KR102675299B1 - External insulation finish construction method for buildings using dry construction method - Google Patents

Abstract

The present invention relates to a construction method for external insulation of a building using a dry construction method, and more specifically, to the external insulation of a building using a dry construction method that can improve insulation and fire resistance by attaching an insulation sheet made of aluminum to the exterior wall of the building. It is about construction method.

Description

External insulation construction method for buildings using dry construction methods {EXTERNAL INSULATION FINISH CONSTRUCTION METHOD FOR BUILDINGS USING DRY CONSTRUCTION METHOD}

The present invention relates to a construction method for external insulation of a building using a dry construction method, and more specifically, to the external insulation of a building using a dry construction method that can improve insulation and fire resistance by attaching an insulation sheet made of aluminum to the exterior wall of the building. It is about construction method.

It is known that 35% of the total heat loss in buildings is heat loss through walls. In order to prevent heat loss through these walls, insulation construction is being carried out on the walls. Insulation construction can be divided into internal insulation method and external insulation method. The internal insulation method is relatively easy to construct and is economical, but it has the disadvantage of causing heat bridges and dew condensation in areas where insulation materials are connected. On the other hand, the external insulation method is more difficult to construct and increases construction costs compared to the internal insulation method, but it can reduce thermal bridges and condensation, which are problems with the internal insulation method, and improve thermal efficiency. Accordingly, there is a recent trend toward mostly construction using external insulation methods.

External insulation methods can be divided into wet methods and dry methods depending on the attachment method of the insulation material and the installation method of the finishing material. In the wet method, the insulation material is attached to the exterior wall of the building using mortar and then finished using a liquid material. In the dry method, the insulation material is attached to the exterior wall using adhesive and fixing brackets, a metal frame is installed, and then metal/stone/cement panels or boards are installed using fixing brackets.

In the wet method, deformation occurs due to repeated external forces caused by strong winds or typhoons, which can cause cracks in the mortar that attaches the insulation to the exterior wall or deterioration of adhesion performance, causing problems such as the entire exterior wall insulation and finishing materials falling off. . Due to these problems, there is a recent trend of applying dry methods instead of wet methods for external insulation methods.

Meanwhile, organic insulation materials, which are widely used as exterior wall insulation, have excellent insulation performance but are vulnerable to fire. Compared to organic insulation materials, inorganic insulation materials such as glass wool and/or mineral wool, which have excellent fire performance, have been used, but due to limitations in construction and water resistance and moisture resistance, EPS (EPS) has been used to date. Expanded Polystyrene or Polyurethane insulation materials are widely used.

KR 10-2017-0065040 A, 2017. 06. 13. KR 10-1429057 B1, 2014. 08. 05. KR 10-1544921 B1, 2015. 08. 10. KR 10-2014-0141911 A, 2014. 12. 11.

Therefore, as frequent exterior wall fire accidents continue to occur and eventually lead to casualties, there is a trend toward restricting the use of organic insulation materials such as EPS insulation materials for exterior walls by changing them from the design stage of the building in order to improve social safety. .

In particular, as the thickness of the insulation material gradually increases in accordance with the policy of strengthening the insulation of buildings, the gap between the concrete wall and the underlying hardware structure has to be widened to install the insulation, so there is a lack of suitable methods to effectively install the finishing material. .

Therefore, the present invention was proposed to solve the conventional problems, and provides insulation properties almost equivalent to those of these insulation materials without using organic or inorganic insulation materials mainly used in the external insulation method of existing buildings, while providing fire resistance in the event of a fire. The purpose is to provide a construction method for external insulation of buildings using dry construction methods that can improve

The present invention according to an embodiment for achieving the above object includes a process of attaching first and second thermal insulation sheets to the exterior wall of a building; A process of installing an underlying hardware structure on the exterior wall of a building to which the first and second thermal insulation sheets are attached; A process of installing cement board on the underlying hardware structure; and a method for constructing external insulation of a building using a dry method, including the process of installing a finishing material on the outer surface of the cement board.

In addition, the first and second thermal insulation sheets may each include an aluminum sheet with an adhesive layer formed on one side, a metal block installed at the upper end of the aluminum sheet, and a magnetic block installed at the lower end of the aluminum sheet.

In addition, the process of attaching the first and second thermal insulation sheets to the exterior wall of the building includes attaching the first thermal insulation sheet to the exterior wall of the building; And the second heat insulation sheet is attached to the outer wall of the building, and the second heat insulation sheet is attached so that the metal block installed at the upper end of the second heat insulation sheet is attached to the magnetic block installed at the lower end of the first heat insulation sheet by magnetic force. It may include the process of attaching a thermal insulation sheet to the exterior wall of the building.

In addition, a plurality of metal blocks and magnet blocks of the first and second row insulation sheets are each installed at predetermined intervals, and an extension protruding upward is formed on the upper part of the first and second row insulation sheets, A groove is formed in the lower part of the first and second row insulation sheets, and when the second row insulation sheet is attached to the outer wall of the building, an extension formed on the upper part of the second row insulation sheet is used to insulate the first row insulation sheet. It can be inserted into the groove formed in the first row insulating sheet through between the magnetic blocks of the sheet.

In addition, a space is formed between the first and second row insulation sheets and the cement board, and the underlying hardware structure includes a plurality of supports supported by the first and second row insulation sheets, and the plurality of supports are Among them, a fire-fighting nozzle installation hole may be formed on the support supported on the upper outer surface of the first thermal insulation sheet, into which a fire-fighting nozzle for injecting fire extinguishing water into the space when a fire occurs is coupled.

As explained above, according to the method of constructing external insulation of a building using the dry method according to the present invention, the external insulation of the building is constructed using an insulation sheet containing an aluminum sheet, so that existing organic or inorganic insulation materials are not used. It is resistant to fire and can provide insulation performance that is almost equivalent to that of organic or inorganic insulation materials.

In addition, according to the external insulation construction method of a building using the dry method according to the present invention, metal blocks and magnetic blocks are installed at the upper and lower parts of the insulation sheet, and when attaching the insulation sheet to the external wall of the building, the magnetic block and By constructing the insulation sheets to be connected to each other through metal blocks, the property of the magnetic block that loses its magnetism as the temperature rises in the event of a fire is used to separate the connections between the insulation sheets to control the spread of the fire, and to prevent the spread of the fire by separating the separated insulation sheets. This can prevent fire from spreading throughout the building.

In addition, according to the external insulation construction method of a building using the dry method according to the present invention, a space is formed between the insulation sheet and the underlying hardware structure, and fire extinguishing water is supplied to the support supported on the upper part of the insulation sheet in the event of a fire. By forming a fire nozzle installation hole where the nozzle is installed, when a fire occurs, fire extinguishing water can be supplied to the space between the insulation sheet and the underlying hardware structure through the fire nozzle to extinguish the fire and prevent its spread.

According to the external insulation construction method of a building using a dry method according to the present invention, the external insulation of the building is constructed using an insulating sheet containing an aluminum sheet that is thinner than the existing EPS panel, thereby protecting the outer wall of the building and the underlying hardware structure. Because the spacing is not wide, it can provide the advantage of being able to install finishing materials more effectively compared to existing construction methods.

1 is a flowchart showing a method of external insulation construction of a building according to an embodiment of the present invention.
Figures 2 to 6 are drawings showing each construction process shown in Figure 1.
Figure 7 is a view showing a cross section of an insulation sheet according to an example of the present invention.
Figure 8 is a cross-sectional view of an insulation sheet according to another example of the present invention.
Figure 9 is a view showing a construction example of the insulation sheet shown in Figure 8.
Figure 10 is a diagram showing the shape of an adhesive layer according to an example of the present invention.
11 is a diagram showing the shape of an adhesive layer according to another example of the present invention.
Figure 12 is a view showing first and second thermal insulation sheets according to another example of the present invention.
Figure 13 is a cross-sectional view taken along the 'AA' cutting line shown in Figure 12.
Figure 14 is a cross-sectional view showing a construction example of a cement board according to an example of the present invention.
FIG. 15 is a view from above of the support of the underlying hardware structure shown in FIG. 14.

Hereinafter, the advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. Throughout this specification, like reference numerals refer to like elements. Additionally, when written as 'A and/or B', it may mean both A and B, or either A or B. Additionally, the size and shape of each component shown in each drawing may be excessive, but this is for convenience of explanation and is not intended to be limiting.

Figure 1 is a flow chart schematically showing the external insulation construction method of a building according to an embodiment of the present invention, and Figures 2 to 6 are drawings showing each construction process shown in Figure 1.

Referring to Figures 1 and 2, the insulation sheet 10 is attached to the outer wall 1 of the building. The insulation sheet 10 basically includes a sheet made of aluminum, and its configuration is as shown in FIG. 7.

Figure 7 is a diagram schematically showing a cross section of an insulation sheet according to an example of the present invention.

Referring to Figure 7, the insulation sheet 10 according to an example of the present invention is an adhesive sheet, and includes an aluminum sheet 11 and an adhesive layer 12 formed on one side of the aluminum sheet 11 (the side attached to the outer wall). Includes. Then, backing paper (not shown) is attached to protect the adhesive layer 12, and after the backing paper is separated, it is adhered to the outer wall 1 through the adhesive layer 12.

Figure 8 is a diagram schematically showing a cross section of an insulation sheet according to another example of the present invention.

Referring to Figure 8, the insulation sheet 20 according to another example of the present invention includes an aluminum sheet 21 and an adhesive layer 22, similar to the insulation sheet 10 shown in Figure 7. And a metal block 23 and a magnet block 24 are installed at the upper and lower ends of the aluminum sheet 21. At this time, the magnet block 24 can use a neodymium magnet with a low Curie temperature (Curie Point).

Figure 9 is a diagram schematically showing a construction example of the insulation sheet shown in Figure 8.

Referring to FIG. 9, insulation sheets 20 and 20' are attached to the exterior wall 1 of the building via adhesive layers 22 and 22'. Hereinafter, for convenience of explanation, the insulation sheet 20 attached to the uppermost part of the exterior wall 1 of the building will be referred to as a 'first row insulation sheet', and the insulation sheet 20 attached to the lower part of the first row insulation sheet 20 will be referred to as 'first row insulation sheet'. The insulation sheet 20' will be named 'second row insulation sheet'.

The number of insulation sheets attached to the exterior wall (1) of a building is determined depending on the height of the exterior wall (1) and the height (vertical length) of the insulation sheets. That is, depending on the height of the outer wall 1 and the height (vertical length) of the insulation sheet, 1 to N (where N is an integer) can be attached and constructed from 1 row to N rows. Figure 9 shows, as an example, a construction example of insulation sheets attached in two rows.

When explaining the construction method of the first and second thermal insulation sheets 20 and 20', first, the first thermal insulation sheet 20 is attached to the outer wall 1. Next, a second heat insulation sheet 20' is attached to the lower part. At this time, the second row insulation sheet 20' is constructed so that the metal block 23' of the second row insulation sheet 20' is attached to the magnetic block 24 of the first row insulation sheet 20 by magnetic force. do.

As shown in FIG. 9, when the first and second thermal insulation sheets 20 and 20' are installed, a fire occurs in the building and the surrounding temperature of the magnetic block 24 rises above the Curie temperature of the magnetic block 24. As it rises, the magnetism of the magnet block 24 is lost. In this way, when the magnetism of the magnet block 24 is lost, the metal block 23' of the second heat insulation sheet 20' attached to the magnet block 24 is separated from the magnet block 24 by magnetic force. , In this process, the second row insulation sheet 20' is separated from the first row insulation sheet 20. Also, when a fire occurs, the adhesive layer 22' of the second heat insulating sheet 20' melts due to heat. As a result, because the adhesive force is no longer maintained, the second thermal insulation sheet 20' separated from the first thermal insulation sheet 20 is separated from the outer wall 1 by gravity. Accordingly, if a fire occurs in the second row insulating sheet 20' or a fire that spreads to the second row insulating sheet 20' does not spread to the first row insulating sheet 20. That is, in the event of a fire, spread to insulation sheets arranged adjacently above and below can be prevented.

That is, in the embodiment of the present invention, when a fire occurs, the connection state (mutual through magnetic force) between the magnetic block 24 of the first heat insulation sheet 20 and the metal block 23' of the second heat insulation sheet 20' The fire spreads from the first row insulation sheet 20 to the second row insulation sheet 20' by separating the first row insulation sheet 20 and the second row insulation sheet 20'. Alternatively, fire can be prevented from spreading from the second row insulation sheet 20' to the first row insulation sheet 20'.

The magnets constituting the magnet block 24 lose their magnetism as their electron spin directions disperse above a certain temperature. The temperature at this time is called the Curie temperature. Therefore, if heat is applied above the Curie temperature of the magnet, it loses its magnetism. Considering that the temperature usually rises to 500-1000°C when a fire occurs, it is preferable to use a neodymium magnet with a relatively low Curie temperature for the magnet block 24, but is not limited to this.

Figure 10 is a diagram schematically showing the shape of an adhesive layer according to an example of the present invention, and Figure 11 is a diagram schematically showing the shape of an adhesive layer according to another example of the present invention.

10 and 11, in the first and second thermal insulation sheets 20 and 20', the adhesive layer 22 and 22' is not formed on the entire surface of the aluminum sheet 21 and 21', but on a portion thereof. It may only be formed sparsely. This is to ensure that the first and second thermal insulation sheets 20 and 20' can be easily separated from the outer wall 1 in the event of a fire. For example, the adhesive layers 22 and 22' may be formed in a dot shape or a straight structure, or may be formed in plural pieces in a diagonal structure.

Figure 12 is a view schematically showing the first and second row insulation sheets according to another example of the present invention, and is a view of the first and second row insulation sheets viewed from the front (front of the aluminum sheet).

Referring to Figure 12, in the first and second thermal insulation sheets (30, 30') according to another example of the present invention, metal blocks (33, 33') are formed at the upper and lower ends of the aluminum sheets (31, 31'). and a plurality of magnet blocks 34 and 34' are installed at predetermined intervals in the horizontal direction. Then, the metal blocks 33 and 33' and the magnetic blocks 34 and 34' are installed to align with each other vertically.

Figure 13 is a cross-sectional view schematically shown along the 'A-A' cutting line shown in Figure 12.

Referring to Figures 12 and 13, in a structure in which a plurality of metal blocks (33, 33') and magnet blocks (34, 34') are installed to be spaced apart at predetermined intervals, the metal blocks (33, 33') and the magnet blocks (33, 33') The insulation between 34 and 34') may be relatively weak. In order to solve this problem, the upper part of the aluminum sheet (31, 31') is extended between the metal blocks (33, 33') and the magnet blocks (34, 34'), so that the metal blocks (33, 33') and the magnet blocks (34) , 34', extension portions 31a and 31a' are formed to cover the area between the two. And, groove portions 31b and 31b' into which the extension portions 31a and 31a' are inserted are formed in the lower portions of the aluminum sheets 31 and 31'. For example, the extension portion 31a' of the second thermal insulation sheet 30' is inserted into the groove portion 31b of the first thermal insulation sheet 30. Through this, the insulation performance between the metal blocks 33 and 33' and the magnetic blocks 34 and 34' can be improved.

As shown in FIGS. 1, 3, and 4, the underlying hardware structure 110 is installed on the outer wall 1 to which the insulation sheet 10 is attached (S12). The underlying hardware structure 110 is installed in a form where a plurality of metal pipes are arranged orthogonal to each other in the X-axis and Y-axis directions at predetermined intervals, for example, in a matrix form (checkerboard). It is preferable that the underlying hardware structure 110 is not in close contact with the insulating sheet 10, but is installed to be spaced apart from the outer surface of the insulating sheet 10 at a predetermined distance. This is to prevent the insulation sheets from easily separating in the event of a fire and spreading the fire.

Next, as shown in FIGS. 1 and 5, the cement board 120 is installed on the underlying hardware structure 110 (S13). Cement board 120 may be made of synthetic resin wood. At this time, after construction of the cement board 120, an empty space 2 (see FIG. 14) is formed between the insulation sheet 10 and the cement board 120.

FIG. 14 is a diagram schematically showing a cross section of a construction example of a cement board according to an example of the present invention, and FIG. 15 is a view of the support of the underlying hardware structure shown in FIG. 14 viewed from above.

Referring to FIG. 14, the upper and lower ends of the underlying hardware structure 110 may be fastened and fixed to the outer wall 1 by the support 111. Accordingly, when the cement board 120 is fastened and fixed to each pipe of the underlying hardware structure 110 through screws (pieces), the thickness of the underlying hardware structure 110 is between the insulation sheet 10 and the cement board 120. An empty space (2) is formed as much as (including the thickness of the support).

Referring to FIG. 15, in the event of a fire, there is a fire extinguishing nozzle (which supplies fire extinguishing water to the support 111) to extinguish the fire by injecting fire extinguishing water into the space 2 between the insulation sheet 10 and the cement board 120. A fire nozzle installation hole (111a) in which (not shown) is installed is formed. Through this, when a fire occurs, the fire can be extinguished by injecting fire extinguishing water into the space 2 between the insulation sheet 10 and the cement board 120 through the fire nozzle installed in the fire nozzle installation hole 111a. That is, even if a fire occurs in the cement board 120, the fire can be prevented from spreading from the cement board 120 to the insulation sheet 10.

1 and 6, the finishing material 130 is attached and installed on the entire outer surface of the cement board 120 (S14). At this time, the finishing material 130 is an exterior material, and various types of panels or tiles can be used.

As above, preferred embodiments of the present invention have been described and illustrated using specific terminology, but such terminology is only intended to clearly describe the present invention. In addition, it is obvious that various changes and changes can be made to the embodiments and described terms of the present invention without departing from the technical spirit and scope of the following claims. These modified embodiments should not be understood individually from the spirit and scope of the present invention, but should be regarded as falling within the scope of the claims of the present invention.

1: The exterior wall of the building
2: Space (gap)
10, 20, 20', 30, 30': Insulation sheet
11, 21, 21', 31, 31': Aluminum sheet
12, 22, 22', 32, 32': Adhesive layer
23, 23', 33, 33': Metal block
24, 24', 34, 34': Magnetic block
110: Lower hardware structure
111: support
111a: Fire nozzle installer
120: cement board
130: finishing material

Claims (5)

A process of attaching first and second heat insulation sheets to the exterior wall of a building;
A process of installing an underlying hardware structure on the exterior wall of a building to which the first and second thermal insulation sheets are attached;
A process of installing cement board on the underlying hardware structure; and
A process of installing a finishing material on the outer surface of the cement board; Including,
The first and second thermal insulation sheets each include an aluminum sheet with an adhesive layer formed on one side, a metal block installed at the upper end of the aluminum sheet, and a magnet block installed at the lower end of the aluminum sheet,
A plurality of metal blocks and magnet blocks of the first and second row insulation sheets are each installed at predetermined intervals, an extension portion protruding upward is formed on the upper part of the first and second row insulation sheets, and the first and second row insulation sheets have an extension portion protruding upward. And a groove is formed in the lower part of the second row insulation sheet, and when the second row insulation sheet is attached to the outer wall of the building, an extension formed on the upper part of the second row insulation sheet is of the first row insulation sheet. A method of constructing external insulation for a building using a dry method that allows the magnetic blocks to be inserted into a groove formed in the first row insulation sheet.
delete According to claim 1,
The process of attaching the first and second thermal insulation sheets to the exterior wall of the building is,
A process of attaching the first thermal insulation sheet to the exterior wall of the building; and
The second row insulation sheet is attached to the outer wall of the building, and the second row insulation sheet is attached so that the metal block installed at the upper end of the second row insulation sheet is attached to the magnetic block installed at the lower end of the first row insulation sheet by magnetic force. A process of attaching an insulation sheet to the exterior wall of the building;
External insulation construction method of a building using a dry method including.
delete According to claim 1,
A space is formed between the first and second row insulation sheets and the cement board, and the underlying hardware structure includes a plurality of supports supported by the first and second row insulation sheets, and among the plurality of supports, the A method of external insulation construction of a building using a dry method in which a fire nozzle installation hole is formed on the support supported on the outer surface of the first row insulation sheet, into which a fire nozzle that injects fire extinguishing water into the space in the event of a fire is coupled.