JP2006316462A - Block masonry retaining wall using chain, and concrete block for use therein - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To implement a reinforcing earth wall or a concrete retaining wall which is simple in structure, easy to construct, strong and stable, and formed of block masonry. <P>SOLUTION: The reinforcing earth wall or the concrete retaining wall is formed of a plurality of concrete blocks 2 which are horizontally and vertically stacked on one another, horizontal chains 3 connecting the right and left concrete blocks 2, 2, vertical chains 4 connecting the upper and lower concrete blocks 2, 2, and reinforcing chains 5 overhanging rearward from the concrete blocks 2. The concrete blocks 2 which are spaced away from one another in the horizontal direction are arranged zigzag as a whole. Each reinforcing chain 5 has one end connected to the concrete block 2 and the other end held by a mound 35 or the cut natural ground 54. Each vertical chain 4 piercing the concrete block 2 in the vertical direction is strained between the lowermost-stage concrete block 2 and the uppermost-stage concrete block 2. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a retaining wall for forming and maintaining a vertical or inclined slope. In particular, the present invention relates to a reinforced earth wall or concrete retaining wall as a block retaining wall configured by stacking concrete blocks in the left and right and up and down directions, and a concrete block used for the same.

  Conventionally, for example, a reinforced earth wall method using a concrete panel as a wall material, such as a tail arme method or a multi-anchor method, is known. However, the embankment that forms the back surface of the wall surface material is easily deformed during rolling, whereas the concrete panel has a large area and high rigidity, so that minute displacement and deformation hardly occur. Therefore, originally, the wall material is displaced slightly following the deformation of the embankment to reduce the earth pressure and stabilize the entire retaining wall, but using a concrete panel did not provide sufficient stability. .

  For these reasons, it has been practiced to obtain a stable reinforced earth wall by using a concrete block having a smaller area than a concrete panel as a wall material. At that time, as disclosed in the following patent documents, block retaining walls using various reinforcing materials have also been proposed. In addition, in the following, the code | symbol of parenthesis is a code | symbol in each patent document.

  In Patent Document 1 below, as shown in FIG. 1, an L-shaped or T-shaped embankment reinforcing material (3) made of reinforcing steel or steel strip is formed in a fixing groove (1d) formed in a wall block (1). It is disclosed that a plurality of hooks (3a) are arranged and filled with a solidified material (6) such as concrete or epoxy resin to connect a plurality of wall blocks (1) adjacent in the left-right direction.

  In the following Patent Document 2, as shown in FIG. 1, a vertical connecting rod (5b) is continuously inserted into a plurality of retaining wall blocks (1) adjacent in the vertical direction, and the vertical connecting rod (5b). Discloses a reinforced earth structure in which an embankment reinforcing material (3) made of reinforcing steel or steel strip is connected via a fixing metal fitting (6).

  Further, in Patent Document 3 below, as shown in FIG. 1, reinforced soil in which a net sheet-like reinforcing body (23) called a geogrid is sandwiched between upper and lower adjacent retaining blocks (25, 26). A structure is disclosed.

JP 2003-321839 A JP 2003-3474 A JP 2001-81780 A

In the case of a concrete panel, a plurality of reinforcing materials are usually attached to a single panel, and the wall material area of one reinforcing material is generally about 0.4 m ^{2 to} 0.75 m ² / piece. On the other hand, the area of the concrete blocks, for 0.1m ² ~0.15m ^{2 /} sheets about and small, in all the concrete blocks be provided reinforcement is uneconomical, concrete block exists that the reinforcing member is not attached. However, according to recent post-earthquake surveys, in the case of a general concrete block retaining wall that is not a reinforced earth method, single or multiple concrete blocks fall off the retaining wall due to local stress concentration. A situation has been reported. Therefore, it is desirable to connect the concrete blocks to each other as much as possible.

  By the way, regarding the construction of the block stacking retaining wall, it is divided into a kneading method and an empty stacking method depending on whether or not the concrete is placed on site and the blocks are joined with concrete. In the kneading method, concrete blocks are integrated with each other by placing concrete (bottled concrete, backfilled concrete) on the hollow portion and back surface of the concrete block. This kneading method is intended to improve the stability of the wall surface by connecting the blocks together with concrete, and is generally performed. In addition, if reinforcing bars are arranged around the concrete block, the integrity is further increased and the earthquake resistance can be improved. However, in this kneading method, even if the earthquake resistance is obtained by integrating the blocks, the effect of obtaining the stability of the entire wall surface is lost because the individual blocks are slightly displaced.

  On the other hand, in the empty stacking method, in order to obtain this effect, the hollow portion and the back surface of the concrete block are filled with crushed stone as a drainage layer. In this empty stacking method, the blocks are constructed with empty joints that do not have mortar joints, etc., so that drainage is not hindered, and the horizontal gap is as large as about 2 cm. Not. In the vertical direction, the blocks are connected with irregularities, and the blocks are connected to each other by an interlocking (meshing) effect by crushed stone filled in the hollow portion and the back surface of the block. However, in this empty loading method, since the small-diameter soil in the crushed stone is lost due to the drainage action, the interlocking effect is not sufficient.

  Here, as in the inventions described in Patent Document 1 and Patent Document 2, even when reinforcing materials such as reinforcing bars and steel strips are used, bending stress and shearing force are easily generated in the reinforcing material due to deformation of the ground. That is, the embankment is generally more compressible than a wall material such as a concrete block, and the consolidation of the foundation ground is generally large in the center of the embankment and the embankment boundary (near the wall) is generally small. Therefore, when reinforcing bars and steel strips are used as reinforcing materials, they have uniform rigidity in the longitudinal direction, so excessive bending stress due to deformation of the ground, drainage layer and embankment layer, or drainage layer and wall material At the boundary, the shear force was received by the difference in displacement of the embankment.

  Further, as in the invention described in Patent Document 3, when a geogrid is used as a reinforcing material, the geogrid is flexible and easily follows displacement, but has a low resistance to a shearing force. There were the following problems. That is, the crushing surface of the crushed stone filled in or around the block was easily damaged during the crushed stone rolling. In the long term, the small-diameter soil was lost due to the drainage action, and the crushed stone surface was easily damaged. Furthermore, since the geogrid is sandwiched between the blocks, there is a risk of shearing between the sandwiched blocks due to the settlement of the embankment.

  The problem to be solved by the present invention is to realize a strong and stable reinforced earth wall or concrete retaining wall with a block structure with a simple configuration and construction. Moreover, it is providing the concrete block used for such a block stacking wall.

  The present invention has been made to solve the above-mentioned problems, and the invention according to claim 1 is directed to a plurality of concrete blocks stacked in the left and right and up and down directions, a horizontal chain connecting the left and right concrete blocks, It is a block stacking wall using a chain characterized by comprising a vertical chain that connects the concrete blocks of each other.

  According to invention of Claim 1, a horizontal chain and a vertical chain are arrange | positioned at net shape, and concrete blocks are connected with this chain net. Therefore, while maintaining the flexible structure using the chain, the concrete blocks can be connected to each other to form a strong and stable retaining wall, and the seismic performance can be improved.

  In the invention according to claim 2, the concrete blocks are arranged in a staggered manner with a gap between adjacent left and right concrete blocks, and the vertical chain passed through each concrete block in the vertical direction is the lowermost step. The block retaining wall using a chain according to claim 1, wherein the block retaining wall is tensioned between a concrete block or a concrete foundation on which the concrete block is placed and a top concrete block.

  According to the second aspect of the present invention, the concrete blocks are staggered with a gap left and right, and the vertical chain is only passed through each concrete block in the middle in the vertical direction. A vertical chain was installed between the concrete blocks without looseness. Thereby, it is possible to configure a stronger and more stable retaining wall while maintaining a flexible structure with a simple configuration and construction, and it is possible to improve seismic performance.

  Invention of Claim 3 is further equipped with the reinforcement chain by which one end part is connected with the said concrete block, and the other end part is hold | maintained by embankment or a cut land mountain, The Claim 1 or Claim 2 characterized by the above-mentioned. Block retaining wall using the described chain.

  According to invention of Claim 3, by using a chain as a reinforcing material, it is easy to absorb the deformation of embankment, and there is no decline in yield strength due to bending caused by the deformation of the ground. Therefore, as a more flexible retaining wall, stability and safety can be improved.

  The invention according to claim 4 is a leaning type retaining wall in which the concrete blocks are stacked so as to incline backward as going upward, and the reinforcing chain is provided only on the uppermost stage or a plurality of stages of concrete blocks. The block retaining wall using the chain according to claim 3, wherein the block retaining wall is provided.

  According to the invention described in claim 4, in the leaning type retaining wall in the cut portion or the like, the reinforcing chain is provided only in the upper concrete block of one or more stages. It is thought that it is not necessary to provide a reinforcing material originally because the natural ground is stable in such a construction site, but by providing a reinforcing material only with the upper concrete block, the lower end of the wall at the time of the earthquake It is possible to improve the earthquake resistance by suppressing the rocking movement around the center.

  The invention according to claim 5 is characterized in that each reinforcing chain from a plurality of concrete blocks arranged side by side is held by a common fixture fixed to a cut mountain by an anchor. Or it is a block stacking retaining wall using the chain of Claim 4.

  If the back surface of the retaining wall is cut and the length of the reinforcing chain cannot be taken sufficiently, the cut land mountain may be anchored and connected to the reinforcing chain, but according to the invention of claim 5, There is no need to provide an anchor for each reinforcing chain, and workability is good.

  The invention according to claim 6 is a concrete block that forms a block stacking wall by stacking left and right and up and down, an insertion portion through which a horizontal chain that connects the left and right concrete blocks is passed, or of this horizontal chain The engagement part to the link and the insertion part through which the vertical chain connecting the upper and lower concrete blocks are passed, or the engagement part to the link of this vertical chain, are provided individually or in common. It is a concrete block for the block-retaining wall.

  According to invention of Claim 6, the concrete block used for the block stacking wall of Claim 1 or Claim 2 can be provided.

  Furthermore, the invention according to claim 7 is characterized in that the engaging portion to the link of the reinforcing chain held on the embankment or the cut mountain is the insertion portion or the engaging portion of the horizontal chain and / or the vertical chain. The concrete block for a block stacking wall according to claim 6, wherein the concrete block is provided individually or in common.

  According to invention of Claim 7, the concrete block used for the block pile retaining wall in any one of Claim 3 to Claim 5 can be provided.

  According to the block pile retaining wall using the chain of the present invention, a strong and stable reinforced earth wall or concrete retaining wall can be realized with a simple configuration and construction. Moreover, according to this invention, the concrete block used for such a block pile retaining wall can be provided.

  Hereinafter, the block stacking retaining wall using the chain of the present invention and the concrete block used therefor will be described in more detail based on examples.

  1 to 4 are schematic views showing Embodiment 1 of a block stacking wall according to the present invention. FIG. 1 is a front view, FIG. 2 is a rear view, FIG. 3 is a longitudinal sectional view in side view, and FIG. It is the perspective view seen from the back side which omitted the part. The retaining wall of the present embodiment is a reinforced soil wall having a vertical wall surface. In the first embodiment, the backfilling material 1 such as cut crushed stone is not only filled on the back side of the concrete block 2 but also in the space between the concrete blocks 2 and 2. 3 and FIGS. 7 to 9, the latter is not shown.

  The block stacking wall according to the first embodiment includes a large number of concrete blocks 2, 2... Arranged side by side and top and bottom, and a plurality of horizontal chains 3, 3 connecting the concrete blocks 2, 2. And a plurality of vertical chains 4, 4... Connecting the concrete blocks 2, 2... Arranged vertically, and reinforcing chains 5, 5.

  Each concrete block 2 basically has the same shape and size. As shown in FIG. 4, the concrete block 2 of the present embodiment is formed in a substantially H shape in plan view. Specifically, a substantially rectangular plate-shaped front material 6 that forms a wall surface, a substantially rectangular plate-shaped rear material 7 that is spaced rearward from the front material 6 and arranged in parallel with the front material 6, and these front surfaces A substantially rectangular plate-shaped web material 8 that connects the material 6 and the rear surface material 7 is integrally formed of concrete.

  The rear member 7 is formed such that the width dimension V in the left-right direction is smaller than the width dimension W of the front member. The web member 8 is disposed perpendicular to the plate surfaces of the front member 6 and the rear member 7 and connects the center portions in the width direction of the front member 6 and the rear member 7. As a result, the front member 6 and the rear member 7 are disposed so as to extend outward in the left-right direction from the web member 8 and have a substantially H shape in plan view as a whole. In this embodiment, the length of the rear surface material 7 extending from the web material 8 to the left and right is about half of the length of the front material 6 extending from the web material 8 to the left and right.

  The connecting portion between the web member 8 and the front member 6 or the rear member 7 is slightly thick and formed in an arc shape. The front material 6, the rear material 7, and the web material 8 are formed in the same height dimension, and the upper surface and lower surface of the concrete block 2 are formed in the horizontal surface. However, on the upper surface of the web member 8, a substantially rectangular low protrusion 9 protrudes upward and is integrally formed. In the plan view, the size of the protrusion 9 is substantially the same as that of the web material 8. The periphery of the protrusion 9 is chamfered in a tapered shape.

  The size of the concrete block 2 is not particularly limited, but in the present embodiment, for example, the lateral width W of the front member 6 is 460 mm, the lateral width V of the rear member 7 is 280 mm, and the height in the vertical direction. H is 240 mm (the height of the protrusion 9 is 15 mm separately), and the depth dimension D in the front-rear direction is 350 mm.

  The concrete block 2 is provided with mounting portions for the horizontal chain 3, the vertical chain 4, and the reinforcing chain 5 individually or in common. The mounting locations and mounting configurations of the chains 3, 4 and 5 with respect to the concrete block 2 can be appropriately changed regardless of the particular, and the mounting configuration may be an insertion portion that simply allows the chains 3, 4, and 5 to pass through. The engaging part of the chains 3, 4, 5 to the link 10 may be used.

  In the concrete block 2 of the present embodiment, an insertion portion 11 through which the vertical chain 4 is passed is formed on the back surface of the front material 6, and to each link 10 of the horizontal chain 3 and the reinforcing chain 5 on the back surface of the rear surface material 7. The engaging portion 12 is formed. Specifically, an insertion portion 11 through which the vertical chain 4 is passed is provided on the rear surface of the front material 6 on either the left or right side of the web material 8. In the insertion portion 11, a metal ring similar to the chain link 10 is horizontally arranged, and half of the insertion portion 11 is embedded and fixed in the concrete block 2. As a result, the other half of the metal ring is provided in the center of the back surface of the front member 6 in the vertical direction, and the vertical chain 4 can be inserted into the hole.

  By the way, the concrete block 2 has a slight gap (20 mm in this embodiment) between the adjacent left and right blocks 2 and 2, and the adjacent upper and lower blocks 2 and 2 are staggered by half to the left and right. Staggered arrangement. Therefore, the said insertion part 11 provided in the back surface of the front surface material 6 is provided alternately by the upper and lower concrete blocks 2 and 2 on either side of the web material 8 on both sides. Alternatively, the insertion portion 11 may be provided on both the left and right sides of the web material 8 on the back surface of the front material 6 and either one of them may be used.

  In addition, since the concrete blocks 2 are staggered as described above, the concrete blocks 2 having a short horizontal dimension cut to a desired dimension are obtained at the left and right ends of the wall constructed by arranging the concrete blocks 2 side by side and vertically. 13 is used.

  The vertical chain 4 passed through each insertion portion 11 of the concrete blocks 2 arranged vertically is tensioned between the concrete blocks 2 and 2 at the lowermost stage and the uppermost stage. FIG. 5 is a view showing a state in which the lower end of the vertical chain 4 is attached to the lowermost concrete block 2, (a) is a side view with a part in cross section, (b) is a rear view seen from the rear, (C) It is the top view which made a part a cross section.

  As described above, on the back surface of the front member 6 of the concrete block 2, a substantially oval metal ring is horizontally arranged, half of which is embedded in the concrete block, and the other half is rearward. It protrudes into the insertion part 11 of the vertical chain 4. And as shown in FIG. 5, the lower end part of the vertical chain 4 is connected with the insertion part 11 of the concrete block 2 of the lowest step.

  Specifically, the link 10 at the lower end of the vertical chain 4 is connected to the lowermost concrete block 2 by the wedge material 14 locked to the insertion portion 11 and the screw rod 15 held by the wedge material 14. Is done. The wedge material 14 has a tapered inclined surface that tapers as it goes upward, and a front surface is formed on the vertical surface 16. The wedge material 14 has a cross-sectional shape in which the upper end portion is smaller than the inner dimension of the insertion portion 11 and the lower end portion is larger than the inner dimension of the insertion portion 11. The vertical surface 16 is fitted into the insertion portion 11 from below with the vertical surface 16 in contact with the back surface of the front material 6 of the concrete block 2.

  The screw rod 15 is disposed so as to penetrate the wedge material 14 in the vertical direction, and a lower end portion is formed in a bolt-like screw portion 17. A nut 18 is screwed into the screw portion 17 from below and is brought into contact with the bottom surface of the wedge material 14. Two plate members 19, 19 are arranged in parallel at a distance from the upper end of the screw rod 15, and are fixed to the screw rod 15 by welding. A link 10 at the lower end of the vertical chain 4 is disposed between the plate members 19 and 19 and is connected by a bolt and nut 20.

  In this way, the link 10 at the lower end of the vertical chain 4 is engaged and fixed to the lowermost concrete block 2 via the screw rod 15 and the wedge material 14. The vertical chain 4 with its lower end fixed in this way is passed through the insertion portions 11 of the concrete blocks 2, 2... Arranged in the middle in the vertical direction, and then connected to the uppermost concrete block 2. The The vertical chain 4 may be connected to the uppermost concrete block 2 in a vertically symmetrical shape with FIG.

  That is, the wedge material 14 is fitted into the insertion portion 11 of the uppermost concrete block 2 from above, and the screw rod 15 is passed through the wedge material 14. The lower end portion of the screw rod 15 is connected to the link 10 at the upper end portion of the vertical chain 4, and the upper end portion of the screw rod 15 is tightened with a nut 18 via a wedge material 14. Thereby, the vertical chain 4 can be tensioned between the concrete blocks 2 and 2 at the lowermost stage and the uppermost stage.

  FIG. 6 is a schematic view showing a back surface portion of the rear member 7 of the concrete block 2 and showing a state in which the lateral chain 3 and the reinforcing chain 5 are attached to the concrete block 2, wherein (a) is a side view and (b). These are plan views, each showing a part thereof in cross section. As shown in this figure, in the present embodiment, two elongated and substantially rectangular mounting plates 21 and 21 are disposed in parallel at the center of the rear member 7 of the concrete block 2 so as to be spaced apart in the vertical direction. In addition, it is provided to extend rearward. Each mounting plate 21 has a base end portion embedded in the concrete block 2 and is fixed to the concrete block 2. The separation distance between the mounting plates 21 and 21 is larger than the thickness of the link 10 of the horizontal chain 3 or the reinforcing chain 5.

  Two bolts 22 and 23 are passed in the vertical direction between the mounting plates 21 and 21 that are spaced apart in the vertical direction and arranged in parallel. These bolts 22 and 23 are passed through the link 10 of the lateral chain 3 or the reinforcing chain 5 and are held by nuts 24 and 25 that are screwed into the front ends of the bolts 22 and 23. The first bolt nuts 22 and 24 arranged on the concrete block 2 side hold the link 10 of the horizontal chain 3. In addition, the link 10 of the reinforcing chain 5 is held by the second bolt nuts 23 and 25 disposed behind the first bolt nuts 22 and 24.

  The horizontal chain 3, the vertical chain 4, and the reinforcing chain 5 may be differently configured chains, but in this embodiment, are configured using links 10 having the same shape and size. As is well known, each of the chains 3, 4, and 5 is formed by connecting the annular links 10 to each other. Each link 10 has the same shape and size as described above, and has a substantially oval shape in which approximately semicircular curved portions are connected by a linear portion.

  The vertical chain 4 is passed through the insertion part 11, the horizontal chain 3 is engaged with the first bolt nuts 22, 24 on the link 10, and the reinforcing chain 5 is connected to the link 10 at one end thereof. The second bolt nuts 23 and 25 are engaged. The concrete block 2 and the horizontal chain 3 are dimensioned so that any link 10 of the horizontal chain 3 can be engaged with the engaging portion 12 of each concrete block 2 arranged in a staggered manner. Yes.

  By the way, as shown in FIG. 4, the other end of the reinforcing chain 5 is engaged with the bearing plate 26, and the bearing plate 26 is fixed to the embankment by the bearing pins 27. The configuration of the support plate 26 is not particularly limited. In the present embodiment, the support plate 26 is formed of an L-shaped material including a horizontal plate portion 28 and a vertical plate portion 29. A substantially cross-shaped insertion hole 30 through which the other end of the reinforcing chain 5 can be inserted is formed in the horizontal plate portion 28. The substantially cross-shaped insertion hole 30 is formed by the intersection of two elongated cutout grooves. One cutout groove extends to the middle of the vertical plate portion 29 to form an extension groove 31. . The extension groove 31 allows the link 10 at the other end of the reinforcing chain 5 passed through the insertion hole 30 to move to the vertical plate portion 29 so that it cannot be dropped off.

  Accordingly, after passing one link 10 at the other end of the reinforcing chain 5 from the lower side of the horizontal plate portion 28 through the insertion hole 30 having a substantially cross shape, the link 10 adjacent to the link 10 is extended to the extending groove 31. In this state, the reinforcing chain 5 can be moved to the vertical plate portion 29. In the state of being moved to the vertical plate portion 29, there is no possibility that the reinforcing chain 5 falls off from the bearing plate 26.

  Small holes 32, 32 are formed in the horizontal plate portion 28 of the pressure bearing plate 26 at two positions sandwiching the insertion hole 30. A support pin 27 can be inserted into the small hole 32. The bearing pin 27 of the present embodiment is composed of a wire bent in a downward U-shape. Therefore, the both ends of the bearing pin 27 are passed through the small hole 32 and driven into the embankment, whereby the bearing plate 26 and thus the other end of the reinforcing chain 5 can be fixed.

  Next, the construction procedure of the block stacking retaining wall of the present embodiment will be described. FIG. 7 to FIG. 9 are diagrams showing, in chronological order, the construction method of the block stacking wall of this embodiment. In order to construct a reinforced earth wall using the concrete block 2 of the present embodiment, as shown in FIG. 7A, first, for example, about 50 cm is excavated at a root portion, and a base material 33 such as a cut crushed stone is formed. Whisper. Next, as shown in FIG. 4B, a concrete frame 34 is made by assembling a mold on the foundation crushed stone 33 formed in this way and placing concrete there.

  After the concrete is hardened, the first-stage concrete blocks 2 are arranged on the concrete foundation 34 as shown in FIG. At that time, a slight gap is formed between the adjacent left and right concrete blocks 2 and 2 as described above. And as shown in the figure (d), the 1st embankment material 35 is unwound and it compacts horizontally. At that time, the embankment layer 35 is provided in a state where a gap of, for example, about 50 cm is opened from the back surface of the concrete block 2. Thereafter, the first back-filling material 1 made of crushed stone or the like is unwound into the gap between the concrete block 2 and the embankment layer 35 and compacted. Note that the first-layer embankment material 35 and the backfill material 1 are provided up to about half the height of the first-stage concrete block 2, and the engaging portion 12 and the like to the horizontal chain 3 are exposed.

  Next, as shown in FIG. 8 (e), the horizontal chain 3 and the vertical chain 4 are attached to the concrete block 2. The horizontal chain 3 can be attached to the concrete block 2 by engaging the first bolt nuts 22 and 24 of the concrete block 2 with the link 10 of the horizontal chain 3 as described above (FIG. 6). In this way, the concrete blocks 2, 2... Arranged on the left and right are connected to each other by the horizontal chain 3 that is horizontally arranged without sagging. Further, the lower end portion of the vertical chain 4 is attached to the lowermost concrete block 2 through the wedge material 14 and the screw rod 15 as described with reference to FIG.

  Next, as shown in FIG. 8 (f), a reinforcing chain 5 is laid on each concrete block 2. In the reinforcing chain 5, the link 10 at one end is connected to the second bolt nuts 23 and 25 of the concrete block 2 (FIG. 6), and the link 10 at the other end is connected to the embankment layer 35 via the bearing plate 26. Fixed. As described above, the downward U-shaped support pin 27 is used to fix the support plate 26 to the embankment layer 35 (FIG. 4).

  Next, as shown in FIG. 8G, the second-stage concrete block 2 is installed on the upper surface of the first-stage concrete block 2. At this time, as shown in FIGS. 1 and 2, the concrete blocks 2, 2... Are staggered so that the second-stage concrete blocks 2 are arranged between the concrete blocks 2, 2 in the first stage. . The second-stage concrete blocks 2 and 2 are also arranged with a slight gap left and right.

  Thereafter, as shown in FIG. 9 (h), the second-layer embankment material 35 is unwound and compacted horizontally. At that time, like the first-layer embankment material 35, it is provided separately from the back surface of the concrete block 2. Then, the backfill material 1 made of crushed stone or the like is unwound into the gap between the concrete block 2 and the embankment layer 35 and compacted. The second-layer embankment material 35 and the like are provided up to about half the height of the second-stage concrete block 2.

  Thereafter, as shown in FIG. 9 (i), the horizontal chain 3 and the vertical chain 4 are attached to the second-stage concrete block 2. The horizontal chain 3 is attached to the second stage concrete block 2 in the same manner as in the first stage. On the other hand, the vertical chain 4 can be attached to the second-stage concrete block 2 only by passing the vertical chain 4 through the insertion portion 11. Then, as shown in FIG. 9 (j), one end portion of the reinforcing chain 5 is connected to the second-stage concrete block 2, and the other end portion of the reinforcing chain 5 is placed in a state where the reinforcing chain 5 is laid horizontally by being strained backward. It fixes to the embankment material 35 using the bearing plate 26. FIG.

  Thereafter, similarly, the concrete blocks 2 are stacked, the embankment material 35 and the backfilling material 1 are unwound and compacted, the left and right concrete blocks 2 and 2 are connected by a horizontal chain 3, and the upper and lower concrete blocks 2 are vertically connected. The chain 4 is passed through the insertion portion 11, and the concrete blocks 2 are stacked up to a desired height while a reinforcing chain 5 is laid on each concrete block 2 toward the rear. Then, the upper end of the vertical chain 4 is connected to the insertion portion 11 via the wedge material 14 and the screw rod 15, and the nut 18 is tightened on the screw rod 15 to the uppermost concrete block 2. Is in tension. Finally, top concrete 36 is provided on the upper part of the uppermost concrete block 2 (FIG. 3).

  In this way, the retaining wall of the concrete block 2 has the horizontal chain 3 and the vertical chain 4 arranged on the back surface in a net shape, and the concrete blocks 2, 2. Moreover, each concrete block 2 is also hold | maintained by the reinforcement chain 5 laid toward back.

  The retaining wall of the present embodiment is composed of three layers: a concrete block 2, a drainage layer 1 made of crushed stone disposed on the back surface thereof, and an embankment layer 35 made of general earth and sand disposed behind the concrete block 2. Here, the consolidation (settlement) of the foundation ground is generally large at the center of the embankment, tends to decrease as it approaches the wall surface side, and the compressibility is greatest for the earth and sand. Therefore, even if careful construction is performed, the embankment is inevitably deformed over time, and the reinforcing material is bent due to the difference in deformation of each layer, and a shearing force acts on the boundary portion of each layer. However, in this embodiment, since the chain 5 is used as the reinforcing material, it is possible to follow the deformation of the ground and prevent a decrease in yield strength due to bending.

  Incidentally, the concrete block 2 has one feature that it can be easily installed in a curved shape, but it may be unstable due to an earthquake. However, if the chain net by the horizontal chain 3 and the vertical chain 4 is provided on the back surface of the concrete block 2 as in this embodiment, the phenomenon that the retaining wall protrudes can be suppressed. Moreover, since the large deformation of the wall surface can be suppressed, the concrete block 2 can be prevented from falling off. Thus, the chain net by the horizontal chain 3 and the vertical chain 4 has an earthquake resistance effect.

  In addition, according to the block stacking retaining wall of the present embodiment, the concrete blocks 2, 2... Are connected to each other, so that there is no risk of dropping the concrete block 2 during installation work, and accident prevention can be achieved. Further, since it is not necessary to wait for the concrete to harden, the concrete block 2 can be continuously installed, and the construction period can be shortened. Moreover, it is economical.

  Moreover, although the upper and lower ends of the vertical chain 4 are connected to the concrete block 2, the vertical chain 4 can be easily tensioned only by tightening the nut 18 with respect to the screw rod 15. The tension of the vertical chain 4 is transmitted to the insertion portion 11 made of a metal ring in a direction perpendicular to the inclined surface of the wedge material 14 in each of the uppermost and lowermost concrete blocks 2 and 2. This force is divided into a tensile force perpendicular to the concrete surface and a couple force parallel to the concrete surface. Among them, the couple force bends the insertion part 11 made of a metal ring, but by making the wedge material 14 gently inclined, most of the force applied to the insertion part 11 is made to be tensile force. Can do.

  Next, a modification of the concrete block 2 of the first embodiment and a block stacking wall using the same will be described. FIG. 10 is a diagram illustrating a first modification of the method for attaching the lateral chain 3 and the reinforcing chain 5 to the rear surface member 7 of the concrete block 2 of the first embodiment, and (a) is a side view in which a part thereof is shown in cross section. , (B) is a plan view partly in section.

  In this modification, a bar 37 having a substantially rectangular cross section is fixed to the center of the rear member 7 of the concrete block 2. About half of the bar 37 is embedded and fixed in the concrete block 2, and the other half is provided extending rearward. Two bolts 22 and 23 are vertically fixed to the extending portion of the bar 37 so as to be separated from each other in front and rear and in parallel. The bolts 22 and 23 are arranged to extend in the vertical direction, and nuts 24 and 25 can be screwed into the front end portion via a pressing plate 38. The holding plate 38 is a substantially rectangular plate material, and two through holes are formed corresponding to the bolts 22 and 23.

  Also in the case of this modification, the link 10 of the horizontal chain 3 is passed through the first bolt 22 disposed at the front, and the link 10 of the reinforcing chain 5 is passed through the second bolt 23 disposed at the rear. The Then, the holding plate 38 is held by the first bolt 22 and the second bolt 23 through the through hole, and then the nuts 24 and 25 are fastened to the tips of the bolts 22 and 23. However, the nuts 24 and 25 may be provided only on one of the bolts 22 (or 23). In this case, the bolts 23 (or 22) on the side where the nuts 24 (or 25) are not provided. It is not necessary to provide a threaded portion, and a simple bar is sufficient.

  FIG. 11 is a view showing a modified example 2 of the method of attaching the lateral chain 3 and the reinforcing chain 5 to the rear surface member 7 of the concrete block 2 of the first embodiment, and (a) is a side view in which a part thereof is a cross section. , (B) is a plan view partly in section. In this modification, the first bolt nuts 22 and 24 and the second bolt nuts 23 and 25 in the first embodiment are made common and configured by a single bolt nut 39 and 40. That is, one bolt 39 is bridged between the two mounting plates 21, 21 protruding from the rear surface material 7 of the concrete block 2, and a nut is attached to the tip of the bolt 39 from the outside of the mounting plate 21. 40 can be screwed. In the case of this modification, between the mounting plates 21, 21, any link 10 of the lateral chain 3 and the link 10 at one end of the reinforcing chain 5 are passed through the bolt 39, and the tip of the bolt 39 What is necessary is just to screw the nut 40 into.

  FIG. 12 is a diagram showing a third modification of the method for attaching the chains 3, 4 and 5 to the concrete block 2 of the first embodiment, (a) is a side view with a part in cross section, and (b) It is the rear view which made a part the cross section. In the concrete block 2 of the first embodiment, the insertion portion 11 through which the vertical chain 4 passes is formed on the back surface of the front material 6, and the links 10 of the horizontal chain 3 and the reinforcing chain 5 are formed on the back surface of the rear material 7. In this modification, the vertical chain 4, the horizontal chain 3, and the reinforcing chain 5 are connected to the center of the rear surface of the rear member 7.

  Specifically, a bolt 41 is fixed to the concrete block 2 at the center of the back surface of the rear member 7, and a hook fitting 42 is attached to the bolt 41. About half of the bolt 41 is embedded and fixed in the concrete block 2, the other half extends rearward, and a threaded portion 43 is formed in the extended portion. On the other hand, the hook metal fitting 42 is a substantially rectangular metal plate, a nut 44 is welded to one end thereof, and a hook-like locking groove 45 is formed on the other end thereof.

  In the case of this modification, after the links 10 of the vertical chain 4 and the horizontal chain 3 are passed through the embedded bolts 41, the nuts 44 of the hook fittings 42 are screwed into the screw portions 43 and fixed. Then, the link 10 of the reinforcing chain 5 is engaged with the locking groove 45 of the hook fitting 42 and used.

  FIG. 13A is a diagram illustrating a fourth modification of the method for attaching the chains 3, 4 and 5 to the concrete block 2 according to the first embodiment. In the case of this modification, the horizontal chain 3, the vertical chain 4, and the reinforcing chain 5 are collectively connected to the concrete block 2 at one place as in the third modification. Specifically, a metal ring similar to a chain link is horizontally arranged on the back surface of the rear material 7 of the concrete block 2, half of which is embedded and fixed in the concrete block, and the other half is behind. It protrudes to be an engagement portion 12 to each chain 3, 4, 5.

  Each of the chains 3, 4, 5 is connected to the concrete block 2 by a shackle 48 comprising a substantially U-shaped material 46 and a bolt 47 provided so as to bridge between both open ends of the engaging portion 12. Is done. That is, the substantially U-shaped member 46 is passed through the links 10 and 10 of the upper and lower vertical chains 4 and 4 and the link 10 at one end of the reinforcing chain 5, and the bolt 47 is connected to the engagement member. In the state where the link 10 of the horizontal chain 3 is passed in addition to the joint portion 12, the bolt 47 is bridged and fixed to both open ends of the substantially U-shaped material 46. In the case of this modification, a relatively short vertical chain 4 is used, and the upper and lower concrete blocks 2 and 2 are sequentially connected.

  By the way, although the said engagement part 12 provided in the concrete block 2 used the link-shaped metal annular body in Fig.13 (a), as shown in the same figure (b), a cap nut is attached to a concrete block. 49 may be embedded, and the eyebolt 50 may be screwed into the cap nut 49. In this case, the bolt 47 of the shackle 48 is passed through the through hole formed in the head of the eyebolt 50. Further, as shown in FIG. 2C, an embedded bolt 41 may be fixed to the concrete block 2 and an eye nut 51 may be screwed into the bolt 41. In this case, the bolt 47 of the shackle 48 is passed through the through hole formed in the eye nut 51.

  FIG. 14: is a schematic side view which shows Example 2 of the block stacking wall of this invention, and has shown one part in cross section. The concrete block 2 and the block retaining wall using the same according to the second embodiment basically have the same configuration as that of the first embodiment. Therefore, in the following, the description will be focused on the different parts, and corresponding portions will be described with the same reference numerals.

  The retaining wall of the second embodiment is a leaning retaining wall. That is, the concrete blocks 2, 2... Are stacked so as to incline backward as they go upward. Therefore, the upper surface of the concrete foundation 34 is formed to be inclined. Also in the block stacking retaining wall of the present embodiment, the backfilling material 1 such as a cut crushed stone is provided on the space between the concrete blocks 2 and 2 arranged in a staggered manner and the back surface of the concrete block 2 as in the first embodiment. Filled.

  In the second embodiment, a reinforcing material such as the reinforcing chain 5 is not provided on the back surface of the concrete block 2, but a chain net including the horizontal chain 3 and the vertical chain 4 is provided. For this purpose, a bolt 41 is fixed to the center of the back surface of the rear member 7 of the concrete block 2. The bolt 41 is made of a substantially L-shaped bar, and the substantially L-shaped portion is embedded in the concrete block 2, and a rod-shaped screw portion 43 is provided to extend rearward.

  In the second embodiment, after the links 10 of the horizontal chain 3 and the vertical chain 4 are passed through the bolts 41, nuts 52 are screwed into the screw portions 43. Thereby, the horizontal chain 3 and the vertical chain 4 are provided on the back surface of the retaining wall constructed of the concrete blocks 2, 2. By connecting the concrete blocks 2 and 2 with a chain net composed of the horizontal chain 3 and the vertical chain 4, it is possible to improve the integrity of the entire block retaining wall and improve the earthquake resistance.

  Next, a modification of the concrete block 2 of the second embodiment and a block stacking wall using the same will be described. FIG. 15: is a schematic side view which shows the modification 1 of the block stacking retaining wall of Example 2, and has shown one part in cross section. In the example of illustration, although the example constructed with embankment is shown, it is applicable similarly to a cut part.

  In the first modification, a chain connecting bracket 53 (corresponding to the mounting plates 21 and 21 and the bolts and nuts 39 and 40 in FIG. 11) provided on the uppermost concrete block 2 is applied to the reinforcing chain 5 as in the first embodiment. The link 10 at one end is engaged, the reinforcing chain 5 is tensioned backward so as not to sag, and the link 10 at the other end is fixed by the bearing plate 26. In the illustrated example, the reinforcing chain 5 is provided only on the uppermost concrete block 2, but the reinforcing chain 5 may be provided on each lower concrete block 2. For example, the reinforcing chain 5 may be provided only on one or two concrete blocks 2 at the uppermost level and immediately below the uppermost level.

  By installing the reinforcing chain 5 at a position approximately 50 cm below the upper end of the retaining wall as in this modification, it is possible to suppress the rocking motion centered on the lower end of the wall during an earthquake. In the present embodiment, the reinforcing chain 5 is installed at one upper end in cross section and is laid at a pitch of about 50 cm in the horizontal direction, but these can be changed as appropriate.

  FIG. 16: is a schematic side view which shows the modification 2 of the block stacking retaining wall of Example 2, and has shown one part in cross section. In this modification, an example in which the cut portion 54 is constructed is shown. This modification is used when the back surface of the wall is cut and the length of the reinforcing chain 5 is not sufficient. That is, the anchor 55 is applied to the cut land 54, and the link 10 of the reinforcing chain 5 is connected to the anchor 55. Thereby, the rocking motion at the time of an earthquake can be suppressed.

  FIG. 17 is a schematic perspective view showing a connection state between the anchor 55 and the reinforcing chain 5. As shown in this figure, an anchor 55 is driven and fixed to a cut land mountain 54 (not shown in FIG. 17). The end portion of the anchor 55 protrudes from the cut land mountain 54 via pedestal concrete 56 provided on the ground surface. An end portion of the anchor 55 protruding from the pedestal concrete 56 is a threaded portion 57, and a piece 59 of a substantially L-shaped fixture 58 is passed through and fixed to the pedestal concrete 56 with a nut 60. The link 10 at the other end of the reinforcing chain 5 is connected to the other piece 61 of the fixture 58 via a shackle 48.

  In FIG. 17, an example in which the anchor 55 is installed for each reinforcing chain 5 is shown, but the anchor 55 may be shared by a plurality of reinforcing chains 5, 5. FIG. 18 is a view showing a configuration in which four reinforcing chains 5, 5... Are connected to a fixture 58 fixed to the cut land 54 with two anchors 55, 55, (a) is a front view, (B) is XX sectional drawing. In this modified example, the fixture 58 is made of an elongated angle steel having a substantially L-shaped cross section, and the left and right ends of one piece 59 are fixed to the anchor 55 of the cut land 54 via the pedestal concrete 56. The other piece 61 has a plurality of (four in the illustrated example) through holes formed at equal intervals, and the reinforcing chain 5 is connected to each through hole via a shackle 48.

  FIG. 19 is a view showing a modified example of the structure for attaching the reinforcing chain 5 to the anchor 55, where (a) is a front view, (b) is a YY sectional view, and (c) is a ZZ sectional view. is there. Also in this modified example, the four reinforcing chains 5 are connected to the fixture 58 fixed by the two left and right anchors 55, 55 as in the embodiment of FIG. The fixture 58 of this modification is made of a substantially rectangular strip steel, and both left and right ends thereof are fixed to the anchor 55 by nuts 60. In this modification, mounting bolts 62 and 62 are fixed between the left and right anchors 55 and 55. Thereby, the threaded portion 57 of the anchor 55 and the mounting bolt 62 are arranged in parallel at equal intervals.

  In this modification, an eye nut 63 can be fixed to the link 10 at the other end of the reinforcing chain 5 via a shackle 48, and the eye nut 63 is screwed and fixed to the screw portion 57 of the anchor 55 or the mounting bolt 62. Is done. In this modification, a plurality of reinforcing chains 5 are made to correspond to one anchor 55, but one reinforcing chain 5 may be attached to one anchor 55. In this case, the eye nut 63 of the reinforcing chain 5 may be screwed into the screw portion 57 of the anchor 55.

  FIG. 20 is a perspective view showing still another modified example of the structure for attaching the reinforcing chain 5 to the anchor 55. In this example, a plate-like hook material 64 is fixed to the screw portion 57 of the anchor 55 with a nut 60, and the link 10 of the reinforcing chain 5 is inserted into the hook-like locking groove 65 formed in the hook material 64. Engaged.

  FIG. 21 is a perspective view showing still another modified example of the structure for attaching the reinforcing chain 5 to the anchor 55. In this example, a piece 67 of a substantially L-shaped material 66 is fixed to the screw portion 57 of the anchor 55 with a nut 60, and a substantially cross-shaped groove 69 is formed in the other piece 68. Therefore, the link 10 of the reinforcing chain 5 can be engaged with the substantially cross-shaped groove 69 in the same manner as the bearing plate 26 of the first embodiment. Also in this modification, the reinforcing chain 5 can be attached directly to the anchor 55.

  FIG. 22 is a perspective view showing still another modified example of the structure for attaching the reinforcing chain 5 to the anchor 55. In this example, a piece 67 of a substantially L-shaped material 66 is fixed to the threaded portion 57 of the anchor 55 with a nut 60, and the link 10 of the reinforcing chain 5 is connected to a hook-like locking groove 65 formed on the other piece 68. Engaged. In FIG. 9A, the other piece 68 is arranged horizontally. However, as shown in FIG. 10B, the other piece 68 may be arranged vertically.

  FIG. 23 is a perspective view showing still another modified example of the structure for attaching the reinforcing chain 5 to the anchor 55. In this example, a nut 71 with a hook 70 is screwed into the threaded portion 57 of the anchor 55, and the link 10 of the reinforcing chain 5 is hooked and engaged with the hook 70.

  24 to 26 are schematic side views showing a third embodiment of the block stacking wall of the present invention, and a part thereof is shown in cross section. The concrete block 2 of the third embodiment and the block stacking wall using the same are basically the same as those of the second embodiment. Therefore, in the following, the description will be focused on the different parts, and corresponding portions will be described with the same reference numerals. 24 corresponds to the embodiment of FIG. 14, the embodiment of FIG. 25 corresponds to the embodiment of FIG. 15, and the embodiment of FIG. 26 corresponds to the embodiment of FIG.

  The third embodiment is different from the second embodiment in that the concrete block is the cognitive block 72. The knowledge block 72 is a conventionally known block, and a bolt 41 protrudes from the central portion of the back surface in the same manner as in the second embodiment. The horizontal chain 3 and the vertical chain 4 are provided on the bolt 41. And a chain net is provided on the back of the wall.

  In the case of the illustrated example, the lower end portion of the vertical chain 4 is connected to the metal fitting 73 of the concrete foundation 34, but the connection to the concrete foundation 34 may be omitted as in the second embodiment. Conversely, in the second embodiment, the lower end portion of the vertical chain 4 may be connected to the concrete foundation 34 as in the third embodiment.

  In the third embodiment, the construction is performed by the kneading method instead of the empty construction method as in each of the above examples. In other words, the interstitial block 72 is filled with the swollen concrete 74. However, there is no backfill concrete. In this embodiment, the wall is provided with drain holes 75 at desired intervals.

  The block stacking wall using the chain of the present invention and the concrete blocks 2 and 72 used therefor are not limited to the configurations of the embodiments described above, and can be changed as appropriate. In particular, in the block stacking wall, if the chain net composed of the horizontal chain 3 and the vertical chain 4 is provided on the back side of the wall, in addition to the shape, size and arrangement of the concrete blocks 2, each chain to the concrete block 2 The attachment positions and attachment methods of 3, 4, and 5 can be changed as appropriate.

It is a schematic front view which shows Example 1 of the block stacking retaining wall of this invention. It is a schematic rear view of the block stacking wall of Example 1, and is partially omitted. It is a schematic longitudinal cross-sectional view of the block stacking wall of Example 1 in a side view. It is the perspective view which showed the principal part of the block stacking retaining wall of Example 1, and was seen from the back side which abbreviate | omitted one part. In the block stacking wall of Example 1, it is a figure which shows the attachment state of the vertical chain lower end part to the concrete block of the lowest stage, (a) is a side view which made a part a cross section, (b) is seen from back It is the rear view, (c) The top view which made a part a cross section. It is the schematic which shows the back surface part of the rear surface material of the concrete block in Example 1, and shows the attachment state of a horizontal chain and a reinforcement chain to a concrete block, (a) is a side view, (b) is a top view Each is shown in cross section. It is explanatory drawing which shows the construction method of the block stacking wall of Example 1 in time series. It is a figure which shows the continuation of FIG. It is a figure which shows the continuation of FIG. It is a figure which shows the modification 1 of the attachment method of a horizontal chain and a reinforcement chain to the rear surface material of the concrete block of Example 1, (a) is a side view which made a part a cross section, (b) is a part It is the top view made into the cross section. It is a figure which shows the modification 2 of the attachment method of a horizontal chain and a reinforcement chain to the rear surface material of the concrete block of Example 1, (a) is a side view which made a part a cross section, (b) is a part It is the top view made into the cross section. It is a figure which shows the modification 3 of the attachment method of each chain to the concrete block of Example 1, (a) is the side view which made a part a cross section, (b) is the rear view which made a part the cross section. . It is a figure which shows the modification 4 of the attachment method of each chain to the concrete block of Example 1. FIG. It is a schematic side view which shows Example 2 of the block stacking wall of this invention, and has shown it by making a part into a cross section. It is a schematic side view which shows the modification 1 of the block stacking wall of Example 2, and has shown it by making a part into a cross section. It is a schematic side view which shows the modification 2 of the block stacking wall of Example 2, and has shown it by making a part into a cross section. It is a schematic perspective view which shows the connection state of the anchor and reinforcement chain in FIG. It is a figure which shows the modification of FIG. 17, (a) is a front view, (b) is XX sectional drawing. It is a figure which shows the modification of FIG. 18, (a) is a front view, (b) is YY sectional drawing, (c) is ZZ sectional drawing. It is a perspective view which shows another modification of the attachment structure of the reinforcement chain to an anchor. It is a perspective view which shows another modification of the attachment structure of the reinforcement chain to an anchor. It is a perspective view which shows another modification of the attachment structure of the reinforcement chain to an anchor. It is a perspective view which shows another modification of the attachment structure of the reinforcement chain to an anchor. It is a schematic side view which shows Example 3 of the block stacking retaining wall of this invention, and shows a part in cross section. It is a schematic side view which shows the modification 1 of the block stacking wall of Example 3, and has shown it by making a part into a cross section. It is a schematic side view which shows the modification 2 of the block stacking retaining wall of Example 3, and shows a part in cross section.

Explanation of symbols

1 Backfilling materials (such as crushed rocks)
2 Concrete block 3 Horizontal chain 4 Vertical chain 5 Reinforcement chain 11 Insertion part (metal ring)
12 Engaging part 34 Concrete foundation 35 Filling (filling material, filling layer)
54 Cut Land (Cut)
55 Anchor 58 Fixture 72 Interference block (concrete block)

Claims (7)

With multiple concrete blocks stacked on the left and right and top and bottom,
A horizontal chain that connects the left and right concrete blocks;
A block stacking wall using a chain comprising a vertical chain for connecting upper and lower concrete blocks. The concrete blocks are arranged in a staggered manner with a gap between adjacent left and right concrete blocks,
The vertical chain passed through the concrete blocks in the vertical direction is provided by being tensioned between the lowermost concrete block or the concrete foundation on which the lower concrete block is placed and the uppermost concrete block. A block stacking retaining wall using the chain according to claim 1. The block holding using the chain according to claim 1 or 2, further comprising a reinforcing chain having one end connected to the concrete block and the other end held on a bank or a cut land. wall. It is a leaning type retaining wall in which the concrete blocks are stacked so as to incline backward as it goes upward,
The block retaining wall using a chain according to claim 3, wherein the reinforcing chain is provided only on the uppermost stage or each concrete block of a plurality of stages. The chain according to claim 3 or 4, wherein each reinforcing chain from a plurality of concrete blocks arranged side by side is held by a common fixture fixed to the cut land with an anchor. Used block stacking wall. A concrete block that forms a block stacking wall by stacking left and right and up and down,
An insertion part through which a horizontal chain connecting the left and right concrete blocks is passed, or an engaging part to the link of this horizontal chain
The insertion part through which the vertical chain connecting the upper and lower concrete blocks is passed, or the engaging part to the link of this vertical chain,
A concrete block for a block stacking wall, which is provided individually or in common. The engaging part to the link of the reinforcing chain held on the embankment or cut land is provided individually or in common with the insertion part or the engaging part of the horizontal chain and / or the vertical chain. A concrete block for a block stacking wall according to claim 6.

Images