KR102452514B1 - Insulation-equipped building-integrated formwork and manufacturing method therefor - Google Patents

Abstract

The present invention relates to a building-integrated formwork including a heat insulating material and a manufacturing method thereof, the formwork comprising: a glass fiber-enhanced member (110) including a glass fiber-reinforced plate (111) formed in a predetermined size, a plurality of reinforcing steel bar fixing parts (113) arranged on one surface of the glass fiber-reinforced plate (111), and embedded reinforcing steel bars (114) fixed to the reinforcing steel bar fixing parts (113); a fiber-reinforced cement cover (120) consisting of a main cover body (121) with the same size as the size of the glass fiber-reinforced plate (111); and a foamed heat insulating material (130) integrally formed between the glass fiber-enhanced member (110) and the fiber-reinforced cement cover (120). A formwork is installed integrally on a wall (W) of a building and a heat insulating material is filled into the formwork, so a heat insulating material does not need to be constructed separately, thereby greatly reducing the construction period of the building.

Description

Insulation-equipped building-integrated formwork and manufacturing method therefor

The present invention relates to a building-integrated formwork provided with a thermal insulation material and a method for manufacturing the same, and more particularly, the insulation material is integrally constructed in the formwork so that the wall (W) can be constructed together with the formwork without removing the formwork, as well as a pair It relates to a building-integrated formwork provided with an insulating material capable of integrally constructing a concrete wall (W) between the formwork and a method for manufacturing the same.

In general, the wall (W) of a building is one of the most important structures of a building, and occupies a large proportion in the overall structure of the building. As the outer or inner wall of a building is designed to insulate for the purpose of relieving global warming, protecting the environment, and saving energy, an insulating material is essential, and accordingly, many types of insulating materials and construction methods are used.

Insulation construction methods for buildings are mainly classified into internal insulation, external insulation, and both-side insulation, in which both interior and exterior are insulated at the same time.

The internal insulation method is a method of installing an insulation material inside a building, and while the construction is relatively easy, condensation may occur due to the thermal bridge phenomenon of the exterior wall and the insulation efficiency is low.

The external insulation method is a method of installing insulation on the exterior wall of a building, and it is easy to secure insulation performance as the thermal bridge phenomenon of the exterior wall is greatly reduced. This gets complicated.

In addition, the two-sided insulation method blocks the problem of reinforced concrete structures, that is, the thermal bridge phenomenon, and can secure excellent thermal insulation performance of the building, but the cost is very high for large-scale residential buildings.

As described above, the insulating materials used for the purpose of insulation of buildings are mainly classified into organic (foamed polybenzene, extruded polybenzene, urethane, etc.) and inorganic (foamed cement, aircrete, etc.), and each has advantages and disadvantages.

Due to the nature of the material, organic insulation is difficult to be firmly integrated with concrete. Under the current construction method, an intermediate member is used to attach it to the inner or outer wall of a building.

Due to the nature of high-rise buildings, there is a lot of separation of external wall insulation attachments, and for safety reasons, the internal insulation method is being constructed rather than the exterior insulation method, which has excellent insulation effect.

Organic insulation is vulnerable to fire, and even if it is a flame-retardant material, there is no significant difference in the results in case of fire.

In addition, in the case of inorganic insulation, there is a construction problem similar to that of organic insulation when it is attached to the wall (W) using a member acting as an intermediate, such as an organic insulation.

In addition, if a space is secured on the wall (W) and filled in by spraying fluid inorganic foam insulation (foamed cement, aircrete, etc.) between the space, it can be applied to specific low-rise buildings, but is not suitable for high-rise buildings. do.

The formwork is a temporary structure that supports the concrete that has not hardened. The formwork is a frame that maintains the shape and dimensions of the concrete, and should be maintained until the strength develops.

An important consideration for the formwork currently used is its repeatability.

The components of wooden formwork consist of formwork board, board, joist, yoke (reinforcement), and support. The joists prevent deformation of the formwork, the yoke prevents deformation of the formwork panel, and the support serves to support the load.

Euroform is a modular formwork developed in Europe and consists of specially coated plywood and steel frame. It is mainly used for walls and columns, and the construction precision is good.

In addition, aluminum foam is a lightweight form made of aluminum alloy, and it has good construction precision and excellent versatility. Damaged aluminum formwork can be recovered from the manufacturing plant and manufactured as a new product.

The essential condition for such a building formwork is to be able to precisely construct the structure, shape, and dimensions of the building, to secure sufficient strength, rigidity and stability, and to be able to bear the load caused by lateral pressure and construction during concrete pouring. .

In addition, it must conform to the conditions of the concrete construction and curing process, the connection between the formwork must be properly sealed to prevent the concrete from leaking, and there must be no significant change in strength, stiffness and stability even in a humid environment.

In addition, a common weakness of current organic and inorganic insulating materials is their low compressive strength, which limits their use.

For example, Patent Document 1 below discloses a 'form in which a slab and a wall are integrally formed'.

The formwork in which the slab and the wall are integral according to the following Patent Document 1 is a formwork, the two wall formwork facing each other and the slab formwork fitted to the upper or lower surface of the inner insulation of the two wall formwork, and the wall The formwork is formed in a lattice form on one side of an internal heat insulating material formed on the inner surface of the wall, an external heat insulating material formed on the outer surface of the wall, and a stud for reinforcing the inner and external heat insulating materials, and and a plurality of connection brackets for permanently connecting and fixing the inner and outer heat insulating materials to the inner and outer heat insulators so as to maintain a constant distance therebetween.

The following Patent Document 2 discloses a 'finishing panel for wall formwork'.

The finishing panel for wall formwork according to the following Patent Document 2 is installed facing each other to form a pair of wall panels for concrete pouring of the wall, and blocking the end of the wall panel to form an end surface of the wall In the closing panel, A plate having a flat front surface in contact with the concrete to be poured, having a length and a width corresponding to the height and thickness of the end face of the wall to be poured, and having a pair of reinforcing ribs formed on the rear surface elongated in the longitudinal direction; a plurality of fixing nuts having a vertical screw hole with respect to the reinforcing rib and coupled to the pair of reinforcing ribs at regular intervals along the longitudinal direction of the reinforcing rib, and the distal end is inserted into each of the fixing nuts by screwing. A fastening bolt having a fastening nut that is closely fixed to the back side of the plate and whose position is adjusted along a thread formed on the bolt body, and a fastening hole for fastening with the fastening pin holes of the left and right wall panels by the fastening pins are provided at both ends, respectively. .

A fastening bar having a pair of through-holes through which the fastening bolts pass, respectively, and a pair of adjusting joists each having a protrusion which is formed long in the longitudinal direction of the plate and is fitted between the fastening bar and the reinforcing rib. .

Each of the pair of adjustment joists has two or more protrusions having different widths, but the two adjacent protrusions form a right angle to each other, and any one protrusion selected from the two or more protrusions is disposed parallel to the center line of the fastening bolt Both ends of the protruding part are firmly coupled by being inserted between the fastening bar and the reinforcing rib by the tightening action of the clamping nut.

Korean Patent Publication No. 10-2020-0028773 Republic of Korea Patent Registration No. 10-2084199 Republic of Korea Utility Model Registration No. 20-0397318

It is an object of the present invention to solve the above problems, by integrating the insulation material between the fiber (glass fiber, basalt fiber and other fibers) reinforced cement cover made of a cement-friendly material with sufficient strength and a fiber-reinforced plate to be integrated into the wall. An object of the present invention is to provide a building-integrated formwork equipped with an insulating material constructed with a

Another object of the present invention is to provide a building-integrated formwork provided with an insulating material that prevents combustion in the event of a fire by an insulating material made of an inorganic material and a method for manufacturing the same.

Another object of the present invention is to provide a building-integrated formwork provided with an insulating material that does not require dismantling of the formwork as it is integrally constructed on the wall of the building, and a method for manufacturing the same.

In order to achieve the above object, the building-integrated formwork provided with the insulation material according to the present invention is a glass fiber reinforced plate 111 that is formed to a predetermined size, and a plurality of glass fiber reinforced plates 111 are disposed on one surface. a glass fiber reinforcement member 110 provided with an embedded reinforcing bar 114 fixed to the reinforcing bar fixture 113 and the reinforcing bar fixture 113; Fiber reinforced cement cover 120 made of a cover body 121 of the same size as the glass fiber reinforced plate 111; It characterized in that it comprises a;

The glass fiber reinforcement member 110 includes a glass fiber reinforcement plate 111 formed in a predetermined size; a plurality of reinforcing ribs 112 formed at regular intervals on one surface of the glass fiber reinforced plate 111; Reinforcing bar fixtures 113 disposed to be spaced apart at regular intervals on one surface of the glass fiber reinforced plate 111; Embedded reinforcing bars 114 fixed to the reinforcing bar fixture 113; Bracket inserts 115 formed to be spaced apart from each other at regular intervals on both sides of the glass fiber reinforced plate 111; and an insertion groove 116 formed inside the bracket insertion hole 115 .

The foam insulation 130 is characterized in that it is made of any one or more inorganic foaming material of rock wool, perlite, foamed cement, glass fiber, and air crete.

It characterized in that it further comprises; load transmission member 150 installed at regular intervals on the side of the glass fiber reinforcement member 110 so that the load applied from the wall (W) can be distributed and transmitted.

The load transmission member 150 includes a load transmission body 152 having a predetermined length, and a load transmission plate formed so that the load applied to the load transmission body 152 is distributed and transmitted to the glass fiber reinforcement member 110 . 153 and a load transmission unit having a pair of inner coupling blades 154 formed on both sides of the load transmission body 152 so that the first housing unit 156 and the second housing unit 159 can be coupled to each other. (151); a first housing unit 156 slidably coupled to the inner coupling wing 154; a second housing unit 159 slidably coupled to the inner coupling blade 154; and a tension bolt (162) fastened to the first housing unit (156) and the second housing unit (159).

The distance between the glass fiber reinforcement member 110 and the fiber-reinforced cement cover 120 is to adjust the distance between the foamed insulating material 130 and the building-integrated formwork provided with a pair of insulating materials filled with the fiber-reinforced cement cover 120 and the manufacturing method 100 thereof It characterized in that it further comprises; the form tie rod member 170 to be able to.

The form tie rod member 170 includes a housing body 174 having a predetermined length, and a load transmission plate formed so that the load applied to the housing body 174 is distributed and transmitted to the glass fiber reinforcement member 110 ( 175) and a load transmission unit having a pair of central coupling blades 176 and 177 formed on the housing body 174 so that the first housing unit 181 and the second housing unit 191 are slidably coupled ( 171, 172); a first housing unit 181 slidably coupled to the first central coupling wing 176; a second housing unit 191 slidably coupled to the second central coupling blade 177; a length adjustment bolt 195 fastened to the first housing unit 181 and the second housing unit 191; and a tie rod member (200) installed between the pair of first housing units (181).

The tie rod member 200 includes a tie rod body 202 having a predetermined length, a first head 203 formed at one end of the tie rod body 202 , and the tie rod body 202 . a first tie rod 201 comprising a second head 204 formed at the other end; A tie rod body 202 formed to a predetermined length, a first head 203 formed at one end of the tie rod body 202 , and a fastening part 206 formed at the other end of the tie rod body 202 . ) and a second tie rod 205 having a thread 207 formed on the inner surface of the fastening portion 206; It is characterized by having any one of them.

In the method of manufacturing a building-integrated formwork provided with a heat insulator according to the present invention, the reinforcing bar fixture 113 is integrally formed so that the embedded reinforcing bar 114 can be inserted and fixed on one surface of the glass fiber reinforced plate 111 having a predetermined thickness. , forming a glass fiber reinforcement member 110 in which a plurality of bracket insertion holes 115 are formed at regular intervals on both sides of the glass fiber reinforced plate 111, respectively; forming a fiber-reinforced cement cover 120 formed to correspond to the glass fiber reinforced plate 111; Filling the foam material between the glass fiber reinforced member 110 and the fiber reinforced cement cover 120 in a state in which the glass fiber reinforced member 110 and the fiber reinforced cement cover 120 are coupled; includes; characterized in that

As described above, according to the building-integrated formwork provided with the insulation material and the manufacturing method thereof according to the present invention, the formwork is integrally installed on the wall (W) of the building, and the insulation material is filled in the formwork, so there is no need to separately construct the insulation material Accordingly, the effect that the construction period according to the construction of the building can be greatly shortened is obtained.

According to the building-integrated formwork provided with the insulation material and the manufacturing method thereof according to the present invention, a glass fiber reinforcement member and a fiber-reinforced cement cover are installed on the outside of the insulation material to protect the foam insulation material from the load applied to the foam insulation material from the building (wall). The effect of being able to increase the strength of the foamed insulation material with low tensile and compressive strength by the high-strength glass fiber reinforcement member and the fiber-reinforced cement cover, and to prevent separation of the foam insulation material is obtained.

According to the integrated building formwork provided with the insulation material and the manufacturing method thereof according to the present invention, it is possible to protect the foamed insulation material from external shocks and various loads from the initial assembly stage of the formwork to the installation of the formwork and the concrete pouring construction, and the embedded reinforcing bar is As it is embedded in concrete, it can be completely integrated with the building, and the foam insulation material is made of inorganic material, so it has excellent weather resistance. Hyogo, which not only shortens the construction period but also greatly improves the efficiency of building construction, is obtained.

1 is an exploded three-dimensional view showing a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
Figure 2 is a three-dimensional view showing a glass fiber reinforcement member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
3 is a cross-sectional view showing a glass fiber reinforcement member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
4 is a three-dimensional view showing a building-integrated formwork provided with a thermal insulation material according to a preferred embodiment of the present invention;
5 is a three-dimensional view showing a state in which a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention is installed adjacently;
6 is a cross-sectional view showing a state in which a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention is constructed;
7 is a process diagram showing a method for manufacturing a building-integrated formwork according to a preferred embodiment of the present invention;
8 is a three-dimensional view showing a load transfer member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
9 is an exploded cross-sectional three-dimensional view showing a load transfer member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
10 is a cross-sectional view showing a load transfer member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
11 is a cross-sectional view showing a state in which a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention is installed;
12 is a three-dimensional view showing a state in which a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention is installed;
13 is a three-dimensional view showing a form tie rod member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
14 is an exploded three-dimensional view showing a form tie rod member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
15 is a cross-sectional view showing a form tie rod member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
16 is an exploded three-dimensional view showing a form tie rod member of a building-integrated formwork provided with an insulating material according to another preferred embodiment of the present invention;
17 is an exploded three-dimensional view showing a state in which a wall and a slab are constructed by a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention;
18 is a three-dimensional view illustrating a state in which a wall and a slab are constructed by an integrated formwork of a building equipped with an insulating material according to a preferred embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily implement them.

However, since the description of the present invention is merely an embodiment for structural or functional description, the scope of the present invention should not be construed as being limited by the embodiment described in the text.

For example, it should be understood that the scope of the present invention includes equivalents capable of realizing the technical idea because the embodiments are capable of various modifications and may have various forms.

In addition, the scope of the present invention should not be construed as being limited thereby because the object or effect presented in the present invention does not mean that a specific embodiment should include all of them or only such effects.

In the present specification, the present embodiment is provided to complete the disclosure of the present invention, and to completely inform those of ordinary skill in the art to which the present invention pertains to the scope of the invention. And the invention is only defined by the scope of the claims.

Accordingly, in some embodiments, well-known components, well-known operations, and well-known techniques have not been specifically described to avoid obscuring the present invention.

Meanwhile, the meaning of the terms described in the present invention is not limited to the dictionary meaning, and should be understood as follows.

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

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

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined.

Terms defined in a commonly used dictionary should be interpreted as having the meaning consistent with the context of the related art, and cannot be interpreted as having an ideal or excessively formal meaning unless explicitly defined in the present invention.

Hereinafter, a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

A building-integrated formwork provided with a heat insulator according to a preferred embodiment of the present invention includes a glass fiber reinforced plate 111 that is formed to a predetermined size, and a reinforcing bar fixture 113 disposed on one surface of the glass fiber reinforced plate 111 in plurality. and a fiber-reinforced cement cover comprising a glass fiber reinforced member 110 having an embedded reinforcing bar 114 fixed to the reinforcing bar fixture 113 and a cover body 121 having the same size as the glass fiber reinforced plate 111 . and 120 and a foamed insulation 130 integrally molded between the glass fiber reinforced member 110 and the glass fiber reinforced cement cover 120 .

1 is an exploded three-dimensional view showing a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention, and FIG. 2 is a glass fiber reinforcement member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention 3 is a cross-sectional view showing a glass fiber reinforcement member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention.

4 is a three-dimensional view showing a building-integrated formwork provided with a heat insulator according to a preferred embodiment of the present invention, and FIG. 5 is a state in which a building-integrated formwork provided with an insulator according to a preferred embodiment of the present invention is installed adjacently. It is a three-dimensional view, and FIG. 6 is a cross-sectional view showing a state in which a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention is constructed.

As shown in FIGS. 1 to 6 , the building-integrated formwork provided with an insulating material according to an embodiment of the present invention includes a glass fiber reinforcement member 110 formed to a predetermined size, and the glass fiber reinforcement member 110 . It consists of a fiber-reinforced cement cover 120 installed on one surface, and a foamed insulation 130 filled between the glass fiber reinforced member 110 and the fiber-reinforced cement cover 120 .

The glass fiber-reinforced member 110 and the fiber-reinforced cement cover 120 are made of a material including fiber-reinforced cement or calcium silicate, which is a material friendly to concrete, to ensure sufficient strength even in a state of being constructed in a building.

This is to protect the foamed insulation 130 from an external shock or load applied to the foamed insulation 130 constructed between the glass fiber reinforced member 110 and the fiber reinforced cement cover 120 .

That is, since the foam insulation 130 is made of an inorganic material, the glass fiber reinforced member 110 and the fiber reinforced cement cover 120 are integrally formed so as to stably maintain its shape so as not to be damaged from rigidity and impact.

The foamed insulation 130 is made of highly foamed cement or a similar inorganic insulation material, and the foamed cement has low strength and brittleness after curing and drying. Fiber cement (Glass fiber reinforced cement (GRC), basalt fiber reinforced cement and other fiber reinforced cements) produced by a method such as the compression method or flow slurry method is used to 110) and a fiber-reinforced cement cover 120 are formed.

As such, the glass fiber reinforced member 110 and the fiber reinforced cement cover 120 have rigidity to withstand loads, lateral pressures, and various external loads generated after concrete is poured, and are used as permanent exterior or interior materials of buildings.

The glass fiber reinforcing member 110 includes a glass fiber reinforced plate 111 having a predetermined size, a plurality of reinforcing ribs 112 formed at regular intervals on one surface of the glass fiber reinforced plate 111, and the glass fiber A reinforcing bar fixture 113 disposed on one surface of the reinforcing plate 111 to be spaced apart at regular intervals, an embedded reinforcing bar 114 fixed to the reinforcing bar fixture 113, and the glass fiber reinforced plate 111 at regular intervals on both sides and a bracket insertion hole 115 formed to be spaced apart from each other, and an insertion groove 116 formed inside the bracket insertion hole 115 .

The glass fiber reinforced plate 111 is formed in the size of a normal formwork, and reinforcing ribs 112 for reinforcing rigidity are disposed on the glass fiber reinforced plate 111 to be spaced apart from each other at regular intervals.

The reinforcing ribs 112 are formed in a grid shape on one surface of the glass fiber reinforced plate 111 to increase the rigidity of the glass fiber reinforced plate 111 .

In addition, the reinforcing bar fixtures 113 to which the embedded reinforcing bars 114 embedded in the wall W are fixed are formed on the glass fiber reinforced plate 111, and a plurality of these rebar fixtures 113 are spaced apart from each other at regular intervals.

An embedded reinforcing bar 114 having a predetermined length is fixed to the reinforcing bar fixture 113 , and the reinforcing bar head 114a is integrally formed with the embedded reinforcing bar 114 not to be separated from the glass fiber reinforced plate 111 .

Bracket insertion holes 115 are formed on both sides of the glass fiber reinforced plate 111, respectively, and the load transmission member 150 or the form tie rod member 170 may be installed in the bracket insertion hole 115 in a buried state. An insertion groove 116 is formed.

The cover body 121 of the fiber-reinforced cement cover 120 is formed in the same size as the glass fiber reinforced plate 111, and the cover body 121 has a reinforcing bar through hole 122 through which the embedded reinforcing bar 114 is penetrated. The insertion groove portion 123 corresponding to the insertion groove portion 116 is also formed on both sides of the cover body 121 .

The glass fiber reinforced member 110 and the fiber reinforced cement cover 120 are filled with a foamed insulating material 130 .

The foam insulation 130 is made of any one inorganic foaming material of rock wool, perlite, foamed cement, glass fiber, and air crete, and of course, it may be made by mixing one or more of these inorganic foaming materials.

Next, a method of manufacturing a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention will be described with reference to FIG. 7 .

7 is a process diagram illustrating a method of manufacturing a building-integrated formwork according to a preferred embodiment of the present invention.

7 shows the manufacturing process of the building-integrated formwork, as shown in FIG. 7, the building-integrated formwork provided with the insulating material of the present invention is embedded in one surface of the glass fiber reinforced plate 111 having a predetermined thickness ( A glass fiber reinforcement member 110 in which a reinforcing bar fixture 113 is integrally formed so that the 114 can be inserted and fixed, and a plurality of bracket insertion holes 115 are formed at regular intervals on both sides of the glass fiber reinforced plate 111, respectively. ) forming step (S10), forming the fiber-reinforced cement cover 120 formed to correspond to the glass fiber reinforced plate 111 (S20), and the glass fiber reinforcement member 110 and the fiber reinforcement and filling the foam material between the glass fiber reinforced member 110 and the fiber reinforced cement cover 120 in a state in which the cement cover 120 is coupled (S30).

The glass fiber reinforced member 110 and the fiber reinforced cement cover 120 are molded using glass fiber reinforced cement (GRC), basalt fiber reinforced cement and other fiber reinforced cements.

At this time, of course, the reinforcing bar fixture 113 can be formed in a state in which the embedded reinforcing bar 114 is inserted.

In addition, the fiber-reinforced cement cover 120 is also molded using the same material, etc., and these glass fiber-reinforced members 110 and the fiber-reinforced cement cover 120 are brought into close contact with a jig (or a mold, not shown).

At this time, each side of the empty space is closed by a jig (not shown) by the cloth fixture 113 and the bracket inserting part 115, and through an injection hole (not shown) so that the foam insulation 130 can be filled. The foam insulation 130 is filled.

After the foam insulation 130 is filled in this way, the building-integrated formwork 100 is molded through the process of curing the building-integrated formwork 100 as shown in FIG. 4 .

On the other hand, the bracket insertion hole 115 has a load transfer member 150, so that it can be combined with another adjacent formwork, as well as to distribute the load applied from the building, that is, the wall (W, see Fig. 6) after the formwork is integrated with the building. 8) may be purchased together, of course.

8 is a three-dimensional view illustrating a load transmission member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention, and FIG. It is an exploded cross-sectional three-dimensional view showing the member, and FIG. 10 is a cross-sectional view showing the load transmitting member of the building-integrated formwork provided with the heat insulating material according to the preferred embodiment of the present invention.

As shown in Figures 8 to 10, the building-integrated formwork 100 according to the embodiment of the present invention is provided with a load transmission member 150 so that the load applied from the building or wall (W) can be distributed.

It further includes a load transmission member 150 installed on the side of the glass fiber reinforcement member 110 at regular intervals so that the load applied from the wall (W) can be distributed and transmitted.

The load transmission member 150 includes a load transmission body 152 having a predetermined length, and a load transmission plate formed so that the load applied to the load transmission body 152 is distributed and transmitted to the glass fiber reinforcement member 110 . 153 and a load transmission unit having a pair of inner coupling blades 154 formed on both sides of the load transmission body 152 so that the first housing unit 156 and the second housing unit 159 can be coupled to each other. (151), a first housing unit 156 slidably coupled to the inner coupling blade 154, a second housing unit 159 slidably coupled to the inner coupling blade 154, and the It consists of a tension bolt 162 fastened to the first housing unit 156 and the second housing unit 159 .

The load transmission member 150 is installed in the insertion groove portion 116 of the glass fiber reinforcement member 110, and the load transmission member 150 includes a load transmission unit 151 installed in the insertion groove portion 116, A first housing unit 156 and a second housing unit 159 that are slidably coupled to the load transmission unit 151 are provided.

The load transmission body 152 of the load transmission unit 150 is formed in a 'C' shape, and the load transmission body 152 includes a first load transmission body 152a and a second load transmission body 152a having a predetermined length. It may be formed of a body 152b.

Of course, in the load transmission body 152, the first load transmission body 152a and the second load transmission body 152b may be integrally formed.

A pair of load transfer plates 153 are formed on one surface of the load transfer body 152 , that is, embedded in the inside of the foam insulation 130 , and a first housing unit 156 on the inside of the load transfer body 152 . ) and the second housing unit 159 are coupled to the inner coupling wing 154 is formed.

9 and 10, the inner coupling blade 154 is spaced apart from the load transmission body 152 by a predetermined height and inclinedly formed, and the housing units 156 and 159 by the inner coupling blade 154. The coupling groove portion 155 to be coupled is formed.

The first housing unit 156 and the second housing unit 159 are identically formed, and will be described with different reference numerals.

The first housing body 157 of the first housing unit 156 is formed in a 'C' shape in cross section, and a first fastening part 158 is formed in the center of the first housing body 157 .

The second housing body 160 of the second housing unit 159 is formed in a 'C' shape in cross section, and the second fastening part 161 is integrally formed at the center of the second housing body 160 .

In addition, a tension bolt 162 fastened to the first housing unit 156 and the second housing unit 159 is provided, and a bolt head 162 is formed on one side of the tension bolt 162, and the tension bolt 162 is formed. A hexagonal coupling portion 164 is integrally formed on the other side of the bolt 162 .

The tension bolt 162 is fastened to the first coupling part 158 and the second coupling part 161, and as the tension bolt 162 is rotated, the first housing unit 156 and the second housing unit (159) is moved to the coupling groove 155 of the inner coupling wing 154 is coupled to the coupling groove (155).

That is, the tension bolt 162 is formed in the form of a stud bolt, and the first housing unit 156 and the second housing unit 159 are coupled to or separated from the coupling groove portion 155 by the tension bolt 162 .

As such the load transmission member 150 is coupled to the insertion groove 116, the load applied from the wall W or the building is transmitted to the load transmission plate 153, and is transmitted to the load transmission plate 153. The load is transmitted by dispersing it to the foam insulation 130 .

The load transfer member 150 shown in FIGS. 8 to 10 is not only embedded in the wall W as shown in FIG. 6 but also can stably couple other adjacent forms 100 to each other, and from the wall W By dispersing the applied load, the rigidity of the formwork 100 is increased.

11 is a cross-sectional view illustrating a state in which a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention is installed, and FIG. It is a three-dimensional view, and FIG. 13 is a three-dimensional view showing a form tie rod member of a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention.

14 is an exploded three-dimensional view showing a form tie rod member of a building-integrated formwork provided with a thermal insulation material according to a preferred embodiment of the present invention, and FIG. It is a cross-sectional view showing a form tie rod member.

11 and 12 show the construction of a concrete wall (W) between a pair of formwork (100), the building-integrated formwork (100) is installed on both sides of the concrete wall (W), respectively.

On the other hand, as shown in FIGS. 11 to 15 , a form tie rod member 170 for adjusting the spacing of the formwork 100 according to the thickness of the concrete wall W is installed between the pair of formwork 100 .

11 to 15, in the building-integrated formwork 100 according to an embodiment of the present invention, the foamed insulation 130 is provided between the glass fiber reinforced member 110 and the fiber reinforced cement cover 120. A form tie rod member 170 is further provided to adjust the separation distance of the building-integrated formwork 100 provided with a pair of filled insulators.

The form tie rod member 170 includes a housing body 174 having a predetermined length, and a load transmission plate formed so that the load applied to the housing body 174 is distributed and transmitted to the glass fiber reinforcement member 110 ( 175) and a load transmission unit having a pair of central coupling blades 176 and 177 formed on the housing body 174 so that the first housing unit 181 and the second housing unit 191 are slidably coupled ( 171 and 172), a first housing unit 181 slidably coupled to the first central coupling blade 176, and a second housing unit slidably coupled to the second central coupling blade 177 ( 191), a length adjustment bolt 195 fastened to the first housing unit 181 and the second housing unit 191, and a tie rod member installed between the pair of first housing units 181 (200) is provided.

The load transfer units 171 and 172 of the form tie rod member 170 are the first load transfer unit 171 installed in the first formwork 100a (see FIG. 11) and the second formwork 100b installed in the first load transfer unit 171 and the second formwork 100b. Two load transfer units 172 are provided, respectively.

Since the first load transfer unit 171 and the second load transfer unit 172 are the same, they will be described as one load transfer unit 173 using the same reference numerals.

The housing body 174 of the load transmission unit 173 is formed in a 'C' shape in cross section, and a load transmission plate 175 is formed on one surface of the housing body 174 to the outside.

In addition, the first central coupling blade 176 and the second central coupling blade 177 are symmetrical to each other so that the first housing unit 171 and the second housing unit 191 can be coupled to the inside of the housing body 174 . is formed

A coupling groove 178 to which the first housing unit 181 and the second housing unit 191 are coupled is formed by the first central coupling blade 176 and the second central coupling blade 177 .

The first housing body 182 of the first housing unit 181 is formed in a 'C' shape in cross section, and a length adjustment bolt 195 is first fastened to the center of the first housing body 182 . A portion 183 is formed.

In addition, an extension coupling part 185 is integrally formed on one side of the first housing body 182 to couple the tie rod member 200 , and the tie rod member 200 is integrally formed on the extended coupling part 185 . A fitting groove 186 is formed so that it can be inserted.

In addition, a second fastening part 193 is formed in the center of the second housing body 192 of the second housing body 191, and the second housing body 192 and the second coupling part 192 are second fastened to the second housing body 192. A fitting groove portion 194 is formed between the portions 193 to be fitted to the central coupling blades 176 and 177 .

A length adjustment bolt 195 is fastened to the second housing unit 191 so as to adjust the distance from the first housing unit 181 .

A bolt head 196 is formed on one side of the length adjustment bolt 195 , and a first fixing groove 197 is formed in the bolt head 196 to be buried by concrete, and the bolt head 196 is formed. One side of the bolt 198 fastened to the first housing unit 181 is integrally extended.

In addition, a second fixing groove 199 is formed in the bolt 198 to be firmly embedded by pouring concrete.

The tie rod member 200 includes a first tie rod 201 and a second tie rod 205 .

The tie rod member 200 includes a tie rod body 202 having a predetermined length, a first head 203 formed at one end of the tie rod body 202 , and the tie rod body 202 . A first tie rod 201 comprising a second head 204 formed at the other end, a tie rod body 202 formed to a predetermined length, and a first head formed at one end of the tie rod body 202 . 203, a fastening part 206 formed at the other end of the tie rod body 202, and a second tie rod 205 having a thread 207 formed on the inner surface of the fastening part 206; do.

13 to 15 , the first tie rod 201 includes a tie rod body 202 having a predetermined length, and a first head formed at both ends of the tie rod body 202 , respectively. 203 and a second head 204 .

The first head 202 may be coupled to the form tie rod member 170 of the first formwork 100a, and the second head 203 is connected to the form tie rod member 170 of the second formwork 100b. can be combined.

The length adjustment of the form tie rod member 170 may be adjusted by the length adjustment bolt 195 fastened to the load transmission unit 173 . That is, by adjusting the gap between the first housing unit 181 and the second housing unit 191 fastened to the length adjustment bolt 195 of the form tie rod member 170, the first tie rod member 201 is adjusted. It is possible to adjust the thickness of the concrete wall (W).

16 is an exploded three-dimensional view showing a form tie rod member of a building-integrated formwork provided with an insulating material according to another preferred embodiment of the present invention.

FIG. 16 shows the second tie rod 205 of the form tie rod member 200, wherein the second tie rod 205 has the same reference numerals for the same names as those of the first tie rod 201 described above. will be used to explain.

The tie rod body 202 of the second tie rod 205 is formed to have a predetermined length, a first head 203 is formed on one side of the tie rod 202 , and the other side of the tie rod 202 is formed on one side of the tie rod 202 . A fastening portion 206 is integrally formed on the side.

A screw thread 207 is formed inside the fastening part 206 so that the tension bolt 162 of the load transmission member 150 can be fastened.

That is, the tension bolt 162 coupled to the first housing unit 156 and the second housing unit 159 of the load transmission member 150 is fastened to the fastening portion 206 of the second tie rod 205 . to be able to adjust the length.

17 is an exploded three-dimensional view showing a state in which a wall and a slab are constructed by a building-integrated formwork provided with an insulating material according to a preferred embodiment of the present invention, and FIG. It is a three-dimensional view showing the state in which the wall and slab are constructed by the integrated formwork of the building.

17 and 18 show a state in which a wall (W) and a slab (the floor surface between floors of a building) are constructed using the building-integrated formwork 100 of the present invention, and the vertical wall (W) constructed as a vertical wall (W) A fixing angle 208 is provided so that the formwork 100c and the horizontal formwork 100d constructed on a horizontal floor can be installed more firmly.

Although the invention made by the present inventors has been described in detail according to the above embodiments, the present invention is not limited to the above embodiments and various modifications can be made without departing from the gist of the present invention.

110: glass fiber reinforced member 111: glass fiber reinforced plate
112: reinforcing rib 113: reinforcing bar fixture
114: embedded reinforcing bar 114a: reinforcing bar head
115: bracket insertion hole 116: insertion groove
120: fiber reinforced cement cover 121: cover body
122: reinforcing bar through hole 123: insertion groove
130: foam insulation
150: load transfer member 151: load transfer unit
152: load transmission body 152a: first load transmission body
152b: second load transfer body 153: load transfer plate
154: inner coupling wing 155: coupling groove portion
156: first housing unit 157: first housing body
158: first fastening part 159: second housing unit
160: second housing body 161: second fastening part
162: tension bolt 163: bolt head
164: hexagonal coupling part
170: form tie rod member 171: first load transfer unit
172: second load transfer unit 173: load transfer unit
174: housing body 175: load transfer plate
176: first central coupling wing 177: second central coupling wing
178: coupling groove
181: first housing unit 182: first housing body
183: first fastening portion 184: insertion groove portion
185: extended coupling portion 186: fitting groove portion
191: second housing unit 192: second housing body
193: second fastening portion 194: fitting groove portion
195: length adjustment bolt 196: bolt head
197: first fixing groove 198: bolt
199: second fixing groove
200: tie rod member 201: first tie rod
202: tie rod body 203: first head
204: second head 205: second tie rod
206: fastening portion 207: thread
208: fixed angle

Claims (9)

A glass fiber reinforced plate 111 that is formed to a predetermined size, a reinforcing bar fixture 113 disposed in a plurality on one surface of the glass fiber reinforced plate 111, and an embedded reinforcing bar 114 fixed to the reinforcing bar fixture 113 The provided glass fiber reinforcement member 110;
Fiber reinforced cement cover 120 made of a cover body 121 of the same size as the glass fiber reinforced plate 111;
Including;;
The glass fiber reinforcement member 110,
Glass fiber reinforced plate 111 formed in a predetermined size;
a plurality of reinforcing ribs 112 formed at regular intervals on one surface of the glass fiber reinforced plate 111;
Reinforcing bar fixtures 113 disposed to be spaced apart at regular intervals on one surface of the glass fiber reinforced plate 111;
Embedded reinforcing bars 114 fixed to the reinforcing bar fixture 113;
Bracket inserts 115 formed to be spaced apart from each other at regular intervals on both sides of the glass fiber reinforced plate 111;
A building-integrated formwork provided with a heat insulator, characterized in that it comprises;
delete According to claim 1,
The foam insulation 130 is a building-integrated formwork provided with an insulation material, characterized in that it is made of any one inorganic foam material of rock wool, perlite, foamed cement, glass fiber, and air crete.
A glass fiber reinforced plate 111 that is formed to a predetermined size, a reinforcing bar fixture 113 disposed in a plurality on one surface of the glass fiber reinforced plate 111, and an embedded reinforcing bar 114 fixed to the reinforcing bar fixture 113 The provided glass fiber reinforcement member 110;
Fiber reinforced cement cover 120 made of a cover body 121 of the same size as the glass fiber reinforced plate 111;
Foamed insulation 130 integrally molded between the glass fiber reinforced member 110 and the fiber reinforced cement cover 120;
and a load transmission member 150 installed at regular intervals on the side surface of the glass fiber reinforcement member 110 so that the load applied from the wall W can be distributed and transmitted.
The load transfer member 150,
A load transmission body 152 formed in a predetermined length, a load transmission plate 153 formed so that the load applied to the load transmission body 152 is distributed and transmitted to the glass fiber reinforcement member 110, and the load transmission a load transmission unit 151 having a pair of inner coupling blades 154 formed on both sides of the main body 152 so that the first housing unit 156 and the second housing unit 159 can be coupled;
a first housing unit 156 slidably coupled to the inner coupling wing 154;
a second housing unit 159 slidably coupled to the inner coupling blade 154;
The first housing unit (156) and the tension bolt (162) fastened to the second housing unit (159); a building-integrated formwork provided with a heat insulator, characterized in that it comprises a.
delete A glass fiber reinforced plate 111 that is formed to a predetermined size, a reinforcing bar fixture 113 disposed in a plurality on one surface of the glass fiber reinforced plate 111, and an embedded reinforcing bar 114 fixed to the reinforcing bar fixture 113 The provided glass fiber reinforcement member 110;
Fiber reinforced cement cover 120 made of a cover body 121 of the same size as the glass fiber reinforced plate 111;
Foamed insulation 130 integrally molded between the glass fiber reinforced member 110 and the fiber reinforced cement cover 120;
A form tie rod member ( 170); including;
The form tie rod member 170,
A housing body 174 formed to a predetermined length, a load transmission plate 175 formed so that the load applied to the housing body 174 is distributed and transmitted to the glass fiber reinforcement member 110, and a first housing unit ( 181) and the second housing unit 191, a pair of central coupling blades (176, 177) formed on the housing body 174 so as to be slidably coupled;
a first housing unit 181 slidably coupled to the first central coupling wing 176;
a second housing unit 191 slidably coupled to the second central coupling blade 177;
a length adjustment bolt 195 fastened to the first housing unit 181 and the second housing unit 191;
Tie rod member (200) installed between the pair of first housing units (181); a building-integrated formwork provided with an insulator, characterized in that it comprises a.
delete 7. The method of claim 6,
The tie rod member 200 includes a tie rod body 202 having a predetermined length, a first head 203 formed at one end of the tie rod body 202 , and the tie rod body 202 . a first tie rod 201 comprising a second head 204 formed at the other end;
A tie rod body 202 formed to a predetermined length, a first head 203 formed at one end of the tie rod body 202 , and a fastening part 206 formed at the other end of the tie rod body 202 . ) and a second tie rod 205 having a thread 207 formed on the inner surface of the fastening portion 206; A building-integrated formwork provided with an insulating material, characterized in that it comprises any one. delete

Images