KR20240131632A - Truss-type wale and method for constructing underground structure using the same - Google Patents

Abstract

A truss belt capable of continuously constructing an underground structure by penetrating a belt and a method of constructing an underground structure using the same are disclosed. The truss belt (50) includes: a wall-side chord (52) that supports a retaining wall (10, 12) in a horizontal direction; an excavation-side chord (54) that supports a horizontal brace (20) and transmits earth pressure transmitted from the retaining wall (10, 12) to the horizontal brace (20); and a truss member (56) that is continuously positioned in a zigzag shape between the wall-side chord (52) and the excavation-side chord (54) and supports the wall-side chord (52) and the excavation-side chord (54) at a predetermined inclination angle to form a truss structure.

Description

Truss-type wale and method for constructing underground structure using the same {Truss-type wale and method for constructing underground structure using the same}

The present invention relates to a truss belt and a method for constructing an underground structure using the same, and more specifically, to a truss belt capable of continuously constructing an underground structure by penetrating the belt, and a method for constructing an underground structure using the same.

In order to construct an underground structure of a building, a retaining wall is installed around the perimeter of the area where the underground structure is to be formed, excavation is performed, and then wales and braces are installed to support the retaining wall so that it does not collapse due to earth pressure. The braces used to support the retaining wall can be classified into horizontal struts installed horizontally between the retaining walls on both sides, and inclined braces (rakers) installed slantedly between the retaining wall and the ground. Horizontal struts are less affected by soil quality and have fewer restrictions on the excavation depth, so they are mainly used in construction near urban areas, and inclined struts are mainly used when the excavation area is wide and the excavation depth is narrow, or when it is difficult to use horizontal struts.

Fig. 1 is a plan view (A) and a cross-sectional view (B) taken along the line a-a showing the installation state of a typical belt and horizontal brace. As illustrated in Fig. 1, piles (10) are installed at predetermined intervals along an area where an underground structure is to be constructed on a site (5) made of soil, the construction area is excavated, and then a retaining plate (12) is inserted between the piles (10) to install a retaining wall (10, 12). Next, a belt (30) is installed in the horizontal direction to support the retaining wall (10, 12) in the horizontal direction so that the earth pressure acting on the retaining wall (10, 12) is uniformly transmitted. The belt (30) is typically made of H-shaped steel and is installed at a vertical interval of approximately 2 to 3 m. In addition, the belt (30) is constructed to adhere closely to the pile (10) of the retaining wall (10, 12), and when there is a gap between the pile (10) and the belt (30), a reinforcing material (32) is inserted and welded. In order to prevent the belt (30) from falling due to the self-weight or loading of the belt (30), a reinforcing bracket (not shown) is installed at the bottom of the belt (30). After the retaining wall (10, 12) and the belt (30) are installed around the excavation area in this way, a horizontal brace (20) is fixed between the belts (30) on both sides to prevent the retaining wall (10, 12) from collapsing due to soil pressure. The horizontal brace (20) is installed at a horizontal interval of approximately 2 to 4 m.

FIG. 2 is a drawing showing the state of constructing an underground structure after a belt (30) and a horizontal brace (20) are installed. As illustrated in FIG. 2, after the retaining wall (10, 12) is supported by the belt (30) and the horizontal brace (20), reinforcing bars (40) are arranged along the retaining wall (10, 12) and concrete is poured to form a wall surface (42) of the underground structure. In FIG. 2, reference numeral 46 denotes a slab forming the floor or ceiling of the underground structure. However, when a belt (30) manufactured from a conventional integral H-shaped steel is used, vertical reinforcing bars (40) cannot be arranged and concrete cannot be poured in the area where the belt (30) is installed due to interference of the belt (30). Accordingly, in an area where the belt (30) is not installed, reinforcing bars (40) are normally placed and concrete is poured to construct a wall surface (42) (A of FIG. 2), and when the area where the belt (30) is installed is reached, the already constructed concrete wall surface (42) is temporarily supported by an inclined support (raker, 44), and then the horizontal support (20) is dismantled, reinforcing bars (40) are placed and concrete is poured to continue constructing the wall surface (42) (B of FIG. 2).

However, in the conventional underground structure construction method, not only is a separate reinforcement process required to reinforce the already constructed concrete wall surface (42) with an inclined brace (44), but also in the area where the belt (30) is installed, the reinforcing bars (40) must be placed separately, and there is a problem that the concrete is not completely poured in the area where the belt (30) is installed, resulting in a gap in the wall surface (42).

Republic of Korea Patent Publication No. 10-2010-0118000 Republic of Korea Patent Publication No. 10-2014-0039781

The purpose of the present invention is to provide a truss belt that can continuously construct an underground structure by penetrating the belt and a method for constructing an underground structure using the same.

Another object of the present invention is to provide a truss belt that can construct an underground structure without dismantling the horizontal brace and thus without installing a separate inclined brace, and a method for constructing an underground structure using the same.

Another object of the present invention is to provide a truss belt that is easy to place reinforcing bars and pour concrete, and a method for constructing an underground structure using the same.

In order to achieve the above object, the present invention provides a truss belt (50) including a wall-side chord (52) that supports a retaining wall (10, 12) in a horizontal direction; an excavation-side chord (54) that supports a horizontal brace (20) and transmits earth pressure transmitted from the retaining wall (10, 12) to the horizontal brace (20); and a truss member (56) that is continuously positioned in a zigzag shape between the wall-side chord (52) and the excavation-side chord (54) and supports the wall-side chord (52) and the excavation-side chord (54) at a predetermined inclination angle to form a truss structure.

In addition, the present invention provides a method for constructing an underground structure, including the steps of installing a retaining wall (10, 12) around an excavated site (5) for constructing an underground structure, installing a truss belt (50) horizontally on the retaining wall (10, 12), and then supporting the truss belt (50) with a horizontal brace (20); and arranging reinforcing bars (40) through the truss belt (50) along the retaining wall (10, 12), and pouring concrete on the reinforcing bars (40) to form a wall surface (42) of the underground structure.

According to the truss belt according to the present invention, since the horizontal brace is not dismantled, an underground structure can be constructed continuously without installing a separate inclined brace. In addition, according to the truss belt according to the present invention and the method for constructing an underground structure using the same, there is an advantage in that reinforcement arrangement and concrete pouring are easy.

Figure 1 is a plan view (A) and a cross-sectional view (B) showing the installation status of a typical belt and horizontal brace.
Figure 2 is a drawing showing the state of construction of an underground structure after the installation of a conventional belt and horizontal braces.
Figures 3 to 5 are a plan view, a cross-sectional view taken along line bb, and a perspective view, respectively, of a truss belt according to one embodiment of the present invention.
Figure 6 is a drawing showing the state of use of a truss belt according to the present invention.
Figure 7 is a drawing showing the connection relationship between a truss belt (50) and a horizontal brace (20) according to one embodiment of the present invention.
Figure 8 is a side view showing a method for constructing an underground structure using a truss belt according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the attached drawings. In the attached drawings, the same components as in the prior art are given the same drawing reference numerals as in the prior art. In the description of the present invention, a detailed description of commonly known functions or configurations is omitted.

FIGS. 3 to 5 are a plan view, a cross-sectional view taken along line b-b, and a perspective view, respectively, of a truss belt according to an embodiment of the present invention, and FIG. 6 is a drawing showing a state of use of a truss belt according to the present invention. As illustrated in FIGS. 3 to 6, a truss belt (50) according to the present invention has a truss structure that allows penetrative arrangement of reinforcing bars (40) and concrete, replacing a conventional single H-shaped steel structure, and includes a wall-side chord member (52), an excavation-side chord member (54), and a truss diagonal member (56).

The above wall-side chord (52) is a retaining wall (10, 12) supporting member that horizontally supports a plurality of piles (10) constituting the retaining wall (10, 12), preferably the retaining wall (10, 12), so that the earth pressure acting on the retaining wall (10, 12) is uniformly transferred to the truss belt (50) and the horizontal brace (20), and is embedded in the wall surface (42) after the construction of the underground structure. The wall-side chord (52) may have various shapes capable of supporting the retaining wall (10, 12), but as best illustrated in FIG. 4, two H-shaped steel beams with a low depth (H) may be connected in parallel and used. The above excavation-side chord (54) is a horizontal chord (20) supporting member that supports the horizontal brace (20) so that the earth pressure transferred from the retaining wall (10, 12) to the truss belt (50) is transferred to the horizontal brace (20). After the construction of the underground structure, i.e., the wall surface (42), it is removed and reused. The above excavation-side chord (54) may have various shapes that can support the horizontal brace (20), and may preferably be manufactured from H-shaped steel. The above truss member (56) supports the wall-side chord (52) and the excavation-side chord (54) at a predetermined inclination angle to form a truss structure, and is continuously positioned in a zigzag shape between the wall-side chord (52) and the excavation-side chord (54). Here, the inclination angle of the truss member (56) can be set to a range in which the earth pressure applied to the wall-side chord (52) can be stably transmitted to the excavation-side chord (54) without bending or breaking the truss member (56). For example, the truss member (56) has a shape in which an angle member having a cross-sectional shape of “L” is tilted 45° to minimize the area interfering with the wall surface (42). In this way, by supporting the wall-side chord (52) and the excavation-side chord (54) with a plurality of truss members (56), a plurality of through holes (60) having a triangular shape are formed inside the truss belt (50). The truss member (56) is embedded in the wall surface (42) after the construction of the underground structure.

As illustrated in FIGS. 3 to 5, the wall-side chord (52), the truss member (56), and the excavation-side chord (54) can be connected via a connecting plate (58). For example, the connecting plate (58) is attached to the wall-side chord (52) and the excavation-side chord (54) by welding at a predetermined, uniform interval, and one end of two truss members (56) is connected to one connecting plate (58) attached to one chord, for example, the wall-side chord (52), and the other end of the two truss members (56) is connected to two adjacent connecting plates (58) attached to the other chord, for example, the excavation-side chord (54), so that the wall-side chord (52), the truss member (56), and the excavation-side chord (54) can form a truss structure. The above wall-side chord (52), truss member (56), excavation-side chord (54), and connecting plate (58) can all be made of steel, and can be joined by a conventional method such as welding or screw joining. For example, the wall-side chord (52) and the truss member (56) can be joined by welding, and the truss member (56) and the excavation-side chord (54) can be detachably joined by screw joining. The truss belt (50) can be manufactured at a factory and installed on site.

FIG. 7 is a drawing showing a connection relationship between a truss belt (50) and a horizontal brace (20) according to one embodiment of the present invention. In the present invention, the truss belt (50) and the horizontal brace (20) may be directly connected, but as shown in FIG. 7, the truss belt (50) and the horizontal brace (20) may be more stably connected and supported through a triangular belt member (22) mounted on one end of the horizontal brace (20). The triangular belt member (22) supports the truss belt (50) through one entire side of the triangle, and the horizontal brace (20) is mounted at a vertex corresponding to the side supporting the truss belt (50). Since the above-mentioned triangular belt member (22) supports the truss belt (50) over a wider area, it disperses the load applied from the truss belt (50) to the horizontal brace (20), thereby not only alleviating the local stress concentration phenomenon of the truss belt (50), but also reducing the buckling length of the horizontal brace (20), thereby improving structural stability. The size of the above-mentioned triangular belt member (22) can be changed according to the earth pressure conditions. The above-mentioned triangular belt member (22) and the truss belt (50) are connected by a detachable connecting means such as a high-strength bolt, so that the triangular belt member (22) can be reused. By using such a triangular belt member (22), the installation interval of the horizontal brace (20) can be widened, and the number of horizontal braces (20) can be reduced.

Next, referring to FIGS. 6 and 8, a method for constructing an underground structure using a truss belt according to the present invention will be described. FIG. 8 is a side view showing a method for constructing an underground structure using a truss belt according to the present invention. As illustrated in FIGS. 6 and 8, in order to construct an underground structure according to the present invention, first, a retaining wall (10, 12) is installed along the perimeter of a site (5) where an underground structure is to be formed, excavation is performed to form an excavated site (5) of a predetermined depth, and the truss belt (50) described above is installed horizontally on the retaining wall (10, 12), and then the truss belt (50) is supported by a horizontal brace (20) and, if necessary, a triangular belt member (22). At this time, a slab (46) forming a floor or ceiling of the underground structure can be constructed in an area where the truss belt (50) is not installed (A of FIG. 8). Next, the reinforcing bars (40) are arranged along the retaining wall (10, 12) through the truss belt (50), specifically, the through hole (60) of the truss belt (50), and concrete is poured into the reinforcing bars (40) to form the wall surface (42) of the underground structure (B of FIG. 8). At this time, a formwork (not shown) for forming the wall surface (42) can be installed around the arranged reinforcing bars (40), and concrete can be poured into the formwork to form the wall surface (42). In this case, at the location of the truss belt (50), the formwork is installed in small pieces so as to avoid the truss beam (56) of the truss belt (50). In this way, when reinforcing bars (40) are placed through the through holes (60) of the truss belt (50) and concrete is poured to form a wall surface (42), the wall-side chord (52) and the truss diagonal member (56) of the truss belt (50) are buried in the wall surface (42). Next, the horizontal brace (20), the triangular belt member (22) located in the area where the wall surface (42) is formed, and the excavation-side chord (54) that is not buried in the wall surface (42) are removed, thereby forming an underground structure (C of FIG. 8).

According to the truss belt according to the present invention and the method for constructing an underground structure using the same, the wall surface (42) can be constructed without dismantling the horizontal brace (20) and the truss belt (50), and there is no need to install a separate inclined brace (raker, 44, see FIG. 2). In addition, since the truss belt (50) can be manufactured in the factory and installed on site, on-site welding is minimized, thereby improving the construction speed, enabling standardized construction, and reducing construction costs. In addition, according to the present invention, since there is no need to cut the reinforcing bar (40) or separate and pour the concrete, lump-sum construction is possible without wall jointing, and there is the effect of reducing wall joints and improving water-proofing performance.

Although the present invention has been described with reference to the attached drawings and exemplary embodiments, the present invention is not limited to the contents illustrated in the drawings and the embodiments described above. Although drawing symbols are used in the claims below to aid understanding, the scope of the rights of the claims below is not limited to the drawing symbols and the contents illustrated in the drawings, but should be comprehensively interpreted to include all modifications of the exemplary embodiments, equivalent structures, and functions.

Claims (7)

Wall side chord (52) supporting the retaining wall (10, 12) in the horizontal direction;
Excavation side current (54) that supports the horizontal brace (20) and transfers the earth pressure transferred from the retaining wall (10, 12) to the horizontal brace (20); and
A truss belt (50) including a truss member (56) that is continuously positioned in a zigzag shape between the wall-side chord (52) and the excavation-side chord (54) and supports the wall-side chord (52) and the excavation-side chord (54) at a predetermined inclination angle to form a truss structure. In the first paragraph, the wall-side current (52), the truss beam (56) and the excavation-side current (54) are connected through a connecting plate (58), the truss belt (50). In the first paragraph, the wall-side siding (52) and the truss member (56) are joined by welding, and the truss member (56) and the excavation-side siding (54) are detachably joined by screw connection, a truss belt (50). In the first paragraph, the truss member (56) is a truss belt member (50) that is formed by tilting an angle member having a cross-sectional shape of “L” at an angle of 45°. A step of installing a truss belt (50) horizontally on a retaining wall (10, 12) installed around a site (5) for constructing an underground structure, and then supporting the truss belt (50) with a horizontal brace (20); and
It includes a step of arranging reinforcing bars (40) through truss belts (50) along the above-mentioned retaining wall (10, 12) and pouring concrete on the reinforcing bars (40) to form a wall surface (42) of an underground structure.
Here, the truss belt (50) includes a wall-side chord (52) that supports the retaining wall (10, 12) in the horizontal direction, an excavation-side chord (54) that supports the horizontal brace (20) and transmits the earth pressure transmitted from the retaining wall (10, 12) to the horizontal brace (20), and a truss member (56) that is continuously positioned in a zigzag shape between the wall-side chord (52) and the excavation-side chord (54) and supports the wall-side chord (52) and the excavation-side chord (54) at a predetermined inclination angle to form a truss structure. A method for constructing an underground structure, further comprising the step of removing a horizontal support (20) located in an area where the wall surface (42) is formed and an excavation side current (54) not buried in the wall surface (42), in the fifth paragraph. A method for constructing an underground structure, wherein, in clause 5, a truss belt member (50) and a horizontal brace (20) are connected through a triangular belt member (22) mounted on one end of the horizontal brace (20).