JP5526217B1 - Construction resistor and embankment structure - Google Patents

Abstract

The present invention provides a resistor 7 in which a resistance portion 72 against movement of the embankment is located in the embankment and a structure of the embankment.
A fixing portion that is a plate attached to an exposed end of an anchor bolt from an inclined surface, a resistance portion that is a plate located in the embankment, and a connecting portion that connects the fixing portion and the resistance portion. 73. Bolt holes are opened in the fixing unit 71. This embedding resistor 7 is positioned in the embankment.
[Selection] Figure 1

Description

  The present invention relates to a resistor for embankment and a method for constructing an embankment structure.

As shown in Patent Document 1, a wall structure, which is a precast plate, is stacked facing a slope, filled with a fill material between the slope and the wall panel, and anchor bolts are placed on the slope. The construction method is known.
A method similar to the above construction method is a method of laminating concrete instead of embankment material between the slope and the wall panel, but installing two bearing plates on the head of the anchor bolt, one of them There is also known a method in which a sheet is attached to the head of an anchor bolt projecting from a slope and embedded in fluidized concrete. (Patent Document 2)

JP 2002-242186 A JP 2007-291707 A

The conventional embankment structure construction method in which the two bearing plates are embedded in the fluid concrete has the following problems as shown in FIG.
<1> One of the bearing plates a is fixed to the slope b, but the second bearing plate a is attached to the head of the anchor bolt c protruding from the slope b.
<2> Therefore, a large number of anchor bolts stand out from the bottom to the top of the entire slope.
<3> On the other hand, between the wall panel and the natural ground, it is necessary to perform many operations such as stacking concrete, especially when laying a reinforcing material on the connecting surface of fluid concrete. The large number of anchor bolts that stand from the slopes hinders their work.
<4> In addition to tightening the bearing plate in contact with the slope with the nut, the second bearing plate positioned in the fluidized concrete needs to be tightened from both sides. That is, it is necessary to tighten nuts at a total of three locations.

In order to solve the above-described problems, the embankment resistor according to the present invention is constructed by stacking a wall panel as a precast plate facing a slope, filling a fill material between the slope and the wall panel, and anchoring the slope. A resistor used for a banking structure formed by driving bolts, the resistor being a separate member from the anchor bolt, and a fixing portion being a plate attached to the exposed end from the slope of the anchor bolt, and the banking It consists of a resistance part that is a plate located inside, and a connecting part that connects the fixing part and the resistance part. A bolt hole is opened in the fixing part. The fixing portion is installed only by exposing the thickness of the fixing portion.
The embankment structure construction method according to the present invention is performed by stacking wall panels, which are precast plates, facing a slope, filling a fill material between the slope and the wall panel, and placing anchor bolts on the slope. It is a construction method of embankment structure, and the anchor bolt is installed with its head exposed only about the thickness of the nut and the thickness of the fixing part of the resistor which is a separate member from the anchor bolt. , on the exposed end, a fixing portion of the resistor is fixed by tightening a nut, it is characterized in that performed by positioning the resistance of the resistor in the embankment.

Since the construction method of the embankment resistor and embankment structure of the present invention is as described above, the following effects can be obtained.
<1> Since the anchor bolt placed on the slope prior to the embankment process is installed only by exposing the fastening dimension of the nut on the head, as in the invention described in Patent Document 2, Long anchor bolts do not stand on the slope.
<2> Therefore, it does not become an obstacle for the worker going up and down the slope, and there is no danger when the worker slips or falls accidentally.
<3> When the height of the wall panel or the surface of the embankment has risen, it is only necessary to attach a resistor to the short exposed end of the anchor bolt at that stage.
<4> When a resistor is manufactured from a single continuous steel plate, it is only necessary to attach it to the exposed end of the anchor bolt with one nut, so use three nuts as described in Patent Document 2. Compared with the method of attaching two bearing plates at two locations, the operation can be performed very quickly.

Explanatory drawing of the Example of the embankment structure of this invention. Explanatory drawing of the other Example of a banking structure. Explanatory drawing of the Example of the resistor for embankment. Explanatory drawing of the other Example of the resistor for embankment. Explanatory drawing of the other Example of the resistor for embankment. The perspective view of the Example of the wall surface panel to be used. Explanatory drawing of the problem of the conventional embankment structure.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

<1> Basic Configuration of Embankment Structure The embankment structure according to the present invention is configured by a retaining wall R, an embankment material 4 and anchor bolts 6. (Figure 1)
The retaining wall R includes at least a foundation block 1, a wall surface panel 3, and a connecting member 2 that connects the wall surface panels.
Here, the embankment material 4 is not fluid concrete but a fluidized embankment material obtained by mixing coal ash (fly ash) or incineration ash with a caking agent, a foaming agent and water.
Moreover, it is also preferable to use the ash mixed embankment material which mixes the said coal ash, earth and sand, and a consolidated material.
Furthermore, it is preferable to use a precast concrete plate lightened by fly ash for the wall surface panel 3.

<2> Foundation block Foundation block 1 is installed on the ground in front of the planned embankment.
The foundation block 1 is formed of cast-in-place concrete or precast concrete.
The base block 1 is fixed to the front ground with a fixing member such as an anchor member 5 as necessary.

<3> Connecting Member The connecting member 2 is a rod-shaped member that fastens between the wall surface panel 3 and the foundation block 1 or between the lower wall surface panel 3 and the upper wall panel 3.
As the connecting member 2, for example, a high-strength steel material suitable for prestressing such as a screw-shaped deformed steel bar, a PC steel bar, a PC steel wire, or a PC steel strand for precast installation can be used. .
The connecting member 2 can be extended by adding a coupler or the like, but in the case of a non-penetrating wall panel 3 described later, the upper and lower wall panels 3 are not penetrated from the bottom to the top of the wall panel 3. It is also possible to use a short connecting member 2 that restrains only between the two.

<4> Wall surface panel <4-1> Vertical penetration type The wall surface panel 3 is a substantially rectangular plate made of reinforced concrete and precast concrete.
A through-hole through which the connecting member 2 passes is formed in the panel 3 in the vertical direction.
When the through hole has a space for storing the connecting nut in the lower portion and a space for storing the plate in the upper portion, the connecting member 2 can be sequentially connected and extended by the coupler in the space.
The connecting member 2 is passed through the through hole of the wall panel 3 and the upper and lower wall panels 3 are connected by tensioning the connecting member 2 to the foundation block 1 or the lower wall panel 3 using a fixing jig such as a plate and a nut. Fix it.
Due to this tension, the wall surface panel 3 can be made independent on the foundation block 1 or the lower wall surface panel 3.
The wall surface panel 3 can employ not only a reinforced concrete plate or a precast concrete plate but also a steel panel.

<4-2> Vertical non-penetrating type A panel in which fastening shelves 31 are independently projected at two locations on the back side of the wall surface panel 3 can also be used. (Fig. 6)
A through hole 32 is opened only inside the fastening shelf 31.
Then, if the connecting member 2 is passed through the through hole 32 of the upper fastening shelf 31 of the lower panel 3 and the through hole 32 of the lower fastening shelf 31 of the upper panel 3 and is tightened with bolts, the upper and lower panels 3 3 can be integrated.

<5> Embankment Material Between the wall surface panel 3 and the slope S, that is, on the back surface of the wall surface panel 3, fluidized concrete is not laminated, but the embedding material 4 is filled and laminated.
As this embankment material 4, various soil qualities, mixed soil, fluidized soil, soil and sand mixed with solidified material, and the like can be used.

<6> Crack preventive material A crack preventive material can be laid almost horizontally for each predetermined layer thickness inside the embankment layer made of the embankment material 4.
As the crack preventing material, for example, a steel material, a rust-prevented wire net, a synthetic resin, a fiber sheet material or a net can be used.
By laying the crack preventing material in the horizontal direction between the layers, the tensile resistance of the embedding material 4 is increased by using the frictional force or the adhesive force acting between the crack preventing material and the embedding material 4. Generation of cracks can be effectively prevented.
Moreover, the overall shear strength of the composite embankment is significantly improved from the embankment material 4 and the crack prevention material.
In addition, you may fix the said crack prevention material to the said wall surface panel 3 back as needed.
However, the presence of this member is not indispensable, and the construction and function of the embankment structure of the present invention can be established without laying depending on the situation.

<7> Anchor Bolt Prior to the embankment step, anchor bolt 6 is placed in advance on slope S on the natural ground side in order to prevent the slope S from collapsing and falling rocks.
The anchor bolt 6 has a structure in which a rod-shaped steel material is inserted into the drilled hole and a grout material such as mortar is injected into the back to fix the ground.
Alternatively, the grout material can be injected prior to the back of the drilled hole, and then the anchor bolt 6 can be inserted.
Various methods for fixing the anchor bolt 6 are known and put into practical use.
In that case, according to the method of the present invention, the anchor bolt 6 is installed only by exposing the head of the bolt 61 to the fastening dimension.
Therefore, unlike the conventional method shown in FIG. 7, many long anchor bolts do not stand outside from the slope.
The anchoring position of the anchor bolt 6 in the natural ground is located in the depth of the natural ground deeper than the assumed sliding surface of the slope, so that the natural ground and the sliding soil mass are integrated.
After the grout material in the drilled hole is hardened, a fixing portion 71 of a resistor 7 to be described later is firmly tightened to the exposed end of the anchor bolt 6 with a nut 61 using a thread formed on the anchor bolt 6.
By this work, tension can be obtained by pressing the anchor bolt to the ground surface at the fixing portion 71.

<8> Resistor A resistor is attached to the exposed end of the anchor bolt 6 in order to integrate the embankment material 4 raised between the wall panel 3 and the slope S and the natural ground inside the slope S. 7.
The resistor 7 is a separate member from the anchor bolt 6 and is attached to the exposed end of the anchor bolt 6 after it is installed on the ground.
Therefore, since the exposed length of the anchor bolt 6 on the ground surface is sufficient to be a short dimension such as the fastening allowance of the nut 61 and the plate thickness of the fixing portion 71, all the anchor bolts are grounded as in the construction method described in Patent Document 2. It is not necessary to expose the forest for a long time and prevent it from becoming a hindrance to the subsequent work.

<9> Structure of resistor The resistor 7 is a member made of steel, concrete, or the like.
Further, for example, the side view can be formed into an S shape, a Z shape, a U shape, a T shape, or the like.
The resistor 7 includes a fixing portion 71, a resistance portion 72, and a connecting portion 73.
When all are made of steel plates, they can be manufactured by bending a single steel plate or welding independent plates.
Alternatively, the whole can be manufactured as an integral casting.
Alternatively, the fixing unit 71, the resistor unit 72, and the connecting unit 73 can be manufactured by fastening with bolts at a factory. (Fig. 4)
Or it can also manufacture as a monolith with the concrete board reinforced with the reinforcing bar.

<9-1> Fixing Unit The fixing unit 71 is a plate body unit that fixes the resistor 7 with a nut to the exposed end of the anchor bolt 6 on the ground surface, and corresponds to a conventional bearing plate of the anchor bolt 6.
A bolt hole having an inner diameter larger than the outer diameter of the anchor bolt 6 and smaller than the outer diameter of the nut 61 is opened in the fixing portion 71.
Alternatively, a long groove having one end opened can be formed instead of an independent hole.
In the present invention, a long groove is also used as a hole as a function, so it is referred to as a “bolt hole”.
The exposed end of the anchor bolt 6 is inserted into this bolt hole, and the nut 61 is fastened to the screw of the anchor bolt 6 so that the resistor 7 and the anchor bolt 6 are integrated via the nut 61.

<9-2> Resistance portion The resistance portion 72 is a plate-like member that is located inside the embankment material 4 and resists the movement of the embankment material 4, and is configured by a plate body or the like.
The installation direction of the resistance portion 72 is positioned substantially parallel to the fixing portion 71.
The resistance portion 72 is not limited to one, and a plurality of plates can be projected from a connecting portion 73 described later, and for example, the side view can be configured in an E shape.

<9-3> Connection Portion The connection portion 73 is a member that connects the fixing portion 71 and the resistance portion 72 that are substantially parallel to each other, and may be a rectangular plate or a columnar shape.
The fixing unit 71, the resistance unit 72, and the connecting unit 73 can be configured to have a rectangular, polygonal, or circular shape in plan view.
When the fixing portion 71 and the resistance portion 72 are thick or have a bent side bent in the thickness direction, the connecting portion 73 and the fixing portion 71, and the connecting portion 73 and the resistance portion 72 are fastened with bolts. Can be adopted. (Figure 3)

<10> Construction Method Next, a method for constructing the embankment structure of the present invention using the above-described members will be described.

<11> Installation of foundation block First, the foundation block 1 is installed in the front ground of the planned embankment site.
In this case, the anchor member 5 is installed on the foundation block 1 and the anchor member 5 is tensioned to fix the foundation block 1 to the ground.
Further, a part of the connecting member 2 is embedded in the foundation block 1 and the other end protrudes upward.

<12> Fixing the Wall Panel The connecting member 2 is tightened and tightened with a torque wrench to fix the wall panel 3 on the foundation block 1.
Then, the side surfaces of the wall surface panels 3 are sequentially arranged side by side in the horizontal direction in the same manner.

<13> Stacking of Wall Panels When using the penetration type wall panel 3, the connecting member 2 is passed through the vertical through hole 32 of the wall panel 3 using a crane or the like, and the wall panel 3 is stacked. .
In the case of using a non-penetrating wall panel 3 having a shape in which fastening shelves 31 are protruded at two positions on the upper and lower sides of the natural ground, the through hole 32 of the fastening shelf 31 of the lower wall panel 3 and the upper panel The connecting member 2 is passed through the through hole 32 of the fastening shelf 31 of the wall surface panel 3 so that only the upper and lower wall surface panels 3 are fastened. (Fig. 6)

<14> Anchor bolt placement Prior to or in parallel with the above work, a hole is drilled in the slope S of the natural ground, the anchor bolt 6 is inserted, and the anchor bolt 6 is fixed with a mortar or the like.
Many well-known methods can be adopted for fixing the anchor bolt 6 in the drilling hole.
The anchor bolt 6 is buried in the drilling hole up to its head and exposed from the slope S, but is produced with a dimension that is not exposed so long.
The exposed dimensions are dimensions obtained by adding the thickness of the nut 61 fastened to the head of the anchor bolt 6, the thickness of the fixing portion 71 of the resistor 7, and some tightening allowance.
The anchor bolt 6 may be placed in advance before the foundation block 1 is installed in order to maintain the overall stability of the slope S.

<15> Attaching the resistor The bolt hole of the fixing portion 71 of the resistor 7 is inserted into the exposed portion of the anchor bolt 6, and the nut 61 is tightened from the outside of the fixing portion 71. (Figs. 3 and 4)
Then, the fixing portion 71 of the resistor 7 functions as a pressure bearing plate for the conventional anchor bolt 6, and tension can be applied to the anchor bolt 6 by a reaction force that presses the fixing portion 71 against the ground surface.
When the resistor 7 has a Z-like shape (FIG. 4) in which the fixing portion 71 and the resistance portion 72 protrude to the opposite side with respect to the connecting portion 73, the resistance body 7 is resistant to the tightening operation of the nut 61. Since the portion 72 does not become an obstacle, the tightening operation and the like are easy.

<16> Position of Resistance Portion The resistance portion 72 of the resistor 7 is separated from the fixing portion 71 by the length of the connecting portion 73.
Therefore, if the length of the connection part 73 is lengthened, the resistance part 72 will be located further away from the slope and inside the embankment.
However, if the length of the connecting portion 73 is made too long, the connecting portion 73 will bend, so that an optimum position is selected and manufactured in relation to its strength.
In any case, since the resistance portion 72 of the resistor 7 is located inside the embankment and the resistor 7 is integrated with the anchor bolt 6, the behavior of the embankment can be largely restricted.

<17> Embankment When the installation of the panel 3 is completed, the backside of the wall panel 3 is filled with, for example, a fluidized embankment material to form one layer of lightweight embankment.
In the case of banking material with high fluidity, it is pumped by a pump and discharged to the banking section through a pipe.
By using high-fluid embankment materials, it is easy to install in places where there is a risk of landslides, in places adjacent to houses or general roads, or in narrow places, and the construction time can be significantly reduced. Yes.
Each wall panel 3 has a sufficient sealing property because it is integrated by high tension caused by the connecting portion 73 material 2.

<18> Laying of anti-cracking material A crack-preventing material made of a rust-proof wire mesh can be laid on the surface of the fluidized embankment material 4 placed in a predetermined layer thickness, if necessary.
Under the present circumstances, you may fix a crack prevention material to the connection metal fitting provided in the wall surface panel 3 back surface as needed.
Further, a net member or the like may be fixed to the head of the anchor bolt 6 that is driven at a predetermined position on the slope S.
This laying is not an indispensable requirement and can be omitted depending on the situation.

<19> Stacking of Wall Panels When using a penetration type wall panel, another PC steel rod is connected to the connecting member 2 to extend the length of the connecting member 2 longer.
Then, the second wall surface panel 3 is installed on the lowermost wall surface panel 3 to perform torque wrench tension.
When the non-penetrating wall surface panel 3 is used, the connection member 2 only needs to be fastened between the lower wall surface panel 3 and the fastening shelf 31 of the upper wall surface panel 3.
After the wall panel 3 is fastened, a banking material 4 made of a fluidized banking material is further filled behind the wall panel 3.

<20> Repetition of work Hereinafter, the connecting member 2 and the wall surface panel 3 are continuously arranged in a predetermined number of steps, and the fluidized embedding material 4 is filled on the back side of the wall surface panel 3.
This work is sequentially repeated to construct a banking structure having a predetermined height and extension.
In some cases, asphalt roadbed C is laid on the top of the embankment layer and then roads are formed after placing concrete.

<21> Connection of Resistor and Wall Panel A method of connecting a part of the resistor 7 and the wall panel 3 with a steel rod 8 or a wire 81 may be employed. (Figure 2)
For example, a steel bar 8 is horizontally installed in the embankment material 4 through the wall panel 3, and the end of the steel bar 8 in the embankment material 4 and the resistor 7 are connected by a wire 81. .
Furthermore, the length can be adjusted by interposing a turnbuckle 82 between the resistor 7 and the wire 81.

<22> Other Construction Examples The embankment structure construction method of the present invention is not limited to the embodiment of the embankment structure described above, and construction of general roads such as highways and general national roads, roads for railway construction It can also be applied to the construction of bodies.

1: Foundation block 2: Connection member 3: Wall panel 4: Filling material 6: Anchor bolt 7: Resistor 71: Fixing part 72: Resistance part 73: Connection part

Claims (2)

It is a resistor used for embankment structures that are piled with wall panels that are precast plates facing the slope, filled with a fill material between the slope and the wall panel, and anchor bolts are placed on the slope,
The resistor is a separate member from the anchor bolt.
A fixing portion which is a plate body attached to the exposed end from the slope of the anchor bolt;
A resistance part which is a plate body located in the embankment;
Consists of a connecting part that connects the fixing part and the resistance part,
Bolt holes are opened in the fixing part,
The head of the anchor bolt is characterized by being installed only by exposing the thickness of the nut and the thickness of the fixing portion of the resistor,
Filling resistor. It is a construction method of a banking structure in which a wall panel that is a precast plate is stacked facing a slope, a filling material is filled between the slope and the wall panel, and anchor bolts are placed on the slope.
The head of the anchor bolt is installed only by exposing the thickness of the nut and the thickness of the fixing portion of the resistor , which is a separate member from the anchor bolt according to claim 1,
The fixing portion of the resistor according to claim 1 is fixed to the exposed end by tightening with a nut,
Perform by placing the resistance part of the resistor in the embankment,
Construction method of embankment structure.

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