KR101710410B1 - Heat Insulating System and Construction Method thereof - Google Patents

Abstract

The present invention relates to an adiabatic system and a construction method using the same, and more particularly, to an adiabatic system capable of replacing a formwork and performing an adiabatic construction while curing a concrete wall, and a method of constructing the same.
The present invention provides an adiabatic system for constructing a concrete wall having a first side and a second side facing each other, the adiabatic system comprising: a heat insulation panel (50) installed at a position corresponding to the first side; An inner wall panel (60) installed at a position corresponding to the second surface; A first wall-embedded socket 11 provided on an inner surface side of the heat insulating panel 50; A second wall embedding socket (12) provided on an inner surface side of the inner wall panel (60); A wall embedding bar (10) having opposite ends connected to the first wall embedding socket (11) and the second wall embedding socket (12), respectively; A thermal bridge interconnection bolt (31) embedded in the thermal insulating panel (50) and connected to the first wall embedded socket (11), one or more serially connected thermal bridge interconnection bolts (31); A connector (33) fitted in the heat insulating panel on the outer surface side of the heat insulating panel (50); A connector connecting bolt 35 fixed to the heat bridge interconnection bolt 31 and embedded in the connector 33 to an outer end of the connector 33 fitted to the outer surface of the heat insulating panel 50; And a finishing cap (371, 372) cooperating with the outer end of the connector (33) to insulate the end of the connector connecting bolt (35) against the outer space, wherein one end of the heat bridge interconnection bolt (31) And an insert nut 312 is installed at the other end of the bolt 311. The insert bolt and the insert nut are insert injection-molded so as to be spaced apart from each other, and a construction method using the same.

Description

TECHNICAL FIELD [0001] The present invention relates to a heat insulation system,

The present invention relates to an adiabatic system and a construction method using the same, and more particularly, to an adiabatic system capable of replacing a formwork and performing an adiabatic construction while curing a concrete wall, and a method of constructing the same.

In case of general reinforced concrete house, the wall construction is done by using form made of euro foam or plywood, installing the inner wall form with the interval corresponding to the thickness of the wall to be constructed, reinforcing the inside of the wall form, The concrete slurry is poured into the concrete to be cured and then the concrete is removed.

In recent years, consumers are increasingly concerned about the rise in the cost of heating energy due to rising oil prices. As a result of government regulations on insulation design due to changes in energy design standards of buildings, reinforcement concrete structures tend to be constructed separately after construction of wall structures have.

Reinforced concrete structures have the advantages of structural stability due to their high durability, but they are hotter in summer and colder in winter due to stronger heat storage than insulation. In order to compensate this, efforts to maximize the advantages of reinforced concrete structures by enhancing the heat insulation performance by the adiabatic method are being carried out on the construction site. However, it is a reality that the aging of skilled professional engineers, the shortage of manpower, and the possibility of construction due to experience by constructor rather than standard specification are implied by each constructor.

Also, there is a disadvantage in that the method of constructing the concrete wall separately and then installing the external heat separately has a disadvantage that the process is cumbersome and requires an additional construction period, and most of it depends on the experience of the constructor without a clear standard, The adhesion strength is lowered due to the shortage, and an accident due to the detachment of the heat insulating material after the completion of the installation due to the absence of the specified fastener may occur.

In a more advanced construction method, a technique has been developed and installed in which a heat insulating material is attached to the inner side of an outer side mold when the wall mold work is performed, so that the heat insulating material is integrally formed.

However, the construction process of the single-walled single-walled concrete wall is carried out by attaching a general cross-section of the styrofoam to the mold by the factory production, so that the cement paste penetrates between the heat insulating material and the heat insulating material when the concrete is poured, The connection between the formwork and the formwork is made by a flat tie, which is a metal transverse member, so that the fixing and spacing of the formwork is maintained, and then the concrete is filled and cured. As a result, the flat tie, which is a metallic connecting pin, And it may be the cause of persistent thermal bridges in the future.

In other words, although the performance by the heat transfer rate value determined for each heat insulating material is guaranteed, the result of the heat insulating value by the construction method shows a large difference. Especially, the thermal bridges between the insulation and the insulation are not considered and the connection material is not produced either. In order to achieve the insulation performance of the insulation itself, the heat bridging between the insulation and the insulation should be minimized, and the insulation between the insulation and the wall should be constructed of a material with low thermal conductivity.

In recent years, as passive houses with high insulation and airtightness are known to the public, the number of building owners who want houses with high insulation performance is increasing. However, in order to construct a house with high insulation performance, the thickness of the insulation material necessarily increases, It is a reality that construction is also difficult and the related materials are also dependent on imports, so it is a reality that the cost is burdened. In addition, aware of the risk of the insulation being dropped, it is customary to apply the wet method (finishing) rather than the dry method It is a reality.

Korean Registered Patent No. 10-0375319 (registered on February 25, 2003) Korean Registered Patent No. 10-1027973 (Registered on April 01, 2011) Korean Registered Patent No. 10-1079646 (registered on October 28, 2011)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an insulation system capable of simplifying construction by simultaneously performing external insulation and formwork construction for a concrete wall, And to provide a wall construction method using the same.

According to an aspect of the present invention, there is provided an adiabatic system for constructing a concrete wall having a first surface and a second surface facing each other, the adiabatic panel having a heat insulation panel installed at a position corresponding to the first surface, ; An inner wall panel (60) installed at a position corresponding to the second surface; A first wall-embedded socket 11 provided on an inner surface side of the heat insulating panel 50; A second wall embedding socket (12) provided on an inner surface side of the inner wall panel (60); A wall embedding bar (10) having opposite ends connected to the first wall embedding socket (11) and the second wall embedding socket (12), respectively; A thermal bridge interconnection bolt (31) embedded in the thermal insulating panel (50) and connected to the first wall embedded socket (11), one or more serially connected thermal bridge interconnection bolts (31); A connector (33) fitted in the heat insulating panel on the outer surface side of the heat insulating panel (50); A connector connecting bolt 35 fixed to the heat bridge interconnection bolt 31 and embedded in the connector 33 to an outer end of the connector 33 fitted to the outer surface of the heat insulating panel 50; And a finishing cap (371, 372) cooperating with the outer end of the connector (33) to insulate the end of the connector connecting bolt (35) against the outer space, wherein one end of the heat bridge interconnection bolt (31) And an insert nut (312) is provided at the other end of the bolt (311), and the insert bolt and the insert nut are insert injection molded to be spaced apart from each other.

The at least one of the surfaces of the first wall-embedded sockets 11 and the heat-bridge interconnection bolts 31 facing each other or the surfaces of the two thermal-bridge interconnection bolts 31 connected in series is provided with the anti- The unlocking portion may have a sawtooth shape arranged along the circumference in the circumferential direction about the rotation axis.

The inner wall surface guide bar 23 is temporarily installed outside the second wall embedding socket 12 and the socket inserting hole 611 of the inner wall panel 60 is guided to the inner wall surface guide bar 23, A wall panel 60 may be provided on the second side.

A panel member fixing bolt 24 is fitted and coupled to the outside of the connector connecting bolt 35 and the outside of the second wall embedding socket 12 and a securing member fixing bolt 26 , 28) and can be fixed by sandwiching the installation members (41, 42).

An angle 38 may be provided on the outer side of the connector connecting bolt 35 for finishing work and closed with a finishing bolt 39.

The heat insulating panel 50 has a structure in which the XPS 51 and the refractory panel 52 are laminated and the refractory panel 52 is located on the outer side of the concrete wall with respect to the XPS 51. On the heat insulating panel 50, And the heat insulating bridge connecting bolts 31 are inserted into the heat insulating interlocking connection bolts 31. The ends of the heat insulating panel are located at positions facing each other when the two heat insulating panels are brought into contact with each other The grooves 53 are formed in communication with each other so that the neighboring two adiabatic panels can be connected by fitting the connecting pins 54 into the grooves 53. [

The inner wall panel 60 is a structure in which an inorganic panel 61 and a fabric 62 are laminated and the fabric 62 is positioned further inside than the inorganic panel 61 with respect to the concrete wall, A socket inserting hole 611 is formed in the same direction as the stacking direction at a predetermined interval and a groove 63 is formed at an end of the inner wall panel at a position where the two inner wall panels face each other , And the neighboring two adiabatic panels can be connected by inserting the connecting pin (64) into the groove (63).

The inner wall panel 60 is formed with a plurality of holes 612. The holes 612 are in the form of a funnel whose width decreases as the distance from the concrete wall increases. The diameter of the large diameter portion of the hole 612 is 5 To 10 mm, and the diameter of the small diameter portion of the porous tube may be 2 to 5 mm.

A bending recess 57 is formed at the center of the corner member 56. The corner member 56 is provided at one end of its one side with a fitting protrusion 56, When the bending projections are bent in the direction in which the bending projections are opposed to each other with respect to the bending grooves, the bending grooves 58 can be fastened to the outward corner of the heat insulating panel, It can be fastened to the inward corner of the heat insulating panel.

The lower end portions of the two adjacent inner wall panels 60 can be inserted and fixed into the connection bracket 85 having a " C "

A waterproof plate 88 is provided at a lower end of the inner wall panel 60. The waterproof plate 88 includes a vertical plate 881 attached to the inner surface of the inner wall panel 60, And a bottom horizontal plate 882 extending horizontally from the lower portion of the bellows-like portion 883 and contacting the base concrete.

Further, the present invention is a method of applying the above-described adiabatic system, comprising the steps of (S01 to S05) placing and curing a foundation concrete; (S06 to S10) of installing the heat insulating panel, the reinforcing bars and the inner wall panel on the foundation concrete; (S11 to S14) of installing a temporary material on the heat insulating panel and the inner wall panel; (S15) placing and curing concrete in a wall space formed by the heat insulating panel and the inner wall panel; Removing the temporary material after the concrete curing of the wall (S16); And a step (S17) of installing a finishing material after the removal of the installation material.

The step of pouring and curing the foundation concrete comprises: a trenching step (S01); A step (S02) of raising a rubble to the terrarium; (Step S03) of placing the heat insulating material on the rubble; (S04) of stacking the heat insulating block for foundation concrete on the upper surface rim of the heat insulating material; And a step (S05) of forming a foundation bottom surface by placing concrete z in a space formed by the heat insulating material and the heat insulating block.

The step of installing the heat insulating panel, the reinforcing bars, and the inner wall panel on the foundation concrete comprises: providing a heat insulating panel (50) and an inner wall panel (60) on the first surface and the second surface, A first wall embedding socket 11 and a second wall embedding socket 12 connected to each other by a wall embedding bar 10 on the inner side of the inner wall panel and the inner wall surface of the inner wall panel, The connector 33 is disposed on the outer side of the heat insulating panel 50 and the connector connecting bolt 35 is connected to the heat bridge interconnection bolt 31) to fix the connector 33. [0050] As shown in Fig.

The step of constructing the heat insulating panel, the reinforcing bars and the inner wall panel on the foundation concrete comprises: provisionally installing an inner wall surface guide bar (23) on a second wall embedding socket (12) provided on the second surface; The socket inserting hole 611 of the inner wall panel 60 is inserted into the guide bar 23 so that the inner wall panel 60 is positioned adjacent to the second wall embedding socket 12 and then the inner wall surface guide bar 23 can be removed from the second wall embedding socket 12 and the panel member fixing bolt 24 is fastened to the second wall embedding socket 12 to fix the inner wall panel 60 .

According to the present invention, since the external heat insulating panel functions as a mold and is integrally formed with the concrete wall, the wall construction process is simplified and the adhesion and adhesion of the external heat insulating panel to the concrete wall are very high.

Further, according to the present invention, the finishing material of the outer wall is surely supported by the concrete wall by the thermal bridge interconnection bolts, thereby firmly supporting the finishing material, and also reliably interrupting the heat bridge between the outside air and the inside.

In addition, according to the present invention, it is possible to construct a passive house with modular construction, so that it is possible to construct a passive house which is sure to block heat bridge even if it is not a skilled construction expert.

In addition, according to the present invention, the construction of a panel member fixing bolt, a construction material, a fixing bolt, a leveling device, and the like are standardized in a modular construction so that the construction can be continuously reused at different construction sites.

Further, according to the present invention, since the finish can be performed without any additional work or work, the construction is very simple.

The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a supporting structure for an insulating panel and an inner wall panel used in an adiabatic system according to the present invention;
FIG. 2 is an exploded perspective view of a thermal bridge interconnection bolt of the present invention,
3 is a side cross-sectional view of a heat bridge interconnection bolt of the present invention,
FIG. 4 is a partial perspective view showing a coupling method of the heat bridge interconnection bolt and the first wall embedding socket of the present invention,
FIG. 5 is a perspective view showing a state where a thermal bridge breaking connection bolt and a connector are fastened to a first wall embedding socket of the present invention and closed by a finishing cap;
6 is a partial perspective view showing a manner in which the inner wall surface guide bar is coupled to the second wall embedding socket of the present invention,
7 is a perspective view showing a process of inserting the inner wall panel into the inner wall surface guide bar coupled to the second wall-
8 is a perspective view showing a disassembled state of a structure provided on an inner wall panel side of a supporting structure of an insulating panel and an inner wall panel used in a heat insulating system,
Fig. 9 is a side view of a supporting structure for an insulating panel and an inner wall panel used in an adiabatic system; Fig.
10 is a side sectional view showing a state in which a formwork and a building material are applied to an outer wall of a building using a supporting structure of an insulating panel and an inner wall panel used in a heat insulating system,
11 is a side sectional view showing a state in which a formwork and a construction material are applied to an inner wall of a building using the support structure of the present invention,
12 is a perspective view of a construction material used in the wall of the present invention,
13 is a partial perspective view showing a process of installing an angle in a connector exposed to the outside of a heat insulating panel of a supporting structure of the present invention,
14 is a rear view showing a part of the heat insulating panel of the present invention,
15 is a partial perspective view of a first embodiment of the heat insulating panel of the present invention,
16 is a partial plan view of a second embodiment of the heat insulating panel of the present invention,
17 is a view showing an example of the lamination method of the heat insulating panel of the present invention,
18 is a partial perspective view of an embodiment of the inner wall panel of the present invention,
19 is a front view showing a part of the inner wall panel of the present invention,
20 is a side sectional view of an inner wall panel and a concrete wall of the present invention,
21 is a partial perspective view showing a state in which a heat insulating panel, an inner wall panel, a reinforcing bar, and support structures thereof are installed on a foundation concrete,
Figure 22 is a view of the connecting bracket of the present invention,
23 is a side sectional view showing a water resistance plate provided at the lower end of the inner wall panel of the present invention,
24 is a view showing a state in which a corner member is installed at the corner of the heat insulating panel of the present invention,
Fig. 25 is a view showing the corner member shown in Fig. 24,
26 is a view showing an inner member and an out-corner member used for an inner wall panel,
FIG. 27 is a side sectional view showing a state in which an outer wall of a wall constructed by applying the adiabatic system of the present invention is finished with a wood panel or a zinc panel,
FIG. 28 is a side sectional view showing a state in which marbles are closed on an outer wall of a wall constructed by applying the adiabatic system of the present invention, FIG.
FIG. 29 is a partial perspective view showing a step of installing an angle for finishing marble on an outer wall of a wall constructed by applying the adiabatic system of the present invention; FIG.
FIG. 30 is a perspective view showing a state in which the outer wall of the wall constructed by applying the adiabatic system of the present invention is closed with marble,
31 is a side sectional view showing a state in which the outer wall of the wall constructed by applying the adiabatic system of the present invention is coarsely closed,
Fig. 32 is a perspective view showing a trenching step of a construction method applying the adiabatic system of the present invention; Fig.
FIG. 33 is a perspective view showing a compaction step of a construction method applying the adiabatic system of the present invention,
FIG. 34 is a perspective view showing a step of laying a heat insulating material in a construction method using the adiabatic system of the present invention;
FIG. 35 is a perspective view showing a step of stacking a heat insulating block for a foundation concrete in a construction method using the heat insulating system of the present invention,
FIG. 36 is a perspective view showing a step of placing a foundation concrete in a construction method applying the adiabatic system of the present invention,
FIG. 37 is a perspective view showing a wall corner construction step of a construction method applying the adiabatic system of the present invention,
FIG. 38 is a perspective view showing an insulating panel construction step of a construction method using the insulation system of the present invention, FIG.
FIG. 39 is a perspective view showing a reinforcing bar construction step of a construction method applying the adiabatic system of the present invention,
40 is a perspective view illustrating a reinforcing bar construction step of a construction method using the adiabatic system of the present invention,
41 is a perspective view showing an inner wall panel construction step of a construction method applying the adiabatic system of the present invention,
FIG. 42 is a perspective view showing door frames and door frame steps of a construction method applying the adiabatic system of the present invention, FIG.
FIG. 43 is a perspective view showing a construction step of an inner wall surface first installation of a construction method applying the adiabatic system of the present invention,
FIG. 44 is a perspective view showing a construction step of an inner wall surface second installation of a construction method using the adiabatic system of the present invention, FIG.
FIG. 45 is a perspective view showing a step of constructing an outer wall surface first installation of a construction method using the adiabatic system of the present invention,
46 is a perspective view showing a step of constructing an outer wall surface second installation of a construction method using the adiabatic system of the present invention,
FIG. 47 is a perspective view showing the concrete placing step of the construction method applying the adiabatic system of the present invention,
48 to 51 are perspective views showing a finishing step of an outer wall surface of a construction method using the adiabatic system of the present invention, and
52 is a perspective view showing an inner wall panel removing step of a construction method applying the adiabatic system of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to inform.

FIG. 1 is a perspective view of a supporting structure for an insulating panel and an inner wall panel used in an adiabatic system according to the present invention, FIG. 2 is an exploded perspective view of a thermal bridge interconnection bolt of the present invention, FIG. 4 is a partial perspective view showing a coupling method of the heat bridge interconnection bolt and the first wall embedding socket of the present invention, FIG. 5 is a perspective view showing the state where the heat bridge interconnection bolt and the connector are fastened to the first wall- Fig. 6 is a partial perspective view showing the manner in which the inner wall surface guide bar is engaged with the second wall-embedding socket of the present invention, Fig. 7 is a perspective view showing the inner wall surface of the inner wall surface guide bar coupled to the second wall- Fig. 8 is a perspective view showing a process of inserting the inner wall panel, and Fig. 8 is a perspective view showing a process of inserting the inner wall panel into the supporting structure of the heat- Tanaen perspective view, and Figure 9 is a side view of the support structure of the heat insulating panel and the inner wall panels in insulation systems.

The supporting structure of the adiabatic system of the present invention comprises a wall embedding bar 10, a first wall embedding socket 11 and a second wall embedding socket 12 as a configuration to be embedded in a concrete wall, Includes at least one thermal bridge interconnection bolt (31), a connector (33) and a connector connecting bolt (35), and has an inner wall surface socket (22) as a configuration to be embedded in the inner wall panel.

The wall embedding bar 10 is an elongated metal bar having a first wall embedding socket 11 at one end and a second wall embedding socket 12 at the other end, do. The first wall embedding socket 11 and the second wall embedding socket 12 may be made of plastic and the inner insert nuts 110 and 120 fastened to the bolt portions formed at both ends of the wall embedding bar 10 are inserted into the insert It may be in the form of an injection.

Although the embodiments of the present invention disclose that these components 10, 11, and 12 are configured as separate components, it goes without saying that these three components 10, 11, and 12 may be integrally manufactured.

A heat insulating panel, which will be described later, is provided outside the first wall embedding socket 11, and a heat bridge interconnection bolt 31, a connector 33, and a connector connecting bolt 35 are inserted into the heat insulating panel. An insert nut 111 is also insert-injected into the outer side of the first wall-embedded socket 11 and an insert bolt 311 protruding from the tip of the thermal bridge interconnection bolt 31 is inserted into the first wall- And is fastened to the molded outer insert nut 111. An insert nut 312 is insert-injected into the rear end of the thermal bridge interconnection bolt 31.

That is, the thermal bridge interconnection bolts 31 are made of a plastic material, and the insert bolts 311 are inserted into the front end portions of the bolts 31 and the insert nuts 312 are insert injection molded at the rear end portions thereof. Since the insert bolts 311 and the insert nuts 312 made of metal are insert-injected in a state where they are spaced apart from each other in the thermal bridge interconnection bolts 31 made of plastic, the insert bolts 311 and the insert nuts 312 are inserted between the insert bolts 311 and the insert nuts 312 The thermal bridging of the heat exchanger is certainly blocked. Also, if the first wall-embedded socket 11 is insert-injected with the inner insert nut 110 and the outer insert nut 111 being spaced apart from each other, the first wall-embedded socket 11 can reliably block the heat bridge once again at this portion.

The thermal bridge interconnection bolts 31 may have a length of, for example, 5 cm and may be connected in series by determining the number of the heat insulating panels 50 according to the thickness of the heat insulating panel 50 to be installed. For example, in the case of using a heat insulation panel of 15 cm, two thermal bridge interconnection bolts 31 may be connected in series to be embedded by 10 cm, and the connectors 33 may be inserted into the remaining 5 cm portions. If the heat insulating panel is 20 cm, three heat bridge interconnection bolts 31 may be connected in series and the connector 33 may be connected to the rear end thereof.

Since the nut face 316 is formed on the outer circumferential surface of the thermal bridge interconnection bolt, it can be fastened with a tool such as a spanner when it is fastened to another member.

On the other hand, as shown in FIG. 4, on the side where the first wall-embedded sockets 11 and the heat bridge interconnection bolts 31 face each other, loosening preventing portions 113 and 313 having a sawtooth shape along the circumference around the central axis in the longitudinal direction, Respectively. Therefore, after the thermal bridge interconnection bolts are screwed into the first wall-embedded sockets, the heat bridge interconnection bolts are prevented from being unraveled again. This is to prevent the loosening of the connection part that may occur instead of reliably blocking the thermal bridge through the multi-stage connection structure.

This release preventing portion 314 is also formed at the rear end of the thermal bridge interconnection bolt 31. Therefore, as shown in FIG. 5, the loosening phenomenon between the thermal bridge interconnection bolts 31 connected in series can also be blocked. Particularly, since the thermal bridge interconnection bolt itself is made of plastic, its internal fastening structure is a bolt-nut of metal. Therefore, when the fastening structure is strongly tightened in order to prevent loosening, The bolt itself may be damaged. However, according to the present invention, it is possible to prevent the loosening phenomenon even if the bolt-nut fastening structure of the metal is not tightened too much by providing the loosening preventing structure on these fastening portions. Therefore, The loosening phenomenon can be solved.

A connector 33 is connected to the rear end of the thermal bridge interconnection bolts 31 connected in series. Since the connector has the protrusion 332 on the inner side of the connector plate 331 as shown in Fig. 8, rotation of the protrusion is prevented when the protrusion is fitted to the heat insulation panel. Therefore, it is not necessary to further form a loosening preventing structure at the tip of the connector.

The connector connecting bolt 35 is inserted from the rear end of the connector 33 and the bolt formed at the tip of the connector connecting bolt 35 is fastened to the rear end of the heat bridge interrupting connecting bolt 31. Accordingly, the connector 33 is fixed to the thermal bridge interconnection bolt 31 as the connector connecting bolt 35 is fastened.

A soft rubber or plastic finishing cap 371 is fitted to the head of the connector connecting bolt 35 inserted into the internal space of the connector 33. The finishing cap 371 has a hexagonal concave portion corresponding to the hexagonal head of the connector connecting bolt, and is fitted into the connector connecting bolt 35 and integrated in the rotational direction. Since the outer circumferential surface of the finishing cap 371 is tightly pressed against the hole of the connector 33, the finishing cap 371 is also integrated with the connector 33 in the rotating direction. Therefore, the connector connecting bolt 35 can also be prevented from being loosened against the thermal bridge interconnection bolt 31.

The finishing cap includes a finishing cap 372 in the form of a bolt hole and a finishing cap 371 in the form of a hole which is optional depending on whether additional bolting is required in the head portion of the connector connecting bolt 35 .

Meanwhile, the second wall-embedded socket 12 may be insert injection-molded with the outer insert nut 121 in a state spaced apart from the inner insert nut 120. As shown in FIG. 6, the inner wall guide bar 23 may be temporarily fastened to the outer insert nut 121. The inner wall guide bar 23 has a shape in which the rear end thereof is thin and gradually gets thicker toward the front end, and the insertion of the inner wall panel 60 can be guided through the thus formed rear end.

A socket inserting hole 611 is formed in the inner wall panel 60 at a position corresponding to the position of the second wall inserting socket 12 so that the position of the plurality of second wall inserting sockets 12 And the positions of the plurality of socket inserting holes 611 of the inner wall panel 60 may be difficult to match at the same time. Accordingly, the present invention is characterized in that after temporarily fastening the inner wall surface guide bar 23 to the second wall embedding socket 12, the inner wall panel 23 is temporarily fastened to the thin rear end portion of the inner wall surface guide bar, The socket inserting hole 611 of the socket 60 is inserted. After inserting the inner wall panel 60 into the inner wall surface guide bar 23 as described above, the inner wall surface guide bar 23 exposed to the outside through the socket inserting hole 611 of the inner wall panel 60 is removed, The panel member fixing bolt 24 can be fastened to the second wall embedding socket 12 to fix the inner wall panel 60 to the second wall embedding socket 12.

The inner wall surface socket 22 can be embedded in the socket inserting hole 611 of the inner wall panel 60. The inner wall socket 22 is formed with a projection 223 in the direction toward the second wall embedding socket 12 and a long hole 123 may be formed in the surface of the second wall embedding socket 12 facing the second wall embedding socket 12 have. The inner surface of the inner wall socket 22 is formed with a nut surface having an inner diameter larger than that of the outer insert nut 121 buried in the second wall embedding socket 12.

The nut surface formed on the inner periphery of the inner wall socket 22 is used when the inner wall panel 60 needs to be removed from the concrete wall C after the concrete wall C is completed. As shown in FIG. 52, the outer diameter of the outer insert nut 121 of the second wall-embedded sockets 12 is larger than the inner diameter of the insert nut 121 and has a diameter corresponding to the nut surface formed on the inner periphery of the inner wall surface socket 22 When the bolt-shaped member E is continuously rotated while being inserted into the inner wall surface socket 22, the inner wall surface socket 22 is taken off the concrete wall C by the bolt-shaped member E. The protrusion 223 and the slot 123 are interdigitated with each other so that the inner wall surface 22 of the inner wall panel 60 is separated from the inner wall panel 60 at the moment when the inner wall panel 60 is initially separated from the concrete wall C, It prevents turning. Since the inner wall panel 22 is configured to easily disengage the inner wall panel 60 from the concrete wall C, the inner wall panel 60 can be easily removed from the inner wall panel 60 if it is not necessary to separate the inner wall panel 60 from the concrete wall C. [ 22) can be omitted.

The connector connecting bolt 35 is fastened to the thermal bridge interconnection bolt 31 to fix the heat insulating panel 50 to the first wall embedding socket 11 and the panel member fixing bolt 24 is fastened After the inner wall panel 60 is fixed to the second wall embedding socket 12, the installation material is installed. This will be described below with reference to FIGS. 10 to 12. FIG.

10 is a side sectional view showing a state in which a formwork and a building material are applied to an outer wall of a building using a supporting structure of an insulating panel and an inner wall panel used in a heat insulating system, And FIG. 12 is a perspective view of a construction material used in the wall of the present invention. FIG.

10, since the connector 33 and the connector connecting bolt 35 are connected to the first wall embedding socket 11 via the thermal bridge interconnection bolts 31, the heat insulating panel 50 is fixed, And the inner wall panel 60 is fixed by connecting the panel member fixing bolt 24 to the second wall embedding socket 12.

As shown in the figure, a horizontal reinforcing bar 72 is placed on the wall embedding bar 10 and a horizontal reinforcing bar 72 is fixed to the vertical reinforcing bars 72, (71) are connected. Since the horizontal reinforcing bar is mounted on the wall buried bar, the horizontal reinforcing bar is at least spaced apart from the outer surface of the concrete wall by the length of the first and second wall embedding sockets, so that the thickness for the concrete covering to the reinforcing bars can be easily secured .

The mounting members 41 and 42 can be made of a synthetic resin such as PC or ABS for light weight, and the cross section thereof is a "C" First, as shown in the state in which the panel member fixing bolt 24 is positioned on the "C" shaped portion by vertically setting the mounting member 41, the mounting member fixing bolt 26 is fixed to the head of the panel member fixing bolt 24 To fix the installation material (41) vertically on the inner wall panel (60). Next, as shown in the state in which the mounting member 42 is laid horizontally and the mounting member fixing bolt 26 is positioned on the "C" seat, the mounting member fixing bolt 28 is fixed to the head portion of the mounting member fixing bolt 26 To fix the mounting member 42 horizontally on the mounting member 41. As shown in Fig. 12 is installed on the mounting member 42 to support the load. The installation material 43 has a turnbuckle and can be adjusted in length, and its upper end can be fixed to the construction material 42 and the lower end can be fixed on the foundation concrete.

The installation method of the above-described construction can be applied to the side of the heat insulating panel 50 as it is. 5, since the surface of the heat insulating panel 50 is finished by the connector plate 331 as shown in FIG. 5, the panel member fixing bolt 24 is fitted to the rear end of the connector connecting bolt 35 It is possible to apply the above-described installation method. When the specifications of the mounting members 41 and 42 are matched with the specifications of the fixing bolts 26 and 28, it is possible to apply the mounting material without distinguishing between the inner wall surface and the outer wall surface.

Fig. 11 is a view showing an installation form of an inner wall not contacting with the outside of the building. That is, since it is not necessary to install the heat insulating panel on both sides of the inner wall, the structure of the inner wall panel 60 shown on the right side of FIG. 10 is applied to both sides. This also applies to the method of installing the installation.

As described above, after the installation of the installation is completed, the wall can be cured by pouring concrete. After curing the wall, the panel member fixing bolts 24, the fixing members 26, 28, and the mounting members 41, 42, 43 are removed. In this state, as shown in FIG. 13, which is a partial perspective view showing a process of installing an angle in a connector exposed to the outside of the insulating panel of the present invention, the connector plate 331 exposed to the outside of the heat insulating panel 50 To fasten the angle 38, the closing bolt 39 can be fastened to the connector connecting bolt 35 with an angle interposed therebetween. The finishing bolt 39 may be formed of a plastic material into which an insert bolt 391 made of metal is insert-injected. According to this construction, the threaded portion of the insert bolt 391 directly connected to the connector connecting bolt 35 made of metal is cut off from the direct contact with the outside air by the plastic material portion of the finishing cap 372 and the finishing bolt 39, It has a thermal bridge blocking effect. As will be described later, when the dry finishing is performed, the finish panel can be simply placed on the heat insulating panel and the piece nails can be fixed to the connector plate 331.

Hereinafter, the structure of the heat insulating panel used in the present invention will be described.

Fig. 14 is a rear view of a part of the heat insulating panel of the present invention, Fig. 15 is a partial perspective view of the first embodiment of the heat insulating panel of the present invention, Fig. 16 is a partial plan view And Fig. 17 is a view showing an example of the lamination method of the heat insulating panel of the present invention.

Referring to FIG. 14, on the heat insulating panel of the present invention, the above-described thermal bridging connection bolt 31 and a perforation 501 for fitting the connector 33 are formed on the upper, lower, left, and right sides.

Referring to FIG. 15, the heat insulating panel 50 of the present invention is formed by stacking the XPS 51 and the refractory panel 52. The XPS is in contact with the concrete wall C side, and the refractory panel 52 is installed in the outside air side. The refractory panel 52 is laminated on the outside in order to compensate for the disadvantages of the organic insulation material such as XPS which is relatively low in fire resistance. The refractory panel may be in the form of a pearlite (thermal conductivity: 0.05 W / mk) having flame resistance and heat insulation combined. (For example, a magnesium board, a CRC board, or the like) for protecting the pearlite is attached to the outer side of the refractory panel 52 (not shown).

On the side surface of the heat insulating panel 50, grooves 53 are formed in the vertical direction as shown in FIG. These grooves 53 are connected to each other when the side surfaces of the two insulating panels 50 face each other, and the connecting pin 54 is half-fitted therein as shown in the figure so that the adjacent two insulating panels 50 can be connected .

Referring to FIG. 16, it is also possible to fix the heat insulating panel 50 by inserting the connecting pins 54 into the grooves formed at the two adjacent step portions with the stepped portions as shown in the heat insulating panel. The stepped portion of the heat insulating panel can be formed by stacking the two panels so that the steps are different from each other and then fitting or bonding the engaging member 55 as shown in Fig.

It goes without saying that the structure of the heat insulating panel need not necessarily be limited to the structure described above.

Hereinafter, the structure of the inner wall panel used in the present invention will be described.

FIG. 18 is a partial perspective view of an embodiment of the inner wall panel of the present invention, FIG. 19 is a front view showing a part of the inner wall panel of the present invention, and FIG. 20 is a side sectional view of the inner wall panel and the concrete wall of the present invention .

The inner wall panel 60 is formed by laminating a fabric 62 on the inner surface of the inorganic panel 61. The fabric 62 is brought into contact with the concrete wall. In addition, a groove 63 is formed around the side surface of the inorganic panel 61 so that the wall panel 60 can be connected to each other by interposing the connecting pin 64 in the groove 63 of the adjacent two inner wall panel Do. The fabric functions to discharge only the excess water to the outside and to prevent the cement paste other than water from escaping in order to increase the fluidity of the concrete in aggregate, sand, cement and water used in concrete formulations.

The strength of concrete is determined by curing conditions, water and cement ratio, air content and mixing time. Among them, water and cement ratio are less than 30% including hydration and binding water and gel, A surplus of 10 to 20% is always generated. These surplus water is present in the concrete, and generates voids along with evaporation of surplus water, which causes water tightness, durability, strength and various durability of the structure. Particularly, in the case of a structure with improved airtightness such as a passive house, the surplus water is an important factor that causes mold and condensation by increasing the humidity of the room for two years after completion. In order to improve the structural strength by eliminating the risk and enhancing the watertightness of the surface layer of the wall, the inner wall panel is formed in the form of a perforated panel.

19 and 20, in addition to the socket inserting hole 611 facing the second wall embedding socket 12, a plurality of the hole pipes 612 are formed regularly in the inner wall panel 60 as shown in FIG. can do. The diameter of the large diameter portion may be about 5 to 10 mm, and the diameter of the small diameter portion may be about 2 to 5 mm. The diameter of the large diameter portion may be about 5 to 10 mm, and the diameter of the small diameter portion may be about 2 to 5 mm. More preferably, the diameter of the small diameter portion may be 3 mm.

Hereinafter, various other structures for supporting the heat insulating panel 50 and the inner wall panel 60 will be described.

Fig. 21 is a partial perspective view showing a state in which a heat insulating panel, an inner wall panel, a reinforcing bar, and a supporting structure thereof are provided on a foundation concrete, Fig. 22 is a view showing a connecting bracket of the present invention, 24 is a view showing a state in which a corner member is provided at the corner of the heat insulating panel of the present invention, FIG. 25 is a view showing the corner member shown in FIG. 24, and FIG. 26 Is an illustration showing the inner and outer corner members used in the inner wall panel.

21, when the inner wall panel 60 is placed on the foundation concrete, corresponding to the fact that the foundation concrete does not form an ideal flat surface, the inner wall panel 60 is made parallel to the base concrete 60 And a leveling device 81 for enabling installation is applicable. The leveling device 81 has a surface attached to the inner wall panel 60 through a piece nail 83 and a horizontal surface in the form of a two-step plate formed perpendicular to the adhering surface, and the adjusting bolt 82 ). That is, when the leveling device 81 is attached to the lower end of the inner wall panel 60 and the adjustment bolt 82 is adjusted to correspond to the bent shape of the foundation concrete, (60) can be installed accurately.

21 and 22, at the lower end of the two neighboring inner wall panels 60, a connection bracket of a "" -shaped shape formed upward toward the opening portion so that the height of the adjacent two inner wall panels can be accurately aligned, 85 are installed. The height of the adjacent two inner wall panels 60 can be exactly matched if the lower ends of the two inner wall panels are partially fitted to the connecting bracket 85 and fixed using the nail 86. [

21 and 23, since the lower end of the inner wall panel 60 forms a horizontal line, and the foundation concrete forms an irregular surface with a curvature, the gap between the lower end of the inner wall panel 60 and the foundation concrete surface Distances are also irregular. A diaphragm 88 is provided at the gap portion. The diaphragm 88 includes a vertical plate 881 attached to the inner surface of the inner wall panel 60 through an adhesive surface 884 such as a double-sided tape, a bellows 883 connected to the bottom of the vertical plate, And a horizontal plate 882 extending in the horizontal direction at a lower end of the bellows 883. Each of these parts may be formed by extrusion molding along the longitudinal direction with the same material, or may be formed by attaching a separate member. As shown in FIG. 23, it is preferable that the bellows 883 is thin and wrinkled so as to be stretchable, and the horizontal plate 882 has a thickness enough to withstand a concrete pail. The purpose of installing the water resistance plate is to prevent the cement paste used in the concrete mixture from excessively escaping through the gap between the bottom of the inner wall panel 60 and the foundation concrete due to self weight together with the surplus water.

Referring to FIGS. 24 and 25, a corner portion may be formed in the heat insulating panel 50 according to the shape of the outer wall, and the corner portion may have a reduced strength. Therefore, in the present invention, the corners of the heat insulating panel can be reinforced by providing corner members 56 that can be used for both the out corner and the incinerator. Of course, the corner member 56 may be made of a plastic material. The corner member 56 is formed at the center thereof with a bending groove 57 having a thickness smaller than that of the other portions. The corner member 56 can be folded on the basis of the bending groove 57. A fitting projection 58 protrudes from both ends of one side of the corner member 56. In the case where the fitting protrusions bend in the direction in which the fitting protrusions face each other in the bending groove, they can be fastened to the outward corner or out corner of the heat insulating panel. When the fitting protrusions bend in the direction in which the fitting protrusions face each other, As shown in Fig.

Fig. 26 shows a structure in which the corner portions of the inner wall panel 60 are connected. In the inner panel of the inner wall panel 60, an inner member 66 is fitted as shown. That is to say the corner portion 661 of the inner wall panel 60 is positioned at the corner of the inner wall panel 60 facing the inner wall of the inner wall panel 60 and then the fitting protrusion 663 is inserted into the groove 63 of the inner wall panel 60 So that the surface contact portion 662 comes into contact with the inner wall panel 60 surface. The surface contact portion 662 is in contact with the surface of the inner wall panel 60 that is in contact with the concrete wall in both surfaces.

The outboard corner of the inner wall panel 60 is fitted with an outcorner member 68 as shown. The corner portions 681 of the outcorner member 68 are positioned at the corner portions of the two outward corner inner wall panels 60 facing each other and then the fitting protrusions 683 are inserted into the grooves 63 of the inner wall panel 60, And the surface contact portion 682 is brought into contact with the inner wall panel 60 surface. The surface contact portion 682 is in contact with the surface of the inner wall panel 60 which is in contact with the concrete wall in both surfaces.

Hereinafter, embodiments in which the concrete wall is cured and the exterior wall is closed after removing the above-mentioned construction material will be described.

FIG. 27 is a side sectional view showing a state in which the outer wall of the wall constructed by applying the adiabatic system of the present invention is finished with a wood panel or a zinc panel. FIG. 28 is a cross- And FIG. 29 is a partial perspective view showing a step of installing an angle to finish the marble on the outer wall of the wall constructed by applying the adiabatic system of the present invention. FIG. 30 is a side view showing the adiabatic system of the present invention And FIG. 31 is a side sectional view showing a state in which the outer wall of the wall constructed by applying the insulation system of the present invention is closed.

27 shows a state in which the wood panel W is fixed on the plate 331 of the connector exposed on the heat insulating panel 50 of the outer wall with the piece nails N. As shown in Fig. The plate 331 is in a quadrant display as shown in FIG. 29, and the wood panels W adjacent to the divided portions can be respectively positioned and fixed through the piece nails. It may also be finished with a zinc panel (Z). In this dry finishing, the present invention can fix the finishing panel to the outer wall without much work.

28 shows a structure in which the angle 38 is fixed to the connector connecting bolt 35 by using the finishing bolt 39 and the marble D is closed at the angle. As shown in the figure, since the metal parts are isolated at three places by the thermal bridge interconnection bolts 31, it can be confirmed that the thermal bridge interception can be surely performed. In order to install the angle, the head portion of the connector connecting bolt 35 must be exposed to the outside, so that the finishing bolt 39 is fastened after fitting the finishing cap 372 with the hole as shown in FIG. Further, when it is not necessary to provide an angle for every connector 33 as shown in Fig. 30, the connector 33 to which the angle is not set is closed with the finishing cap 371 having no hole.

FIG. 31 shows a masonry finish with a brick B, in which case the mover 38 can be fixed to the outer wall using the angle 38 and the mating angle 381.

As described above, according to the present invention, various finishes can be easily and easily applied.

Hereinafter, a construction method using the adiabatic system of the present invention will be described.

First, a terahertz S01 is performed as shown in Fig.

Next, as shown in FIG. 33, the rubble is prepared (S02). It is preferable that the rubble is about 500 mm high.

Next, as shown in FIG. 34, the heat insulating material is placed on the rubble (S03). The insulation is 100 mm thick, and the two stages are offset from each other as shown. The second-stage heat insulating material is stacked so as to have an area smaller than that of the first-stage heat insulating material (see FIG. 37).

Next, as shown in Fig. 35, the heat insulating block is piled up around the bottom insulating material (S04). 37, the heat insulating block is stacked on the bottom insulating material of the first end, the inner surface of the heat insulating block is brought into contact with the side of the bottom insulating material of the second end, and the bottom insulating material of the second end is stacked again on the outer surface thereof . At this time, the bottom of the insulation block is located lower than the horizon, and the upper end of the insulation block protrudes higher than the horizon. And the space between the outer side of the heat insulating block and the horizon plane is filled.

Next, as shown in FIG. 36, the foundation concrete is laid and cured in a space formed by the bottom insulating material and the heat insulating block (S05).

After the foundation concrete is cured, a wall corner is constructed as shown in FIG. 38 (S06). The corner of the wall is a form in which two "brackets" are braced back and the openings of the "C" shape are at 90 degrees to each other. The heat insulating panel 50 is inserted into the " C "-shaped opening.

Next, as shown in Fig. 39, a heat insulating panel is constructed (S07). The heat insulating panel can be mounted on the upper part of the heat insulating block (see Fig. 21 and the like). At this time, the refractory panel 52 portion of the heat insulating panel 50 is exposed to the outside, the XPS 51 portion is disposed to face inward, and the adjacent heat insulating panel is connected to the groove 53 with the connecting pin 54 interposed therebetween , The heat brink connection bolts 31 are inserted into the perforations 501 of the heat insulating panel so as to correspond to the thickness of the heat insulating panel, which is fastened to the first wall embedded sockets 11 disposed on the inner surface of the heat insulating panel. Then, the connector 33 is fitted from the outside of the heat insulating panel and the connector connecting bolt 35 is connected to the rear end of the thermal bridge interconnection bolt 31. One end of the wall embedding bar 10 is connected to the inner end of the first wall embedding socket 11 and the second wall embedding socket 12 is connected to the other end of the wall embedding bar 10 again. Further, the corner member 56 is appropriately bent to be provided on the inner and outer corners of the heat insulating panel (see FIGS. 24 and 25, etc.).

Then, as shown in FIG. 40, horizontal reinforcing bars and vertical reinforcing bars are laid (S08). The horizontal reinforcing bars 72 are fixed on the wall embedding bars and the vertical reinforcing bars 71 are fixed to the horizontal reinforcing bars or the wall embedding bars.

Then, the inner wall panel 60 is installed as shown in FIG. 41 (S09). To match the inner wall panel 60 to the second wall embedding socket 12, the inner wall surface guide bar 23 is first temporarily connected to the outer end of the second wall embedding socket 12, The second wall-embedded sockets 12 and the inner wall panel 60 are installed in such a manner as to align the socket inserting holes 611 of the inner wall panel 60 (see FIGS. 6 and 7, 23 can be removed and the panel member fixing bolt 24 can be installed to fix the inner wall panel 60. At this time, the inner wall panels can be connected laterally by connecting the connection pins 64 to the grooves 63 of the adjacent two inner wall panels 60. A connection bracket 85 is provided at the lower end of the two inner wall panels 60 So that the height of the two adjacent inner wall panels can be aligned. A leveling device 81 is provided at the lower end of the inner wall panel 60 to align the inner wall panel 60 with respect to the foundation concrete and the vertical plate 881 of the waterproof plate 88 is attached to the inner surface of the inner wall panel And the water level plate 882 is made to protrude outward through a gap between the inner wall panel and the foundation concrete and the concrete pail 882 is fixed to the foundation concrete do.

The above-described thermal insulation panel construction (S07), reinforcing bar construction (S08) and inner wall construction (S09) do not necessarily have to proceed in the order described above, and the order may be different according to the condition of the site and the convenience of the operator.

Next, a door frame and a window frame are constructed as shown in FIG. 42 (S10).

Next, as shown in FIG. 43, the first set material 41 is installed in the direction perpendicular to the inner wall surface (S11), and the second set material 42 is placed in the horizontal direction on the first set material Install it. The panel member fixing bolt 24 is fastened to the panel member fixing bolt 24 from the rear end of the installation member 41 in a state where the panel member fixing bolt 24 is positioned in the opening of the first installation member 41, The first fixing member is fixed and the fixing member fixing bolt 28 is fixed to the fixing member fixing bolt 26 from the rear end of the fixing member 42 in a state where the fixing member fixing bolt 26 is positioned in the opening of the second fixing member 42 And the second substrate is fixed in the horizontal direction. If the horizontal second structural members are shorter than the wall, a plurality of the construction members can be used by being connected to each other in the longitudinal direction, and the brackets can be reinforced by attaching the brackets to the connection portions. The second substrate (42) is provided with a third substrate (43) in the form of a strut. The top of the third tile is fixed to the second tile and the bottom is fixed to the foundation concrete.

As shown in FIG. 45, the first installation member 41 is installed in the vertical direction on the outer wall surface (S13), and the second installation member 42 is installed in the horizontal direction as shown in FIG. 46 (S14).

The construction of the temporary wall on the inner wall surface and the construction of the temporary wall on the outer wall surface do not necessarily have to proceed in the order described above, and the order may be different according to the condition of the site and the convenience of the operator.

Next, as shown in FIG. 47, the wall is cured by placing concrete in a space formed by the heat insulating panel 50 and the inner wall panel 60 (S15).

When the wall curing is completed, the above-mentioned construction material is removed as shown in FIG. 51 (S16), and a finish material is applied (S17).

When a heavy weight finish material is to be applied, as shown in FIG. 48, the finishing bolt 39 is inserted by inserting a finishing cap 372 having a hole and installing the angle 38 and the finishing bolt 39. At this time, if there is a portion where the angle 38 and the finishing bolt 39 do not need to be provided as shown in FIG. 49, by inserting the finishing cap 371 having no hole, the outside air is supplied to the connector connecting bolt (35). It is possible to apply the finishing material D by appropriately distributing the portion where the angle cap 38 and the finishing bolt 39 are provided and the portion where the finishing cap 371 is sandwiched by fitting the finishing cap 372 as shown in FIG.

Also, when a lightweight finish material is to be applied, the finish panel W can be directly fixed to the connector plate 331 with a piece nip N as shown in FIG.

On the other hand, although the inner wall surface can be finished by directly wrapping on the inner wall panel, the inner wall panel 60 may be removed if necessary. 52 is a perspective view showing a step of removing the inner wall panel of the construction method using the adiabatic system according to the present invention. The inner wall panel is a member having a screw thread having a diameter corresponding to the thread formed on the inner surface of the inner wall socket 22 E) is inserted into the concrete wall C and the ends thereof are supported and rotated by the concrete wall C, the inner wall panel 60 can be removed from the concrete wall.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the invention is not limited to the disclosed exemplary embodiments. It is obvious that a transformation can be made. Although the embodiments of the present invention have been described in detail above, the effects of the present invention are not explicitly described and described, but it is needless to say that the effects that can be predicted by the configurations should also be recognized.

10: Wall embedding bar
11: first wall embedding socket
110: Inner insert nut
111: outer insert nut
113: Release preventing portion
12: second wall embedding socket
120: Inner insert nut
121: outer insert nut
123: Slots
22: My wall socket
223: projection
23: My wall guide bar
24: Panel member fixing bolt
26: Fixing bolt (intermediate)
28: Mounting bolt (finish)
31: Thermal bridge interconnection bolts
311: Insert Bolt
312: Insert nut
313:
314:
316: Nut cotton
33: Connector
331: Connector plate
332: protrusion
35: Connector connection bolt
371: Finishing cap (no hole)
372: Finishing cap (with holes)
38: Angle
381: Applied Angle
39: Finishing bolt
391: Insert Bolt
41: Construction material
42: Construction
43: Construction material
50: Insulating panel
501: Thousand studies
51: XPS
52: Refractory panel
53: Home
54: connecting pin
55:
56: Corner member
57: Bending groove
58: insertion projection
60: My wall panel
61: Mineral panels
611: socket inserting hole
612:
62: Fabric
63: Home
64: connecting pin
66: Inner member
661:
662:
663: Insert projection
68: out corner member
681:
682:
683: insert projection
71: vertical reinforcement
72: horizontal reinforcement
81: Leveler
82: Adjustment bolt
83: Pisse nail
85: Connection bracket
86: Pisse nail
88:
881: Vertical plates
882: Horizontal plate
883: Bellows
884: Adhesive face
S01:
S02: Mud compaction
S03: Insulation laying
S04: Building insulation block for foundation concrete
S05: Foundation concrete pouring
S06: Construction of wall corners
S07: Insulation panel construction
S08: Reinforcement construction
S09: Construction of inner wall panel
S10: Construction of door frames and window frames
S11: Construction of inner wall first building
S12: Construction of inner wall second building
S13: Construction of outer wall first building
S14: Construction of second exterior wall
S15: Concrete pouring
S16: Remove the installation
S17: Finishing material construction
B: Brick
C: Concrete wall
D: Marble
E: Bolt-shaped member
N: Pisse nail
W: Wood panel
Z: The zinc panel

Claims (15)

1. An adiabatic system for constructing a concrete wall having first and second surfaces facing each other,
A heat insulating panel (50) installed at a position corresponding to the first surface;
An inner wall panel (60) installed at a position corresponding to the second surface;
A first wall-embedded socket 11 provided on an inner surface side of the heat insulating panel 50;
A second wall embedding socket (12) provided on an inner surface side of the inner wall panel (60);
A wall embedding bar (10) having opposite ends connected to the first wall embedding socket (11) and the second wall embedding socket (12), respectively;
An insert bolt 311 is provided at one end and an insert nut 312 is provided at the other end of the insert bolt 311. The insert bolt and the insert nut are insert injection molded into a synthetic resin having a thermal conductivity lower than that of the insert bolt and the insert nut, The heat insulating bridge connecting bolts 31 are embedded in the heat insulating panel 50 and connected to the first wall embedding socket 11 so as to correspond to the thickness of the heat insulating panel 50, A thermal bridge interconnection bolt (31) that remains connected to the first wall embedded socket (11) in a state of being embedded in the heat insulating panel (50) even after the construction of the concrete wall;
A connector 33 fitted to the heat insulating panel at the outer surface side of the heat insulating panel 50 and having a connector plate 331 provided at the rear thereof for supporting the heat insulating panel 50; And
A connector 33 fitted to the outer surface of the heat insulating panel 50 is fixed to the thermal bridge interconnection bolt 31 and is buried inside the connector 33 to the outer end of the connector 33. After the concrete wall is constructed, And a connector connecting bolt (35) for fixing the connector (33) to the thermal bridging connecting bolt (31) in a state of being embedded in the thermal bridging connecting bolt (31)
Wherein an angle (38) for providing a finish material is disposed outside the connector connecting bolt (35) and a closing bolt (39) is connected to the head portion of the connector connecting bolt (35).
The method according to claim 1,
The at least one of the surfaces of the first wall-embedded sockets 11 and the heat-bridge interconnection bolts 31 facing each other or the surfaces of the two thermal-bridge interconnection bolts 31 connected in series is provided with the anti- Is formed,
Wherein the unlocking portion has a saw-tooth shape arranged along the circumference in a circumferential direction about a rotation axis.
The method according to claim 1,
The inner wall surface guide bar 23 is temporarily installed outside the second wall embedding socket 12 and the socket inserting hole 611 of the inner wall panel 60 is guided to the inner wall surface guide bar 23, And a wall panel (60) is installed on the second side.
The method according to claim 1,
A panel member fixing bolt (24) is fitted and coupled to the outside of the connector connecting bolt (35) and the outside of the second wall embedding socket (12)
(41, 42) is fixed to the outside of the panel member fixing bolt (24).
The method according to claim 1,
(W) to the connector plate (331) instead of the angle (38) and the finishing bolt (39).
The method according to claim 1,
The heat insulating panel 50 is a structure in which the XPS 51 and the refractory panel 52 are laminated and the refractory panel 52 is located outside the XPS 51 with respect to the concrete wall,
A perforation 501 is formed on the heat insulating panel 50 in the same direction as the stacking direction at regular intervals to insert the heat bridge interconnection bolts 31,
A groove 53 is formed in the end portion of the heat insulating panel so as to face each other when the two adiabatic panels are brought into contact with each other so that the connecting pin 54 is inserted into the groove 53, Wherein the heat insulation system comprises:
The method according to claim 1,
The inner wall panel 60 is a structure in which an inorganic panel 61 and a fabric 62 are laminated and the fabric 62 is positioned more inside than the inorganic panel 61 with respect to the concrete wall,
A socket inserting hole 611 is formed on the inner wall panel in the same direction as the stacking direction at regular intervals,
A groove 63 is formed in the end portion of the inner wall panel so as to face each other when the two inner wall panels are in contact with each other so that the connection pin 64 is inserted into the groove 63, Is connected to the heat exchanger.
The method according to claim 1,
The inner wall panel 60 is formed with a plurality of holes 612,
The perforated pipe 612 is in the form of a funnel whose width decreases as it moves away from the concrete wall,
Wherein the diameter of the large diameter portion of the pipe tube (612) is 5 to 10 mm, and the diameter of the small diameter portion of the pipe tube is 2 to 5 mm.
The method according to claim 1,
A corner member (56) is provided at a corner of the heat insulating panel (50)
Bending grooves 57 are formed at the center of the corner member 56 and fitting protrusions 58 protrude from both ends of one side of the corner member 56 so that the fitting protrusions Wherein the heat insulating panel is fastenable to an outward corner of the heat insulating panel when bending in a direction facing the heat insulating panel and is fastened to an inward corner of the heat insulating panel when the fitting protrusions are bent in a direction in which the fitting projections face each other, .
The method according to claim 1,
Characterized in that the lower ends of the two adjacent inner wall panels (60) are inserted and fixed in a "C" shaped connecting bracket (85) opening upward.
The method according to claim 1,
A water resistance plate 88 is provided at the lower end of the inner wall panel 60,
The diaphragm 88 includes a vertical plate 881 attached to the inner surface of the inner wall panel 60, a bell-shaped portion 883 formed at a lower portion of the vertical plate, And a floor horizontal plate (882) extending in the direction of the bottom wall and contacting the foundation concrete.
A construction method for applying the adiabatic system according to any one of claims 1 to 11,
A step of placing and curing the foundation concrete (S01 to S05);
(S06 to S10) of installing the heat insulating panel, the reinforcing bars and the inner wall panel on the foundation concrete;
(S11 to S14) of installing a temporary material on the heat insulating panel and the inner wall panel;
(S15) placing and curing concrete in a wall space formed by the heat insulating panel and the inner wall panel;
Removing the temporary material after the concrete curing of the wall (S16); And
And a step (S17) of installing a finishing material after the removal of the installation material.
The method of claim 12,
In the step of pouring and curing the foundation concrete,
A tearing step S01;
A step (S02) of raising a rubble to the terrarium;
(Step S03) of placing the heat insulating material on the rubble;
(S04) of stacking the heat insulating block for foundation concrete on the upper surface rim of the heat insulating material; And
(S05) of forming a foundation bottom surface by placing concrete in a space formed by the heat insulating material and the heat insulating block.
The method of claim 12,
The step of installing the heat insulating panel, the reinforcing bars, and the inner wall panel on the foundation concrete comprises:
(50) and an inner wall panel (60) are provided on the first surface and the second surface, respectively. The inner wall surface of the first wall is connected to the inner surface of the adiabatic panel and the inner wall surface of the inner wall panel, The socket 11 and the second wall embedding socket 12 are installed and the tip of the thermal bridge interconnection bolt 31 embedded in the heat insulating panel 50 is connected to the first wall embedding socket 11, The connector 33 is disposed outside the heat insulating panel 50 and the connector connecting bolt 35 is fastened to the rear end of the heat bridge interconnection bolt 31 to fix the connector 33. [ A method of constructing an insulation system.
The method of claim 12,
The step of installing the heat insulating panel, the reinforcing bars, and the inner wall panel on the foundation concrete comprises:
The inner wall surface guide bar 23 is temporarily installed in the second wall embedding socket 12 provided on the second surface and the socket inserting hole 611 of the inner wall panel 60 is inserted into the inner wall surface guide bar 23 The inner wall surface guide bar 23 is detached from the second wall embedding socket 12 and the panel member fixing bolt 24 is removed from the second wall embedding socket 12 after the inner wall panel 60 is positioned adjacent to the second wall embedding socket 12 ) To the second wall embedding socket (12) to secure the inner wall panel (60).

Images