KR101379279B1 - Outside insulation system and construction methods - Google Patents

Abstract

An outside insulation system according to one aspect of the present invention comprises an insulation panel which is disposed on the outer side of a wall and prevents heat loss due to a heat bridge; a fiber-based insulator which is disposed between the wall and the insulation panel and conducts planarization to make the surface of the wall be perpendicular to the ground, a fixing material which is inserted into the wall by passing through the insulation panel and the fiber-based insulator and fixing the insulation panel and the fiber-based insulator to the wall by flexible movement, and an elastic fixing pin which is disposed outside the insulation panel and controls the movement of the flexible fixing material in combination with the fixing material.

Description

Outside Insulation System And Construction Methods

The present invention relates to an external insulation system and a construction method, and more particularly, to an external insulation system and a construction method that can be constructed simply and quickly by a dry prefabricated configuration.

In general, the building, which is a residential space, should be constructed with an insulation structure for cooling as well as heating.

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

Heat-resistant system has high energy loss due to heat bridge and cold bridge phenomena through the structure. Therefore, in recent years, thermal insulation and cold bridge phenomena are fundamentally used, and the external thermal insulation system with low energy loss is mainly used.

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

In the wet system, the insulation is attached to the entire outer wall of the building by adhesive mortar, etc., and then an intermediate layer such as fiber mortar, glass fiber, and mesh is laid on the surface of the insulation attached to the outer wall, and the embossed finish is applied to the surface. It is to apply.

Since the wet system is constructed without an expansion joint that absorbs the contraction and expansion of the entire outer wall of the building, there is a problem that cracks and surface layers are cracked due to different shrinkage and expansion ratios depending on the temperature of the constructed insulation, intermediate layer, and finish. .

In addition, the wet system is adhered to the outer wall of the building by adhesive bonding using adhesive mortar, so durability is not guaranteed even in the life cycle limit of the building, thereby causing peeling of the insulation.

The improvement of the wet system as described above is a dry system that is constructed by stacking a plurality of insulation panels manufactured to a certain standard represented by a dry bit using a connecting hardware such as fasteners.

However, the conventional dry system has a problem that the cumbersome and difficult to construct the connecting hardware, and consequently the construction is not easy.

In addition, since there is no consideration of the connection parts between the insulation panels, heat or cold air escapes through the connection parts, resulting in a large energy loss, and the coupling between the connection hardware and the insulation panels is not stable, such that the insulation panels are dropped. The problem is still scattered.

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

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

External insulation system according to an aspect of the present invention for achieving the above object is provided on the outside of the wall to prevent heat loss by the thermal bridge, and provided between the wall and the insulation panel of the wall A fibrous insulation material for flattening the surface to be perpendicular to the ground, and a fixing member inserted through the insulation panel and the fibrous insulation material and inserted into the wall to move elastically to closely fix the insulation panel and the fibrous insulation material to the wall; It may include an elastic fixing pin which is provided on the outside of the heat insulating panel and controls the movement of the fixing material moving in combination with the fixing material.

The fixing material is an elastic material for elastically moving the fixing material, an anchor connected to one end of the elastic material and inserted into the wall to fix the fixing material to the wall, and connected to the other end of the elastic material, the insulation panel and the It may be provided with a heat insulating material fixing pin penetrating the fiber-based heat insulating material.

The anchor has a first coupling protrusion coupled to one end of the elastic material therein, a locking jaw that prevents the heat insulating material fixing pin from being inserted into the anchor more than a predetermined depth, and the heat insulating material fixing pin is separated from the outside of the anchor. It may be provided with a departure prevention jaw to prevent.

The heat insulating material fixing pin may include a plurality of through holes through which the elastic fixing pin passes, a second coupling protrusion coupled to the other end of the elastic material, and a locking protrusion caught by the locking jaw and the release preventing jaw.

The heat insulating material fixing pin may be sharply formed at one end to easily penetrate the heat insulating panel and the fibrous insulation material.

A fixing plate may be further provided between the elastic fixing pin and the heat insulation panel to lower a physical force application area of the elastic fixing pin.

The fixing plate may include a plurality of insertion grooves into which a fixing member for fixing a separate finishing material installed outside the insulation panel is inserted.

In addition, the outer insulation system according to one side of the present invention for achieving the above object comprises the steps of: (a) inserting a fixing member having an elastic material and the one end is pointed; (b) coupling a fibrous insulation to the fixing member so that one end of the fixing member protrudes; (c) coupling a heat insulation panel to the fixing member such that one end of the fixing member protrudes and faces a fibrous insulation material; (d) pulling the one end of the fixing member so that the fixing member has an elastic force and then inserting an elastic fixing pin to fix the fixing member; . ≪ / RTI >

After pulling the one end of the fixing material so that the fixing material has an elastic force may be further provided with a step of cutting one end of the fixing material after the step of fixing the fixing material by inserting an elastic fixing pin.

After pulling the one end of the fixing member and before the step of fixing the fixing member by inserting the elastic fixing pin may further comprise the step of coupling the fixing plate for lowering the physical force application area of the elastic fixing pin.

According to the external insulation system according to the present invention, it can be easily and quickly installed through a dry type method using a fixing material and a heat insulating material.

In addition, by using the restoring force of the elastic material provided in the fixing material, the heat insulating material can be fixed to the wall elastically to firmly fix the heat insulating material to the wall and to be in close contact.

1 is a cross-sectional view of an outer insulation system according to an embodiment of the present invention.
Figure 2 is an enlarged cross-sectional view of the fixing member according to an embodiment of the present invention.
Figure 3 is a front view and a side view of the heat insulating material fixing pin according to an embodiment of the present invention.
4 is a cross-sectional view of the end of the insulating material fixing pin shown in FIG.
5 is a flow chart of the construction method of the outer insulation system according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the thermal insulation system and construction method according to an embodiment of the present invention.

1 is a perspective view showing an outer insulation system according to an embodiment of the present invention.

As shown in FIG. 1, the external insulation system 10 according to an embodiment of the present invention includes an insulation panel 100 provided on an outer side of the wall 20, the wall 20, and the insulation panel 100. A fibrous insulation material 200 provided between the fixing member 300 and the fixing member 300 to elastically fix the insulation panel 100 and the fibrous insulation material 200 to the wall 20, and the movement of the fixing member 300. It is provided with an elastic fixing pin 400 to control.

The insulation panel 100 is provided over the outer front surface of the wall 20 to prevent heat loss by blocking a thermal bridge that can occur between the inside and the outside of the structure.

As a material used for the insulation panel 100, foamed polystyrene foam or styrofoam may be used.

Can be. When styrofoam is used as the material of the insulation panel 100, the compressive strength is 16 N / cm ² The above styrofoam can be used.

 And, the size of the insulation panel 100 may be manufactured in 1200mm X 900mm, it may be produced in various sizes depending on the size or shape of the wall (20).

The fibrous insulation 200 is provided between the wall 20 and the insulation panel 100 to form a double composite panel together with the insulation panel 100.

Since the fibrous insulation material 200 is provided between the wall 20 and the heat insulation panel 100, the fibrous insulation material 200 may be flattened to be perpendicular to the ground by supplementing the surface of the uneven or curved wall 20. As a result, a gap may not be generated between the wall 20 and the heat insulation panel 100, so that more efficient heat insulation may be realized, and an effect of increasing the degree of completion of the final finish may be obtained.

As the fibrous material forming the fibrous insulation 200, glass fibers, rock wool, polyester and fibers may be used.

The insulation panel 100 and the fibrous insulation 200 are fixed to the wall 20 by the fixing member 300.

The fixing member 300 includes an anchor 320 inserted into and fixed to the wall 20, and a heat insulating fixing pin 330 provided to protrude out of the wall 20. The insulation panel 100 and the fibrous insulation 200 are penetrated and fixed through the insulation fixing pin 330.

One end of the heat insulating material fixing pin 330 is inserted into the anchor 320 and connected to the anchor 320. The heat insulating material fixing pin 330 and the anchor 320 are connected by the elastic material 310. Accordingly, the insulation fixing pin 330 can be moved elastically.

The elastic material 310 may be a material having a restoring force such as spring, rubber and silicon.

In addition, an elastic fixing pin 400 is provided on one surface of the heat insulation panel 100 which does not come into contact with the fibrous insulation material 200. The elastic fixing pin 400 penetrates the through-hole 331 of the heat insulating material fixing pin 330 to be described later so as to abut one surface of the heat insulating panel 100 that is not against the fibrous insulation material 200.

The elastic fixing pin 400 is provided to control the movement of the insulating material fixing pin 330 that is elastically moved by the elastic material 310.

On the other hand, the fibrous insulation 200 and the heat insulation panel 100 is in close contact with the wall 20 by the anchor 320, the elastic material 310, the heat insulating material fixing pin 330 and the elastic fixing pin 400. Can be fixed.

For example, in the state in which the fibrous insulation 200 and the insulation panel 100 are coupled to the fixing member 300, the insulation fixing pin 330 is pulled out and the elastic fixing pin 400 penetrates the through hole 331. When the insulating material fixing pin 330 is placed after the coupling, the insulating material fixing pin 330 is moved in the direction of the wall 20 by the restoring force of the elastic material 310. ) It can also be fixed in close contact with the wall 20 is moved in the direction of the wall (20).

In addition, as mentioned above, since the elastic fixing pin 400 is provided to face one surface of the insulating panel 100, the insulating material fixing pin 330 may move toward the wall 20 by the restoring force of the elastic member 310. When moving together with the insulating material fixing pin 330 serves to apply a pushing force to the insulating panel 100 can be further in close contact.

However, the elastic fixing pin 400 is limited in size because it is coupled through the through-hole 331 of the heat insulating material fixing pin 330. Therefore, the elastic fixing pin 400 penetrates the insulation panel 100 by the restoring force of the elastic material 310 and may cause a problem of being inserted into the insulation panel 100. In order to prevent this problem, the fixing plate 500 is provided between the insulating panel 100 and the elastic fixing pin 400.

The fixing plate 500 has a coupling groove 520 into which the heat insulating material fixing pin 330 is inserted and coupled, and the heat insulating material fixing pin 330 is inserted into the coupling groove 520 and the size of the elastic fixing pin 400. It can be made larger.

In addition, the shape of the fixing plate 500 may be formed in various forms such as a circle, a square and a triangle, and the fixing plate 500 itself may be used as the finishing material 600 without installing a separate finishing material 600.

Since the fixing plate 500 is provided between the elastic fixing pin 400 and the insulating panel 100, the physical force application area of the elastic fixing pin 400 is lowered, so that the elastic fixing pin 400 as described above is used to make the insulating panel 100. It is possible to prevent a problem that is penetrated and inserted into the insulation panel 100.

In addition, the fixing plate 500 is provided so as to be in contact with the insulating panel 100, so that when the elastic fixing pin 400 moves in the direction of the wall 20 by the restoring force of the elastic material 310, the fixing plate 500 also moves together. The fibrous insulation 200 and the insulation panel 100 may be fixed to the wall 20 by a strong force.

On the other hand, the fixing plate 500 is provided with an insertion groove 510 is inserted into the fixing member 610 for fixing the finishing material 600 when installing a separate finishing material 600 outside the insulation panel 100.

At this time, when the fixing plate 500 is used by hard plastics, wood panels, reinforced plastics, etc., the finishing material 600 may be installed through fixing members 610 such as screws.

Since the fixing member 610 for fixing the finishing material 600 is provided on the fixing plate 500 without being fixed to the heat insulating panel 100, thermal bridge phenomenon by the fixing member 610 does not occur, so that the heat insulating material may be more effectively insulated.

Next, the fixing member 300 will be described in more detail.

2 is an enlarged cross-sectional view showing a fixing member according to an embodiment of the present invention, Figure 3 is a front view and a side view showing a heat insulating material fixing pin according to an embodiment of the present invention, Figure 4 is a heat insulating material fixing pin shown in FIG. It is sectional drawing which shows the state which the terminal of is cut | disconnected.

As shown in FIG. 2, the fixing member 300 according to the exemplary embodiment of the present invention includes an anchor 320 inserted into the wall 20, a fibrous insulation 200, and a heat insulating panel 100. It is provided with a heat insulating material fixing pin 330 to be fixed to, and an elastic material 310 to elastically move the heat insulating material fixing pin 330.

The anchor 320 has a predetermined length and may be formed in a cross-sectional shape of various shapes such as a circle, a rectangle, and a triangle.

The anchor 320 forms an inner space, the first coupling protrusion 321 having one end of the elastic material 310 connected to one surface provided with an elastic material 310 and provided in the direction in which the heat insulating material fixing pin 330 is inserted. It is provided.

The first coupling protrusion 321 may be manufactured integrally with the anchor 320 so that the restoring force of the elastic material 310 may be effectively exhibited. In this embodiment, the first coupling protrusion 321 has a rectangular shape. The first coupling protrusion 321 may be formed in various forms.

The anchoring jaw 322 is provided in the longitudinal direction of the anchor 320 to prevent the insulation fixing pin 330 from being inserted beyond a predetermined depth by the restoring force of the elastic material 310. If the locking jaw 322 is not provided, the shape of the elastic member 310 may be deformed or destroyed by an impact caused by the restoring force of the elastic member 310, thereby preventing the restoring force from being exerted. Therefore, the locking jaw 322 may be provided inside the anchor 320 to prevent the above problem.

The locking jaw 322 may be provided in plurality in accordance with the shape or location of the anchor 320. And, like the first coupling protrusion 321 may be manufactured integrally with the anchor 320.

In addition, at the end of the longitudinal direction of the anchor 320 in which the heat insulating material fixing pin 330 is inserted into the anchor 320, one end of the heat insulating material fixing pin 330 is prevented from escaping to the outside of the anchor 320. 323 is provided.

The release prevention jaw 323 is a user pulls the insulation fixing pin 330 excessively, the insulation fixing pin 330 is separated from the anchor 320 so that the insulation fixing pin 330 is elastically moved by the elastic material 310. It is provided to prevent the problem that does not occur.

And, it may be provided in plurality in accordance with the shape of the anchor 320, it may be manufactured integrally with the anchor 320.

In addition, the gap between the locking jaw 322 and the separation prevention jaw 323 allows the elastic material 310 to be maintained in the range in which the elastic material 310 is not damaged while maximizing the restoring force.

For example, when the gap between the locking step 322 and the separation prevention step 323 is very narrow, the activity range that the insulation fixing pin 330 can move elastically narrow can effectively exhibit the restoring force of the elastic material 310. none. On the contrary, in the case where the gap between the locking step 322 and the separation prevention step 323 is very wide, the restoring force of the elastic material 310 may be exerted effectively because the insulating material fixing pin 330 has a wide range of activity that can be moved elastically. The shape of the elastic material 310 may be deformed or destroyed by an impact caused by excessive restoring force. Therefore, it is effective to provide the locking jaw 322 and the separation prevention jaw 323 within the range in which the elastic material 310 is not damaged while exhibiting the restoring force of the elastic material 310 to the maximum.

Insulating material fixing pin 330 has a predetermined length and one end is inserted into the anchor 320, it may be formed in a cross-sectional shape of various forms similar to the anchor 320.

The heat insulating material fixing pin 330 is provided with a second coupling protrusion 332 protruding from the other end of the elastic material 310 to one end inserted into the anchor 320. In the present embodiment, the shape of the second coupling protrusion 332 was shown to be rectangular. The second coupling protrusion 332 may be formed in various forms.

In addition, the locking projection 333 is provided to protrude in the width direction of the heat insulating material fixing pin 330 in the space formed between the locking jaw 322 and the separation prevention jaw 323 provided in the anchor 320. The locking protrusion 333 is located in a space formed between the locking jaw 322 and the release preventing jaw 323, so that the movement of the insulation fixing pin 330 is prevented from being separated out of the anchor 320. The movement is proposed by the locking step 322 so as not to be excessively inserted in the direction of the elastic material 310. The locking protrusion 333 may be provided in plural numbers according to the shape of the heat insulating material fixing pin 330.

On the other hand, the other end of the heat insulating material fixing pin 330 is protruded to the outside of the heat insulating panel 100 after the fiber-based heat insulating material 200 and the heat insulating panel 100 are combined. The other end of the heat insulating material fixing pin 330 is formed in a pointed shape so that the fiber-based heat insulating material 200 and the heat insulating panel 100 can be easily inserted. Thus, the user can easily slide in and engage.

In addition, the heat insulating material fixing pin 330 includes a through hole 331 through which the elastic fixing pin 400 for controlling the movement of the heat insulating material fixing pin 330 passes.

The through hole 331 may be provided in plural to maintain a predetermined interval to couple the elastic fixing pin 400 to the insulating fixing pin 330 according to the thickness or the situation of the insulating panel 100. Therefore, the user can easily couple the elastic fixing pin 400 according to the situation.

In addition, one end of the sharply formed heat insulating material fixing pin 330 may be cut using a cutting equipment (not shown) after the fibrous heat insulating material 200 and the heat insulating panel 100 are combined.

The reason for cutting one end of the sharply formed heat insulating material fixing pin 330 is to make it easy to install the finishing material 600 to be installed later. When cutting, the elastic fixing pin 400 may be cut as close as possible to the combined position so that the cutting surface may form the same surface as the heat insulating material fixing pin 330.

Next, the construction method of the outer insulation system 10 will be described.

Figure 5 is a flow chart of the construction method of the outer insulation system according to an embodiment of the present invention.

As shown in FIG. 5, the construction method of the outer insulation system 10 according to an embodiment of the present invention includes (a) an elastic member 310 and a fixing member 300 having one end pointed to a wall 20. Inserting in step S110; (B) step (S120) of coupling the fibrous-based heat insulator 200 to the fixing member 300 so that one end of the fixing member 300 protrudes; (c) coupling the heat insulation panel 100 to the fixing material 300 such that one end of the fixing material 300 protrudes and is opposed to the fibrous insulation material 200 (S130); And (d) pulling the one end of the fixing member 300 so that the fixing member 300 has an elastic force, and then inserting the elastic fixing pin 400 to fix the fixing member 300 (S140).

And, although not shown in the drawing (d) after pulling the one end of the fixing member 300 so that the fixing member 300 has an elastic force after the step of fixing the fixing member 300 by inserting the elastic fixing pin 400 It may further comprise a step (S150) of cutting one end of the fixing member 300, (d) after pulling the one end of the fixing member 300 is inserted into the elastic fixing pin 400 to fix the fixing member 300 Prior to the step may further comprise a step (S160) for coupling the fixing plate 500 to lower the physical force application area of the elastic fixing pin 400.

As described above, the outer insulation system 10 of the present invention is provided with a fibrous-based insulation 200 to form a double-composite panel together with the insulation panel 100 to cover the surface of the uneven or curved wall 20. It can supplement and realize more efficient heat insulation.

In addition, the elastic member 310 may be provided inside the fixing member 300 to move elastically, and thus the fibrous insulation 200 and the insulation panel 100 may be tightly fixed to the wall 20.

In addition, it is possible to achieve the effect of reducing the overall construction cost because the construction can be easily and quickly carried out by the dry construction method of the prefabricated form by assembling each member to shorten the construction period.

In the above described the external insulation system and construction method according to an embodiment of the present invention, the spirit of the present invention is not limited to the embodiments presented herein. 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: thermal insulation system 20: wall
100: insulation panel 200: fibrous insulation
300: fixing material 400: elastic fixing pin
500: fixed plate 600: finish

Claims (10)

An insulation panel provided outside the wall to prevent heat loss due to the thermal bridge;
A fibrous insulation material provided between the wall and the insulation panel to flatten the surface of the wall to be perpendicular to the ground;
A fixing member inserted into the wall and elastically moving through the insulating panel and the fibrous insulating material to tightly fix the insulating panel and the fibrous insulating material to the wall;
An elastic fixing pin which is provided on the outside of the heat insulation panel and controls the movement of the fixing member in combination with the fixing member;
The thermal insulation system provided between the elastic fixing pin and the insulating panel having a fixing plate for lowering the physical force applied area of the elastic fixing pin.
The method according to claim 1,
The fixing material is an elastic material to elastically move the fixing material,
An anchor connected to one end of the elastic material and inserted into the wall to fix the fixing material to the wall;
And an insulating material fixing pin connected to the other end of the elastic material and penetrating the insulating panel and the fibrous-based insulating material.
3. The method of claim 2,
The anchor has a first coupling protrusion coupled to one end of the elastic material therein,
A catching jaw to prevent the insulation fixing pin from being inserted into the anchor more than a predetermined depth;
External insulation system characterized in that it has a release preventing jaw to prevent the insulating material fixing pin is separated from the outside of the anchor.
The method of claim 3,
The insulating material fixing pins and a plurality of through holes to allow the elastic fixing pins to penetrate;
A second coupling protrusion coupled to the other end of the elastic material,
External insulation system characterized in that it comprises a locking projection to be caught by the locking jaw and the separation prevention jaw.
3. The method of claim 2,
The heat insulating material fixing pin is characterized in that one end is formed pointed to easily penetrate the heat insulating panel and the fibrous insulation.
delete The method according to claim 1,
The fixing plate has an outer insulation system, characterized in that it has a plurality of insertion grooves into which a fixing member for fixing a separate finishing material is installed outside the insulation panel.
(a) inserting a fixing member having an elastic material and having a pointed end to a wall;
(b) coupling a fibrous insulation to the fixing member so that one end of the fixing member protrudes;
(c) coupling a heat insulation panel to the fixing member such that one end of the fixing member protrudes and faces a fibrous insulation material;
(f) of elastic retaining pins. Coupling a fixed plate for lowering the physical force application area; And
(d) pulling the one end of the fixing member so that the fixing member has an elastic force and then inserting an elastic fixing pin to fix the fixing member; External insulation construction method comprising a.
9. The method of claim 8,
(d) pulling the one end of the fixing material so that the fixing material has an elastic force and then inserting an elastic fixing pin to fix the fixing material, and (e) cutting the one end of the fixing material further comprising: .


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