KR20110011074A - Block system for embankment or revetment and method build-up thereof - Google Patents

Abstract

PURPOSE: A block system for an embankment or a retaining wall and a construction method thereof are provided to securely support soil without installing an anchor block or a geogrid. CONSTITUTION: A block system for an embankment or a retaining wall comprises block bodies(2) and a tension member(14). Protrusion parts and concave parts are formed on both side surfaces of the block bodies. A pair of through holes are vertically formed on the top of the block bodies. The tension member is continuously connected to the block bodies in an axial direction using cap units(16). The tension member penetrates through the through holes of the block bodies.

Description

Block system for embankment or retaining wall and its construction method {Block system for embankment or revetment and method build-up}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a block system for an axis or retaining wall, and in particular, an axis or retaining wall capable of firmly supporting soil without installing a geogrid or an anchor block as a backfill space by applying a pre-stress in a vertical direction to a constructed block. Block system and its construction method.

Soil support at the fore or incision depends on the shaft or retaining wall.

A shaft is a traditional way of supporting soil by stacking stones on a slope, and is formed by the construction of a cantilever, a processed stone such as a stone, or a natural stone, or by constructing a shaft block of concrete structure and filling the back with rubble or mortar or concrete. It is carried out in such a way that it is cast and integrated.

If the backfill on the shaft block is rubble filled, the construction cost is low and the construction period is short, but the construction height is limited because it is vulnerable to horizontal earth pressure, and the backfilling with mortar or concrete is expensive and curing Will also be long.

Retaining walls are known as gravity retaining wall, anti-gravity retaining wall, Y-shaped retaining wall, L-shaped retaining wall, rear wall retaining wall, front wall retaining wall, shelf retaining wall, lattice retaining wall, reinforced earth retaining wall, etc. Any construction is done in the process of decorating formwork, reinforcing reinforcing bars, and then placing concrete to form walls, which requires a long construction period and a lot of personnel and equipment.

Reinforced soil retaining wall is similar to the above-mentioned block in that the pre-molded block is piled in the field, but it has an external feature that the back length is longer than the block of block, and geogrid, tension bar, anchor block at every height during back filling It is distinguished from the shaft block in that the back is laid to increase the frictional force in the ground.

Korean Patent Publication No. 10-0379341 and Korean Laid-Open Patent Publication No. 10-2001-0097072 show examples of reinforcing soil retaining walls.

Among the above-described retaining wall related technologies, reinforcement earth retaining wall has both simplicity of construction and structural robustness, but the terrain where there is not enough space for backfilling due to the adjacent land of other owners near a site (e.g. In order to install geogrids or anchor blocks, it is inevitable to invade adjacent lands, and therefore, because the landlords have to obtain permission from the owners of adjacent lands, the construction process is often not smooth due to the huge land use compensation problem. These unusual topologies frequently appear in bank constructions for river maintenance.

It is an object of the present invention for a shaft or retaining wall that can be securely and firmly supported the soil without invading the land of other adjacent owners even in the field conditions that do not have sufficient backfill space in order to solve the above-mentioned problems In providing a block system.

Another object of the present invention is to provide a construction method using the block or retaining wall block system.

A block system for the shaft or retaining wall for achieving the above object of the present invention is formed on both sides of the projection and the recess associated with the other adjacent block body to the side, the upper surface is provided with one or a pair of vertically drilled through A periphery of the through hole is formed as a recessed concave groove, and an opposite bottom surface is formed with a convex portion having an outer diameter that can be accommodated as an inner diameter of the concave groove; The cap nut can be continuously connected in the axial direction and can be implemented in a configuration including a tension member installed through the through hole of the block body.

In the above-described configuration, the tension member may have a hook at both ends in a symmetrical direction, and a thread portion which is screwed with the cap nut is directly below the upper hook.

In addition, the length of the tension member may be set to an arbitrary multiple of the height of the block body so that the upper hook of the tension member is always exposed through the upper concave groove of the block body.

The tension member may be composed of one selected from wire rods such as wire ropes, chains and chains, or rods such as steel bars and rods.

In the construction method of the present invention, the block bodies adjacent to the position where the foundation concrete layer is placed are connected to each other by connecting the projections and the recesses of the side sides, and arranged in one row, and the through hole of each block body penetrates the tension member with the cap nut inserted downward. A foundation pouring step of installing and then concrete to solidify integrally; The upper hook of the tension member is concave groove of the uppermost block body by constructing the convex portion of the upper block body to be inserted into the concave groove of the lower block body while penetrating the through hole of the other block body with the tension member exposed upwardly for each through hole of the block body. Building step repeatedly stacked until exposed; Tension step of pre-stressing the block body by engaging the upper hook of the tension member exposed to the recess of the uppermost block body by engaging the lower hook of another tension member and screwing and tightening the cap nut attached to the upper tension member to the thread of the lower tension member. Wow; A backfilling step of backfilling and compacting the soil behind the prestressed block; A repeating step of building the block body to a desired height by repeating the building step, the pulling step, and the back filling step; A cap nut is put on the upper hook of the tension member exposed by the concave groove of the uppermost block body, and it can be implemented by a finishing step of prestressing and backfilling the final block body.

The present invention of the above-described configuration is a pre-stressed state by the built-up shaft block or retaining wall block has a stress against the compressive strain in the vertical direction applied by the post-tensioning action by the tensioning material to be filled without the installation of geogrid or anchor block There is an effect of firmly supporting the tensile strain due to the transverse pressure of the soil generated later.

Since the present invention can be installed without geogrids or anchor blocks, it is possible to construct a structure that can ensure the safety of the retaining wall even in a site where it is difficult to secure sufficient backfilling space or difficult to secure it. Gain the benefits and benefits of overriding the problem of private property involvement.

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

1 is a perspective view showing the structure of a block body used in a shaft system or retaining wall block system according to the present invention, the block body 2 is a projection (4) on one side so as to be stacked in a side engagement with the adjacent block body (2) ) Is provided and a recess 6 is formed on the opposite side.

In addition, the block 2 has one or a pair of vertically formed through-holes 8 in the vertical direction, and the periphery of the through-holes 8 is sufficiently recessed in a predetermined radius to form a concave groove 10. And, the opposite side is formed with a convex portion 12 having an outer diameter of the size that can be fitted into the inner diameter of the concave groove 10.

The center of the through hole 8 is set to a position that is slightly localized toward the back filling on the upper surface of the block body 2.

When the block body 2 is constructed, the side projections 4 are engaged with the concave portions 6 of the adjacent block bodies 2, and the concave grooves 10 formed on the upper surface are constructed thereon. It is constructed while fitting the bottom side convex portion 12 of another block body 2 to be made.

In addition to the block 2 described above, the shaft or retaining wall block system according to the present invention further includes a tension member 14 and a cap nut 16 shown in FIG. 2.

The tension member 14 has a wire rod or rod having a predetermined length, which has hooks 14a and 14b having the same shape at the upper and lower ends, and a threaded portion 14c is provided directly under the upper hook 14a. The cap nut 16 is penetrated by the lower hook 14b of the tension member 14 and can be screwed into the threaded portion 14c of the other tension member 14.

The base concrete layer 18 is first constructed at the position where the block body 2 is to be constructed. At this time, the lowermost tension member 14 has the lower hook 14b and the cap nut 16 having the base concrete layer ( 18) is disposed so as to be embedded in, preferably, the block body 2 is arranged in one horizontal line before the foundation concrete layer 18 is placed in the form of a through hole 8 through the tension member 14 to the foundation It is preferable to allow the concrete layer 18 to solidify integrally.

A new tension member 14 may be continuously connected integrally to the upper end of the tension member 14 having one end embedded in the foundation concrete layer 18.

The connection between the tension member 14 and the other tension member 14 may be adopted in any form as long as it is a structure that can be firmly connected to each other. In the present invention, the hook 14a (provided at the upper and lower ends of the tension member 14 ( A structure in which the coupling grooves 14d are provided in the symmetric direction in 14b) is adopted to be engaged with each other.

3 shows a state in which the upper hook 14a of the tension member 14 and the lower hook 14b of the other tension member 14 are integrally engaged with each other and combined.

In FIG. 3, the lower hook 14b of the upper tension member 14 is engaged with the upper hook 14a of the lower tension member 14, and the periphery thereof is covered with a cap nut 16 screwed to the threaded portion 14c. The connection state between the hooks 14a and 14b is protected from being peeled off.

On the other hand, the screw 14 of the cap nut 16 causes the tension member 14 to post-tension with respect to the block 2, resulting in a prestressed state through the bottom of the concave groove 10. . As a result, the constructed block body 2 is provided with a stress against the compressive strain in the vertical direction, thereby forming a rigid retaining wall that solves the tensile strain caused by the lateral pressure generated by the load action of the soil.

In addition, the center axis of the prestress acting as described above is set to a position slightly offset from the upper surface of the block body 2 toward the back filling, so that the center of the constructed block body 2 is slightly pulled to the rear side. As a result, the structure of the block body 2 becomes a form that resists the force to be conducted in the future.

The length of the tension member 14 described above in the present invention caps an arbitrary multiple of the height of the block body 2 (the height including the convex portion 12 at the bottom) and the depth of the concave groove 10 formed on the upper surface. It is recommended to set the dimensions slightly larger than the height of the nut 16.

When the length of the tension member 14 is a multiple of the height of the block body 2, the upper hook 14a of the tension member 14 is always located inside the concave groove 10 of the block body 2, and the threaded portion 14c. ) Is partially exposed through the upper end of the through hole (8), so that the pre-tensioning is performed by the block body (2) by implementing post-tensioning by simply screwing and tightening the cap nut (16). Because.

The construction method using the reinforcement soil retaining wall system having the above-described configuration is carried out in a basic placing step, a construction step, a tension step, a connecting and repeating step of the tension member, and a finishing tension step.

The foundation casting step is a process of placing the foundation concrete layer 16 shown in FIG. 2 on the ground, in which the row of block bodies 2 are fitted with the protrusions 4 and the recesses 6 on both sides. It is important to arrange in the engaged state and to solidify together with the block body 2 in the concrete to be poured through the tension member 14 through the through hole 8 of each block body (2).

In the step of constructing, the convex portion 12 formed on the bottom surface of the upper block body 2 is formed in the bottom surface of the upper block body 2 while the through hole 8 of the block body 2 passes through the tension member 14. It is constructed to fit in, but is repeatedly constructed until the upper hook (14a) of the tension member 14 is exposed through the concave groove 10 of the uppermost block body (2).

In the tensioning step, the lower hook 14b of the new tension member 14 is engaged by connecting with the upper hook 14a of the tension member 14 exposed to the recessed groove 10 of the block body 2 constructed on the uppermost side, and the cap nut is connected. (16) is inserted and then screwed into the threaded portion 14c of the lower tension member 14, and then tightened to post-tension, so that the vertically stressed block 2 is applied.

In addition, when the cap nut 20 is tightened, it is recommended that a pre-stress is not applied to the block body 2 by more than the breaking strength of the block body 2 by using a device capable of measuring torque, for example, a torque wrench.

The prestressed block body 2 is in close contact with the foundation concrete layer 16 and has a stress against the compressive deformation force, thereby relieving the tensile strain caused by the transverse earth pressure action, thereby strengthening the soil. Can be supported.

When the tension phase is complete, the backfill phase is performed.

The back filling step is carried out by filling the aggregate and soil to the rear of the constructed block body 2 as in the conventional manner and compacting the soil with a self-propelled vibratory roller.

In the field where the backfill space is too narrow to enter even small vibratory rollers, compactors or rammers can be used to compact the soil.

The repetition step is performed by repeating the above-described construction step, tensioning step, and backfilling step so that the prestress is applied at every predetermined height while increasing the construction height of the block body.

When the block body 2 is constructed to the desired height through a repeating step, the new tension member 14 is not connected. At this time, only a part of the upper hook 14a and the threaded portion 14c of the tension member 14 is exposed upward through the concave groove 10 in the uppermost block body 2, and then a finishing step is performed.

In the finishing step, the cap nut 16 is screwed into the upper hook 14a of the tension member 14 exposed to the concave groove 10 of the uppermost block body 2, screwed and tightened, and the final prestress is applied. This process is carried out to complete the desired retaining wall as shown in FIG.

1 is a perspective view of a block body applied to the reinforced earth retaining wall system of the present invention.

Figure 2 is a view explaining the construction process of the reinforced earth retaining wall system of the present invention.

Figure 3 is a side view for explaining the integral connection state of the tension members in the construction of the reinforced earth retaining wall system of the present invention.

Figure 4 is a side cross-sectional view showing a state of construction by the reinforced soil retaining wall system of the present invention.

* Description of the symbols for the main parts of the drawings *

2: block body 4: protrusion

6: recess 8: through hole

10: concave groove 12: convex portion

14: tension member 14a: upper hook

14b: lower hook 14c: threaded portion

16: cap nut 18: foundation concrete layer

Claims (5)

Protruding portions 4 and concave portions 6 which are engaged with other block bodies 2 which are laterally adjacent to each other are formed on both sides thereof, and the upper surface is provided with one or a pair of vertically formed through holes 8. A block body 2 formed of a convex portion 12 having an outer diameter that is recessed and formed as a concave groove 10 and an opposite bottom surface thereof can be accommodated as an inner diameter of the concave groove 10; A tension member 14 capable of being continuously connected in the axial direction by the cap nut 16 and penetrating through the through hole 8 of the block body 2; A block system for a shaft or retaining wall, which is configured to provide a prestress to the block body (2) by screwing between the tension member (14) and the cap nut (16). The method according to claim 1, The tension member 14 has hooks 14a and 14b formed on both ends in a symmetrical direction, and a threaded portion 14c to which the cap nut 20 is screwed is formed immediately below the upper hook 14a. Block system for an axis or retaining wall, characterized in that. The method according to claim 1, The length of the tension member (14) is a block system for a shaft or retaining wall, characterized in that set to any multiple of the height of the block body (2). The method according to any one of claims 1, 2, 3, The tension member (14) is a block system for the shaft or retaining wall, characterized in that consisting of one selected from the wire rod or rod. The block bodies 2 adjacent to the position where the foundation concrete layer is placed are arranged in a row so that the projections 4 and the recesses 6 on the side sides are connected to each other, and the caps are formed in the through holes 8 of the respective block bodies 2. A base placing step of installing the nut 16 through the tension member 14 inserted downward and then pouring the concrete to solidify integrally; The convex portion 12 of the upper block body 2 is the lower block body while passing through the through hole 8 of the other block body 2 with the tension member 14 exposed upwardly at each through hole 8 of the block body 2. Constructing step that is built to be connected to the concave groove 10 of (2) to be repeatedly stacked until the upper hook 14a of the tension member 18 is exposed to the concave groove 10 of the uppermost block body (2) Wow; A cap attached to the upper tension member 14 by engaging and connecting the lower hook 14b of the other tension member 14 to the upper hook 14a of the tension member 14 exposed by the concave groove 10 of the uppermost block body 2. A tensioning step of screwing and tightening the nut 16 to the threaded portion 14c of the lower tension member 14 to prestress the block body 2; A back filling step of back filling and compacting the soil behind the block body 2 to which the prestress is applied; A repeating step of building the block body 2 to a desired height by repeating the building step, the pulling step, and the back filling step; The cap nut 16 is screwed on the upper hook 14a of the tension member 14 exposed by the concave groove 10 of the uppermost block body 2, screwed and tightened, and a prestress is applied to the final block body 2, Backfill finishing step; A method for building a shaft system or retaining wall block system.

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