KR100495243B1 - Self supporting retaining wall construction method - Google Patents

Abstract

The present invention can install the retaining wall by not installing or minimizing the foundation plate according to the ground, and the self-supporting retaining wall which can pour the retaining wall without the installation of additional formwork for supporting the formwork when the concrete is placed by the site As to the installation method, in the case of inverted T-shaped retaining wall installation, in the case where the ground is a ground or a soft ground layer having a lack of supporting capacity other than the rock layer, the pillar pile is inserted into the ground and additional foundation plates are formed on the ground. The base plate is formed together with the filler, characterized in that the size of the base plate is produced in a minimum size in proportion to the insertion depth of the pillar file to be inserted.

Description

Self supporting retaining wall construction method

The present invention relates to a self-supporting retaining wall installation method. More specifically, the retaining wall can be installed by not installing or minimizing the foundation plate according to the ground, and the self-supporting retaining wall installation that can pour the retaining wall without installing a separate formwork supporting fixture when the concrete is laid by the site casting It is about a method.

Retaining wall is a kind of earth structure that can safely use the space in front of the retaining wall while supporting the earth pressure of the backing soil in the hills or cuts of roads installed in mountains and hills, and is usually made of foundation plates, walls and pillar members.

Such a retaining wall may be installed by pouring concrete directly into a predetermined shape using a formwork in the field in the form of an L-shaped retaining wall, an inverted L-shaped retaining wall, an inverted T-shaped retaining wall, or the like for retaining walls, as shown in FIGS. 1A, 1B, and 1C. After the precast member is manufactured in advance in the factory and transported to the site, the retaining wall is generally installed by a precast installation method of assembling and installing the member.

However, in such a retaining wall installation, the foundation earthwork is commonly performed first, followed by the construction of spheres, that is, foundation plates, walls and pillar members.

FIG. 1D shows the earthwork lines necessary for installing the inverted T-shaped retaining wall, in particular, a foundation breaker S for installing the retaining wall 10, and a base plate 11 in an internal space formed by the foundation breaker. And the wall 12 will be installed.

At this time, in order to secure the work space for the foundation plate installation, it is necessary to cut the foundation trench with a width D2 wider than the width of the foundation plate D1. However, in the case of the excavation work, if the ground is rock, it is a factor of increasing air delay and construction cost in construction, such as the blasting work for the excavation, and if the foundation plate increases in proportion to the height of the retaining wall, Since the trench area for plate construction is also large, there is a problem that the usable paper around the retaining wall is reduced. Also, in the case of the retaining wall installed around the road, road restriction or control of the road is required to secure space for the trench. Inevitably, the building retaining wall had a problem in that the paper or the ground had to be reduced as much as the width of the base plate.

In addition, the base plate is generally formed as a plate-shaped concrete structure for supporting the wall from the bottom, it is essential to install the retaining wall in order to support the earth pressure by the backing soil deposited on the back wall. This is because at least a lower portion of the pillar member must be fixed to the lower portion of the base plate to support the earth pressure acting on the pillar member and the wall to serve as a support for supporting the earth pressure.

In this case, the foundation plate is generally formed by pouring concrete directly in the field, unlike the pillar member and the wall, whether the retaining wall is installed in the site casting method or the precast method. Therefore, in order to install the foundation plate, it is inevitably required to be manufactured to an appropriate size to support the earth pressure in the rear view, and in general, the foundation plate having a size larger than necessary for quality control is often installed, which is a factor of increasing construction cost. there was.

In addition, in the case of construction by site-casting concrete for wall construction formed on the upper base plate, as shown in FIG. Done. At this time, when placing concrete, temporary copper bar 14, which serves as a support to resist the pressure of placing concrete, should be installed.In the case of such formwork, the installation period is longer than the form installation period, and consequently the air may be delayed. There was a problem that only.

SUMMARY OF THE INVENTION An object of the present invention is to provide a self-supporting retaining wall installation method in which a retaining wall can be provided without minimizing or without a base plate constituting the retaining wall according to the condition of the ground on which the retaining wall is installed.

Another object of the present invention is to provide a self-supporting retaining wall installation method capable of installing a retaining wall without installing a formwork such as a temporary copper bar installed to form a retaining wall.

The present invention to achieve the above technical problem,

First, if the ground where the retaining wall is to be installed is a rock layer, the pillar pile is inserted and fixed in a hole artificially formed in the rock to replace the role of the foundation plate, and a wall is formed between the pillar members fixed to the rock layer. In addition, external force, including earth pressure acting on the wall, can be supported by the crane and the wall only.

Second, if the ground to which the retaining wall is to be installed is not ordinary rock or soft ground, at least deep enough to support the external force, the pillar pile is inserted into and fixed in an artificially formed hole in the ground. To form a wall,

When the work for securing the depth of the hole is relatively more expensive in terms of air and construction cost than the work for forming the base plate, the column pile is fixed to the hole, but the minimum base plate can be formed,

Third, in the method of manufacturing the wall in the field between the pillar piles fixed to the ground, when installing the formwork for forming the wall formed between the pillar members, install the formwork club that serves as a support for resisting the pressure of pour concrete Instead, it is instead technical features to provide a fastening member that can be tied to the formwork and the fixture to support the formwork to the pillar member is fixed to the ground to ensure a sufficient support force.

BRIEF DESCRIPTION OF DRAWINGS To describe the present invention more clearly and easily, the following describes the best embodiments of the present invention in detail with reference to the accompanying drawings, and embodiments according to the present invention may be modified in various other forms, and thus the scope of the present invention. Is not limited to the embodiment described below.

Self-supporting retaining wall installation method of the present invention in the reverse T-shaped retaining wall installation, the step of drilling a hole 110 in the ground (100) (s1); Inserting the pillar pile 200 into the hole 110 and then filling the filler 300 in the space between the hole and the pillar pile to fix the pillar pile 200 to the ground 100 (s2); And further install the wall 400 between the pillar pile 200 to support the external force including the earth pressure of the backing soil by the pillar pile 200 and the wall 400.

The retaining wall installed by the present invention includes all retaining walls irrespective of the classification according to their names such as gravity retaining walls and subwall retaining walls, and classification according to installation methods such as on-site casting and precast methods. This is because the technical feature of the present invention adopts a method of installing a pillar pile on the ground as a configuration that resists external force, including backing earth pressure, and this pillar pile is attached to the type and installation method of the retaining wall. Because it is not.

In the case of the ground 100 in which the retaining wall is installed, the ground layer may be divided into a rock layer and a soft ground layer including soils other than the rock layer and the rock layer.

Since such classification is possible by a classification method known to those skilled in the art, there is no need to present a criterion in particular in the present invention, but in the present invention, it is largely divided into a rock layer and other ground layers (ground layer or soft ground layer lacking supporting force). Explain separately.

This distinction is necessary because it is related to the formation of the base plate according to the installation depth of the pillar pile to be described later.

The step s1 is a step of forming a hole 110 having a predetermined diameter as a ground 100 by a mechanical method in a rock layer or other ground layer.

Figures 2a, 2b and 2c shows the step s1 sequentially according to the construction order.

When the ground 100 is a rock layer, a hole having a diameter larger than the diameter of the pillar pile 200 to be described later is formed by using a mechanical means such as a rotary drill. In the case of the hole formed in the rock layer, there is no fear that the empty wall will fall, so it is not necessary to install a casing for maintaining the empty wall. In this case, the depth of the hole is such that the external force including the earth pressure acting on the retaining wall in consideration of the height of the retaining wall is transferred to the pillar pile so that the supporting force can be obtained so that the pillar pile can resist the external force. h).

In the case of layers other than the rock, forming a hole having a diameter larger than the diameter of the pillar pile 200 using a mechanical device is the same as the rock layer, but in the case of the soft ground layer, there is a fear that the hollow walls fall. Accordingly, it is preferable to further install a casing 210 for maintaining the empty wall as shown in addition to FIG. 2A. The casing may be a member such as a general round steel pipe.

The step s2 is a step of fixing the pillar pile in the hole 110 formed in the ground (100). That is, the pillar pile is fixed to the ground so that the external force acting on the retaining wall can be resisted by the pillar pile.

As a method of fixing the pillar pile 200 to the ground 100, it is proposed in the present invention by the hole 110 having a larger diameter than the pillar pile, such as the purchase of concrete, mortar, etc. in the space between the pillar pile and the hole and It is a method by the filling of the filler 300 easy to manufacture.

However, in addition to the method other than the use of such fillers, the usual means for fixing the pillar pile to the ground will be included in the technical scope of the present invention.

The pillar pile 200 may use a conventional H-shaped steel. Depending on the depth of the hole to be formed in the ground, a number of H-shaped steel can be connected by welding, and precast concrete products can be used. Preferably, it is advantageous in terms of construction and quality control to use steel in order to secure sufficient strength to resist external forces.

When the pillar pile 200 is fixed to the hole 110 formed in the ground using a filler or the like, the pillar pile is fixed to the ground and integrated.

The integration step by the fixing is a core configuration that can omit the construction of the base plate in the present invention in that the pillar pile provides a lower fixing portion that can resist the external force.

That is, in the conventional retaining wall, as the column member is fixed to the foundation plate, the foundation plate and the pillar member are integrated with each other so that the foundation plate acts as a lower part fixing part of the pillar member so that the pillar member installed on the foundation plate acts on the retaining wall. While following a resistance mechanism to

In the present invention, as the pillar pile 200 is fixed to the ground 100, the ground 100 and the pillar pile 200 are integrated with each other, so that the ground acts as a lower part of the pillar pile so that the pillar pile fixed to the ground retains the wall. It follows a resistance mechanism that resists external forces acting on it.

When the pillar pile 200 is fixed to the ground 100 which is a rock layer, the pillar pile is firmly fixed to the ground and integrated, thereby completely replacing the role of the base plate of the conventional retaining wall. ) Is installed on the ground 100 including the rock layer, in the case of the present invention, it is possible to omit the foundation plate installation in the retaining wall installation.

If the installation of the base plate can be omitted, it is possible to significantly reduce the earth work for installing the base plate has the advantage that it is possible to reduce the air and construction costs. For example, when it is necessary to install retaining walls adjacent to mountains or hills, the amount of cut can be greatly reduced by the elimination of foundation plates, and the earthwork also obstructs the use of surrounding structures, facilities, and land (such as traffic control). Therefore, omitting such earthwork can be a huge factor in reducing air and construction costs.

Furthermore, when the pillar pile 200 is fixed to the ground 100 other than the rock layer, the pillar pile is firmly fixed to the ground, so that the pillar pile 200 must be installed at a much deeper depth than the rock layer to secure a predetermined support force.

This is because it is necessary to install the pillar pile deep in the ground so that the pillar pile can be more securely fixed and integrated with the ground.

However, depending on the site conditions, it may not be easy to install the pillar pile deeply into the ground, and the cost of offsetting the effect of air shortening and construction cost reduction by earthwork by installing the foundation plate may be If so, this may not be desirable from an economic point of view.

In the present invention, the installation depth of the pillar pile 200 is determined in consideration of the ease of construction and economical efficiency, etc., and the installation depth of the pillar pile insufficient is made possible by the minimum foundation plate installation.

The installation depth of the quantitative pillar pile and the size of the base plate corresponding thereto are not uniformly determined, and a configuration ratio of maximizing the pillar pile and minimizing the size of the foundation plate is preferable because of the characteristics of the present invention.

FIG. 3B shows, as a comparative example, a conventional inverted T-shaped retaining wall which may have the same mechanical function as that of the pillar pile and base plate of the present invention shown in FIG. 3A.

In FIG. 3B, a base plate 500 having a minimum size is installed at a pillar file inserted into the ground 100 and fixed by the filler. At this time, when filling the filler 300, it is installed using the same material as the base plate, whereby the base plate 500 to function as a structural member that resists the earth pressure acting on the back wall together with the wall.

In this case, it can be seen that the conventional retaining wall of FIG. 3A is installed in a relatively large area despite the same height of the wall H as compared with the base plate 500 of the present invention.

The step s3 is a step of installing the wall 400 between the pillar pile 200 fixed to the ground (100).

After fixing the column pile 200 on the ground 100 to form a wall 400 to accommodate the backing soil, even if the form is installed directly on the site and cast concrete in the form of the wall to form the wall It does not matter, it is possible to use precast concrete wall boards made for the convenience of construction and shortening of the air, and to use wall members such as lightweight panels.

In the present invention looks at the basis of the way to form the wall (400) by placing concrete in the field in particular in relation to the installation of formwork (including clubs).

4A and 4B illustrate the formwork 600 installed by the formwork installation method of the present invention installed on the pillar pile 200 fixed to the ground 100 together with the pillar pile in cross section and a partial perspective view.

The formwork installation method includes the step of installing the formwork for the wall (600) on the both sides of the pillar pile 200 is included inside or between the pillar pile (ss1);

Forming a plurality of formwork fixtures 610 in the longitudinal direction on the outer surface of the wall formwork 600, the end of the formwork is installed so as to protrude further in the longitudinal direction than the end of the formwork, protruding formwork fixture The two ends of the tie to each other with a fastener 620 and then placing the concrete between the formwork to form a wall (ss2); includes.

The step ss1 is a step of installing the formwork 600 for forming the wall (400). The wall 400 may be formed between the pillar piles 200 of the present invention, but when H-shaped steel is used as the pillar pile, when the concrete wall is formed between the H-shaped steel, the H-shaped steel is exposed to the outside air, thereby deteriorating durability such as corrosion. Since the wall formwork may be concerned that the pillar pile 200 is located inside the formwork so that the pillar pile and the wall are integrated with each other.

If the pillar pile 200 is made of a concrete material such as a precast concrete pillar pile, it is possible to form the wall by installing the wall formwork only between the pillar pile.

The ss2 step is a process of constraining the wall formwork 600 to the pillar pile itself. That is, after installing a plurality of additional up and down the form plate so as to protrude both ends of the outside of the form in the longitudinal direction, the formwork installed by tying the end more protruding than the form in the longitudinal direction with a fastener such as wire pillars themselves To be bound to.

Various reinforcing bars are arranged inside the formwork 600, and when the internal pressure of the formwork is largely generated as concrete is poured, there is a problem such as a positional deviation of the formwork.

Such temporary copper bar is generally installed by fixing the outer surface of the formwork to the surrounding ground, etc. This means that the pillar pile is reliably fixed and installed as shown in the present invention to support the pressure due to the formwork while restraining the formwork. It was because they could not secure the means to play a role.

Since the pillar pile 200 of the present invention is securely fixed to the ground to secure the strength enough to resist external forces, without having to install a separate temporary fixture for fixing the formwork, the formwork fixture 610 as the cover plate ) The mold is installed on the outer surface of the mold in the longitudinal direction up and down a number of.

At this time, the end of the formwork 610 is installed so as to protrude more than the formwork end to install the fastening material 620 that can tie the protruding end to each other at each end of the formwork.

As a result, the form fixture is bundled by the fastener to offset the force to be formed by the pressure due to the concrete placing.

By the retaining wall installation method of the present invention, various unreasonable design methods and air delay and construction cost increase factors by the conventional base plate installation can be eliminated, and the retaining wall installation which can satisfy both the constructability and economical efficiency through the rational rationalization of the retaining wall construction Becomes possible.

1A, 1B, 1C, 1D, and 1E illustrate a conventional retaining wall, a retaining wall on which earthwork lines necessary for installing the retaining wall are indicated, and a retaining wall in which a conventional temporary copper bar is installed.

Figures 2a, 2b and 2c sequentially shows the step of fixing the column pile of the present invention to the ground (rock layer).

3A and 3B sequentially illustrate the step of fixing the pillar pile of the present invention to the ground (ground other than the rock layer) with a minimum base plate.

Figure 4a and 4b shows the formwork and fasteners installed in the formwork of the present invention.

<Description of the symbols for the main parts of the drawings>

100: ground 110: hole

200: pillar pile 300: filler

400: wall 500: base plate

600: formwork 610: formwork

620: Fastener

Claims (5)

delete delete delete delete In the installation of the inverted T-shaped retaining wall, drilling a hole (110) in the ground (100); Inserting the pillar pile 200 into the hole 110 and then fixing the pillar pile 200 to the ground 100; Filling the filler 300 including concrete and mortar in the space between the hole and the pillar pile; And installing a wall 400 between the pillar piles 200, wherein the ground pile is a ground or soft ground layer having insufficient support force other than the rock layer. The base plate 500 is further formed on the ground, and the base plate is formed together with the filler, and the size of the base plate 500 is a minimum size in proportion to the insertion depth of the pillar pile to be inserted. In being made of, When the wall 400 is formed as a concrete wall by casting in-situ, the pillar pile 200 is included inside or between the pillar piles, wall formwork 600 is installed on both sides of the pillar pile 200, and the wall After installing the formwork 610 in the longitudinal direction on the outer surface of the formwork 600, the end of the formwork is installed so as to protrude further in the longitudinal direction than the end of the formwork, both ends of the protruding formwork fixture The self-supporting retaining wall installation method, characterized in that by tying each other with a fastener 620 to each other and then forming a wall between the formwork to form a wall, without forming a separate provision for supporting the formwork.