KR20130023538A - Concrete composite wall construction method with inner insulation, composite shear connector and composite form-tie - Google Patents

Abstract

PURPOSE: A concrete composite wall construction method is provided to hold the position of an insulator and to effectively prevent energy loss by installing a composite form tie for connecting a sandwich wall panel. CONSTITUTION: A concrete composite wall construction method comprises the following steps: pre-assembling and installing an insulator(110) and a composite connecting material between an euro form(210) and a gang form(220) for installing to the external wall of a building; interconnecting the gang form and euro form by a composite form tie and passing the composite form tie(400) through the insulator; and forming a concrete wall by pouring concrete(C) between the euro form and gang form. [Reference numerals] (AA) Cutting; (BB) Steel material

Description

Construction method of construction site suspended thermal wall using composite form ties {CONCRETE COMPOSITE WALL CONSTRUCTION METHOD WITH INNER INSULATION, COMPOSITE SHEAR CONNECTOR AND COMPOSITE FORM-TIE}

The present invention relates to a method for constructing a site suspended hot wall using a synthetic form tie. More specifically, the insulating material is installed between the gangform and the euroform set in the field, but the construction of the site suspended heat wall to allow the composite foam tie to penetrate the insulating material and to install the suspended heating wall by placing concrete between the gangform and the euroform. It is about a method.

In the existing concrete wall structure, for example, as shown in Figure 1a adopts a heat-insulating structure that installs the heat insulator 10 inside the outer wall 40 of the building, the floor heating 20 is the dominant In the multi-family house in Korea, the loss of heating energy flowing out to the outer wall 40 through the floor slab 30 is pointed out as a problem.

Accordingly, the outer insulation structure, which is one of the element technologies for realizing zero energy and zero carbon building structures, which are being promoted nationwide for the purpose of preventing global warming, is formed through an outer wall through the floor slab 30 as shown in FIG. Since the heating energy transmitted up to 40 is blocked by the heat insulating material 10 installed on the outer side of the outer wall 40, it is a structure that can expect a high energy saving effect.

However, in the case of the external insulation structure, in order to install the heat insulating material 10 on the outside of the outer wall, construction difficulties such as scaffolding for external work, additional construction of the protective finishing material 50, and durability of the heat insulating material exposed to the outdoor environment. Due to the problems in the aspect it has not yet reached the stage of full-scale commercialization.

In order to selectively collect the disadvantages of the heat resistant structure and the advantages and disadvantages of the external heat insulating structure, a so-called middle heat structure for inserting the heat insulating material 10 in the middle of the concrete walls A and B as shown in FIG. 1C. The concept of the wall was introduced.

In other words, the sandwich panel-type walls in which the insulation is formed between the concrete walls are attached to the outer wall.

1D and 1E show a perspective view and a cross-sectional view of an example in which a conventional concrete wall is constructed using the gang form 2 and the flow path 1.

Specifically, the Euroform (1, the inner formwork for the concrete wall) is a member of the panel form made of steel (steel) material to a certain standard, the gangform (2, the outer formwork for the concrete wall) is a certain thickness A flat iron plate 21 having a plurality of horizontal bars (22) made of square pipes are welded one by one on each side while maintaining a constant interval, and two horizontal bars (22) formed on several lines Several pairs of vertical bars 21 in a state adjacent to each other are welded at a predetermined interval.

In addition, a plurality of insertion holes 24 are drilled in the flat iron plate 21 of the gangform 2 as shown in FIG. 1E, and each of the insertion holes 24 is formed between a pair of two vertical bars 23. Is formed to be located, the gang foam support cones 25 are assembled to each of the plurality of insertion holes 24, one by one.

The flow path (1) and the gang form (2) is installed at a predetermined interval by the fastening device, the fastening device, and the interval holding hole (3) for supporting the gang form (2) with one end fixed to the flow path (1) The connection nut body 31 of the spacing holder 3 passes through the gang form support cone 25 assembled in the insertion hole 24 through a pair of longitudinal bars 23 welded to the gang form 2. A fastener 4 having a threaded portion 41 screwed thereon and an assembly hole 43 of a flat plate fastening portion 42 protruding outward of the vertical bar 23 while being formed at the other end of the fastener 4. Consists of a fastening wedge pin (5) to be fitted.

At this time, the assembly is formed so as to receive the plate fastening portion 42 of the fastener (4) which is formed separately from the gang form (2) and is screwed to the spacing holding (3) from the outside of the gang form (2) The fastening support member 6 is installed.

The fastening support member 6 is made of an iron plate, and has a support 61 having a size capable of supporting two pairs of vertical bars 23 at the same time, and a center of the support 61. The protruding reinforcement part 62 protruding toward one side (the opposite side of the gangform on the drawing) from the side and the flat plate fastening part 42 formed at the other end of the fastener 4 can be fitted in the center of the protruding reinforcement part 62. It has a structure in which the through hole formed in a straight shape so that

The fastening support member 6 as described above has the flat plate fastening portion 42 in a state where the flat plate fastening portion 42 of the fastener 4 penetrates through the through hole so as to protrude out of the protruding reinforcement portion 62. When the fastening wedge pin 5 is fitted into the assembly hole 43 formed in the one side of the fastening wedge pin 5 (the left side as opposed to the support member for fastening as the left side in the drawing) is supported at the end of the assembly hole 43 and the other surface Is tightly supported by the protruding reinforcement 62, so that the fastening wedge pin 5 is coupled to the fastener 4 so that the fastening support member 6 pushes the two vertical bars 23 simultaneously. It is to support the gang form (2) by the action.

Accordingly, in order to construct a suspended heat wall using the gangform and the euroform, a heat insulating material (10, indicated by a double-dotted line) is installed between the gangform and the euroform, and concrete is cured by pouring concrete (C, indicated by a single-dotted line) to cure the concrete wall. When the (A, B) is completed, the lower end of the wedge pin (5) for fastening the fastening support member (6) is hit by a hammer or the like to be removed from the assembly hole (43).

Accordingly, the fastening support member 6 is naturally separated from the vertical bar 23, so that the fastening support member 6 can be easily collected, and the fastener 4 can be removed while the fastening support member 6 is separated. By disassembling the screw will be made dismantling of the fastener (4).

At this time, the gap maintaining tool 3 is blown by a hammer or the like at a portion connected to the Euroform 1, so that the head 3a is cut and disassembled together with the Euroform 1. Therefore, it can be seen that the gap retaining region 3 from which the head 3a is removed is embedded in concrete and heat insulating material.

At this time, as shown in FIG. 1e, in order to secure the integrity of the heat insulating material 10 and both concrete walls A and B, a shear connector 70 made of steel (rebar) is used. In this case, the shear connector 70 is used. There is a problem in that energy loss, that is, a heat bridge occurs.

That is, the share connector installed to join both concrete walls (A, B) has a problem that acts as a cause of halving the advantages of the wall of the heat-recessed structure proposed for the purpose of preventing the loss of heating energy by thermal bridge phenomenon.

In addition, when constructing a concrete wall using a conventional gangform and euroform, as shown in FIG. 1F, the gap retaining holes 3 and the fasteners 4 are screwed together without using the gangform support cone 25 and the connecting nut body 31. Although there is an example of connecting to each other through the connection portion 41 in this case, problems such as the position of the heat insulating material 10 is changed when placing concrete, and the thermal bridge phenomenon by the shear connector 70 formed in the heat insulating material 10 Problems that have arisen still remain.

Therefore, the present invention is to construct a suspended heat wall of the building using the euro foam, gang form and form tie, in particular, to provide a construction method for the construction of on-site suspended heat wall using a synthetic form tie that can effectively prevent thermal bridge phenomenon. do.

Suspended thermal wall is basically to install a heat insulating material between the concrete wall and the heat insulating material to be connected to each other to integrate the concrete walls (also referred to as shear connector, the share connector of Fig. 1e and 1f) is to be installed. do.

Accordingly, in the present invention, the form tie installed between the gang form and the euro form serves as a connecting material for connecting both concrete walls to be spaced apart from each other.

This is because the form ties are installed so as to penetrate the heat insulating material in order to construct the suspended heat wall by the site-pouring method, so that the form ties can serve as a connecting material for integrating both concrete walls.

At this time, the form ties are made of synthetic form ties installed by connecting FRP form ties and steel form ties to minimize thermal bridges to be delivered to concrete walls.

In addition, restraining means (circle, etc.) for restraining the position of the heat insulating material may be set in the heat insulating material front part and the rear part in order to prevent a problem such as the position fluctuation due to the impact when the concrete is placed in the heat insulating material installed between the gang form and the euro form of the present invention. The constraining means was formed integrally with the synthetic form ties so that the synthetic form ties of the present invention also constrain the position of the heat insulator.

In addition, the heat insulating material is to be installed to the composite connecting material to further prevent the thermal bridge phenomenon of the suspended heat wall more effectively.

That is, the composite connector is arranged on the side of the heat insulating material so as to protrude laterally from the front portion (A2) and the rear portion (B2) of the heat insulating material, and the adhesive is attached between the gangform and the euroform by attaching the heat insulating material attached to the side with an adhesive. To be installed.

Since the composite connecting material made of FRP material is about 2/1000 to 1/100 times smaller than the thermal conductivity of the connecting material made of steel used in the conventional suspended heating wall, the energy loss (thermal bridge phenomenon) that has been pointed out as a problem in the existing suspended heating wall is reduced. There is an advantage that can be minimized.

In addition, in the arrangement method, the composite connecting material is arranged to penetrate the heat insulating material from the inside of one concrete wall so as to span the inside of the other concrete wall so that both concrete walls behave structurally integrally, compared with the existing non-synthetic concrete wall. When the moment arm length is increased by the composite connecting material, the bending moment resistance can be increased by 50% to 70% or more, thereby providing improved bending strength and rigidity.

Synthetic form ties used in the site-type suspended heat wall according to the present invention pointed out as a problem in the conventional suspended heat wall because the portion passing through the insulation is arranged as FRP form ties, in addition to the role of the connecting material to integrate both concrete walls together. Has the advantage of minimizing the energy loss (heat bridge phenomenon).

In addition, the composite connecting member installed in the insulation material is arranged to penetrate the insulation material from the inside of one concrete wall with the synthetic form ties so as to cover the inside of the other concrete wall so that both concrete walls behave structurally integrally. Compared to the wall, the bending moment resistance can be increased by 50% to 70% or more due to the increased moment arm length by the composite connecting member, thereby providing more improved bending strength and rigidity.

In addition, since the composite connecting material is made of a FRP material is used it is possible to more surely prevent the thermal bridge phenomenon in the suspended heat wall.

The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

1A is a conceptual diagram of heating energy loss of a heat insulating structure in a conventional floor heating structure,
1B is a conceptual diagram of preventing heating energy loss by an external insulation structure in a conventional floor heating structure,
Figure 1c is a conceptual diagram of preventing the heating energy loss by the heat dissipation structure in the conventional floor heating structure,
Figure 1d, 1e and 1f is a perspective view of the assembly of the conventional gangform and the flow path and concrete wall construction cross-sectional view using the same,
2a and 2b is an assembled perspective view and a combined perspective view of the interruption heat wall according to the first embodiment of the present invention,
Figure 3a and Figure 3b is an assembled perspective view and a perspective view of the interruption heat wall according to the second embodiment of the present invention,
4a and 4b is an assembled perspective view and a perspective view of the interruption heat wall according to the third embodiment of the present invention,
5 is a conceptual view (using Examples 1 and 2) of the field-pouring interrupted heat wall of the present invention.
6 is a conceptual view (using Example 3) of the construction of the field-pouring interrupted heat wall of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

[The interrupted heat wall using the assembled insulating material and the composite connecting material according to the present invention (Example 1)]

Suspended heating wall 100 of the present invention is pre-assembled and installed the heat insulating material 110 and the composite connecting member 120 between the flow path 210, the inner formwork and the gang form 220, the outer formwork is installed on the building outer wall as shown in Figure 2a. Afterwards, the gangform 220 and the euroform 210 are connected to each other by the synthetic form tie 400, but the composite form tie 400 passes through the insulation, and then the euroform 210 and the gangform 220 The concrete (C) is poured between the heat insulator (110) is constructed so that the outer and inner concrete walls (130, 140) are formed.

Finally, the euroforms and the gangforms 210 and 220 are dismantled, and the finished heat dissipation wall is finally finished as shown in FIG. 2B. The insulation material 110 is formed from the inside of the outer concrete wall 130 and the heat insulating material 110 formed between the final concrete walls 130 and 140. It is formed of a composite connecting member 120 penetrating and extending into the inner concrete wall 140.

At this time, the composite form tie 400 is dismantled only one side steel form tie 420 is installed in the gang form 220, FRP form tie 410 is embedded in the heat insulating material 110, the other side in the inner concrete wall 140 Steel form ties 430 are buried.

In addition, the outer reinforcement assembly 160 is installed between the gangform 220 and the heat insulator 110.

The outer reinforcing bar assembly 160 is spaced apart from the heat insulating material 110 is installed is installed in a manner of assembling and installing using a plurality of heat insulating material 110 is installed in accordance with the size of the gang foam and euro foam pre-synthetic connector 120 is installed.

At this time, the groove 111 is formed on the side surface of the heat insulator 110 so as to be formed in a waveform in the vertical direction, and the composite connecting member 120 of the present invention is disposed in a wave in the groove of the wave shape.

At this time, the important point is that the front end (A1) and the rear end (B1) of the synthetic connecting member 120 is arranged to protrude from the front and rear parts (A2, B2) of the heat insulating material (110).

As described above, the synthetic connecting member 120 protrudes into the front portion A and the rear portion B of the heat insulator 110 and is embedded in the poured concrete to synthesize the outer and inner concrete walls 130 and 140 with each other.

In this case, the synthetic connecting material 120 may be manufactured in the form of a rod, but it may be used by cutting a predetermined length into a strip shaped wave form.

In this case, the composite connecting member 120 is made of a FRP material.

Since the composite connector 120 of the FRP material has a thermal conductivity much lower than that of the steel, even if the concrete walls 130 and 140 are connected (bonded), the thermal bridge phenomenon can be minimized. (The thermal conductivity of the connector manufactured from steel. 2 / 1000-1 / 100 times smaller)

In addition, the composite connecting material of the FRP material itself has a tensile strength equal to or higher than that of steel, thereby exhibiting sufficient mechanical strength necessary for the composite behavior of the concrete wall, and thus significantly improved insulation performance compared to the existing suspended heat wall. It can be maintained.

As such, when the assembly installation of the heat insulator 110 attached to the side of the synthetic connection member 120 is completed, the inner reinforcing bar assembly 170 is installed to secure a constant coating thickness from the flow path 210 which will be described later.

In addition, the inner side of the reinforcement assembly 170 is spaced apart from the euro foam 210 is installed in the building.

When the concrete is poured (in-situ) between the euroform and the gangform 210 and 220 and the heat insulator 110, the construction of the intermediate heat wall of the present invention is possible.

In this case, when using the interrupted heat wall according to the present invention for structural use it is to use the inner and outer reinforcement assembly (160, 170) as shown in Figures 2a and 2b, but using the outer concrete wall 130 for non-structural In this case, it is not necessary to minimize the thickness t1 of the outer concrete wall and the outer reinforcement assembly 160 or install the outer reinforcement assembly 160.

Thus, the thicknesses t1 and t2 of the final outer and inner concrete walls may be adjusted.

Synthetic form tie 400 of the present invention connecting the gang form 220 and the euro form 210 used in such a heat-dissipating wall is FRP form tie 410 and FRP form tie 410 penetrating the heat insulating material 110 It is connected to both ends and is divided into one side and the other side steel form ties (420,430) are installed to extend to the gang form 220 and the flow path 210, respectively.

The synthetic form tie 400 is provided with restraining means 440 (a kind of spacer) which is installed to contact the front and rear portions of the heat insulating material 110, whereby the synthetic form tie 400 is basically a gang form 220 and It serves to connect the flow path 210 to each other, and to prevent the thermal bridge phenomenon of the interrupted heat wall by the FRP form tie 410 embedded through the heat insulating material 110, restraining means 440 installed It also serves as a kind of spacer that can prevent the phenomenon that the position of the heat insulating material 110 is changed by the impact caused by the concrete pouring.

[Secondary heat wall using the assembled insulating material and the composite connecting material according to the present invention (Example 2)]

3A and 3B illustrate the site-pouring interrupted heat wall 100 according to the second embodiment, which is different from the first embodiment in the synthetic connecting member 120, the first embodiment having a rod shape or a thin thickness. Although the composite connector 120 is used in the form of a strip, the second embodiment uses the composite connector 120 in the form of a grid.

Specifically,

That is, as shown in Figure 3a to prepare a grid (GRID) composite connecting material produced in a constant size and cut vertically.

As such, it can be seen that various grid composite connectors 120 are vertically cut.

Accordingly, as shown in FIG. 3B, the grid composite connecting member 120 is vertically attached (using adhesive) to the insulation 110 side.

Of course, it can be seen that the front portion A1 and the rear portion B1 of the grid composite connecting member 120 protrude from the front portion A2 and the rear portion B2 of the insulation.

As described above, the second embodiment, in addition to the configuration of attaching the grid composite connector 120 to the insulation 110 side with an adhesive, the euroform and gangform (210, 220), the inner and outer reinforcement assembly (160, 170) and the euroform and gangform (210,220) By placing concrete (C) between the heat insulating material and the heat insulating material 110, the inner and outer reinforcing bar assemblies 160 and 170 are embedded in the concrete walls 130 and 140 in the same manner as in Example 1.

Of course, in the case of using the suspended heat wall for structural use as shown in Figure 3b, the inner and outer reinforcement assembly (160, 170), but when using the outer concrete wall 130 for non-structural use of the outer concrete wall It is not necessary to minimize the thickness and outer reinforcement assembly 160 or install the outer reinforcement assembly.

In this regard, the interruption heating wall according to the second embodiment is particularly easy to manufacture and install the composite connecting member 120, compared to the first embodiment has a very simple effect of manufacturing the interruption heating wall.

Synthetic form tie 400, which connects the gang form 220 and the euro form 210, which is also used in such a heat-recessed wall is also connected to both ends of the FRP form tie 410 and the FRP form tie through the heat insulating material 110 And are divided into steel form ties 420 and 430 extending to the gang form 220 and the euro form 210, respectively, which is the same as the first embodiment.

Furthermore, the synthetic form tie 400 is also provided with restraining means 440 (a kind of spacer) installed to contact the front and rear portions of the heat insulating material 110.

Therefore, the synthetic form tie 400 according to the second embodiment also serves to connect the gang form 220 and the euro form 210 to each other, and to the FRP form tie 410 embedded through the heat insulating material 110. It is also possible to prevent the thermal bridge phenomenon of the interrupted heat wall, and also serves as a kind of spacer to prevent the phenomenon of the position of the heat insulating material 110 is changed by the impact of the concrete placing by the restraining means 440 installed. It can be seen that.

[Secondary heat wall using the assembled insulating material and the composite connecting material according to the present invention (Example 3)]

4A and 4B illustrate the interruption heat wall 100 according to the third embodiment, and the difference from the first and second embodiments is that the composite connecting material 120 is connected to the heat insulating material 110 used in constructing the interruption heat wall. FRP form ties and steel form ties without using a) can be an example of using a composite form tie 400 is connected to each other.

Since the form tie penetrating the insulation 110 is FRP form tie 410, the FRP form tie may also serve as the composite connecting member 120 according to Examples 1 and 2 to use the synthetic connecting member 120. It is not.

That is, as shown in FIG. 4a, the heat insulating material 110 is installed in parallel between the gangform 220 and the flow path 210, and the flow path and the gangform 210 and 220, the inner and outer reinforcing assemblies 160 and 170, and the flow path are installed. By placing concrete (C) between the gangforms 210 and 220 and the heat insulator 110, the outer and inner concrete walls 130 and 140 are formed so that the inner and outer reinforcement assemblies 160 and 170 are embedded in the concrete walls 130 and 140. To form.

Of course, even in this case, when using the interruption heat wall for structural use as shown in Figure 4b, the inner and outer reinforcing bar assembly (160, 170), but when using the outer concrete wall 130 for non-structural the outer It is not necessary to minimize the thickness of the concrete wall and the outer reinforcement assembly 160 or install the outer reinforcement assembly.

Accordingly, the interruption heat wall according to the third embodiment does not use the composite connecting material (! 20), and thus, the construction of the interruption heat wall can be more economical.

Synthetic form ties 400 for connecting the gangform 220 and the flow path 210 used in such a heat-recessed wall are the same as the first and second embodiments.

[In-Place Method of Recessed Hot Wall Construction Method 1 (Use of Recessed Hot Wall of Example 1 or 2)]

Referring to Figure 5 based on the construction method 1 is assembled between the heat insulating material 110 and the composite connecting member 120 is installed between the gang foam 220 and the euro foam 210 and the concrete (C) on the gang foam 220 and the euro foam 210 It can be seen that it is constructing the interrupted heat wall by pouring).

Specifically, as shown in FIG. 5, the gangform 220 and the flow path 210 are installed. The gangform 220 and the flow path 210 are restrained from each other by the synthetic form tie 400 of the present invention.

In this case, the pre-assembled heat insulating material 110 and the composite connector 120 are prepared in advance so as to be arranged in advance between the gang foam 220 and the euro foam 210, and a plurality of the gang foam 220 and the euro foam 210 are parallelly attached to each other according to the installation area. (Adhesive).

Accordingly, the other steel form tie 430 installed in the euro form 210 in the synthetic form tie 400 extends through the euro form 210 to the rear portion of the heat insulating material 110, but is formed on the rear portion B of the heat insulating material 110. The other steel form ties 430 are provided with restraining means 440 in the form of a disc.

In addition, one side of the steel form tie 420 installed in the gang form 220 in the form tie 400 is to extend through the gang form 220 to the rear of the gang form,

In the form tie 400, the FRP form tie 410 is to be connected to each other to the steel form tie (420,430) through the heat insulating material 110, FRP foam to be in contact with the front portion (A) of the heat insulating material (110). It can be seen that the tie 410 is provided with a restraining means 440 in the form of a disc.

In this case, the insulating member 110 and the synthetic connecting member 120 are assembled between the gang form 220 and the euro form 210, and the FRP form tie 410 penetrates the insulating member 110, and the one side and the other steel form tie The final outer concrete wall 130 and the inner concrete wall (420,430) by placing the concrete (C) on both sides of the heat insulating material 110 in a state that is connected to both ends of the FRP form tie 410 is fixed to the gang form and the euro foam ( 140).

As a result, the outer concrete wall 130 and the inner concrete wall 140 can be seen to be basically integrated with each other by the composite connecting material 120, and also to be completely integrated with each other by the synthetic form tie 400.

At this time, the surface of the other steel form tie 430 embedded in the inner concrete wall 140 is preferably treated with a rough surface to ensure sufficient adhesion performance with the concrete.

In this case, the outer concrete wall 130 may be relatively thin and may function as a non-structural structure by not disposing the outer reinforcing bar assembly, and it does not matter even if a wire mesh or an outer reinforcing bar assembly is installed.

On the other hand, the inner concrete wall 140 between the rear surface of the heat insulating material 110 and the euroform 210 can be seen that the inner reinforcing bar assembly 170 is disposed therein and a little thicker than the outer concrete wall 130. It can be seen that it is formed to function as a structure.

Accordingly, when the outer and inner concrete walls 130 and 140 are cured, the gang form 220 and the flow path 210 are dismantled.

The gang form 220 is to disassemble the gang form 220 and one side steel form tie 420 at the same time, while separating the one side steel form tie 420 from the FRP form tie 410,

FRP form tie 410 is to be embedded through the heat insulator 110,

The other steel form tie 430 is embedded in the inner concrete wall 140 while hitting the head 430a to be dismantled together with the head and the flow path (210).

In addition, the hole formed by the form tie in the final finished heat-dissipating wall is finished by using a mortar, etc. separately so as not to damage the aesthetics.

[Method 2: Construction of Suspended Hotwall]

Referring to FIG. 6, the difference between the construction method 2 and the construction method 1 is that the steel form ties 420 and 430 and the FRP form tie 410 are connected by using the insulation 110 that is not installed with the synthetic connecting member 120. The use of synthetic form tie 400 is the same.

This is because it is more economical to use the heat insulating material 110 that is not provided with the composite connector 120 in consideration of the fact that the synthetic form tie 400 may serve as a conventional synthetic connector in the suspended heat wall.

Specifically, as shown in FIG. 6, the gangform 220 and the flow path 210 are installed. The gangform 220 and the flow path 210 are restrained from each other by the synthetic form tie 400 of the present invention.

At this time, the pre-assembled heat insulating material 110 is pre-arranged between the gang foam 220 and the flow path 210 so that a plurality of the gang foam 220 and the flow path 210 in parallel with each other in accordance with the installation area (adhesive) is carried out. Same as Example 1.

In this case, the other steel form ties 430 installed on the euro form 210 in the synthetic form tie 400 extend through the euro form 210 to the rear portion of the heat insulator 110, but the rear portion B of the heat insulator 110. On the other side of the steel form tie 430 is provided with a restraining means 440 in the form of a disc,

One side steel form tie 420 installed in the gang form 220 in the form tie 400 is to extend through the gang form 220 to the rear portion,

In the form tie 400, the FRP form tie 410 is to be connected to each other to the steel form tie (420,430) through the insulation 110,

It can be seen that the FRP form tie 410 to be in contact with the front portion of the heat insulator 110 is provided with a restraining means 440 in the form of a disc.

Insulation 110 is installed between the gangform and the euro foam is disposed, the FRP form tie 410 of the form tie 400 to penetrate the insulation 110, the steel form ties (420, 430) the amount of FRP form tie The outer concrete wall 130 and the inner concrete wall 140 are formed by pouring concrete C to both sides of the heat insulating material 110 in a state connected to the end and fixed to the gang form and the flow path.

Accordingly, when the outer and inner concrete walls 130 and 140 are cured, the gang form 220 and the flow path 210 are dismantled.

Gang form 220 is to disassemble the gang form 220 and the one side steel form tie 420 at the same time, while separating the one side steel form tie 420 from the FRP form tie 410,

FRP form tie 410 is to be embedded through the heat insulator 110,

The other steel form tie 430 is embedded in the inner concrete wall while hitting the head 430a to be dismantled together with the head and the flow path 210 is the same.

In addition, the hole formed by the form tie in the final finished heat-dissipating wall is finished by using a mortar, etc. separately so as not to damage the aesthetics.

100: interrupted heat wall according to the present invention
110: Insulation
111: home
120: composite connecting material
130: outer concrete wall
140: inner concrete wall
210: Euroform
220: gangform
400: synthetic foam tie
410: FRP Form Tie
420,430: One side and the other steel form ties
440: means of restraint

Claims (11)

The gang foam 220 and the euro foam 210 is spaced apart using the form tie 400, and the insulation 110 is installed between the gang foam 220 and the euro foam 21, the insulation 110 is a plurality of Attaching the heat insulating material to each other so as to be assembled, and placing the concrete (C) so that the heat insulating material 110 is embedded between the gangform 220 and the flow path 210;
The form tie 400 is that the one and the other steel form ties 420, 430 are connected to each other at both ends of the FRP form tie 410 and the FRP form tie 410, the FRP form tie 410 is a heat insulating material ( 110, and the steel form ties 420 and 430 are connected to both ends of the FRP form ties 410, the composite form ties characterized in that the extension is installed in the gang form 220 and the euro form 210, respectively. Construction method of on-site suspended hotwall using The method of claim 1,
Installed on the outer circumferential surface of the FRP form tie (410) constraining means (440) to be installed so as to contact the front portion of the heat insulator (110) on-site suspended hot wall construction method using a composite form tie. 3. The method according to claim 1 or 2,
The one-side steel form tie 220 is installed on the outer circumferential surface of the field suspended heat wall construction method using a composite form tie, characterized in that the restraining means 440 is further installed to contact the rear portion of the heat insulating material (110). The method of claim 1, wherein the heat insulating material 110 is to be further formed on the side so as to protrude from the front portion (A2) and the rear portion (B2) of the heat insulating material, the composite connector 120 is formed on the side On-site suspended heating wall construction method using a composite form tie, characterized in that to be installed by attaching to each other attached to the heat insulating material (110) attached to each other. The method of claim 4, wherein the composite connecting member 120 is formed in the form of a wave form as a rod or strip (STRIP) in the form of a wave shape so as to be installed on the side of the heat insulating material 110, characterized in that the interruption Heat wall construction method. The method according to claim 5, wherein the insulating member 110 is formed on the side surface to form a groove 111 formed in a wave form so that the composite connector 120 in the form of a waveform, characterized in that the composite connector 120 is inserted into the groove. Method for construction of on-site suspended heat wall using synthetic form tie. According to claim 4, The synthetic connector 120 is cut to the synthetic connector 120 made in the form of a grid (GRID) by cutting the synthetic connector 120, the site using a synthetic form tie, characterized in that installed vertically on the side Construction method of suspended heat wall. 5. The method of claim 4, wherein the outer reinforcing bar assembly 160 is further installed between the gangform 220 and the heat insulator 110. 5. The method of claim 4, wherein the inner reinforcing bar assembly is further installed between the flow path 210 and the heat insulator 110. The method of claim 4, wherein the inner and outer concrete walls formed between the gangform 220 and the flow path 210 are formed to be formed by varying the thickness (t1, t2) with each other, the site stop using a composite form tie Heat wall construction method. According to claim 4, The synthetic connector 120 is attached to the side of the heat insulating material 110 to attach a plurality of heat insulators 110 made in advance in the factory by adhesive to each other in the field to be installed between the gangform and the euroform Method for constructing on-site suspended heating wall using a composite form tie, characterized in that.

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