KR101543268B1 - Outside Insulation System - Google Patents

Abstract

According to an aspect of the present invention, there is provided an external thermal insulation system comprising: a heat insulating material provided on an outer side of a wall to prevent heat loss due to heat bridging; a frame provided between the wall and the heat insulating material, A plurality of fixing members having one end coupled to the frame and the other end inserted into holes drilled in the wall to fix the frame to the wall; and a fixing auxiliary member provided between the fixing member and the hole to increase the binding force of the fixing member The heat insulating material may have grooves formed in a grid shape having the same shape as that of the frame so that the frame formed in the grid shape on one surface is inserted into the heat insulating material.

Description

Outside Insulation System

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an external heat insulating system, and more particularly, to an external heat insulating system having a dry type prefabricated structure and capable of simple and quick construction.

It is common to construct a residential space with a thermal insulation structure for cooling as well as heating.

The insulation system of a building can be roughly divided into an inner insulation system for installing the insulation material on the inner wall of the building and an outer insulation system for installing the insulation material on the outer wall of the building.

The thermal insulation system in the interior has a large energy loss due to the thermal bridge and cold bridge phenomenon through the structure. Therefore, in recent years, an external thermal insulation system which mainly prevents heat bridging and cold bridging phenomenon and has a low energy loss is used.

External insulation systems can be broadly divided into wet and dry systems.

In the wet system, a heat insulation material is attached to the entire outer wall of the building by point bonding using an adhesive mortar or the like, and then an intermediate layer of fiber mortar, glass fiber, or mesh is laid on the surface of the heat insulating material adhered to the outer wall, and an embossing finish material .

Since the wet system is constructed without an expansion joint to absorb shrinkage and expansion in the entire outer wall of the building, there is a problem that the shrinkage occurs and the surface layer breaks due to the difference in shrinkage rate and expansion rate depending on the temperature of the heat insulating material, .

In addition, since the wet system is attached to the outer wall of the building by point bonding using an adhesive mortar, durability is not ensured even when the life cycle of the building is limited.

The improvement of the defects of the wet system as described above is a dry system in which a plurality of heat insulating panels, which are manufactured by using a connecting hardware such as a fastener, and are manufactured to a certain standard, such as dry bits, are constructed.

However, in the conventional dry type system, it is troublesome and difficult to construct the connecting hardware, and consequently, the construction is not easy.

In addition, since there is no consideration of the connection part between the heat insulating panels, heat or cool air escapes through the connection part, energy loss is largely generated, and the connection between the connecting hardware and the heat insulating panel is not stable, The problem is still sporadic.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a dry external insulation system that can be installed quickly and easily.

It is still another object of the present invention to provide an external thermal insulation system capable of firmly fixing and adhering a heat insulating material to a wall.

To achieve the above object, according to one aspect of the present invention, there is provided an external thermal insulation system comprising: a heat insulating material provided on an outer side of a wall to prevent heat loss due to heat bridging; and a heat insulating material provided between the wall and the heat insulating material, A plurality of fastening members, one end of which is coupled to the frame and the other end of which is inserted into a hole drilled in the wall to fix the frame to the wall, and a plurality of fixing members provided between the fixing member and the fixing member, The heat insulating material may include grooves formed in a lattice shape having the same shape as that of the frame so that the frame formed in the lattice shape on one side of the heat insulating material is inserted into the heat insulating material.

The fixing member may include a coupling portion that engages with the frame, and an insertion portion that is inserted into the hole.

The insertion portion has a plurality of protrusions on the surface thereof. The protrusion has a sharp edge. The insertion portion has an inclined surface formed in a direction in which the insertion portion is inserted into the hole, and an engagement surface formed in a direction in which the insertion portion is withdrawn from the hole can do.

The insertion portion may have a thread on the surface.

The frame may include a plurality of horizontal frames that are parallel to the ground and a plurality of vertical frames that are perpendicular to the horizontal frames.

The horizontal frame and the vertical frame may have a plurality of coupling grooves that engage with the fixing member.

A mesh-like mesh for easily attaching the finishing material may be joined to the other surface of the heat insulating material.

According to another aspect of the present invention, there is provided an external thermal insulation system, comprising: a heat insulating material disposed outside a wall to prevent heat loss due to heat bridging; and a heat insulating material disposed between the wall and the heat insulating material, A plurality of fixing members for fixing the frame to the wall by inserting one end of the frame into the hole and the other end being inserted into a hole formed in the wall; And a fixing auxiliary member for increasing the binding force of the fixing member, and the heat insulating member may include a plurality of block insulating members sandwiched between the plurality of grid space portions formed in the grid-shaped frame.

The fixing member may include a coupling portion that engages with the frame, and an insertion portion that is inserted into the hole.

The insertion portion has a plurality of protrusions on the surface thereof. The protrusion has a sharp edge. The insertion portion has an inclined surface formed in a direction in which the insertion portion is inserted into the hole, and an engagement surface formed in a direction in which the insertion portion is withdrawn from the hole can do.

The insertion portion may have a thread on the surface.

According to the external heat insulation system according to the present invention, it is possible to easily and quickly construct through the dry type method using the fixing material, the frame and the heat insulating material.

Then, the fixing member, the frame, and the heat insulating material are coupled through the assembly method, so that the heat insulating material can be firmly fixed to the wall and closely contacted.

1 is a cross-sectional view of an adiabatic system according to an embodiment of the present invention.
2 is an exploded perspective view of an external thermal insulation system according to an embodiment of the present invention;
3 is a perspective view of a frame according to an embodiment of the present invention;
4 is a side view of the fixture according to one embodiment of the present invention.
5 is a side view of a fixture according to another embodiment of the present invention;
6 is an exploded perspective view showing an external heat insulating system according to another embodiment of the present invention.

Hereinafter, an external heat insulating system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is an exploded perspective view illustrating an external heat insulating system according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view of an external heat insulating system according to an embodiment of the present invention. Fig.

1 to 3, an external thermal insulation system 10 according to an embodiment of the present invention includes a heat insulating material 100 provided on the outer side of a wall 20, a frame 100 for mounting the heat insulating material 100 A fixing member 300 for fixing the frame 200 to the wall 20 and a fixing auxiliary member 400 between the fixing member 300 and the wall 20.

The heat insulating material 100 is provided over the entire outer surface of the wall body 20 to prevent thermal bridges between the inside and the outside of the structure to prevent heat loss.

The heat insulating material 100 is provided on the wall 20 in a panel form, and expanded polystyrene foam, styrofoam, or the like can be used as the material. When the styrofoam is used as the material of the heat insulating material 100, the compressive strength is 16 N / cm ² Or more of styrofoam may be used.

The size of the heat insulating material 100 may be 1200 mm x 900 mm, but it may be variously sized depending on the size and shape of the wall body 20.

A mesh 500 is coupled to one side of the heat insulating material 100.

The mesh 500 is connected to one side of the heat insulating material 100 in a net shape and is fixed to the wall 20 by a heat insulating material 100 for easily attaching the finish material 600 for finishing the heat insulating material 100 to the heat insulating material 100. [ (100) and the finishing material (600).

As the finishing material 600, finishing can be performed by using a spray-type finishing material sprayed on the existing insulating material or by applying an improved cement paste.

The other side of the heat insulating material 100 to which the mesh 500 is not bonded is mounted in combination with the frame 200. The frame 200 is inserted into the heat insulating material 100 and bonded to the heat insulating material 100. Therefore, the other side surface of the heat insulating material 100 to which the frame 200 is coupled can form a flat surface without the protruding portion of the frame 200, and thus the gap with the wall body 20 is not generated.

The heat insulating material 100 is mounted on the frame 200 in a prefabricated manner through a tight fitting method without being directly fixed to the wall body 20 by a separate fixing member (not shown) (Not shown).

Therefore, when the heat insulating material 100 is directly fixed to the wall 20, the heat insulating material 100 (not shown) is inserted into the heat insulating material 100 through the fixing member (not shown) ) Can be prevented in advance.

In addition, since a separate fixing member (not shown) can be used and the construction is simple, it is effective in terms of overall construction time and cost reduction.

As a result, the heat insulating material 100 can be fixed to the wall 20 without any gap, and the heat insulating material 100 can minimize the lifting phenomenon by the frame 200, thereby realizing the external heat insulating more effectively.

On one side of the frame 200 facing the wall 20, a fixing member 300 for fixing the frame 200 to the wall 20 is provided.

A plurality of fixing members 300 are provided on one side of the frame 200 at regular intervals.

A part of the fixing member 300 is inserted into the hole 21 formed in the wall 20 and the remaining part is inserted into the frame 200 so that the fixing member 300 is inserted between the wall 20 and the frame 200 No gaps occur.

At this time, a coupling groove 230 for inserting the fixing member 300 is provided on one side of the frame 200. A plurality of coupling grooves 230 of the frame 200 are provided at predetermined intervals such as the fixing member 300.

The configuration of the fixing member 300 will be described later in more detail.

A fixing auxiliary member 400 is provided between the hole 21 formed in the wall 20 and the fixing member 300. In this embodiment, the fixed auxiliary member 400 is provided, but the fixed auxiliary member 400 may not be provided depending on the situation.

The fixing auxiliary member 400 is provided in such a form that it pushes the hole 21 drilled in the wall body 20 and pushes it to enclose a part of the fixing member 300 inserted into the hole 21 and inserted into the hole 21, (20) and the fixing member (300).

The fixing auxiliary member 400 may be made of aluminum, a hard rubber, and a soft synthetic resin depending on circumstances.

Although not shown in the drawing, a separate protruding portion and a locking protrusion for enhancing the binding force between the wall body 20 and the fixing auxiliary member 400 and the binding force between the fixing auxiliary member 400 and the fixing member 300 may be provided on the inside and outside have.

Next, the heat insulating material 100 and the frame 200 on which the heat insulating material 100 is mounted will be described in more detail.

The frame 200 on which the heat insulating material 100 is mounted is manufactured in the form of a steel pipe having an empty interior. In this embodiment, the horizontal frame 210 and the vertical frame 220 are steel pipe pipes having a rectangular cross section. However, the frame 200 may have various shapes in a polygonal shape.

The horizontal frame 210 and the vertical frame 220 can be integrated with each other and can be integrated with the horizontal frame 210 and the vertical frame 220 manufactured through welding or various coupling methods, Most preferred.

It is most preferable that the frame 200 is integrally manufactured because the frame 200 is brought into contact with the wall 20 on one side and is brought into contact with the heat insulating material 100 on the other side. The wall 20 and the heat insulating material 100 are not protruded from the surface where the wall 20 and the heat insulating material 100 are brought into contact with each other so that the frame 200 can be brought into contact with the wall 20 and the heat insulating material 100. However, when the frame 200 is manufactured by welding or various joining methods, a portion protruding from the surface where the wall 20 and the heat insulating material 100 are abutted by welding or various joining methods is produced. As a result, a space is formed between the frame 200 and the wall 20, the frame 200 and the heat insulating material 100, and the frame 200 is detached from the outer wall or the heat insulating material 100 It can cause the dropout. If force is exerted to remove the space generated by the protruding portion, the shape of the frame 200 may be deformed or a gap may be generated in the heat insulating material 100. [

The frame 200 includes a plurality of horizontal frames 210 and a plurality of vertical frames 220. The horizontal frame 210 is provided to be horizontal with the ground, and the vertical frame 220 is formed to be perpendicular to the horizontal frame 210, and the overall shape is formed in a lattice shape.

In this embodiment, the frame 200 is formed in a lattice shape in which the horizontal frame 210 and the vertical frame 220 are perpendicular to each other. However, the frame 200 may be formed in a lattice shape with an oblique line.

On the other hand, the above-mentioned heat insulating material 100 is provided on one side with an insertion groove 110 for inserting and inserting into the frame 200.

The insertion groove 110 is formed in a lattice shape having the same shape as that of the frame 200 so that the heat insulating material 100 is inserted into the frame 200. The insertion groove 110 is also inserted into the horizontal insertion groove 111 and the frame 200 in which the horizontal frame 210 of the frame 200 is inserted, as the frame 200 has the horizontal frame 210 and the vertical frame 220. [ And a vertical insertion groove 112 into which the vertical frame 220 of the vertical frame 220 is inserted. The horizontal insertion grooves 111 are formed horizontally with respect to the ground and are formed in a plurality of vertical insertion grooves 112 perpendicular to the horizontal insertion grooves 111.

The insertion groove 110 may have a depth equal to the thickness of the frame 200 and may have the same shape as the shape of the frame 200. The frame 200 and the heat insulating material 100 can be brought into contact with the wall 20 because they form the same surface without any protruding portion and no gap is generated between the heat insulating material 100 and the wall body 20, Insulation is possible.

The width of the insertion groove 110 may be the same as the size of the frame 200 or may be smaller than the size of the frame 200 so that the insertion groove 110 may be inserted in the insulation member 100 in an interference fit manner. The frame 200 and the heat insulating material 100 are coupled in an interference fit manner so that the frame 200 and the heat insulating material 100 can be combined without using a separate joining member or adhesive. In addition, since it is simply fitted, it is also effective in terms of workability.

Next, the fixing member 300 for fixing the frame 200 on which the heat insulating material 100 is mounted to the wall body 20 will be described in detail.

FIG. 4 is a side view showing a fixing member according to an embodiment of the present invention, and FIG. 5 is a side view showing a fixing member according to another embodiment of the present invention.

3 to 5, a fixing member 300 according to an embodiment of the present invention includes a coupling portion 310 that engages with a frame 200, and a coupling portion 310 that is inserted into a hole 21 formed in the wall 20 And an inserting portion 320.

The coupling part 310 has an insertion part 320 on one side and the other side is inserted and coupled to the frame 200. The frame 200 has a coupling groove 230 into which the coupling portion 310 is inserted so that the coupling portion 310 is inserted into the frame 200.

Here, the coupling grooves 230 of the frame 200 are provided in the horizontal frame 210 and the vertical frame 220, respectively, and a plurality of coupling grooves 230 are provided at regular intervals.

The engaging portion 310 of the fixing member 300 and the engaging groove 230 of the frame 200 are formed in the same shape. In this embodiment, the coupling portion 310 and the coupling groove 230 may be formed in various shapes.

The coupling portion 310 may have a thickness equal to the depth of the coupling groove 230. Therefore, the frame 200 and the heat insulating material 100 can form the same surface without protruding portions.

The engaging portion 310 may have the same size as the engaging groove 230 or may have a predetermined size larger than that of the engaging groove 230 and may be inserted into the engaging groove 230 in an interference fit manner. The coupling portion 310 and the coupling groove 230 are coupled with each other in an interference fit manner so that the coupling portion 310 and the coupling groove 230 can be coupled without using a separate coupling member or adhesive. In addition, since it is simply fitted, it is also effective in terms of workability.

One end of the insertion portion 320 is connected to the coupling portion 310 and the other end is inserted into the hole 21 formed in the wall 20. The insertion portion 320 may be pointed at the distal end of the insertion portion 320 in order to easily fix the fixing member 300 to the wall even if the insertion portion 320 is inserted deeper than the depth of the perforated hole 21 .

In this embodiment, the shape of the insertion portion 320 is a cylindrical shape. The insertion portion 320 may be formed in various shapes.

In addition, a plurality of protrusions 321 are provided on the surface of the inserting portion 320 to maintain a constant gap.

The overall shape of the projection 321 is formed such that its edge is sharp. The projection 321 is formed with an inclined surface 321a formed in a direction in which the insertion portion 320 is inserted into the hole 21 formed in the wall 20 and a hole 321b formed in the insertion portion 320 in a direction And an engaging surface 321b formed in the direction of withdrawal from the main body 21.

Since the protrusion 321 has the inclined surface 321a so that the insertion portion 320 is easily inserted into the hole 21 and the insertion portion 320 is inserted into the hole 21 by the engagement surface 321b The insertion portion 320 can be prevented from being easily detached from the hole 21. [

Meanwhile, the fixing member 300 may be provided in various forms and methods other than those described above.

Hereinafter, the fixing member 300 according to another embodiment of the present invention will be described. Hereinafter, only different parts from the above-described embodiment will be described in detail, and the same or similar parts will not be described in detail.

3 to 5, the fixing member 300 may form a thread 322 on the surface of the insertion portion 320. [

The fixing member 300 is provided to protrude from a side of the frame 200 which is not in contact with the wall body 20, unlike the fixing member 300 of FIG. The insertion portion 320 is inserted into the hole 21 of the wall 20 through the frame 200.

The frame 200 can be fixed to the wall 20 more easily by engaging the engaging portion 310 of the fixing member 300 so as to project out of the frame 200. [

For example, in the case of the fixing member shown in FIG. 4, the fixing portion 300 of the fixing member 300 is inserted into the coupling groove 230 of the frame 200 after it is preferentially installed on the wall body 20. At this time, the fixing member 300 is provided with a plurality of fixing members 300 on the wall to increase the coupling force between the wall body 20 and the frame 200. In order to mount the frame 200 so as to face the wall 20, a plurality of coupling grooves 230 into which the coupling parts of the plurality of fixing members 300 can be inserted are required. A plurality of fixing members 3000 may be installed on the plurality of coupling grooves 230 so that the frame 200 may face the wall 20. However, It is somewhat difficult to insert into the coupling grooves 230 without error.

5 is fixed so that the engaging portion 310 protrudes to the outside of the frame 200 so that the frame 200 can easily be abutted against the wall 20. As shown in FIG. The fixing member 300 may be inserted into the coupling groove 230 after the frame 200 is positioned on the wall 20 in the case of the fixing member 300 shown in FIG. At this time, a groove (not shown) having a predetermined size is provided on one surface of the coupling part 310 of the fixing member 300 so that the user can more easily rotate the coupling part 310 by using a driver (not shown) The fastening member 300 may be threaded into the coupling groove 230 and inserted into the wall body 20 after passing through the frame 200.

5 does not require a process of inserting the engaging portion 310 into the engaging groove 230 and does not require the thread 322 of the inserting portion 320 and the groove of the engaging portion 310 The frame 200 can be easily fixed by rotating the fixing member 300 through rotation.

4, the effect that the insertion portion 320 is fixed to the wall 20 without being easily dislodged from the hole 21 can be suppressed by the thread 322. Further, since the screw 322 serves as the projection 321 of the fixing member 300 shown in Fig. Can be exercised.

A fixing auxiliary member 400 may be provided between the wall 20 and the fixing member 300 to increase the coupling force between the wall body 20 and the fixing member 300 according to circumstances.

Meanwhile, the external heat insulating system 10 of the present invention may be provided in various forms and methods other than the above-described forms.

Hereinafter, an external heat insulating system 10 according to another embodiment of the present invention will be described. Hereinafter, only different parts from the above-described embodiment will be described in detail, and the same or similar parts will not be described in detail.

FIG. 6 is an exploded perspective view illustrating an external heat insulating system according to another embodiment of the present invention.

6, the adiabatic system 10 includes a heat insulating material 100 provided on the outside of the wall 20, a frame 200 on which the heat insulating material 100 is mounted, And a fixing auxiliary member 400 between the fixing member 300 and the wall 20. [

The heat insulating material 100 is sandwiched between a plurality of lattice spaces 240 formed in a lattice-shaped frame 200 as a plurality of block insulating materials 120.

At this time, the grid space 240 is formed as a plurality of spaces formed by the horizontal frame 210 and the vertical frame 220. In this embodiment, the lattice space part 240 has a rectangular shape. However, the lattice space part 240 can be formed in various shapes according to the shape of the frame 200.

The block insulating material 120 is formed to be larger than the size of the lattice space part 240 or larger than the size of the lattice space part 240 and is coupled to the lattice space part 240 in an interference fit manner.

The block insulating material 120 and the lattice space part 240 can be combined without using a separate joining member or adhesive or the like because the block insulating material 120 is coupled to the lattice space part 240 in an interference fit manner. In addition, since it is simply fitted, it is also effective in terms of workability.

The block insulating material 120 has the same thickness as the depth of the lattice space part 240 so that after the lattice space part 240 is coupled to the lattice space part 240, can do. Thus, the mesh 500 can be easily combined.

As described above, the external heat insulating system 10 of the present invention can be easily and quickly constructed in a prefabricated form using the fixing member 300, the frame 200, and the heat insulating material 100, So that it can be fixed firmly and firmly.

While the present invention has been described with reference to the exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. Those skilled in the art, who understands the spirit of the present invention, can readily suggest other embodiments by adding, changing, deleting, adding, or the like of components within the scope of the same idea, I would say.

10: Exterior insulation system 20: Wall
100: Insulation material 200: Frame
300: fixing member 400: fixing auxiliary member
500: Mesh 600: Finishing material

Claims (11)

A heat insulating material provided on the outside of the wall to prevent heat loss due to heat bridging,
A frame provided between the wall and the heat insulating member and having the heat insulating material mounted thereon,
A plurality of fixing members, one end of which is coupled to the frame and the other end of which is inserted into a hole formed in the wall to fix the frame to the wall,
And a fixing auxiliary member provided between the fixing member and the hole to increase a binding force of the fixing member,
The heat insulating material has an inserting groove formed in a lattice shape having the same shape as that of the frame so that the frame formed in the lattice shape is inserted into the heat insulating material,
Wherein the fixing member has a coupling portion that engages with the frame and an insertion portion that is inserted into the hole,
Wherein the frame comprises a plurality of horizontal frames horizontally aligned with the ground and a plurality of vertical frames perpendicular to the horizontal frames,
Wherein the horizontal frame and the vertical frame have a plurality of coupling grooves that engage with the fixing member,
Wherein the engaging portion is formed to have a size equal to or greater than a size of the engaging groove and to be inserted into the engaging groove in an interference fit manner.
delete The method according to claim 1,
Wherein the insertion portion has a plurality of projections on a surface thereof,
Wherein the protrusion has a sharp edge and has an inclined surface formed in a direction in which the insertion portion is inserted into the hole and an engagement surface formed in a direction in which the insertion portion comes out of the hole.
The method according to claim 1,
Wherein the inserting portion is provided with a thread on a surface thereof.
delete delete The method according to claim 1,
Wherein a mesh-like mesh for easily attaching a finishing material is coupled to the other surface of the heat insulating material.
A heat insulating material provided on the outside of the wall to prevent heat loss due to heat bridging,
A frame provided between the wall and the heat insulating member and having the heat insulating material mounted thereon,
A plurality of fixing members, one end of which is coupled to the frame and the other end of which is inserted into a hole formed in the wall to fix the frame to the wall,
And a fixing auxiliary member provided between the fixing member and the hole to increase a binding force of the fixing member,
Wherein the heat insulating material has a plurality of block heat insulating materials sandwiched in a plurality of lattice spaces formed in the grid-shaped frame,
Wherein the fixing member has a coupling portion that engages with the frame and an insertion portion that is inserted into the hole,
Wherein the frame comprises a plurality of horizontal frames horizontally aligned with the ground and a plurality of vertical frames perpendicular to the horizontal frames,
Wherein the horizontal frame and the vertical frame have a plurality of coupling grooves that engage with the fixing member,
Wherein the engaging portion is formed to have a size equal to or greater than a size of the engaging groove and to be inserted into the engaging groove in an interference fit manner.
delete 9. The method of claim 8,
Wherein the insertion portion has a plurality of projections on a surface thereof,
Wherein the protrusion has a sharp edge and has an inclined surface formed in a direction in which the insertion portion is inserted into the hole and an engagement surface formed in a direction in which the insertion portion comes out of the hole.
9. The method of claim 8,
Wherein the inserting portion is provided with a thread on a surface thereof.

Images