KR20230030596A - Temporary earth retaining facility using guide bracket and ground anchor and its construction method - Google Patents

Abstract

The present invention is to provide a retaining facility using a guide bracket and a ground anchor for constructing a retaining facility regardless of before and after excavation even in a narrow space in a downtown area, and a construction method thereof. The retaining facility using a guide bracket and a ground anchor according to the present invention includes a cast-in-place concrete pile; a waling; a guide bracket; and a ground anchor.

Description

Temporary earth retaining facility using guide bracket and ground anchor and its construction method}

The present invention relates to a temporary earth retaining facility using a guide bracket and a ground anchor and a method for constructing the same, in particular, after constructing a cast-in-place concrete pile on the ground and inserting a ground anchor or load-bearing body into the ground of the cast-in-place concrete pile, After installing a wale with a guide bracket across the poured concrete pile, fixing the single-strand tension member or double-strand tension member to the guide bracket, and then tensioning the single-strand tension member or double-strand tension member, separate support material on the excavation side Even without installation, there is no risk of piles falling or collapsing into the excavation space, and temporary earth retaining facilities using guide brackets and ground anchors that enable easy excavation work safely and at low cost even in narrow spaces in downtown areas. It's about the construction method.

For the construction of underground structures, earth retaining structures are installed around the work area, which include thumb pile earth walls, diaphragm walls, sheet piles, and CIP. A variety of techniques are being applied.

Such a conventional earth retaining method has the following problems.

In the case of excavation work, since the retaining wall alone cannot resist the earth pressure of the background soil, a large number of support materials (Strut, Earth Anchor, Raker, etc.) must be used to reinforce it.

However, this support material reinforcement method is uneconomical, and in the case of the strut method, it is difficult to secure a working space, and the earth anchor method has a disadvantage that construction is impossible when the free space of the site is small.

Registered Patent No. 10-1498711

Accordingly, the present invention has been made to solve the above-mentioned problems, and after constructing a cast-in-place concrete pile on the ground, inserting a ground anchor or load bearing body into the ground of the cast-in-place concrete pile, After installing the wale with the guide bracket attached across the pile, fixing the single-strand tension member or double-strand tension member to the guide bracket, and then tensioning the single-strand tension member or double-strand tension member to install a separate support member on the excavation side. There is no concern about the earth retaining wall falling into the excavation space or collapsing even without it, and even in a narrow space in the downtown area, regardless of the widening of the ground site on the back side of the cast-in-place concrete pile, as well as temporary earth retaining facilities regardless of before and after excavation The purpose is to provide a temporary retaining facility and its construction method using a guide bracket and a ground anchor to build a.

The retaining facility using the guide bracket and the ground anchor according to the present invention for achieving the above object includes a cast-in-place concrete pile; A wale sheet disposed across the cast-in-place concrete pile; a guide bracket installed at a predetermined position of the wale; It is characterized in that the single-strand tension member is wound on the guide bracket and the other side is composed of a ground anchor fixed to the ground.

In addition, the retaining facility using the guide bracket and the ground anchor according to the present invention for achieving the above object includes a cast-in-place concrete pile; A wale sheet disposed across the cast-in-place concrete pile; a guide bracket installed at a predetermined position of the wale; It is characterized in that the double-stranded tension member is wound around the guide bracket and the lower body is fixed to the ground at the same time as the other side.

In addition, the method for constructing a retaining facility using a guide bracket and a ground anchor according to the present invention for achieving the above object includes a cast-in-place concrete pile; A wale sheet disposed across the cast-in-place concrete pile; a guide bracket installed at a predetermined position of the wale; As a method of constructing a retaining facility using a ground anchor and a guide bracket composed of a ground anchor in which a single-strand tension member is wound on the guide bracket and the other side is fixed to the ground at the same time, constructing a cast-in-place concrete pile on the ground; Forming a drilling hole by drilling the ground of the cast-in-place concrete pile; Inserting and fixing a ground anchor into the drilling hole; Installing a wale to which a guide bracket is attached across the cast-in-place concrete pile; Fixing the single-stranded tension member installed on the ground anchor to the guide bracket; It is characterized in that it consists of the step of tensioning the single-stranded tension member with a constant tension.

In addition, the method for constructing a retaining facility using a guide bracket and a ground anchor according to the present invention for achieving the above object includes a cast-in-place concrete pile; A wale sheet disposed across the cast-in-place concrete pile; a guide bracket installed at a predetermined position of the wale; A method of constructing a retaining facility using a ground anchor and a guide bracket composed of a lower body in which a double-stranded tension member is wound around the guide bracket and the other side is fixed to the ground at the same time, Constructing a cast-in-place concrete pile on the ground; Forming a drilling hole by drilling the ground of the cast-in-place concrete pile; Inserting and fixing the lower body into the perforation hole; Installing a wale to which a guide bracket is attached across the cast-in-place concrete pile; fixing the double-strand tension member installed on the lower body to a guide bracket; It is characterized in that it consists of the step of tensioning the double-strand tension member with a constant tension.

As described above, the retaining facility and its construction method using the guide bracket and ground anchor according to the present invention have the following effects.

First, the present invention installs a guide bracket on the wale, installs a single-strand tension member or double-strand tension member of the ground anchor on the guide bracket, fixes it in the middle of the wale, and then tensions the single-strand tension member or double-strand tension member By applying the load on the back side of the cast-in-place concrete pile to the middle of the wale, there is an advantage that there is no risk of the cast-in-place concrete pile falling into the excavation space or collapsing without installing a separate support on the excavation side.

Second, the present invention has the effect of constructing an earth retaining facility regardless of the wide area of the ground site on the back side of the cast-in-place concrete pile even in a narrow space in the downtown area, as well as before and after excavation.

Third, in the present invention, the ground anchor or lower body is installed at a deeper depth than the cast-in-place concrete pile, and the single-stranded tension member combined with the ground anchor or the double-stranded tension member combined with the lower body stretches the middle of the wale to the outside of the excavation space. By being tensioned, it has the advantage of relieving concerns such as the fall or collapse of the cast-in-place concrete pile into the excavation space.

Fourth, since the present invention can minimize the installation of support materials or wales on the excavation side, it is easy to secure a work space and has an advantage of improving workability.

1 is a perspective view 1 showing a retaining facility using a guide bracket and a ground anchor according to the present invention;
2 is a front view 1 showing a retaining facility using a guide bracket and a ground anchor according to the present invention;
3 is a plan view 1 showing a retaining facility using a guide bracket and a ground anchor according to the present invention;
Figure 4 is a cross-sectional view 1 showing a retaining facility using a guide bracket and a ground anchor according to the present invention;
5 is an exploded perspective view 1 showing a retaining facility using a guide bracket and a ground anchor according to the present invention;
6 is a perspective view 1 showing a guide bracket of a retaining facility using a guide bracket and a ground anchor according to the present invention;
7 is a front view 1 showing a guide bracket of a retaining facility using a guide bracket and a ground anchor according to the present invention;
8 is a plan view 1 showing a guide bracket of a retaining facility using a guide bracket and a ground anchor according to the present invention;
9 is a side view 1 showing a guide bracket of a retaining facility using a guide bracket and a ground anchor according to the present invention;
10 is a construction diagram 1 showing a state of constructing a retaining facility using a guide bracket and a ground anchor according to the present invention;
11 is a perspective view 2 showing a retaining facility using a guide bracket and a ground anchor according to the present invention;
12 is a front view 2 showing a temporary earth retaining facility using a guide bracket and a ground anchor according to the present invention;
13 is a plan view 2 showing a retaining facility using a guide bracket and a ground anchor according to the present invention;
14 is a cross-sectional view 2 showing a retaining facility using a guide bracket and a ground anchor according to the present invention;
15 is an exploded perspective view 2 showing a retaining facility using a guide bracket and a ground anchor according to the present invention;
16 is a perspective view 2 showing a guide bracket of a retaining facility using a guide bracket and a ground anchor according to the present invention;
17 is a front view 2 showing a guide bracket of a retaining facility using a guide bracket and a ground anchor according to the present invention;
18 is a plan view 2 showing a guide bracket of a retaining facility using a guide bracket and a ground anchor according to the present invention;
19 is a side view 2 showing a guide bracket of a retaining facility using a guide bracket and a ground anchor according to the present invention;
Figure 20 is a construction diagram showing a state of constructing a temporary retaining facility using a guide bracket and a ground anchor according to the present invention 2.

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

[Example 1]

[Temporary retaining facility using guide brackets and ground anchors]

1 is a perspective view 1 showing a temporary retaining facility using a guide bracket and a ground anchor according to the present invention, Figure 2 is a front view 1 showing a temporary retaining facility using a guide bracket and a ground anchor according to the present invention, Figure 3 is the present invention 1 and 4 are cross-sectional views showing temporary retaining facilities using guide brackets and ground anchors according to the present invention, and FIG. 5 is a guide bracket and ground according to the present invention. It is an exploded perspective view 1 showing a retaining facility using an anchor.

As shown in these drawings, the retaining facility (P) using the guide bracket and ground anchor according to the present invention includes a cast-in-place concrete pile (100); A wale 200 disposed across the cast-in-place concrete pile 100; a guide bracket 300 installed at a predetermined position of the wale 200; It consists of a ground anchor 400 in which the single-strand tension member 420 is wound around the guide bracket 300 and the other side is fixed to the ground G.

That is, the retaining facility (P) using the guide bracket and the ground anchor according to the present invention is a structure formed by organically combining the cast-in-place concrete pile 100, the wale 200, the guide bracket 300, and the ground anchor 400 am.

Here, the cast-in-place concrete pile (CIP, 100) is a pile manufactured by excavating the ground with an auger to form a drilling hole, inserting a reinforcing bar network or H beam into the drilling hole, and then casting and curing the concrete. .

In addition, the wale 200 is composed of any one of a section steel, an H section, an I section, a c section, a section, a steel pipe, a hollow pipe, a round steel pipe, a rectangular pipe, and a section.

In particular, the section steel is a general term for long steel pre-formed into a certain cross-sectional shape such as H-type and L-type, and is mainly used for civil engineering, architectural pillars or beams, foundation piles and mechanical products, and there are various types of section steel depending on the shape of the cross section. , depending on the epidemiological rationality and purpose of use.

In addition, the H-beam is made by hot rolling with an H-shaped cross section widely used in the framework of large structures such as buildings and ships or civil engineering works.

Here, the part corresponding to the horizontal bar in the center of the H-beam is called the web, and the part corresponding to the vertical bar on both sides is called the upper and lower flanges. .

In addition, there is an I-beam with a cross section similar to the H-beam. In the H-beam, the thickness of the upper and lower flanges is constant to the end, the tip of the upper and lower flanges are not rounded, and in the I-beam, the width is smaller than the height H-beams are different in that some have width equal to height.

The wide flange H-beam is called wide flange H-beam, and its overall cross section is square, making it easy to use as a pillar of a building.

Standards are specified in KS D 3503, and shapes and dimensions are specified in KS D 3051.

On the other hand, the steel pipe is a building material made of an alloy of iron and carbon, and means that the cross section is a hollow circular pipe or rectangular pipe, and it is revealed that a square pipe and pipes of various shapes can be used as needed.

In particular, it is clarified that no special technical requirements are required in using circular tubes as various tubes such as square tubes and closed tubes.

The guide bracket 300 includes a support plate 310 having a certain thickness and width; a vertical plate 320 extending at right angles from both ends of the support plate 310; a horizontal plate 330 extending at right angles from the vertical plate 320; It consists of a semicircular fixing pulley 340 coupled between the horizontal plates 330.

That is, in the guide bracket 300, a plurality of steel plates 310, 320, and 330 are bent to form a bracket, and a semicircular fixing pulley 340 is installed on the bracket.

Here, the single-strand tension member 420 is caught on the semi-circular fixing pulley 340 and passed between the vertical plates 320, and the angle of the single-strand tension member 420 is changed from vertical to horizontal by the semi-circular fixing pulley 340. It is formed to extend to the side of the wale (200).

In addition, the ground anchor 400 includes an anchor body 410 having a constant weight disposed at the lower end; It is composed of a single-strand tension member 420 having one side embedded in the anchor body 410 and simultaneously drawing a certain length to the other side.

That is, the ground anchor 400 has a structure in which the anchor body 410 and the single-strand tension member 420 are organically coupled.

Here, the anchor body 410 is disposed at the bottom and is a structure having a constant weight.

In addition, the single strand tension member 420 is fixed to the guide bracket 300, and the other side is fixedly installed to the anchor body 410 fixed to the ground (G).

In addition, the single-strand tension member 420 may be accommodated in the sheath in an elastic manner.

The ground anchor 400 is installed vertically or inclined to the opposite side of the cast-in-place concrete pile 100 in the ground G on the back side of the cast-in-place concrete pile 100.

The inclination angle of the ground anchor 400 maintains an angle (0 ° to 20 °) that does not exceed the site boundary based on 0 °.

In the ground anchor 400 described above, the lower part is fixed to the anchor body 410 in a state in which tension is introduced into the single-stranded tension member 420, and the upper part is fixed to the middle part of the wale 200 through the guide bracket 300. do.

Here, a straight ground activity line (L) of about 20 to 45 ° at the depth of the excavation area can be assumed in the ground (G) around the excavation area where the ground anchor 400 is installed. The anchor body 410 of is installed in a deeper position (stable area) than the ground activity line (L).

Accordingly, the tension force of the ground anchor 400 can be stably exerted.

In addition, the ground anchor 400 to which tension is applied extends upward from the ground on the back side of the cast-in-place concrete pile 100 to the side of the cast-in-place concrete pile 100 at a predetermined angle of 0 ° to 20 ° in an inclined state or in a vertical state. And it is bent at an obtuse angle, for example, 90° to 110° in the semicircular fixing pulley 340, and extends toward the middle portion of the wale length 200.

Here, the ground anchor 400 applies a horizontal force to the middle portion of the wale 200 by taking a reaction force in a vertical direction and a reaction force in a horizontal direction to the ground G through the guide bracket 300.

As a result, since the load in the direction in which the cast-in-place concrete pile 100 collapses to the ground G on the back side acts on the cast-in-place concrete pile 100, the moment and deformation in the direction of collapse in the excavation area of the cast-in-place concrete pile 100 are alleviated and the field The collapse of the poured concrete pile 100 toward the excavation area is prevented.

The earth retaining facility (P) using the guide bracket and the ground anchor according to the present invention having the configuration as described above installs the ground anchor 400 on the back side ground (G) of the cast-in-place concrete pile 100, and the site A wale strip 200 is installed on the poured concrete pile 100, a guide bracket 300 is installed on the wale strip 200, and the single-strand tension member 420 of the ground anchor 400 is installed on the guide bracket 300. After installation, by tensioning the single-stranded tension member 420 and applying a load on the back side of the cast-in-place concrete pile 100 to the middle of the wale 200, the site does not require a separate support member to be installed on the excavation side. Not only is there no risk of the poured concrete pile 100 falling or collapsing into the excavation space, but it is also possible to safely excavate the excavation work in a narrow space in the downtown area at low cost.

[Method of constructing temporary earth retaining facility]

10 is a construction diagram 1 showing a state of constructing a retaining facility using a guide bracket and a ground anchor according to the present invention.

As shown in this figure, the method of constructing a retaining facility using a guide bracket and a ground anchor according to the present invention comprises the steps of constructing a cast-in-place concrete pile 100 on the ground (G); Forming a drilling hole by drilling the ground of the cast-in-place concrete pile 100; Inserting and fixing a ground anchor into the drilling hole; Installing a wale 200 to which a guide bracket 300 is attached across the cast-in-place concrete pile 100; Fixing the single-strand tension member 420 installed on the ground anchor 400 to the guide bracket 300; It consists of a step of tensioning the single-strand tension member 420 with a constant tension.

That is, in the method of constructing a retaining facility using a guide bracket and a ground anchor according to the present invention, a cast-in-place concrete pile 100 is constructed on the ground (G), and the ground (G) of the cast-in-place concrete pile 100 is auger, etc. After excavating with an excavator to form a drilling hole, inserting and fixing the ground anchor 400 in the drilling hole, the wale 200 with the guide bracket 300 attached across the cast-in-place concrete pile 100 After installing, the single-strand tension member 420 installed on the ground anchor 400 is fixed to the guide bracket 300, but the single-strand tension member 420 of the ground anchor 400 is placed in a semicircular shape of the guide bracket 300. The load on the ground on the rear side of the middle part of the wale 200 by the anchorage in the state where it is hung on the fixing pulley 340, the semicircular fixing pulley 340 is fixed, and the single-stranded tension member 420 is introduced with a tension force. is to grant

Here, the ground anchor 400 is installed on the ground (G) on the outer circumferential side of the excavation area.

Subsequently, a guide bracket 300 is installed on the wale 200 on the outer circumference of the excavation area.

Subsequently, the single-strand tension member 420 of the ground anchor 400 is hung on the semi-circular fixing pulley 340 of the guide bracket 300, the semi-circular fixing pulley 340 is fixed, and the single-strand tension member 420 It is fixed to the middle part of the wale 200 by the anchorage in the state where the tension force is introduced.

That is, the single-strand tension member 420 of the ground anchor 400 fixed in the middle of the wale 200 is turned to a horizontal state in the semicircular fixing pulley 340 of the guide bracket 300 installed on the wale 200 .

By this, it is possible to install the ground anchor 400 to a deep position in the ground after suppressing the distance in the horizontal direction from the wale 200 of the ground anchor 400.

Therefore, the cast-in-place concrete pile is moved to the excavation area of the cast-in-place concrete pile 100 by applying a horizontal force to the middle of the wale 200 regardless of the wide narrowing of the ground (G) site on the back side of the cast-in-place concrete pile 100. It is possible to install a ground anchor 400 that prevents the collapse of the 100.

In addition, the single-strand tension member 420 of the ground anchor 400 for connecting the ground anchor 400 to the middle of the wale 200 is installed on the guide bracket 300 installed in the middle of the wale 200. By doing so, there is no need to expose the surface of the cast-in-place concrete pile 100.

Therefore, the ground anchor 400 can be installed regardless of before and after excavation in the excavation area.

In addition, as described above, the ground anchor may be inclined to the opposite side of the cast-in-place concrete pile, or it may be vertical, or the cast-in-place concrete pile itself may be inclined.

In the method of constructing a temporary retaining facility using a guide bracket and a ground anchor according to the present invention consisting of the steps described above, a temporary retaining facility using a guide bracket and a ground anchor ( P) is inserted, fixed with cement milk, and after fixing the single-strand tension member 420 installed on the ground anchor 400 to the guide bracket 300, the single-strand tension member 420 is tensioned with a constant tension to form a wale. By applying a load to the back-side ground (G) in the middle of (200), the cast-in-place concrete pile 100 falls into the excavation space or collapses without installing a separate support material on the excavation side Concerns such as In addition, it is possible to carry out excavation work safely and at low cost even in a narrow space in the downtown area.

In addition, the ground anchor 400 is installed at a depth deeper than the cast-in-place concrete pile 100, and the single-strand tension member 420 combined with the ground anchor 400 tensions the middle part of the wale 200 to the outside of the excavation space. By being tensioned, there is an advantage in that the cast-in-place concrete pile 100 can eliminate concerns such as falling or collapsing into the excavation space.

In addition, since the installation of supports or wales on the excavation side can be minimized, it is easy to secure a working space and has the advantage of improving workability.

[Example 2]

[Temporary retaining facility using guide brackets and ground anchors]

Figure 11 is a perspective view 2 showing a retaining facility using a guide bracket and a ground anchor according to the present invention, Figure 12 is a front view 2 showing a temporary retaining facility using a guide bracket and a ground anchor according to the present invention, Figure 13 is the present invention Plan view 2 showing a temporary retaining facility using a guide bracket and ground anchor according to the present invention, Figure 14 is a cross-sectional view showing a temporary retaining facility using a guide bracket and ground anchor according to the present invention 2, Figure 15 is a guide bracket and ground according to the present invention It is an exploded perspective view 2 showing a retaining facility using an anchor.

As shown in these drawings, the retaining facility (P) using the guide bracket and ground anchor according to the present invention includes a cast-in-place concrete pile (100); A wale 200 disposed across the cast-in-place concrete pile 100; a guide bracket 300 installed at a predetermined position of the wale 200; The guide bracket 300 is composed of a lower body 500 in which the double-strand tension member 430 is wound and the other side is fixed to the ground G.

That is, the retaining facility (P) using the guide bracket and the ground anchor according to the present invention is a structure formed by organically combining the cast-in-place concrete pile 100, the wale 200, the guide bracket 300, and the lower body 500 am.

Here, the cast-in-place concrete pile (CIP, 100) is a pile manufactured by excavating the ground with an auger to form a drilling hole, inserting a reinforcing bar network or H beam into the drilling hole, and then casting and curing the concrete. .

In addition, the wale 200 is composed of any one of a section steel, an H section, an I section, a c section, a section, a steel pipe, a hollow pipe, a round steel pipe, a rectangular pipe, and a section.

In particular, the section steel is a general term for long steel pre-formed into a certain cross-sectional shape such as H-type and L-type, and is mainly used for civil engineering, architectural pillars or beams, foundation piles and mechanical products, and there are various types of section steel depending on the shape of the cross section. , depending on the epidemiological rationality and purpose of use.

In addition, the H-beam is made by hot rolling with an H-shaped cross section widely used in the framework of large structures such as buildings and ships or civil engineering works.

Here, the part corresponding to the horizontal bar in the center of the H-beam is called the web, and the part corresponding to the vertical bar on both sides is called the upper and lower flanges. .

In addition, there is an I-beam with a cross section similar to the H-beam. In the H-beam, the thickness of the upper and lower flanges is constant to the end, the tip of the upper and lower flanges are not rounded, and in the I-beam, the width is smaller than the height H-beams are different in that some have width equal to height.

The wide flange H-beam is called wide flange H-beam, and its overall cross section is square, making it easy to use as a pillar of a building.

Standards are specified in KS D 3503, and shapes and dimensions are specified in KS D 3051.

On the other hand, the steel pipe is a building material made of an alloy of iron and carbon, and means that the cross section is a hollow circular pipe or rectangular pipe, and it is revealed that a square pipe and pipes of various shapes can be used as needed.

In particular, it is clarified that no special technical requirements are required in using circular tubes as various tubes such as square tubes and closed tubes.

The guide bracket 300 includes a support plate 310 having a certain thickness and width; a vertical plate 320 extending at right angles from both ends of the support plate 310; a horizontal plate 330 extending at right angles from the vertical plate 320; It consists of a semicircular fixing pulley 340 coupled between the horizontal plates 330.

That is, in the guide bracket 300, a plurality of steel plates 310, 320, and 330 are bent to form a bracket, and a semicircular fixing pulley 340 is installed on the bracket.

Here, the double-strand tension member 430 is caught on the semi-circular fixing pulley 340 and passed between the vertical plates 320, and the angle of the double-strand tension member 430 is changed from vertical to horizontal by the semi-circular fixing pulley 340. It is formed to extend to the side of the wale (200).

And, the lower body 500 is a structure having a constant weight disposed at the lower end.

It is composed of a double-stranded tension member 430 having one side embedded in the lower body 500 and at the same time drawing a certain length to the other side.

That is, it has a structure in which the double-strand tension member 430 is organically coupled to the lower body 500.

Here, the lower body 500 is disposed at the lowermost end and is a structure having a constant weight.

In addition, the double-strand tension member 430 is fixed to the guide bracket 300, and the other side is fixed to the lower body 500 fixed to the ground (G).

Also, the double-strand tension member 430 may be accommodated in the sheath in an elastic manner.

The lower body 500 is installed vertically or inclined to the opposite side of the cast-in-place concrete pile 100 on the ground (G) on the rear side of the cast-in-place concrete pile 100.

The inclination angle of the lower body 500 maintains an angle (0° to 20°) that does not exceed the site boundary based on 0°.

The inner lower body 500 is fixed to the inner lower body 500 in a state where tension is applied to the double-strand tension member 430, and the upper part is fixed to the middle portion of the wale 200 through the guide bracket 300.

Here, a straight ground activity line (L) of about 20 to 45 ° at the depth of the excavation area can be assumed in the ground (G) around the excavation area where the lower body 500 is installed. is installed in a deeper position (stable area) than the ground activity line (L).

Accordingly, the tension force of the lower body 500 can be stably exerted.

In addition, the lower body 500 to which tension is applied extends upward from the ground on the rear side of the cast-in-place concrete pile 100 to the side of the cast-in-place concrete pile 100 at a predetermined angle of 0° to 20° or in a vertical state. And it is bent at an obtuse angle, for example, 90° to 110° in the semicircular fixing pulley 340, and extends toward the middle portion of the wale length 200.

Here, the lower body 500 applies a horizontal force to the middle portion of the wale 200 by taking a reaction force in a vertical direction and a reaction force in a horizontal direction to the ground G through the guide bracket 300.

As a result, since the load in the direction in which the cast-in-place concrete pile 100 collapses to the ground G on the back side acts on the cast-in-place concrete pile 100, the moment and deformation in the direction of collapse in the excavation area of the cast-in-place concrete pile 100 are alleviated and the field The collapse of the poured concrete pile 100 toward the excavation area is prevented.

The earth retaining facility (P) using the guide bracket and ground anchor according to the present invention having the configuration as described above installs the lower body 500 on the back side ground (G) of the cast-in-place concrete pile 100, and the site A wale strip 200 is installed on the cast concrete pile 100, a guide bracket 300 is installed on the wale strip 200, and the double-stranded tension member 430 of the lower body 500 is installed on the guide bracket 300. After installation, the double-stranded tension member 430 is tensioned to apply a load on the back side of the cast-in-place concrete pile 100 to the middle of the wale 200, so that a separate support member is not installed on the excavation side. Not only is there no risk of the poured concrete pile 100 falling or collapsing into the excavation space, but it is also possible to safely excavate the excavation work in a narrow space in the downtown area at low cost.

[Method of constructing temporary earth retaining facility]

20 is a construction diagram 2 showing a state of constructing a retaining facility using a guide bracket and a ground anchor according to the present invention.

As shown in this figure, the method for constructing a retaining facility using a guide bracket and a ground anchor according to the present invention includes a cast-in-place concrete pile 100; A wale 200 disposed across the cast-in-place concrete pile 100; A guide bracket 300 installed at a predetermined position of the wale 200; As a method of constructing a temporary retaining facility using a guide bracket and a ground anchor composed of a lower body 500 in which the double-stranded tension member 430 is wound around the guide bracket 300 and the other side is fixed to the ground G, (G) constructing a cast-in-place concrete pile 100; Forming a drilling hole by drilling the ground (G) of the cast-in-place concrete pile (100); Inserting and fixing the lower body 500 into the perforation hole; Installing a wale 200 to which a guide bracket 300 is attached across the cast-in-place concrete pile 100; fixing the double-strand tension member 430 installed on the lower body 500 to the guide bracket 300; It consists of a step of tensioning the double-strand tension member 430 with a constant tension.

That is, in the method of constructing a retaining facility using a guide bracket and a ground anchor according to the present invention, a cast-in-place concrete pile 100 is constructed on the ground (G), and the ground (G) of the cast-in-place concrete pile 100 is auger, etc. After excavating with an excavator to form a drilling hole, inserting and fixing the lower body 500 in the drilling hole, and then crossing the cast-in-place concrete pile 100, the guide bracket 300 is attached to the wale 200 After installing, the double-stranded tension member 430 installed on the lower body 500 is fixed to the guide bracket 300, but the double-stranded tension member 430 of the lower body 500 has a semicircular shape of the guide bracket 300. Load on the ground on the rear side of the middle part of the wale 200 by the anchorage in a state where it is hung on the fixing pulley 340, the semicircular fixing pulley 340 is fixed, and tension is applied to the double-stranded tension member 430. is to grant

Here, the lower body 500 is installed on the ground G on the outer circumferential side of the excavation area.

Subsequently, a guide bracket 300 is installed on the wale 200 on the outer circumference of the excavation area.

Subsequently, the double-strand tension member 430 of the lower body 500 is hung on the semi-circular fixing pulley 340 of the guide bracket 300, the semi-circular fixing pulley 340 is fixed, and the double-strand tension member 430 It is fixed to the middle part of the wale 200 by the anchorage in the state where the tension force is introduced.

That is, the double-stranded tension member 430 of the inner lower body 500 fixed in the middle of the wale 200 is turned to a horizontal state in the semicircular fixing pulley 340 of the guide bracket 300 installed on the wale 200. .

Accordingly, it is possible to install the lower body 500 to a depth in the ground after suppressing the horizontal distance of the lower body 500 from the wale 200.

Therefore, the cast-in-place concrete pile is moved to the excavation area of the cast-in-place concrete pile 100 by applying a horizontal force to the middle of the wale 200 regardless of the wide narrowing of the ground (G) site on the back side of the cast-in-place concrete pile 100. It is possible to install the lower body 500 that prevents the collapse of the 100.

In addition, by installing the double-strand tension member 430 of the inner lower body 500 to connect the inner lower body 500 to the middle part of the wale 200 on the guide bracket 300 installed in the middle of the wale 200, , there is no need to expose the surface of the cast-in-place concrete pile 100.

Therefore, the lower body 500 can be installed regardless of before and after excavation in the excavation area.

In addition, as described above, the lower body 500 may be inclined to the opposite side of the cast-in-place concrete pile, or may be vertical, or the cast-in-place concrete pile itself may be inclined.

The retaining facility construction method using the guide bracket and the ground anchor according to the present invention consisting of the steps described above is to drill the ground (G) to form a drilling hole, and use the guide bracket and the lower body 500 in the drilling hole After inserting the temporary earth retaining facility (P) and fixing it with cement milk, fixing the double-strand tension member 430 installed on the lower body 500 to the guide bracket 300, the double-strand tension member 430 with a constant tension By tensioning and applying a load to the back side ground (G) in the middle of the wale 200, the cast-in-place concrete pile 100 falls into the excavation space or collapses without installing a separate support material on the excavation side. Not only is there no risk of damage, but it is also possible to safely excavate in a narrow space in the downtown area at low cost and easily.

In addition, the lower body 500 is installed at a depth deeper than the cast-in-place concrete pile 100, and the double-stranded tension member 430 combined with the lower body 500 tensions the middle part of the wale 200 to the outside of the excavation space. By being tensioned, there is an advantage in that the cast-in-place concrete pile 100 can eliminate concerns such as falling or collapsing into the excavation space.

In addition, since the installation of supports or wales on the excavation side can be minimized, it is easy to secure a working space and has the advantage of improving workability.

Preferred embodiments described in the detailed description of the present invention are illustrative and not limiting, the scope of the present invention is shown by the appended claims, and all modifications that fall within the meaning of those claims do not apply to the present invention. will be included

100: cast-in-place concrete pile 120: web
130: flange 200: wale
300: guide bracket
310: support plate 320: vertical plate
330: cover plate 340: bottom plate
350: semicircular fixed pulley 400: ground anchor
410: anchor body 420: single-stranded tension member
430: double strand tension member 500: lower body
G: ground L: ground action line
P: Earth retaining facility using guide brackets and ground anchors

Claims (10)

A cast-in-place concrete pile 100;
A wale 200 disposed across the cast-in-place concrete pile 100;
a guide bracket 300 installed at a predetermined position of the wale 200;
A retaining facility using a guide bracket and a ground anchor, characterized in that the single-strand tension member 420 is wound around the guide bracket 300 and the ground anchor 400 is fixed and fixed to the ground at the same time as the other side. According to claim 1,
The wale 100 is a retaining facility using a guide bracket and a ground anchor, characterized in that it is composed of any one of a section steel and a steel pipe. According to claim 1,
The guide bracket 300 includes a support plate 310 having a certain thickness and width; a vertical plate 320 extending at right angles from both ends of the support plate 310; a horizontal plate 330 extending at right angles from the vertical plate 320; Earth retaining facility using a guide bracket and a ground anchor, characterized in that composed of a semicircular fixing pulley 340 coupled between the horizontal plates 330. According to claim 1,
The ground anchor 400 includes an anchor body 410 having a constant weight disposed at the lower end; An earth retaining facility using a guide bracket and a ground anchor, characterized in that it consists of a single-stranded tension member 420 in which one side is embedded in the anchor body 410 and a certain length is drawn to the other side. A cast-in-place concrete pile 100;
A wale 200 disposed across the cast-in-place concrete pile 100;
a guide bracket 300 installed at a predetermined position of the wale 200;
Earth retaining facility using a guide bracket and a ground anchor, characterized in that the double-stranded tension member 430 is wound around the guide bracket 300 and the other side is composed of an inner lower body 500 fixed to the ground (G). According to claim 5,
The wale 100 is a retaining facility using a guide bracket and a ground anchor, characterized in that it is composed of any one of a section steel and a steel pipe. According to claim 5,
The guide bracket 300 includes a support plate 310 having a certain thickness and width; a vertical plate 320 extending at right angles from both ends of the support plate 310; a horizontal plate 330 extending at right angles from the vertical plate 320; Earth retaining facility using a guide bracket and a ground anchor, characterized in that composed of a semicircular fixing pulley 340 coupled between the horizontal plates 330. A cast-in-place concrete pile 100;
A wale 200 disposed across the cast-in-place concrete pile 100;
a guide bracket 300 installed at a predetermined position of the wale 200;
A method of constructing a retaining facility using a guide bracket and a ground anchor composed of a ground anchor 400 in which a single-stranded tension member 420 is wound around the guide bracket 300 and the other side is fixed to the ground G,
Constructing a cast-in-place concrete pile 100 on the ground (G);
Forming a drilling hole by drilling the ground of the cast-in-place concrete pile 100;
Inserting and fixing a ground anchor 400 into the drilling hole;
Installing a wale 200 to which a guide bracket 300 is attached across the cast-in-place concrete pile 100;
Fixing the single-strand tension member 420 installed on the ground anchor 400 to the guide bracket 300;
The method of constructing a retaining facility using a guide bracket and a ground anchor, characterized in that it consists of the step of tensioning the single-stranded tension member 420 with a constant tension. According to claim 8,
Earth retaining facility construction method using a guide bracket and a ground anchor, characterized in that the ground anchor 400 is vertically installed in the same direction as the cast-in-place concrete pile 100. A cast-in-place concrete pile 100; A wale 200 disposed across the cast-in-place concrete pile 100; a guide bracket 300 installed at a predetermined position of the wale 200; A method of constructing a retaining facility using a ground anchor and a guide bracket composed of a lower body 500 in which the double-stranded tension member 430 is wound around the guide bracket 300 and the other side is fixed to the ground G,
Constructing a cast-in-place concrete pile 100 on the ground (G);
Forming a drilling hole by drilling the ground (G) of the cast-in-place concrete pile (100);
Inserting and fixing the lower body 500 into the perforation hole;
Installing a wale 200 to which a guide bracket 300 is attached across the cast-in-place concrete pile 100;
fixing the double-strand tension member 430 installed on the inner lower body 500 to the guide bracket 300;
The method of constructing a retaining facility using a guide bracket and a ground anchor, characterized in that the double-stranded tension member 430 is tensioned with a constant tension.

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