KR102260481B1 - Bracing structure for soil sheathing and wall construction method using the same - Google Patents

Abstract

The present invention relates to a bracing structure for a soil sheathing process, which is installed on a soil sheathing side wall installed for constructing a building in an underground space, comprising: a first bracing member extended in a first transversal direction which crosses the underground space; a second bracing member engaged with end units on one side or both sides of the first bracing member, and extended in a second transversal direction which crosses the first transversal direction; and a strut unit placed in the first transversal direction, whose one end unit is engaged with the second bracing member, and whose other end unit is connected to an inner side surface of the soil sheathing side wall. As such, the present invention is able to construct a wall which is higher than the installation position of the bracing before dismantling the bracing, increase the degree of freedom of construction, and reduce the construction period.

Description

BRACING STRUCTURE FOR SOIL SHEATHING AND WALL CONSTRUCTION METHOD USING THE SAME

The present invention relates to a bracing structure for a retaining process and a wall construction method using the same, and more particularly, to a bracing structure for a retaining process that can shorten the air period and increase the degree of freedom in construction, and a wall construction method using the same will be.

In general, at the construction site of a building having an underground floor, excavation work is preceded by less than the number of basement floors used. Therefore, the process of installing a temporary structure to secure an underground space for performing construction work and to resist the earth pressure of the side wall of the space in order to prevent subsidence of the surrounding ground is called a retaining process, and at this time, a temporary reinforcement structure that can be installed An example of the bracing structure may be mentioned.

This retaining bracing structure is installed across both sides of the excavated underground space and is configured to resist earth pressure by applying lateral pressure to the retaining side walls such as retaining boards and pile walls built on the inner surface of the space. On the other hand, temporary structures such as such bracing are usually demolished only when load-bearing members are built in an underground space to resist earth pressure without bracing. That is, a plurality of bracings are installed at regular intervals along the height direction of the underground space, and as construction progresses, the bracings are sequentially removed.

On the other hand, since the retaining bracing is a fairly large-scale temporary member and is installed across both sides of the underground space at the same time, it may act as an obstacle to the construction of the basement floor of the building. This is especially true when constructing the basement wall of a building, since the basement wall must pass in front of the retaining wall and bracing connects the retaining side walls on both sides to each other, making the basement wall impassable. Of course, hasty dismantling of the bracing may cause collapse of the retaining wall and subsidence of the surrounding ground, so disassembling the bracing first to simply construct the basement wall can be very risky. For this reason, in the prior art, the construction of the basement wall was limited to the lower part of the bracing.

That is, as the conventional bracing structure for retaining material approaches as a limiting factor with respect to the construction of the basement wall, there is a problem in that the construction height of the wall, the construction method, and the degree of freedom are limited, and the air for wall construction and disassembly of the bracing structure There was also the problem of increasing.

Korean Patent Publication No. 10-1218825 (2012.12.28)

An object of the present invention is to provide a bracing structure for a retaining process capable of increasing the degree of freedom of wall construction and shortening the air, and a wall construction method using the same.

According to one aspect of the present invention, in the bracing structure for the retaining process installed on the retaining side wall installed for the construction of a building in the underground space, the first extending along the first transverse direction crossing the underground space A bracing member and a second bracing member coupled to one or both ends of the first bracing member, the second bracing member extending along the second transverse direction intersecting the first transverse direction, and disposed along the first transverse direction, one end portion It is coupled to the second bracing member, the other end can provide a bracing structure for retaining process, characterized in that it comprises a strut portion connected to the inner surface of the retaining wall.

Here, one end of the strut part is coupled to the second bracing member, and the other end is interposed between one or a plurality of strut members connected to the inner surface of the retaining side wall and the retaining side wall and the strut member, and a length adjustment unit capable of adjusting the length. It may be configured to further include. In detail, the length adjustment unit can be applied with a jack (jack).

The strut member may have a longitudinal direction parallel to the longitudinal direction of the first bracing member. Furthermore, the strut member may include a plurality of first strut members arranged to be aligned with respect to the first bracing member, and a plurality of second strut members arranged symmetrically to each other on both sides of the first strut member. can

On the other hand, a wall is installed between the first bracing member and the retaining side wall, and the strut part has one end coupled to the retaining side wall, and the other end is coupled to one side wall of the wall facing the retaining side wall. An inner strut member, and one end of the wall Coupled to the other side wall, the other end may be configured to include an outer strut member coupled to the second bracing member.

In this case, the strut part may be configured to further include a connecting member that is installed inside the wall, one end is coupled to the inner strut member and the other end is coupled to the outer strut member.

Here, the strut member is installed through an opening formed through the wall, and may be configured to be coupled to the wall by pouring concrete through the opening.

In addition, a wall is installed between the first bracing member and the retaining wall, and the strut member is installed through a separation space formed between adjacent walls, and may be configured to be coupled with the walls by concrete pouring of the separation space. .

The bracing structure for the retaining process of the present invention may further include a brace member having one end coupled to the end of the first bracing member, and the other end being coupled to the side surface of the second bracing member.

On the other hand, the strut portion may be configured such that one end is fixedly coupled to the second bracing member. In addition, one end of the strut portion may be configured to be detachably coupled to the second bracing member.

According to another aspect of the present invention, the present invention provides a first bracing member installed along a first transverse direction crossing the underground space of a building, and a second intersecting first transverse direction at one or both ends of the first bracing member A second bracing member installed along the transverse direction, and disposed along the first transverse direction, one end coupled to the second bracing member, the other end includes a strut portion connected to the inner surface of the retaining wall, the strut portion, one end One or a plurality of strut members coupled to the second bracing member, the other end being connected to the inner surface of the retaining side wall, and interposed between the retaining side wall and the strut member, a length adjustment unit capable of length adjustment, and one end of the retaining side wall An inner strut member coupled with the other end to one side wall of the wall facing the retaining wall, and an outer strut member having one end coupled to the other side wall of the wall and the other end coupled to the second bracing member, and the inside of the wall In the state where the bracing structure for retaining process is installed, one end is coupled to the inner strut member and the other end includes a connecting member coupled to the outer strut member, the first bracing member and the retaining member are installed to the position where the strut member is installed. installing a part of the wall between the side walls, and installing a part of the wall so that one side is connected to the strut member so that the wall is supported; A method comprising: installing a connecting member inside a wall, and installing an inner strut member and an outer strut member to be connected to the connecting member; It is possible to provide a wall construction method using a bracing structure for retaining process, characterized in that it comprises the step of removing the strut member and installing the rest of the wall after the inner strut member and the outer strut member are installed on a part of the wall. have.

According to another aspect of the present invention, the present invention provides a first bracing member installed along a first transverse direction crossing the underground space of a building, and a first bracing member intersecting the first transverse direction at one or both ends of the first bracing member 2 A second bracing member installed along the transverse direction, disposed along the first transverse direction, one end coupled to the second bracing member, and the other end connected to the inner surface of the retaining side wall one or a plurality of first strut members In the state in which the bracing structure for the retaining process comprising the strut part is installed, a part of the wall is installed between the first bracing member and the retaining side wall to the position where the strut part is installed, and one side is connected to the strut member so that the wall is supported. The steps of installing a part of the wall, installing the second strut member through the opening formed through the wall, coupling both ends of the second strut member to the retaining side wall and the second bracing, respectively, pouring concrete into the opening 2 A bracing structure for retaining process, characterized in that it comprises the steps of installing a strut member and installing the remaining part of the wall after removing the first strut member in a state where the second strut member is installed on a part of the wall It is possible to provide a wall construction method used.

Also, according to another aspect of the present invention, the present invention provides a first bracing member installed along a first transverse direction crossing the underground space of a building, and one or both ends of the first bracing member intersecting the first transverse direction A second bracing member installed along the second transverse direction, and disposed along the first transverse direction, one end coupled to the second bracing member, and the other end connected to the inner surface of the retaining side wall, one or a plurality of first strut members In a state in which the bracing structure for the retaining process comprising a strut part comprising a is installed, a part of the wall is installed between the first bracing member and the retaining side wall to the position where the strut part is installed, but one side is connected to the strut member so that the wall is supported and installing a part of the wall; A second strut member is installed through the space formed between adjacent walls, and both ends of the second strut member are coupled to the retaining side wall and the second bracing part, respectively, and then concrete is poured into the spaced space for the second strut. A wall using a bracing structure for retaining process, characterized in that it comprises the steps of installing a member, and installing the remaining part of the wall after removing the first strut member in a state where the second strut member is installed on a part of the wall Construction methods can be provided.

Here, the strut portion is interposed between the retaining side wall and the first strut member, the second strut member and the inner strut member, and may further include a length adjustment unit capable of length adjustment, wherein the length adjustment unit is a jack ( jack) can be applied.

On the other hand, since the description of the technology disclosed in this specification is merely an embodiment for structural or functional description, the scope of the disclosed technology should not be construed as being limited by the embodiment described in the text. That is, since the embodiment may have various changes and may have various forms, it should be understood that the scope of the disclosed technology includes equivalents capable of realizing the technical idea. In addition, since the object or effect presented in the disclosed technology does not mean that a specific embodiment should include all of them or only such effects, it should not be understood that the scope of the disclosed technology is limited thereby.

In addition, the meaning of the terms described in the present invention should be understood as follows. Terms such as “first” and “second” are for distinguishing one component from another, and the scope of rights should not be limited by these terms. For example, a first component may be termed a second component, and similarly a second component may be termed a first component.

Furthermore, when it is mentioned that a certain element is "connected" to another element, it may be directly connected to the other element, but it should be understood that other elements may exist in between. On the other hand, when it is mentioned that a certain element is "directly connected" to another element, it should be understood that the other element does not exist in the middle. On the other hand, other expressions describing the relationship between elements, that is, "between" and "between" or "neighboring to" and "directly adjacent to", etc., should be interpreted similarly.

The singular expression is to be understood to include the plural expression unless the context clearly dictates otherwise, and terms such as "comprises" or "have" refer to the specified feature, number, step, action, component, part or these It is intended to indicate that a combination exists, and it should be understood that it does not preclude the possibility of the existence or addition of one or more other features or numbers, steps, operations, components, parts, or combinations thereof.

The bracing structure for the retaining process and the wall construction method using the same according to the present invention enable the construction of a wall having a height greater than the installation position of the bracing before disassembling the bracing, thereby increasing the degree of freedom of construction and removing the air. It can provide a shortening effect.

1 is a view showing a bracing structure for retaining process according to an embodiment of the present invention.
Figure 2 is a view showing another embodiment of the bracing structure for retaining process according to an embodiment of the present invention.
3 is a view showing a state in which a strut part is constructed as a space between walls in a bracing structure for a retaining process according to an embodiment of the present invention.
4 is a view showing a state in which a strut part is constructed as an opening formed in a wall in the bracing structure for a retaining process according to an embodiment of the present invention.
5 to 12 are views showing a wall construction method using a bracing structure for retaining process according to an embodiment of the present invention.
13 to 18 are views showing another embodiment of the wall construction method using the bracing structure for the retaining process according to the embodiment of the present invention.

Hereinafter, it will be described in more detail with reference to preferred embodiments to which the present invention pertains.

First, the bracing structure for the retaining process according to an embodiment of the present invention is applied for the retaining process in the underground space during construction of a building, and a retaining side wall is built in the underground space after excavation to prevent surrounding soil and soil, here A retaining board installed between a plurality of braces or a pile wall composed of a plurality of piles may be included. And the retaining wall is usually installed along the width direction wale (wale), the bracing structure can be coupled to such a wale.

Hereinafter, a bracing structure for a retaining process (hereinafter referred to as a 'bracing structure') according to an embodiment of the present invention will be described with reference to the drawings.

1, the bracing structure of the present invention is installed on the retaining side wall 10 installed for the construction of a building in an underground space, and a first bracing member 100, a second bracing member 200, and a strut It may consist of parts.

First, the first bracing member 100 is installed extending along the first transverse direction crossing the underground space. The first bracing member 100 may apply a known H-beam, etc., but is not limited thereto, and various configurations may be applied if the purpose of supporting the retaining side wall 10 can be achieved.

The second bracing member 200 is coupled to one or both ends of the first bracing member 100 and is installed to extend along a second transverse direction intersecting the first transverse direction. In the drawings, the second bracing member 200 is coupled to cross at right angles to the first bracing member 100 , but is not limited thereto. In addition, the second bracing member 200, it is preferable to apply the configuration of the same standard as the first bracing member 100, but is not limited thereto, and, like the first bracing member 100, various configurations such as H-beam can be applied.

The strut part is disposed along a first transverse direction parallel to the first bracing member 100 , one end is coupled to the second bracing member 200 , and the other end is connected to the inner surface of the retaining wall 10 .

Specifically, the strut part may include a strut member 310 and a length adjustment unit 320 .

The strut member 310, one end is coupled to the second bracing member 200, the other end is connected to the inner surface of the retaining wall (10). Here, the strut member 310 may be coupled to the retaining side wall 10, for example, a specific portion of the wale.

In addition, the strut member 310 may have a longitudinal direction parallel to the longitudinal direction of the first bracing member 100 .

On the other hand, the strut member 310 may be configured in one or a plurality, and when configured as one, the first to prevent buckling of the second bracing member 200 without eccentric earth pressure of the retaining side wall 10 . It is preferable to be arranged to be aligned with the first bracing member 100 so as to be delivered to the bracing member 100 .

On the other hand, when the strut member 310 is composed of a plurality, the second bracing member 200 is symmetrically disposed at equal intervals in the longitudinal direction to evenly distribute the earth pressure transmitted from the retaining side wall 10 to distribute the first It is preferable to transmit it to the bracing member 100 .

In the drawings, a case in which the strut member 310 is composed of three members is shown as an embodiment. In this case, the strut member 310 is disposed to be aligned with the first bracing member 100 and is symmetrical to each other on both sides of the first strut member 311 and the first strut member 311 positioned at the center. It may be configured to include a pair of second strut members 312 that are arranged to be.

The length adjustment unit 320 is interposed between the retaining wall 10 and the strut member 310, and is configured to be adjustable in length. Here, the length adjustment unit 320, easy handling and length adjustment can be applied to an easy jack (jack), but is not limited thereto.

On the other hand, this length adjustment unit 320 can provide an effect of not only adjusting the overall length of the strut part, but also adjusting the lateral force applied by the bracing structure to the retaining wall 10 through length adjustment.

Meanwhile, the strut part may be coupled to the first bracing member 100 in various coupling methods. For example, the strut part may be configured such that one end of the strut member 310 is fixedly coupled to the second bracing member 200 through welding, etc., and the length of the strut member 310 can be adjusted through the length adjustment unit 320 . have.

Alternatively, one end of the strut portion may be configured to be detachably coupled to the second bracing member 200 . Such a detachable configuration can be applied in various ways, such as a bolt coupling configuration using a fastening bolt and a nut, and a detailed description thereof will be omitted.

According to the above bar, one end of the strut member 310 is configured to be coupled to the retaining side wall 10 , and the other end is coupled to the second bracing member 200 , so that all or part of the lateral force applied by the bracing structure is used as a retainer. It is transmitted to the side wall 10, and the lateral force applied to the retaining wall 10 through the length adjustment unit 320 can also be adjusted.

On the other hand, the bracing structure for the retaining process of the present invention, one end is coupled to the end of the first bracing member 100, the other end is a brace member 600 coupled to the side of the second bracing member 200 (brace) It may be configured to further include.

The brace member 600 may be coupled to a plurality of strut members 310 to the first bracing member 100, and may transmit a lateral force applied to the retaining side wall 10 through one or more strut members 310, In consideration of this, the stress transfer between the components is effectively made, so as to prevent deformation of the coupling structure between each other, and to have a stable structure.

Meanwhile, referring to FIG. 2 , when the wall 20 is installed between the first bracing member 100 and the retaining side wall 10 , one end of the strut part is coupled to the retaining side wall 10 , and the other end is the retaining side wall. An inner strut member 410 coupled to one side wall of the wall 20 facing the 10, one end coupled to the other side wall of the wall 20, and the other end coupled to the second bracing member 200 It may be configured to include an outer strut member (420).

Here, the inner strut member 410 and the outer strut member 420 are, as shown, the retaining side wall 10, the wall 20 and the second bracing member 200 through the bolted configuration and length adjustment unit 440 as shown. ) can be detachably coupled to. Accordingly, in the present invention, there is no need to dismantle the bracing structure during construction of the wall 20, and it is possible to escape the constraint of increasing the construction height of the wall 20 in order to avoid interference with the bracing structure.

In this way, when the inner strut member 410 and the outer strut member 420 are coupled to the wall 20, the strut part connects the inner strut member 410 and the outer strut member 420 to each other through the connecting member 430. can be connected

This connection member 430 is installed inside the wall 20, one end is through-fastened with the wall 20 to be coupled with the inner strut member 410, and the other end is also through-fastened with the wall 20 to be through-fastened with the outer strut. It is coupled to the member 420 and is configured to be positioned in a straight line with the inner strut member 410 and the outer strut member 420 .

Here, in order for the inner strut member 410, the connecting member 430, and the outer strut member 420 to be connected to each other in a straight line, the inner strut member 410 is formed on both outer surfaces of the wall 20 (PC panel). ) and the outer strut member 420 may be formed with a mark or a coupling part that can be visually recognized by the operator in order to help the coupling to the designated position.

On the other hand, here, the wall 20 is a single-ply PC panel in which the connecting member 430 in the wall 20 is embedded in concrete, or both ends of the connecting member 430 in the wall 20 are each concrete panel. Various embodiments are possible, such as a hollow PC panel embedded in a PC panel or a panel in which on-site concrete is poured into the space inside the hollow PC panel. Furthermore, as the wall 20 in the drawing, a PC (Precast Concrete) wall 20 may be used, but the present invention is not limited thereto. In some embodiments, the cast-in-place concrete wall 20 using a formwork may be used.

The connection member 430, as shown, can be applied with a bolt fastening configuration with a steel bar member, and various coupling configurations can be applied as long as it is a configuration that can be installed after the wall 20 is constructed.

As described above, the strut part can correctly transmit the lateral force applied by the bracing structure constructed by connecting the inner strut member 410, the connecting member 430, and the outer strut member 420 to the retaining side wall 10. .

The strut part is interposed between the retaining side wall 10 and the inner strut member 410, and may be configured to include a length adjustment unit 440 capable of length adjustment, and this length adjustment unit 440 is the above-described With the same configuration as the length adjustment unit 320, it is possible to adjust the length of the strut part as well as adjust the lateral force applied to the retaining wall 10, and a detailed description thereof will be omitted.

Hereinafter, with reference to FIGS. 3 and 4 , when the wall 20 is installed, an embodiment in which the strut member 310 is installed through the wall 20 instead of the above-described connecting member 430 will be described. do it with

First, referring to FIG. 3 , the strut member 310 is formed between the adjacent walls 20 when the wall 20 is installed between the first bracing member 100 and the retaining side wall 10 . It is installed through the separation space 22 , and may be configured to be coupled with the walls 20 by pouring concrete in the separation space 22 .

That is, the basement wall 20 of the building may include a plurality of PC wall 20 modules, and the PC wall 20 modules adjacent to the portion where the connecting member 430 is installed in the wall 20 are spaced apart from each other. (22) is installed to form, the connection member 430 is located in this separation space 22, and then, when the wall 20 is constructed, the formwork is installed in the space 22 between the PC wall 20 modules. It can be constructed by pouring on-site concrete.

Next, referring to FIG. 4 , the strut member 310 may be installed through the opening 21 formed through the wall 20 . In this case, the strut member 310 may be configured to be coupled to the wall 20 by installing a formwork and pouring concrete after being installed in the opening 21 formed in advance by processing to the adjacent side.

That is, in this case, the wall 20 is a connecting member in the wall 20 when the PC wall 20 module adjacent to the part where the connecting member 430 is to be installed is processed in advance and the PC wall 20 module is coupled to each other. The opening 21 for coupling of the 430 may be configured to be formed. In this case, even if the PC wall 20 modules are coupled to each other, it is possible to insert and install the connecting member 430 through the opening 21 formed thereby, and between the PC wall 20 modules during the subsequent construction of the wall 20 It can be constructed by installing a formwork in the opening 21 formed in the , and pouring on-site concrete. Here, Fig. 3 and Fig. 4 (a) shows a plan view, and (b) shows a front view.

Hereinafter, a wall 20 construction method (hereinafter referred to as 'wall 20 construction method') using the bracing structure of the present invention will be described. First, since the bracing structure uses the above-described bracing structure, a detailed description thereof will be omitted since it has been described above. Accordingly, the following will focus on the wall 20 construction method. In addition, the inner strut member 410 and the outer strut member 420 of FIG. 2 described above are named as coupling-type strut members coupled to the inside and outside of the wall 20, respectively, and the strut member 310 of FIG. 1 is the first 1 The bracing member 100 and the retaining side wall 10 will be named as an integrated strut member coupled to each construction method will be described.

First, in the wall construction method according to the embodiment of the present invention, a part of the wall 20 is installed between the first bracing member 100 and the retaining side wall 10 up to the position where the strut member 310 is installed, but the wall 20 ) to be supported so that one side is connected to the integral strut member, and a part of the wall 20 is installed.

Then, the connecting member 430 is installed inside the wall 20 at a designated position, and the inner strut member 410 and the outer strut member 420 are installed so as to be connected to the connecting member 430 to form a combined strut member. install

When the inner strut member 410 and the outer strut member 420 are installed on a part of the wall 20 in this way, the integral strut member 310 of the central part is removed in this state, and then the rest of the wall 20 is installed.

On the other hand, here, in installing the wall 20 and the strut member 310, the integrated strut member 310 can be installed instead of the coupling strut member including the inner strut member 410 and the outer strut member 420 described above. have.

In this case, the strut member 310 may be installed as a space 22 between the opening 21 formed in the wall 20 and the wall 20 .

First, looking at the case where the strut member 310 is installed in the opening 21, a part of the wall 20 is connected to the first strut member 311 in the center so that the wall 20 is supported, and the wall 20 ) part is installed, and in this state, the second strut member 312 is installed through the opening 21 formed through the wall 20 in advance, so that both ends of the second strut member 312 are connected to the retaining side wall 10 and Coupled to each of the second bracing portion. In this case, the coupling and fixing of the second strut member 312 may be performed by a worker pouring concrete into the opening 21 in the field.

When the second strut member 312 is installed to one side in this way, after the first strut member 311 is removed in this state, the remaining part of the wall 20 is installed, and the installation of the remaining part of the wall 20 is described above. Since it proceeds in the same process as the process, a detailed description thereof will be omitted.

Next, a case in which the strut member 310 is installed in the space 22 between the adjacent walls 20 instead of the opening 21 of the wall 20 will be described. Also in this case, first, a part of the wall 20 is connected to the first strut member 311 in the center so that the wall 20 is supported, and a part of the wall 20 is installed, and in this state, the adjacent walls 20 ) by installing the second strut member 312 through the spaced space 22 formed between them, both ends of the second strut member 312 are coupled to the retaining side wall 10 and the second bracing portion, respectively. At this time, the coupling and fixing of the second strut member 312 may be performed by a worker pouring concrete into the opening 21 in the field as in the above-described opening 21 .

In this way, when the second strut member 312 is installed on a part of the wall 20 , the first strut member 311 is removed in this state and the remaining part of the wall 20 is installed.

On the other hand, in the above-described wall construction method, the above-described length adjustment units 320 and 440 can be installed, of course, and a description thereof will be omitted since it has been described above.

Hereinafter, with reference to Figs. 12 to 18, the wall construction method of the present invention will be described in detail.

First, in the case of FIGS. 5 to 12, the wall 20 is constructed on one side of the integrated strut member (first strut member 311) and then the wall 20 is sequentially constructed on the other side, and FIG. 13 18 to 18 show that the wall 20 is constructed on one side of the integrated strut member 310 and a part of the wall 20 is constructed symmetrically on the other side of the integrated strut member 310, and then each wall 20 is connected. Yes.

First, a wall construction method will be described with reference to FIGS. 5 to 13 . First, in the case of the bracing structure on the right, the basement wall 20 has already been constructed at the installed position, and the bracing structure passes through the wall 20 and is coupled to the retaining wall 10 . In each of the left and middle bracing structures, one integral strut member 310 is coupled to the middle of the first bracing member 100, and three coupled strut members are coupled to the right bracing structure. In this state, a method of constructing the wall 20 based on the location of the intermediate integral strut member 310 will be described.

Referring to FIG. 5 , the basement wall 20 can be constructed in a state in which the bracing structure is installed in the underground space, and it is possible to first construct the wall 20 in a portion where the bracing structure is not located.

Referring to FIG. 6 , in the state where the integral strut member 310 in the middle is coupled to the first bracing member 100, the wall 20 is constructed up to the front of the position where the right strut member 310 is coupled in the drawing. can

That is, the basement wall 20 may be constructed even before the coupling position of the right strut member 310 in proximity to the strut member 310 in the middle. Here, in front of the coupling position of the right strut member 310, a space 22 or an opening 21 may be prepared in the wall 20 for coupling of the strut member 310 in the wall 20, or the wall ( 20) A PC panel having an inner connecting member 430 (steel bar member) installed therein may be provided.

Referring to FIG. 7 , the left strut member 310 may be coupled to the first bracing member 100 , and the right strut member 310 passing through the constructed wall 20 may be coupled. The process of coupling the right strut member 310 is, for example, coupling the inner strut members 410 and 300 to the first bracing member 100, and the separation space 22 of the wall 20 or the opening ( After inserting the connecting member 430 in the wall 20 to pass through 21), the other end of the connecting member 430 in the wall 20 is coupled to one end of the inner strut member 410, and to the retaining side wall 10 This may be accomplished by a process of coupling the other end of the coupled outer strut member 420 to one end of the connecting member 430 in the wall 20 .

On the other hand, the description that the strut member 310 passing through the constructed wall 20 can be coupled here is a concept encompassing the case of using the PC panel in which the connecting member 430 in the wall 20 is installed therein.

That is, when the PC panel in which the connecting member 430 is installed in the wall 20 in FIG. 6 is provided, the inner strut member 410 and the outer strut member 420 can be coupled to the corresponding PC panel, which is also It is included in the concept of coupling the strut member 310 passing through the constructed wall 20 .

In this embodiment, the first bracing member 100, the inner strut member 410, the wall 20, the PC panel), the outer strut member 420, and the coupling type strut member by the process of coupling the retaining side wall 10 to each other can form. Furthermore, the present invention is not limited to a specific order with respect to the coupling order of the strut member 310 or its components. Before and after coupling the strut member 310, the length may be adjusted by manipulating the length adjustment unit 440 as needed.

Referring to FIG. 8 , in a state in which the left and right strut members 310 are coupled, the intermediate strut member 310 may be removed, and the wall 20 may be constructed at the corresponding position. As described above, in front of the coupling position of the intermediate strut member 310, a spaced space 22 or an opening 21 may be prepared in the wall 20 for coupling of the strut member 310 in the wall 20, Alternatively, a PC panel in which the connecting member 430 in the wall 20 is installed may be provided. Since the left and right strut members 310 are completely coupled to transmit the lateral force of the bracing structure to the retaining side wall 10, even if the intermediate strut member 310 is removed, the retaining side wall 10 is not likely to collapse.

Referring to FIG. 9 , the intermediate strut member 310 passing through the constructed wall 20 may be coupled. This process may be substantially the same as the coupling process of the right strut member 310 described with reference to FIG. 3 .

Referring to FIG. 10 , in a state in which the middle and right strut members 310 are coupled to the first bracing member 100 , the wall 20 can be constructed up to a position before the coupling position of the left strut member 310 .

That is, the basement wall 20 may be constructed up to or beyond the position of the left strut member 310 following the wall 20 constructed at the position of the intermediate strut member 310 . As described above, in front of the coupling position of the left strut member 310, a spaced space 22 or an opening 21 may be prepared in the wall 20 for the coupling of the strut member 310 in the wall 20, Alternatively, a PC panel in which the connecting member 430 in the wall 20 is installed may be provided.

Referring to FIG. 11 , the left strut member 310 passing through the constructed wall 20 may be coupled. This process may be substantially the same as the coupling process of the right strut member 310 described with reference to FIG. 3 .

According to the above, since it is possible to bear the lateral force only with the middle and right strut members 310, the case of omitting the process of coupling the left strut member 310 in this step may be considered, but in this case, the middle and right strut members ( Since the resultant force of the stress applied to the 310 does not coincide with the extending direction of the second bracing member 200 , if it is left for a long time, the possibility of buckling may increase. Therefore, it may be advantageous to install the left strut member 310 so that the resultant force of the stress applied to the strut members 310 coincides with the extending direction of the second bracing member 200 .

On the other hand, the case of removing the right strut member 310 instead of adding the left strut member 310 as necessary may be considered. In this case, since only the intermediate strut member 310 remains, the stress applied to the strut member 310 may match the extending direction of the second bracing member 200 . However, since the intermediate strut member 310 at this time is composed of several components coupled to each other and may have lower strength than the integral member, it may be advantageous to include both the left and right strut members 310 to share the stress. have.

Referring to FIG. 12 , the wall 20 may be continuously constructed in a portion where the bracing structure is not located following the wall 20 constructed in FIG. 7 . 5 to 12, the wall 20 at the position where the strut member 310 is installed and the wall 20 at the position where the bracing structure is not installed are composed of different modules, so that these wall 20 modules are at different stages Although the construction case is illustrated by way of example, the present invention is not limited in this way.

For example, the wall 20 module constructed at the position where the left strut structure is to be installed in FIG. 6 and the wall 20 module at the position where the bracing structure is not installed in FIG. 8 are the same module or in the step shown in FIG. It could be done at the same time.

Next, a wall construction method using a bracing structure for retaining process according to another embodiment of the present invention will be described with reference to FIGS. 13 to 18 . The construction method of the wall related to the bracing structure will be described focusing on the intermediate bracing structure shown in the drawings.

Referring to FIG. 13 , the basement wall 20 can be constructed in a state in which the bracing structure is installed in the underground space, and it is possible to first construct the wall 20 in a portion where the bracing structure is not located.

Referring to FIG. 14 , in a state in which the intermediate integral strut member 310 is coupled to the first bracing member 100, the wall 20 can be constructed up to the front of the position where the right strut member 310 is coupled. .

That is, the basement wall 20 may be constructed even before the coupling position of the right strut member 310 in proximity to the strut member 310 in the middle. As described above, in front of the coupling position of the right strut member 310, a spaced space 22 or an opening 21 may be prepared in the wall 20 for coupling of the strut member 310 in the wall 20, Alternatively, a PC panel in which the connecting member 430 in the wall 20 is installed may be provided.

Referring to FIG. 15 , the right strut member 310 passing through the constructed wall 20 may be coupled in a state in which the intermediate integral strut member 310 is coupled to the first bracing member 100 . A process of coupling the right strut member 310 may be substantially the same as the coupling process described with reference to FIG. 7 .

Referring to FIG. 16 , in a state in which the middle and right strut members 310 are coupled to the first bracing member 100 , the wall 20 may be constructed in front of the position where the left strut member 310 is coupled.

That is, the basement wall 20 is the left side of the wall 20 in a state where the wall 20 is not yet constructed at the position of the intermediate strut member 310, and the wall 20 is constructed at a position including the front of the left strut member 310. can do. As described above, in front of the coupling position of the left strut member 310, a spaced space 22 or an opening 21 may be prepared in the wall 20 for the coupling of the strut member 310 in the wall 20, Alternatively, a PC panel in which the connecting member 430 in the wall 20 is installed may be provided.

17, in a state in which the middle and right strut members 310 are coupled to the first bracing member 100, the left strut member 310 passing through the constructed wall 20 can be coupled, Subsequently, the intermediate strut member 310 may be removed. A process of coupling the left strut member 310 may be substantially the same as the coupling process described with reference to FIG. 3 .

Referring to FIG. 18 , the wall 20 may be constructed at a position corresponding to the position of the removed intermediate strut member 310 . That is, as described in FIGS. 14 and 16 , the wall 20 has already been constructed at positions corresponding to the positions of the right strut member 310 and the left strut member 310 , and the spaced space 22 therebetween. ), since the intermediate strut member 310 was removed, it is possible to construct the wall 20 in the spaced space 22 by connecting the walls 20 on both sides to each other.

11, when only the middle and right strut members 310 are installed, the resultant stress does not coincide with the extension direction of the second bracing member 200. Therefore, if left unattended for a long time, the possibility of buckling, etc. Although it has been mentioned that it can be raised, when the left and right strut members 310 are used as in FIG. 14 , the left strut member 310 and the right strut member 310 are separated from the axis of the second bracing member 200 . If they are located at the same distance, the resultant force of the stresses applied thereto will coincide with the extending direction of the second bracing member 200 .

Of course, following the configuration shown in Fig. 14, the intermediate strut member 310 passing through the wall 20 can be combined, and in this case, the stress shared by each strut member 310 will be small, so that a more stable structure can be obtained. can

In the above, for convenience of explanation, the integral strut member 310 and the coupling type strut member have been separately mentioned, but in all cases, the integrated strut member 310 may be replaced with the coupled type strut member in the combined form. . In addition, for convenience of explanation, it is mentioned that the inner strut member 410 of the coupling type strut member is coupled between the first bracing member 100 and the wall 20 after the integral strut member 310 is completely removed for convenience of explanation. However, the present invention is not limited to these details.

For example, in one embodiment of the present invention, when the strut member 310 is removed, only the remaining part except the inner strut member 410 of the corresponding strut member 310 is removed, and the inner strut member 410 is the first It may remain coupled to the bracing member 100 . In this case, the wall 20 to be constructed may be constructed adjacent to or in combination with the inner strut member 410 remaining in the first bracing member 100 , and at the same time or subsequent to the connection member in the wall 20 . 430 and the outer strut member 420 may be coupled. In this case, it can be seen that the first bracing member 100 includes a plurality of inner strut members 410 .

As another example, the inner strut member 410 may be omitted in the coupling type strut member. That is, the coupling type strut member may be composed of a connecting member 430 and an outer strut member 420 within the wall 20 . In this case, the wall 20 to be constructed may be constructed adjacent to or in combination with the first bracing member 100, and at the same time or subsequent to the connection member 430 in the wall 20 is the first bracing member ( 100) can be directly coupled.

In some embodiments in which a PC panel in which the connecting member 430 in the wall 20 is installed is used, all of the strut members 310 may be integrally formed in the PC panel. That is, the connecting member 430 in the wall 20 may be located inside the PC panel, and the inner strut member 410 and the outer strut member 420 may be formed on both sides of the outer surface of the PC panel, respectively. . In this case, the construction of the wall 20 at a position corresponding to the position of the strut member 310 combines the inner strut member 410 formed on the PC panel to the first bracing member 100 and the outer strut formed on the PC panel The process of coupling the member 420 to the retaining wall 10 may be included.

Of course, it is also possible that the strut member 310 is integrally formed with the PC panel and the inner strut member 410 is omitted or the inner strut member 410 is included in the first bracing member 100 . In this case, in the construction of the wall 20 at a position corresponding to the position of the strut member 310 , the connecting member 430 in the wall 20 formed in the PC panel is directly connected to the first bracing member 100 or the first The process of coupling to the inner strut member 410 formed in the bracing member 100 and coupling the outer strut member 420 formed in the PC panel to the retaining side wall 10 may be included.

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

Although the above has been described with reference to the preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the claims below. You can do what you can do.

10: retaining side wall 20: wall
21: opening 22: separation space
100: first bracing member 200: second bracing member
310: strut member 311: first strut member
312: second strut member 320: length adjustment unit
410: inner strut member 420: outer strut member
430: connection member 440: length adjustment unit
600: brace member

Claims (6)

In the bracing structure for the retaining process installed on the retaining side wall 10 installed for the construction of a building in the underground space,
a first bracing member 100 extending along a first transverse direction crossing the underground space;
a second bracing member 200 coupled to one or both ends of the first bracing member 100 and extending along a second transverse direction intersecting the first transverse direction;
It is disposed along the first transverse direction, one end is coupled to the second bracing member 200, the other end is a strut portion connected to the inner surface of the retaining side wall 10; includes,
The strut part,
One end is coupled to the second bracing member 200, the other end is one or a plurality of strut members 310 connected to the inner surface of the retaining side wall 10, the retaining side wall 10 and the strut member 310 ) interposed between, and configured to further include a length adjustment unit 320 capable of length adjustment,
A wall 20 is installed between the first bracing member 100 and the retaining side wall 10,
The strut part,
An inner strut member 410 that one end is coupled to the retaining side wall 10, and the other end is coupled to one side wall of the wall 20 facing the retaining side wall 10;
an outer strut member 420 having one end coupled to the other side wall of the wall 20 and the other end coupled to the second bracing member 200;
a connecting member 430 installed inside the wall 20, one end coupled to the inner strut member 410 and the other end coupled to the outer strut member 420;
Interposed between the retaining side wall (10) and the inner strut member (410), the bracing structure for retaining process, characterized in that it further comprises a length adjustment unit (440) that can be adjusted in length.
The method of claim 1,
The strut member 310 is disposed in a longitudinal direction parallel to the longitudinal direction of the first bracing member 100,
A plurality of first strut members 311 arranged to be aligned with respect to the first bracing member 100;
Bracing structure for retaining process, characterized in that it comprises a plurality of second strut members (312) disposed symmetrically to each other on both sides of the first strut member (311).
The method of claim 1,
A wall 20 is installed between the first bracing member 100 and the retaining side wall 10,
The strut member 310,
Bracing structure for retaining process, characterized in that it is installed through an opening formed through the wall 20, and is configured to be coupled to the wall 20 by pouring concrete through the opening.
The method of claim 1,
A wall 20 is installed between the first bracing member 100 and the retaining side wall 10,
The strut member 310,
Bracing structure for retaining process, characterized in that it is installed through the space formed between the adjacent walls, and is configured to be coupled with the walls by pouring concrete in the space.
A first bracing member 100 installed along a first transverse direction crossing the underground space of a building, and a second transverse direction intersecting the first transverse direction at one or both ends of the first bracing member 100 The second bracing member 200 installed along, and disposed along the first transverse direction, one end is coupled to the second bracing member 200, the other end is a strut portion connected to the retaining side wall 10 inner surface including,
The strut portion, one end is coupled to the second bracing member 200, the other end is connected to the inner surface of the retaining side wall 10, one or a plurality of strut members 310, the retaining side wall 10 and the A length adjustment unit 440 interposed between the strut members 310 and adjustable in length, one end coupled to the retaining side wall 10, and the other end facing the retaining side wall 10, a wall 20 an inner strut member 410 coupled to one side wall of the outer strut member 420 having one end coupled to the other side wall of the wall 20 and the other end coupled to the second bracing member 200; Bracing structure for retaining process installed inside the wall 20, one end coupled to the inner strut member 410 and the other end including a connecting member 430 coupled to the outer strut member 420 with installed,
A part of the wall 20 is installed between the first bracing member 100 and the retaining side wall 10 to the position where the strut member 310 is installed, but one side is the strut member ( 310) and installing a part of the wall 20;
installing the connecting member 430 inside the wall 20 and installing the inner strut member 410 and the outer strut member 420 to be connected to the connecting member 430;
In a state in which the inner strut member 410 and the outer strut member 420 are installed on a part of the wall 20, the strut member 310 is removed and the remaining part of the wall 20 is installed. A wall construction method using a bracing structure for a retaining process, characterized in that it is constructed by delete

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