KR101880559B1 - Synthetic wall building construction method - Google Patents

Abstract

The present invention relates to a method to construct a building with a composite wall, capable of increasing land use efficiency. According to the present invention, the method to construct a building with a composite wall comprises: a step of forming a plurality of first holes having a first diameter in a horizontal direction and extended in a vertical direction on the ground by being spaced apart from each other, arranging an H-beam inside each first hole, and depositing and curing concrete; a step of forming a plurality of second holes having a smaller second diameter than the first diameter and extended in the vertical direction on the ground, and depositing and curing concrete; a step of excavating the ground inside the first and second holes to arrange a rebar inside the first and second holes, and arranging a mold inside the rebar; and a step of depositing and curing concrete between the first hole and the mold, and between the second hole and the mold. The outer end parts of the first and second holes are arranged on a virtual plane, and at least a part of the rebars installed between the second hole and the mold are arranged in a space between a virtual plane connecting the inner end part of the first hole and a virtual plane connecting the inner part of the second hole.

Description

{Synthetic wall building construction method}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method of constructing a composite wall structure, and more particularly, to a construction method of a composite wall body in which a temporary earth retaining wall for underground excavation and an underground structure wall as an outer wall of an underground structure are integrated.

Generally, construction of underground structure is performed by first constructing the temporary earth retaining wall, installing the formwork and reinforcing bars separately on the inner side, and installing the underground structure by pouring concrete, and then the temporary retaining wall is demolished or left underground.

However, the above-mentioned temporary earth retaining wall includes structures formed by H-shaped steel or reinforcing bars and concrete placed around the H-shaped walls, and is not easy to dismantle.

In addition, since the underground structure is constructed by installing a formwork and a reinforcing bar separately on the inner side of the temporary earth retaining wall and pouring concrete thereinto, the land outside the underground structure is wasted and the building area is reduced. In addition, As the work of installing the formwork and the reinforcement in the narrow space inside the wall is made, the construction is difficult, and the construction cost is increased and the construction period is delayed.

In order to solve the above problems, Korean Patent No. 10-1029040 entitled " Permanent retaining wall structure with gap-retaining pile for preventing corrosion and its construction method "(Figs. 12A to 12B) is disclosed. The prior art has been described in detail in order to prevent the ground slope 900 from being corroded by moisture and to prevent the surface of the H- The corrosion-preventing gap-retaining layer 103 having a certain thickness D1 and D2 as a whole is integrally wrapped and encapsulated so as to cover the perimeter of the perforated hole of the paperboard at regular intervals, A spacing-retaining thumb pile (100); The soil retaining plate 200 is sandwiched between the inner sides of the spaced-apart thumb piles 100 exposed at the front in the state where the spacing-maintaining thumb piles 100 are vertically buried at regular intervals, ; A wale band 300 supported by a brace 360 on the wale joint exposed surface 102 of the wall portion 110 of the gap maintaining pendulum 100 and having one rear side joined and fixed horizontally; And a pedestal 400 installed on one side of the front surface of the wale band 300 and on which a stiffener 460 fixed to the ground panel gypsum 900 is inserted and fixed. The present invention relates to a permanent retaining wall structure (see claim 1) provided with a thumb pile, which is inserted vertically into a ground pad gravel 900 and is sealed and covered with a corrosion inhibiting gap retaining layer 103 even when exposed to soil moisture for a long period of time Since the H-shaped steel body 101 is not corroded and can withstand loads such as earth pressure, it is possible to eliminate the installation space for reinforcement reinforcement, thereby maintaining a gap for preventing corrosion, which minimizes the thickness of the permanent earth retaining wall structure It is an object of the present invention to provide a permanent retaining wall structure provided with a thumb pile and an operation method therefor.

However, in the prior art, since the earth retaining plate 200 is installed on the inner flange of the gap retaining pile 100 and the concrete 960 is laid thereon, structural reinforcement is not provided between the thumb piles 100, There is a problem that rigidity can not be used properly.

In the prior art, the concrete 960 is placed only inside the filler S and the thumb pile 100, and is combined with the thumb pile 100, so that the synthetic force of the concrete 960 and the thumb pile 100 is insufficient There is a problem.

In addition, since the above-mentioned prior art is manufactured by coating the corrosion-resistant space-maintaining layer 103 such as concrete, cement paste, epoxy, etc. on the H-shaped steel 101, There is a problem that the H-shaped steel 101 coated with the anti-corrosion spacer layer 103 can not be used for other purposes.

KR 10-1029040 B1

In order to solve the problems described above, according to the present invention, the use efficiency of the land is increased by eliminating the space between the temporary earth retaining wall and the wall of the underground structure by integrally constructing the temporary earth retaining wall and the underground structure wall, It provides the construction method of the synthetic wall building which not only improves the convenience of construction but also saves the construction cost because the stability of the underground structure is increased by using it as a part of the wall of the structure and the formwork work in the narrow space is unnecessary for the construction of the wall of the underground structure do.

The present invention also provides a method of constructing a composite wall structure in which corrosion of an H-shaped steel by underground water or the like is prevented by providing a corrosion preventing lid on the outer flange of the H-shaped steel, thereby enhancing durability.

Further, by providing a plurality of through holes in the third member of the corrosion preventive cover, the concrete penetrates well between the third member and the outer flange, so that the outer flange of the H-shaped portion and the corrosion preventing lid are well bonded and the corrosion of the H- And to provide a method of constructing a composite wall structure that can prevent the formation of a composite wall structure.

It is also intended to provide a method of constructing a composite wall structure in which the outer flange of the H-shaped steel, the third member of the corrosion-preventing lid, and the concrete are firmly joined by forming the inner side surface and the outer side surface of the third member of the corrosion- .

In addition, since the outer formwork is provided on the outer side of the first member or the inner side of the third member of the corrosion-prevention lid, the outer formwork can be easily joined to completely separate the temporary earth retaining wall and the ground, And to provide a construction method of a composite wall building which increases the structural stability.

In addition, a synthetic wall structure capable of guiding and draining the groundwater flowing inward into the hypothetical earth retaining wall by inserting the drainage material into the induction flange, which includes the angular induction flange provided on the inner side of the third member of the corrosion- We want to provide construction method.

The method for constructing a composite wall structure according to the present invention is characterized in that a plurality of first holes having a first diameter in the horizontal direction and extending in the vertical direction are spaced apart from each other in the ground, and H-shaped steel is disposed in each of the plurality of first holes Curing by pouring concrete; A plurality of second holes extending in a vertical direction and having a second diameter smaller than the first diameter in a horizontal direction between the plurality of first holes are formed in the ground, Pouring and curing; Disposing the first hole and the ground on the inner side of the second hole to arrange a reinforcing bar inside the first hole and the second hole, and arranging a form inside the reinforcing bar; And placing and curing concrete between the first hole and the die and between the second hole and the die, wherein the outer end of the second hole and the outer end of the first hole are placed on a virtual plane At least a part of the reinforcing bars disposed between the second hole and the mold is spaced from a virtual plane connecting the inner ends of the plurality of first holes and a virtual plane connecting the inner ends of the plurality of second holes, As shown in FIG.

Wherein the step of excavating the inner side of the first hole and the inner hole of the second hole to excavate the ground includes excavating the ground to the inner flange of the H-shaped steel, separating the formwork from the inner flange of the H- As shown in FIG.

Wherein the step of disposing the H-shaped steel in each of the plurality of first holes includes the step of placing the H-shaped steel in the first hole by adhering a tape to the flange surface of the inner flange of the H-shaped steel, The step of excavating the hole and the ground on the inner side of the second hole to remove the tape adhering to the flange surface of the inner flange of the H-shaped steel to remove the concrete and the ground disposed on the inner side of the tape can do.

The step of placing concrete in each of the plurality of second holes may include placing H-shaped steel having a size smaller than that of the H-shaped steel disposed inside the first holes in each of the plurality of second holes and casting concrete The first hole may have the same first diameter in both the first direction of the horizontal direction and the second direction perpendicular to the first direction.

Wherein said H-shaped steel comprises a corrosion-resistant lid to prevent corrosion of the outer flange, said corrosion-resistant lid comprising: a first member covering an outer surface of an outer flange of said H-shaped steel; a pair of second Wherein the first member, the pair of second members, and the pair of third members of the anti-corrosion lid are provided on the outer flange of the H- And a spacing space for accommodating the web of the H-shaped steel may be formed between the pair of third members.

Wherein a part of the concrete placed in the first hole is injected through the plurality of through holes and the outer flange of the H-shaped steel and the pair of third members .

Wherein a portion of the concrete poured into the first hole is injected through the irregularities so that the outer flange of the H-shaped portion and the pair of third members .

The method of constructing the composite wall structure according to the present invention comprises: And a pair of third members covering the inner side surfaces of the outer flange, a first member covering the outer side surface of the outer flange of the H-shaped steel, a pair of second members covering both side surfaces of the outer flange, The method comprising the steps of: forming a plurality of first holes spaced apart from each other in a vertical direction and having a first diameter in a horizontal direction; Inserting the H-shaped arc having the anti-corrosion lid into the plurality of first holes and fixing the H-shaped arc inside the first hole; Excavating an inner ground of the first hole, a ground between the plurality of first holes, and an inner ground between the plurality of first holes; Providing an outer mold to a pair of pivotal outer mold guides disposed outside of said first member of said corrosion resistant lid; Disposing a reinforcing bar inside the H-shaped steel; Disposing an inner mold on the inner side of the reinforcing bar; And pouring and curing concrete between the outer mold and the inner mold, wherein the first member, the pair of second members, and the pair of third members of the corrosion-prevention lid are located outside the H- And may be provided so as to be in contact with the outer side surface, the both side surfaces, and the inner side surface of the flange.

Wherein the web of each of the plurality of H-shaped steels is provided with a nut, and the method of constructing the composite wall structure includes a step of placing a concrete rod between the outer die and the inner die and a steel rod connecting the two H- And the steel bar may be disposed closer to the inner flange than the outer flange of the H-shaped steel.

The corrosion-preventing lid further includes a pair of L-shaped induction flanges provided inside the pair of third members, and a drain member may be inserted into the grooves of the induction flange.

Through the present invention, the utilization efficiency of the land is increased by eliminating the space between the temporary earth retaining wall and the underground structure wall by integrating the temporary earth retaining wall and the underground structure wall, and by utilizing the temporary earth retaining wall as a part of the underground structure wall, The construction of the wall of the underground structure is not required to be performed in a narrow space, so that the convenience of construction is increased and the construction cost can be saved.

Further, by providing the corrosion-prevention lid on the outer flange of the H-shaped steel, corrosion of the H-shaped steel by ground water or the like is prevented, and durability is increased.

Further, by providing a plurality of through holes in the third member of the corrosion preventive cover, the concrete penetrates well between the third member and the outer flange, so that the outer flange of the H-shaped portion and the corrosion preventing lid are well bonded and the corrosion of the H- It is possible to have an effect that can be prevented.

In addition, by forming the inner side surface and the outer side surface of the third member of the corrosion-prevention lid to be irregular, the outer flange of the H-shaped steel, the third member of the corrosion prevention lid, and the concrete can be firmly bonded.

In addition, since the outer formwork is provided on the outer side of the first member or the inner side of the third member of the corrosion-prevention lid, the outer formwork can be easily joined to completely separate the temporary earth retaining wall and the ground, It can have an effect of increasing the structural stability.

In addition, since the drainage member is inserted into the induction flange including the angular induction flange provided on the inner side of the third member of the corrosion-prevention lid, the groundwater flowing into the inside of the temporary earth retaining wall can be well guided and drained downwardly .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view for explaining a step of forming a first hole in a synthetic wall building construction method according to a first embodiment of the present invention, disposing H-shaped steel in a first hole, and curing concrete. FIG.
FIG. 2 is a view for explaining a step of forming a second hole in the method of constructing a composite wall structure according to the first embodiment of the present invention, disposing H-shaped steel in the second hole, and curing concrete.
3 is a view for explaining a step of excavating the ground inside the holes in the method of constructing the composite wall structure according to the first embodiment of the present invention to arrange the formwork and disposing the reinforcing bars between the holes and the formwork.
4 is a view for explaining a step of pouring and curing concrete between holes and a mold in a method of constructing a composite wall structure according to a first embodiment of the present invention.
5A and 5B are a plan view and a perspective view of a synthetic wall construction method according to a second embodiment of the present invention.
6 is a perspective view showing a state in which a perforation hole is formed for the construction of the synthetic wall according to the third embodiment of the present invention.
7 is a perspective view showing a state in which H-shaped beams are inserted into a perforation hole for the construction of the synthetic wall according to the third embodiment of the present invention.
8A is a perspective view showing a ground excavation for constructing a synthetic wall according to a third embodiment of the present invention.
FIG. 8B is a perspective view showing an enlarged view of a corrosion prevention cover of a synthetic wall according to a third embodiment of the present invention. FIG.
FIGS. 8C to 8E are enlarged views showing through-holes formed in the corrosion-prevention lid of the synthetic wall according to the third embodiment of the present invention, the shapes of the irregularities, and the shapes of the induction flange and the drain.
FIG. 9 is a perspective view showing a state in which an outer formwork and a reinforcing bar are installed for the construction of the synthetic wall according to the third embodiment of the present invention.
10 is a perspective view showing an inner mold for installing a synthetic wall according to a third embodiment of the present invention.
FIG. 11 is a perspective view showing concrete pouring outside the inner molder for constructing the synthetic wall according to the third embodiment of the present invention. FIG.
12A and 12B are views of the prior art.

Hereinafter, some embodiments of the present invention will be described with reference to the accompanying drawings. However, the technical spirit of the present invention is not limited to some embodiments described.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements.

When a component is described as being "connected" or "coupled" to another component, the component may be directly coupled or coupled to the other component, but another component It is to be understood that the elements may be " connected " or " coupled ".

Hereinafter, a method of constructing a composite wall structure according to a first embodiment of the present invention will be described.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view for explaining a step of forming a first hole in a synthetic wall building construction method according to a first embodiment of the present invention, disposing H-shaped steel in a first hole, and curing concrete. FIG.

1 and 2, the method for constructing a composite wall structure comprises forming a plurality of first holes 10 having a first diameter D1 in a horizontal direction and extending in a vertical direction and spaced apart from each other, The method may include the step of curing the concrete (first concrete) 11 by placing the H-shaped steel 20 in each of the first holes 10.

The diameter of the first hole 10 may be constant. The plurality of first holes 10 may be spaced apart from each other. A second hole 70 having a smaller diameter than the first hole 10 may be disposed in the spacing space of the first hole 10.

In this embodiment, the first hole 10 may have the same first diameter D1 in both the first direction of the horizontal direction and the second direction perpendicular to the first direction. That is, the cross section of the first hole 10 may be a circle having a constant diameter. In other words, the first hole 10 may have a single circular shape instead of an ellipse or a partially deformed circle or a figure formed by superimposing two circles. As compared with the case where the cross section of the first hole 10 is completely caused as in this embodiment, it is easy to excavate (construction).

FIG. 2 is a view for explaining a step of forming a second hole in the method of constructing a composite wall structure according to the first embodiment of the present invention, disposing H-shaped steel in the second hole, and curing concrete.

The synthetic wall building construction method comprises a plurality of second holes (5) having a second diameter (D2) smaller than the first diameter (D1) in the horizontal direction between a plurality of first holes (10) 70), and pouring and curing concrete (second concrete) 71 in each of the plurality of second holes 70.

Although the first hole 10 and the second hole 70 are formed in the present embodiment, the first hole 10 and the second hole 70 may be formed simultaneously, It is also possible to construct the second hole 70 first and then construct the first hole 10 later.

In the method of constructing a composite wall structure, placing the concrete 71 in each of the plurality of second holes 70 may be performed by placing an H-shaped steel 80 or a reinforcing bar in each of the plurality of second holes 70, 71). ≪ / RTI > The step of pouring the concrete 71 into each of the plurality of second holes 70 may be carried out in a plurality of second holes 70 in the respective H holes of the H- And placing the small-sized H-shaped steel (80) and casting the concrete (71). In other words, the H-shaped steel 80 can be disposed in the second hole 70 as in the first hole 10. However, the size of the H-shaped steel 80 disposed in the second hole 70 may be smaller than the size of the H-shaped steel 20 disposed in the first hole 10. In addition, a reinforcing bar may be disposed in the second hole 70 instead of the H-shaped steel bar 80. On the other hand, an iron plate can be coupled to each of the inner flanges of the plurality of H-shaped steel bars 80 disposed in the plurality of second holes 70. More specifically, in the modification, the second hole 70 may be formed in the same diameter as the first hole 10 by being excavated by an auger having the same diameter as that of the first hole 10. At this time, a plurality of H-shaped beams (not shown) are formed so that the H-shaped steel 80 having a size smaller than that of the H-shaped steel 20 disposed in the first hole 10 is closely contacted to the boundary line 1 inside the second hole 70 80 by welding an iron plate to each of the inner flanges. That is, an iron plate may be coupled to the H-shaped steel 80 to fix the H-shaped steel 80 having a small size in the second hole 70 at a predetermined position. Therefore, the size of the iron plate may correspond to the size of a part of the second hole 70. [

The second diameter D2 of the second hole 70 may be smaller than the first diameter D1 of the first hole 10 in this embodiment. As a result, compared with the model in which only the first hole 10 having a constant diameter is disposed, the reinforcing bars are disposed in the free space generated by the second holes 70, The strength can be increased.

In this embodiment, the outer end of the second hole 70 and the outer end of the first hole 10 may be disposed on a virtual plane. That is, the outer end of the second hole 70 and the outer end of the first hole 10 may be arranged on an imaginary straight line when the upper surface of the ground 50 is compared. Such a structure of this embodiment is a structure in which the outer end of the first hole 10 and the outer end of the second hole 70 can be disposed on the boundary line 1 so that the composite wall can be provided as close as possible to the boundary line It provides the advantage of having. At this time, the boundary line (l) may be a boundary line in which the owner of the land is changed.

The distance between the center of the first hole 10 and the center of the second hole 70 in this embodiment is smaller than the distance between the first radius R1 of the first hole 10 and the second radius 70 of the second hole 70, (R2). ≪ / RTI > The first radius R1 of the first hole 10 is half the first diameter D1 and the second radius R2 of the second hole 70 is the second diameter D2. . That is, the first hole 10 and the second hole 70 can be in contact with each other. That is, in this embodiment, the first hole 10 and the second hole 70 may not overlap with each other. Also, the first hole 10 and the second hole 70 may be continuous. As a comparative example, a model in which a part of the first hole 10 and the part of the second hole 70 are overlapped can be considered. However, the comparative example may be a model that exists only theoretically but is actually impossible to construct. Because there is a part overlapping the first hole 10 and the second hole 70, one of them is firstly excavated and the other one is excavated later. In this case, in the process of excavating a hole to be excavated later, This is because the soil is introduced into the excavated hole and accumulated. In this embodiment, since there is no portion where the first hole 10 and the second hole 70 overlap, it is possible not only that the gravel of any one hole flows into the other hole during the excavation process, but also it can be excavated at the same time. That is, this embodiment has an advantage that the construction time can be shortened as compared with the comparative example. The second hole 70 and the second hole 70, which are adjacent to each other, can also be in contact with each other. Furthermore, the first hole 10 and the second hole 70 may be overlapped with each other. In addition, the second holes 70 and the second holes 70, which are adjacent to each other, may be partially overlapped.

3 is a view for explaining a step of excavating the ground inside the holes in the method of constructing the composite wall structure according to the first embodiment of the present invention to arrange the formwork and disposing the reinforcing bars between the holes and the formwork.

In the method of constructing a composite wall structure, reinforcing rods 35 are disposed inside the first holes 10 and the second holes 70 by excavating the ground 5 inside the first holes 10 and the second holes 70 And disposing the form 30 inside the reinforcing bar 35. That is, after the ground 5 inside the first hole 10 and the second hole 70 is excavated, the reinforcing bars 35 may be disposed first and then the formwork 30 may be disposed.

In the method of constructing a composite wall structure, the ground 30 is disposed by excavating the ground 5 inside the first hole 10 and the second hole 70, and the gap between the first hole 10 and the mold 30, And placing a reinforcing bar (35) between the two holes (70) and the mold (30). However, the mold 30 may be referred to as "inner mold 30" to distinguish it from the later described outer mold 40.

At least a portion of the reinforcing bars 35 disposed between the second hole 70 and the mold 30 may be disposed outside the reinforcing bars 35 disposed between the first hole 10 and the mold 30 have. In other words, at least a part of the reinforcing bars 35 disposed between the second hole 70 and the mold 30 has a virtual plane connecting the inner ends of the plurality of first holes 10 and a plurality of second holes 70, which are connected to the inner surface of the base plate. That is, as the diameter of the second hole 20 is smaller than the diameter of the first hole 10 and the outer end of the second hole 20 is located coplanar with the outer end of the first hole 10 And the reinforcing bars 35 may be disposed in the clearance space inside the second holes 20. [ The strength of the composite wall according to the present embodiment can be increased by the present reinforcing bars 35. [

4 is a view for explaining a step of pouring and curing concrete between holes and a mold in a method of constructing a composite wall structure according to a first embodiment of the present invention.

The composite wall building construction method may include placing and curing concrete (third concrete) 90 between the first hole 10 and the mold 30 and between the second hole 70 and the mold 30 have. At this time, the poured concrete and the cured concrete can form the underground structure wall body 2. The underground structure wall 2 can form the synthetic wall 3 together with the temporary earth retaining wall 1 formed by the concrete 11 and 71 laid in the first hole 10 and the second hole 70 have.

Hereinafter, a method of constructing a composite wall structure according to a second embodiment of the present invention will be described. Hereinafter, a description will be given mainly of differences from the first embodiment of the construction method of the composite wall building according to the second embodiment. That is, the contents common to the first embodiment of the synthetic wall construction method according to the second embodiment can be analogously applied to the description of the first embodiment.

5A and 5B are a plan view and a perspective view of a synthetic wall construction method according to a second embodiment of the present invention.

The step of excavating the ground 5 inside the first hole 10 and the second hole 70 in the method of constructing the composite wall building structure and disposing the formwork 30 may be carried out in the inside of the inner flange 21 of the H- And the step of installing the form 30 on the inner flange 21 of the H-shaped steel 20 by separating the form 30 from the inner flange 21 of the H-shaped steel 20. FIG. That is, the form 30 can be coupled to the inner flange 21 of the H-shaped arc 20. At this time, the form 30 can be coupled to the inner flange 21 of the H-shaped steel 20 through the steel rods and the bolts. Alternatively, the form 30 may be provided via a foam tie bolt provided on the flange surface of the inner flange 21 of the H-shaped steel 20. [

The step of arranging the H-shaped steel 20 in each of the plurality of first holes 10 in the method of constructing the composite wall structure may be performed by adhering a tape to the flange surface of the inner flange 21 of the H- 10). ≪ / RTI > At this time, the step of excavating the ground 5 inside the first hole 10 and the second hole 70 to dispose the mold 30 may be performed by bonding the flange 21 of the inner flange 21 of the H- And removing the concrete 11 and the ground 5 disposed inside the tape by removing the tape.

In the composite wall building construction method, the H-shaped steel 20 may include an anti-corrosion lid 50 to prevent corrosion of the outer flange 22. At this time, the description of the anti-corrosion lid 50 according to the third embodiment to be described later can be applied to the anti-corrosion lid 50 according to the second embodiment. The corrosion preventive cover 50 includes a first member 51 covering the outer side surface (flange surface) of the outer flange 22 of the H-shaped steel 20, a pair of second members covering the both side surfaces of the outer flange 22 52) and a pair of third members (53) covering the inner surface of the outer flange (22). At this time, a space for accommodating the web of the H-shaped steel 20 may be formed between the pair of third members 53.

Further, the pair of third members 53 may include a plurality of through-holes 56 (see Fig. 8C). A part of the concrete 11 placed in the first hole 10 is injected through the plurality of through holes 56 to be connected to the outer flange 22 of the H- .

In addition, the inner side surface and the outer side surface of the pair of third members 53 may be formed by the concavities and convexities 57 (see Fig. 8D). At this time, a part of the concrete 11 placed in the first hole 10 is injected through the unevenness 57 to join the outer flange 22 of the H-shaped steel 20 and the pair of third members 53 .

Further, the corrosion preventive cover 50 may include a pair of pillar-shaped outer mold guides (refer to 54 in Fig. 8B) disposed outside the first member 51. Fig. At this time, the outer formwork 40 may be inserted between the outer form guides 54 of the adjacent H-shaped beams 20 among the plurality of the H-shaped beams 20. Alternatively, the steel rods 23 may be disposed between the webs of each of the plurality of H-shaped steel rods 20 arranged alternately. At this time, the connecting bar may be disposed on the inner side of the center of the web of the H-shaped steel 20 from the center. More specifically, a nut having a long length is welded to both sides of the web of the H-shaped portion 20, a long nut is provided in the middle, and a steel bar 23 or two reinforcing bars are rotated between the nut and the nut So that the H-shaped beams 20 can be coupled with each other.

In addition, the anti-corrosion lid 50 may include a pair of angled induction flanges 58 provided inside the pair of third members 53. At this time, a drain member 60 can be inserted into the groove of the induction flange 58 (see FIG. 8E).

In this embodiment, the first concrete 11 placed in the first hole 10, the second concrete 71 inserted in the second hole 70, and the holes 10 and 70, The third concrete 90 may be separately installed. Alternatively, the reinforcing bars 35 may be disposed between the outer mold 40 and the inner mold 30, and then the first to third concrete 11, 71, and 90 may be simultaneously It is possible. At this time, the steel rods 23 connecting the plurality of H-shaped beams 20 may be disposed before the concrete is poured.

Hereinafter, a method of constructing a composite wall structure according to a third embodiment of the present invention will be described in detail with reference to FIGS.

6 to 11, the synthetic wall building construction method according to the third embodiment of the present invention is a method of constructing a composite wall body 3 in which a temporary earth retaining wall body 1 and an underground structure wall body 2 are integrated, Forming first holes 10 spaced apart from each other, inserting H-shaped beams 20 into the first holes 10, excavating the ground to the outer flanges of the H-shaped beams 20, A step of assembling reinforcing bars of the synthetic wall 3, installing an inner mold 30 of the underground structure wall 2 on the inner side of the assembled reinforced bar, placing concrete on the outer side of the inner mold 30, Step < / RTI > Hereinafter, 'inside' such as inside, inside, and inside refers to the underground structure, and 'outside' such as outside, outside, and outside refers to the outside of the underground structure, that is, the side where the ground is not excavated.

Referring to FIG. 6, forming the first holes 10 is a step of forming a plurality of first holes 10 so as to be spaced apart from the ground along the earth retaining wall to be constructed. That is, a plurality of first holes 10 are formed in an earth drill, auger or the like in a place where a temporary earth retaining wall is to be installed. The first hole 10 may be formed in consideration of the size of the H-shaped steel 20 to be inserted into the first hole 10 and the casing may be used in consideration of the ground condition.

Referring to FIG. 7, the step of inserting the H-shaped beams 20 into the first holes 10 is a step of inserting the H-shaped beams 20 into the first holes 10 formed in the above step . The H-shaped steel 20 is buried in concrete to form a temporary earth retaining wall 1 and at the same time, it can be combined with an underground structure wall 2 to form a synthetic wall 3.

8A and 9, the step of assembling and installing the reinforcing bars of the synthetic wall 3 includes excavating the ground up to the outer flanges of the H-shaped beams 20 and then attaching the underground structure wall 2 and the portion of the temporary earth retaining wall 1 And assembling and installing vertical and horizontal reinforcing bars. That is, vertical and horizontal reinforcing bars are arranged and assembled between the H-shaped sections 20, that is, the part forming the temporary cladding wall 1 and the inner part of the H-shaped sections 20, that is, . The excavation of the ground is performed by excavating from the portion where the underground structure is to be installed to the outer flange of the H-shaped sections 20, or by first drilling a cylindrical shape between the H-shaped sections 20 by an earth drill, auger, The part where the structure will be installed can be excavated.

The reinforcement of the synthetic wall 3 is formed on the outer side of the inner formwork 30, that is, in the concrete laid between the inner formwork 30 and the ground in a step to be described later to form the synthetic wall 3, It is desirable to appropriately arrange the vertical and horizontal reinforcing bars and to mutually connect the reinforcing bars.

Referring to FIG. 10, the step of installing the inner formwork 30 is a step of installing an inner formwork 30 for forming the synthetic wall 3 on the inner side of reinforced bars assembled and assembled in the above-mentioned step. That is, an inner mold 30 is installed on the inner side of the reinforcing bars to prepare concrete for pouring concrete in a later step. The inner mold 30 may be coupled to the reinforcing bar or H-shaped section 20 or may be supported inside the inner mold 30.

In this embodiment, the temporary earth retaining wall 1 is a wall which is composed of reinforcing bars provided between the H-shaped beams 20 and the H-shaped beams 20 and concrete filled therebetween and is in contact with the ground, The wall 2 is a wall constituted by reinforcing bars disposed on the inside of the temporary earth retaining wall 1 and concrete filled between the reinforcing bars to form an outer wall of the underground structure. Refers to the whole of the wall 1 and the underground structure wall 2 integrally formed. Therefore, the composite wall 3 of the present embodiment is formed by integrally forming the temporary earth retaining wall 1 with the underground structure wall 2 to increase the rigidity of the underground structure wall 2, It is possible to effectively use the land by forming the underground structure wall body 2 in contact with the temporary earth retaining wall body 1 and also to reduce the amount of concrete used in the outer formwork 2 for forming the underground structure wall body 2, It is not necessary to install the apparatus in a narrow space, and the operation is remarkably convenient.

Referring to FIG. 11, the step of pouring concrete is a step of forming a synthetic wall 3 by placing concrete between the inner mold 30 and the outer mold 40, or between the inner mold 30 and the ground. Therefore, the concrete can be installed to integrate the temporary earth retaining wall 1 including the H-shaped steel 20 and the wall 2 of the underground structure inside thereof. It is preferable that the reinforcing bars are appropriately connected in order to integrate the temporary earth retaining wall 1 and the underground structure wall 2 together.

The method for constructing a composite wall structure according to another example of the present invention includes a first member 51 covering an outer surface of an H flange 22 and an outer flange 22 of an H flange 22, (3) comprising a corrosion preventing lid (50) including a pair of second members (52) covering the outer flange (22) and a pair of third members (53) A step of forming a plurality of first holes 10 having a first diameter D1 in a horizontal direction and extending in a vertical direction so as to be spaced apart from each other, 10. The method according to claim 1, further comprising the step of inserting an H-shaped steel (20) having a corrosion preventive lid (50) in each of the first holes (10) A step of excavating the ground 5 of the corrosion preventive lid 50, the ground 5 between the first holes 10 and the inner ground 5 between the plurality of first holes 10, One member 51 disposed on the outer side A step of disposing an outer mold 40 on the outer die guide 54 of the L-shaped form, a step of disposing a reinforcing bar 35 inside the H-shaped steel 20, a step of forming an inner mold 30 on the inner side of the reinforcing bar 35 And placing and curing the concrete 90 between the outer mold 40 and the inner mold 30. At this time, the H-shaped steel 20 may be fixed to the ground 5 through an earth anchor, or a strut may be installed between the plurality of H-shaped steel 20 and supported.

Nuts may be provided on the webs of each of the plurality of H-shaped steel rods 20. At this time, the method of constructing the composite wall structure includes a step of placing the concrete 11 between the outer formwork 40 and the inner formwork 30 and joining the steel rods connecting the two H-shaped beams 20 adjacent to the nut before curing . The steel bar may be disposed closer to the inner flange 21 than the outer flange 22 of the H-shaped steel 20. [ On the other hand, "linking material" can be used as a concept including a steel bar. That is, the connecting member can be used for connecting the H-shaped portion 20.

The corrosion preventive cover 50 includes a first member 51 covering the outer side surface of the outer flange 22 of the H-shaped steel 20, a pair of outer flanges 22 covering both side surfaces of the outer flange 22, A pair of third member 53 covering the inner side surface of the outer flange 22 and a pair of L-shaped induction flange provided on the inner side of the pair of third members 53 58). At this time, a drain member 60 may be inserted into the groove of the induction flange 58.

Referring to FIGS. 8A and 8B, the H-shaped steel 20 may further include an anti-corrosion lid 50 to prevent corrosion. The corrosion preventive lid 50 is constructed to prevent the H-shaped steel 20 from being corroded by underground water or the like of the ground. The corrosion preventing lid 50 includes a first member 51 for covering the outer side surface of the outer flange of the H- A pair of second members (52) covering both sides of the outer flange, and a pair of third members (53) covering inner sides of the outer flanges, wherein the pair of third members (53) A spacing distance through which the web of the H-shaped section 20 can be inserted can be formed.

The corrosion-preventive lid 50 completely prevents the corrosion of the H-shaped steel 20, so that the structural durability of the synthetic wall 3 can be remarkably increased. In other words, in the case of the prior art, corrosion was prevented by the concrete placed around the H-shaped steel, but in reality, it was impossible to prevent corrosion completely due to poor construction of concrete and penetration of groundwater continuously. There is a problem that the structural durability is remarkably lowered.

In addition, a pair of outer die guides 54 may be provided on the outer side of the first member 51 of the corrosion prevention lid 50. The outer die guide 54 may be welded to both outer ends of the first member 51 of the corrosion preventing lid 50 or formed integrally with the corrosion preventing lid 50.

The outer mold guide 54 may be formed by inserting an outer mold 40, that is, a mold installed on a side facing the ground, so as to be firmly fixed to the outer mold 40. Therefore, the outer mold 40 is slidably inserted between the adjacent outer mold guides 54 and the concrete is placed between the outer mold 40 and the inner mold 30, 1 and the underground structure wall 2 can be integrated to form the synthetic wall 3.

In another embodiment, the outer die guide 54 may be coupled to the corrosion-preventing lid 50. In another embodiment, the outer die guide 54 ) Can be combined. Accordingly, the outer mold 40 can be coupled to the inside of the outer flange of the H-shaped steel 20. [

Referring to FIG. 8C, through holes 56 may be formed in the pair of third members 53 of the anti-corrosion lid 50. The through holes 56 formed in the third member 53 allow the outer flange of the H-shaped section 20 and the pair of third members 53 to be firmly joined to each other by the concrete penetrating therethrough, Corrosion of the H-shaped steel 20 can be completely prevented by preventing the groundwater from permeating between the outer flange of the section steel 20 and the third member 53.

8D, the pair of third members 53 of the corrosion-prevention lid 50 may be provided with concavities and convexities 57 on the inner side surface and the outer side surface (the surface in contact with the H-shaped steel and the outer flange). The concrete to be placed is well injected between the third member 53 and the outer flange of the H-shaped steel 20 so that the third member 53 is well bonded to the H-shaped steel 20 and the third member 53 ) And its inner concrete can be joined well and structurally robust. The concavities and convexities 57 may be formed on the inner surface of the first member 51 of the corrosion-prevention lid 50 as required. The corrosion-resistant cover 50 may be made of a steel material treated with a corrosion treatment, plastic, or the like.

According to still another aspect of the present invention, there is provided a method of constructing a composite wall structure in which a wall of a building and an underground structure are integrated, comprising the steps of: forming first holes (10) A step of inserting H-shaped beams (20) into the first holes (10), excavating the ground up to the outer flanges of the H-shaped beams (20), assembling and installing reinforcing bars of the composite wall (3) Installing an inner mold (30) of the underground structure wall (2) inside the reinforcing bar and pouring concrete outside the inner mold (30), wherein the H-shaped steel (20) The corrosion-resistant lid (50) further comprises a first member (51) covering the outer side surface of the outer flange of the H-shaped steel (20), a first member A pair of second members (52) covering the outer flange And a pair of third members 53 covering a part of the inner side surface.

The present embodiment mainly focuses on the difference from the above-described embodiment.

The third member 53 of the corrosion preventing cover 50 of this embodiment can be formed to cover a part of the inner surface of the outer flange. So that the inner surface of the outer flange of the exposed H-shaped section 20 can be adhered well to the concrete being poured.

In addition, a pair of L-shaped induction flanges 58 may be provided inside the pair of third members 53 of the corrosion preventing lid 50. That is, the pair of pivotally-shaped induction flanges 58 may be formed long in the longitudinal direction in the third member 53 of the corrosion-prevention cover 50. Therefore, the drainage material 60 is inserted into the grooves formed by the third member 53 and the L-shaped induction flange 58 from the upper side to the lower side so that the groundwater flowing on the corrosion-proof lid 50 flows through the drainage member 60 So that the groundwater can be prevented from permeating into the synthetic wall 3.

The drainage material 60 may be one of a porous pipe, a porous pipe, a nonwoven fabric, a woven fabric, and a fiber filter. The water discharging member 60 prevents the concrete to be poured from flowing into the grooves to form a flow path, and to discharge the permeated groundwater downward.

The utilization of the ground can be maximized by constructing the temporary earth retaining wall 1 and the underground structure wall 2 integrally with each other through the above embodiments and the structural rigidity of the underground structure wall 2 is increased with a small amount of material, It is possible to construct an underground structure that is quick in construction and saves cost.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all of the components may be selectively coupled to one or more of them. It is to be understood that the terms such as 'include', 'comprising', or 'having', as used herein, mean that a component can be implied unless specifically stated to the contrary. But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

1: Hypothetical earth retaining wall 2: Underground structure wall
3: synthetic wall 10: first hole
20: H-beam 30: inner formwork
40: outer mold 50: corrosion-resistant cover
60: drainage material 70: second hole
80: H-beam

Claims (11)

Forming a plurality of first holes spaced apart from each other in a vertical direction and having a first diameter in a horizontal direction, placing H-shaped steel in each of the plurality of first holes, and curing concrete by pouring concrete;
A plurality of second holes extending in a vertical direction and having a second diameter smaller than the first diameter in a horizontal direction between the plurality of first holes are formed in the ground, Pouring and curing;
Disposing the first hole and the ground on the inner side of the second hole to arrange a reinforcing bar inside the first hole and the second hole, and arranging a form inside the reinforcing bar; And
Placing and curing the concrete between the first hole and the mold and between the second hole and the mold,
Said H-shaped steel comprising an anti-corrosion lid to prevent corrosion of the outer flange,
The corrosion-preventing lid includes a first member covering the outer side surface of the outer flange of the H-shaped steel, a pair of second members covering both side surfaces of the outer flange, and a pair of third members covering the inner side surface of the outer flange and,
The first member, the pair of second members, and the pair of third members of the corrosion-prevention lid are disposed in contact with the outer side surface, both side surfaces, and the inner side surface of the outer flange of the H-
A space for accommodating the web of the H-shaped steel is formed between the pair of third members,
Wherein the corrosion-preventing lid further comprises a pair of angled induction flanges provided inside the pair of third members,
A drainage member is inserted into the groove of the induction flange,
Wherein an outer end of the second hole and an outer end of the first hole are disposed on an imaginary plane and at least a portion of the reinforcing bars disposed between the second hole and the mold is connected to a virtual And the imaginary plane connecting the inner ends of the plurality of second holes. The method according to claim 1,
The step of excavating the ground in the first hole and the second hole to dispose the formwork
And a step of excavating the ground up to the inner flange of the H-shaped steel, and disposing the form on the inner flange of the H-shaped steel, spaced from the inner flange of the H-shaped steel. The method of claim 2,
Wherein the step of disposing the H-shaped steel in each of the plurality of first holes includes the step of placing the H-shaped steel in the first hole by adhering a tape to the flange surface of the inner flange of the H-
The step of excavating the ground in the first hole and the second hole to dispose the mold removes the tape adhered to the flange surface of the inner flange of the H-shaped steel to remove the concrete and the ground disposed inside the tape A method of constructing a composite wall structure including steps. The method according to claim 1,
The step of placing concrete in each of the plurality of second holes may include placing H-shaped steel having a size smaller than that of the H-shaped steel disposed inside the first holes in each of the plurality of second holes and casting concrete A method of constructing a composite wall structure. delete delete The method according to claim 1,
Wherein the pair of third members includes a plurality of through holes,
And a part of the concrete placed in the first hole is injected through the plurality of through holes to join the outer flange of the H-shaped steel and the pair of third members. The method according to claim 1,
Wherein the inner side surface and the outer side surface of the pair of third members are formed by unevenness,
And a part of the concrete placed in the first hole is injected through the unevenness to join the outer flange of the H-shaped arc and the pair of third members. H - section; And
A corrosion preventive lid including a first member covering the outer side surface of the outer flange of the H-shaped steel, a pair of second members covering both side surfaces of the outer flange, and a pair of third members covering the inner side surface of the outer flange A method of constructing a composite wall structure for constructing a composite wall comprising:
Forming a plurality of first holes spaced apart from each other in a vertical direction and having a first diameter in a horizontal direction;
Inserting the H-shaped arc having the anti-corrosion lid into the plurality of first holes and fixing the H-shaped arc inside the first hole;
Excavating an inner ground of the first hole, a ground between the plurality of first holes, and an inner ground between the plurality of first holes;
Providing an outer mold to a pair of pivotal outer mold guides disposed outside of said first member of said corrosion resistant lid;
Disposing a reinforcing bar inside the H-shaped steel;
Disposing an inner mold on the inner side of the reinforcing bar; And
Placing and curing concrete between the outer mold and the inner mold,
The first member, the pair of second members, and the pair of third members of the corrosion-prevention lid are disposed in contact with the outer side surface, both side surfaces, and the inner side surface of the outer flange of the H-
Wherein the corrosion-preventing lid further comprises a pair of angled induction flanges provided inside the pair of third members,
And a drain member is inserted into the groove of the induction flange. The method of claim 9,
Wherein a nut is provided on the web of each of the plurality of H-
The composite wall building construction method further includes the step of joining a steel bar connecting the two H-shaped steel bars adjacent to the nut before pouring and curing the concrete between the outer mold and the inner mold,
Wherein the steel bar is disposed closer to the inner flange than the outer flange of the H-shaped steel. delete

Images