KR102638676B1 - Construction method of earth retaining wall without wale - Google Patents

Abstract

The present invention allows the anchor body to be directly anchored to the thumb pile during earth retaining construction, thereby omitting the strips and brackets, and the brackets for fixing the anchor body do not protrude to the front of the earth retaining wall, so that the basement wall to be constructed is grounded. Even if it is higher than the anchor, it is easy to remove the anchor, and when a composite wall is constructed without removing the anchor, there is no unnecessary concrete filling on the outside of the basement wall, so it is an economical method of beltless earth retaining construction.
The present invention is a plurality of unit piles that are spaced apart from each other on the left and right to form a space continuous up and down and open front and rear between them, and a filler material that is a soft material filled in the space between the pair of unit piles, and which are driven into the ground. Column thumb stakes; Earth retaining members provided between neighboring thumb piles; An anchorage tube provided on the front side between the unit piles of the thumb pile and having a anchorage plate formed on the inner peripheral surface of the rear end side; An anchor body inserted into the ground behind the thumb pile, one end of which is drawn out between the unit piles into the interior of the anchorage pipe; and an anchoring port provided in front of the anchoring plate inside the anchoring tube to which one end of the anchor body is anchored. It is for constructing a bandless earth retaining structure consisting of.

Description

Construction method of earth retaining wall without wale}

The present invention allows the anchor body to be directly anchored to the thumb pile during earth retaining construction, thereby omitting the straps and brackets, and the brackets or fixtures for fixing the anchor body do not protrude to the front of the earth retaining wall, allowing the basement wall to be constructed as a back wall. Even when it is higher than a ground anchor, it is easy to remove the anchor, and when a composite wall is constructed without removing the anchor, there is no unnecessary concrete filling on the outside of the basement wall, so it is an economical method of beltless earth retaining construction.

When excavating the ground for the construction of an underground structure, surrounding soil or water may flow into the site, or the surrounding ground and adjacent structures may settle or collapse. Therefore, to prevent this, earth retaining construction is carried out by installing temporary structures that resist lateral pressure such as earth pressure and water pressure.

In conventional earth retaining construction, the horizontal plank pile method was mainly used, in which thumb piles such as H-piles were driven into the ground and earth plates were installed between adjacent thumb piles.

Meanwhile, when installing a retaining wall and performing ground excavation work, a multifaceted review must be conducted on ground conditions such as stress or deformation of the retaining wall and deformation of the surrounding ground, construction conditions, and excavation sequence. Accordingly, the raker method, strut method, and earth anchor method are used to stably support the lateral pressure.

Among these, the raker method or strut method reduces work efficiency because it can interfere with other processes due to the interference of the raker or strut placed in the field.

Therefore, if conditions allow for anchor construction in an adjacent site, the ground anchor method is advantageous as there are no interference factors within the site.

As shown in FIG. 1, the earth retaining method using an earth anchor installs a strip 200 in the horizontal direction on the front of the earth anchor, installs a bracket 300 on the front of the strip 200, and anchors the anchor body by the anchor 400. Settlement 100. After completion of the retaining construction, the anchor body 100 is removed by cutting it with an oxygen cutter, etc. in the space between the retaining retaining material and the bracket 300, if necessary.

This conventional earth anchor earth retaining method requires the installation of a separate wale, requires a wale support on the front of the earth retaining wall to support the strip, and the strip, brackets, and wale support protrude from the front of the earth retaining wall.

In particular, when constructing a basement exterior wall with a back wall where formwork is installed on both sides of the wall, it is necessary to secure work space for formwork installation. However, when the wale and bracket protrude, the wale and bracket interfere, so overcutting is required to secure sufficient work space, which increases the amount of earthwork.

In addition, when the basement exterior wall is constructed as a composite wall, there is a problem that the amount of concrete poured for the composite wall increases significantly due to the protruding parts of the strips and brackets.

Therefore, a method of removing the strips and brackets can be considered. If it is difficult to match the basement floor height and the vertical spacing of the ground anchors in the construction plan, the ground anchors must be removed from the space outside the exterior wall after building above the ground anchor height when constructing a side wall. Therefore, the work is cumbersome and difficult. In addition, when an exterior wall with a high basement level, such as a logistics warehouse, is constructed as a composite wall, it is not possible to pour the wall at once to remove the strips and brackets at each stage, and it is inconvenient to pour concrete separately for each height of the strips and brackets. There is.

Accordingly, technologies for removing the wale and fixing the anchor body on the thumb peg side have been developed, such as Japanese Patent Publication No. 11-50457, Korean Patent No. 10-0907904, etc.

Although this conventional technology omits the wale, the bracket for fixing the anchor still protrudes from the front of the retaining wall. Therefore, the amount of concrete poured increases when constructing a joint wall, and it is difficult to secure work space for formwork installation when constructing a double wall.

In order to solve the above problems, the present invention aims to provide a wale-less earth retaining construction method in which the strip can be omitted while constructing the earth anchor using the earth anchor method, and the brackets or fixtures for fixing the anchor do not protrude to the front of the earth retaining material. do.

Accordingly, in the present invention, when a basement wall constructed as a double wall is constructed higher than the ground anchor, the anchor body can be easily removed, and even when a composite wall is constructed without removing the anchor body, the amount of unnecessary concrete filling on the outside of the basement wall is eliminated, making it economical. The purpose of this study is to provide a construction method for wale mud retaining.

The present invention according to a preferred embodiment consists of a pair of unit piles spaced apart from each other on the left and right to form a space that is open front and rear and continuous up and down, and a filler that is a soft material filled in the space between the pair of unit piles. Multiple rows of thumb piles driven into the ground; Earth retaining members provided between neighboring thumb piles; An anchorage tube provided on the front side between the unit piles of the thumb pile and having a anchorage plate formed on the inner peripheral surface of the rear end side; An anchor body inserted into the ground behind the thumb pile, one end of which is drawn out between the unit piles into the interior of the anchorage pipe; and an anchoring port provided in front of the anchoring plate inside the anchoring tube to which one end of the anchor body is anchored. To construct a strip-less earth retaining structure, comprising: (a) vertically boring the ground at the earth retaining installation location and inserting the thumb pile; (b) excavating the soil in front of the thumb pile and constructing a retaining member between neighboring thumb piles; (c) inserting and grouting the anchor body by obliquely or horizontally drilling the rear ground into the space between the unit piles of the thumb pile; (d) installing the anchorage pipe so that one end of the anchor body penetrates between the unit piles of the thumb pile, and installing the anchorage to be accommodated inside the anchorage pipe; and (e) the rear end is in close contact with the front of the anchor, and the front end protrudes in front of the thumb pile, the anchor body penetrates the inner peripheral surface of the rear end, and a jack chair is provided with a pressure plate for pressing the wedge coupled to the anchor. Installing a hydraulic jack on the front end of the jack chair to tension the anchor body that penetrates the jack chair and protruding from the front end of the jack chair, and then fixing the anchor body in the anchorage hole; It provides a bandless earth retaining construction method characterized by consisting of.

The present invention according to another preferred embodiment provides a bandless earth retaining construction method, characterized in that a support plate is provided on the front outside of the anchorage pipe and supported by hanging on the front of the unit piles on both sides.

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The present invention according to another preferred embodiment provides a bandless earth retaining construction method, characterized in that a horizontal fixing member supporting the side of the thumb pile is provided on the front of the earth retaining member.

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According to another preferred embodiment of the present invention, in step (d), the rear end is inserted into the interior of the anchorage tube and supported on the anchorage plate between the anchorage pipe and the anchorage, and the front end protrudes forward of the thumb pile. The outer surface is further provided with an intermediate support member in which an anchor body is received and a receiving space portion exposed to the outside is formed, and after step (e), (f) is located inside the receiving space portion of the intermediate support member through the intermediate support member. Cutting the anchor body; Provides a bandless earth retaining construction method further comprising:

According to the present invention, a plurality of thumb piles are installed laterally spaced apart from each other at the retaining installation location, a retaining member provided between neighboring thumb piles to support earth pressure, and an anchor body embedded in the rear ground to support the retaining earth. It is configured to provide a wale-less earth retaining construction method that can omit wales and brackets by directly anchoring the anchor body to the thumb pile.

In particular, since the anchor of the anchor body is provided between a pair of unit piles constituting the thumb pile and is not exposed to the outside, the portion protruding outside the retaining wall can be minimized.

Accordingly, the brackets or anchors for fixing the anchor do not protrude from the front of the earth retaining wall, making it easy to remove the anchor even if the basement wall constructed as a back wall is constructed higher than the ground anchor, and even if the composite wall is constructed without removing the anchor, the underground wall Economical construction is possible by eliminating unnecessary concrete filling on the outside of the wall.

Figure 1 is a diagram showing the state of fixation of an anchor body in a conventional ground anchor method.
Figure 2 is a perspective view showing a stripless earth retaining device.
Figure 3 is a perspective view showing the combined state of the thumb pile and anchorage pipe.
Figure 4 is a cross-sectional perspective view showing a settlement pipe.
Figure 5 is a cross-sectional perspective view showing the combined state of the unit pile and anchorage pipe.
Figure 6 is a flat cross-sectional view showing the combined state of the thumb pile and anchorage pipe.
Figure 7 is a perspective view showing an embodiment in which filler is provided between unit piles.
Figure 8 is a cross-sectional perspective view showing an intermediate support member.
Figure 9 is a cross-sectional perspective view showing the coupled state of the intermediate support member.
Figure 10 is a perspective view showing the coupled state of the intermediate support member.
Figure 11 is a perspective view showing an embodiment provided with a horizontal fixture.
Figures 12 to 16 are diagrams showing the step-by-step process of the bandless earth retaining construction method of the present invention.
Figure 17 is a cross-sectional perspective view showing a jack chair.
Figure 18 is a perspective view showing the installed state of the jack chair.
Figure 19 is a cross-sectional perspective view showing the installed state of the jack chair.
Fig. 20 is a cross-sectional view showing the tension state of the anchor body caused by the jack chair.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

Figure 2 is a perspective view showing a belt-less earth retainer, and Figure 3 is a perspective view showing a combined state of a thumb pile and an anchorage pipe.

As shown in Figures 2 and 3, the bandless earth retaining device includes a pair of unit piles 20 that are spaced apart from each other on the left and right and are open front and rear between them and form a continuous space up and down, and the pair of unit piles 20 ) A plurality of rows of thumb piles (2) composed of filler material (25), which is a soft material filled in the space between them, and inserted into the ground (1); A retaining member (3) provided between neighboring thumb piles (2); An anchorage pipe (4) provided on the front side between the unit piles (20) of the thumb pile (2) and having a anchorage plate (41) formed on the inner peripheral surface of the rear end side; An anchor body (5) inserted into the ground behind the thumb pile (2), one end of which is drawn out between the unit piles (20) and into the anchorage pipe (4); and an anchorage port (6) provided in front of the anchorage plate (41) inside the anchorage pipe (4) to which one end of the anchor body (5) is anchored. It is characterized by being composed of.

The present invention is intended to provide a wale-less earth retaining construction method in which the strips are omitted while constructing earth retaining using the earth anchor method, and the brackets or anchors (6) for anchoring the anchor body (5) do not protrude to the front of the earth retaining material.

Accordingly, the present invention makes it easy to remove the anchor body (5) even when the basement wall constructed as a double wall is constructed higher than the ground anchor, and fills the outside of the basement wall with unnecessary concrete even when the composite wall is constructed without removing the anchor body (5). The purpose is to provide a belt-less earth retaining construction method that allows for economical construction by eliminating the bulk of the material.

The bandless earth retaining device includes a plurality of thumb piles (2) installed to be spaced apart from each other in the transverse direction at the earth retaining installation location, an earth retaining member (3) provided between neighboring thumb piles (2) to support earth pressure, and a back ground ( It is composed of an anchor body (5) embedded in 1) and supporting the earth retaining block.

The retaining member 3 may be a retaining plate or a soil cement wall (SCW).

Unlike the conventional earth anchor retaining method where a strip and bracket are installed separately and an anchor body is installed on the bracket, in the present invention, the anchor body (5) is directly anchored to the thumb pile (2), thereby omitting the strip and bracket. .

For this purpose, the thumb pile (2) is composed of a pair of unit piles (20) spaced apart from each other on the left and right, and the anchor body (5) penetrates between the neighboring unit piles (20).

The unit pile 20 may be composed of a front flange 21, a rear flange 22, and a web 23. In Figure 3, etc., a unit pile 20 composed of a U-beam steel is shown, but H-beam steel or a square steel pipe can also be used.

A pair of unit piles 20 may be integrally coupled to each other by a connecting material 24 connecting the front and rear sides, respectively.

In order to anchor one end of the anchor body 5 between the unit piles 20, an anchorage pipe 4 is provided between the unit piles 20.

The anchorage pipe (4) is formed in a tube shape with front and rear openings and is provided on the front side between the unit piles (20).

The anchorage pipe (4) may be provided so that there is no or minimal portion protruding in front of the thumb pile (2).

Inside the anchorage pipe (4), an anchorage port (6) into which one end of the anchor body (5) is anchored is accommodated.

A wedge 60 for anchoring one end of the anchor body 5 is provided in front of the anchorage 6.

In order to support the anchorage 6 accommodated inside the anchorage tube 4, a anchorage plate 41 is integrally provided on the inner circumferential surface of the rear end of the anchorage tube 4 to support the rear end of the anchorage 6 in close contact with the anchorage plate 41. .

A through hole (H) through which the anchor body (5) passes is formed in the anchoring plate (41).

The through hole (H) may be formed in plural numbers so that each anchor body (5) passes through it one by one, or it may be formed as one large hole in the center so that all anchor bodies (5) penetrate at the same time.

The anchor plate 41 can be used in any shape as long as it supports the rear end of the anchor 6.

The fusing tube 4 may be circular or square.

As described above, in the present invention, while applying an earth anchor to a retaining earth, the anchor body (5) can be directly anchored to the thumb pile (2), thereby omitting the strip and bracket.

In addition, since the anchorage 6 of the anchor body 5 is provided inside the thumb pile 2, the portion protruding outside the retaining wall can be minimized.

Figure 4 is a cross-sectional perspective view showing the anchorage pipe, Figure 5 is a cross-sectional perspective view showing the combined state of the unit pile and the anchorage pipe, and Figure 6 is a flat cross-sectional view showing the combined state of the thumb pile and the anchorage pipe.

As shown in FIGS. 4 to 6, a support plate 42 may be provided on the front outside of the anchorage pipe 4 and is supported by being hung on the front of the unit piles 20 on both sides.

The anchorage pipe (4) is stored inside the neighboring unit pile (20). Therefore, in order to transmit the earth pressure acting on the earth retaining body to the anchor body 5, a support plate 42 that is expanded and supported toward the front flange 21 of the unit pile 20 may be provided in front of the anchorage pipe 4. .

A reinforcing part 43 inserted between the unit piles 20 on both sides may be formed to protrude on the back of the support plate 42.

The reinforcement portion 43 prevents the fusing tube 4 from moving left and right and reinforces the support plate 42.

When a pair of unit piles 20 are connected to each other by a connecting material 24, the anchoring pipe 4 can be installed by mounting the support plate 42 of the anchoring pipe 4 on the upper part of the connecting material 24. .

Figure 7 is a perspective view showing an embodiment in which filler is provided between unit piles.

As shown in Figure 7, the space between the pair of unit piles 20 is filled with a filler 25, which is a soft material.

The thumb pile (2) is a pair of unit piles (20) spaced apart from each other, and an open front and rear space is formed between them, which is continuous up and down. Therefore, when backfilling the back of the earthen membrane, filler material 25 can be filled in the space between the unit piles 20 to prevent defective backfilling and to prevent soil from leaking into the underground space along with groundwater.

The filler 25 can be made of soft materials such as EPS, ALC, wood, etc., and can be made of various other materials.

Figure 8 is a cross-sectional perspective view showing the intermediate support member, Figure 9 is a cross-sectional perspective view showing the coupled state of the intermediate support member, and Figure 10 is a perspective view showing the coupled state of the intermediate support member.

As shown in Figures 8 to 10, between the fusing tube 4 and the anchoring port 6, the rear end is inserted into the interior of the fusing tube 4 and supported on the anchoring plate 41, and the front end is supported by the thumb. An intermediate support member 61 may be further provided on the outer surface of the pile 2 to protrude forward, forming a receiving space 611 in which the anchor body 5 is accommodated and exposed to the outside.

The length of the anchor body 5 of the earth anchor installed in the upper part is usually longer than that of the lower part. As a result, there are many cases where underground walls invade adjacent land and must be removed after construction. Of course, the lower earth anchor can also be removed as needed.

In the conventional earth anchor method using a wale and bracket, when the anchor body needs to be removed, the anchor body is cut using an oxygen cutter or the like in the wale space on the back of the bracket.

In contrast, in the present invention, since the anchorage tube (4), which accommodates the anchorage (6) without a wale or bracket, is provided inside the thumb pile (2), the anchor body (5) is also not exposed to the outside, making the anchor body (5) It is difficult to cut.

Therefore, an intermediate support member 61 is installed between the anchorage pipe 4 and the anchorage 6 so that the anchorage 6 is provided outside the earthen barrier, and the intermediate support member 61 is provided on the outer surface of the intermediate support member 61. The anchor body 5 penetrating through (61) forms a receiving space 611 exposed to the outside, so that the anchor body 5 can be cut in the receiving space 611.

The intermediate support member 61 can be optionally used when the anchor body 5 needs to be removed.

The rear end of the intermediate support member 61 is provided with a first support plate 612 that is hooked to the fixing plate 41, and the front is provided with a second support plate 613 on which the anchor head of the anchor body 5 is mounted and supported. may be provided.

A through hole H through which the anchor body 5 passes is formed in the first support plate 612 and the second support plate 613.

The intermediate support member 61 only needs to protrude to the front of the earth retaining wall to the extent that the anchor body 5 can be cut with an oxygen cutter through the receiving space 611. Therefore, the part that protrudes from the front of the earthen membrane can be minimized.

Figure 11 is a perspective view showing an embodiment provided with a horizontal fixture.

As shown in FIG. 11, a horizontal fixture 31 supporting the side of the thumb pile 2 may be provided on the front of the retaining member 3.

When the retaining member 3 is a retaining plate, horizontal fixing members 31 may be provided on both sides of the front of the retaining member 3.

The horizontal fixture 31 supports the side of the thumb pile 2 and can reduce the effective buckling field of the thumb pile 2.

The horizontal fixing members 31 may be provided in plural numbers spaced apart from each other in the vertical direction.

The horizontal fixing member 31 is configured in an angle shape so that one leg is fixed to the front of the earth retaining member 3, and the other leg can be supported in close contact with the side of the thumb pile (2).

Figures 12 to 16 are diagrams showing the step-by-step process of the bandless earth retaining construction method of the present invention.

The present invention's bandless earth retaining construction method is for constructing the bandless earth retaining described above with reference to FIGS. 2 to 11.

In the bandless earth retaining construction method of the present invention, the step of (a) vertically drilling the ground (1) at the earth retaining installation location and inserting the thumb pile (2) is first performed (FIG. 12). And (b) the soil in front of the thumb pile (2) is excavated, and an earth retaining member (3) is constructed between the neighboring thumb piles (2) (FIG. 13).

In other words, the thumb pile (2) and the retaining member (3) are constructed in the same manner as the conventional thumb pile retaining method.

Next, (c) the anchor body 5 is inserted and grouted by obliquely or horizontally drilling the rear ground 1 into the space between the unit piles 20 of the thumb pile 2 (FIG. 14).

In step (c), the rear ground (1) is drilled obliquely or horizontally through the space between the pair of unit piles (20) constituting the thumb pile (2). Then, construct the anchor body (5) at the location of the thumb pile (2).

Thereafter, (d) the anchorage pipe 4 and the anchorage 6 are installed so that one end of the anchor body 5 penetrates between the unit piles 20 of the thumb pile 2 (FIG. 15).

With one end of the anchor body 5 protruding from the front of the thumb pile 2, an anchor pipe 4 is installed between neighboring unit piles 20 so that the anchor body 5 penetrates.

Similarly, an anchorage hole (6) is installed in front of the anchorage plate (41) inside the anchorage pipe (4) so that one end of the anchor body (5) penetrates.

If the anchor body (5) needs to be removed, an intermediate support member (61) can be installed between the anchor pipe (4) and the anchor (6).

And (e) the anchor body 5 is tensioned and the anchor body 5 is anchored to the anchorage 6 (FIG. 16).

In step (e), the hydraulic jack (8) is mounted to tension the anchor body (5), and then the anchor body (5) is anchored to the anchor (6).

The earth retaining construction can be completed by repeating steps (b) to (e).

If the anchor body (5) is removed after completion of construction of the underground structure, the anchor body (6) is separated by cutting the anchor body (5) with an oxygen cutter, etc. through the receiving space portion (611) of the intermediate support member (61). Next, the anchor body (5) can be removed from the ground (1).

Figure 17 is a cross-sectional perspective view showing the jack chair, Figure 18 is a perspective view showing the installed state of the jack chair, and Figure 19 is a cross-sectional perspective view showing the installed state of the jack chair. And Figure 20 is a cross-sectional view showing the state of tension of the anchor body caused by the jack chair.

As shown in FIGS. 17 to 20, in step (d), the anchorage 6 is accommodated inside the fusing pipe 4, and in step (e), the rear end is the front of the anchorage 6. After installing the jack chair (7), which is closely attached to the jack and the front end protrudes in front of the thumb pile (2), a hydraulic jack (8) is installed on the front end of the jack chair (7) to penetrate the jack chair (7) The anchor body 5 protruding from the front end of the chair 7 can be tensioned.

In the conventional earth anchor method using wales and brackets or the wale-less earth anchor method, the bracket on which the anchor is anchored protrudes and is exposed in front of the earth retaining wall, so it is easy to tension it by installing a hydraulic jack on the front of the earth retaining wall.

In contrast, in the present invention, since the anchor (6) is accommodated inside the anchor pipe (4), the anchor body (5) must be tensioned by inserting the hydraulic jack (8) into the anchor pipe (4). However, if the diameter of the hydraulic jack (8) is larger than the anchorage pipe (4), it is difficult to install the hydraulic jack (8).

Therefore, after receiving the anchorage (6) inside the anchorage pipe (4), a jack chair (7) capable of pressurizing the anchorage (6) can be installed between the anchorage (6) and the hydraulic jack (8). .

The rear end of the jack chair (7) is accommodated inside the fusing tube (4) and is in close contact with the front of the anchoring tube (6), and the front end protrudes to the outside of the fusing tube (4) and a hydraulic jack (8) is mounted on the front. .

The jack chair (7) can be formed in a tube shape so that the anchor body (5) penetrates the jack chair (7) and protrudes forward.

The inner peripheral surface of the rear end of the jack chair 7 may be provided with a pressure plate 71 that presses the wedge 60 coupled to the anchorage 6 through which the anchor body 5 penetrates.

When tensioning the anchor body 5 by the hydraulic jack 8, a pressure plate 71 may be provided on the inner peripheral surface of the rear end side of the jack chair 7 to limit the movement of the wedge 60 pre-installed on the anchorage 6. .

When the hydraulic jack (8) is mounted on the front end of the jack chair (7) to tension the anchor body (5), the anchor body (5) moves outward and tension force is introduced, while the wedge (60) is attached to the pressure plate (71). It is caught and placed in the anchorage (6).

When the tension of the anchor body 5 is completed, the anchor body 5 is slightly shortened, and the wedge 60 moves to the wedge hole side of the anchorage 6 due to friction between the anchor body 5 and the wedge 60. Thus, settlement is completed.

A through hole (H) through which the anchor body (5) passes is formed in the pressure plate (71).

In step (d), the rear end is inserted into the interior of the anchorage tube 4 and supported on the anchorage plate 41 between the anchorage pipe 4 and the anchorage port 6, and the front end is connected to the thumb peg 2. An intermediate support member 61 is further provided on the outer surface that protrudes forward and forms a receiving space 611 that accommodates the anchor body 5 and is exposed to the outside, and after step (e) (f) ) Cutting the anchor body 5 located inside the receiving space 611 of the intermediate support member 61 through the intermediate support member 61; More may be included.

If removal of the anchor body (5) is necessary, an intermediate support member (61) can be installed between the anchor pipe (4) and the anchor (6) in step (d). And in step (e), the hydraulic jack (8) is mounted and the anchor body (5) is tensioned, so that the anchor body (5) can be anchored to the anchorage (6).

Thereafter, the anchor body (5) is cut with an oxygen cutter or the like through the receiving space portion (611) of the intermediate support member (61) to separate the anchorage (6) and the anchor body (5) is removed from the ground (1). Step (f) may be further performed.

1: Ground 2: Thumb pile
20: unit pile 21: front flange
22: rear flange 23: web
24: connecting material 25: filling material
3: Earth retaining member 31: Horizontal fixer
4: fixation tube 41: fixation plate
42: support plate 43: reinforcement part
5: Anchor body 6: Anchoring port
60: Wedge 61: Middle support member
611: Accommodating space 612: First support plate
613: Second support plate 7: Jack chair
71: pressure plate 8: hydraulic jack
H: Through hole

Claims (9)

It consists of a pair of unit piles (20) spaced apart from each other on the left and right to form a space that is open forward and backward and continuous up and down, and a filler (25) which is a soft material filled in the space between the pair of unit piles (20). A plurality of rows of thumb piles (2) inserted into the ground (1);
A retaining member (3) provided between neighboring thumb piles (2);
An anchorage pipe (4) provided on the front side between the unit piles (20) of the thumb pile (2) and having a anchorage plate (41) formed on the inner peripheral surface of the rear end side;
An anchor body (5) inserted into the ground behind the thumb pile (2), one end of which is drawn out between the unit piles (20) and into the anchorage pipe (4); and
An anchorage port (6) provided in front of the anchorage plate (41) inside the anchorage pipe (4) to which one end of the anchor body (5) is anchored; It is intended to construct a band-less earth retaining structure consisting of,
(a) vertically drilling the ground (1) at the retaining location to insert the thumb pile (2);
(b) excavating soil in front of the thumb pile (2) while constructing a retaining member (3) between neighboring thumb piles (2);
(c) inserting and grouting the anchor body (5) by obliquely or horizontally drilling the rear ground (1) into the space between the unit piles (20) of the thumb pile (2);
(d) The anchorage pipe (4) is installed so that one end of the anchor body (5) penetrates between the unit piles (20) of the thumb pile (2), and the anchorage (6) is connected to the anchorage pipe (4). Installing to be accommodated inside; and
(e) The rear end is in close contact with the front of the anchor (6), and the front end protrudes forward of the thumb pile (2), so that the anchor body (5) penetrates the inner peripheral surface of the rear end and is coupled to the anchor (6). After installing the jack chair (7) equipped with a pressure plate (71) that pressurizes the wedge (60), install a hydraulic jack (8) at the front of the jack chair (7) to penetrate the jack chair (7) and press the jack chair (7). ) Tensing the anchor body (5) protruding at the front end and then anchoring the anchor body (5) in the anchorage (6); A bandless earth retaining construction method characterized by consisting of.
In paragraph 1:
A bandless earth retaining construction method, characterized in that a support plate (42) is provided on the front outside of the anchorage pipe (4) and is supported by hanging on the front of the unit piles (20) on both sides.
delete delete In paragraph 1:
A beltless earth retaining construction method, characterized in that the front of the earth retaining member (3) is provided with a horizontal fixing member (31) supporting the side of the thumb pile (2).
delete delete delete In paragraph 1:
In step (d), the rear end is inserted into the interior of the anchorage tube 4 and supported on the anchorage plate 41 between the anchorage pipe 4 and the anchorage port 6, and the front end is connected to the thumb peg 2. An intermediate support member 61 is further provided on the outer surface that protrudes forward and forms a receiving space 611 that accommodates the anchor body 5 and is exposed to the outside,
After step (e), (f) cutting the anchor body 5 located inside the receiving space 611 of the intermediate support member 61 through the intermediate support member 61; A bandless earth retaining construction method further comprising:

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