KR102428858B1 - Frame-integrated insulation module and exterior material construction method using the same - Google Patents

Abstract

The present invention relates to a frame-integrated insulator module and an exterior material construction method using the same, in which an insulator and an exterior material are rapidly and firmly constructed. The frame-integrated insulator module comprises: an insulator (1) including an insulation member (11) and a support frame (12); an installation member (2) fixed to an outer wall of a building; a connecting member (3); and an exterior material support horizontal member (4) coupled to the connecting member (3).

Description

Frame-integrated insulation module and exterior material construction method using the same}

The present invention relates to a frame-integrated insulator module and a method for constructing an exterior material using the same, and more particularly, by integrally forming a support frame on the surface of an insulation member in the longitudinal direction, and installing a transverse exterior material supporting member in the horizontal direction of the insulation to provide zinc It relates to a frame-integrated insulator module and a method for constructing an exterior material using the same, which enables the construction of the insulation and exterior material to be quickly and firmly performed by binding the insulation material to the support frame and the exterior material support horizontal member in close contact with the insulation material in the horizontal and vertical directions.

In general, in order to strengthen the insulation in a concrete slab structure, insulation is installed on the inside and outside of the wall. ), glass fiber insulation material, mineral wool insulation material, cellulose insulation material, phenol foam board insulation material, and the like. is mainly used as

On the other hand, exterior materials for building finishing such as stone panels and various wooden panels made of natural or artificial stones such as marble or granite are installed on the exterior walls of buildings to increase the aesthetics of the exterior and protect the walls.

When installing the finishing exterior material on the exterior wall of the building, first install the insulating material on the exterior wall surface of the building using adhesive or fasteners, insert anchor bolts from the outside of the insulation to penetrate the installed insulation material, fix it on the exterior wall of the building, and then Fixing hardware is installed using the anchor bolt protruding outward, and the exterior material is installed using bolts or screws to be supported by the fixing hardware.

However, in the conventional construction method for finishing exterior materials as described above, as an angle-shaped fixing hardware is installed between the insulating material and the finishing material, a void of about 5 cm corresponding to the thickness of the fixing hardware is formed between the insulation and the finishing material. There is a disadvantage in that the external space of the building is reduced by protruding outward from the outer wall of the building.

In addition, when a strong wind blows, wind flows into the air gap between the insulating material and the finishing material formed by the fixing hardware, and a vortex phenomenon occurs in the air gap, which causes wind vibration and noise.

In addition, during rain, rainwater flows into the voids and causes corrosion of the fixing hardware made of metal, which causes a decrease in the strength of the fixing hardware and the removal of the exterior material in the long term.

On the other hand, there is zinc among exterior materials for construction finishing materials that are in the spotlight in recent years.

Zinc refers to a building exterior material that is painted or coated on a metal plate, and mainly steel, zinc, and aluminum plates are used.

Because zinc has a semi-permanent lifespan due to its excellent durability and strength, it has been widely used as a roofing material for buildings in the past.

However, when zinc is installed by the conventional exterior material construction method, it is difficult to effectively fix the zinc, and the thin zinc cannot be stably supported, so that the surface is meandering or curved, and the aesthetics of the appearance is reduced. However, there is also the disadvantage that the zinc vibrates when the wind blows and noise is generated.

Therefore, in order to prevent this, a plywood material with a wide and flat surface is additionally installed to be supported by the fixing hardware used in the conventional exterior material construction method, and then zinc must be fixed in close contact with the surface of the plywood material. There is a disadvantage that not only protrudes further to the outside, but also the construction period increases according to the additional installation of the plywood, and the construction cost accordingly increases.

Registered Patent Publication No. 10-2152707

In order to solve the disadvantages of the prior art as described above, the present invention forms a support frame integrally on the surface of an insulating member in the longitudinal direction, and installs a transverse facing member supporting the insulating material in the transverse direction of the insulating material, so that the building facing material is supported while closely adhering to the insulating material. An object of the present invention is to provide a frame-integrated insulation module that is bound to a frame and a transverse exterior member supporting member in the horizontal and vertical directions, and an exterior material construction method using the same.

In order to achieve the object as described above, the frame-integrated insulation module of the present invention is,

A heat insulating member 11 formed in a plate-like shape with a predetermined thickness of a heat-insulating material, and having concave grooves formed on the upper and lower surfaces and the outer surface;

a support frame 12 embedded in the recessed groove formed on the outer surface of the heat insulating member 11 in the longitudinal direction and integrally formed with the heat insulating member 11; Insulation (1) comprising a, and

Installation member (2) fixed to the outer wall surface of the building;

a connecting member (3) inserted into the concave groove formed on the upper and lower surfaces of the heat insulating member (11) and vertically connecting the heat insulating material (1) while being coupled with the installation member (2);

an exterior material supporting horizontal member 4 coupled to the connecting member 3 and in close contact with the outside of the heat insulating material 1 in the horizontal direction; includes

In one embodiment, the concave groove is,

an upper concave groove 111 formed in the transverse direction of the heat insulating member 11 on the upper surface of the heat insulating member 11;

a lower concave groove 112 formed in the transverse direction of the heat insulating member 11 on the bottom surface of the heat insulating member 11;

a longitudinal concave groove 113 formed in the longitudinal direction of the insulating member 11 on the outer surface of the insulating member 11;

a transverse concave groove 114 formed in the horizontal direction at the upper end and lower end of the outer surface of the insulating member 11; It is characterized in that it includes.

In one embodiment, the vertical concave groove 133 is characterized in that a plurality is formed at regular intervals.

In one embodiment, the support frame 12,

an input groove 121 into which the exterior material support horizontal member 4 is put in the upper and lower portions; It is characterized in that it is formed.

In one embodiment, the support frame 12,

an extension plate 122 protruding laterally from both sides; It is characterized in that it further comprises.

In one embodiment, the installation member (2),

a fixing plate 21 having a plurality of through holes 211 formed therein and fixed to the outer wall of the building by a fixing means;

The outer plate 33 is integrally formed at a right angle with the fixing plate 21 at the lower end of the fixing plate 21, and is coupled to the inner plate 32 formed in the connecting member 3 by forming a plurality of long holes 221 by a coupling means. ); It is characterized in that it includes.

In one embodiment, the connecting member (3),

a lower connecting plate 31 inserted into the upper concave groove formed on the upper surface of the heat insulating member;

an inner plate 32 seated on the upper surface of the heat insulating member and coupled to the installation member;

an outer plate 33 seated on the upper surface of the heat insulating member and coupled to the outer facing member supporting horizontal member;

an upper connection plate 34 inserted into a lower concave groove formed in the bottom surface of the insulation member of another insulation material positioned above the insulation material into which the lower connection plate 31 is inserted; It is characterized in that it includes.

In one embodiment, a plurality of locking projections 311 are further provided on the surface of the lower connection plate 31 .

In one embodiment, a plurality of locking projections 341 are further provided on the surface of the upper connection plate 34 .

In one embodiment, the exterior material supporting horizontal member (4),

a horizontal support plate 41 formed with a length corresponding to the horizontal length of the heat insulating material 1;

a coupling protrusion piece 42 protruding from the inner surface of the horizontal support plate 41 and coupled to the coupling groove 331 formed in the outer plate 33 of the connecting member 3; It is characterized in that it includes.

On the other hand, the exterior material construction method using the frame-integrated insulation module of the present invention,

An installation member installation step (S10) of installing the installation member (2) on the outer wall of the building at regular intervals;

A connecting member installation step (S20) of installing the connecting member (3) to be coupled to the installed installation member (2);

Insulation installation step (S30) of installing the insulating material (1) arranged in a horizontal and vertical direction so as to be bonded to the outer wall while being coupled to the installed connecting member (3);

The exterior material support is provided so that the horizontal boundary line in which the vertically arranged insulator 1 is in contact with each other is obscured by installing the exterior material supporting horizontal member 4 to be coupled with the connecting member 3 exposed to the lower part of the installed insulation 1 furnace member installation step (S40);

Airtight member attaching step (S50) of attaching the airtight member 5 along the boundary line so that the vertical boundary line in which the horizontally arranged insulator (1) is in contact with each other is obscured;

An exterior material installation step (S60) of attaching the inner surface of the zinc to the outer surface of the heat insulating material (1) and installing the zinc by binding with a direct screw along the support frame (12) and the exterior material support horizontal member (4) of the insulation material (1); It is characterized in that it includes.

In one embodiment, the transverse exterior support member installation step (S40) is characterized in that the horizontal support plate 41 of the exterior material support horizontal member 4 is coupled to the support frame 12 of the insulator 1 by a coupling means. .

In one embodiment, the exterior material support horizontal member installation step (S40) is characterized in that after the installation of the exterior material support horizontal member 4, the airtight member 5 is further attached to the upper portion of the exterior material support horizontal member 4 .

According to the present invention, there is an effect that the structural strength of the heat insulating material is improved by configuring the heat insulating material so that the support frame is integral with the surface of the heat insulating member in the longitudinal direction.

In addition, there is an effect of improving airtightness and heat-blocking properties by coupling the exterior material support horizontal member to the connecting member coupled to the installation member installed on the outer wall of the building, and the interface between the insulation materials is covered by the exterior material support member.

In addition, when installing zinc, which is an exterior material, it can be directly coupled to the support frame and the exterior support horizontal member so that it is closely attached to the outer surface of the insulation material, so that the zinc can be quickly and conveniently installed without additionally installing additional fixing hardware or plywood. And, it can be installed firmly, so that the work time required for the exterior construction is greatly reduced, and the construction cost is also reduced.

In particular, when zinc is installed, the inner surface of the exterior material is installed in direct contact with the flat surface of the insulation material that is installed on the outer wall of the building first. There is an effect that can be done.

In addition, by preventing rainwater or various foreign substances from entering between the insulating material and the exterior material, corrosion of the support frame is suppressed, thereby preventing a decrease in the fixing force of the exterior material or falling off.

1 is a perspective view according to a preferred embodiment of the frame-integrated insulation module of the present invention.
Figure 2 is an exploded perspective view of a thermal insulation material according to a preferred embodiment of the frame-integrated insulation module of the present invention.
3 is an enlarged cross-sectional plan view of an insulation material according to a preferred embodiment of the frame-integrated insulation module of the present invention.
Figure 4 is a cross-sectional view of the exterior material support member according to a preferred embodiment of the frame-integrated insulation module of the present invention.
5 is a side cross-sectional view of a construction state according to a preferred embodiment of the frame-integrated insulation module of the present invention.
6 is a front view illustrating a construction state according to a preferred embodiment of the frame-integrated insulation module of the present invention.
7 is a flowchart illustrating a method of constructing an exterior material using the frame-integrated insulation module of the present invention.

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

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

That is, since the embodiment may have various changes and may have various forms, it should be understood that the scope of the present invention includes equivalents capable of realizing the technical idea.

In addition, since the object or effect presented in the present invention does not mean that a specific embodiment should include all of them or only such effects, it should not be understood that the scope of the present invention is limited thereby.

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

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

In addition, terms such as "first" and "second" will only refer to distinguishing elements from each other, and are not limited by the order of manufacture, and the scope of rights should not be limited by these terms.

1 is a perspective view of a frame-integrated insulator module according to a preferred embodiment of the present invention, FIG. 2 is an exploded perspective view of an insulating material according to a preferred embodiment of the frame-integrated insulator module of the present invention, and FIG. 3 is a frame-integrated insulator module of the present invention. is a planar enlarged cross-sectional view of the insulation material according to a preferred embodiment of the present invention, Figure 4 is a cross-sectional view of the exterior material support horizontal member according to a preferred embodiment of the frame-integrated insulation module of the present invention, Figure 5 is a preferred embodiment of the frame-integrated insulation module of the present invention According to the construction state side cross-sectional view, Figure 6 is a front view of the construction state according to a preferred embodiment of the frame-integrated insulation module of the present invention.

It will be described with reference to FIGS. 1 to 6 .

The frame-integrated thermal insulation module of the present invention includes a thermal insulation material (1), an installation member (2), a connection member (3), and a transverse exterior material support member (4).

The heat insulating material (1) includes a heat insulating member (11) and a support frame (12).

The heat insulating member 11 is formed of a heat insulating material in a plate shape having a predetermined thickness, and concave grooves are formed on the upper and lower surfaces and the outer surface.

The insulating material can be manufactured in a plate shape of a predetermined thickness while having thermal insulation properties such as rigid polyurethane foam insulation, flexible polyurethane foam insulation, expanded polystyrene insulation, compressed styrofoam insulation, glass fiber insulation, mineral wool insulation, cellulose insulation, and phenolic foam board insulation. Any material can be used as a building insulation material.

The concave groove includes an upper concave groove 111 , a lower concave groove 112 , a vertical concave groove 113 , and a horizontal concave groove 114 .

The upper concave groove 111 is formed at a predetermined depth in the transverse direction of the heat insulating member 11 on the upper surface of the heat insulating member 11 .

It is preferable that the width and depth of the upper concave groove 111 correspond to the thickness and length of the lower connecting plate 31 of the connecting member 3 .

The lower recessed groove 112 is formed from the bottom surface of the heat insulating member 11 to a predetermined depth in the transverse direction of the heat insulating member 11 .

The depth of the lower concave groove 112 is preferably formed to correspond to the thickness and length of the upper connecting plate 34 of the connecting member 3 .

The vertical concave groove 113 is formed in the longitudinal direction of the heat insulating member 11 on the outer surface of the heat insulating member (11).

It is preferable that the depth and cross-sectional shape of the vertical concave groove 113 correspond to the cross-sectional shape of the support frame 12 .

A plurality of vertical concave grooves 113 may be formed at predetermined intervals.

The horizontal concave groove 114 is formed to a predetermined depth in the horizontal direction from the upper end and the lower end of the outer surface of the heat insulating member (11).

The depth of the horizontal concave groove 114 is preferably formed to correspond to the thickness of the horizontal support plate 41 of the exterior material support member (4).

The support frame 12 is embedded in the vertical concave groove 113 formed on the outer surface of the heat insulating member 11 to be integrally formed with the heat insulating member 11 .

All surfaces in contact with the support frame 12 and the heat insulating member 11 are preferably adhered so that the support frame 12 and the heat insulating member 11 are firmly integrated.

The cross-sectional shape of the support frame 12 is not limited, but in consideration of lightness, structural safety and durability, it is preferable to form an aluminum extrusion material having a cross-sectional shape of approximately “Π” in plan view.

The upper and lower ends of the support frame 12 are formed with an input groove 121 into which the exterior material support horizontal member 4 is inserted. The input groove 121 is preferably formed to be connected without a step with the horizontal concave groove 114 formed to a predetermined depth in the horizontal direction from the upper end and the lower end of the outer surface of the heat insulating member 11 .

In an embodiment, the support frame 12 may further include an extension plate 122 to protrude laterally from both sides.

Therefore, when viewed from the front of the heat insulating material 1, as the horizontal width of the support frame 12 is enlarged, the coupling between the heat insulating member 11 and the support frame 12 becomes stronger.

As described above, as the support frame 12 is integrated with the heat insulating member 11 in the longitudinal direction, not only the strength of the heat insulator 1 is improved, but also when zinc, which is a building exterior material, is installed on the outside of the heat insulator 1, zinc Since the support frame 12 supports the load acting on the zinc by directly binding it to the support frame 12 so as to be in close contact with the outer surface of the insulating material 1, the installation of the zinc is made more robust and stable.

In addition, when the zinc, which is a building exterior material, is installed on the outside of the insulating material 1 as the horizontal width of the support frame 12 is enlarged, the area to which the direct screw is to be bound is enlarged, so that between the support frame 12 and the zinc using the direct screw There is an effect of improving the speed, convenience and efficiency of the binding operation.

The installation member 2 is fixed to the outer wall surface of the building and is made of a metal plate to be coupled to the support frame 12 of the insulator 1 , and includes a fixing plate 21 and an outer plate 33 .

The fixing plate 21 has a plurality of through holes 211 formed therein and is fixed to the outer wall of the building by means of fixing means.

The fixing means may be any one of pieces, screws, and bolts that are inserted into the through holes 211 so that the fixing plate 21 is closely fixed to the outer wall of the building.

The outer plate 33 is integrally formed at a right angle with the fixed plate 21 at the lower end of the fixed plate 21, and a plurality of long holes 221 are formed to connect with the inner plate 32 formed in the connecting member 3 as a coupling means. are combined

The coupling means may be any one of pieces, screws, and bolts.

The connecting member 3 is inserted into the concave groove formed on the upper and lower surfaces of the heat insulating member 11 and is coupled to the installation member to vertically connect the heat insulating material to the lower connecting plate 31, the inner plate 32, the outer plate 33, and the upper part. a connecting plate 34 .

The lower connection plate 31 is formed to be equal to or longer than the horizontal length of the heat insulating material and is inserted into the upper concave groove 111 formed on the upper surface of the heat insulating member.

In one embodiment, a plurality of locking projections 311 may be further provided on the surface of the lower connection plate 31 .

Preferably, the locking protrusion 311 is formed in a saw blade shape so that the lower connecting plate 31 inserted into the upper concave groove 111 is not arbitrarily discharged.

The inner plate 32 is formed to be equal to or longer than the horizontal length of the insulator, and is coupled to the outer plate 33 of the installation member 2 by a coupling means while being seated on the upper surface of the insulating member.

The outer plate 33 is formed to be equal to or longer than the horizontal length of the heat insulating material and is seated on the upper surface of the heat insulating member. 42) is input and combined.

The coupling groove 331 is formed in the front and rear direction of the outer plate 33 on the front surface of the outer plate 33, and the engaging protrusion pieces 42 of the outer plate supporting transverse member 4 are inserted and coupled thereto.

It is preferable that the inner surface of the coupling groove 331 is formed in a saw-tooth shape so that the coupling protrusion piece 42 injected into the coupling groove 331 is not arbitrarily discharged.

The upper connection plate 34 is formed to be equal to or longer than the horizontal length of the insulator and is inserted into the lower concave groove formed in the bottom surface of the insulating member of another insulating material located above the insulating material into which the lower connection plate 31 is inserted. .

In one embodiment, a plurality of locking projections 341 may be further provided on the surface of the upper connection plate 34 .

It is preferable that the locking protrusion 341 is formed in a saw blade shape so that the upper connection plate 34 inserted into the lower concave groove 112 is not arbitrarily discharged.

The lower connecting plate 31, the inner plate 32, the outer plate 33, and the upper connecting plate 34 of the connecting member 3 are at right angles to each other so that the longitudinal cross-section of the connecting member 3 is “+”. It would be preferable, but it should be noted in advance that the present invention is not limited thereto.

In addition, the material of the connecting member 3 is preferably a metal material, more preferably an aluminum extrusion material.

The exterior material support horizontal member 4 is coupled to the connecting member 3 and includes a horizontal support plate 41 and a coupling protrusion piece 42 to be in close contact with the outside of the heat insulating material 1 in the horizontal direction.

The horizontal support plate 41 is formed of a plate material having a length corresponding to the horizontal length of the connecting member 3 .

Although the material of the horizontal support plate 41 is not limited, it is preferable to use a material having a thin thickness and excellent strength.

In addition, an airtight material made of a soft material having elasticity may be further provided on the inner surface of the horizontal support plate 41 .

In an embodiment, the horizontal support plate 41 may be coupled to the support frame 12 of the heat insulating material 1 by a coupling means.

The coupling means is preferably a direct screw.

The coupling protrusion piece 42 is formed to protrude from the inner surface of the horizontal support plate 41 and is coupled to the coupling groove 331 formed in the outer plate 33 of the connecting member 3 .

When the coupling protrusion piece 42 is inserted into the saw blade-shaped coupling groove 331, it is preferable that the end portion is formed in the shape of an arrowhead so as not to be discharged arbitrarily.

On the other hand, when the exterior material supporting horizontal member 4 is installed to be coupled to the connecting member 3 , the horizontal supporting plate 41 is inserted into the horizontal concave groove 114 of the heat insulating member 11 to form the heat insulating member 11 . When the outer surface of the outer surface and the outer surface of the horizontal support plate 41 are flattened, when the zinc as a building finishing material is installed on the outside of the heat insulating material 1, the outer surface of the heat insulating material 1 can be installed so that the inner surface of the zinc is in close contact.

After the installation of the frame-integrated insulation module of the present invention configured as described above is completed, when the zinc, which is a building exterior material, is installed on the outside of the insulation 1, the support frame 12 formed in the vertical direction on the insulation 1 and the zinc are directly connected. Fast installation of zinc is possible by binding with screws, and binding the zinc to the exterior material supporting transverse member 4 installed in the transverse direction on the insulator 1 with a direct screw.

In addition, when the zinc is installed, the inner surface of the zinc is closely attached to the outer surface of the insulating material 1, and at the same time, as the binding of the zinc becomes very strong, lifting or bending of the zinc is prevented, thereby effectively suppressing the vibration, vibration and noise of the zinc after construction. .

7 is a flowchart illustrating a method of constructing an exterior material using the frame-integrated insulation module of the present invention.

Although it will be described with reference to FIG. 7 , a detailed description of the components having the same reference numerals and components overlapping those of the above-described embodiment will be omitted.

The exterior material construction method using the frame-integrated insulation module of the present invention includes an installation member installation step (S10), a connecting member installation step (S20), an insulating material installation step (S30), an exterior material support horizontal member installation step (S40), an airtight member attachment step (S50), characterized in that it comprises an exterior material installation step (S60).

In the installation member installation step (S10), the installation members 2 are installed at regular intervals horizontally and vertically according to the standard of the insulating material 1 on the outer wall of the building.

That is, by inserting a fixing means into the through hole 211 formed in the fixing plate 21 of the installation member 2 composed of the fixing plate 21 and the coupling plate 22, the fixing plate 21 is fixed in close contact with the outer wall surface of the building. .

It is preferable to use an anchor bolt as the fixing means.

The connecting member installation step (S20) installs the connecting member (3) to be coupled with the installation member installed in the installation member installation step (S10).

That is, the inner plate 32 of the connecting member 3 is coupled to the coupling plate of the installation member by means of a coupling means so that the connecting member 3 is accurately leveled.

The coupling means is preferably a direct screw.

The coupling position of the inner plate 32 may be located above or below the coupling plate.

As an example, when installing the insulating material on the lowermost end of the outer wall of the building, the inner plate 32 of the connecting member 3 positioned below the insulating material is located above the coupling plate of the installation member.

As another example, after installing all the insulating materials in the horizontal direction on the lowermost end of the outer wall of the building, when the insulating materials are stacked and arranged in the vertical direction, the inner plate 32 of the connecting member 3 located on the upper part of the insulating material is the installation member. It should be noted in advance that it will be easy for installation work to be located on the lower side of the coupling plate, but is not limited thereto.

The insulating material installation step (S30) is coupled with the connecting member (3) installed in the connecting member installation step (S20) while installing the insulating material (1) to be adhered to the outer wall, the insulating material (1) arranged in the horizontal and vertical directions to be in close contact with each other install

That is, in the state in which the installation of the connecting member 3 is completed, the lower end of the heat insulating member is seated so that the upper connecting plate 34 of the connecting member 3 is inserted into the lower concave groove 112 of the heat insulating member 11 . The inner surface of the insulating member is adhered to the outer wall of the building so that it is vertically upright.

Therefore, in the process of installing the insulator 1, the insulator 1 is supported by the connecting member 3, so that the installation of the insulator is made faster and more simply, and when the insulator is installed to be arranged in the horizontal and vertical directions, the correct Vertical and horizontal installation is easy.

The exterior material supporting transverse member installation step (S40) is to be coupled with the connecting member 3 exposed to the lower part of the insulating material 1 combined with the connecting member 3 in the insulating material installation step (S30) to be coupled to the exterior material supporting horizontal member 4 The horizontal boundary line in which the vertically arranged insulator (1) is in contact with each other is covered by installing .

That is, the coupling protrusion piece 42 of the exterior material support horizontal member 4 composed of the horizontal support plate 41 and the coupling protrusion piece 42 is formed on the outer plate 33 of the connecting member 3 exposed to the lower portion of the heat insulating material 1 . When inserted into the coupling groove 331 by an interference fit method, the horizontal support plate 41 is inserted into the horizontal concave groove 114 formed on the front surface of the heat insulating member 11, and the exterior material is in close contact with the surface of the horizontal concave groove 114. The supporting transverse member (4) is coupled to the installation member (2).

On the other hand, when the insulators 1 arranged in the horizontal and vertical directions are installed in close contact with each other in the insulating material installation step (S30), the horizontal concave grooves formed in each insulating material 1 at the boundary where the vertically arranged insulators 1 are in contact ( 114) are connected to each other, and as it is put into the horizontal support plate 41 of the exterior material support horizontal member 4 inside the horizontal concave recess 114, the coupling force between the installation member 2 and the exterior material support horizontal member 4 not only the fixing force acts simultaneously on the insulator 1 arranged vertically by the Thermal cross-blocking properties are improved.

In one embodiment, the transverse exterior support member installation step (S40) may combine the horizontal support plate 41 of the exterior support horizontal member 4 with the support frame 12 of the insulator 1 by means of a coupling means.

The coupling means is preferably a direct screw.

Accordingly, the installation member 2, the connection member 3, the exterior material supporting horizontal member 3, and the support frame 12 of the heat insulating material 1 are all combined to form a structure in which the entire structure becomes more robust.

In one embodiment, the exterior material support horizontal member installation step (S40) may further attach the airtight member 5 to the upper portion of the exterior material support horizontal member 4 after the installation of the exterior material support horizontal member 4 .

The attachment of the airtight member 5 is preferably attached to the surface of the heat insulator 1 so that the horizontal concave groove 114 of the heat insulator 1 is completely concealed together with the exterior support member 4 .

The airtight member 5 may be any material as long as it has waterproofness and heat insulation, has a thin thickness, and can be attached to the surface of the heat insulator 1, but it is preferable to use a silver foil tape widely used in the field of building insulation. .

In the airtight member attaching step (S50), when the insulators (1) arranged in the horizontal and vertical directions are installed in close contact with each other in the insulating material installation step (S30), the vertical boundary line where the insulators (1) arranged in the horizontal direction are in contact with each other is covered Attach the airtight member (5) along the boundary line.

The airtight member 5 may be any material as long as it has waterproofness and heat insulation, has a thin thickness, and can be attached to the surface of the heat insulator 1, but it is preferable to use a silver foil tape widely used in the field of building insulation. .

In the exterior material installation step (S60), when the airtight member attachment step (S50) is completed, the inner surface of the zinc 6, which is a building exterior material, is closely attached to the outer surface of the insulation material 1, and the support frame 12 of the insulation material 1 and A zinc is installed by binding with a direct screw along the exterior material support horizontal member (4).

That is, fast installation of zinc by binding the support frame 12 and zinc formed in the vertical direction to the insulator 1 with a direct screw, and binding the zinc to the exterior support transverse member 4 installed in the horizontal direction to the insulator 1 with a direct screw. becomes possible

In addition, when zinc is installed, the inner surface of the zinc is closely attached to the outer surface of the insulating material 1, and at the same time, as the zinc bond becomes very strong, lifting or bending of the zinc is prevented, thereby effectively suppressing the vibration, vibration, and noise of the zinc after construction. .

Therefore, in the exterior material construction method using the frame-integrated insulation module of the present invention, the airtightness of the interface between the insulation materials 1 is improved by the exterior material support horizontal member 4 directly coupled to the installation member 2 installed on the exterior wall of the building, Since it is possible to directly combine zinc, which is a building exterior material, to the support frame 12 and the exterior material support horizontal member 4, the zinc can be installed quickly, simply and securely without additionally installing a separate fixing hardware. The work time required for exterior construction is greatly reduced, and construction costs are also reduced.

In addition, when zinc is installed, the inner surface of the exterior material is installed in direct contact with the flat surface of the insulation material (1), which is first installed on the exterior wall of the building, thereby preventing the occurrence of voids between the insulation material (1) and the zinc exterior material. , noise, etc. can be suppressed.

In addition, by preventing rainwater or various foreign substances from flowing between the insulator 1 and the exterior material, corrosion of the support frame 12 is suppressed, thereby preventing a decrease in the fixing force of the exterior material or falling off.

As mentioned above, although the embodiment of the present invention has been described in detail, the scope of the present invention is not limited thereto, and various modifications and improved forms of the present invention are also provided by those skilled in the art using the basic concept of the present invention as defined in the following claims. is within the scope of the right.

W: Exterior wall B: Adhesive
1: insulation material 11: insulation material
111: upper concave groove 112: lower concave groove
113: vertical recessed groove 114: horizontal recessed groove
12: support frame 121: input groove
122: expansion plate 2: mounting member
21: fixing plate 211: through hole
22: coupling plate 221: long hole
3: connection member 31: lower connection plate
32: inner plate 33: outer plate
331: coupling groove 34: upper connection plate
4: exterior material support horizontal member 41: horizontal support plate
42: coupling stone piece 5: airtight member
6: Zinc S10: Installation member installation step
S20: Connection member installation step S30: Insulation material installation step
S40: exterior material support horizontal member installation step S50: airtight member attachment step
S60: Exterior re-installation step

Claims (5)

A heat insulating member 11 formed in a plate-like shape with a predetermined thickness of a heat-insulating material, and having concave grooves formed on the upper and lower surfaces and the outer surface;
a support frame 12 embedded in the concave groove formed on the outer surface of the heat insulating member 11 in the longitudinal direction and formed integrally with the heat insulating member 11 in the longitudinal direction to support the load of the zinc; Insulation (1) comprising a, and
Installation member (2) fixed to the outer wall surface of the building;
a connecting member (3) inserted into the concave groove formed on the upper and lower surfaces of the heat insulating member (11) and vertically connecting the heat insulating material (1) while being coupled with the installation member (2);
an exterior material supporting horizontal member 4 coupled to the connecting member 3 and in close contact with the outside of the heat insulating material 1 in the horizontal direction; including,
The concave groove is
an upper concave groove 111 formed in the transverse direction of the heat insulating member 11 on the upper surface of the heat insulating member 11;
a lower concave groove 112 formed in the transverse direction of the heat insulating member 11 on the bottom surface of the heat insulating member 11;
a longitudinal concave groove 113 formed in the longitudinal direction of the insulating member 11 on the outer surface of the insulating member 11;
a transverse concave groove 114 formed in the horizontal direction at the upper end and lower end of the outer surface of the insulating member 11; includes,
The support frame 12,
Doedoe input grooves 121 are formed in the upper and lower portions,
The input groove 121 is formed to connect without a step with the horizontal concave groove 114 formed to a predetermined depth in the horizontal direction from the upper end and the lower end of the outer surface of the insulating member 11, and the exterior material supporting member 4 is inserted,
The exterior material support horizontal member (4),
a transverse support plate 41 formed with a length corresponding to the transverse length of the heat insulating material 1 and coupled to the supporting frame 12 by a coupling means, coupled with the zinc in the transverse direction to support the load of the zinc;
a coupling protrusion piece 42 protruding from the inner surface of the horizontal support plate 41 and coupled to the coupling groove 331 formed in the outer plate 33 of the connecting member 3; Including a frame-integrated insulation module, characterized in that the exterior material for construction is closely attached to the insulation material and is bound to the support frame and the exterior material support horizontal member in the horizontal and vertical directions.
delete According to claim 1,
The connecting member (3) is,
a lower connecting plate 31 inserted into the upper concave groove formed on the upper surface of the heat insulating member;
an inner plate 32 seated on the upper surface of the heat insulating member and coupled to the installation member;
an outer plate 33 seated on the upper surface of the heat insulating member and coupled to the outer facing member supporting horizontal member;
an upper connection plate 34 inserted into a lower concave groove formed in the bottom surface of the insulation member of another insulation material positioned above the insulation material into which the lower connection plate 31 is inserted; Frame-integrated insulation module comprising a.
delete An installation member installation step (S10) of installing the installation members (2) of the frame-integrated insulation module of any one of claims 1 and 3 to the outer wall of the building at regular intervals;
A connecting member installation step (S20) of installing the connecting member (3) to be coupled to the installed installation member (2);
Insulation installation step (S30) of installing the insulating material (1) arranged in a horizontal and vertical direction so as to be bonded to the outer wall while being coupled to the installed connecting member (3);
The exterior material support is provided so that the horizontal boundary line in which the vertically arranged insulator 1 is in contact with each other is obscured by installing the exterior material supporting horizontal member 4 to be coupled with the connecting member 3 exposed to the lower part of the installed insulation 1 furnace member installation step (S40);
Airtight member attaching step (S50) of attaching the airtight member 5 along the boundary line so that the vertical boundary line in which the horizontally arranged insulator (1) is in contact with each other is obscured;
An exterior material installation step (S60) of attaching the inner surface of the zinc to the outer surface of the heat insulating material (1) and installing the zinc by binding with a direct screw along the support frame (12) and the exterior material support horizontal member (4) of the insulation material (1); An exterior material construction method using a frame-integrated insulation module comprising a.

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