KR20210001477U - Drain block for a reinforcing drain wall of slope - Google Patents

Abstract

The present invention is installed in the form of a retaining wall from the rear side of the cut-off slope, which is cut off by a certain amount of the slope to make the opening surface flat, while constructing a reinforced drainage wall that collects the underground water or seepage water flowing out from the cut-off slope to the slope side. It relates to a drainage block manufactured in a hexahedral block shape for this purpose, and more specifically, the drainage block is composed of a hexahedral block body and a water collecting cover disposed on the front surface of the block body, but the front surface of the body of the block body ( Drain holes in the front and rear directions are formed through the entire surface at close intervals, and the water collection cover is a cover of a " ]" shape that covers the entire front surface of the block body, and soil and sand on the rear surface of the block body By attaching a filter sheet that blocks the inflow of water and allowing only underground water or permeated water to pass through, and by providing a drain port connected to the drain line at the bottom of the water collection cover of the drain block located at the lowermost side of the reinforcing drainage wall, the inside of the cut-off slope The groundwater or permeated water introduced into the tunnel is collected in the lower part of the reinforced drainage wall through the filter sheet, the block body, and the water collecting cover, and then is concentrated to the outside of the slope through the drain hole and the drain line provided in the water collecting cover at the location. On the other hand, the construction work of the reinforced drainage wall using the drainage block also relates to the drainage block for the inclined surface reinforced drainage wall so that it can be easily, quickly, and firmly performed only by the work by man who does not use a separate heavy equipment.

Description

Drain block for a reinforcing drain wall of slope

The present invention is installed in the form of a retaining wall along the cut slope from the rear side of the cut slope that has been cut off by a certain amount of the slope to make the opening surface flat, while the reinforcement drainage that collects the underground water or seepage water flowing out from the cut slope to the slope side It relates to a drainage block manufactured in a hexahedral block shape for the construction of a wall.

In general, when the slope of a mountain slope or hill is partially damaged due to a natural disaster such as heavy rain or flood, the damaged slope is cut off by a certain amount and a new slope is created by filling the area with soil, and roads or railways on the mountain slope or hill In case of new construction, etc., a certain amount of hillside or hill is cut off to make the surface flat, and then the remaining part is created as a new slope, and it is built near rivers or lakes to prevent overflow of rivers and use water resources. The embankment or embankment is also created with a slope due to the filling of the soil.

As described above, when an unstable slope in a filled or cut area created as a new topography by cutting or filling in the soil is left as bare ground, the slope is easily lost due to various natural causes such as heavy rain or flooding. In addition, in severe cases, there is a high risk of inducing enormous human and property damage due to the collapse of the slope in the state of bare ground, so by installing a separate protective and reinforcing structure on the slope, Risk factors such as falling rocks should be blocked in advance.

As a conventional slope protection and reinforcement method for stabilizing the slope as described above, a method of fixing a vegetation mat and a wire mesh on the slope using an anchor bolt, and then attaching a green soil composition with excellent viscosity through the wire mesh, and the slope angle of the slope A method is known for constructing a lattice structure frame with a front reinforcement grid and a floor reinforcement grid on the surface of an inclined surface by connecting horizontal frames at regular intervals along the bent frame bent in the shape of "∠" according to the figure.

In addition, a method of connecting various blocks made of plastic, concrete, or steel material in the shape of a square or hexagon on the surface of the inclined surface, and drilling a hole of a certain depth in the inclined surface using a perforator, and then sanding the hole A method of grouting by inserting a nail and mortar and a method of constructing a large concrete structure in the form of a retaining wall on the front side of a slope are additionally known.

Among the conventional slope protection and reinforcement methods as described above, the method using a vegetation mat and wire mesh has the advantage of achieving greening of the slope by promoting the growth of grass and woody plants. Compared to other methods, the protection strength of the slope was inferior, and in the case of the method in which blocks of various materials were connected on the surface of the slope, the protection strength of the slope could be slightly improved compared to the method using a vegetation mat and wire mesh. However, there was a disadvantage that early greening of slopes was difficult due to severe soil loss in rainy weather.

In addition, the grouting method or the concrete retaining wall method has the advantage of improving the protection and reinforcing strength of the slope to a very high level compared to the other methods described above. Not only is it not environmentally friendly because it is impossible to grow herbaceous and woody plants, but there are also disadvantages in that the initial cost for construction is excessive, and continuous maintenance must be performed in parallel after the construction of the structure.

On the other hand, in the case of the slope protection method using the lattice structure frame, the surface strength of the slope can be sufficiently secured by the front reinforcement grid and the floor reinforcement grid disposed on the front side of the slope, as well as the wall provided by the front reinforcement grid. It has the advantage that greening of the slope is also possible by attaching the vegetation soil by attaching the greening sheet to the structure. Japanese Patent Laid-Open Publication No. 4-213625 (1992. 8. 4) has the advantage that the slope reinforcement structure using the grid structure frame is used. . Published).

The lattice structure frame as described above forms the inclined surface reinforcement structure 20 together with the reinforcement drainage wall 11 and the drainage pipe 14 as drainage structures disposed over the rear side and the bottom side of the cut-out slope as in FIG. 1, and the The reinforcement drainage wall 11 is constructed in such a way that the drainage blocks 12 manufactured in the shape of a hexahedral block are sequentially buttted along the width and height directions of the cut-out slopes, and the grid structure frame 10 is a drainage pipe 14. It is to be connected and installed in a stacked manner along the height direction of the inclined surface at the tip side of the

The conventional drainage block 12 used for the construction of the reinforcement drainage wall 11 as described above is, as shown in FIGS. 2 and 3, aggregate in the inner space of the outer frame 15 having a hexahedral shape. Filling (17), it becomes an aggregate-type drainage block (12) provided with a metal cover network (16) to prevent the outflow of aggregate (17) over the six surfaces provided by the corresponding outer frame (15). The aggregate-type drainage block 12 of the underground that flows into the cut-out slope as the soil component introduced into the cover network 16 fills the void between the aggregate 17 after a certain period of time after the reinforcement of the slope has passed. There was a problem in that water or seepage water could not be smoothly discharged to the outside of the slope.

For this reason, if fine bones or cracks caused by underground water or infiltration water gradually progress and increase (expand) inside the cut slope, there is a very high risk of causing the collapse of the slope due to the weakening of the ground. , The reinforcement drainage wall 11 was first built by stacking a plurality of drainage blocks 12 on the rear side of the cut-out slope in the form of a retaining wall due to the structural characteristics of connecting the cover network 16 along the outer frame 15. Next, even if the lowermost drainage block 12 of the reinforcing drainage wall 11 is connected to a drainage line such as a drainage pipe 14, it is difficult to ensure reliable drainage of underground water or infiltration water.

In other words, in the case of the reinforcing drainage wall 11 constructed in the form of a retaining wall using the conventional aggregate-type drainage block 12, the underground water or infiltrated water gathers together through the drainage line connected to the lower end of it and cannot be discharged intensively. A significant portion of groundwater or infiltration water flows directly into the soil compaction layer through each aggregate-type drainage block 12 constituting the drainage wall 11 . By inducing fine bones or cracks, it will seriously adversely affect the safety after construction of the soil compaction layer including the lattice structure frame 10 .

In order to compensate for this problem to some extent, by attaching the filter sheet 13 to the front and rear cover nets 16 of the aggregate-type drainage block 12, the soil component from the cut-off slope is covered together with groundwater or infiltration water. By blocking the inflow between the voids of the aggregate 17 through the mesh 16, it is possible to maintain the voids between the aggregates 17 necessary for drainage work to the maximum, and together with each drainage block 12 As the front and rear surfaces of the reinforcing drainage wall 11 are covered with the filter sheet 13, it absorbs the underground water or infiltration water discharged from the cut-off slope and transfers it to the lower end of the reinforcing drainage wall 11 to which the drainage pipe 14 is connected. was made to be induced.

However, only the improvement of attaching the filter sheet 13 to the front and rear surfaces of the existing aggregate-type drainage block 12 is the soil compaction layer in front of the reinforcement drainage wall 11, with the groundwater or seepage water flowing into the cut-off slope. Since there is always a possibility that it will leak into the soil, underground water or seepage water does not flow out into the soil compaction layer, but collects the entire amount inside the lower end along the reinforced drainage wall 11, and then passes through the drainage pipe 14 connected to the location on the inclined surface. There was a problem that could not effectively achieve the ultimate purpose of allowing concentrated discharge to the outside of

In particular, since the conventional aggregate-type drainage block 12 has a very heavy weight, heavy equipment such as a large crane is required when installing the reinforcing drainage wall 11 using the drainage block 12 on the rear side of the cut-off slope. As it had to be additionally used, it became a factor to unnecessarily increase the construction cost, and when the aggregate-type drainage block 12 is made as small as possible to a level where the construction work of the reinforced drainage wall 11 by manpower is possible, the width of the cut slope The work of stably constructing the reinforced drainage wall 11 by accurately abutting the small-sized drainage blocks 12 in the front and rear and left, right, and up and down directions along the height and height direction was also very difficult and difficult.

The present invention has been devised to solve the conventional problems as described above, and the drainage block is composed of a block body in a hexahedral shape and a water collecting cover disposed on the front surface of the block body, but the front surface of the body of the block body ( Drain holes in the front and rear directions are penetrated at close intervals over the entire surface, and the water collecting cover is made to have a “ ]”-shaped cross-section that covers the entire front surface of the block body, and soil and sand on the rear surface of the block body By attaching a filter sheet that blocks the inflow of water and allowing only underground water or permeated water to pass through, and by providing a drain port connected to the drain line at the bottom of the water collecting cover of the drain block located at the lowest side of the reinforcing drainage wall, the inside of the cut-off slope The groundwater or permeated water introduced into the tunnel is collected in the lower part of the reinforced drainage wall through the filter sheet, the block body, and the water collecting cover, and then concentrated to the outside of the slope through the drain hole and the drainage line provided in the water collecting cover at the location. On the other hand, the main technical task of the construction work of the reinforcement drainage wall using the drainage block is to make it easy, fast, and robust only by the manpower who does not use a separate heavy equipment.

The present invention as a means to solve the above technical problem is installed in the form of a retaining wall at the rear side of the cut slope that has been flattened by cutting the slope by a certain amount, while the groundwater or infiltration flowing out from the cut slope to the slope side In the drainage block manufactured in the shape of a hexahedral block for the construction of a reinforcement drainage wall to collect water, the drainage block includes a hexahedral block body, a water collection cover disposed on the front side of the block body, and the block body It is made to include a filter sheet attached to and installed on the rear surface of the block body, and drain holes penetrating the body in the front and rear directions are formed at tight intervals over the front of the body, while the water collecting cover is the block body At the left and right ends of a square plate having the same area as the front surface of Alternatively, it is characterized in that a drain port connected to the drain channel is provided.

In addition, an assembly groove and an assembly protrusion for stacking the block body are respectively formed on the upper and lower surfaces of the block body, and the drain hole of the block body is inclined downward by a predetermined angle toward the front side. At least one partition plate having the same shape as the side plate is formed in the center of the rear surface of the water collection cover, and the drain hole is installed in at least one number for each space partitioned by the partition plate Characterized in that, the bottom plate connecting the left and right side plates is installed at the lower end of the water collection cover of the drainage block located at the lowermost side of the reinforcing drainage wall, and the water collection cover of the drainage block located at the uppermost side of the reinforced drainage wall It is characterized in that a cover plate connecting the left and right side plates is installed on the upper side.

According to the present invention as described above, the drainage block for the construction of the reinforcing drainage wall is composed of a hexahedral block body and a water collecting cover disposed on the front surface of the block body, but over the entire body of the block body, The drainage holes in the rear direction are penetrated at close intervals, and the water collection cover is made to have a “ ]”-shaped cross-section that covers the entire front surface of the block body, and blocks the inflow of soil to the rear surface of the block body. By attaching a filter sheet that allows only water or permeated water to pass through, and providing a drain connected to the drain line at the lower end of the water collection cover located at the lowermost side of the reinforcing drainage wall, the underground water or permeated water introduced into the cut-off slope is filtered It provides the effect that the entire amount of water is collected to the lower side of the reinforced drainage wall through the seat, block body and water collecting cover, and then concentrated to the outside of the slope through the drain hole and drain line provided in the water collecting cover at the location.

Through this, the risk of collapse of the slope due to the weakening of the ground is prevented more reliably by blocking in advance the progress and increase (expansion) of fine bones or cracks caused by underground water or seepage water in the cut slope or the inside of the soil compaction layer. In the case of the block body and the water collection cover, it is possible to manufacture by injection molding using plastic materials, and even if the drainage block itself is enlarged to a relatively large size, the overall weight of the drainage block is aggregate-type drainage As it can be made much lighter than the block, the construction of the reinforced drainage wall using the drainage block can also be quickly and easily performed without the use of additional heavy equipment and only by manpower. It is to provide very useful effects, such as being able to perform the construction work of the reinforcing drainage wall in a prefabricated manner more accurately and firmly by using the assembly grooves and assembly projections provided on the upper and lower surfaces.

1 is an external perspective view showing an inclined surface reinforcement structure including a grid frame;
Figure 2 is a partial exploded perspective view showing a conventional drainage block used for the reinforcement drainage wall of Figure 1;
Figure 3 is an external perspective view of the coupled state of Figure 2;
Figure 4 is an exterior perspective view showing the installation state of the reinforcement drainage wall using the drainage block according to the present invention.
5 is a structural diagram of a drainage block according to the present invention.
Figure 6 is a bottom perspective view of the block body shown in Figure 5;
7 (A) and (B) are side cross-sectional views of the drain block according to the present invention.
8 is an external perspective view showing another embodiment of a drainage line used together with a reinforced drainage wall.
9 is an external perspective view showing another embodiment of a drainage line used together with a reinforced drainage wall.
10 to 19 are construction explanatory views sequentially showing the construction process of the inclined surface reinforcement structure using the drainage block according to the present invention.
Fig. 20 is a side cross-sectional view of Fig. 19;

Hereinafter, the present invention for achieving the above object will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 4 to 6, the drainage block 12 for the inclined surface reinforcement drainage wall 11 according to the present invention has a hexahedral block body 18 and the front side of the block body 18. It consists of a water collecting cover 19 disposed, and in the block body 18, drain holes 18a penetrating the body in the front and rear directions are formed at close intervals over the entire surface of the body, while the The water collecting cover 19 is a cover having a " ]" shape cross-section in which the side plates 19b protrude rearwardly on the left and right ends of a square plate having the same area as the front surface of the block body 18 .

Therefore, when the water collection cover 19 is installed facing the front surface of the block body 18, the front surface of the block body 18 and the rear surface of the water collection cover 19 are provided with a predetermined margin by the side plate 19b. By being spaced apart at a distance, the corresponding clearance provides a vertical drainage passage, and the filter sheet 13 is attached to the rear surface of the block body 18 constituting the drainage block 12 and installed, and the drainage block A drain hole (19a) connected to the drain pipe (14) is provided on the lower side of the collecting cover (19) of the drain block (12) located at the lowermost side of the reinforced drain wall (11) constructed by (12).

The drain hole 18a formed in the block body 18 provides a horizontal (front, rear) direction drainage passage connected with the vertical drain passage described above, and the front surface of the body of the block body 18 and about 70 to 80% of the total area of the rear surface form the drain hole 18a, and the remaining portion forms the edge portion of the block body 18 and the support rib 18b of the drain hole 18a desirable.

Although each drain hole 18a is formed as a square hole in the drawing, it may be formed as a hole of various shapes such as a circular hole or a polygonal hole, and the drainage block 12 is used to reinforce the drainage wall 11 In order to secure all of the speed, convenience and accuracy of the construction work, it is preferable to form the assembly groove portion 12a and the assembly projection portion 12b respectively on the upper surface and the lower surface of the block body 18 to correspond to each other.

If necessary, a side assembly structure between the block body 18, such as the assembly groove 12a and the assembly protrusion 12b, can be provided on the left side and the right side of the block body 18 as well, and the block body An assembly groove or an assembly step in which the side plate 19b of the water collection cover 19 is fitted in the left and right edges of the front surface of (18) may be formed, and the filter sheet 13 is formed using an adhesive. to be attached to the rear surface of the block body 18, and after forming fastening holes (not shown) at regular intervals on the edge portion provided along the rear surface edge of the block body 18, the filter sheet ( 13) can be attached on the block body 18 by screwing.

In addition, at least one partition plate 19c having the same shape as the side plate 19b may be additionally formed in the center of the rear surface of the water collection cover 19, and the partition plate 19c is In addition to providing the function of further subdividing the drainage passage in the vertical direction provided by the cover 19, the soil is filled and compacted toward the front side of the reinforced drainage wall 11 constructed using the drainage block 12. In the process, the function of reinforcing meat to prevent the water collecting cover 19 from protruding from the block body 18 side by the compaction force of the soil and soil is paralleled, and in consideration of this, the number of installations of the partition plate 19c is at least 1 It is desirable not to exceed a maximum of three in dogs.

When the partition plate 19c is installed in the center of the water collection cover 19 as described above, the drain hole 19a disposed on the lowermost side of the reinforcing drainage wall 11 is the partition plate 19c of the water collection cover 19. At least one drain hole will be installed for each vertical drain passage partitioned by the . However, in consideration of the total number of drain pipes 14 installed, one drain hole for each vertical drain passage provided by the partition plate 19c. It is most economical to install (19a), and in some cases, the upper end of the drainage block 12 constituting the first layer (lowest layer) of the reinforcing drainage wall 11 or the drainage block 12 constituting the second layer. By additionally connecting the drain pipe 14 to the lower end, the drain pipe 14 may supplement the function of the lowermost drain pipe 14 .

7 (A) and (B) show another application example of the drainage block 12 disposed on the lowermost and uppermost sides of the reinforced drainage wall 11, respectively. The bottom plate 19d connecting the left and right side plates 19b is installed on the lower side of the water collection cover 19 of the drainage block 12 located at the lowermost side, and located on the uppermost side of the reinforcing drainage wall 11 By installing a cover plate 19e connecting the left and right side plates 19b on the upper side of the water collecting cover 19 of the drain block 12, the water collecting cover 19 provides the vertical direction of the drainage passage floor. It is desirable to prevent infiltration of water from leaking and to prevent soil from flowing into the upper end of the drain passage.

In addition, each drain hole (18a) is formed to be inclined downward by a predetermined angle, for example, an angle of about 10 degrees from the rear side of the block body 18 toward the front side, thereby discharging underground water or infiltration water. It is preferable to perform more reliably than this, and as shown in FIG. 7(A), the lower surface of the block body 18 of the drainage block 12 disposed on the lowermost side of the reinforcement drainage wall 11 has an assembly protrusion ( 12b) is not formed, but if the assembly protrusion 12b is embedded through the bottom surface of the cut-off surface, it does not interfere with the construction of the reinforcement drainage wall 11 at all, so the application of the block body 18 It is preferable to manufacture and use only one type of block body 18 in which both the assembly groove part 12a and the assembly protrusion part 12b are formed so as not to cause confusion.

8 and 9 show another embodiment of a drainage line applicable to the inclined surface reinforcement structure 20 together with the reinforcement drainage wall 11 using the drainage block 12 of the present invention, shown in FIG. What has been done is that a drain channel 14a having a “U” cross section is installed instead of the pipe-type drain pipe 14, and the one shown in FIG. 9 is that the drain channel 14a is additionally connected across the width direction of the inclined surface. For this purpose, the drain line shown in FIG. 9 becomes the prefabricated channel 21 between the straight channel 21a, the cross channel 21b and the tee-shaped channel 21c, and the pipe-type drain pipe 14 described above. It goes without saying that even in this case, it can be installed as a drainage line of the structure shown in FIG. 9 using a straight pipe, a cross-shaped connecting pipe, and a tee-shaped connecting pipe.

The process of constructing the inclined surface reinforcement structure 20 including the grid structure frame 10 using the drainage block 12 of the present invention having the configuration as described above is briefly described with reference to FIGS. 10 to 20 as follows. same.

First, for the restoration work of the damaged slope or the opening work of a road or railroad, the slope is cut by a certain amount to first create a flattened cut slope, and then, as shown in FIG. From the rear side, the drainage block 12 of the present invention along the width and height directions of the cut-out slope 22 is faced up, down, left, and right directions to construct the reinforcement drainage wall 11, but each drainage block 12 ) with the filter sheet 13 attached to the rear surface of the block body 18 constituting the block body 18, each block using the assembly grooves 12a and assembly protrusions 12b of the upper and lower surfaces of the block body 18 The body 18 and the front water collecting cover 19 are installed while facing each other in a stacked manner.

Although it is shown in the drawing that the reinforcement drainage wall 11 having two layers is built at a time by using each drainage block 12, it is also possible to sequentially build the reinforcement drainage wall 11 one layer at a time. It is possible, and as shown in FIG. 11, along the front side open surface of the cut-out slope 22 on which the reinforcement drainage wall 11 is built in this way, a reinforcement sheet 23 such as a geogrid is laid as shown in FIG. 12, and then reinforced as in FIG. The drain pipe 14 is connected to each drain hole 19a of the drain block 12 located at the lowermost side of the drain wall 11 so that the drain pipe 14 is placed on the upper surface of the reinforcing sheet 23, while each The tip outlet side of the drain pipe 14 is positioned inside the main drain pipe 24 pre-constructed on the front side of the slope.

As shown in FIG. 13 in the above state, by pouring and hardening the foundation concrete 25 on the upper surface of the reinforcement sheet 23 so that each drain pipe 14 is embedded, it is used for compaction construction of soil. To provide a necessary foundation, and when a drainage channel 14a is installed in place of the drainage pipe 14, before pouring the foundation concrete 25, cover the upper surface of each drainage channel 14a with a cover, etc. 14a) so that the concrete does not flow into the interior, and after the foundation concrete 25 is finally hardened, as in FIGS. 14 and 15 , the reinforcement sheet 23 is additionally covered on the upper surface of the foundation concrete 25 and then , so that the grid structure frame 10 is placed on the tip side of the reinforcing sheet 23, and if necessary, the grid structure frame 10 is mounted on the foundation concrete 25 together with the reinforcing sheet 23 using an anchor bolt or the like. It can also be made to be firmly fixed.

In the state in which the reinforcement sheet 23 and the grid structure frame 10 are arranged on the upper surface and the tip side of the foundation concrete 25 in the same manner as described above, as in FIGS. 16 and 17, the grid structure frame 10 is By filling and compacting the soil between the rear surface and the front surface of the reinforcement drainage wall 11, the soil compaction layer 26 corresponding to the first floor height of the reinforcement drainage wall 11 is constructed, and then the soil compaction layer The upper surface of the reinforcing sheet 23 is additionally covered, and the front upper portion of the grid structure 10 is exposed to the outside by a certain length through the upper surface of the soil compaction layer 26, It is to be used for connection with another grid structure frame 10 to be located on the upper part.

In the above state, as shown in FIG. 18, another grid structure frame 10 is disposed on the upper surface of the tip side of the soil compaction layer 26, and each grid structure frame 10 is connected and installed in a stacked manner. , it is preferable to firmly fix the grid structure frame 10 input in this step on the soil compaction layer 26 using anchors or piles that are driven into the soil compaction layer 26 through the reinforcement sheet 23 .

As in FIGS. 19 and 20 in the above state, by filling and compacting soil between the rear surface of the grid structure frame 10 and the front surface of the reinforcement drainage wall 11, 2 of the reinforcement drainage wall 11 The soil compaction layer 26 corresponding to the layer height is additionally constructed, and by sequentially passing through this series of processes, the slope reinforcement structure 20 including the grid structure 10 and the reinforcement drainage wall 11 is installed. It can be constructed according to the height of the slope, and after the reinforcement construction of the slope is completed, the greening of the slope is finally induced by attaching the greening sheet on the front wall structure of the lattice structure frame 10 and attaching the vegetation soil. .

When the reinforced drainage wall 11 using the drainage block 12 of the present invention is built on an inclined surface through a series of construction processes as described above, the groundwater or permeated water introduced into the cut-off slope 22 is filtered through the filter sheet ( 13) and the block body 18 and the water collecting cover 19, the entire amount of water is collected toward the lower end of the reinforced drainage wall 11, and then through the drain 19a and the drainage line provided in the water collecting cover 19 at the corresponding position, the inclined surface By blocking in advance the progress and increase (expansion) of fine bones or cracks caused by underground water or infiltration water in the cut slope 22 or the soil compaction layer 26 through this, , it is possible to more reliably prevent the risk of collapse of the slope due to the weakening of the ground.

In particular, in the case of the block body 18 and the water collecting cover 19, it is possible to manufacture by injection molding using a plastic material, and even if the drain block 12 itself is enlarged to a relatively large size, the As the overall weight can be significantly reduced compared to the aggregate-type drainage block, the construction of the reinforced drainage wall 11 using the drainage block 12 is also quickly performed by manpower without using additional heavy equipment. and at the same time can be easily performed, the construction work of the reinforcing drainage wall 11 is further prefabricated by using the assembly grooves 12a and the assembly protrusions 12b provided on the upper and lower surfaces of the block body 18. It can be done accurately and reliably.

The contents described above on the basis of FIGS. 10 to 20 are only one representative example of constructing the inclined surface reinforcement structure 20 using the drainage block 12 according to the present invention, and the foundation concrete 25 and the main The application of the drainage channel 24 and the application position of the reinforcement sheet 23 can be arbitrarily adjusted and changed according to the construction conditions, and the drainage block 12 and the reinforcement drainage wall 11 using the same are the grid structure frame. Regardless of (10), it can be used alone for the reinforcement construction of the inclined surface, and even in the case of the filter sheet 13, it is not separately installed for each drainage block 12, but is cut out like the reinforcement sheet 23 It clarifies that it can be installed as one large sheet covering the width and height directions of the slopes 22 .

10: lattice structure frame 11: reinforcement drainage wall 12: drainage block
12a: assembly groove 12b: assembly protrusion 13: filter sheet
14: drain pipe 14a: drain channel 15: outer frame
16: cover network 17: aggregate 18: block body
18a: drain hole 18b: support meat 19: water collecting cover
19a: drain hole 19b: side plate 19c: partition plate
19d: bottom plate 19e: cover plate 20: reinforcing structure
21: prefabricated channel 21a: straight channel 21b: cross channel
21c: Tee-shaped channel 22: Cut-off side 23: Reinforcement sheet
24: main drainage channel 25: concrete foundation 26: soil compaction layer

Claims (4)

Reinforced drainage wall that is installed in the form of a retaining wall from the rear side of the cut-off slope 22 that cuts the slope by a certain amount to flatten the open surface, and collects the underground water or infiltration water flowing out from the cut-off slope 22 to the slope side. In the drainage block 12 produced in a hexahedral block shape for the construction of (11),
The drain block 12 includes a hexahedral block body 18 , a water collecting cover 19 disposed on the front side of the block body 18 , and a filter attached to the rear surface of the block body 18 . Consists of including the sheet (13),
In the block body 18, drain holes 18a penetrating the body in the front and rear directions are formed at tight intervals over the entire surface of the body, while the water collecting cover 19 is formed in the block body 18. The side plate 19b is formed to protrude rearward at the left and right ends of the square plate having the same area as the front surface of the "]" shaped cross-section cover,
A drain hole (19a) connected to a drain pipe (14) or a drain channel (14b) is provided at the lower end of the water collecting cover (19) of the drain block (12) located at the lowermost side of the reinforcing drain wall (11) Drainage block for slope reinforcement drainage wall. The block body (18) according to claim 1, wherein an assembly groove (12a) and an assembly protrusion (12b) for stacking the block body (18) are respectively formed on the upper and lower surfaces of the block body (18). The drain hole (18a) of the body (18) is inclined downward by a predetermined angle toward the front side. According to claim 1 or 2, at least one partition plate (19c) having the same shape as the side plate (19b) is formed in the center of the rear surface of the water collecting cover (19), the drain hole (19a) A drainage block for an inclined surface reinforcement drainage wall, characterized in that at least one or more is installed in each space partitioned by the partition plate (19c). According to claim 1 or 2, wherein the bottom plate connecting the left and right side plates (19b) on the lower side of the water collecting cover (19) of the drain block (12) located at the lowermost side of the reinforcing drain wall (11) ( 19d) is installed, and a cover plate 19e connecting the left and right side plates 19b is installed on the upper side of the water collection cover 19 of the drainage block 12 located at the uppermost side of the reinforcing drainage wall 11. Drainage block for slope reinforcement drainage wall, characterized in that it becomes.

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