4a, 4a, and further fixed groove 1d
The fixing material 4 is filled in the fixing hole 4a and fixed.

In this case, the fixing portion 3 of the embankment reinforcement 3
It is also possible to prevent the embankment reinforcing member 3 from rising by pressing the shaft portion a or between the fixing portions 3a and 3b with a fixing metal fitting (not shown) from above. As the fixing metal fitting in this case, a metal fitting formed of a reinforcing bar or the like and having a U-shaped opening right below so as to straddle the shaft portion of the embankment reinforcing member 3 can be considered. The fixing bracket can be fixed by inserting the legs at both ends into small holes formed in the upper end of the wall block.

FIGS. 12 (a) and 12 (b) show an example in which the adjacent wall surface blocks 1 and 1 are connected to each other by the connecting fitting 7. In this case, the connecting member 7 is formed of a reinforcing bar or the like, and hooks 7a having a substantially L-shaped side surface are formed at both ends. Further, fixing holes 1r, 1r are formed at both ends of the surface flange 1a of the adjacent wall block 1, 1, respectively.

By connecting hooks 7a, 7a at both ends into the fixing holes 1r, 1r of the surface flange 1a, the connecting metal fitting 7 is installed between the adjacent wall surface blocks 1, 1 so that the wall surface blocks 1 adjacent to each other. , 1 are connected to each other.

The hook 3a on the tip side of the embankment reinforcement 3
Is fixed in a fixing hole 1f formed in the rear surface flange 1b of the wall surface block 1.

13 (a) and 13 (b) show another example of a method of fixing the hook 3a of the embankment reinforcement 3 to the wall surface block 1, particularly, at the upper end of each wall surface block 1, a fixing hole or a fixing groove. Instead of providing the ring block 8, a ring ring 8 made of a reinforcing bar or the like is projected on the back surface of each wall block 1, and the hook 3 is attached to the ring ring 8.
By inserting a horizontally, one end side of the embankment reinforcement 3 is fixed to the wall surface block 1. In this case, the ring 8 is fixed to the fixing hole 1s formed in the back surface of the wall surface block 1 by the solidifying material 6.

FIGS. 14A to 14C show an example of a method for fixing the hooks 3a of the embankment reinforcing member 3 to the wall surface blocks in the same manner.
(A)), or the fixing metal fitting 10 is provided in a protruding manner on the back surface portion (FIG. 14B) of the joint between the upper and lower wall surface blocks 9, 9.

Further, a fixing plate 3c is projected from one end side (wall surface block side) of the embankment reinforcing member 3, and connecting holes 10a and 3d are formed in the fixing metal fitting 10 and the fixing plate 3c, respectively. Then, by fixing the fixing plate 3c on the side of the fixing metal fitting 10 and inserting the connecting pin between the connecting holes 10a and 3d, one end side of the embankment reinforcing member 3 is connected to the wall surface block 9. A thick wall panel as shown is used for the wall block in this case.

FIGS. 15 (a) and 15 (b) show an example of a method of fixing one end side of the embankment reinforcement material 3 to the wall surface block 9 as well. The upper and lower wall surface blocks 9 and 9 are stacked one above the other. A connecting key 11 is attached to connect the blocks 9 to each other, and a fixing plate 3c is projectingly provided on one end side (wall surface block side) of the embankment reinforcement 3, and a connecting hole 3d is formed in the fixing plate 3c. .

By inserting the connecting key 14 into the connecting hole 3d of the fixing plate 3c, one end of the embankment reinforcing member 3 is connected to the wall surface block 10.

As the wall surface block in this case, a rectangular parallelepiped block as shown in the figure is used. Further, the connecting key 11 is fixed by the solidifying material in the fixing holes formed in the upper and lower wall blocks 9, 9, respectively.

16 (a) to 16 (c) show an example of a bearing block, in which a reinforcing bar or a steel plate is embedded as a resistance member 4b on the side of the fixing hole 4a (wall block 1 side).
In this case, the resistance member 4b is embedded in the embedding groove 4c with a solidifying material.

17 to 21 show another example of a method of fixing both ends of the embankment reinforcement to the wall block and the bearing block.

In the example of FIG. 17, fixing holes 1t and 4d having a predetermined depth are formed on the side portions of the wall surface block 1 and the bearing block 4, respectively, and the end portions of the embankment reinforcement 3 are formed in the fixing holes 1t and 4d. Is inserted and the solidifying material 6 is filled.

18 (a), (b) and (c), the wall block 1 and the bearing block 4 each have a bolt member or a strip member projecting as a connecting member 12, and a reinforcing bar or a bar. An embankment reinforcement material 3 such as a wire mesh material is connected via a turnbuckle 13 and bolts and nuts 14.

In the example of FIGS. 19 (a) and 19 (b), the embankment reinforcement 3 is attached to the connecting member 12 projecting from the wall surface block 1.
Geotextiles are attached by directly winding as.

Further, in the example of FIGS. 20A, 20B and 20C, the fixing hole 1t formed in the wall surface block 1 is formed.
Ends of the reinforcing bar, strip steel, etc. are fixed inside the embankment reinforcing material 3 by a solidifying material.

[0118]

The invention of the present application is as described above.
In particular, the embankment reinforcement material has a substantially L shape or T formed at the end.
The letter-shaped hook is fixed in the fixing groove or fixing hole formed on the wall block and the bearing block with a solidifying material, so the structure is much simpler than the fixing with bolts and nuts as before. In addition, since bolts and nuts are not required, it is possible to significantly reduce the construction work and the construction cost.

In addition, the wall surface block and the bearing pressure block are
Zero resistance or very low slump Super-concrete concrete is compacted by using a powerful vibrator and compactor in a mold to form a dry block, and a resistance member that resists withdrawal of embankment reinforcement. Since reinforcing bars, steel plates, etc. are buried as, it is possible to provide a reinforced soil structure that is extremely stable in terms of strength.

[Brief description of drawings]

FIG. 1 (a) is a partial perspective view showing an example of a reinforced soil structure constructed as a retaining wall, (b) is a perspective view of a wall block, a bearing block and an embankment reinforcement, and (c) is a perspective view. It is a longitudinal cross-sectional view of a bearing block.

FIG. 2A is a partial plan view showing an example of a reinforced soil structure constructed as a retaining wall, and FIG. 2B is a perspective view of a wall block, a bearing block and an embankment reinforcement.

3A is a partial perspective view showing an example of a reinforced earth structure constructed as a retaining wall, and FIG. 3B is a perspective view of a wall surface block.

FIG. 4 (a) is a partial perspective view showing an example of a reinforced soil structure constructed as a retaining wall, and FIG. 4 (b) is a partial plan view thereof.
(C) is a partial longitudinal sectional view of the wall surface block, and (d) is a partial perspective view of the wall surface block.

FIG. 5 (a) is a partial perspective view showing an example of a reinforced earth structure constructed as a retaining wall, and FIG. 5 (b) is a partial plan view thereof.
(C) is a partial longitudinal sectional view of the wall surface block, and (d) is a partial perspective view of the wall surface block.

6A is a partial plan view showing an example of a reinforced soil structure constructed as a retaining wall, FIG. 6B is a perspective view of a wall surface block, an embankment reinforcement and a bearing block, and FIG. Partial longitudinal cross-sectional view of the wall block, (d), (e) is a perspective view showing the wall block and the embankment reinforcement.

7 (a) to 7 (e) are perspective views showing an example of an embankment reinforcement.

8A to 8H are perspective views showing another example of the wall surface block.

9A and 9B are partial perspective views showing a wall surface block and an embankment reinforcement, and FIG. 9C is a partial vertical sectional view of the wall surface block.

FIG. 10A is a perspective view of the wall block and the embankment reinforcement, and FIG. 10B is a partial vertical cross-sectional view of the wall block.

FIG. 11A is a partial plan view showing an example of a reinforced soil structure constructed as a retaining wall, and FIG. 11B is a perspective view of an embankment reinforcement.

FIG. 12A is a partial plan view showing an example of a reinforced soil structure constructed as a retaining wall, and FIG. 12B is a perspective view of a wall surface block, an embankment reinforcement member, and a bearing block.

13A is a perspective view of the wall block and the embankment reinforcement, and FIG. 13B is a partially cutaway side view of the wall block.

14A and 14B are partial vertical cross-sectional views showing an example of a reinforced soil structure constructed as a retaining wall, and FIG. 14C is a perspective view of an embankment reinforcement.

15A is a partial vertical cross-sectional view showing an example of a reinforced soil structure constructed as a retaining wall, and FIG. 15B is a perspective view of an embankment reinforcement.

16 (a) and 16 (b) are perspective views of a reinforced soil block showing an example of a bearing block, and FIG. 16 (c) is a partial longitudinal sectional view thereof.

17 (a) is a partial plan view showing an example of a reinforced soil structure constructed as a retaining wall, FIG. 17 (b) is a perspective view of a wall block, an embankment reinforcement and a bearing block, and FIG. It is a partial longitudinal cross-sectional view of a pressure block.

18 (a) to 18 (d) are perspective views of a wall surface block, a bearing block and an embankment reinforcing material.

19 (a) and 19 (b) are perspective views of a wall block and an embankment reinforcement.

20 (a), (b), (c) are wall blocks,
It is a perspective view of a bearing block and an embankment reinforcement.

FIG. 21 (a) is a vertical cross-sectional view showing an example of a conventional reinforced earth structure constructed as a retaining wall, and FIG. 21 (b) is a side view of a reinforcing bar end portion.

[Explanation of symbols]

1 wall block (reinforced soil block) 2 embankment 3 embankment reinforcement 4 bearing block (reinforced soil block) 5 cavity 6 consolidation material 7 Connecting bracket 8 rings 9 wall blocks 10 Fixing bracket 11 Link key 12 Connection member 13 turn buckle 14 bolts and nuts

Claims (22)

[Claims] 1. A embankment reinforcement material embedded in an embankment filled in a back portion of a reinforced soil wall surface formed by stacking a plurality of wall surface blocks, wherein the embankment reinforcement member is provided in a fixing hole or a fixing groove provided in the wall surface block. The embankment reinforcement material is characterized by being fixed by inserting one end. 2. A embankment reinforcement material embedded in an embankment filled on the back of a reinforced earth wall surface formed by stacking a plurality of wall surface blocks, wherein the embankment reinforcement member is provided in a fixing hole or a fixing groove provided in the wall surface block. The embankment reinforcing material is characterized in that it is fixed by inserting one end and filling with a solidifying material. 3. The fixing is performed by inserting the other end into a fixing hole or a fixing groove provided in the bearing block embedded in the embankment and filling the fixing material. The embankment reinforcement material according to Item 1 or 2. 4. The embankment reinforcement material according to claim 1, wherein the other end of the embankment reinforcement material is fixed to the ground. 5. At least one end is formed in a hook shape, an L-shape, or a T-shape.
The embankment reinforcement material according to any one of 1. 6. A fill embankment reinforcement material embedded together with a bearing block in an embankment filled in a back portion of a reinforced soil wall surface formed by stacking a plurality of wall surface blocks, wherein one end and / or the other end is provided with a connecting metal fitting. Via the wall block and / or the pressure bearing block, and the connecting metal member is fixed in the fixing hole or fixing groove provided in the wall block and / or the pressure bearing block by a solidifying material. An embankment reinforcement material characterized by being present. 7. The surface is galvanized or coated with synthetic resin,
Alternatively, the embankment reinforcement material according to any one of claims 1 to 6, wherein the zinc-plated top is coated with a synthetic resin. 8. A reinforcing earth block used as a wall block for holding embankment and / or a bearing block for resisting pulling out of the embankment reinforcement embedded in the embankment, the fixing hole fixing the embankment reinforcement. Alternatively, the reinforcing soil block is characterized in that a fixing groove is formed and a block reinforcing material that resists pulling out of the embankment reinforcing material is embedded. 9. The reinforced soil block according to claim 8, wherein the block reinforcing material is embedded in the embedding hole or the embedding groove by a solidifying material. 10. The reinforced soil block according to claim 8, which is formed of a dry block. 11. A reinforced earth structure in which an embankment reinforcing material having a bearing block is embedded in an embankment filled in a back portion of a reinforced earth wall surface, wherein an embedding hole or an embedding groove is formed in the bearing block. The reinforced earth structure is characterized in that a resistance member that resists pulling out of the embankment reinforcing material is embedded in the embedding hole or groove by a solidifying material. 12. A wall block for retaining the embankment and / or
Alternatively, in a reinforced soil structure in which a reinforced soil block is installed as a bearing block that resists pulling out of the reinforced embankment embedded in the embankment, a fixing hole or a fixing groove is formed in the reinforced soil block, and the fixing hole is formed. Alternatively, a reinforced soil structure characterized in that the embankment reinforcing material is fixed in the fixing groove by a solidifying material. 13. A reinforcing earth structure in which a back of a reinforced earth wall surface formed by stacking wall blocks is filled with embankment, and an embankment reinforcing material is embedded in the embankment, and a fixing hole or a fixing member is formed in the wall block. A reinforced soil structure, wherein a groove is formed, and one end of the embankment reinforcing material or a connecting member for connecting the embankment reinforcing material is fixed by a solidifying material in the fixing hole or the fixing groove. 14. In a reinforced soil structure formed by stacking a plurality of wall blocks for holding embankment, the wall blocks are connected by a connecting member, and the connecting member is a fixing hole or a fixing groove formed in the wall block. A reinforced earth structure characterized by being fixed by being inserted into or inserted into and being filled with a solidifying material. 15. A plurality of wall blocks are laminated as a reinforced soil wall surface, and a wall block to which the embankment reinforcement is fixed and a wall block to which the embankment reinforcement is not fixed are laminated as wall blocks adjacent to each other in the lateral direction. The reinforced soil structure according to any one of claims 11 to 14, wherein 16. A plurality of wall blocks are laminated as a reinforced soil wall surface, and a wall block to which the embankment reinforcement is fixed and a wall block to which the embankment reinforcement is not fixed are laminated as the wall blocks vertically adjacent to each other. The reinforced earth structure according to any one of claims 11 to 15. 17. A cavity is provided between each wall block laminated as a reinforced soil wall surface and / or a wall block adjacent in the lateral direction, and the cavity is filled with crushed stone or gravel, a solidifying material, or a block. The reinforced soil structure according to any one of claims 11 to 16, characterized in that 18. The wall surface is formed by stacking a plurality of wall surface blocks as a reinforced soil wall surface while combining them by interlocking to form a wall surface.
Reinforced soil structure according to any one of 1. 19. The reinforced earth structure according to claim 11, wherein the wall block is formed of a surface flange, a back flange and a web, or a surface flange and a web. 20. The reinforced soil structure according to claim 11, wherein the embankment reinforcement is a rod-shaped reinforcement, a strip-shaped reinforcement, a mesh material or a geotextile. 21. The reinforced soil structure according to claim 11, wherein the embankment is filled with Styrofoam, blocks, foam mortar or soil cement. 22. The reinforced stone wall surface formed by laminating wall surface blocks is filled with crushed stone or gravel, or sandy soil or solidified soil, according to any one of claims 11 to 21. Reinforced earth structure.