KR100495878B1 - Method for underground watertight wall - Google Patents

Abstract

The present invention includes a plurality of main piles (100) embedded in the ground or submarine ground in the longitudinal direction, the groove portion 110 is formed in the longitudinal direction on both sides of the adjacent main pile; A plurality of auxiliary files (200) inserted in the groove in the longitudinal direction to fill gaps between the main files (100); An undercarriage wall method including an undercarriage wall structure including the undercarriage wall structure, comprising: a gulting process for embedding the main pile (100a); Providing a temporary auxiliary file (300) corresponding to half in the longitudinal direction of the auxiliary file (200) and formed as a structure filling the groove (110) of the main file (100); Embedding the main file (100a) in which the temporary auxiliary files (300a1, 300a2) are inserted into both groove portions (110a); A burial process for embedding the other main pile (100b) adjacent to the embedded main pile (100a); Removing the temporary auxiliary file (300a2) on the side adjacent to the oyster; The auxiliary file 200 is inserted into the embedded main file 100a side groove part 110b1, and the other main file 100b into which the temporary auxiliary file 300b2 is inserted is inserted into the opposite groove part 110b2. and; Repeating the steps to form the order wall structure; By presenting a subterranean order wall construction method, it is possible to obtain better construction properties and high order effect.

Description

Underground Order Wall Method {METHOD FOR UNDERGROUND WATERTIGHT WALL}

The present invention relates to an underground order wall structure and a method of forming a pile by laying a pile in the ground or underwater ground in a longitudinal direction. Specifically, a groove portion is formed in an adjacent section between piles. The present invention relates to a structure for increasing the order effect by inserting an auxiliary file into the groove portion.

In such a barrier wall structure, a means for preventing water from penetrating through the gap between the pile and the pile is required, and there have been many studies on this.

1 to 3 show a conventional underground order wall structure published in the Republic of Korea Patent Publication (1999-0015942), Figure 1 is a plan view, Figures 2 and 3 is an enlarged perspective view of the main portion.

As shown, the conventional underground order wall structure is basically a structure in which a plurality of steel pipe piles 2 are lined in the longitudinal direction and filled in the piles 2 as a means for filling gaps between the piles 2. On the contrary, it adopts a structure in which a connecting steel pipe 3 having a relatively small diameter and an incision 4 is formed.

A pair of relatively small-diameter connecting steel pipes 3 are welded to the opposite portions of the outer circumferential surface of the relatively large-diameter steel pipe pile 2, and a cutout portion 4 is formed along a longitudinal direction at a predetermined portion of the connecting steel pipe 3. The formed steel pipe pile 2 has a structure to be embedded or lined up in the underground or subsea ground so that the connection steel pipe 3 is coupled to each other.

In order to further increase the ordering effect, the tube 10 is inserted into the space 7 formed by engaging the connection steel pipe 3, and in the tube 10, air, mortar, soil cement, or water-expandable water-proofing agent It is intended to be injected.

However, in the conventional structure as described above, since stress concentration occurs at the welded joint portions of the steel pipe pile 2 and the connecting steel pipe 3, there is a problem that the resistance to earth pressure is weak, as well as the connection of the connecting steel pipe 3. Since the cutouts 4 have a structure in which they are interlocked with each other, the disassembly is difficult and the material is difficult to recycle.

In the case of the conventional order wall construction method using other piles, various methods are employed as a means for filling the gaps between piles. It has been pointed out as a problem because the construction is rough in actuality and it is difficult to expect a high order effect.

It is an object of the present invention to provide an underground order wall structure and a method for solving the problems as described above, which is more excellent in workability and obtains a high order effect.

In order to achieve the above object, the present invention includes a plurality of main piles (100) embedded in the ground or in the water in the longitudinal direction, the groove portion 110 is formed in the longitudinal direction on both sides of the main pile; A plurality of auxiliary files (200) inserted in the groove in the longitudinal direction to fill gaps between the main files (100); Present an underground containment wall structure that includes:

Here, the groove 110 is preferably configured to have a cross-sectional shape corresponding to half of the cross-sectional shape of the auxiliary pile 200.

In addition, the auxiliary pile 200 may have a rectangular cross-sectional shape, may have a circular cross-sectional shape, or may be formed by an H beam.

On the other hand, the present invention is another means for achieving the above object, that is, the order wall method using the order wall structure, a burial process for embedding the main pile (100a); Providing a temporary auxiliary file (300) corresponding to half in the longitudinal direction of the auxiliary file (200) and formed as a structure filling the groove (110) of the main file (100); Embedding the main file (100a) in which the temporary auxiliary files (300a1, 300a2) are inserted into both groove portions (110a); A burrow process for embedding another main pile (100b) adjacent to the embedded main pile (100a); Embedding the other auxiliary files (100b) into which the temporary auxiliary files (300b1 and 300b2) are inserted into both groove parts (110b); Removing the temporary auxiliary files (300a2, 300b1) opposed between the main files (100a, 100b); Embedding the auxiliary file (200) in the groove (110a, 110b) of the main file from which the temporary auxiliary file (300a2, 300b1) is removed; Repeating the steps to form the order wall structure; We present underground order wall construction method to include.

In addition, the present invention is another means for achieving the above object, that is, the order wall method using the order wall structure, a burial process for embedding the main pile (100a); Providing a temporary auxiliary file (300) corresponding to half in the longitudinal direction of the auxiliary file (200) and formed as a structure filling the groove (110) of the main file (100); Embedding the main file (100a) in which the temporary auxiliary files (300a1, 300a2) are inserted into both groove portions (110a); A burrow process for embedding another main pile (100b) adjacent to the embedded main pile (100a); Removing the temporary auxiliary file (300a2) on the side adjacent to the oyster; The auxiliary file 200 is inserted into the embedded main file 100a side groove part 110b1, and the other main file 100b into which the temporary auxiliary file 300b2 is inserted is inserted into the opposite groove part 110b2. and; Repeating the steps to form the order wall structure; We present underground order wall construction method to include.

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

As shown in Figures 4 to 6, the underground order wall structure according to the present invention is basically, lined in the longitudinal direction in the underground or subsea ground, the groove 110 in the longitudinal direction on both adjacent side piles A plurality of main files 100 formed; It is composed of a plurality of auxiliary piles 200 which are inserted in the groove in the longitudinal direction to fill the gap between the main pile 100.

That is, in the present invention, by simply inserting the auxiliary file 200 into the main file 100 in which the groove part 110 is formed, the present invention has a structure that fills the gap between the main files 100, which is easier than the conventional structure. It is possible to secure a workability and to obtain an excellent degree of effect.

In addition, in the conventional structure, since the stress concentration occurs in the welded joint portion between the steel pipe pile (2) and the connecting steel pipe (3), the present invention has a problem that the resistance to earth pressure is weak, whereas the auxiliary pile 200 is Since the structure is inserted into the groove 110 of both main piles 100 to disperse the stress, it is possible to obtain the effect of having a strong resistance to earth pressure.

Furthermore, the conventional structure has a structure in which the cutout portions 4 of the connecting steel pipes 3 are interlocked with each other, so that the dismantling is difficult and the recycling of materials is difficult. ) Takes a structure inserted into the groove portion of the main pile 100, it is easy to dismantle it can obtain an advantageous effect in terms of recycling the material.

The auxiliary pile 200 has a configuration that is inserted into the groove 110 of the two main piles by half, the cross-sectional shape of the auxiliary pile 200 to take a variety of changes in consideration of the ease of manufacture and the order effect In addition, the cross-sectional shape of the groove 110 corresponding thereto may be variously changed.

That is, as shown in various embodiments shown in FIGS. 6 to 11, the auxiliary pile 200 may be deformed into a rectangular shape, a circular shape, and various other cross-sectional shapes, and the groove 110 of the main pile 100 may be modified. 7 to 9 may have a cross-sectional shape corresponding to the shape of the auxiliary pile 200, or may have a separate cross-sectional shape as shown in FIGS.

6 and 7 illustrate a case in which the cross section of the auxiliary pile 200 has a simple rectangular shape and a circular shape, and FIGS. 8 to 11 illustrate a case in which the cross section of the auxiliary pile 200 has a secondary curvature. In FIG. 6 and FIG. 7, the case of FIG. 6 and FIG. 7 may be excellent, but in the order effect, the case of FIGS. 8 to 11 may be more preferable.

In particular, Figures 9 to 11 is a case where the H beam is used as the auxiliary pile 200, it is preferable in terms of the material can be used as it is of a conventional general structure.

In this case, the cross-sectional shape of the groove 110 of the main pile 100 will be excellent in terms of the order effect to form so as to correspond to the cross-sectional shape of the H beam as shown in FIG.

However, in order to ensure the ease of manufacturing, as shown in Figs. 10 and 11, even if the structure adopting a structure in which some deformation is applied to the general steel pipe and filling the gap by mortar or the like, there is no significant difference in terms of order effect. will be.

Hereinafter, the order construction method using the underground order wall structure which has the above structure is demonstrated.

In actual construction, in order to embed the order wall structure having the above structure in the ground, a means for easily constructing the embedding of the auxiliary pile 200 inserted between the main piles 100 is required.

That is, when the main pile 100 of the above-described structure is simply purchased, and the auxiliary pile 200 is subsequently to be embedded in the groove portion 100, the soil around the groove portion 110 corresponds to the surrounding soil. This is because the collapse of the auxiliary file 200 may cause a problem that the insertion and embedding is not properly.

Accordingly, as shown in FIG. 12, the auxiliary auxiliary file 300 corresponds to half in the longitudinal direction of the auxiliary file 200, and has a temporary auxiliary file 300 formed as a structure filling the groove 110 of the main file 100. By temporarily purchasing together with (100), a means for securing a purchase space of the auxiliary file 200 was devised.

Fig. 13 is a process chart showing the process of the underground order wall method according to the present invention.

As shown in the figure, first, a burrowing process for embedding the main pile 100a is performed (FIG. 13A), and the main pile 100a is embedded in the burrowed space, where both groove portions of the main pile 100a are formed. Insert temporary auxiliary files (300a1, 300a2) in the embedded together. Here, the purchase of the temporary auxiliary file 300 together is to secure the purchase space of the auxiliary file 200 to be purchased in the future (Fig. 13b).

Proceeding with the burrow process for embedding the other main pile (100b) adjacent to the embedded main pile (100a), for easy embedding of the other main pile (100b) is the size of the other main pile (100b) It is more widely secured (FIG. 13C).

Subsequently, the other main files 100b having the temporary auxiliary files 300b1 and 300b2 inserted in the grooves 110b are inserted into the recessed spaces, in which case the other main files 100b are then excavated. This should be made in close contact with the side to be performed. This is to easily secure the boundary surface of the gulting space by the temporary auxiliary file 300b2 inserted into the other main file 100b to easily perform the next pitting work. (FIG. 13D)

Thereafter, the temporary auxiliary files 300a2 and 300b1 opposed to the main files 100a and 100b are removed, and the positions secured by the temporary auxiliary files 300, that is, the groove parts 110a and 110b of the main files are removed. Purchase the auxiliary file 200 in (Fig. 13E).

By repeating such a process, the order wall structure having the structure described above can be obtained.

However, when the same method as in the above embodiment is taken, the process of removing the two temporary auxiliary files 300a2 and 300b1 and inserting and embedding the auxiliary file 200 may be difficult. Thus, the embedded main file 100a After the burrowing process for embedding the other main pile (100b) adjacent to (FIG. 13C), immediately after removing the temporary auxiliary file (300a2) of the side adjacent to the gulting portion and the other state of the auxiliary file 200 is inserted You may also choose to embed the file 100b.

That is, in this case, the auxiliary file 200 is inserted immediately without the need for attaching a temporary temporary auxiliary file 300b1 to the embedded main file 100a side groove 110b1 of the other main file 100b, and the opposite side thereof. The protruding portion of the auxiliary file 200 inserted into the groove 110b1 of the other main file 100b by embedding the other main file 100b with the temporary auxiliary file 300b2 inserted only in the groove 110b2. What is necessary is just to embed the other main file 100b so that it may be inserted into the groove part 110a2 of this prefilled main file 100a. (FIG. 13E).

In the embodiment of the present method illustrated in FIG. 13, the cross-sectional shape of the auxiliary pile 200 and the cross-sectional shape of the main pile groove 110 are illustrated as an example, but are illustrated in FIGS. 7 to 11. Of course, the present method can be applied to the structure of the embodiment as it is.

The present invention provides an underground order wall structure and a construction method which can be more excellent in workability and obtain a high order effect.

1 to 3 show a conventional underground order wall structure,

1 is a plan view

2 and 3 is an enlarged perspective view of the main portion

4 to 10 show an embodiment of the order wall structure according to the present invention,

4 is a plan view of a first embodiment

5 is an enlarged perspective view of a main part of the first embodiment;

6 is a cross sectional view of the first embodiment;

7 is a cross sectional view of a second embodiment;

8 is a cross sectional view of a third embodiment;

9 is a cross sectional view of a fourth embodiment;

10 is a cross sectional view of a fifth embodiment;

11 is a cross sectional view of a sixth embodiment

12 is a cross-sectional view showing a main file in which a temporary auxiliary file and an auxiliary file are mounted;

13 is a process chart showing a process of the order wall method according to the present invention.

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

100: main file 110: groove

200: auxiliary file 300: temporary auxiliary file

Claims (7)

A plurality of main piles 100 embedded in the ground or subsea ground in the longitudinal direction, and having grooves 110 formed in the longitudinal direction on both sides of adjacent main piles; A plurality of auxiliary files (200) inserted in the groove in the longitudinal direction to fill gaps between the main files (100); As an underground order wall method using the underground order wall structure to include, A burrow process for embedding the main pile (100a); Providing a temporary auxiliary file (300) corresponding to half in the longitudinal direction of the auxiliary file (200) and formed as a structure filling the groove (110) of the main file (100); Embedding the main file (100a) in which the temporary auxiliary files (300a1, 300a2) are inserted into both groove portions (110a); A burrow process for embedding another main pile (100b) adjacent to the embedded main pile (100a); Embedding the other auxiliary files (100b) in which the temporary auxiliary files (300b1, 300b2) are inserted into both groove parts (110b); Removing the temporary auxiliary files (300a2, 300b1) opposed between the main files (100a, 100b); Embedding the auxiliary file (200) in the groove (110a, 110b) of the main file from which the temporary auxiliary file (300a2, 300b1) is removed; Repeating the steps to form the order wall structure; Underground line wall construction. A plurality of main piles 100 embedded in the ground or subsea ground in the longitudinal direction, and having grooves 110 formed in the longitudinal direction on both sides of adjacent main piles; A plurality of auxiliary files (200) inserted in the groove in the longitudinal direction to fill gaps between the main files (100); As an underground order wall method using the underground order wall structure to include, A burrow process for embedding the main pile (100a); Providing a temporary auxiliary file (300) corresponding to half in the longitudinal direction of the auxiliary file (200) and formed as a structure filling the groove (110) of the main file (100); Embedding the main file (100a) in which the temporary auxiliary files (300a1, 300a2) are inserted into both groove portions (110a); A burrow process for embedding another main pile (100b) adjacent to the embedded main pile (100a); Removing the temporary auxiliary file (300a2) on the side adjacent to the oyster; The auxiliary file 200 is inserted into the embedded main file 100a side groove part 110b1, and the other main file 100b into which the temporary auxiliary file 300b2 is inserted is inserted into the opposite groove part 110b2. and; Repeating the steps to form the order wall structure; Underground line wall construction. delete delete delete delete delete