KR20120102442A - A buffing block that is possible a design, and a breast wall using it, and constructing method of the breast wall - Google Patents

Abstract

PURPOSE: A shock absorbing block with a design, a retaining wall using the same, and a construction method thereof are provided to reduce construction time by manufacturing the blocks in a plant and assembling the blocks in a construction site. CONSTITUTION: A shock absorbing block with a design comprises a front plate(100), a shock absorbing member(200), second connection members(300), connectors(400), and a block(500). The front plate is composed of a body and first connection members. The shock absorbing member is composed of cells, first couplers, and second couplers. The first and second couplers are installed between the cells. The second connection members have first through holes(310). One ends of the connectors are coupled to the second couplers of the shock absorbing member through the first through holes of the second connection members, and the other ends are installed on the rear surfaces of the second connection members and fix one ends of the second connection members to the rear surface of the shock absorbing member. The block has coupling grooves in which the second connection members are coupled.

Description

Buffering block that is possible a design, and a breast wall using it, and constructing method of the breast wall}

The present invention relates to a buffer block using a designable front plate and a shock absorbing member capable of absorbing shock, a retaining wall having a beautiful appearance using the same, and a construction method thereof.

In general, the retaining wall refers to a wall made so that the soil of the land or incision surface does not collapse or flow due to soil pressure. In this case, the structure is constructed to prevent ground collapse.

Such a conventional retaining wall uses reinforced concrete on a fill surface or a cut surface, which causes a problem in that the construction process is very complicated and the construction period is consumed a lot, resulting in enormous construction costs.

In order to solve such a conventional problem, a retaining wall construction technique has recently been proposed in which a plurality of retaining wall blocks are stacked along a fill surface or an incision surface and constructed by filling rubble or the like on the back surface thereof. However, the conventional retaining wall block as described above was made of concrete, etc., the appearance was not beautiful. In order to solve such a problem, a decorative block is used, but the adhesion between the decoration and the block is weak and there is a problem that the decorations attached to the retaining wall easily fall off.

In addition, if a block is damaged by an external impact, there are many inconveniences such as disassembling and retaining the retaining wall block to repair it. There is a problem such as wearing.

An object of the present invention created to solve the above problems is to provide a shock-absorbing block that combines the shock absorbing member and the front plate in the block manufactured at the factory to resist the impact of the external load and to beautifully aesthetics of the retaining wall. In addition, the front plate is easily removable to the shock absorbing member to change the appearance or can be easily replaced when broken provides a buffer block that reduces the maintenance, maintenance costs. It is to provide a retaining wall that can reduce the construction air and the construction cost by constructing the retaining wall in a way that the blocks are arranged horizontally and vertically stacked.

In order to achieve the above object, the present invention is provided between the front plate made of the body and the first connection member protruding from the rear of the body, between the cell and the cell or the outer surface and the cell of various shapes that are generated by the cell wall is crossed A buffer member comprising a first coupling member having a locking groove on one side of the upper surface and a second coupling member inserted into and installed between the cell or the outer surface and the cell on one side of the upper surface, and the first and rear surfaces penetrating the front and rear sides. The second connecting member having a through hole, one end of which penetrates through the first through hole of the second connecting member, is coupled to the second coupling member of the shock absorbing member, and the other end is fixed to the back of the second connecting member. It consists of a block having a coupling groove on the front side of the head so that the connecting member and the second connecting member is coupled to one end of the second connecting member, the end of the first connecting member is the locking groove of the first coupling member Coupled front plate is fixed to the cushioning member, there is provided a buffer block design is possible that the second connecting member is connected to the buffer member being coupled to the coupling groove of the block.

In another aspect, the present invention is a retaining wall formed by stacking blocks, the base is installed on the ground, the front plate consisting of the body and the first connection member protruding from the rear of the body, between the cell and the cell having a variety of shapes formed by crossing the cell wall Alternatively, the buffer member is formed between the outer surface and the cell, and includes a first coupling member having a locking groove on one side of the upper surface and a second coupling member inserted between the cell or between the outer surface and the cell on one side of the rear surface, and on one side of the front / rear side. A second connection member having a first through hole formed through the front / rear surface, one end of which passes through the first through hole of the second connection member, is coupled to the second coupling member of the buffer member, and the other end of the second connection member is formed on the rear surface of the second connection member; The connecting member for fixing one end of the second connecting member to the rear of the buffer member in a manner to be fixed to, the head consisting of a trapezoidal shape with a coupling groove on the front and one end is connected to the end of the head The body and one end of the 'Y' shape is made of a lower portion connected to the other end of the body, the upper / lower side of the head is formed through the upper / lower surface of the second through-hole and the body of which becomes smaller toward the lower surface It consists of a block having a third through-hole formed on one side of the upper surface and the lower surface through the upper and lower surfaces, and a block having a protruding material protruding from one side of the upper surface of the lower portion, and a fill material deposited on the back side of the block. Arranged and stacked vertically, the second connecting member connected to the buffer member is coupled to the coupling grooves of the respective blocks stacked and stacked, and the first connecting member of the front plate is coupled to the respective buffer members. It provides a retaining wall using a buffer block that can be designed.

The present invention having the above configuration has the following effects.

First, the construction period can be shortened by manufacturing and installing blocks at the factory. In addition, the quality of the retaining wall is consistent and excellent because it is produced uniformly in the factory.

Second, the aesthetics are beautiful due to the installation of the designable front panel, and the front panel is easy to attach and detach.

Third, due to the use of the shock absorbing member is easy to absorb the shock to the external load, less damage to the block, economical, less damage to the vehicle, such as external impact is stable.

Fourth, as the retaining wall can be made by simply assembling the block in the field, the construction cost can be saved.

1 is an exploded perspective view of a buffer block according to the present invention.
Figure 2 shows a perspective view of the front plate according to the present invention.
Figure 3 shows an embodiment of a perspective view of the buffer member according to the present invention.
4 shows a front view of FIG.
FIG. 5 shows a rear view of FIG. 3.
Figure 6 shows a second embodiment of a perspective view of a buffer member according to the present invention.
7 shows a perspective view of a block according to the invention.
8 is a view illustrating a coupling of the buffer member and the second connection member according to the present invention.
Figure 9 shows a side view of the shock absorbing member and the second connecting member according to the present invention.
Figure 10 shows a front view of the retaining wall constructed using the buffer block according to the present invention.
Figure 11 shows a side view of a retaining wall constructed using a buffer block according to the present invention.
12 is a view showing a construction method of a retaining wall according to the present invention.
13 is a cross-sectional view of the fixing material and the reinforcement in the retaining wall according to the present invention.
14 is a plan view of the fixing material and the reinforcement in the retaining wall according to the present invention.
15 is a view showing one embodiment of a retaining wall according to the present invention.
Fig. 16 is a view showing a second embodiment of the retaining wall according to the present invention.
Fig. 17 is a view showing a third embodiment of the retaining wall according to the present invention.
18 shows a fourth embodiment of the retaining wall according to the present invention.
Fig. 19 shows a fifth embodiment of the retaining wall according to the present invention.
20 shows a sixth embodiment of the retaining wall according to the present invention.

Hereinafter, a detailed description of a buffer block, a retaining wall using the same, and a construction method thereof, which can be designed according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows an exploded perspective view of the buffer block according to the present invention, Figure 2 shows a perspective view of the front plate according to the present invention. Figure 3 shows an embodiment of a perspective view of the buffer member according to the present invention, Figure 4 shows a front view of FIG. FIG. 5 shows a rear view of FIG. 3, and FIG. 6 shows a second embodiment of a perspective view of a cushioning member according to the invention. Figure 7 shows a perspective view of a block according to the present invention, Figure 8 shows a view in which the buffer member and the second connection member according to the present invention is combined. Figure 9 shows a side view of the shock absorbing member and the second connecting member according to the present invention.

The present invention relates to a buffer block 10 that can be used in the retaining wall design, and in detail, the front plate 100 consisting of the body 110 and the first connection member 120 protruding from the rear of the body 110. In order to be installed between the cell 210 and the cell 210 having various shapes formed by the cell wall 211 intersecting, or between the outer surface 220 and the cell 210, the locking groove 231 is provided on one side of the upper surface. 1 buffer member 200 and the buffer member 200 made of a second binder 240 is inserted between the cell 210 or between the outer surface 220 and the cell 210 is installed on one side of the back, one side of the front / rear Second connection member 300 having a first through hole 310 is formed through the front / rear, one end penetrates through the first through hole 310 of the second connection member 300 buffer member 200 It is coupled to the second coupling member 240 and the other end is fixed to the rear of the second connecting member 300 so that one end of the second connecting member 300 is fixed to the back of the buffer member 200 The coupling member 400 and the second connecting member 300 is composed of a block 500 having a coupling groove 511 on one side of the front surface of the head 510, the end of the first connecting member 120 is the first Coupled to the engaging groove 231 of the binder 230, the front plate 100 is fixed to the shock absorbing member 200, the second connecting member 300 to which the shock absorbing member 200 is connected is a coupling groove of the block 500 It is characterized in that coupled to (511).

The front plate 100 is composed of a body 110 and the first connecting member 120. The outer shape of the body 110 is possible in a variety of shapes to enable the design of the retaining wall 20, but preferably has a rectangular shape. The outer surface of the body 110 may be convexly embossed or concavely engraved according to the shape of the design. Alternatively, the outer surface of the body 110 may be used by mixing the embossed and intaglio according to the planned design. The outer surface of the body 110 may be manufactured by adding color to the shape in accordance with the sketch of the design. The first connection member 120 is formed by protruding from one side of the inner surface of the body 110 is coupled to the shock absorbing member 200 described later can be protruded from the inner surface of the body 110 in various forms One preferably protrudes in the shape of a long rod.

The first connection member 120 has a hook ring 121 formed at an end thereof, such that the first connection member 120 is fitted into the locking groove 231 of the buffer member 200 to the front of the buffer member 200. It is fixed. Since the front plate 100 is made to be detachable to the outer surface of the shock absorbing member 200, the front plate 100 can be replaced at any time according to a place, a terrain, or a feature. That is, when there is damage to the front panel 100 or want to replace the design, only the front panel 110 is removed by replacing it. The front plate 100 is made of a variety of materials, such as wood, plastic, steel.

The buffer member 200 includes a cell 210, a first binder 230, and a second binder 240. The cell 210 is formed in various shapes by intersecting the cell walls 211, and is mainly formed in the form of a triangle or a quadrangle. Since the shock absorbing member 200 is formed of a combination of cell 210 shapes, the shock absorbing member 200 may not only easily absorb the impact applied to the shock absorber but also less impact on the impacting object, and may not be easily deformed by distortion due to climate change. Since the buffer hole 212 is formed at one side of the cell wall 211 of the buffer member 200, the shock applied to the buffer member 200 may be more safely absorbed. In addition, by combining LEDs, light bulbs, etc. in the cell can be used as signs, billboards, etc., the front plate 100 is coupled to the buffer member 200 combined with the LED, light bulbs, etc. in the cell can make a more aesthetic retaining wall.

The first coupling member 230 is installed between the cells 210 or between the outer surface 220 and the cells 210 and has a locking groove 231 on one side of the upper surface. The locking groove 231 of the first coupling member 230 is where the first connection member 120 of the front plate 100 is fitted. As the front plate 100 is coupled to the buffer member 200 according to the planned design, the retaining wall 20 becomes beautiful. That is, the shape of the various forms are formed in the body 110 of the front plate 100 and retaining wall 20 due to coupling the front plate 100 to the locking groove 231 of the buffer member 200 according to the planned design Various pictures can be shaped on the surface of the.

The second binder 240 is inserted into and installed between the cell 210 or between the outer surface 220 and the cell 210 on one side of the rear surface of the buffer member 200. The second coupling member 240 is coupled to the connecting member 400 described later to allow the second connecting member 300 to be coupled to the rear surface of the buffer member 200. The second binder 240 may be any material as long as it satisfies the strength required for the coupling member 400, but preferably uses a nut. The buffer member 200 is manufactured by using various materials such as wood, plastic, and steel.

The second connection member 300 has a first through-hole 310 generated by passing through the front / rear surface on one side of the front / rear side. The second connection member 300 is shaped in various forms depending on the shape of the coupling groove 511 of the block 500 described later, but preferably has a 'T' shape. A narrow portion of the second connection member 300 is coupled to the rear surface of the buffer member 200. The first through hole 310 is a passage through which the connecting member 400 to be described later penetrates and is coupled to the rear surface of the buffer member 200, and is formed through one side surface of the second connecting member 300. A fixing groove 320 is formed at the other end of the second connection member 300 to fix the other end of the connection member 400. That is, the fixing groove 320 is formed at the end of the first through hole 310. The second connection member 300 is produced by using a variety of materials such as wood, plastic, steel.

One end of the connecting member 400 penetrates through the first through hole 310 of the second connecting member 300 to be coupled to the second coupling member 240 of the buffer member 200, and the other end of the second connecting member 300 is closed. One end of the second connection member 300 is fixed to the rear surface of the buffer member 200 by the method of being fixed to the rear surface. By the connecting member 400, the second connecting member 300 may be structurally secured to the rear surface of the buffer member 200. The connecting member 400 may be any material as long as it is a material capable of coupling the second connecting member 300 to the shock absorbing member 200, but preferably a bolt is used.

The block 500 consists of a head 510, a body 520, and a bottom 530. Head 510 is made of a trapezoidal shape with a thickness, there is a coupling groove 511 on the front is coupled to the second connecting member 300. The coupling groove 511 may have various shapes depending on the coupling shape of the second connection member 300, but is preferably formed in an inverted 'T' shape to be structurally coupled to the second connection member 300. . The body 520 is formed of a 'Y' shape, one end of which is connected to the end of the head 510, the lower portion 530 is connected to the other end of the body 520.

The second through hole 540 is formed through the top / bottom side of the top / bottom side of the head 510, but the diameter decreases toward the bottom. That is, when the blocks 500 are stacked in a zigzag, the protruding material 560 may be coupled to the lower surface of the block 500.

The third through hole 550 penetrates the upper surface / lower surface on one side of the upper surface / lower surface of the body 520. The protrusion 560 protrudes from one side of the upper surface of the head 510 and the lower portion. The protrusion 560 of the head 510 may be coupled to the end of the second through hole 540 when the block 500 is stacked in a zigzag to increase resistance to horizontal stress. In addition, the protruding material 560 protrudes on the upper surface so that the blocks 500 do not directly collide with each other when the blocks 500 are stacked, so that damage does not occur during movement. In addition, the fixing hole 570 is formed on one side of the upper surface of the body 520 is coupled to one end of the fixing member 800 described later. The block 500 may be made of any material as long as it satisfies the required strength, but is preferably manufactured using concrete.

Figure 10 shows a front view of the retaining wall constructed using the buffer block according to the present invention, Figure 11 shows a side view of the retaining wall constructed using the buffer block according to the present invention.

The present invention relates to a retaining wall (20) completed using a buffer block (10), which can be designed. Specifically, in a retaining wall formed by stacking blocks, a base (600) and a body installed on the ground (1) Between the cell 210 and the cell 210 having various shapes formed by the front plate 100 and the cell wall 211 formed of the first connection member 120 protruding from the rear of the body 110 and 110. Alternatively, the outer surface 220 and the cell 210 are installed between the first coupling member 230 having the locking groove 231 on one side of the upper surface and the one side of the cell 210 or the outer surface 220 and the cell ( A second connection member having a buffer member 200 formed of a second coupling member 240 inserted into and installed between 210 and a first through hole 310 formed through the front / rear surface on one side of the front / rear side ( 300, one end penetrates through the first through hole 310 of the second connection member 300 and is coupled to the second coupling member 240 of the buffer member 200, and the other end is connected to the rear surface of the second connection member 300.The connection member 400 for fixing one end of the second connection member 300 to the back of the shock absorbing member 200 in a manner to be attached, the head 510 and one end of the trapezoidal shape having a coupling groove 511 on the front Body 520 made of a 'Y' shape connected to the end of the head 510 and one end is made of a lower portion 530 connected to the other end of the body 520, the top / bottom of the head 510, the upper surface / The third through hole 550 and the head which is formed through the lower surface through the upper surface / lower surface on the upper surface / lower surface of the second through hole 540 and the body 520 is smaller in diameter toward the lower surface 510 and the block 500 having a protruding material 560 protruding on one side of the upper surface of the lower part 530 and a fill material 700 laid behind the block 500, the block 500 based ( 600 to be horizontally arranged and vertically stacked, and the second connection member 300 to which the buffer member 200 is connected is stacked and Coupled to the coupling groove 511 of each of the excitation block (500) and then the first connecting member 110 of front plate 100, characterized in that coupling each of the buffer member (200).

Configurations not described herein are described in the buffer block.

The foundation 600 is installed on the ground 1 of the portion where the retaining wall 20 is erected, and is formed by using discarded concrete or aggregate. Base 600 is a configuration for stably stacking blocks 500.

The front plate 100 is composed of a body 110 and the first connecting member 120. The first connection member 120 has a hook ring 121 formed at the end thereof, such that the first connection member 120 is fitted into the locking groove 231 of the buffer member 200.

The shock absorbing member 200 is a place where the front plate 100 is coupled and is resistant to the impact of external loads and to warpage due to climate change. In addition, the buffer hole 212 is formed at one side of the cell wall 211 of the shock absorbing member 200, so that the shock to the external load is not only absorbed, but also less shock to the object to the impact.

The fill material 700 may be filled after stacking all of the blocks 500 by stacking the back of the block 500, and may be filled on the back of the block 500 every time the stack 500 is stacked one by one. . The landfill material 700 may be any material as long as it can be landed behind the block 500, but high quality soils having good drainage are used if possible. The fill material 700 may be a ready-mixed concrete at any time.

The head 510 of the block 500 has a coupling groove 511 on the front side of the inverted T shape, and the second connection member 300 has a shape corresponding to the shape of the coupling groove 511. It is not easily released by load. In other words, it is a structurally stable structure.

The body 520 of the block 500 has a fixing hole 570 formed on one side of the upper surface thereof, so that one end of the fixing member 800 is inserted into the fixing hole 570 so that the fixing member 800 is fixed to the block 500. One end of the reinforcing material 810 is connected to the other end of the fixing material 800, the other end is inserted into the soil to be filled is fixed by the weight of the fill material 700. The fixing member 800 satisfies the required strength and may be made of any material as long as one end of the reinforcing member 810 is coupled and fixed to the fixing hole 570. In addition, the reinforcement 810 may be any material as long as it can be fixed by the weight of the fill material 700 while satisfying the required strength, but preferably a geogrid is used.

12 is a view showing a construction method of the retaining wall according to the present invention, Figure 13 is a cross-sectional view of the fixing material and the reinforcing material is installed in the retaining wall according to the present invention. 14 is a plan view of the fixing material and the reinforcement in the retaining wall according to the present invention. 15 is a view showing an embodiment of the retaining wall according to the present invention, Figure 16 is a view showing a second embodiment of the retaining wall according to the present invention. Fig. 17 is a view showing a third embodiment of the retaining wall according to the present invention, and Fig. 18 is a view showing the fourth embodiment of the retaining wall according to the present invention. 19 is a view showing a fifth embodiment of the retaining wall according to the present invention, and FIG. 20 is a view showing a sixth embodiment of the retaining wall according to the present invention.

The present invention relates to a method for constructing a retaining wall (20) using a buffer block (10), which can be designed. Specifically, in a method for constructing a retaining wall (20) by stacking blocks, (a) ground (1) Installing the base 600 thereon, (b) the body 520 made of a 'Y' shape is connected to the end of the head 510 and the end of the head 511 made of a trapezoidal shape with a coupling groove 511 on the front surface ) And one end of the lower portion 530 connected to the other end of the body 520, but is formed through the upper surface / lower surface on one side of the upper surface / lower surface of the head 510, but the second through-hole becomes smaller toward the lower surface. The third through hole 550 and the protruding material protruding from one side of the upper surface of the head 510 and the lower part 530 are formed through the upper and lower surfaces at one side of the upper and lower surfaces of the ball 540 and the body 520. A block 500 having a fixing hole 570 formed on one side of the upper surface 560 and the body 520 is horizontally placed on the base 600. Step of installing so as to be stacked vertically, (c) Filling the fill material 700 on the back of the block 500, (d) Various shapes generated by the cell wall 211 is crossed by using the connection material 400 It is installed between the cell 210 and the cell 210 or between the outer surface 220 and the cell 210 of the first coupling member 230 having a locking groove 231 on one side of the upper surface and the cell 210 on one side of the rear surface. A block 500 in which the second connection member 300 is coupled to the rear surface of the buffer member 200 including the second binding member 240 inserted into and installed between the outer surface 220 and the cell 210. (E) coupling the first connection member 120 of the front plate 100 to the locking groove 231 of the shock absorbing member 200 according to the designed design. Characterized in that made.

Configurations that are not described herein are described in the buffer block and the retaining wall.

After stacking the blocks 500 in the step (b), the fill material 700 is deposited on the back of the block 500. The fill material 700 may be filled after all of the blocks 500 are stacked, but may be filled whenever the blocks 500 are stacked one by one.

In step (b), one end of the fixing member 800 is inserted into the fixing hole 570 of the block 500, and one end of the reinforcing member 810 is coupled to the other end of the fixing member 800, and the other end of the reinforcing member 810 is filled. Inserted into the soil to be fixed by the weight of the fill material (700). As shown in FIG. 14, the reinforcing material 810 is a rigid geogrid, one end of which is coupled to the fixing material 800 and fixed to the top surface of the block 500, and the other end of the reinforcement material 700 is filled by the height of the block 500. It is installed and fixed by the fill material 700 is filled in the next step. When the reinforcement 810 is a flexible geogrid, one end of the reinforcement 810 may be fixed to the block 500 by the weight of the block 500 instead of the fixing material 800.

In step (b), the block 500 is installed horizontally on the base 600 once, and thereafter, the block 500 is installed in two stages on the first stage of the block 500, and the block 500 is installed on the second stage. ) Is spaced a predetermined distance from the position of the block 500 is installed at the first end so that one end of the second through hole 540 is connected to the protruding material 560 on the upper surface of the block 500. Assembling between the blocks 500 as described above is to ensure that the structure of the retaining wall 20 is more stable in the way that the upper block 500 retreats behind the lower block 500 during the construction of the retaining wall 20. Block 500 may be simply stacked by vertical stacking, but by stacking blocks 500 by zigzag stacking to increase resistance to external loads. That is, when the block 500 is stacked in a zigzag, the protrusion 560 may be coupled to the second through hole 540 on the bottom surface of the block 500, thereby increasing the coupling force between the blocks 500.

Step (d) is a step of making the exterior of the retaining wall 20 in accordance with the planned design by coupling the front plate 100 to the buffer member 200. The shock absorbing member 200 composed of various cells 210 has a strong structure against external shock. The buffer member 200 may further absorb the external shock by making the buffer hole 212 further at one side of the cell wall 211. In addition, the front plate 100 is easily detachable to the shock absorbing member 200 by the first connection member 120 to change the appearance of the retaining wall 20 or easily replace the front plate 100 when there is some damage. can do.

As described above, the preferred embodiment of the buffer block and the retaining wall and the construction method using the same according to the present invention have been described, which will be described as at least one embodiment. It is not limited, and the scope of the technical idea of the present invention is not limited / limited by the drawings or the description with reference to the drawings. In addition, the concept and embodiment of the invention presented in the present invention may be used by those skilled in the art as a basis for modifying or designing to other structures for carrying out the same purpose of the present invention. The equivalent structure modified or changed by those skilled in the art to which the present invention pertains is to be bound by the technical scope of the present invention described in the claims, and the spirit or scope of the invention described in the claims. Various changes, substitutions and alterations are possible without departing from the scope of the invention.

1: Ground 10: Buffer Block
20: retaining wall 100: front panel
110: body 120: first connection member
200: buffer member 210: cell
220: outer surface 230: first bonding material
240: second binder
300: second connection member 310: first through hole
320: settling groove 400: connecting member
500: block 510: head
520: Body 530: Lower
540: second through hole 550: third through hole
560: protruding material 570: fixing hole
600: foundation 700: fill
800: fixing material 810: reinforcing material

Claims (17)

A front plate comprising a body and a first connection member protruding from a rear surface of the body;
It is installed between the cells having various shapes and the cells formed by crossing the cell wall and between the outer surface and the cell, the first binding member having a locking groove on one side of the upper surface and the one side of the cell or between the outer surface and the cell. A buffer member made of a second binder inserted into and installed in the buffer member;
A second connection member having a first through hole formed at one side of the front / rear surface and penetrating the front / rear surface;
The second end is connected to the back side of the buffer member in such a manner that one end penetrates through the first through hole of the second connection member and is coupled to the second coupling member of the shock absorbing member, and the other end is fixed to the back of the second connection member. A connecting member for fixing one end of the connecting member; And
Consists of a block having a coupling groove on the front side of the head to be coupled to the second connection member,
The end of the first connecting member is coupled to the engaging groove of the first coupling member to the front plate is fixed to the buffer member, the second connecting member connected to the buffer member is coupled to the coupling groove of the block A buffer block that can be designed to be characterized.
The method of claim 1,
A cushioning block is formed at an end of the first connecting member, and the buffer block can be designed, characterized in that the first connecting member is fitted into the engaging groove of the buffer member.
The method of claim 1,
A cushioning block capable of designing, characterized in that a fixing groove is formed so that the other end of the connecting member is fixed to the end of the first through hole of the other end of the second connecting member.
The method of claim 1,
A buffer block capable of designing a buffer hole is formed in one side of the cell wall of the buffer member.
The method of claim 1,
The coupling groove in the front of the head of the block has an inverted T-shape, the second connecting member is a buffer block that can be designed, characterized in that formed in a shape corresponding to the shape of the coupling groove.
The method of claim 1,
The block is a buffer block capable of design, characterized in that the head consisting of a trapezoidal shape with a thickness and one end is connected to the end of the head 'Y' shape and the lower end is connected to the other end of the body.
The method of claim 6,
A second through-hole formed on one side of the top / bottom side of the head to penetrate the top / bottom side, the diameter of which is reduced toward the bottom;
A third through hole formed through one of the upper and lower surfaces of the body and penetrating the upper and lower surfaces; And
The buffer block can be designed, characterized in that it further comprises a protrusion protruding on one side of the upper surface of the head and the lower portion.
8. The method according to claim 6 or 7,
The buffer block is possible design, characterized in that it further comprises a fixing hole formed on one side of the upper surface of the body.
In the retaining wall formed by stacking blocks,
Foundation installed on the ground;
A front plate comprising a body and a first connection member protruding from a rear surface of the body;
The cell wall is formed between the various shapes of the cell and the cell or the outer surface and the cell is installed between the coupling member having a locking groove on one side of the upper surface and the one side of the cell or between the outer surface and the cell A buffer member made of a binder inserted and installed;
A second connection member having a first through hole formed at one side of the front / rear surface and penetrating the front / rear surface;
One end of the second connection member is formed on the rear surface of the buffer member in such a manner that one end penetrates through the first through hole of the second connection member and is coupled to the binding member of the buffer member and the other end is fixed to the rear surface of the second connection member. A connecting material to which one end is fixed;
The head is made of a trapezoidal shape with a coupling groove on the front and one end is made of a 'Y' shaped body connected to the end of the head and one end is connected to the other end of the body, the upper and lower sides of the head The second through hole is formed through the upper surface / the lower surface, but the diameter decreases toward the lower surface and the third through hole formed through the upper surface / lower surface on one side of the upper surface / lower surface of the body and one side of the upper surface of the head and lower A block having a protruding material protruding from the block; And
It consists of landfill material that is filled behind the block,
The block is arranged horizontally and vertically stacked on the foundation, and the second connection member to which the buffer member is connected is coupled to the coupling groove of each of the blocks stacked and stacked, and the first plate of the front plate Retaining wall using a cushioning block that can be designed, characterized in that for coupling the connecting member to each of the buffer member.
The method of claim 9,
Retaining wall is formed at the end of the first connecting member is retaining wall using a buffer block that can be designed, characterized in that the first connecting member is fitted into the engaging groove of the buffer member.
The method of claim 9,
Retaining wall using a cushioning block that can be designed, characterized in that the buffer hole is generated on one side of the cell wall of the buffer member.
The method of claim 9,
Retaining wall using a buffer block design is possible, characterized in that the coupling groove in the front of the head of the block has an inverted T shape, the second connecting member is formed in a shape corresponding to the shape of the coupling groove.
The method of claim 9,
A fixing hole formed at one side of the upper surface of the body;
A fixing member having one end inserted into the fixing hole; And
Retaining wall using a cushioning block, the design is characterized in that it further comprises a reinforcing member is connected to the other end of the fixing material, the other end is inserted into the soil to be filled, and fixed by the weight of the fill material.
In the construction method of laminating blocks to create a retaining wall,
(a) installing a foundation on the ground;
(b) a head made of a trapezoidal shape with a coupling groove on the front and a body made of a 'Y' shape connected to one end of the head and a lower part connected to the other end of the body, the upper surface of the head / A second through-hole formed on one side of the lower surface through the upper surface and the lower surface, but the third through-hole and the head and the lower portion formed through the upper surface / lower surface on one side Installing a block having a protruding material protruding from one side of an upper surface of the upper surface and a fixing hole generated at one side of the upper surface of the body to be horizontally arranged and vertically stacked on the base;
(c) depositing the fill material behind the block;
(d) a connection member is used to be installed between the cells having various shapes formed by crossing the cell walls and between the cells or between the outer surface and the cells. Coupling a second coupling member to the coupling groove of the block, the second coupling member being coupled to a rear surface of the buffer member formed of a coupling member inserted and installed between an outer surface and the cell; And
(e) Retaining wall construction method using a cushioning block capable of designing comprising the step of coupling the first connecting member of the front plate to the engaging groove of the buffer material in accordance with the designed design.
15. The method of claim 14,
Inserting one end of the fixing material into the fixing hole of the block in the step (b), the other end of the fixing material is coupled to one end of the reinforcing material and the other end of the reinforcing material is inserted into the soil to be filled so that it is fixed by the weight of the fill material Retaining wall construction method using a buffer block capable of designing a feature.
15. The method of claim 14,
In step (b), the block is installed horizontally on the base once, and then the block is installed in two stages on the first stage of the block, and then the block installed in the second stage has one end of the second through hole. Retaining wall construction method using a cushioning block that can be designed, characterized in that a predetermined distance away from the position of the block is installed in the first stage so as to be connected to the protrusion on the upper surface of the block.
15. The method of claim 14,
Retaining wall construction method using a cushioning block that can be designed, characterized in that the buffer member of the step (d) is characterized in that the buffer hole is generated on one side of the cell wall.

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