KR102050427B1 - Soil retaining wall using two rows pile - Google Patents

Abstract

The present invention is a heat transfer pile 100 is installed along the left and right directions; A rear heat pile 200 installed in a row along the left and right direction at the rear of the heat transfer pile 100; After heat pile member 201 installed on the after pile 200, to support the rear soil pile (a) of the rear of the rear pile 200; In addition to being formed at a height lower than the rear soil layer (a), and the heat transfer soil installed in the heat transfer pile 100 to support the intermediate soil portion (b) formed between the heat transfer pile 100 and the after-heat pile (200) Member 101; A rear heat strip 200a installed along the left and right directions at the front of the rear heat pile 200; An upper spacer 500 having a rear end coupled to the rear heat transfer strip 200a and a front end coupled to the heat transfer pile 100 so as to be integral with the heat transfer pile 100; It is installed along the left and right directions in front or rear of the heat transfer pile 100, the heat transfer strip installed at a height corresponding to the height of the upper surface of the middle soil portion (b) and the height of the upper spacer 500 ( 100a); The lower spacer member is coupled between the heat transfer pile 100 and the after heat pile 200, and is disposed between a height of an upper surface of the intermediate earth and sand portion b and a height of the heat transfer strip 100a. By presenting a two-row clamshell structure, characterized in that, including, improve the mutual coupling structure of the piles, strips, spacers, and prevent the contact of the spacers and retaining members excellent structural stability, economics and workability Get it.

Description

SOIL RETAINING WALL USING TWO ROWS PILE}

TECHNICAL FIELD The present invention relates to the field of construction, and in particular, to a masonry structure.

An earthquake structure is a structure that is installed at a site that is sloped or excavated at a construction site, to prevent rockfall or debris from scattering, and to be temporarily installed in order to prevent the earth wall from falling down during the excavation of the excavation section for foundation work. It is called.

In other words, the earthen structure should be designed to withstand the working load with sufficient strength and rigidity as a means to secure the trench.

Recently, in order to solve the inconvenience of the construction by the support material installed in the excavation area (working area), a two-row earthquake method has been developed in which the thumb piles are installed in two rows and the earth block members are installed (FIGS. 1 to 3). .

Such a conventional two-row mud structure, the heat transfer pile 100 of the H pile structure is installed so as to support both ends of the heat transfer mud member 101, such as earth plate or sheet pile; A rear heat pile 200 having an H pile structure installed in a rear of the heat transfer pile 100 so as to support both ends of the rear heat blocking member 201; Heat transfer strips (10a, 10b) installed along the left and right directions on the heat transfer pile 100; After heat strips 20 are installed along the left and right directions in the after heat pile 200; An upper spacer member 30 installed to maintain a gap between the heat transfer pile 100 and the rear heat pile 200; It is configured to include; center portion spacer 40 is installed to maintain the center portion of the heat transfer pile 100 and the rear heat pile 200 (Fig. 1,2).

In order to form a solid support structure by coupling the upper ends of the heat transfer pile 100 and the after heat pile 200, the heat transfer strips 10a are respectively disposed along the left and right directions on the top of the heat transfer pile 100 and the top of the heat transfer pile 200. And after the heat transfer strip 20 is installed, and the front end and the rear end of the upper spacer 30 for each coupling point of the heat transfer pile 100 and the heat transfer strip 10a and the coupling point of the after heat transfer pile 200 and the after heat transfer strip 20. Combine each of these.

The after-heat piling member 201 is installed on the after-row pile 200 so as to support the rear soil spraying portion a at the rear of the after-heat pile 200.

The heat-transfer blocking member 101 is formed at a lower height than the rear soil layer (a), and the heat transfer pile 100 to support the middle soil portion (b) formed between the heat transfer pile 100 and the rear heat pile 200. Is installed.

This structure excavates the upper region between the heat transfer pile 100 and the after heat pile 200 and shares a part of the earth pressure by the after heat clogging member 201, thereby obtaining excellent structural stability through even distribution of load. There is an advantage.

Specifically, the front end of the center spacer 40 is coupled to the rear flange 120 of the heat transfer pile 100 in a double nut structure, the rear end of the center spacer 40 is the front flange 210 of the rear heat pile 200. Take a structure that is bonded to the double nut structure in the) (Fig. 3).

On the other hand, since the retaining member (101,102) is pushed forward by the earth pressure, it is naturally coupled to the structure in surface contact with the rear surface of the front flange (110,210) of the pile (100,200).

However, the following problems have been pointed out in the conventional two-row structure.

First, since the three members of the upper end of the heat transfer pile 100, the heat transfer strip (10a), the front end of the upper spacer 30 must meet each other at one point, the construction in the actual site is not very good.

Second, as the three members meet at one point, compressive force, tensile force, and bending moment all occur, so that structural analysis is complicated and difficult.

Third, since the heat transfer strip (10a) is installed on the top of the heat transfer pile 100, the distance between the top heat transfer strip (10a) and the lower support point is large, it is necessary to install the additional heat transfer strip (10b).

Fourth, since the rear end of the center spacer 40 is coupled to the front flange 210 of the rear row pile 200 in a double nut structure, the double nut of both ends of the rear row retaining member 201 and the rear end of the center spacer 40. Inconsistencies occur between the bonding structures.

For this reason, it was pointed out that the structural stability due to the reduction of the supporting area of both ends of the afterheated earth blocking member 201, and the inconvenience of construction.

The present invention is derived to solve the above problems, to improve the mutual coupling structure of piles, strips, spacers, to prevent the interference between the spacer and the retaining member, to obtain excellent structural stability, economics and workability The purpose is to present a two-row clamshell structure.

In order to solve the above problems, the present invention is a heat transfer pile 100 is installed along the left and right directions; A rear heat pile 200 installed in a row along the left and right direction at the rear of the heat transfer pile 100; After heat pile member 201 installed on the after pile 200, to support the rear soil pile (a) of the rear of the rear pile 200; In addition to being formed at a height lower than the rear soil layer (a), and the heat transfer soil installed in the heat transfer pile 100 to support the intermediate soil portion (b) formed between the heat transfer pile 100 and the after-heat pile (200) Member 101; A rear heat strip 200a installed along the left and right directions at the front of the rear heat pile 200; An upper spacer 500 having a rear end coupled to the rear heat transfer strip 200a and a front end coupled to the heat transfer pile 100 so as to be integral with the heat transfer pile 100; It is installed along the left and right directions in front or rear of the heat transfer pile 100, the heat transfer strip installed at a height corresponding to the height of the upper surface of the middle soil portion (b) and the height of the upper spacer 500 ( 100a); The lower spacer member is coupled between the heat transfer pile 100 and the after heat pile 200, and is disposed between a height of an upper surface of the intermediate earth and sand portion b and a height of the heat transfer strip 100a. It proposes a two-row earthquake structure comprising a; (300).

The heat transfer pile 100, the after heat pile 200, the heat transfer strip length (100a), the heat transfer strip length (200a) and the upper spacer 500 is preferably in the H-section structure.

Support member 150 of the "a" shaped cross section coupled to the rear surface of the heat transfer pile 100 and the bottom surface of the upper spacer 500 so as to support the upper spacer 500 with respect to the heat transfer pile 100. It is preferable to further include;

It is preferable to further include a; rib plate 151 coupled to the rear surface of the heat transfer pile 100, the upper surface of the upper flange of the upper spacer 500 and the side of the web.

A coupling plate 510 welded to the rear end of the upper spacer 500 is further included, and the front flange 210a and the coupling plate 510 of the rear stripe length 200a are preferably bolted to each other.

The lower spacer 300 is preferably a pair of steel bar structure coupled at intervals in the left and right directions.

The front surface of the rear heat retaining member 201 is coupled to the surface contact with the rear surface of the front flange 210 of the rear heat pile 200, the rear end of the lower spacer 300 and the direct coupling of the rear heat pile 200 In order to prevent the contact between the rear heat pile 200 and the rear heat retaining member 201, the auxiliary coupling member 400 installed in front of the rear heat pile 200 so that the rear end of the lower spacer 300 is coupled. It is preferable to further include;

The auxiliary coupling member 400 preferably has a shorter H file structure than the rear row pile 200.

It is preferable that the rear surface of the rear flange 430 of the auxiliary coupling member 400 and the front surface of the front flange 210 of the rear row pile 200 are welded to the surface contact.

A coupling part 411 is formed at the front flange 410 of the auxiliary coupling member 400, and the rear end of the lower spacer 300 is fixed by a double nut 310 through the coupling part 411. It is preferable to be.

A pair of coupling parts 411 are formed on both sides of the front flange 410 of the auxiliary coupling member 400, respectively, and a rear end of the pair of lower spacers 300 is a pair of coupling parts, respectively. It is preferable that the coupling part 411 has a long hole structure formed on both sides of the front flange 210 with the trimming parts 412 and extended to the web side.

The lower spacer 300 is installed with respect to the whole area between all the heat transfer pile 100 and the after heat pile 200, the upper spacer 500 is all the heat transfer pile 100 and the after heat pile 200 It is preferable that it is provided with respect to a part of area | region between (

The present invention proposes a two-row mud structure that improves the mutual coupling structure of piles, strips, and spacers, and prevents the spacers and the mud members from being in contact, thereby obtaining excellent structural stability, economy and constructability.

1 is a longitudinal cross-sectional view of a conventional two-row mudguard structure.
Figure 2 is a cross-sectional top view of a conventional two-row cladding structure.
3 is a cross-sectional view of the central portion of a conventional two-row cladding structure.
Figure 4 below shows an embodiment of a two-row mudstone structure according to the present invention,
4 is a longitudinal sectional view of the first embodiment;
5 is a plan view of the first embodiment;
6 is a front view of the coupling plate of the upper spacer;
7 is a longitudinal sectional view of the second embodiment;
8 is a cross sectional view of a second embodiment;
9 is a partial perspective view of a second embodiment.
10 is a front view of the auxiliary coupling member.

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

As shown in Figure 4, the two-row soil structure according to the present invention is basically, the heat transfer pile 100 is installed along the left and right directions; After-heat pile 200 is installed in a row along the left and right in the rear of the heat transfer pile 100; After heat pile member 201 installed on the after pile 200 so as to support the rear soil pile (a) of the rear of the after pile (200); In addition to being formed at a lower height than the rear soil portion (a), and the heat transfer soil member 101 installed on the heat transfer pile 100 to support the intermediate soil portion (b) formed between the heat transfer pile 100 and the after-heat pile (200). ); A rear heat strip 200a installed along the left and right directions at the front of the rear heat pile 200; An upper spacer 500 coupled to the rear heat transfer strip 200a and having a front end coupled to the heat transfer pile 100 so as to be integral with the heat transfer pile 100; Heat transfer strip 100a is installed along the left and right directions in front or rear of the heat transfer pile 100, and is installed at a height corresponding to the height of the upper surface of the middle soil portion b and the height of the upper spacer 500; Coupled between the heat transfer pile 100 and the after-heat pile 200, the lower spacer 300 is installed at a height corresponding to the height of the upper surface of the middle soil portion (b) and the height of the heat transfer strip (100a); It is configured to include.

That is, the three members of the upper end of the heat transfer pile 100, the heat transfer strip 100a, and the front end of the upper spacer 500 do not meet each other at one point, but the top and top of the heat transfer pile 100 are not. While the front end of the spacer 500 is coupled, the heat transfer strip 100a has a structure that is coupled to its lower position (separate position).

This has the following effects.

First, since the three members do not need to meet each other at one point, the construction is excellent in actual field compared with the prior art.

Second, only the compressive force is generated in the coupling portion of the upper end of the heat transfer pile 100 and the upper spacer 500, the other load (tensile force, bending moment) is the heat transfer pile 100 and the heat transfer strip (100a) The structural analysis can be simplified by occurring at the coupling part of.

Third, since the heat transfer strip 100a is installed at the central portion of the heat transfer pile 100 rather than at the top, the space between the top heat transfer strip 100a and the lower support point is reduced, so that the additional heat transfer strip is not necessary or installed. Can be reduced.

Heat transfer pile 100, after heat pile 200, heat transfer strip length (100a), heat transfer strip length (200a) and the upper spacer 500 is to take the H cross-sectional structure (H pile, H beam) structural stability, economical efficiency, workability Preferred for

The front end of the upper spacer 500 is welded to the rear of the heat transfer pile 100 in an integrated structure, in order to perform this operation stably, to support the upper spacer 500 against the heat transfer pile 100. , First, the welding member 150 of the "a" shaped cross section is welded to the rear surface of the heat transfer pile 100, and the bottom surface of the upper spacer 500 is coupled thereto.

Preferably, the rib plate 151 is welded to the rear surface of the heat transfer pile 100, the upper surface of the upper flange of the upper spacer 500, and the side surface of the web to form an integral coupling structure.

It is preferable to weld the coupling plate 510 to the rear end of the upper spacer 500 and bolt the front flange 210a and the upper coupling plate 510 of the rear heat strip 200a for construction and structural stability. .

Unlike the upper spacer 500 that takes the H beam structure, the lower spacer 300 is sufficient to take a pair of steel rod structures that are spaced apart in the left and right directions.

On the other hand, as described above, since the earth retaining members (101, 102) are pushed forward by the earth pressure, it is naturally coupled to the structure in surface contact with the rear surface of the front flanges (110, 210) of the pile (100,200).

By the way, in the conventional two-row cladding structure, since the rear end of the center spacer 40 is coupled to the front flange 210 of the rear row pile 200 in a double nut structure, both ends and the center spacer of the rear row brick member 201 ( There was a problem in that contact occurred between the double nut coupling structures at the rear of 40).

Therefore, in order to prevent the rear end of the rear spacer 200 and the rear row pile member 201 due to the direct coupling of the rear end of the lower spacer 300, the rear end of the lower spacer 300 is coupled. It is preferable to take a structure in which the auxiliary coupling member 400 is installed in front of the rear row pile 200 (FIGS. 7 to 10).

That is, in order to solve the problem of the prior art that the rear end of the lower spacer 300 and the rear end of the lower spacer 300 is in contact with the rear end pile member 201 occurs. A separate auxiliary coupling member 400 is installed in front of the rear row pile 200, and the rear end of the lower spacer 300 is to be coupled to the auxiliary coupling member 400.

Therefore, since the coupling structure of the rear end of the lower spacer 300 does not have any influence on the front flange 210 of the rear row pile 200, the rear end of the lower spacer 300 and the rear end of the rear wall member 201 This is prevented, and thereby, the effect of increasing the structural stability due to securing the supporting areas of both ends of the post-heating retaining member 201, and the convenience of construction can be obtained.

Auxiliary coupling member 400 may be implemented in a variety of structures, when using a short H-length structure (piece of H file) compared to the after-row pile 200, there is an advantage that the manufacturing and construction is simple.

In this case, it is preferable for structural stability that the back coupling of the rear flange 430 of the auxiliary coupling member 400 and the front surface of the front flange 210 of the rear row pile 200 are in surface contact.

A coupling part 411 is formed on the front flange 410 of the auxiliary coupling member 400, and the rear end of the lower spacer 300 penetrates the coupling part 411 to be fixed by the double nut 310. Taking is preferred for workability and structural stability.

Specifically, a pair of coupling parts 411 are formed on both sides of the front flange 410 of the auxiliary coupling member 400, respectively, and the rear ends of the pair of lower spacers 300 are each pair of coupling parts ( It is desirable for structural stability to have a structure that binds to 411).

Here, the coupling part 411 is formed with the trimming part 412 at both edges of the front flange 210 and also takes the long hole structure extended to the web side, the lower spacer 300, the double nut 310 and the auxiliary coupling The advantage that the mutual coupling operation of the members 400 can be conveniently added.

As described above, for structural efficiency and economical efficiency, an expensive H beam is used as the upper spacer 500, and a low-cost steel rod is used as the lower spacer 300. It is not necessary to install the entire area between the pile 100 and the rear row pile 200.

Therefore, the lower spacer 300 is installed with respect to the entire area between all the heat transfer pile 100 and the after heat pile 200, the upper spacer 500 is between all the heat transfer pile 100 and the after heat pile 200. It is desirable to have a structure installed for some of the areas for structural efficiency and economics.

For example, the upper spacers 500 may be alternately installed one by one of the regions between all the heat transfer piles 100 and the after heat piles 200 (FIG. 5).

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

100: heat transfer pile 100a: heat transfer strip
110: front flange 101: heat transfer soil member
150 support member 151 rib plate
200: after pile 200a: after heating strip
210: front flange 201: post heat retaining member
300: lower spacer 310: double nut
400: auxiliary coupling member 410: front flange
411: coupling portion 412: trimming
420: web 430: rear flange
500: upper spacer

Claims (12)

Heat transfer pile 100 is installed along the left and right directions;
A rear heat pile 200 installed in a row along the left and right direction at the rear of the heat transfer pile 100;
After heat pile member 201 installed on the after pile 200, to support the rear soil pile (a) of the rear of the rear pile 200;
In addition to being formed at a height lower than the rear soil layer (a), and the heat transfer soil installed in the heat transfer pile 100 to support the intermediate soil portion (b) formed between the heat transfer pile 100 and the after-heat pile (200) Member 101;
A rear heat strip 200a installed along the left and right directions at the front of the rear heat pile 200;
An upper spacer 500 having a rear end coupled to the rear heat transfer strip 200a and a front end coupled to the heat transfer pile 100 so as to be integral with the heat transfer pile 100;
It is installed along the left and right directions in front or rear of the heat transfer pile 100, the heat transfer strip installed at a height corresponding to the height of the upper surface of the middle soil portion (b) and the height of the upper spacer 500 ( 100a);
The lower spacer member is coupled between the heat transfer pile 100 and the after heat pile 200, and is disposed between a height of an upper surface of the intermediate earth and sand portion b and a height of the heat transfer strip 100a. 300; and
The heat transfer pile 100, the after heat pile 200, the heat transfer strip length (100a), the heat transfer strip length (200a) and the upper spacer 500 is H cross-sectional structure,
The lower spacer 300 is a pair of steel rods structured at intervals in the left and right directions,
The lower spacer 300 is installed with respect to the whole area between all the heat transfer pile 100 and the back heat pile 200,
The upper spacer 500 is installed for a portion of the area between all the heat transfer pile 100 and the back heat pile 200,
The front surface of the rear heat retaining member 201 is coupled to the surface contact with the rear surface of the front flange 210 of the rear heat pile 200,
In order to prevent the rear end of the lower spacer 300 and the rear heat pile 200 and the rear heat retaining member 201 due to the direct coupling of the rear pile 200, of the lower spacer 300 Further comprising: an auxiliary coupling member 400 installed in front of the rear row pile 200 so that the rear end is coupled,
The auxiliary coupling member 400 has a shorter H-file structure than the rear row pile 200,
Welding the rear surface of the rear flange 430 of the auxiliary coupling member 400 and the front surface of the front flange 210 of the rear row pile 200 in surface contact,
A coupling part 411 is formed on the front flange 410 of the auxiliary coupling member 400,
The rear end of the lower spacer 300 is fixed by the double nut 310 through the coupling portion 411,
A pair of the coupling portion 411 is formed on both sides of the front flange 410 of the auxiliary coupling member 400,
The rear ends of the pair of lower spacers 300 are respectively coupled to the pair of coupling portions 411,
The coupling part 411 is a two-layered earthquake structure, characterized in that the trimming portion 412 is formed at both edges of the front flange 410 and the long hole structure is extended to the web side. delete The method of claim 1,
Support member 150 of the "a" shaped cross section coupled to the rear surface of the heat transfer pile 100 and the bottom surface of the upper spacer 500 so as to support the upper spacer 500 with respect to the heat transfer pile 100. ;
Two-row earthquake structure further comprising. The method of claim 3,
A rib plate 151 coupled to a rear surface of the heat transfer pile 100, an upper surface of the upper flange of the upper spacer 500, and a side surface of the web;
Two-row earthquake structure further comprising. The method of claim 1,
Further comprising; a coupling plate 510 welded to the rear end of the upper spacer 500;
The front flange (210a) and the coupling plate (510) of the rear row strip (200a) is a two-row soil structure, characterized in that the bolted. delete delete delete delete delete delete delete

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