KR100654884B1 - Geogrid puller and method for covering soil using it - Google Patents

Abstract

The present invention relates to a geogrid tensioner for tensioning the geogrid used for the construction of the reinforcement earth retaining wall and the reinforcing slope, the first rod having a ring arranged at a predetermined interval on one side, and fixedly attached to both ends of the first rod It is formed with a second rod, wherein the second rod is formed on both ends of the wheel, and relates to a method for constructing the reinforcement soil retaining wall and the reinforcement slope using the geogrid tensioner thus formed.

Collar, Tensioner, Half Band, Laying

Description

Geogrid tensioning machine and construction method using it {GEOGRID PULLER AND METHOD FOR COVERING SOIL USING IT}

1 shows a geogrid tensioner according to the invention,

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a perspective view of a geogrid tensioner according to the present invention;

4 shows an embodiment of a geogrid tensioner according to the invention,

5 is another embodiment of a geogrid tensioner in accordance with the present invention;

6 and 7 illustrate a method of constructing a reinforced soil retaining wall and a reinforced slope using a geogrid tensioner according to the present invention.

* Description of Major Symbols in Drawings *

11: ring 12: rod 1

13: bar 2 14: wheels

15: bar 16, the third rod

20: Geogrid

The present invention relates to a geogrid tensioner for imparting tensile force to geogrids used in constructing reinforcement soil retaining walls and reinforcing slopes and a method of constructing the geogrid tensioner.

The reinforcement earth process using reinforcement has largely reinforced earth retaining wall and reinforcing slope, and the reinforcement earth retaining wall (MSEW) and reinforced steep / soil slopes (RSS) contain reinforcing material in the fill layer to make the soil dynamic. It is a method of constructing a structure by reinforcing. In this case, the reinforcing materials used include steel strips, high density polyethylene grids (HDPE), coated polyesterr grids (PVC), and the like, which are non-extension reinforcing materials.

Among these, with the development of the manufacturing method of the polymer material, a polymer-based reinforcing material, which is an economical and high-quality stretchable reinforcing material, is being developed at a rapid rate. In particular, HDPE grid is widely used because it has high chemical resistance, biological resistance, little damage during construction, and is integrally produced during production, and unlike weak fabrics, there is no weak point of joint strength. Such a geogrid has a network structure and is arranged horizontally in the soil layer. The use of such a grid has various advantages such as not only structural stability but also recycling of the excavated soil in the construction site, and construction of a block layer and soil work at the same time, which can shorten the air.

In general, soil in fill layer causes horizontal displacement with respect to vertical load. As such, in order to overcome the weakness of the soil having a small resistance to tension, the geogrid, which is the reinforcement described above, is put into the structure when constructing the retaining wall and the reinforcing slope. When geogrid, which is a reinforcement material, is placed in the fill layer, the horizontal displacement of the soil is suppressed by the frictional force between the soil and the reinforcement material moving horizontally with respect to the vertical load, and the reinforcement receives the tensile force and has a reinforcement effect.

 In order for these stiffeners to function effectively, displacement of the volume must occur when the soil is destroyed (that is, compaction above the critical gap ratio is required) and it must be installed evenly so that the stiffener can suppress this displacement. . If the reinforcing material is not folded or provided with tension, the reinforcing material may not be able to perform its function by failing to generate a tension force with the soil during the displacement of the earth.

In the case of reinforcing earth retaining wall and reinforcing slope construction, when the geogrid is installed, in order to impart a tensile force to the geogrid, in order to impart a tensile force to the geogrid by applying a foot or by pulling the geogrid by hand with a relatively rigid geogrid. However, the conventional method of tensioning the geogrid using such attraction force does not add uniform tensile force to the geogrid, and makes room for the soil to be displaced, so that the frontal reinforcement of the reinforcement soil such as the retaining soil retaining wall or the reinforcing slope is increased. It was to provide a cause to cause the phenomenon has the problem that the reinforcement soil is destroyed.

Accordingly, there is a need for an apparatus capable of providing uniform tensile force to the geogrid to overcome the above problems.

The present invention is to solve the above problems, and relates to a geogrid tensioner for tensioning the geogrid, which is a reinforcement used in the construction of the reinforcement earth retaining wall and reinforcement slope, and a method of constructing the reinforcement soil wall and reinforcement slope using the same will be.

In order to achieve the above object, the geogrid tensioner of the present invention is formed with a first rod having a ring arranged on one side at a predetermined interval, and a second rod fixedly attached to both end surfaces of the first rod, The two rods are configured such that wheels are formed at both ends thereof.                         

In order to achieve another object, a method of constructing a reinforced earth retaining wall using the geogrid of the present invention, the process of connecting the geogrid to the front surface, such as a modular block or concrete panel; Binding a geogrid tensioner to an end of the geogrid; Pulling the geogrid tensioner to maintain the geogrid taut; Fixing the pinned pin to the end of the taut geogrid; Laying down a predetermined soil on the geogrid and then slicing it evenly; And by repeating the above process to build a reinforcement body of the reinforcement earth retaining wall,

The method for constructing a reinforcing slope includes: mounting a geogrid on a guide frame such as a semi-, multi-, or reinforcing frame; Depositing soil on the geogrid at a predetermined height after the front surface treatment according to the front slope; Binding the geogrid tensioner to an end of the geogrid; Pulling the geogrid tensioner to maintain the geogrid taut; Fixing the pinned pin to the end of the taut geogrid; Laying down a predetermined soil on the geogrid and then slicing it evenly; And repeating the above-described process to build a reinforcement body of the reinforcing slope.

The above object of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings, by those skilled in the art.

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

Figure 1 shows a geogrid tensioner according to the invention, Figure 2 is a cross-sectional view of the A-A section of Figure 1, Figure 3 is a perspective view of the geogrid tensioner according to the present invention.

1 to 3, the geogrid tensioner 10 according to the present invention includes a first rod 12 having a ring 11 arranged at predetermined intervals on one side thereof, and the first rod 12. The second rod 13 is formed to be attached to both end surfaces of the second rod 13 is designed to be attached to the wheels 14 on both ends thereof.

The ring 11 is formed to have a predetermined interval so as to fit between the apertures of the mesh of the geogrid at the end of the geogrid 20 (shown in Figure 4). Therefore, the gap is preferably formed corresponding to the gap of the hole of the geogrid 20, the geogrid is formed in a different size and spacing of the hole for each manufacturer, so that a separate geogrid tensioner is formed for each specification It will be seen as unnecessary. Therefore, preferably, it is preferable to have a spacing of usually 2.0 cm to 2.5 cm so that it can be located in the middle of the hole in consideration of the spacing of the holes.

The ring 11 is formed in a shape that can be easily connected to the geogrid 20 network. Such a shape may be formed in various shapes such as a hemispherical shape or a rake shape as shown in FIG. 2. That is, the ring 11 of the geogrid tensioner 10 may be any shape as long as it is not constrained to a certain frame and can be easily hung on the mesh of the geogrid 20.

The ring 11 formed in the above-described form is attached to the first rod 12. The first rod 12 is formed as an annular rod, the second rod 13 is attached to both ends of the first rod 11, both ends of the second rod 13 of a predetermined thickness Allow wheels 14 to be attached. As shown in the cross section of FIG. 2, the radius of the second rod 13 is formed to be larger than the radius of the first rod 12. Preferably, the radius of the second rod 13 is preferably formed to be 2 to 3 times larger than the radius of the first rod 12. In addition, the length of the first rod 12 is formed differently according to the size of the geogrid 20, it is preferable to be uniformly formed in a length of 1m to 1.5m.

Wheels 14 having a predetermined thickness attached to both ends of the second rod 13 serve to easily move the geogrid tensioner 10 and are wound around the circumference of the second rod 13. It also serves to prevent the line 15 from falling out. In addition, the wheel 14 may be formed to rotate relative to the first rod (12).

The ring 11, the first rod 12, the second rod 13, and the wheel 14 constituting the geogrid tensioner 10 described above may be formed of steel sheets, steel pipes, PVC pipes, and other polymer composite materials. It can be used, but considering the strength and weight of the material, it is preferable to form a PVC pipe or other polymeric composite material.

3 and 4, the embodiment of the geogrid tensioner 10 according to the present invention will be described in detail, in addition to the above-described components, the geogrid tensioner 10, the second rod of the geogrid tensioner ( A string 15 is fixedly formed on the circumference of 13). By pulling the string 15 at both ends, a tensile force can be applied to the geogrid 20. However, in such a case, since the same force cannot be equally applied to both strings 15, an eccentricity is generated and the geogrid cannot be evenly spread.

In order to overcome this problem, the third rod 16 of a predetermined length is connected to both ends of the string 15, and the user pulls the third rod 16 to pull the geogrid 20. Keep it evenly taut. By using the geogrid tensioner 10 configured as described above, the geogrid 20 can be easily maintained in tension.

An embodiment using the geogrid tensioner 10 is shown in FIG. The string 15 is wound twice or three times on the circumference of the second rod 13 of the geogrid tensioner 10 to be tensioned. The reason why the wire 15 is wound in this way is that the wire 15 wound on the second rod 13 can be tensioned without applying an excessive force to the geogrid 20 by using a force that is loosened.

5 shows another embodiment of the present invention, the geogrid tensioner shown is a first rod 12 having rings 11 arranged at predetermined intervals on one side, such as the geogrid tensioner 10 described above. And a second rod 13 attached to both end surfaces of the first rod 12, wherein the wheel 14 is formed at one end surface of the second rod 13. do. The above-described embodiment has no features different from the first embodiment of the present invention except that the wheel is mounted only on one end face of the second rod 13.

The process of constructing a reinforced earth retaining wall or reinforcing slope using the geogrid tensioner 10 according to the present invention described above is as follows.

As shown in FIG. 6, when constructing the reinforced earth retaining wall using the geogrid tensioner 10, the geogrid is first connected to a front surface such as a modular block or a concrete panel. Then, using the ring 11 of the geogrid tensioner 10 to the hole of the net of the end of the geogrid 20 to bind to each other. After binding, a proper force is applied to the third rod 16 shown in FIG. 4 by the user's manpower to keep the geogrid 20 taut (S102). If the geogrid 20 is not kept taut, there is room for displacement of the soil. This phenomenon may cause a phenomenon in which the reinforcement soil collapses later. The taut geogrid 20 is fixed to the ground using a fixing pin, for example, rebar, wedge rods, etc. at the end thereof. After such a process is completed, a predetermined soil is laid on the geogrid 20, and then the process of compacting the soil is evenly carried out (S104), and the above-described process (S100 to S104) is repeated again to obtain soil at a desired height. To install the reinforcement earth retaining wall construction (S105).

7 shows a process of constructing a reinforcement slope using the geogrid tensioner 10. First, a process of seating the geogrid 20 on a guide frame such as a semi-rigid, multi-band, or reinforcing frame is performed (S100). After that, after the front surface treatment according to the front inclination, the step (S101) of laying the soil on the geogrid 20 to a predetermined height is carried out, and the geogrid 20 on the upper surface of the installed soil It seats and binds the geogrid tensioner 10 at its end. After binding, a proper force is applied to the third rod 16 shown in FIG. 4 by the user's attraction to keep the geogrid 20 taut (S102), and the taut geogrid 20 is maintained. Is fixed to the end of the geogrid 20 to the ground using a pin, for example, rebar, wedge rods and the like. After such a process is completed, a predetermined soil is laid on the geogrid 20, and then the process of compacting the soil is evenly carried out (S104), and the above-described process (S100 to S104) is repeated again to obtain soil at a desired height. Install the reinforcing slopes to be installed (S105).

In the case of pulling by using an excavator or the like to pull the geogrid tensioner 10, there is a possibility that excessive stress is applied to the geogrid 20, it is preferable to apply an appropriate force to the geogrid tensioner 10 by the user's manpower Do.

By using the geogrid tensioner as described above to properly tension the geogrid has the effect of suppressing the collapse of the soil laid during the construction of the reinforcement soil retaining wall and reinforcing slope.

The foregoing description relates to specific embodiments and can be easily understood by those of ordinary skill in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the claims. Could be.

Claims (8)

A first rod having a ring arranged at a predetermined interval on one side; Is formed with a second rod attached to both end surfaces of the first rod, The second rod is a geogrid tensioner, characterized in that the wheel is formed on one side or both end surfaces. The geogrid tensioner of claim 1, wherein the geogrid tensioner further comprises a string that is secured to the second rod. 3. The geogrid tensioner of claim 2, wherein the geogrid tensioner further comprises a third rod having a predetermined length to impart a balanced tension to the geogrid at both ends of the string. The geogrid tensioner of claim 1, wherein the aperture of the second rod is larger than the aperture of the first rod. The geogrid tensioner of claim 1, wherein the geogrid tensioner is formed of any one of a steel sheet, a steel pipe, a PVC pipe, and a polymer composite material. Connecting a geogrid to a front face such as a modular block or concrete panel; Binding a ring of geogrid tensioner to an end of the geogrid; Pulling the geogrid tensioner to maintain the geogrid taut; Fixing the pinned pin to the end of the taut geogrid; Laying down a predetermined soil on the geogrid and then slicing it evenly; And Reinforced soil construction method using a geogrid tensioner characterized in that for constructing the reinforcement soil of the retaining wall retaining wall by repeating the above process. Mounting a geogrid on a guide frame such as a semi-, multi-, or reinforcing frame; Depositing soil on the geogrid at a predetermined height after the front surface treatment according to the front slope; Binding a ring of geogrid tensioner to the geogrid end; Pulling the geogrid tensioner to maintain the geogrid taut; Fixing the pinned pin to the end of the taut geogrid; Laying down a predetermined soil on the geogrid and then slicing it evenly; And Reinforced soil construction method using a geogrid tensioner characterized in that to construct a reinforcement soil of the reinforcement slope by repeating the above process. The method according to claim 6 or 7, wherein the fixing pin is a wedge rod, reinforcement earth construction method using a geogrid tensioner, characterized in that any one of the rebar.

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