JP5770330B2 - Reinforced earth wall structure - Google Patents

Description

  The present invention relates to a reinforced earth wall structure for protecting a slope.

  As a method of reinforced soil wall construction consisting of wall materials such as concrete panels that hold earth pressure from the embankment and reinforcing materials that are provided in the embankment to reinforce the embankment, A geotextile method using geotextile as a reinforcing material is known.

  Further, a reinforced earth wall construction method using a concrete panel as a wall surface material and using a chain coupled to the wall surface material as a reinforcing material is also known (Patent Document 1).

  In the above construction method, the use of a chain as a reinforcing material can exert a reinforcing effect with three of friction resistance, bearing resistance and shear resistance, but a concrete panel having a thickness sufficient to withstand earth pressure is heavy. There was a problem that it was expensive because of transportation and installation.

  On the other hand, as shown in FIG. 15, the wall material is configured by filling excavated soil (not shown) into a frame body 91 partitioned by a plurality of honeycomb cells 91a as the wall material, and the geotextile 92 is formed into the honeycomb cell 91a. There is also known a reinforced earth wall structure 9 which is inserted into and wound around to form a reinforcing material and this wall surface material is stacked up and down (Patent Document 2).

  In the above reinforced earth wall structure, the lightweight frame 91 is transported to the construction site, the frame 91 is deployed at the construction site, and the wall material is assembled by filling the excavated soil therein, so that the wall material itself is low cost. There is an advantage that it can be built with. However, since it is necessary to insert the geotextile 92 as the reinforcing material into the honeycomb cell of the joint portion and wind it, a large amount of the geotextile 92 is required, and the laying of the reinforcing material and the formation of the embankment layer are complicated. There is a problem that the construction of the entire reinforced earth wall structure 9 is expensive. Further, since the strip-shaped geotextile 92 is used as the reinforcing material, in order to connect the wall surface material to the reinforcing material, the shape of the cell of the frame needs to be a honeycomb having a straight side or a rectangle, There was a problem that a frame having cells surrounded by curved sides could not be used.

JP 2006-90071 A JP 2006-63563 A

  Therefore, the problem to be solved by the present invention is that each member constituting the reinforced earth wall is lightweight and has a small burden of material transportation, and the connection between the wall surface and the reinforcing material is strong while being an easy construction method, It is to provide a reinforced earth wall structure that is low in cost as a whole.

  The present invention was made in order to solve the above-mentioned problem, and the invention according to claim 1 is characterized in that a retaining wall formed by stacking wall materials up and down, an embankment formed behind the retaining wall, A chain coupled to the retaining wall and extending rearwardly in the embankment, wherein the wall surface material is formed by filling a frame body partitioned by cells that open vertically, and the frame body is viewed in plan view. A pair of arc-shaped pieces formed in an arc shape, the cell is defined by a pair of opposed arc-shaped pieces, and the arc-shaped pieces include a plurality of vertical bars extending in the vertical direction and a plurality of horizontal bars extending in the circumferential direction. Are formed so as to intersect with each other in a lattice pattern, and the vertical stripes of the adjacent arc-shaped pieces are gathered together, and a binding material made of a helical wire is wound around, and the arc-shaped pieces are bonded to each other. The chain is locked to the wound vertical bars It is a reinforced earth wall structure characterized by

According to the first aspect of the present invention, since the frame constituting the wall surface material is partitioned into cells that open up and down, the weight is light and the transportation burden is small, and the reinforcing material is a chain. It is possible to provide a reinforced earth wall structure that can be easily combined with a material and a reinforcing material and can form a bank and can be constructed at low cost. In addition, it provides a reinforced earth wall structure that can be built at low cost by using a frame that is compact when not assembled and is easy to transport to the construction site and easy to assemble at the construction site. can do. In addition, the frame is lightweight and easy to assemble at the construction site, can provide a reinforced earth wall structure with a high degree of freedom in the shape of the retaining wall, and supports high-strength portions of the wall material with chains. By doing so, a reinforced earth wall structure having a stable structure can be provided.

  The invention according to claim 2 includes a retaining wall formed by stacking wall materials vertically, a bank formed behind the retaining wall, and a chain coupled to the retaining wall and extending backward in the bank. The wall surface material is formed by filling a frame body partitioned by cells that open vertically, and the frame body includes a plurality of arc-shaped pieces formed in an arc shape in a plan view, and is disposed to face each other. The cell is defined by a pair of arcuate pieces, and the arcuate pieces are formed by intersecting a plurality of vertical bars extending in the vertical direction and a plurality of horizontal bars extending in the circumferential direction in a lattice shape, and the adjacent arcuate pieces The vertical stripes of the pieces are gathered together, a binding material made of a helical wire is wound, the arc-shaped pieces are joined together, and the chain is locked to a locking member provided on the frame, The locking member skewers the frame body in the width direction of the reinforcing earth wall. Through the so that, a muscle member which is engaged with the longitudinal muscle is a reinforced soil wall structure, characterized in that it said chain is anchored to the muscle material within the cell.

According to the second aspect of the present invention, since the frame constituting the wall surface material is partitioned into cells that open up and down, the weight is light and the burden of transportation is small, and the reinforcing material is a chain. It is possible to provide a reinforced earth wall structure that can be easily combined with a material and a reinforcing material and can form a bank and can be constructed at low cost. In addition, it provides a reinforced earth wall structure that can be built at low cost by using a frame that is compact when not assembled and is easy to transport to the construction site and easy to assemble at the construction site. can do. In addition, the frame is lightweight and easy to assemble at the construction site, can provide a reinforced earth wall structure with a high degree of freedom in the shape of the retaining wall, and the frame and chain are connected with a small number of parts. It can be done.

  According to a third aspect of the present invention, there is provided a retaining wall formed by stacking wall materials vertically, a bank formed behind the retaining wall, and a chain coupled to the retaining wall and extending rearward in the bank. The wall surface material is formed by filling a frame body partitioned by cells that open vertically, and the frame body includes a plurality of arc-shaped pieces formed in an arc shape in a plan view, and is disposed to face each other. The cell is defined by a pair of arcuate pieces, and the arcuate pieces are formed by intersecting a plurality of vertical bars extending in the vertical direction and a plurality of horizontal bars extending in the circumferential direction in a lattice shape, and the adjacent arcuate pieces The vertical stripes of the pieces are gathered together, a binding material made of a helical wire is wound, the arc-shaped pieces are joined together, and the chain is locked to a locking member provided on the frame, Whether the locking member is a locking bracket that contacts the rear of the frame Becomes, the locking fitting its entire length is constituted longer than the eyes of the lattice of the arcuate pieces, a reinforced soil wall structure, characterized in that the chain is tethered to the anchor fitting.

According to the invention described in claim 3, since the frame constituting the wall surface material is partitioned into cells that open up and down, the weight is light and the transportation burden is small, and the reinforcing material is a chain. It is possible to provide a reinforced earth wall structure that can be easily combined with a material and a reinforcing material and can form a bank and can be constructed at low cost. In addition, it provides a reinforced earth wall structure that can be built at low cost by using a frame that is compact when not assembled and is easy to transport to the construction site and easy to assemble at the construction site. can do. Moreover, the frame is lightweight and easy to assemble at the construction site, and can provide a reinforced earth wall structure with a high degree of freedom in the shape of the retaining wall. Since it is configured to be longer than the eyes, the locking with the chain is maintained without coming out of the cell.

According to a fourth aspect of the invention, the upper of the wall member is stacked set back from the lower of the wall material, according to claim 1, wherein the retaining wall is formed This is a reinforced earth wall structure.

According to the fourth aspect of the present invention, there is provided a reinforced earth wall structure in which a retaining wall having an inclined slope can be provided and the upper surface portion of the filler exposed from the receded wall surface material can be greened. can do.

  According to the present invention, since the frame constituting the wall material is partitioned into cells that open up and down, the weight is light and the burden of transportation is small, and the reinforcing material is a chain. Therefore, it is possible to provide a reinforced earth wall structure that can be easily constructed and can be constructed at low cost.

It is the top view and sectional drawing which show the whole structure of the reinforced earth wall structure which concerns on 1st embodiment of this invention. It is the isometric view schematic diagram which looked at the wall surface material and the chain among the reinforcement earth wall structures which concern on 1st embodiment except a filler and embankment. It is sectional drawing which looked at the connection part of the wall surface material and chain in the reinforced earth wall structure which concerns on the 1st Example of 1st embodiment except a filler and embankment. It is sectional drawing which looked at the connection part of the wall surface material and chain in the reinforced earth wall structure which concerns on the 2nd Example of 1st embodiment except a filler and embankment. It is sectional drawing which looked at the connection part of the wall surface material and chain in the reinforced earth wall structure which concerns on the 1st example of coupling | bonding of the 3rd Example of 1st embodiment except a filler and embankment. It is sectional drawing which looked at the connection part of the wall surface material and chain in the reinforced earth wall structure which concerns on the 2nd example of coupling | bonding of the 3rd Example of 1st embodiment except a filler and embankment. The plane which looked at the connection part of the wall surface material and chain in the reinforced earth wall structure which concerns on the 3rd example of coupling | bonding of the 3rd Example of 1st embodiment, and a 4th example of coupling | bonding except a filler and embankment. It is a figure and sectional drawing. It is sectional drawing which looked at the connection part of the wall surface material and chain in the reinforced earth wall structure which concerns on the 1st example of a coupling | bonding of the 4th Example of 1st embodiment except a filler and embankment. It is sectional drawing which looked at the connection part of the wall surface material and chain in the reinforcement | strengthening earth wall structure which concerns on the 2nd example of coupling | bonding of the 4th Example of 1st embodiment except a filler and embankment. It is sectional drawing which shows the process of constructing the reinforced earth wall structure which concerns on this invention, (a) shows the state which expand | deployed the frame and combined with the chain, (b) shows a filler in the cell of a frame. It is a figure of the state filled. It is sectional drawing which shows the process of constructing | assembling the reinforced earth wall structure which concerns on this invention, (a) shows the state which constructed | assembled the lowest wall material and embankment layer, (b) is the 2nd wall material from the bottom And the state which built the embankment layer is shown. It is sectional drawing which shows the process of constructing the reinforced earth wall structure which concerns on this invention, (a) shows the state which constructed | assembled the uppermost wall material and embankment layer, (b) finished the roadbed used as a road surface Indicates the state. It is the perspective view which looked at the wall surface material except the filler and embankment among the reinforced earth wall structure which concerns on 2nd embodiment. It is the side view which looked at the connection part of the wall surface material and chain in the reinforced earth wall structure which concerns on 2nd embodiment except a filler and embankment. It is a perspective schematic diagram which shows the positional relationship of the shape of a wall surface material among a conventional reinforced earth wall structure, and the reinforcing material which consists of geotextiles, and a wall surface material.

  Next, embodiments of the present invention will be described with reference to the drawings. The embodiments described below are preferred embodiments of the present invention, and thus various technically preferable limitations are given. However, the scope of the present invention is particularly limited in the following description. As long as there is no description of the effect, it is not restricted to these aspects.

(First embodiment)
First, the whole structure of the reinforced earth wall structure which concerns on 1st embodiment of this invention is demonstrated based on FIG. 1 and FIG. Fig.1 (a) is a top view of the reinforced earth wall structure which concerns on this invention, FIG.1 (b) is sectional drawing which shows the cross section AA in Fig.1 (a). FIG. 2 is a schematic perspective view of the wall surface material and the chain in the reinforced earth wall structure, excluding the filler and the embankment.

  The reinforced earth wall structure 1 includes a retaining wall 2 in which wall materials 3 are stacked one above the other. In the reinforced earth wall structure 1 shown in FIG. 1, the wall surface materials 3 are stacked so that the upper wall material 3 is moved backward from the lower wall material 3. As a result, an inclined slope is realized. Moreover, the embankment layer 41 is provided in layer form behind each wall surface material 3, and the embankment 4 is formed as a whole. A chain 5 extending rearward is laid between the embankment layers 41, and the rear end of the chain 5 is fixed to the ground by a fixture 6. The wall surface material 3 is coupled to the chain 5, whereby the retaining wall 2 is reinforced. The wall surface material 3 is configured by filling the cells of the frame 31 with the filler 32. Since the upper wall member 3 is disposed so as to recede from the lower wall member 3, the upper surface portion of the filler 32 is exposed, and when the filler 32 is made of soil, the part can be greened.

  Next, the wall surface material 3 and the chain 5 which are main components of the reinforced earth wall structure 1 according to the first embodiment will be described with reference to FIGS. 1 and 2. FIG. 2 is a schematic perspective view of the wall surface material 3 stacked in two stages so that the upper stage is retracted from the lower stage, excluding the embankment and the filler.

  The frame 31 is formed by alternately joining three strips 33, 34, and 35 extending in the longitudinal direction at the joint portion 31f. The strips 33, 34, and 35 in the developed state are wavy in a plan view. It becomes a curve and cells 31a, ..., 31a are formed between the strips. That is, each cell 31a has a shape surrounded and surrounded by two sides of a substantially sinusoidal curve in plan view, and is partitioned by a front partition wall and a rear partition wall in the front-rear direction, and an upper opening and a lower opening in the upper and lower directions It is open at. In the form shown in FIG. 2, one frame 31 has two rows of cells 31a in the front and rear, and the five cells 31a in the front row use the first strip 33 as a front partition wall and the second strip 34 as a rear partition. The four cells 31a and the two half-divided cells 31g in the rear row are formed with the second strip 34 as a front partition wall and the third strip 35 as a rear partition wall.

  In addition, since the frame 31 in a non-deployment state is strip | belt shape and is lightweight and compact, it can be easily conveyed to a construction site. When deployed at the construction site, the frame 31 is partitioned into a plurality of partitioned cells 31a.

  The material of the strips 33, 34, and 35 constituting the frame 31 can be arbitrarily selected, but high-density polyethylene is preferably used in terms of strength, weight, weather resistance, environmental resistance, chemical resistance, and the like. . Further, the strips 33, 34, and 35 may be provided with holes, which makes it lighter and easier to transport. However, it is possible to prevent the filler from flowing out of the slope by configuring the first strip 33 without holes. Further, at the joining portion 31f, the strips are joined together by an appropriate method such as stitching or fusion.

  The wall material 3 is configured by filling the frame 31 with the filler 32. At this time, if an embankment material is used as the filler 32, it is not necessary to separately carry the material to the construction site, which is preferable. However, it is of course possible to use a cement that solidifies after filling as the filler 32. When a part of the chain 5 is accommodated in the cell and the filler is consolidated, the connection between the wall surface material 3 and the chain 5 becomes strong.

  The rear end of the chain 5 is fixed to the ground G by a fixing tool 6. Although the structure of the fixing tool 6 and the fixing method to the ground G are arbitrary, the fixing tool 6 illustrated in FIG. 1 includes a bearing plate 61 and an anchor pin 62 having an L-shaped cross section. The chain 5 is fixed to the ground G by inserting the rear end of the chain 5 into a notch provided in the bearing plate 61 and driving the anchor pin 62 through the link of the chain 5.

  The method for connecting the wall surface material 3 and the chain 5 will be described in detail in the following description of the embodiment. In addition, all the cross-sectional views in FIGS. 3 to 9 referred to for explaining the following embodiments are cross sections corresponding to the cross section AA in FIG. 1A except for the filler and the embankment. FIG.

(First embodiment)
The reinforced earth wall structure 1 which concerns on the 1st Example of 1st embodiment is demonstrated based on FIG. In this embodiment, a predetermined length on the front side of the chain 5 is accommodated in the cell 31a in the front row of the frame 31 and buried together with the filler, and the filler is sufficiently tightened in the cell 31a. By being hardened, the chain 5 and the wall surface material 3 are firmly coupled by frictional resistance. In the present embodiment, one chain 5 is coupled to one wall material 3.

(Second embodiment)
Next, the reinforced earth wall structure 1 according to the second example of the first embodiment will be described with reference to FIG. In this embodiment, the chain 5 is fastened to an anchor pin 36 placed on the filler of the lower wall material 3L, and the upper portion of the anchor pin 36 is embedded in the filler of the upper wall material 3U. Has been. With this configuration, the upper and lower wall members 3L and 3U are coupled to the single chain 5 via the filler and the anchor pin 36. The number of anchor pins to be placed and the placement position can be arbitrarily set. That is, in the form shown in FIG. 4, the chain 5 is connected to the anchor pin 37, and the anchor pin 37 is embedded in the filler of the upper wall material while being placed on the lower bank. The anchor pin 37 can be omitted, or it can be moved forward and placed on the lower wall material filler.

  In the present embodiment, since the chain 5 and the frame body 31 are not directly coupled, a concentrated load does not act on the frame body 31 and the support force from the chain 5 acts on the frame body 31 evenly via the filler. To do.

  It is also possible to adopt a form in which an anchor pin 37 is driven by interposing a plate extending from the upper end of the lower rear partition wall 31eL to the lower end of the upper rear partition wall 31eU. If it carries out like this, it will become easy to arrange | position the upper wall material 3U in a predetermined position relatively with respect to the lower wall material 3L.

(Third embodiment)
Next, the reinforced earth wall structure 1 which concerns on the 3rd Example of 1st embodiment is demonstrated based on FIGS. The reinforced earth wall structure 1 according to the third embodiment is a reinforced earth wall structure in which the chain 5 is locked to a locking member provided on the frame body 31 of the wall surface material 3. Hereinafter, four examples of coupling in this embodiment will be described.

(First combination example)
The reinforced earth wall structure 1 shown in FIG. 5 has a configuration using a hook as a locking member. A hook 71a is hung on the lower end of the rear partition wall 31eL of the cell 31aL in the front row of the lower frame 31L, and the chain 5 is locked thereto. A hook 71b is hung on the upper end of the rear partition wall 31eU of the cell 31aU in the front row of the upper frame 31U, and the chain 52 is locked thereto. The chain 52 is coupled to the chain 5 with a bolt 51, and the rear end of the chain 5 is fixed to the ground by a fixture 6. With this configuration, the two upper and lower wall surface materials 3L and 3U are coupled to one chain 5.

  The position where the hooks 71a and 71b are hung on the frame 31 is arbitrary, but in the present embodiment, the hooks are hung on the rear partition walls 31eL and 31eU. Since this portion is a place where the second strip 34 and the third strip 35 are superposed, the rigidity is high, and the frame 31 is not easily deformed even if it is pulled by the chains 5 and 52, and thus is suitable. The hooks 71a and 71b, the chains 5 and 52, and the frame body 31 are combined so that the chains 5 and 52 are not detached in the process of locking the chains 5 and 52 to the hooks 71a and 71b. It is preferable to use and bind. Further, when the filler is sufficiently compacted in the cell, the frictional resistance between the filler and the chains 5 and 52 is increased. Contributes to a strong bond.

  For the uppermost wall member 3U of the reinforced earth wall structure 1, it is preferable to provide a hook 71c for preventing slippage as shown in FIG. In other words, the vertical load 71d of the hook 71c is brought into contact with the rear partition wall 31eU of the cell 31aU in the front row of the uppermost wall member 3U, and the curved portion 71e is inserted into the link of the chain 5 so as to apply the wheel load. Even in this case, it is possible to prevent the uppermost wall member 3U from shifting forward.

(Second combination example)
The reinforced earth wall structure 1 shown in FIG. 6 has a configuration using a coupler 72 composed of an L-shaped metal fitting 72a and a pin 72b as a locking member. That is, the link of the chain 52 is inserted into the notch provided in the L-shaped metal fitting 72a fastened to the upper frame 31U with the bolt 73, and the pin 72b is inserted into the link. Thereby, the chain 52 and the frame 31U are coupled. Although not shown, the chain 5 is similarly coupled to the lower frame body, and the chain 5 and the chain 52 are coupled by a bolt 51. The rear end of the chain 5 is fixed to the ground by a fixture 6. With this configuration, the two upper and lower wall surface materials 3L and 3U are coupled to one chain 5. Further, when the filler is sufficiently compacted in the cell, the frictional resistance between the filler and the chains 5 and 52 is increased. 3 contributes to a strong bond.

  The fixture 6 is composed of a bearing plate 61 and an anchor pin 62. Since the bearing plate 61 is also L-shaped in cross section, it is necessary to use the L-shaped bracket 72a and the bearing plate 61 as a common component. This is preferable because the number of types can be reduced. Moreover, although the fastening position of the L-shaped metal fitting 72a in the frame 31 is arbitrary, in this embodiment, it is the rear partition wall 31e of the cell 31a in the front row. Since this portion is a place where the second strip 34 and the third strip 35 are superposed, the rigidity is high, and the frame 31 is not easily deformed even if it is pulled by the chains 5 and 52, and thus is suitable.

  Further, it is of course possible to directly connect the links of the chains 5 and 52 and the frame 31 with bolts instead of the coupler 72 in the reinforced earth wall structure shown in FIG. And the chains 5 and 52 can be combined.

(Third combination example)
The reinforced earth wall structure 1 shown to Fig.7 (a), (b) is the structure which used the reinforcing material 74 which is a elongate bar as a locking member. Fig.7 (a) is a top view of the one-step wall material of the reinforced earth wall structure 1 which concerns on a present Example, FIG.7 (b) is sectional drawing which shows the cross section BB. A string 74 penetrates the frame 31 so as to skew the cells 31a arranged in the longitudinal direction of the frame 31, and the chain 5 is secured to the string 74 in the cell 31a. Yes. As a result, the frame 31 and the chain 5 are coupled with a small number of components.

(Fourth combination example)
The reinforced earth wall structure 1 shown in FIGS. 7C and 7D has a configuration using a locking metal fitting 75 as a locking member. FIG.7 (c) is a top view of the one-step wall material of the reinforced earth wall structure 1 which concerns on a present Example, FIG.7 (d) is sectional drawing which shows the cross section CC. In the cell 31a, the chain 5 is fastened to a locking fitting 75 that abuts along the curved surface of the rear partition wall 31e. As a result, the frame body 31 and the chain 5 are coupled with a small number of parts.

(Fourth embodiment)
Next, a reinforced earth wall structure 1 according to a fourth example of the first embodiment will be described with reference to FIGS. In the reinforced earth wall structure 1 according to the fourth embodiment, the chain 5 is locked to the locking member provided on the frame 31 of the wall surface material 3, and the wall surface in which the locking members are stacked in the vertical direction. It is the reinforced earth wall structure 1 comprised so that the relative position of materials 3 might be prescribed | regulated. Hereinafter, two examples of coupling in this embodiment will be described.

(First combination example)
The reinforced earth wall structure 1 shown in FIG. 8 has a configuration in which a coupler 76 composed of a stepped fitting 76a and an eyebolt 76b is used as a locking member. The lower frame body 31L and the upper frame body 31U are coupled by a stepped metal fitting 76a. Specifically, the rear partition wall 31eL of the cell 31aL in the front row of the lower frame body 31L and the lower part of the stepped metal fitting 76a. The vertical portion 76c is in contact with the rear partition wall 31eU of the cell 31aU in the front row of the upper frame 31U, and the upper vertical portion 76d of the stepped metal fitting 76a is in contact with each other by bolts. The chain 5 is fastened to an eye bolt 76b fastened to the stepped metal fitting 76a. With this configuration, the two upper and lower wall surface materials 3L and 3U are coupled to one chain 5. Further, the stepped metal fitting 76a defines a relative position between the upper and lower wall surface materials 3L and 3U, and when the wall surface material 3 is stacked, a predetermined position relative to the lower wall surface material 3L. It becomes easy to arrange the upper wall surface material 3U on the wall. The position of the eyebolt 76b is limited to the illustrated position and can be set arbitrarily. Further, instead of the eyebolt 76b, a perforated ear metal or a clevis protruding from the stepped fitting can be used as a coupling portion with the chain 5. Furthermore, instead of the eyebolt 76b, an anchor pin that is driven through the stepped metal fitting 76a is used, and the wall material of the upper and lower two stages can be coupled to one chain 5 by fastening the chain 5 to the anchor pin. It is.

(Second combination example)
The reinforced earth wall structure 1 shown in FIG. 9 is a view showing an example of a method of joining the lowermost wall member 3L and the chain 5, and a coupler 77 comprising an L-shaped metal fitting 77a and an anchor pin 77d as a locking member. It is the structure using. The L-shaped fitting 77a is fixed to the ground by anchor pins 77d, and the chain 5 is fixed to the anchor pins 77d. Here, the eyebolt 78 is fastened to the rear partition wall 31eL of the cell 31aL in the front row of the lowermost frame 31L with the eye facing the cell 31aL, and the anchor pin 77d passes through the eye of the eyebolt 78. Yes. Further, the vertical portion 77b of the L-shaped metal fitting 77a is fastened with a bolt while being in contact with the rear partition wall 31eU of the cell 31aU in the front row of the upper frame 31U, and is provided on the horizontal portion 77c of the L-shaped metal fitting 77a. An anchor pin 77d passes through the hole. The chain 5 fixed to the anchor pin 77d extends rearward through a notch provided in the vertical portion 77b. Therefore, not only the lowermost wall surface material 3L is fixed to the ground, but also the upper wall material 3U is coupled to the lowermost wall material 3L, and the chain 5 is connected to the two wall material 3L, It is connected to 3U. The L-shaped metal fitting 77a defines the relative positions of the upper and lower wall surface materials 3L and 3U, and when the wall surface materials 3 are stacked, a predetermined position relative to the lower wall surface material 3L. It becomes easy to arrange the upper wall surface material 3U on the wall.

  Instead of using the eyebolt 78, the anchor pin 77d is brought into contact with the rear partition wall 31eL of the cell 31aL in the front row of the lowermost frame 31L, whereby the upper wall material 3U with respect to the lower wall material 3L. It is also possible to determine the relative position.

(Reinforced soil wall structure construction procedure)
Next, the procedure for constructing the reinforced earth wall structure according to the first combination example of the second example of the first embodiment will be described with reference to FIGS.

  The frame 31 is expanded using the expansion auxiliary frame 81 and installed on the ground. At this time, in order to connect the plurality of frames 31,..., 31 in the longitudinal direction, the corresponding strips of the adjacent frames 31 are overlapped and fastened with bolts or the like. The hook 71a is hung on the lower end of the rear partition wall 31eL of the cell, particularly where the second strip 34 and the third strip 35 are joined, and the tip of the chain 5 is locked to the hook 71a so as not to come off. It is bound using a binding band 71f. The rear part of the chain 5 is left out of the cell (FIG. 10A).

  Next, the filling material 32 made of embankment material is put into the cell, and the development auxiliary frame 81 is pulled out and compacted with “octopus” or the like. The surface of the filler 32 is shaped so that the upper opening of the cell matches the surface of the filler 32 (FIG. 10B). By filling the cell 32 with the filler 32 while a part of the chain 5 is accommodated in the cell, a strong frictional resistance acts between the chain 5 and the filler 32, so that the chain 5 is firmly attached to the wall surface material 3L. To join. In addition, when the cement which solidifies after filling is used as the filler 32, the coupling | bonding of the wall surface material 3 and the chain 5 will become stronger.

  Next, the first embankment layer 41 is unwound and formed on the rear portion of the wall surface material 3L. Note that the compaction in the vicinity of the frame 31 is performed using a vibration compactor. Thereafter, the chain 5 is pulled manually, the rear end of the chain 5 is inserted into a notch provided in the bearing plate 61, and an anchor pin 62 is driven and fixed to the ground (FIG. 11 (a)).

  Next, similarly to the first layer, the second-layer frame body 31 is developed, and the frame body 31 is disposed by retracting a predetermined amount on the first layer. The hook 71b is hung on the upper end of the rear partition wall 31eU of the cell, particularly the portion where the second strip 34 and the third strip 35 are joined, and the tip of the chain 52 is locked to the hook 71b so that it does not come off. Binding is performed using a binding band 71f. Then, the chain 52 is coupled to the chain 5 laid on the first embankment layer 41 using bolts 51. Then, the cell is filled with a filling material 32 made of a filling material in the same procedure as the first layer, and the second filling layer 41 is unrolled and formed at the rear of the wall surface material 3U (FIG. 11B). ).

  Repeat this procedure until the top layer is constructed. The uppermost wall member 3 is attached with a hook 71c for preventing misalignment in order to prevent forward displacement due to wheel load (FIG. 12A).

  Finally, the roadbed R that becomes the road surface is carefully compacted and finished. In addition, the level | step-difference part of a frame body by a longitudinal gradient is processed by the sandbag 82 (FIG.12 (b)).

  In this way, it can be constructed by repeating the development of the frame body, filling into the cells, and rolling the embankment layer, and further, the curing period is unnecessary, so that it is possible to construct a reinforced soil wall in a short period of time.

  In addition, since the two steps of wall surfaces 3L and 3U adjacent to each other are coupled to one chain 5, the wall surface can be stably supported by a small number of chains. Further, the design cost can be reduced by treating the two-stage wall materials 3L and 3U and the single chain 5 as one unit, and further standardizing and designing the unit.

(Second embodiment)
Next, a reinforced earth wall structure according to a second embodiment of the present invention will be described with reference to FIGS. FIG. 13: is the perspective view which looked at the wall surface material except the filler and embankment among the reinforced earth wall structures which concern on 2nd embodiment.

  The frame body 37 constituting the wall material of the reinforced earth wall structure according to the present embodiment includes a plurality of arc-shaped pieces 38 formed in an arc shape in a plan view, and a cell is formed by a pair of arc-shaped pieces 38 and 38 arranged to face each other. 37a is partitioned. The arc-shaped pieces 38 are connected by a connecting piece 39. In the frame 37 shown in FIG. 13A, two cells 37a and 37a are partitioned by four arc-shaped pieces 38,.

  FIG. 13B shows a perspective view of the arc-shaped piece 38. The arc-shaped piece 38 is formed by intersecting a plurality of linear vertical bars 38a extending in the vertical direction and a plurality of arc-shaped horizontal bars 38b extending in the circumferential direction in a lattice pattern. The vertical bars 38a and the horizontal bars 38b are preferably made of iron wire, which are welded at an intersection and integrated as an arc-shaped piece 38.

  FIG. 13C shows a perspective view of the coupling piece 39. The connecting piece 39 is made of a helical wire, and the plurality of arc-shaped pieces 38 are connected to each other by winding around the adjacent vertical bars 38a. The connecting piece 39 is preferably made of iron wire and can be wound around the vertical bars 38a by twisting.

  Next, a method of connecting the wall surface material 3 and the chain 5 in the reinforced earth wall structure according to the present embodiment will be described with reference to FIG. FIG. 14 is a side view of the wall surface material 3 and the chain 5 as seen without the filler and the embankment.

  The reinforced earth wall structure shown in FIG. 14 (a) applies a method similar to the joining method shown in FIGS. 7 (a) and (b) in the first embodiment, and is long as a locking member. The muscle material 74, which is a bar material, is used. A streak 74 passes through the frame 37 so as to skew the cells 37a arranged in the longitudinal direction of the frame 37 (depth method in the figure), and the chain 5 is connected to the streaks 74 in the cell 37a. Stopped. As a result, the frame 37 and the chain 5 are coupled with a small number of parts.

  The reinforcing earth wall structure shown in FIG. 14 (b) applies a method similar to the joining method shown in FIGS. 7 (c) and (d) in the first embodiment, and a locking metal fitting as a locking member. 75 is used. In the cell 37a, the chain 5 is fastened to a locking fitting 75 that contacts the rear of the frame 37. Since the entire length of the locking metal fitting 75 is longer than the grid of the arc-shaped piece 38, the locking with the chain 5 is maintained without coming out of the cell 37a.

  In addition to the method shown in FIG. 14, it is of course possible to lock the chain 5 to the vertical stripe 38a around which the coupling piece 39 is wound. In this case, a reinforced earth wall structure having a stable structure can be provided by supporting a portion of the frame body 37 having high strength with a chain.

  As described above, the differences between the reinforced earth wall structure according to the second embodiment and the reinforced earth wall structure according to the first embodiment are the configuration method of the frame body constituting the wall surface material 3, the wall surface material and the chain. It is a combination method. Filling material is formed in a frame body partitioned by cells that are opened up and down to form a wall surface material, and the wall surface material is stacked up and down to form a retaining wall, and the embankment formed behind the retaining wall, and the retaining wall The basic overall configuration that is provided with a chain that is connected to the bank and extends rearward in the embankment is common to the two embodiments. Therefore, the construction procedure of the reinforced earth wall structure in the second embodiment is the same as that in the first embodiment.

DESCRIPTION OF SYMBOLS 1 Reinforced earth wall structure 2 Retaining wall 3 Wall surface material 31 Frame body 31a Cell 32 Filler 33, 34, 35 Band piece 36 Anchor pin 37 Frame body 37a Cell 38 Arc-shaped piece 38a Vertical bar 38b Horizontal bar 39 Coupling piece 4 Filling 5, 52 Chain 6 Fixing tool 71a, 71b, 71c Hook 72 Connecting tool 74 Muscle material 75 Locking metal fitting 76 Connecting tool 76a Stepped metal fitting 77 Connecting tool 77a L-shaped metal fitting

Claims (4)

Retaining wall made up of wall materials stacked up and down,
The embankment formed behind the retaining wall;
A chain coupled to the retaining wall and extending backward in the embankment;
The wall material is formed by filling a filler in a frame partitioned into cells that are opened up and down,
The frame includes a plurality of arc-shaped pieces formed in an arc shape in plan view,
The cell is partitioned by a pair of arcuate pieces arranged opposite to each other,
The arc-shaped piece is formed by crossing a plurality of vertical bars extending in the vertical direction and a plurality of horizontal bars extending in the circumferential direction in a lattice shape,
Combining the vertical stripes of the adjacent arc-shaped pieces, a binding material made of a helical wire is wound, the arc-shaped pieces are combined,
A reinforced earth wall structure in which the chain is locked to the longitudinal bars wound around the binding material . Retaining wall made up of wall materials stacked up and down,
The embankment formed behind the retaining wall;
A chain coupled to the retaining wall and extending backward in the embankment;
The wall material is formed by filling a filler in a frame partitioned into cells that are opened up and down,
The frame includes a plurality of arc-shaped pieces formed in an arc shape in plan view,
The cell is partitioned by a pair of arcuate pieces arranged opposite to each other,
The arc-shaped piece is formed by crossing a plurality of vertical bars extending in the vertical direction and a plurality of horizontal bars extending in the circumferential direction in a lattice shape,
Combining the vertical stripes of the adjacent arc-shaped pieces, a binding material made of a helical wire is wound, the arc-shaped pieces are combined,
The chain is locked to a locking member provided on the frame,
The locking member is a muscle material that penetrates the frame body so as to be skewered in the width direction of the reinforcing earth wall, and a chain is secured to the muscle material in the cell.
A reinforced earth wall structure characterized by that . Retaining wall made up of wall materials stacked up and down,
The embankment formed behind the retaining wall;
A chain coupled to the retaining wall and extending backward in the embankment;
The wall material is formed by filling a filler in a frame partitioned into cells that are opened up and down,
The frame includes a plurality of arc-shaped pieces formed in an arc shape in plan view,
The cell is partitioned by a pair of arcuate pieces arranged opposite to each other,
The arc-shaped piece is formed by crossing a plurality of vertical bars extending in the vertical direction and a plurality of horizontal bars extending in the circumferential direction in a lattice shape,
Combining the vertical stripes of the adjacent arc-shaped pieces, a binding material made of a helical wire is wound, the arc-shaped pieces are combined,
The chain is locked to a locking member provided on the frame,
The locking member is composed of a locking metal fitting abutting on the rear side of the frame body, and the entire length of the locking metal structure is longer than the grid of the arc-shaped piece, and the chain is fixed to the locking metal fitting. ing
A reinforced earth wall structure characterized by that . The reinforced earth wall structure according to any one of claims 1 to 3, wherein the upper wall surface material is retreated from the lower wall surface material and stacked to form the retaining wall.

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