KR20160022208A - The Assembling Type Guiding Insulation Used To Exterior Insulation Method - Google Patents

Abstract

The present invention relates to a heat insulating material used in an outer heat insulating method of a building, wherein the heat insulating material has a front surface, a rear surface which is the opposite surface of the front surface, a first side surface, a second side surface opposite to the first side surface, A plurality of first protrusions protruding in a predetermined cross-sectional shape are provided on the first side surface, the first protrusions being spaced apart from each other by a predetermined distance, and the second side surface A plurality of second binding grooves that are recessed to correspond to the shapes of the first projections are formed at positions corresponding to the first projections provided on the first side surface, The third side surface is provided with a third protruding portion. The fourth side surface is provided with a fourth binding groove recessed corresponding to the shape of the third protrusion at a position corresponding to the third protrusion provided on the third side surface. Wherein the first and third protrusions and the fourth and the fourth binding grooves are connected to each other in the vertical and horizontal directions.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an assembly type guiding insulation material used in an outer insulation method,

More particularly, the present invention relates to a heat insulating material used for external heat insulation, in which a plurality of heat insulating materials are vertically, laterally, and laterally fitted, adjacent heat insulating materials are simultaneously fixed by an anchor, and a plurality of adhesive inducing portions The present invention relates to an assembly type guiding insulation material used for external heat insulation.

The insulation method used to improve the insulation performance of a building is divided into internal insulation, interrupted heat, and external insulation depending on the location of the insulation. Of these, the external insulation method requires insulation to be attached to the outside of the building, It is a method of closing the outside of the insulation with an exterior finishing material that can complement the impact resistance.

This method is capable of completely covering the outside of the building with the heat insulating material, so that it is possible not only to remove the heat insulating discontinuity but also to be able to be installed outside the already built building.

Also, the easiest and cheapest method among these external insulation methods is to install the bead method insulation using styrofoam on the outer surface of the building frame, and to finish the outer surface thereof with the mortar mortar.

In Korea, this method was introduced in the 1980s, but it has been recognized as a cheap method and has been rarely utilized. Recently, the need for external insulation has attracted attention.

In Europe, on the other hand, the standard specification for such an external insulation method clearly shows the detailed details to be followed up to a very small detail throughout the technology. Of course, Korea has prepared and published its standards, but it is not much compared with Europe.

That is, when the insulation is adhered to the external insulation method, it can be expected to have a high quality finish according to the European standard specification specifications as well as the domestic specification standards. However, only a small number of specialists such as European standard specifications are aware of this, and even technical training is not conducted for professional construction companies or workers who directly construct them.

As a result, the workers who directly install the insulation material used in the external insulation method are often constructed only by experience or custom, and there is a problem that the insulation material is separated from the external wall as shown in FIG.

SUMMARY OF THE INVENTION The present invention has been made to overcome the above-described problems of the related art, and its object is as follows.

First, it is intended to provide an assembly type guiding insulation material which is used in an outer insulation construction method in which the adjacent insulation materials are fitted together by vertically and horizontally fitting together and an adjacent insulation material is fixed at the same time.

Another object of the present invention is to provide an assembly type guiding insulation material used in an external heat insulation method that can prevent a heat bridge phenomenon by providing an anchor lid which covers the head part of an anchor inserted and fixed through an anchor insertion part.

Third, it is intended to provide an assembly type guiding insulation material which is used in an outer insulation method in which a plurality of adhesive inducing portions protruding from the rear surface beyond a specified area are provided to induce stable adhesion.

Fourthly, the present invention provides an assembly type guiding insulation material which is used in an outer insulation method in which a construction site, a physical property, a gluing method, and the like are printed on the front and rear surfaces by letters.

According to an aspect of the present invention, there is provided a heat insulating material for use in an outer heat insulating method of a building, the heat insulating material including a front surface, a rear surface, a first side surface opposite to the front surface, A third side surface adjacent to the first and second side surfaces, and a fourth side surface opposite to the third side surface, wherein the first side surface has a first protrusion protruding in a predetermined cross- Wherein a plurality of second binding grooves are formed in the second side surface at positions corresponding to the first protrusions provided on the first side surface to correspond to the shapes of the first projections, And a third protrusion protruding in a shape of a predetermined cross section is provided on the side surface, and a third protrusion formed on the fourth side surface at a position corresponding to the third protrusion provided on the third side surface to correspond to the shape of the third protrusion Is provided with a fourth coupling groove into hooked, insulation is laminated construction is characterized in that each of the projections 1,3 and a-2,4 bond in vertical and horizontal grooves connecting to each other the male and female counterparts.

In addition, the heat insulating material of the present invention includes a plurality of anchor inserting portions which are perforated to penetrate through the front and rear surfaces in a predetermined section, and an adhesive inducing portion protruding at a predetermined height in a predetermined shape at a recessed portion of the rear surface. Characterized in that the physical properties and the construction range of the heat insulating material are printed by letters and the method of applying the adhesive to the surface of the back surface of the heat insulating material is printed by letters.

According to the present invention, the following effects are expected.

First, it is easy to laminate construction, improving workability and shortening construction period.

In other words, in the heat insulating material of the present invention, the protruding portions and the coupling grooves are coupled to each other in a vertical and a left-right fitting manner corresponding to male and female, so that a plurality of the heat insulating materials can be easily and easily laminated without tearing.

At this time, the first projecting portion on the front side and the second coupling groove on the rear side are arranged in such a manner that a pair of different shapes cross each other diagonally, and a heat insulating material is stacked in a clogged joint manner, so that a stable structure can be formed.

Second, the adjacent heat insulating materials are simultaneously fixed in a form in which the anchors are shared, so that the bonding force is improved, and the anchor lid covering the head portion of the anchor is provided, thereby preventing the heat bridge phenomenon.

Thirdly, since a plurality of adhesive inducing portions protruding from the rear surface in a predetermined area or more are provided, it is possible to induce stable attachment, thereby preventing a troublesome installation in advance.

In addition, by using an appropriate amount of adhesive mortar or the like for the adhesive guide portion, it is possible to prevent the waste and reduce the construction cost.

Fourth, since the construction site, the physical properties, the bonding method, and the like are printed on the front and back surfaces by letters, it is possible to easily construct even the unskilled person.

In other words, even if the related technicians, including the skilled workers participating in the construction, are not familiar with the detailed specifications of the standard specification, the standard specification can be obtained by easy construction according to the guide of the characters printed on the surface, It provides a consistent standard for the method, quantifies the amount of work required for construction, and can calculate the appropriate construction cost.

1 is a photograph showing a problem caused by a conventional external heat insulating method.
FIG. 2 is an exploded perspective view of a front surface of an assembled type guiding insulation material used in the outer insulation method according to the present invention.
3 is a perspective view of the rear surface of the assembled type guiding insulation material used in the outer insulation method according to the present invention.
FIG. 4 is a cross-sectional view illustrating that an assembled type guiding insulation material used in an outer heat insulating method according to the present invention is bonded to a structure of a building.
FIG. 5 shows various embodiments in which the assembled type guiding insulation material used in the outer insulation method according to the present invention can be applied to each construction layer.
FIG. 6 shows an embodiment in which the assembly type guiding insulation material used in the outer heat insulating method according to the present invention is laminated in a clogged joint manner.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is an exploded perspective view of the front surface 110 of the assembled type guiding insulation material 100 used in the outer insulation method according to the present invention, and FIG. 3 is an exploded perspective view of the assembled guiding insulation material 4 is a cross-sectional view illustrating that the assembled guiding insulation material 100 used in the outer heat insulating method according to the present invention is bonded to the structure of the building.

The present invention relates to a heat insulating material 100 used in an outer heat insulating method of a building, wherein the heat insulating material 100 has a front surface 110, a rear surface 120, which is the opposite surface of the front surface 110, A third side 150 adjacent to the first and second sides 130 and 140 and a fourth side 160 opposite to the third side 150. The second side 140 is opposite to the first side 130, And a plurality of first protrusions 132 protruding in a predetermined cross-sectional shape are spaced apart from each other by a predetermined distance, and the second side surface 140 is provided with a plurality of first protrusions 132, A plurality of second binding grooves 142 that are recessed to correspond to the shapes of the first projecting portions 132 are provided at positions corresponding to the first projecting portions 132 provided on the third side surfaces 150 And a third protrusion 152 protruding in a predetermined cross-sectional shape is provided on the third side surface 150 and a third protrusion 152 protruded in a shape corresponding to the third protrusion 152 provided on the third side surface 150 And a fourth binding groove 162 which is recessed to correspond to the shape of the third protrusion 152 is provided at a position of the second protrusion 152. The heat insulation material 100 to be laminated is formed of the first and third protrusions 132, And the binding grooves (142, 162) are connected to each other in the upper, lower, left, and right directions in correspondence with each other.

The heat insulating material 100 of the present invention is integrally molded and formed of a hexahedron having six surfaces including a front surface 110, a rear surface 120, and first, second, third and fourth sides 130, 140, 150 and 160. Such a heat insulating material 100 may be made of various materials such as minerall and phenol foam, and it may be molded by EPS (Expanded Poly-Styrene) to reduce the construction cost.

The front surface 110 refers to the front surface when the heat insulating material 100 is fixed to the structure of the building and the rear surface 120 refers to the surface opposite to the front surface 110, it means.

The first side surface 130 refers to a surface facing upward when the heat insulating material 100 is fixed to the structure of the building and the second side surface 140 is located on the opposite side of the first side surface 130, Surface. In addition, the third and fourth sides 150 and 160 refer to the surfaces of the heat insulating materials 100 that are connected to each other.

At this time, a plurality of first protrusions 132 are formed on the first side face 130 and a second binding groove 142 is formed on the second side face 140 so that the heat insulating material 100 is vertically connected .

The first protrusions 132 are integrally formed so as to protrude from the first side surface 130 at a predetermined angle, and a plurality of the protrusions 132 are spaced apart from each other by a predetermined distance.

And a plurality of second binding grooves 142 corresponding to the second binding grooves 142 are spaced apart from each other by a predetermined distance in the form of an inwardly fined shape at the second side 140 opposite to the first side 130.

The first projecting portion 132 and the second binding groove 142 are formed at corresponding positions corresponding to each other. As shown in FIG. 2, the first projecting portion 132 and the second binding groove 142 are formed in a tapered cross- .

In other words, the heat insulating material 100 located at the lower side is installed in such a manner that the first side face 130 is viewed upward, and the heat insulating material 100 located at the upper side is installed such that the second side face 140 faces downward. The first projecting portion 132 formed on the first side face 130 of the heat insulating member 100 is engaged with the second binding groove 142 formed on the second side face 140 of the heat insulating material 100 mounted on the upper face And the heat insulating material 100 are connected to each other.

Furthermore, the first protrusions 132 and the second binding grooves 142 formed on the first and second side surfaces 130 and 140 of the heat insulating material 100 may have various numbers and shapes.

On the other hand, a third protrusion 152 is formed on the third side face 150 and a fourth binding groove 162 corresponding to the third side face 150 is formed on the fourth side face 160 so that the heat insulating material 100 is assembled left and right.

The third protrusion 152 is formed integrally with the third side surface 150 so as to protrude from the third side surface 150. The first protrusion 132 may have the same shape as the first protrusion 132.

The corresponding fourth binding groove 162 is formed at a position corresponding to the third protrusion 152 in a shape corresponding to the third protrusion 152 inwardly in the fourth side 160 opposite to the third side 150 .

The third projecting portion 152 and the fourth binding groove 162 preferably have a tapered cross section for the same reason as the first projecting portion 132 and the second binding groove 142 described above, And serves to connect the heat insulating materials 100 disposed therebetween.

In addition, the third protrusion 152 and the fourth binding groove 162 formed on the third and fourth sides 150 and 160 of the heat insulating material 100 may be formed in various shapes.

The heat insulating material 100 of the present invention further comprises a plurality of anchor inserting portions 170 punctured to penetrate the front surface 110 and the rear surface 120 in a predetermined section, The upper surface of the heat insulating material 100 is fixed to the head portion of the anchored fastener 100 while the lower surface thereof is in contact with the upper surface of the heat insulating material 100, A plurality of anchor lids 180 fitted into the anchor insertion portions 170 to flatten the front surface 110 are provided in the anchor insertion portion 170. The anchor insertion portions 170 are provided on the anchor insertion portion 170, And at the same time, the body portion of the anchor A is closely inserted into the body.

The anchor insertion portion 170 is configured to penetrate the front surface 110 and the rear surface 120 of the heat insulating material 100 and is used as a space into which the anchor A for fixing the heat insulating material 100 to the structure of the building is inserted do.

As shown in FIG. 4, the anchor A is engaged with the head portion of the anchor A in the middle, and the anchor A is inserted into the body portion It is preferable that it is formed in a cross-section that can be inserted and passed through in close contact.

At this time, the anchor insertion portion 170 has a circular cross-section at the inner surface of the front surface 110 and the rear surface 120, and has a semicircular cross-section at each side, and has a fan-shaped cross-section at each corner. The anchor A inserted into the formed anchor insertion portion 170 can simultaneously fix two or more heat insulation materials 100 connected to the upper and lower sides or the left and right sides. Particularly, the shapes of the anchor insertion portions 170 formed at the sides and corners of the heat insulating material 100 are configured to be fixed at the same time when the adjacent heat insulating materials 100 are connected to each other. Accordingly, a plurality of the heat insulating materials 100 coupled to the outer surface of the structure, Can be stably coupled to each other.

After the anchor A is inserted and fixed to the anchor insertion part 170, the anchor lid 180 is inserted into the space of the anchor insertion part 170, which is empty over the head part of the anchor A,

The anchor cover 180 is constructed such that its bottom surface is in contact with the head portion of the anchor A and its upper surface is flat so as not to be stepped from the front surface 110 of the heat insulating material 100. The same material as the material of the heat insulating material 100 . Particularly, the anchor lid 180 can be closely attached to the anchor insertion part 170 without any error, when the heat insulating material 100 is molded. Such an anchor lid 180 exhibits an effect of interrupting the heat bridging which prevents the heat from being transmitted to the inside through the anchor A and serves to provide a flat base surface when the laying of the anchor lid 180 is performed later, It is possible to provide an appearance.

The back surface 120 of the heat insulating material 100 according to the present invention is formed in a recessed shape with a predetermined area inside and is provided with an adhesive inducing part 122 protruding at a predetermined height in a predetermined form at a recessed part of the rear surface 120 of the heat insulating material 100, And the protruded area of the rear surface 120 including the plurality of adhesive inducing portions 122 may be 40% or more of the total area of the rear surface 120. [

In the heat insulating material 100 of the present invention, a relatively low space is formed on the inner surface of the rear surface 120, and a plurality of adhesive inducing portions 122 are formed in this space.

As shown in FIG. 3, the adhesive inducing portion 122 is formed by a plurality of projecting portions in the shape of a predetermined cross section in a low stepped space of the rear surface 120, and an adhesive for fixing the heat insulating material 100 to the structure of the building is formed. It is a losing part. As such an adhesive, an adhesive mortar called a so-called topping can be used.

Also, it is preferable that the adhesive inducing portion 122 is constituted by 40% or more of the total area of the rear face 120, which is the area combined with the other portion of the relatively protruded rear face 120 except for the low- Do. At this time, the height of the adhesive inducing portion 122 may be such that the other portion of the rear surface 120 protruded relatively coincides with the highest point, so that the heat insulating material 100 is fixedly attached to the structure of the building.

In FIG. 3, the shape of the adhesion inducing portion 122 is shown as a circle, but it may be formed in various shapes such as a polygon including a rectangle.

FIG. 5 shows various embodiments in which the assembled type guiding insulation material 100 used in the outer insulation method according to the present invention can be applied to each construction layer, and FIG. 6 is a perspective view of an assembled type And the guiding thermal insulating material 100 is laminated in a clogged manner.

In the present invention, the building is composed of multiple layers, and a plurality of sections are divided into a plurality of sections from the lowest floor to the uppermost floor, and the number of the anchor inserting sections 170 may be different in each section of the heat insulating material 100.

The method of applying the adhesive to the surface of the rear surface 120 of the heat insulating material 100 is described in the present invention in such a manner that the physical properties and the construction range of the heat insulating material 100 are printed on the surface of the front surface 110 of the heat insulating material 100, And can be printed with the protruding characters 200.

That is, as shown in FIG. 5, the layer to be applied may be printed on the front surface 110 of the heat insulating material 100 with the protruding characters 200, and the number of the anchor inserting portions 170 Can be formed differently. This is because the number of anchors A that are structurally satisfactory is applied in consideration of the fact that the condition of the wind load varies depending on the height of the installed heat insulating material 100 and the installation site. Further, the skilled artisan can easily recognize the binding position and quantity of the anchor (A) according to the ordinance standard in accordance with the height of the layer where the heat insulating material 100 is installed and the installation position.

At this time, the characters 200 formed on the surface of the heat insulating material 100 may be printed in a shape protruding from 2 to 3 mm, and serve to guide the thickness of the primer mortar during the plaster finish. Further, the reinforcement mesh is forced to impregnate the intermediate portion of the mortar precisely.

The first side surface 130 of the heat insulating material 100 is formed with a pair of first protrusions 132 having different shapes and the second side surface 140 is formed with the same shape as the first protrusions 132, And the first and second coupling grooves 142 and 142 are coupled to each other so that the first and second coupling grooves 142 and 142 are located at the intersections of the first and second coupling grooves 142 and 142, The plurality of heat insulating materials 100 can be stacked and joined together in a jammed manner.

That is, as shown in FIG. 6, it is structurally preferable that a plurality of the heat insulating materials 100 are piled up in a clogged joint like bricks. This is because, in the case of an integral joint, the amount of thermal displacement is concentrated on a straight joint, so that the deflection of the heat insulating material 100 may occur as shown in [Reference 1], and cracks may be caused by repeated shrinkage of the waterproofing finish film Because.

[Reference Figure 1]

In addition, according to the present invention, the anchor A inserted into the anchor inserting portion 170 formed at each side or each corner can simultaneously fix two or more heat insulating materials 100 connected vertically or horizontally. That is, as shown in FIG. 6, the anchor insertion portion 170 formed at each side or edge of the heat insulating material 100 is formed in a cross section joined with the anchor insertion portion 170 of the adjacent heat insulating material 100, (A) can be inserted tightly, and two or more heat insulating materials (100) are fixed together by an anchor (A) inserted in such a space.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

It is therefore intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

A: Anchor
100: Insulation
110: Front
120: rear
122:
130: First aspect
132: first protrusion
140: Second side
142: second binding groove
150: Third aspect
152: third projection
160: Fourth aspect
162: fourth binding groove
170: anchor insertion portion
180: Anchor cover
200: Character

Claims (9)

In the heat insulating material 100 used in the outer heat insulating method of a building,
The heat insulating material 100 includes a front surface 110, a rear surface 120 that is opposite to the front surface 110, a first side surface 130, a second side surface 140 that is opposite to the first side surface 130, A third side face 150 adjacent to the first and second side faces 130 and 140 and a fourth side face 160 opposite to the third side face 150,
A plurality of first protrusions 132 protruding in a predetermined cross-sectional shape are provided on the first side surface 130 at predetermined intervals,
The second side surface 140 is provided with a second binding groove 142 which is recessed to correspond to the shape of the first projection 132 at a position corresponding to the first projection 132 provided on the first side 130, Respectively,
The third side surface 150 is provided with a third protrusion 152 protruding in a predetermined cross-sectional shape,
The fourth side surface 160 is formed with a fourth binding groove 162 which is recessed to correspond to the shape of the third protrusion 152 at a position corresponding to the third protrusion 152 provided on the third side surface 150, Respectively,
The heat insulating material 100 to be laminated is connected to each of the first and third protrusions 132 and 152 and the second and fourth binding grooves 142 and 162 so as to be vertically and laterally left- Guiding insulation. The method of claim 1,
The heat insulating material 100 further includes a plurality of anchor inserting portions 170 punctured to pass through the front surface 110 and the rear surface 120 in a predetermined section,
The anchor A passes through the anchor inserting portion 170 and one end thereof is stuck to the structure of the building to fix the heat insulating material 100,
A plurality of anchors installed in the anchor insertion part 170 such that the lower surface of the anchor A is in contact with the head part of the anchored fastener A and the upper surface thereof is flattened with the front surface 110 of the heat insulating material 100. [ A cover 180 is provided,
Wherein the anchor insertion portion 170 is configured to have a sectional shape in which a head portion of the anchor A is engaged and a body portion of the anchor A is closely inserted. Guiding insulation. 3. The method of claim 2,
The building is composed of a plurality of layers, and is divided into a plurality of sections in units of a plurality of layers from the lowest layer to the uppermost layer,
Wherein the number of the anchor inserting parts (170) is different in each section of the heat insulating material (100). 4. The method of claim 3,
The anchor insertion portion 170 has a circular cross section at the inner surface of the front surface 110 and the rear surface 120 and has a semicircular cross section at each side,
An anchor (A) inserted into an anchor inserting part (170) formed on each side or each corner is used to simultaneously fix two or more heat insulating materials (100) connected vertically or horizontally. Guiding insulation. 5. The method according to any one of claims 1 to 4,
The rear surface 120 of the heat insulating material 100 is formed in a shape in which a certain area is recessed inward,
A plurality of adhesive inducing portions 122 protruding to a predetermined height in a predetermined form are formed in the recessed portion of the rear surface 120 of the heat insulating material 100,
Wherein the protruded area of the rear surface (120) including the plurality of adhesive induction parts (122) is greater than 40% of the total area of the rear surface (120). 5. The method according to any one of claims 1 to 4,
A pair of first protrusions 132 having different shapes are formed on the first side surface 130 of the heat insulating material 100,
The second side surface 140 is provided with a pair of second binding grooves 142 so that the second side surface 140 is located at a portion where the same shape as the first projecting portion 132 is diagonally intersected,
The first and the second coupling grooves 142 are fitted to the upper and lower heat insulating materials 100 so that the plurality of heat insulating materials 100 are stacked and joined together in a jam- Which is used for the outer heat insulating method. The method of claim 5,
A pair of first protrusions 132 having different shapes are formed on the first side surface 130 of the heat insulating material 100,
The second side surface 140 is provided with a pair of second binding grooves 142 so that the second side surface 140 is located at a portion where the same shape as the first projecting portion 132 is diagonally intersected,
The first and the second coupling grooves 142 are fitted to the upper and lower heat insulating materials 100 so that the plurality of heat insulating materials 100 are stacked and joined together in a jam- Which is used for the outer heat insulating method. 5. The method according to any one of claims 1 to 4,
On the surface of the front surface 110 of the heat insulating material 100, the physical properties and the construction range of the heat insulating material 100 are printed in the characters 200,
Characterized in that a method of applying adhesive to the surface of the rear surface (120) of the heat insulating material (100) is printed with the protruded characters (200). The method of claim 5,
On the surface of the front surface 110 of the heat insulating material 100, the physical properties and the construction range of the heat insulating material 100 are printed in the characters 200,
Characterized in that a method of applying adhesive to the surface of the rear surface (120) of the heat insulating material (100) is printed with the protruded characters (200).

Images