KR20090004922U - Block, coupler, and reinforced soilretaining wall Structure using the same - Google Patents

Abstract

The present invention relates to a block, a coupler, and a reinforcement earth retaining wall structure using the same, and more particularly, to compensate for a problem caused by stress concentration at the connection part of the reinforcement and the front part generated during settlement of the soil after reinforcement earth retaining wall construction. A block, coupler, and reinforcement earth retaining wall structure using the same that allow settlement of the reinforcement material.

The reinforced earth retaining wall structure of the present invention, in the reinforced earth retaining wall structure, geogrid; A coupler having a fixed part connected to the geogrid at one end and a support part formed at the other end based on a central connection part; And a block having a locking hole drilled in an up and down direction of the block body, and a settlement guide groove recessed downwardly from an upper side to a predetermined depth so as to communicate with the locking hole so that the thermal connection part is inserted and moved. Supporting the tensile force transmitted and at the same time in contact with the support portion to guide the shanghai comprises a rail portion protruding on the inner surface of the engaging hole, the support portion is formed as a straight support rod orthogonal to the connection portion, the rail portion both sides of the support rod And a pair of longitudinal protrusions having a hemispherical cross section in point contact with the outer circumferential surface.

As a result, the coupler is guided to the rail portion of the block when the reinforcing material is settled according to the settlement of the ground, so that the coupler moves downwards more smoothly, thereby improving durability and stability of the retaining wall.

Description

Block, coupler, and reinforced soil retaining wall structure using the same {Block, coupler, and reinforced soilretaining wall structure using the same}

The present invention relates to a block, a coupler, and a reinforcement earth retaining wall structure using the same, and more particularly, to compensate for a problem caused by stress concentration at the connection part of the reinforcement and the front part generated during settlement of the soil after reinforcement earth retaining wall construction. A block, coupler, and reinforced earth retaining wall structure using the same are constructed to allow settlement of the reinforcement.

Reinforced soil retaining wall is designed to suppress the lateral displacement of the block by the load received by the backfilled soil by the reinforcement connected to the back of the front protective material (block). It is widely used for building apartment complexes and reinforcing slopes.

Various methods have been proposed as a method of connecting the blocks of the reinforced earth retaining wall and the reinforcement. For example, a method of matching unevenness between a block and a block and inserting a grid type reinforcement into the unevenness and inserting the reinforcement by a connecting device such as a connector, a clip and a connecting pin has been proposed.

In the method of directly inserting the reinforcement into the unevenness of the block, the reinforcement has to be closely contacted by the unevenness or the jaw of the block, so that the warpage of the reinforcement is large and cracks and breakages occur easily. The method of connecting the block and the reinforcement with a connection pin or clip has a disadvantage in that it is difficult to form a hole into which the connection pin or the clip is inserted into the block, and pin insertion is difficult during construction.

Above all, the conventional reinforcement retaining wall cannot cope with the stress concentration at the front part of the reinforcement that occurs during the settlement of the fill soil after construction, and there is a concern that the reinforcement (geogrid) is broken and the retaining wall collapses.

In order to solve this problem, the Republic of Korea Patent No. 10-0696994 proposes a connecting device having a structure that can flow according to the settlement of the ground soil as a connecting device for connecting the reinforcement and the block.

1 is a block diagram illustrating components of a connection device proposed in Korean Patent No. 10-0696994. Referring to this, the connection device 100 is formed of a 'c' type of fixing table 101, connecting table 102, 'S' type fastener 103, as shown in Figure 2 block 200 and geogrid ( 400).

Referring to Figure 2, the fixing unit 101 of the connecting device 100 is inserted into the insertion hole of the block of one side of the side facing in the 'c' shape, the connecting table 102 is inserted to be movable to the other side, Finally, the fastener 103 is connected in such a manner as to fasten the opposite sides.

As such, the assembly of the connection device 100 proposed in Korean Patent No. 10-0696994 may not be simply performed.

In particular, when the construction step by step, the assembly of the connecting device 100 is separated and progressed in time to make the construction very complicated. For example, prior to installing the blocks 200 in a row, the '101'-type fixing base 101 must be fitted into the insertion holes of the plurality of blocks 200 forming one layer.

In performing the backfilling of the blocks 200, the back of the blocks 200 are filled with aggregate for drainage, in which the force is applied to the fixing base 101 during the backfilling of the corrugated body and its installation position and installation state are affected. It is easy to receive. For this reason, when filling the aggregate, it was necessary to work delicately so that the holding base 101 was kept in the center and vertical direction of the block. And, after the back-filled, one-by-one connection (102) to the geogrid 400 to be fitted to the fixture 101, and must be assembled with a fastener 103 finish.

As such, the proposed connecting device 100 requires very complicated work in actual construction, and the connecting device 100 is assembled with various parts 101, 102, and 103, and thus its management is not easy.

Moreover, the fixing base 101 inserted into the block in the form of 'c' forms a protruding portion up and down of the block, which prevents the block 200 from being stacked horizontally, thereby inevitably upper, The lower surface is to be formed in multiple stages, making the block difficult and may be a factor to increase the manufacturing cost.

On the other hand, there is a possibility that the fixing base 101 may be bent and move in the longitudinal direction due to the lateral attraction force received by the geogrid 400. In addition, as described above, when the fixing base 101 is not installed at right angles and is installed at an angle due to the aggregate, it is not easy for the connecting table 102 to move vertically along the fixing base 101. In these cases, there is a problem in that stress concentration applied to the front part of the reinforcement 300 due to settlement cannot be prevented.

On the other hand, as a way to solve the problems of the above-described Patent No. 10-0696994 Korean Republic Patent No. 10-0665022 'reinforced soil retaining wall block and connector' is disclosed.

As shown in FIG. 3, 'T' is applied to a block body having a first through hole 11, a second through hole 12, an insertion protrusion 13, and an insertion groove 14. A block 1 having a 'type connector mounting groove 15', and a 'b' type inserting portion 31 and a locking protrusion 32 connected to the reinforcement 2 so as to be inserted into the connector mounting groove 15. The connector 3 is provided.

According to the reinforcement soil retaining wall block and the connector, the lowering movement of the 'T' type insertion portion 31 is more easily performed through the 'T' type connector mounting groove 15, and is applied to the front part of the reinforcement due to settlement. Loss of stress has the advantage of relieving stress concentration to some extent.

However, since the inner surface of the 'T' type inserting portion 31 and the 'T' type connector mounting groove 15 is in surface contact with each other, when the reinforcing material 2 is lowered due to settlement of the ground, As a large frictional force is applied, the lowering movement of the connector 3 is not performed smoothly, which causes deformation or damage to the reinforcing material 2 and the connector 3.

In particular, the reinforcement soil retaining wall contains a large amount of water due to the inflow of groundwater and rainwater flowing out from the back, so the 'T' type inserting portion 31 is equipped with a 'T' type connector due to corrosion of the block 1 and the connector 3. As it adheres to the inner surface of the groove 15, it is impossible to descend. Such a misalignment of the connector 3 acts as a lethal factor that deepens the deformation and damage of the reinforcement 2 and impairs the durability and stability of the reinforcement retaining wall. There is a situation.

And, when installing the connector (3) between the block (1) and the reinforcement (2) during the construction of the retaining wall retaining wall, the 'T' type insert portion 31 of the connector (3) is a free end, so There is a problem that the deflection phenomenon occurs, the locking projection 32 side of the connector 3 is easily separated from the reinforcing material 2, the connector 3 is separated upward by the impact during the compaction of fill.

Accordingly, since the connector 3 separated during the construction of the reinforcement soil retaining wall must be re-attached each time, an increase in construction time and construction labor cost is caused. In addition, when constructing the retaining wall of the reinforcement soil, a large amount of connectors (3) are installed at a time, so it is impossible to check all the disconnected connectors (3). Since it occurs randomly, the durability and stability of the reinforced earth retaining wall cannot be secured sufficiently.

Therefore, the present invention is to facilitate the construction of the coupler to move down smoothly in the settlement of the reinforcement according to the settlement of the ground soil, providing the convenience of construction and management, the durability and stability of the retaining wall, coupler, and It is to provide a reinforced earth retaining wall structure using the same.

Another object of the present invention is to maintain the position of the coupler in the construction process of the reinforced earth retaining wall, and to prevent the detachment of the coupler, to provide the convenience of construction and management, to improve the durability and stability of the retaining wall One block, coupler, and to provide a reinforced earth retaining wall structure using the same.

In order to achieve the above object, in the reinforced earth retaining wall structure, geogrid; A coupler having a fixed part connected to the geogrid at one end and a support part formed at the other end based on a central connection part; And a block having a locking hole drilled in an up and down direction of the block body, and a settlement guide groove recessed downwardly from an upper side to a predetermined depth so as to communicate with the locking hole so that the thermal connection part is inserted and moved. Supporting the tensile force transmitted and at the same time in contact with the support portion to guide the shanghai comprises a rail portion protruding on the inner surface of the engaging hole, the support portion is formed as a straight support rod orthogonal to the connection portion, the rail portion both sides of the support rod And a pair of longitudinal protrusions having a hemispherical cross section in point contact with the outer circumferential surface.

In order to achieve the above object, the block is used to construct a reinforcement earth retaining wall while being connected to the geogrid by a coupler, comprising: a catching hole drilled in the vertical direction of the block body so that one side of the coupler is inserted; A settlement guide groove recessed downwardly from an upper side of the block body so as to communicate with the locking hole so that one side of the coupler moves downward; And a rail part protruding from an inner surface of the engaging hole to contact one side of the coupler, and guiding downward movement of one side of the coupler, wherein the rail part protrudes from the left and right inner surfaces based on the settlement guide groove, and one outer peripheral surface of the coupler. It is characterized in that it consists of a pair of longitudinal projections having a hemispherical cross section so as to contact with the point.

In order to achieve the above object, a locking hole drilled in the up and down direction of the block body, a settlement guide groove recessed downwardly from the upper side of the block body to a predetermined depth in communication with the locking hole, and a hemispherical cross section on the left and right inner surfaces of the locking hole. In a block having a rail portion formed by a pair of longitudinal protrusions having a coupler for connecting a geogrid, the coupler has a fixed portion connected to the geogrid at one end based on a central connection portion, and is caught at the block at the other end. Is provided with a support portion, characterized in that it further comprises a roller member which is in close contact with the rail to the support portion and the rolling.

Here, the support portion is formed of a straight support rod orthogonal to the connecting portion, the roller member may be a pair of roller rods rotatably coupled to both sides of the support rod.

According to the present invention, the coupler is guided to the rail portion of the block when the reinforcement material is settled according to the settlement of the soil, so that it moves downwards more smoothly, thereby improving the durability and stability of the retaining wall, and by the cover means in the construction process of the retaining wall. Not only can the coupler be positioned correctly, but it can also prevent departure due to external impact, thereby improving the workability and convenience of management.

1 is an exploded perspective view showing a component configuration of a conventional coupler;

2 and 3 is a perspective view showing a conventional reinforced earth retaining wall structure,

Figure 4a is a perspective view showing a block according to an embodiment of the present invention,

4B is a plan view of main parts of FIG. 4A;

Figure 5 is an exploded perspective view showing a coupler according to an embodiment of the present invention,

Figure 6 is a perspective view for explaining the reinforced earth retaining wall structure according to an embodiment of the present invention;

Figure 7 is a perspective view for explaining a modification of the reinforced earth retaining wall structure according to an embodiment of the present invention,

8a and 8b is a perspective view showing a cover means applied to the modified example of the reinforced earth retaining wall structure according to an embodiment of the present invention,

9 is a view for explaining the operation of the reinforced earth retaining wall structure according to an embodiment of the present invention;

10 is a view for explaining the modification of the reinforced earth retaining wall structure according to an embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

500: block 510: block body

520: Jam hole 530: Settlement guide home

540: rail part 600: coupler

610: Fixed part 620: Support part

630: connecting portion 640: roller member

700: cover means 710: cover member

720: insertion member 722: longitudinal member

724: Jam Jaw 800: Geogrid

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention in detail.

Figure 4a is a perspective view showing a block according to an embodiment of the present invention, Figure 4b is a plan view of the main portion of Figure 4a.

4A and 4B, a block 500 according to an embodiment of the present invention includes a locking hole 520, a settlement guide groove 530, and a rail part in a block body 510 having a substantially hexahedral shape. 540, which is used to construct a reinforced soil retaining wall while being connected to each other with a reinforcing material (hereinafter referred to as a geogrid 800) by a coupler 600 to be described later.

The locking hole 520 is a hole that penetrates and is formed in an up and down direction of the block body 510 and is formed such that one side of the coupler 600 is inserted and locked. The shape of the locking hole 620 may be formed in various structures if one side of the coupler 600 is easily inserted and locked, and thus may be modified according to the shape of the corresponding coupler 600. In this embodiment, since one side of the coupler 600 is a straight structure, it is penetrated and formed in a rectangular structure to correspond to this.

The settlement guide groove 530 is recessed downward from the upper side of the block body 510 to communicate with the locking hole 520 so that one side of the coupler 600 moves downward. At this time, the width of the settlement guide groove 530 is formed to facilitate the insertion and downward movement of the coupler 600 side member passing through the groove.

The rail unit 540 protrudes from the inner surface of the locking hole 520 so that one side of the coupler 600 contacts, guides the downward movement of one side of the coupler 600, and is transmitted to the coupler 600 from the geogrid 800 side. Tensile force will be supported.

For example, the rail unit 540 protrudes along the moving direction of the coupler 600 on the left and right sides of the inner surface (the inner surface of the geogrid 800 of the locking hole 520) based on the settlement guide groove 530, and the coupler 600. It consists of a pair of longitudinal protrusions having a hemispherical cross section so as to be in point contact with one outer peripheral surface of the.

In addition, the trapezoidal hole which penetrates up and down in the block body 510 in contact with the locking hole 520 is formed to control the weight of the block or to reduce the concrete mortar which is the material of the block.

Figure 5 is an exploded perspective view showing a coupler according to an embodiment of the present invention.

Referring to FIG. 5, the coupler 600 according to an embodiment of the present invention includes a fixing part 610 connected to the geogrid 800 side, a supporting part 620 caught on the block 500 side, and a fixing part. And a connection part 630 disposed at the center to connect the 610 and the support part 620.

The support part 620 further includes a roller member 640 contacted with the rail part 540 to be moved in a cloud, so that the downward movement of the coupler 600 is more smoothly performed when the geogrid 800 is settled. do.

The fixing part 610 may be formed in various forms as long as it can be connected to the geogrid 800, but in the present embodiment, a plurality of hooks 212 are formed at predetermined intervals on the straight holder 211.

The support part 620 may be configured in various forms as long as it can be inserted into the locking hole of the above-described block, but in the present embodiment, the support part 620 is formed as a straight support rod orthogonal to the connection part.

The roller member 640 is composed of a pair of roller rods rotatably coupled to both sides of the support rod provided as the support portion 620. The roller rod may be formed in the form of a round rod having a hollow portion to be fitted to the outer circumferential surface of the support rod. At this time, the support rod is provided with a pin 650 to prevent the separation of the roller member 640. In addition, as a method for preventing the detachment of the roller member 640, various methods such as a method of fastening a fixing nut in addition to the method using a pin may be applied.

Figure 6 is a perspective view for explaining a reinforced earth retaining wall structure according to an embodiment of the present invention.

Referring to Figure 6, the reinforced earth retaining wall structure according to an embodiment of the present invention is implemented by using the block 500, the coupler 600, and the geogrid 800.

The coupler 600 is configured such that the fixing part 610 formed at one end of the coupler 600 is connected to the geogrid 800 and the supporting part 620 formed at the other end thereof is caught on the block 500 side.

The fixing part 610 is provided with a plurality of hooks 612 is inserted and fixed to the geogrid 800, the support part 620 is formed of a straight support rod orthogonal to the connecting portion 630, the roller member so as to rotate when moved downward ( 640.

The block 500 is provided with a locking hole 520 drilled in the vertical direction of the block body 510 to allow the support part 620 of the coupler 600 to be inserted therefrom, and to be in communication with the locking hole 520 from the upper side. It is provided with a sinking guide groove 530 that is recessed downward to a depth so that the connecting portion 630 is inserted and moved, and provided with a rail portion 540 protruding on the inner surface of the locking hole 520 from the geogrid 800 side. While supporting the tensile force transmitted to 620 is in contact with the support portion 620 is to guide the shandong.

At this time, the rail portion 640 is composed of a pair of longitudinal projections having a hemispherical cross section so as to point contact with the outer circumferential surface of the roller member 640 to minimize the frictional force when the support rod moves downward.

7 is a perspective view for explaining a modification of the reinforced earth retaining wall structure according to an embodiment of the present invention, Figures 8a and 8b is a perspective view showing a cover means applied to a modified example of the reinforced earth retaining wall structure according to an embodiment of the present invention to be.

Referring to Figure 7, a modified example of the reinforced earth retaining wall structure according to an embodiment of the present invention is to construct a reinforced earth retaining wall structure using a block 500, coupler 600, and geogrid 800, the coupler in the construction process It is further provided with a cover means 700 is inserted and installed in the locking hole 520 of the block 500 so that the 600 is positioned in place.

The cover means 700 includes a cover member 710 for sealing the upper opening of the locking hole 520, and an insertion member 720 in which one side of the coupler 600 is seated.

The insertion member 720 includes a plurality of locking projections 724 protruding at a predetermined vertical interval from the vertical member 722 extending downwardly to the cover member 710 so as to be inserted into the locking hole 520.

Since the cover member 710 seals the upper opening of the engaging hole 520, the coupler 600 may be prevented from deviating upward by the impact generated during the construction of the reinforced earth retaining wall structure.

The catching jaw 724 has rigidity enough to support the load of the support part 620 in a state in which the settling force is not applied to the coupler 600, but is formed of a flexible material, thereby allowing the coupler 600 to carry out its own weight. As a result, the deflection phenomenon of moving the support part 620 side downward can be prevented. For example, the locking jaw 624 may be formed of a plate-shaped member formed of a flexible silicone material.

The cover means 700 has a structure having a single insertion member 720 in the cover member 710 as shown in FIG. 8A, or a plurality of cover members 710 in the cover member 710 as shown in FIG. 8B. It may be formed in a structure having an insertion member 720. In addition, the shape of the cover means 700 may be variously changed according to the shape or structure of the support 620 of the coupler 600.

9 is a view for explaining the operation of the reinforced earth retaining wall structure according to an embodiment of the present invention, showing a state seen from the line A-A of FIG.

The process of constructing the reinforced soil retaining wall structure according to the embodiment of the present invention will be described in detail using the block 500 shown in FIG. 4A and the coupler 600 shown in FIG. 5.

First, the foundation of the reinforcement soil retaining wall is formed, and the first stage blocks 500 are stacked on the foundation, and then backfilling of the first stage blocks 500 is performed. The backfill is filled with aggregate for drainage to the back of the blocks (500), the backfill to fill the back of the aggregate, and then the compaction of the backfill is carried out, but using a 1 ton lightweight compaction equipment up to 1m from the back of the block After 1m, vibration compaction equipment of about 4 tons or more is used.

When the back filling operation is completed, as shown in FIG. 6, the support part 620 of the coupler 600 is installed to be inserted through the upper side of the locking hole 520 of the block 500 to be in close contact with the rail part 540. Install geogrid 800 as a reinforcement. When the geogrid 800 is installed, a predetermined interval is formed so that neighboring geogrids 800 do not overlap each other.

When the hook 612 is fitted so that the fixing part 610 of the coupler 600 is connected to one side of the geogrid 800 installed as described above, the installation of the reinforcing soil retaining wall structure is completed.

Then, by repeating the installation process of the block 500, the coupler 600, and the geogrid 800 as described above to complete the reinforced earth retaining wall having the desired block layer.

When the construction of the reinforced soil retaining wall is a certain period of time, the geogrid 800 is gradually settled due to settlement of the ground soil, the coupler 600 guides the downward movement of the geogrid 800.

At this time, since the support portion 620 of the coupler 600 is in point contact with the rail portion 540, the friction force is minimized and smoothly moved downward. In addition, even if the block 500 is corroded due to the groundwater and rainwater flowing out to the rear surface of the reinforced soil retaining wall, the support part 620 is in contact with the rail part 540 so that the support part 620 is not easily fixed and is interlocked with the settlement of the geogrid 800. To be moved downwards. As a result, deformation or damage of the coupler 600 and the geogrid 800 may be prevented due to the movement defect.

In particular, since the roller member 640 is provided on the support 620 in contact with the rail 540 as shown in FIG. 9, the settlement of the geogrid 800 is performed more smoothly.

FIG. 10 is a view for explaining a modification of the reinforced earth retaining wall structure according to the embodiment of the present invention, and shows a state seen from line A-A of FIG.

According to a modification of the reinforced earth retaining wall structure according to an embodiment of the present invention, as shown in Figure 10, the cover means 700 is provided in the engaging hole 520 of the block 500 to stabilize the coupler 600 By supporting it, the construction of the reinforced earth retaining wall structure can be carried out more smoothly.

That is, since the support part 620 of the coupler 600 is seated and supported by the locking jaw 724, the support part 620 is prevented from hitting the lower part of the locking hole 520 due to the weight of the coupler itself. Even when an impact occurs during the construction of the retaining wall, since the cover member 710 blocks the detachment of the coupler 600 upward, there is no need to repeatedly check or modify the installation state of the coupler 600, thereby providing convenience in construction. In addition, the construction time can be shortened and the labor cost of construction can be expected.

In addition, the locking jaw 724 is formed to have flexibility, and when the lowering force of the coupler 600 self-weight due to the settlement of the geogrid 800 is applied, it is folded down flexibly so that the downward movement of the support part 620 is stable. Is performed.

While several embodiments of the present invention have been shown and described as described above, those skilled in the art can appreciate that the present embodiments can be modified without departing from the spirit or principles of the present invention. Could be. The scope of the invention will be defined by the appended claims and their equivalents.

Claims (4)

In the reinforced earth retaining wall structure, Geogrid; A coupler having a fixed part connected to the geogrid at one end and a support part formed at the other end based on a central connection part; It includes a block having a locking hole perforated in the vertical direction of the block body, and a settlement guide groove which is recessed downward from the upper side to a predetermined depth in communication with the locking hole to insert and move the heat connection portion, The block includes a rail portion protruding on the inner surface of the engaging hole to support the tensile force transmitted to the support portion and to contact the support portion to guide the shanghai movement, The support portion is formed of a straight support rod orthogonal to the connection portion, Reinforcement earth retaining wall structure, characterized in that the rail portion consists of a pair of longitudinal projections having a hemispherical cross section so as to be in point contact with both outer peripheral surfaces of the support bar.  In the block used to construct the reinforcement retaining wall while being connected to the geogrid by a coupler, A catching hole drilled in the vertical direction of the block body so that one side of the coupler is inserted; A settlement guide groove recessed downwardly from an upper side of the block body so as to communicate with the locking hole so that one side of the coupler moves downward; And Protruding to the inner surface of the engaging hole so that one side of the coupler is in contact, comprising a rail unit for guiding the downward movement of the coupler side, The rail portion protrudes from the left and right inner surface relative to the settlement guide groove, characterized in that the block consisting of a pair of longitudinal projections having a hemispherical cross-section so as to make point contact with the one outer peripheral surface of the coupler.  A pair of longitudinal projections having a hemispherical cross-section on the left and right inner surfaces of the engaging body, the engaging hole drilled in the up and down direction of the block body, the sinking guide groove recessed downwardly from the upper side of the block body to a predetermined depth so as to communicate with the engaging hole; In the block having a rail portion formed with a and a coupler for connecting the geogrid, The coupler is, A fixing part connected to the geogrid is formed at one end based on a central connection part, and a support part engaged with the block is provided at the other end, Coupler characterized in that it further comprises a roller member which is in close contact with the rail to the support portion rolled. The method of claim 3, The support portion is formed of a straight support rod orthogonal to the connection portion, The roller member is a coupler, characterized in that a pair of roller rods rotatably coupled to both sides of the support rod.