KR20170135494A - Form assembly - Google Patents

Abstract

The present invention relates to a mold assembly which has a structure in which a reinforced concrete structure can stably accommodate stored goods, and can reduce a period and costs consumed to construct the reinforced concrete structure. According to an embodiment of the present invention, the mold assembly comprises: an internal mold configured to form an accommodation space of stored goods; an external mold configured to cover the internal mold and form a concrete depositing space between the internal mold and the external mold; and a coupling member mutually coupling the internal mold and the external mold.

Description

FORM ASSEMBLY < RTI ID = 0.0 >

The present invention relates to a formwork assembly for constructing a reinforced concrete structure.

Structures constructed with reinforced concrete to protect storage tanks such as septic tanks buried in the ground are known in the art. With respect to such a reinforced concrete structure, for example, Korean Unexamined Patent Application Publication No. 2003-0028503 proposes a concrete integrated type septic tank structure. In order to construct the reinforced concrete structure proposed by the above document, a reinforcing material is installed around the septic tank, and the die is assembled around the septic tank so as to be separated from the septic tank. Also, the concrete is poured into the spaced space between the septic tank and the formwork, and cured.

However, in order to construct a reinforced concrete structure according to the above document, it is necessary to use a storage tank manufactured as an integral type, for example, the structure, specification, material and performance of a sewage treatment facility manufactured product of the sewerage method Article 52 (3) Products made of polyethylene (PE) or glass fiber reinforced plastic (FRP) that are subject to the standard [Table 12] shall be used. Such an integral type storage tank is considerably large and heavy, so it is difficult to transport the storage tank from the manufacturing factory to the construction site, and it is difficult to store the storage tank even when it is transported to the construction site. In addition, in some cases, it is difficult to assemble the formwork in the storage tank in the construction site. Therefore, it is troublesome to transport the storage tank and the formwork to a separate place, In addition, since the form is not stably supported in the storage tank, the stability of the form is weak, and the space between the storage tank and the formwork, that is, the space for placing the concrete, is complicated. Therefore, when the reinforced concrete structure is installed, it is difficult to inject concrete into the space, and it is difficult to construct a strong reinforced concrete structure. Also, when the storage tank is broken due to the concrete pressure generated during the construction of the reinforced concrete structure, soil around the structure may be easily contaminated due to leakage of the stored water stored in the storage tank.

Korean Patent Publication No. 2003-0028503

When constructing a reinforced concrete structure for accommodating a stored product, it is desirable to have a structure capable of stably receiving the stored product, and to shorten the construction time required for the construction and reduce the construction cost.

The present invention provides a mold assembly having a structure in which a reinforced concrete structure can stably receive a stored product, and can reduce the time and cost required for constructing the product.

To this end, the present invention provides a formwork assembly for constructing a reinforced concrete structure capable of receiving a stored product without using a storage tank.

The present invention provides a dual structure form assembly. The mold assembly according to an exemplary embodiment includes an inner mold that is configured to form a containment space for the stock, an outer mold that surrounds the inner mold and forms a concrete pouring space between the inner mold and the inner mold, And a joining member for joining the form to each other.

In one embodiment, the form assembly further includes a reinforcing steel reinforcement disposed in the concrete pouring space.

In one embodiment, the inner mold is formed of a plate-shaped inner assembling member, and the outer mold is formed of a plate-like outer assembling member.

In one embodiment, the inner building member includes a plurality of inner side plates and a plurality of inner end plates, wherein the outer building member includes a plurality of outer side plates and a plurality of outer end plates. Further, the diameter of the inner end plate is formed to be larger than the diameter of the end face of the cylindrical portion composed of the plurality of inner side plates. Further, the engaging member has the inner end plate between the outer side plate and the outer end plate to engage the outer side plate, the outer end plate, and the inner end plate with each other.

In one embodiment, the inner side plate and the outer side plate are curved shapes and include a protruding opening in any one of the plurality of inner side plates.

In one embodiment, the inner end plate includes a plurality of first fasteners for engagement with the plurality of inner side plates, and a plurality of second fasteners for engagement with the plurality of outer side plates and the outer end plate. And the inner and outer molds are coupled to each other by the coupling member. An inner notch for pouring concrete is formed on the upper edge of the inner end plate.

In one embodiment, each of the plurality of inner side plates has a pair of inner curved flanges and a pair of inner straight flanges at the edges. Wherein the inner curved flange includes a plurality of inner curved fasteners corresponding to the plurality of first fasteners and the inner linear flange includes a plurality of inner linear fasteners for coupling between the plurality of inner side plates .

In one embodiment, the outer end plate is formed with a plurality of third fasteners corresponding to the plurality of second fasteners, and an outer notch portion for pouring concrete is formed at an upper edge of the outer end plate.

In one embodiment, each of the plurality of outer side plates has a pair of outer curved flanges and a pair of outer straight flanges at the edges. A plurality of outer curved fasteners corresponding to the plurality of second fasteners are formed in the curved outer flange, and a plurality of outer linear fasteners for joining the plurality of outer side plates are formed in the outer linear flange .

In one embodiment, the form assembly further includes a foot plate coupled to a lower edge of the inner end plate by the engagement member.

In one embodiment, the reinforcing steel reinforcement comprises a plurality of vertical stiffeners arranged in the longitudinal direction in the concrete installation space, a plurality of horizontal stiffeners arranged in the lateral direction in the concrete installation space, and a plurality of vertical stiffeners And a wire wound on at least one of the vertical stiffener and the horizontal stiffener for fixing the position.

In one embodiment, the reinforcing steel reinforcement further includes a plurality of spacers interposed between at least one of the vertical reinforcement and the horizontal reinforcement to position the vertical reinforcement and the horizontal reinforcement in the concrete installation space.

In one embodiment, the inner and outer assembly members are formed of a synthetic resin material comprising at least one of polyethylene, glass fiber reinforced plastic.

According to an embodiment of the present invention, a reinforced concrete structure capable of stably receiving stored products without using a storage tank integrally manufactured using a dual structure formwork assembly can be constructed. Assembly members assembled with formwork assemblies are modularized, easy to transport and store, and easy to assemble. In addition, since the formwork assembly has a structure in which the outer formwork is directly coupled to the inner formwork, the structure has a stable structure and the space structure for pouring concrete between the inner formwork and the outer formwork is simple. Therefore, it is possible to smoothly place the concrete in the concrete insertion space formed between the inner formwork and the outer formwork, so that a strong reinforced concrete structure can be constructed. Also, since the inner formwork and the outer formwork of the formwork assembly are integrated into the wall of the reinforced concrete structure, the waterproofing and the method performance are excellent. Therefore, even when using for a long time, the safety of the reinforced concrete structure is excellent, so that the reliability of the quality of the structure can be improved. As described above, the reinforced concrete structure constructed using the formwork assembly according to one embodiment of the present invention is shorter in construction time and in construction cost than the reinforced concrete structure constructed using the conventional storage tank .

1 is a perspective view illustrating a form assembly according to an embodiment of the present invention.
FIG. 2 is a perspective view of a form assembly according to an embodiment of the present invention.
3 is a perspective view showing the inner formwork of the form assembly shown in Fig.
Fig. 4 is an enlarged view of part B shown in Fig. 3. Fig.
FIG. 5 is a perspective view showing an inner assembling member assembled with the inner mold shown in FIG.
Fig. 6 is an enlarged perspective view of the inner side plate of the inner assembly member shown in Fig. 5; Fig.
Fig. 7 is an enlarged perspective view of the inner end plate of the inner assembling member shown in Fig. 5; Fig.
8 is a perspective view illustrating a form assembly according to another embodiment of the present invention.
9 is a perspective view showing an inner formwork of the formwork assembly shown in Fig.
10 is a perspective view showing an inner end plate according to a modification of the present invention.
11 is a longitudinal sectional view of a form assembly to which the inner end plate shown in Fig. 10 is applied.
Fig. 12 is an enlarged view of part C shown in Fig.
13 is an enlarged view of portion D shown in Fig.
FIG. 14 is a perspective view illustrating an inner die of a reinforcing steel reinforced material according to an embodiment of the present invention. FIG.
FIG. 15 is a perspective view showing an inner formwork in which a reinforcing steel reinforcement is wired according to another embodiment of the present invention. FIG.
16 is a view showing a part of an inner mold provided with a reinforcing steel reinforcement according to an embodiment of the present invention.
17 is a view showing a modified example of the inner linear flange of the inner mold according to the embodiment of the present invention.
Fig. 18 is an enlarged view of portion E shown in Fig. 16. Fig.
Fig. 19 is an enlarged view of the portion F shown in Fig. 16. Fig.
20 is a perspective view showing a spacer according to an embodiment of the present invention.
21 is a perspective view illustrating an outer assembly member assembled into an outer mold according to an embodiment of the present invention.
22 is an enlarged view of part A shown in Fig.
23 is a flowchart illustrating a method of constructing a reinforced concrete structure according to an embodiment of the present invention.
24 to 28 are reference views for explaining a method of constructing a reinforced concrete structure according to an embodiment of the present invention.

Embodiments of a mold assembly according to the present invention will be described with reference to the accompanying drawings. In the drawings, the same reference numerals designate the same or corresponding components or parts.

As used herein, the direction indicators such as 'upper' and 'upper' refer to directions in which the protrusion openings of the form assembly are oriented with respect to the ground, and direction indicators such as 'down' and 'lower' do. As used herein, the direction indicators such as 'forward', 'front' and the like refer to a direction in which one end of the form assembly approaches, in a form assembly extending parallel to the ground, and 'rear' The direction of the direction indicator means the opposite direction. The form assembly shown in the accompanying drawings may be placed differently and the directional directives may be interpreted accordingly.

The reinforced concrete structure to be constructed using the formwork assembly of the embodiment can be used as a storage tank for storing the stored contents, a water tank, an acid tank, a sewage treatment facility (sewage treatment facility, a septic tank), and the like. In the case of a reinforced concrete structure constructed using a conventional storage tank, the reinforced concrete structure serves as a protection box for protecting the storage tank, but the reinforced concrete structure according to the embodiment itself serves as a storage tank .

Referring to Figures 1 and 2, the form assembly 1000 of one embodiment has a dual tank structure in which one of the two tanks having a dual structure, specifically a corresponding shape, is received in the other tank. The form assembly 1000 includes an inner mold 100 and an outer mold 200 having a shape corresponding to the inner mold 100. The outer mold 200 surrounds the inner mold 100, 100 in a direction perpendicular to the surface of the substrate. The inner mold 100 includes a plurality of plate-shaped members, that is, inner assembly members (see 121A to 121D and 130 in Fig. 5), which become the base material to be assembled into the inner mold 100. Similarly, the outer mold 200 includes a plurality of plate-shaped members, that is, outer assembly members (see 210A to 210D and 220 in Fig. 21), which are basic materials to be assembled into the outer mold 200. [ The inner mold 100 is assembled into a tubular shape by the inner assembling members 121A to 121D and 130. [ The outer mold 200 is assembled into a tubular shape in which an upper part of the outer mold assembly 200 is opened by the outer assembly members 210A to 210D and 220 (i.e., not surrounded by the outer assembly members 210A to 210D and 220) A space for pouring concrete 10 (see Fig. 26) between the pouring mold 100 and the concrete pour space S1 is formed. An upper portion of the inner mold 100 is exposed to the outside by an opened upper portion of the outer mold 200. The upper part exposed to the outside of the inner mold 100 is in communication with the concrete installation space S1 so that the concrete 10 is poured into the open upper part of the outer mold 200, And is injected into the space S1. In the form assembly 1000, the concrete 10 may be cured by being placed on the upper part of the inner mold 100 exposed to the outside, as well as the concrete placement space S1. The form assembly 1000 of one embodiment further includes a reinforcing steel reinforcement 300 embedded in the concrete 10 to be cured and integrally cured with the concrete 10. The reinforcing steel reinforcement 300 is installed in the concrete installation space S1. The form assembly 1000 of one embodiment is used to assemble the inner mold 100 and the outer mold 200 and includes a coupling member 400 for coupling the inner mold 100 and the outer mold 200 together .

The outer assembly members 210A to 210D and 220 assembled into the inner assembly members 121A to 121D and 130 assembled into the inner mold 100 and the outer mold 200 are assembled together with the inner mold 100 and the outer mold 200, And is modularized according to the site unit or the functional unit in each of them, and has a standardized size and shape. Therefore, the inner assembling members 121A to 121D and 130 and the outer assembling members 210A to 210D and 220 are easy to carry, store and assemble, and can be easily replaced even if breakage occurs during handling. Compared with the prior art in which a storage tank needs to be replaced entirely in the event of a breakage in the storage tank, the form assembly 1000 is constructed and used to provide a reinforced concrete structure 2000 (see Figures 27 and 28) Construction period and construction cost for construction can be reduced.

In one embodiment, the engaging member 400 includes an inner assembling member 121A to 121D, 130, outer assembling members 210A to 210D, 220, or inner assembling members 121A to 121D, A bolt 410 inserted into the assembling members 210A through 210D and 220 and a washer 420 inserted into the bolt 410 and a nut 430 screwed or bolted to the bolt 410 (See Figs. 17 and 18). The bolts 410 may be formed of the inner assembling members 121A to 121D and 130 assembled by the engaging member 400 and / or the outer assembling members 210A to 210D and 220 during the construction of the reinforced concrete structure 2000 It is preferable to use a high-strength bolt capable of withstanding the pressure of the concrete so as not to be arbitrarily separated by the concrete pressure. The bolt 410 has a length sufficient to fit through the plurality of inner assembling members 121A to 121D and 130 and / or the outer assembling members 210A to 210D and 220, and the operator tightens the nut 430 The hexagonal head can be provided to facilitate the screwing operation. The bolts 410, the washers 420 and the nuts 430 may be defined in consideration of the concrete pressure generated during the construction of the reinforced concrete structure 2000. Although the bolt 410, the washer 420 and the nut 430 are used as the coupling member 400 in the embodiment, the coupling member 400 is not limited to the bolt 410, the washer 420 and the nut 430. For example, May be used in parallel.

Referring to Figures 3 and 4, the inner formwork 100 includes a storage receiving space S2 (see Figures 25-28) of a storage (e.g., wastewater, wastewater, water or oil, etc.) In the form of a tank that forms the inside of the tank. The inner mold 100 is combined with the reinforced concrete wall 2100 (see FIGS. 27 and 28) formed by hardening the concrete 10 when the reinforced concrete structure 2000 is installed. The inner formwork 100 of one embodiment has a substantially cylindrical assembly shape, but is not limited thereto. In other embodiments, the inner mold 100 may have an assembled shape, such as a polygonal tube.

The inner mold 100 has a main body 110 in which at least one cylindrical portion 120 is engaged while being coupled to each other in the lateral direction (forward and backward directions FD / RD in FIG. 3) And a pair of inner end plates 130 which are assembled to be opposed to the open both ends in the direction (forward and backward direction). The inner end plate 130 is assembled to the body portion 110 by a plurality of engaging members 400 and closes the open end of the body portion 110. [ The body portion 110 of one embodiment includes one cylindrical portion 120. The body portion 110 'of another embodiment includes a plurality of cylindrical portions 120, which will be described later.

Referring to FIG. 5, the inner assembling members 121A to 121D and 130 include a plurality of inner side plates 121A to 121D assembled with the cylindrical portion 120 together with a pair of inner end plates 130. As shown in FIG. The plurality of inner side plates 121A to 121D have a curved shape with a predetermined curvature and the edges are assembled to the cylindrical portion 120 by being abutted to each other. In one embodiment, the cylindrical portion 120 is formed by four inner side plates 121A to 121D, but is not limited thereto. Of the four inner side plates 121A to 121D, the inner side plate 121A is disposed so as to be convex to the upper side UD, the inner side plate 121B is disposed to be convex downward (LD) 121C are arranged so as to be convex to the left room LSD and the inner side plate 121D is arranged to be convex to the right room RSD. The inner side plate 121A is provided with a protruding opening 122 protruding toward the upper side UD. The protruding openings 122 serve as an inlet or an inlet of the storage for accommodating the storage in the interior of the reinforced concrete structure 2000. One protrusion opening 122 is provided in the inner side plate 121A but a plurality of protrusion openings 122 may be provided when the area of the inner side plate 121A is large.

Each of the plurality of inner side plates 121A to 121D has two long sides and two short sides facing each other and a rectangular plate shape in which the short side is curved. 6, each of the inner side plates 121A to 121D includes a pair of inner linear flanges (bent in a direction toward the outer side when assembled into the cylindrical portion 120) 123 and a pair of inner curved flanges 124 connecting the pair of inner straight flanges 123. Although the inner side plate 121D is shown as an example in Fig. 6, the inner side flange 123 and the inner side curved flange 124 are also provided in the other inner side plates 121A to 121C. The inner linear flange 123 is formed on each of the two long sides of the inner side plates 121A to 121D and the inner curved flange 124 is formed on the two short sides of the inner side plates 121A to 121D respectively. A plurality of inner straightening fasteners 125 are formed in the inner straightening flange 123 to allow the bolts 410 of the fastening member 400 to be inserted in the longitudinal direction of the inner straightening flange 123 for engagement between the plurality of inner side plates. do. The inner curved portion flange 124 is formed with a plurality of inner curved coupling portions 126 through which the bolts 410 of the coupling member 400 can be inserted in the extending longitudinal direction. The plurality of inner curved portion fasteners 126 correspond to the plurality of first fasteners 134 formed on the inner end plate 130. In one embodiment, the inner straight line fastener 125 and the inner curve fastener 126 are equally spaced in the inner linear flange 123 and the inner curved flange 124, respectively, but are not limited thereto Do not. For example, in the portion where the pressure of the concrete generated at the time of construction of the reinforced concrete structure 2000 is concentrated, the inner straight line fastening part 125 and the inner curved line fastening part 126 are formed to have a relatively narrow gap .

When the cylindrical portion 120 is assembled by the plurality of inner side plates 121A to 121D, the inner straight line flanges 123 are brought into contact with each other by the adjacent inner side plates. A plurality of inner straightening fasteners 125 formed in each of the inner straightening flanges 123 of the two inner side plates butted against each other when the adjacent inner side plates are in contact with each other are arranged so as to fit the bolts 410 therein. The height H1 of the inner linear flange 123 and the inner curved flange 124 that are bent outward in the inner side plates 121A to 121D may vary depending on the size of the cylindrical portion 120. [ For example, as the size of the cylindrical portion 120 increases, the concrete pressure generated when the concrete is poured increases. Therefore, the inner linear flange 123 and the inner curved flange 124 ) Can be increased in proportion to the concrete pressure. In one embodiment, the inner straight flange 123 and the inner curved flange 124 have the same height H1 with respect to the curved surface (outer surface) of the inner side plates 121A to 121D. In another embodiment, The height H1 of the straight portion flange 123 and the inner curve portion flange 124 may be different from each other. For example, if both ends of the reinforced concrete structure 2000 are designed to have a thickness greater than the side, the height of the inner curved flange 124 may be greater than the height of the inner straight flange 123.

7, the inner end plate 130 includes a circular plate portion 131 for closing the end of the cylindrical portion 120, and a rim portion 131 extending from the rim of the circular plate portion 131 in the radially outward direction (ROD) 132). In the inner end plate 130, an inner notch 133 is formed in the rim 132 for cutting an upper part of the rim for pouring concrete.

The inner end plate 130 is assembled to abut against the inner curved flange 124 of the plurality of inner side plates 121A to 121D assembled with the cylindrical portion 120 (see FIG. 4). The diameter of the inner end plate 130 is formed to be larger than the diameter of the end face of the cylindrical portion 120 composed of the plurality of inner side plates 121A to 121D. In the inner end plate 130, the disk 131 has a diameter D1 which is the same as the outer diameter D of the end portion of the cylindrical portion 120 (see Fig. 2). A plurality of first fasteners 134 corresponding to a plurality of inner curved portion fasteners 126 of the inner curved portion flange 124 are formed through the disc portion 131 along the edge. The plurality of first fasteners 134 are formed so that the inner end plate 130 is fixed to the end of the cylindrical portion 120 (the main body portion 110) by the engaging member 400, And is aligned with the fastener 126.

The outer mold 200 is assembled to the rim 132 of the inner end plate 130. The rim 140 is provided with a plurality of The second fastener 135 is formed to pass therethrough. That is, the inner end plate 130 is formed with a plurality of first fasteners 134 for coupling with the plurality of inner side plates 121A to 121D, and the plurality of outer side plates 210A to 210D and the outer end plates A plurality of second fasteners 135 for coupling with the plate 220 are formed so that the inner mold 100 and the outer mold 200 are coupled to each other by the coupling member 400.

A plurality of openings 136 are formed in the rim portion 132 along an edge (specifically, an edge between the first fastener 134 and the second fastener 135). The plurality of openings 136 are formed in the concrete placement space S1-1 formed at the side of the formwork assembly 1000 and the concrete placement space S1-2 formed at the end of the formwork assembly 1000, (See Figs. 11 and 12). A part of the concrete flows directly into the concrete installation space S1-1 and the remaining part of the concrete 10 flows into the inner notch portion S1-1, Through the opening 133 and the opening 136, into the concrete pouring space S1-2. The diameter D2 of the rim 132 may be increased or decreased in consideration of the size of the reinforced concrete structure 2000 and the thickness of the reinforced concrete wall 2100 and the like. That is, as the difference between the diameter D2 of the rim portion 132 and the diameter D1 of the disk portion 131 increases, the distance between the inner mold 100 and the outer mold 200 becomes larger, The thickness of the reinforced concrete wall body 2100 in the structure 2000 can be increased. The openings 136 may be formed to have different sizes depending on positions at the rim 132. For example, the opening 136 located below the rim 132 may be formed to be relatively larger than other portions so that the concrete 10 can be smoothly injected to the lower side of the formwork assembly 1000.

The form assembly 1000 'of another embodiment may have an extended structure than the formwork assembly 1000 of the embodiment according to the size, storage capacity, etc. of the reinforced concrete structure 2000. To this end, in another embodiment, the body 110 'comprises a plurality of cylindrical portions 120, as shown in FIGS. The form assembly 1000 'including the main body 110' has a plurality of protruding openings 122 spaced apart in the extending direction of the main body 110 '. When the main body 110 'includes a plurality of the cylindrical portions 120, the inner end plates 130 are interposed between the cylindrical portions 120. When the inner end plate 130 of the embodiment is interposed between the cylindrical portions 120, the inner mold 100 'has a space S2 for accommodating a plurality of stored products formed by each of the plurality of cylindrical portions 120 I have.

As shown in FIG. 10, a central portion of the inner end plate 130 'interposed between the cylindrical portions 120 is formed so that the accommodating spaces S2 of the stored product formed in the inner mold 100' That is, a through hole 131A may be formed in the disk 131. As shown in FIGS. 11 and 13, the mold assembly 1000 'to which the inner end plate 130' is applied is configured such that the storage space S2 of the storage formed in each of the cylindrical portions 120 is separated from the inner end plate Through holes 131A formed in the first and second electrodes 130 'and 130'.

The inner assembling members 121A to 121D and 130, that is, the inner side plates 121A to 121D and the inner end plates 130 and 130 'assembled with the inner molds 100 and 100' (water proofing), anticorrosion performance, durability, and the like. In one embodiment and in another embodiment, the inner assembling members 121A through 121D, 130 assembled with the inner molds 100, 100 'are formed of at least one of polyethylene, glass fiber reinforced plastic material. The inner molds 100 and 100 'are not limited to the material according to one embodiment, but may also be formed of a metal material such as an alloy or a composite material of metal and synthetic resin. The thickness of each of the inner assembling members 121A to 121D and 130 assembled into the inner molds 100 and 100 'may be determined in consideration of the size and storage capacity of the reinforced concrete structure 2000, It is preferable that the thickness is designed so as not to be easily broken at the time of construction and for a long period of use.

14 to 20, a reinforcing steel reinforcement 300 is installed on the inner molds 100 and 100 'before assembling the outer molds 200 and 200'. 14 and 15, the reinforcing steel reinforcement 300 includes a plurality of vertical stiffeners (reinforcing bars) arranged to fit the reinforcing bars so as to surround the inner molds 100 and 100 'in the circumferential direction (longitudinal direction) And a plurality of horizontal stiffeners 320 extending in the longitudinal direction (transverse direction) of the inner formwork 100 and arranged in a lattice form on the plurality of vertical stiffeners 310. [ The vertical stiffener 310 may be in contact with the inner straight flange 123 protruding from the side of the inner formwork 100 at the time of wiring while the wired vertical stiffener 310 is attached to the inner straight flange 123, (Refer to FIG. 17). [0053] As shown in FIG. Each of the plurality of recessed grooves 123A is fitted with a vertical stiffener 310 inserted therein. In one embodiment, the vertical stiffener 310 is not wired in a completely wound form to the body 110 of the inner formwork 100, but is wired in a top-down fashion, And can be completely wound on the main body 110.

The reinforcing steel reinforcement 300 further includes a wire 330 for fixing the vertical stiffener 310 and the horizontal stiffener 320, as shown in Figs. 16, 18 and 19. The wire 330 may be wound around the vertical stiffener 310 fitted to the concave groove 123A and fixed to the coupling member 400 as shown in FIG. In an embodiment, the vertical stiffener 310 is first placed on the inner mold 100 and then the horizontal stiffener 320 is placed on the outer side of the vertical stiffener 310. However, the present invention is not limited thereto. That is, after the horizontal stiffener 320 is first laid on the inner mold 100, the vertical stiffener 310 may be laid out from the outer side of the horizontal stiffener 320. Each of the plurality of vertical stiffeners 310 is laid and wound and fixed to the joining member 400 used for assembling the inner mold 100 as shown in Fig. Further, each of the plurality of horizontal stiffeners 320 is laid, and the vertical stiffeners 310 are wound and fixed by the wires 330 as shown in Fig. In one embodiment, wire 330 is wound only at a portion of the intersection of vertical stiffener 310 and horizontal stiffener 320, but in other embodiments vertical stiffener 310 and horizontal stiffener 320, So that the wire 330 can be wound.

The reinforcing steel reinforcement 300 further includes a plurality of spacers 340 as shown in Fig. The spacer 340 has a substantially ring shape and has a fitting hole 341 formed at the center thereof so as to be fitted to at least one of the vertical stiffener 310 and the horizontal stiffener 320, And a plurality of through holes 342 are formed so as to be firmly embedded in the through holes 342. The spacers 340 maintain the distance between the inner mold 100 and the outer mold 200, i.e., the concrete pouring space S1, constant. Further, the spacer 340 sets the position of the vertical stiffener 310 and the horizontal stiffener 320 in the concrete installation space S1. That is, the vertical stiffeners 310 and the horizontal stiffeners 320 are positioned at approximately the center of the concrete installation space S1 so that the vertical stiffeners 310 and the horizontal stiffeners 320 are stably embedded in the concrete. The spacer 340 may be formed of a material such as a vertical stiffener 310 and a horizontal stiffener 320.

Referring to FIG. 21, the outer mold 200 includes a plurality of outer side plates 210A to 210D and a pair of outer end plates 220. As shown in FIG. The outer formwork 200 is coupled with the reinforced concrete wall body 2100 formed by hardening the concrete 10 when the reinforced concrete structure 2000 is installed. A plurality of outer side plates 210A to 210D curved at a predetermined curvature are assembled between the inner end plates 130 so that an upper part of the main body 110 including the protruding openings 122 of the inner mold 100 is fixed to the outside The side of the main body 110 is wrapped. The plurality of outer side plates 210A to 210D form a concrete casting space S1 between the side portions of the main body portion 110. [

Each of the plurality of outer side plates 210A to 210D corresponds to the side plates 121B to 121D of the inner mold 100 and has two long sides and two short sides facing each other, . The outer side plates 210A to 210D include a pair of outer straight flanges 211 bent toward each other at an edge thereof (bent in a direction toward the outer side when assembled to the outer die 200) And a pair of outer curved flanges 212 connecting the straight flanges 211. The outer straight flanges 211 are formed on two long sides of the outer side plates 210A to 210D respectively and the outer curved flanges 212 are formed on the two short sides of the outer side plates 210A to 210D respectively. A plurality of outer straightening fasteners 213 through which the bolts 410 of the fastening member 400 are inserted are formed in the outer straightening flange 211 in order to engage with the plurality of outer side plates And a plurality of outer curved coupling members 214 through which the bolts 410 of the coupling member 400 are inserted are formed in the outer curved flange 212 along the extending direction thereof. 21 shows an outer linear fitting 213 formed on the outer linear flange 211 of the outer side plates 210A and 210B which do not abut against the other outer side plates of the plurality of outer side plates 210A to 210D But is not limited thereto. That is, the outer linear fittings 213 may be formed on the outer linear flanges 211 so that the outer side plates 210A to 210B having a symmetrical shape can be easily assembled.

When the plurality of outer side plates 210A to 210D are assembled in the left direction LSD and the right direction RSD of the inner molds 100 and 100 ', the outer rectilinear flanges 211 Assembled together. A plurality of outer straightening fasteners 213 formed on each of the outer straightening flanges 211 of the outer side plates are aligned to be able to fit the bolts 410 when the adjacent outer side plates are brought into contact with each other. When the plurality of outer side plates 210A to 210D are assembled to the inner molds 100 and 100 ', the outer curved portion flanges 212 of the outer side plates 210A to 210D are arranged at the rim of the inner end plate 130 (132). A plurality of outer curved coupling parts 214 formed on the outer curved flange 212 of the outer side plates 210A to 210D are formed in a plurality of second fastening parts 214 formed on the rim 132 of the inner end plate 130, The outer side plates 210A to 210D can be fixed to the inner end plate 130 through the engaging member 400 by being aligned with the sphere 135. [ That is, in one embodiment, the engaging member 400 has the inner end plate 130 between the outer side plates 210A to 210D and the outer end plate 220 to form the outer side plates 210A to 210D, 220 and the inner end plate 130 to each other.

In the outer side plates 210A to 210D, the outer linear flange 211 and the outer curved flange 212, which are bent outward with respect to the curved surface (outer surface) of the outer side plates 210A to 210D, H2 may vary depending on the size of the form assembly 1000. For example, the height H2 may increase in proportion to the size of the form assembly 1000. The outer straight flange 211 and the outer curved flange 212 may be formed at different heights. The height of the outer curved flange 212 may be greater than the height of the outer straight flange 211 when both ends of the reinforced concrete structure 2000 are designed to have a thicker thickness than the side portions.

The outer end plate 220 is assembled to the inner end plate 130 so as to surround the inner end plate 130 at a front side FD and a rear side RD of the inner molds 100 and 100 '. The outer end plate 220 of one embodiment has a curved surface portion 221 which is convex in the direction opposite to the direction toward the inner end plate 130 when assembled to the inner end plate 130, And a rim 222 extending radially outward. In this outer end plate 220, the rim 222 is provided with a plurality of second fasteners 135 of the inner end plate 130 (corresponding to a plurality of second fasteners 135 when assembled to the inner end plate 130) (Aligned with the first engaging hole 135), and a plurality of third fastening holes 223 are formed along the edges. An outer notch portion 224 corresponding to the inner notch portion 133 of the inner end plate 130 is formed on the rim portion of the rim portion 222 for pouring concrete. 22, when the outer mold 200 is assembled, the inner space of the concrete pouring space 133 formed at the opposite ends of the mold assemblies 1000 and 1000 'by the inner notch portion 133 and the outer notch portion 224, (S1-2) is opened and communicated with the open upper portion of the form assembly (1000). Although not shown in FIG. 22, a plurality of openings 136 formed in a rim portion 132 of the inner end plate 130 form a concrete pouring space S1- 1 and the concrete installation space S1-2 formed at the ends of the form assemblies 1000 and 1000 'are connected to allow the concrete 10 to flow. Therefore, even if the concrete 10 is poured into the upper part of the form assembly 1000, 1000 ', the concrete 10 passes through the inner notch 133 and the outer notch 224, (Specifically, S1-2) formed between the inner end plate 130 and the outer end plate 220 (see arrows in FIG. 20).

The form assemblies 1000 and 1000 'further include a support plate 500 (see FIG. 2) for stably maintaining the posture and reinforcing the buckling of the reinforced concrete structure 2000 during construction. The support plate 500 is assembled to the lower edge of the inner end plate 130. The support plate 500 has a plurality of support plate fasteners 510 corresponding to the second fasteners 135 of the inner end plate 130 and can be assembled by the engagement member 400. The thickness and size of the support plate 500 may vary depending on the size, weight, and the like of the supporting mold assembly 1000. The support plate 500 of one embodiment is formed of the same material as the inner assembly members 121A to 121D and 130, but is not limited thereto and may be formed of a material such as a metal.

The outer side plates 210A to 210D and the outer end plates 220 are assembled into the inner mold members 121A to 210D assembled into the outer molds 200, 121D, and 130, respectively. The thickness of each of the inner assembly members 121A to 121D and 130 assembled into the outer mold 200 may be determined in consideration of the size and storage capacity of the reinforced concrete structure 2000. [

A reinforced concrete structure 2000 to be constructed using the formwork assemblies 1000 and 1000 'of the above-described embodiments and a construction method thereof will be described with reference to FIGS. 23 to 28. FIG.

As shown in FIG. 23, the method of constructing a reinforced concrete structure according to an embodiment includes a step S110 of performing a digging operation, a step S120 of installing a form assembly 1000, a step S120 of piling up a concrete, (Step S130) of controlling the moisture until the concrete is completely hardened and protecting it from being damaged by impact or the like (step S140), and finishing step S140. Although not shown in FIG. 23, the preparation step may include a step prior to the step S110. In the preparing step, the inner assembly members 121A to 121D and 130 and the outer assembly members 210A to 210D and 220, which are assembled into the inner mold 100 and the outer mold 200 of the form assembly 1000, Transporting them from the manufacturing plant, storing them until the time of construction, and the like.

In the trenching step S110, a space S3 for buried land is formed from the ground 1 to a predetermined depth in accordance with the size of the reinforced concrete structure 2000 to be installed (refer to FIG. 24). The floor 2 in the buried space S3 is flattened. When the bottom 2 is difficult to be flattened, a subslab concrete can be laid and cured so that the bottom 2 can be thinned by flattening low-strength concrete.

When the tearing step S110 is completed, the formwork assembly 1000 is installed in the buried space S3 (S120) (see FIG. 25). The form assembly 1000 may be installed in a manner to be assembled in the buried space S3 or may be installed in such a manner that the buried space S3 is assembled around the buried space S3 and then put in the buried space S3. The mold assembly 1000 may be installed in such a manner that a part of the mold assembly 1000 is first assembled around the buried space S3 and then moved to the buried space S3 to be seated and the remaining part is assembled in the buried space S3 . Although not shown, the form assembly 1000 'of another embodiment can be equally installed. And a checking step of checking whether the inner assembling members 121A to 121D and 130 are damaged before assembling the inner assembling members 121A to 121D and 130 at the stage of installing the form assembly 1000. [

After the form assembly 1000 is installed, the buried space S3 is lifted up to a predetermined height by the gravel 3, etc., and the concrete 10 is placed on the form assembly 1000 to be cured (S130) ). The abnormality of the form assembly 1000 can be confirmed prior to the back-up. Further, when backfilling is performed, it is chopped every time the height becomes a certain height from the bottom 2, and ground settlement or the like can be prevented. An auxiliary device such as a vibrator or the like may be used so that the concrete 10 is smoothly injected into the concrete placement space S1 of the formwork assembly 1000 and the bubble layer is not generated in the concrete 10. [ have.

When the concrete 10 placed in the form assembly 1000 is cured, a finishing step is performed to further fill the buried space S3 so as to be flat with the ground (S140) (see FIG. 27) ). In the method of constructing a reinforced concrete structure according to an embodiment, the concrete is poured around the formwork assembly 1000 installed in the buried space S3, and the concrete 10 is installed. However, the present invention is not limited thereto. That is, since the mold assembly 1000 according to the embodiment has a structure in which the concrete 10 can be smoothly injected to the lower portion of the mold assembly 1000, the concrete 10 is installed in the mold assembly 1000 installed in the space S3. It is also possible to re-cure the periphery of the form assembly 1000 after curing.

The method of constructing a reinforced concrete structure according to an embodiment further includes a step S150 of placing and curing the slab concrete 4 on the upper side of the formwork assembly 1000 after the finishing step S140 or finishing step S140 (See Fig. 28). The slab concrete 4 protects the reinforced concrete structure 2000 by dispersing or blocking the load applied to the reinforced concrete structure 2000 when the upper side of the reinforced concrete structure 2000 is used as a parking lot.

In a reinforced concrete structure 2000 constructed through the method of constructing a reinforced concrete structure according to an embodiment of the present invention, a plurality of reinforced concrete structures (not shown) are formed on the inner side (inner periphery) and the outer side (outer periphery) of the cured reinforced concrete wall 2100 The inner mold 100 and the outer mold 200 each having the plate assembled therein are integrally formed. Therefore, in the case of the reinforced concrete structure 2000, it is possible to effectively prevent the leakage of the stored matter stored in the inner mold 100 and the outer mold 200 by the integrated mold 100 and the outer mold 200 without any separate waterproofing work.

In order to construct the reinforced concrete structure according to the above-described embodiment, the structure, size, material, and performance of the inner and outer molds 100 and 200 are not used, It is easy to change it to various reinforced concrete structures 2000.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings. It will be apparent to those skilled in the art that various substitutions, alterations, and changes may be made without departing from the scope of the present invention.

100, 100 ': inner formwork 110, 110'
120: Cylindrical portions 121A to 121D: Inner side plates
122: projecting opening 140: inner end plate
200, 200 ': outer moldings 210A to 210D: outer side plates
220: outer end plate 300: reinforcing steel reinforcement
310: vertical stiffener 320: horizontal stiffener
330: wire 340: spacer
400: coupling member 1000, 1000 ': form assembly
2000: Reinforced concrete structure S1: Concrete placement space
S2: accommodation space S3: buried space

Claims (13)

A dual structure form assembly comprising:
An inner die configured to form a storage space for the stored product,
An outer mold enclosing the inner mold and forming a concrete pouring space between the inner mold and the inner mold,
And an engaging member for engaging the inner mold and the outer mold together,
Form assembly. The method according to claim 1,
And a reinforcing steel reinforcement disposed in the concrete installation space.
Form assembly. The method according to claim 1,
Wherein the inner mold comprises a plate-like inner assembling member,
Wherein the outer mold is formed of a plate-
Form assembly. The method of claim 3,
Wherein the inner assembly member includes a plurality of inner side plates and a plurality of inner end plates,
Wherein the outer assembly member includes a plurality of outer side plates and a plurality of outer end plates,
Wherein a diameter of the inner end plate is formed to be larger than a diameter of a cross section of the cylindrical portion composed of the plurality of inner side plates,
Wherein the engaging member engages the outer side plate, the outer end plate, and the inner end plate with the inner end plate between the outer side plate and the outer end plate,
Form assembly. 5. The method of claim 4,
Wherein the inner side plate and the outer side plate have a curved shape,
And a plurality of inner side plates,
Form assembly. 6. The method of claim 5,
Wherein the inner end plate has a plurality of first fasteners for engaging with the plurality of inner side plates and a plurality of second fasteners for engaging the plurality of outer side plates and the outer end plate, The inner and outer molds are coupled to each other by a coupling member,
An inner notch for pouring concrete is formed on an upper edge of the inner end plate,
Form assembly. The method according to claim 6,
Each of the plurality of inner side plates has a pair of inner curved flanges and a pair of inner straight flanges at the edges,
Wherein the inner curved flange includes a plurality of inner curved fasteners corresponding to the plurality of first fasteners,
Wherein the inner linear flange includes a plurality of inner linear fasteners for coupling between the plurality of inner side plates,
Form assembly. 8. The method of claim 7,
A plurality of third fasteners corresponding to the plurality of second fasteners are formed on the outer end plate,
And an outer notch for pouring concrete is formed on an upper edge of the outer end plate. 9. The method of claim 8,
Each of the plurality of outer side plates has a pair of outer curved flanges and a pair of outer straight flanges at the edges,
A plurality of outer curved fasteners corresponding to the plurality of second fasteners are formed in the outer curved flange,
Wherein the outer linear flange is formed with a plurality of outer linear fasteners for coupling between the plurality of outer side plates.
Form assembly. 5. The method of claim 4,
And a support plate coupled to a lower edge of the inner end plate by the engagement member. 3. The method of claim 2,
The reinforcing steel reinforcement
A plurality of vertical stiffeners arranged longitudinally in the concrete installation space,
A plurality of horizontal stiffeners arranged in the lateral direction in the concrete installation space,
And a wire wound on at least one of the vertical stiffener and the horizontal stiffener to fix the position of the vertical stiffener and the horizontal stiffener. 12. The method of claim 11,
Wherein the reinforcing steel reinforcement further comprises a plurality of spacers interposed between at least one of the vertical stiffener and the horizontal stiffener to position the vertical stiffener and the horizontal stiffener in the concrete pouring space. The method of claim 3,
Wherein the inner and outer assembly members are formed from a synthetic resin material comprising at least one of polyethylene, glass fiber reinforced plastic.

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