KR200428941Y1 - Strut system of temporary retaining wall - Google Patents

Abstract

The present invention provides an opening in the embedded slab which is buried in the basement outer wall while contacting it with the basement wall when the basement wall is constructed as the basement wall and the joining wall in the supporting structure of the basement wall where the interlayer slab of the building basement supports the barrier wall. The present invention relates to a reverse support structure of a retaining wall that enables the construction of a basement wall to be continuously carried out by constructing it, and a method of continuous construction of a building basement joint wall which suppresses the occurrence of a reverse joint of the basement outer wall and strengthens the integrity by applying the same.

The reverse support structure of the retaining wall for the continuous construction of the underground plywood of the present invention is the retaining wall; A beam constructed toward the retaining wall; And, reinforced concrete slab which is constructed to be in close contact with the retaining wall above the beam and is constructed to directly support the retaining wall.

The reinforcement concrete slab is divided into a buried slab buried in the basement outer wall and an exposed slab exposed outside the basement outer wall while the cladding wall is constructed of a basement outer wall and a cladding wall. After installing the embedding die plate including the vertical plate portion vertically installed more than the exposed slab thickness along the opening of the bottom plate portion, the concrete is poured over the exposed slab thickness to form an opening at the boundary of the vertical plate portion, integral construction with the exposed slab The embedding die plate is characterized in that it is formed to a size that can be penetrated through the vertical reinforcement of the outer layer of the outer wall to be arranged in two layers so that the opening facing each other.

Retaining wall, plywood, inverted joint, earth pressure, continuous

Description

Strut system of temporary retaining wall for continuous construction of underground plywoods

1 and 2 are a plan view (a) and a cross-sectional view (b) to (d) according to a construction sequence showing a reverse support structure of a conventional underground retaining wall.

Figure 3 is a plan view (a) and a cross-sectional view (b) to (e) according to the construction sequence showing an embodiment of the reverse support structure of the retaining wall for the continuous construction of the underground plywood according to the present invention.

4 is a cross-sectional view showing various embodiments of the construction form of the embedded slab in the reverse support structure of the retaining wall for the continuous construction of the underground plywood according to the present invention.

Figure 5 is a view showing various embodiments of the formwork forming plate applied to the present invention.

<Description of Major Symbols in Drawing>

10: retaining wall 11: filling material

15: fixing member 15a: supporting member

15b: fixing member

20: see 25: pedestal

30: reinforced concrete slab 30a: embedded slab

30b: exposed slab 35: slab rebar

40: embedded die plate 41a: vertical plate portion

41b: bottom plate portion 43: opening portion

45: water chin

50: outer wall

S: Sleeve B: Dowel Bar

J: Inverted Joint

The present invention relates to a reverse support structure of a retaining wall for continuous construction of underground plywood. More specifically, in a supporting structure of an underground retaining wall in which an interlayer slab of a building basement supports a retaining wall, It relates to a reverse support structure of a retaining wall that allows the construction of a basement outer wall to be continuously carried out by constructing an opening of a buried slab which is buried in the basement outer wall while contacting the retaining wall.

In general, the underground structure is constructed by constructing the main wall wall such as H-Beam + earth plate, CIP (Cast in-Place Pile), SCW (Soil Cement Wall), and then excavating the inside of the wall to build the structure. Excavation process involves bracing work to support external force such as earth pressure delivered through wall. Generally, temporary wall struts, ground anchors, or permanent structures are used for the construction of the retaining walls. Among these, adjacent structures in the city center use the permanent structures to secure structural stability, shorten the air, and generate civil complaints. It is the most advantageous when considering aspects, such as possession inhibition.

The support method using the permanent structure is composed of the reverse support method in combination with the reverse punching method.In this reverse support method, the beams and slabs, which are horizontal interlayer structures in the basement of the building, are constructed and pre-installed to serve as the permanent structures supporting the wall The remaining upper and lower cladding parts between the rim beams or slabs, which are horizontal interlayers, will be constructed later. That is, the interlayer structure is first constructed to directly support the retaining wall in the form of slab or rim beam, and then excavated. Generally, this process is repeatedly performed to the lowermost basement, and then the basement outer wall is built integrally with the retaining wall. It will be constructed with plywood.

1 and 2 is a view showing an example of the conventional underground retaining support method, Figure 1 is a state in which the slab supports the retaining wall, Figure 2 is an example in which the rim beam is constructed for the structural safety reinforcement of Figure 1 As a result, the rim beam supports the retaining wall.

Conventional underground plywood structure extends the slab or rim beam to the underground outer wall portion as shown in Figs. 1 and 2 to support the external force such as earth pressure by pre-installed to settle directly to the earth wall, and to post-install the remaining upper and lower parts of the outer outer wall Or it consists of a method of embedding the rim beam in the basement outer wall. At this time, for the post-construction of the basement outer wall, the installation of concrete sleeve (S) must be installed on the slab or the rim beam to be pre-installed, and furthermore, to integrate the basement outer wall of the upper and lower layers due to the difficulty of continuous reinforcement of the interlayer main reinforcing bars. Installation of a separate dowel bar (B) is required (see FIGS. 1B and 2B).

However, concrete pouring through sleeves is difficult to construct and makes it difficult for concrete to be filled tightly, resulting in inverted joints (interlayer gaps in the outer wall of the basement, J) on the slab or rim beams (FIG. 1C and 2c), the reverse oscillation joint (J) acts as a cause of deterioration of the structural performance of the building to further develop after the concrete shrinkage (see FIGS. 1d and 2d). That is, the inflow of groundwater is made through the inverted joint. The inflow of groundwater causes corrosion of reinforcing steel and deterioration of concrete, resulting in deterioration of durability of the structure.

The present invention was devised to improve the above-mentioned problems, and in the support structure of the basement wall, in which the interlayer slab of the building basement is constructed to support the barrier wall, the barrier wall is in contact with the barrier wall when the barrier wall is constructed as the basement outer wall and the plywood wall. The purpose is to provide a reverse support structure for the basement wall, which allows the construction of the basement wall to be easily carried out by constructing the buried slab embedded in the basement wall.

Another object of the present invention is to support the underground retaining wall while constructing the buried slab that is embedded in the underground outer wall so that the opening is formed, thereby making it possible to easily construct the underground outer wall interlayer continuously without installing the sleeve or the dowel bar. To provide a support structure.

Another object of the present invention is to provide a reverse support structure for an underground mud wall to block the groundwater introduced through the mud wall to improve the waterproofing performance of the basement outer wall by providing a configuration that serves as a water stop.

The present invention to achieve the above object is an earthen wall; A beam constructed toward the retaining wall; And, reinforced concrete slab which is constructed to be in close contact with the retaining wall above the beam and is constructed to directly support the retaining wall.

The reinforcement concrete slab is divided into a buried slab whose end contacting with the mud wall is buried in the basement outer wall and an exposed slab exposed outside the basement outer wall, and the buried slab is formed of an opening plate. And a buried formwork plate including a vertical plate portion vertically installed above the exposed slab thickness along the opening of the bottom plate portion, and then placing concrete above the exposed slab thickness to form an opening at the vertical plate portion boundary. It is integrally constructed, and the embedded formwork plate is formed to have a size that can be penetrated by simultaneously penetrating the vertical reinforcement of the basement outer wall, which is arranged in two layers so as to face the opening, and reverses the soil wall for the continuous construction of the underground plywood wall. Provide a support structure.

Hereinafter, the present invention according to the accompanying drawings and preferred embodiments will be described in detail.

The present invention is in the structure of the support of the basement wall in which the interlayer slab of the building basement is constructed to support the barrier wall, the basement outer wall while contacting the barrier wall (10) when the barrier wall (10) is constructed as a base wall and the outer wall (50) As the embedded slab 30a embedded in the 50 is constructed so that the opening 43 is formed, in the construction of the basement outer wall 40, the interlayer continuous reinforcement of the vertical reinforcement and the interlayer continuous casting of the concrete are possible, thereby enhancing the integrity. It is a technical feature to complete the underground plywood. According to this technical feature, the present invention proposes a reverse support structure of an underground retaining wall.

3 is a view showing a reverse support structure of the basement wall according to the present invention. In the underground reverse drilling method, the supporting structure of the underground retaining wall is the retaining wall (10); A beam 20 constructed toward the retaining wall 10; And a reinforced concrete slab 30 which is constructed to be in close contact with the retaining wall 10 above the beam 20 and is constructed to directly support the retaining wall 10. Concrete slab 30 serves as an interlayer horizontal structure supporting the retaining wall (10). The present invention is the construction form of reinforced concrete slab (30) to continuously install the basement outer wall (50) between floors when constructing the basement wall (10) and the basement outer wall (50) in the basement plywood in the ground structure Is changing. In other words, the reinforced concrete slab 30 has a structure that sufficiently guides the interlayer continuous reinforcement of the vertical reinforcement of the basement outer wall 50 and the interlayer continuous casting of the concrete while sufficiently supporting the retaining wall 10.

Specifically, in the present invention, the embedded slab 30 is buried in the basement outer wall 50 while contacting the reinforced concrete slab 30 with the soil wall 10; and the exposed slab 30b exposed outside the basement outer wall 50; Then, after installing the embedding slab (40) to the embedding slab (30a) and cast concrete more than the exposed slab (30b) thickness to maintain the opening 43 as it is to be integrated with the exposed slab (30b) have. However, the embedded die plate 40 for the construction of the embedded slab 30a includes a bottom plate portion 41b having an opening 43 formed therein; and vertically above the exposed slab 30b thickness along the opening 43 of the bottom plate portion. It is configured to include a vertical plate portion (41a), and the opening 43 is to be adopted to be formed to a size that can be penetrated through the vertical reinforcement of the basement outer wall 50, which is double reinforcement facing each other at the same time have. As a result, the present invention is to support the retaining wall 10 in a state where the reinforced concrete slab 30 is integrated with the embedded slab 30a and the exposed slab 30b until the stage before the construction of the basement outer wall 50, After construction of the basement outer wall 50, the embedded slab 30a of the reinforced concrete slab is embedded in the basement outer wall 50 so that only the exposed slab 30b serves as an interlayer structure of the completed building. The opening 43 of the embedding die plate remains in the opening state as the boundary of the vertical plate portion 41a even after the embedding slab 30a is completed, which is the interlayer continuous reinforcement of the vertical reinforcement of the basement outer wall 50 and the concrete. It is used as a space for continuous casting between floors.

Figure 4 shows various embodiments of the construction form of the embedded slab 30a in the reverse support structure of the retaining wall for the continuous construction of the underground plywood according to the present invention. The embedded slab 30a may be constructed with the same thickness as the exposed slab 30b, as shown in FIG. 3 (b), but the portion where the embedded slab 30a is in direct contact with the retaining wall 10 receives the most horizontal force. Considering that it is desirable to be made of a reinforcing structure compared to the exposed slab (30b). Thus, in the present invention, as shown in FIG. 4 (a), the entire embedded slab 30a is formed thicker than the exposed slab 30b, or as shown in FIG. 4 (c), the earth wall of the embedded slab 30a ( 10) It is proposed to form the end of the most direct contact with the cross section below. In the case of Figure 4 (a) it can be easily implemented by adopting that the height of the vertical plate (41a) is made larger than the exposed slab (30b) thickness by the embedded die plate (40). In particular, if the upper end of the buried slab 30a is formed to extend in cross section below, as shown in FIG. 4 (c), the extended best end may also serve as a water cutting jaw, contributing to improved waterproof performance. On the other hand, Figure 4 (b) is a form constructed by applying the embedded slab plate provided with a water cutting jaw directly to improve the waterproof performance.

FIG. 5 is a view illustrating various embodiments of the embedding die plate 40 applied to the construction of the embedded slab 30a in the present invention, and the embedding die plate 40 has a bottom plate portion in which an opening 43 is formed ( 41b) and a vertical plate portion 41a vertically placed along the opening portion. The bottom plate portion 41b and the vertical plate portion 41a serve as formwork surfaces for concrete placing of the embedded slab 30a, and in particular, the vertical plate portion 41a also serves as a reinforcing material supporting the horizontal force. In view of such a role, the purchase die 40 is appropriate to be manufactured by adopting a material having a certain structural strength such as steel sheet, thin precast concrete, and wire mesh, and it is also possible to manufacture two or more materials in combination. Do. However, when the embedded die plate 40 is made of metal such as steel sheet or wire mesh, the bottom plate portion 41b is waterproofed to reduce the strength of the embedded slab 30a through corrosion inhibition of the embedded die plate 40. It is desirable to prevent. On the other hand, the opening 43 formed in the bottom plate portion 41b of the embedding die plate may be any shape, such as square, triangular, cylindrical, but if the area is minimized, the structural strength of the embedded slab 30a will be maximized. As shown in FIG. 5, a butterfly opening which gradually narrows in width and then widens again is preferable.

The embedding formwork plate 40 of FIG. 5 is all manufactured as a unit unit, and they are continuously installed. 5 (a) to 5 (c) show the buried formwork plate 40 in the form of one opening 43, Figures 5 (d) and 5 (e) is three openings 43 5 shows a formwork plate 40 having a form formed therein, and FIG. 5 (f) shows the formwork plate 40 having an intermittent embossing formed on the surface to strengthen the unity with concrete. FIG. 5 (g) shows the embedding die plate 40 in which the bottom plate portion 41b is made of wire mesh, and FIG. 5 (h) shows a separate opening as the bottom plate portion 41b is made of wire mesh. 5 shows a buried formwork plate 40 having no shape (the gap between the wire mesh can be utilized as an opening in the case where only the bottom plate portion and the vertical plate portion are provided without forming an opening portion), and FIG. 5 (i) shows the bottom plate portion. (41b) shows the buried formwork plate 40 protruded water projection jaw 45 formed on the lower surface. Although not specifically illustrated, the embedding die plate 40 may be manufactured so that continuous irregularities are formed, such as a conventional deck plate, to enhance the integrity of the concrete and serve as a water cutting jaw. Particularly, when the embedded die plate 40 is made of steel sheet and the exposed slab 30b of the reinforced concrete slab is constructed as a deck plate, the deck plate of the exposed slab 30b and the bottom plate portion 41b of the embedded die plate are If it is configured to be manufactured integrally, the decking plate installation process of the embedding slab 40 and the exposed slab 30b of the embedded slab will be integrated into one, and as a result, the integrity of the embedded slab 30a and the exposed slab 30b will be further strengthened. Will be.

On the other hand, the reverse support structure of the above-mentioned ground mud wall of the present invention can be applied to complete the mud wall, with reference to Figure 3 will be described how to apply the reverse support structure of the ground mud wall of the present invention.

(a) construction and installation of internal pillars

First, construct the retaining wall 10 on the boundary line where the building is installed, and install the column at the position of the inner pillar. The soil wall 10 may be any case that is constructed in a heat-heating manner, such as H-Beam + earth plate, CIP (Cast in-Place Pile), SCW (Soil Cement Wall), and FIG. 3 is a soil wall (CIP 10). ).

(b) excavation

Excavate to a predetermined depth. At this time, the excavation proceeds to the extent that the retaining wall 10 exposed to the outside can support the earth pressure sufficiently.

(c) Construction of interlevel horizontal structures

The interlayer horizontal structure of the beam 20 and the reinforced concrete slab 30 is constructed as a horizontal support of the retaining wall 10 while applying the reverse support structure of the above-mentioned underground retaining wall. Beam 20 is constructed so as to face the retaining wall 10, and may be in any form, such as steel, SRC, RC, PC, composite structure, Figure 3 shows a steel cheolgolbo not settled in the retaining wall (10) Doing. If the reinforced concrete slab 30 is constructed so that the embedded slab 30a and the exposed slab 30b are distinguished, the embedded slab 30a is constructed by applying the embedded formwork plate 40, and includes a reinforced concrete structure. 3 shows the reinforced concrete slab 30 in which the slab reinforcing bar 35 is disposed on-site while the deck plate is used to construct the exposed slab 30b.

In particular, when using the deck plate in the construction of the exposed slab 30b of the reinforced concrete slab 30 as shown in Figure 3 to connect the beam 20 adjacent to the end of the beam 20 in order to stably mount the deck plate Mounting beam 25 may be further installed, the mounting beam 25 is installed in the same position as the inner line of the basement outer wall 50 to avoid interference with the main reinforcing bar 55 of the basement outer wall. Furthermore, the deck plate of the exposed slab 30b and the purchase formwork plate of the embedded slab 40 are integrally manufactured for easy construction of the reinforced concrete slab 30 divided into the embedded slab 30a and the exposed slab 30b. May be adopted.

(d) completion of supporting wall

Repeating the excavation step and the step (c) of the interlayer horizontal structure construction step of step (b) to complete the supporting wall 10 by the interlayer horizontal structure to the lowermost floor of the building.

(e) construction of plywood

When the retaining wall 10 supporting frame is completed, the basement outer wall 50 in contact with the retaining wall 10 is constructed. The construction of the basement outer wall 50 is to reinforce the vertical rebar to pass through the opening of the buried slab (30a), and then cast concrete through the opening of the buried slab (30a) to the end of the beam 20 of the interlayer horizontal structure It is made of a method of embedding the embedded slab (30a) of the concrete slab. Since the opening of the embedded slab 30a is sufficiently secured in the construction of the interlayer horizontal structure, the interlayer continuous reinforcement of the vertical reinforcement of the basement outer wall and the interlayer continuous casting of the concrete are possible through the opening. Thus, the basement outer wall 50 is constructed as a single underground plywood in contact with the retaining wall while strengthening the interlayer integrity.

The construction of the plywood wall may also be performed for the purpose of shortening the air and increasing work efficiency even in the completion of the retaining wall support frame in step (d). In other words, even if it is not the lowest floor of the building, when the construction of some inter-level horizontal structures is completed, the reference floor is set, and concrete is then sequentially poured on the basis of the inter-layer horizontal structure of the reference floor to construct the basement outer wall 50 integrally with the earth wall 10. The middle wall construction step is to proceed and the middle wall construction step is to be carried out simultaneously with the excavation and construction of the inter-layer horizontal structure of the reference layer or less.

According to the present invention as described above, in the support structure of the basement wall, in which the interlayer slab of the building basement is constructed to support the wall, when the wall is constructed as the base wall and the cladding wall, it is embedded in the base wall while contacting the wall of the wall By constructing the slab using the embedded slab plate having the opening, the opening can be maintained as it is, so that the construction of the basement outer wall can be continuously carried out between layers. As a result, it is possible to easily vertically reinforce the vertical reinforcement of the basement outer wall without installing a sleeve or a dowel bar, and also to continuously cast concrete without distinction between layers, thereby strengthening the integrity while suppressing the occurrence of reverse joints. Can be completed with plywood.

In addition, the present invention can be completed by using a built-in formwork plate provided with a water cutting jaw in the construction of the embedded slab or by extending the cross section below the top end of the embedded slab to serve as a water breaking jaw, thereby improving the waterproofing basement plywood. do.

Claims (7)

Earthen wall; A beam constructed toward the retaining wall; And, reinforced concrete slab which is constructed to be in close contact with the retaining wall above the beam and is constructed to directly support the retaining wall. The reinforcement concrete slab is divided into a buried slab which is buried in the basement outer wall and an exposed slab exposed outside the basement outer wall while the retaining wall is constructed of the basement outer wall and the joining wall. The buried slab is provided with a bottom plate portion having an opening formed therein and a buried formwork plate including a vertical plate portion vertically installed above the exposed slab thickness along the opening of the bottom plate portion, and then placing concrete above the exposed slab thickness to limit the vertical plate portion. It is constructed integrally with the exposed slab while forming the furnace opening, The buried formwork plate is a support structure for the earth wall for continuous construction of the underground plywood, characterized in that formed in the size to be able to penetrate through the vertical reinforcement of the basement outer wall to be reinforced in two layers to face the opening. In claim 1, The buried formwork of the embedded slab is made of any one of steel sheet, thin precast concrete or wire mesh or composited with two or more materials. In claim 2, When the embedded die of the embedded slab is made of steel sheet, when the exposed slab of the reinforced concrete slab is constructed as a deck plate, the deck plate of the exposed slab and the bottom plate of the embedded die of the embedded slab are integrally manufactured. Inverted support structure of retaining wall for continuous construction of underground plywood. In claim 2, In the case where the bottom plate of the embedded die of the embedded slab is made of wire mesh, the wire mesh is disposed in the opening of the bottom plate, and the embedded slab is constructed such that the opening is formed at the boundary of the vertical plate. Reverse support structure of the retaining wall for construction. The method according to any one of claims 1 to 4, Recess support structure of the retaining wall for the continuous construction of the underground plywood, characterized in that the buried formwork of the embedded slab is formed intermittent embossing or continuous irregularities on the surface. The method according to any one of claims 1 to 4, Recess support structure of the retaining wall for the continuous construction of the underground plywood, characterized in that the buried formwork plate of the buried slab is made to protrude water breaking jaw on the bottom surface of the bottom slab. The method according to any one of claims 1 to 4, Reverse support structure of the earth wall for the continuous construction of the underground plywood, characterized in that the top end of the reinforced slab of the slab embedded slab directly in contact with the earth wall is extended in the form of a cross section downward.

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