KR20090057510A - Insulator - Google Patents

Abstract

A heat insulation material having a damp-proofing function is provided to prevent the performance degradation of the heat insulation material and to secure the stability of a building. A heat insulation material having a damp-proofing function comprises: a rear joint(104) in the one side end and a front joint(107) in the other side end. The adjacent heat insulation materials have the structure in order to be embossing-coupled. The rear joint is consisting of: a rear groove(102) extending to the vertical direction, located inside the rear one side end to be separated with certain distance; and a rear protrusion(103) extending along the vertical direction, located between the rear groove and the rear one side end. The front joint includes a front groove(105) extending to the vertical direction, located at the front the other side end to be connected to the rear joint; and a front protrusion(106) extending to the vertical direction, located between the front groove and the front the other side end.

Description

Insulation Material

The present invention relates to a heat insulating material to be installed on the wall, and more particularly, to a heat insulating material to have a moisture-proof function to prevent moisture from penetrating the inner wall while minimizing damage from moisture to the heat insulating material installed on the wall.

Insulation material is a cold insulating material intended to be used at about 100 ° C or less, a heat insulating material of 100 to 500 ° C, a heat insulating material of 500 to 1,100 ° C, and a fireproof insulating material that can be used at 1,100 ° C or more. Iii).

The heat insulating material preferably has a small thermal conductivity of the material itself, but most of the thermal conductivity is not so small, so that the thermal conductivity is made porous so that the thermal conductivity of the air in the pores is used.

The materials are largely divided into organic and inorganic materials. Organic materials include cork, cotton, felt, cork carbide, foam rubber, etc., and are suitable for use at about 150 ° C or lower.

The insulation is used in many places such as the outer wall of a furnace, reaction tower, storage tank of oil, the outer wall of a steam conduit or a water pipe, and the exterior of a refrigerator. The room is insulated from low or high temperatures.

Here, when the conventional heat insulator is constructed, as shown in FIG. 1, a plurality of heat insulators 10 manufactured in one standard are installed adjacent to each other in the horizontal direction, and stacked in a vertical direction. It is constructed.

That is, the construction of the wall is completed by constructing the outer wall coating agent and the outer wall finish material 1 after the heat insulating material 10 in the horizontal and vertical directions as described above.

However, as described above, the heat insulating material 10 constructed as described above may cause problems such as moisture or water soaking in the heat insulating material 10 due to seasonal temperature difference and breakage of the outer wall finish material 1. have.

In addition, as shown in FIG. 2, when any one of the heat insulators 10 is wetted with water, the water is soaked into the adjacent heat insulator 10 so that the adjacent heat insulators 10 are all wetted with water. There was a problem caused.

And, as shown in Figure 3, when any one of the heat insulator 10 is wet with water, the water is moved to the inner wall (3) along the joint 2 between the heat insulator 10 and the heat insulator (10) In addition, by gradually flowing to the lower side along the inner wall 3, the lower heat insulating material 10 is wetted with water and loses the heat insulating function or there is a problem such that the water is filled between the inner wall (3).

In order to solve the above problems, the present invention enhances the bonding force with the adjacent heat insulating material while blocking the mobility by moisture and moisture so that even if any one of the heat insulated water and moisture moves to the adjacent heat insulating material of the adjacent heat insulating material. It solves the problem of lowering the thermal insulation performance, and even if any one of the heat insulators is exposed to moisture and moisture, the water and the moisture flows downward along the outer surface while preventing water and moisture from entering the inside through the seams of the upper and lower heat insulators. The object is to provide a heat insulating material which allows the flow to be ensured so that the performance of the heat insulating material can be ensured.

The above object is, in the heat insulating material to be installed on the wall, the rear groove formed to a predetermined depth at a position spaced a predetermined distance from one side end of the rear surface is formed to extend vertically, than the rear surface from the rear surface between the rear groove and one side end A rear coupling portion in which a rear protrusion protruding to a low height extends vertically; The front groove formed at a predetermined depth is vertically formed at a position spaced a predetermined distance from the other end of the front side to be unevenly coupled to the rear coupling portion, and is vertically extended, and is lower than the front at the front side between the front groove and the other end. Protruding front protrusion is achieved by a heat insulating material, characterized in that it comprises a front coupling portion extending vertically.

In addition, the above object, in the heat insulating material to be constructed on the wall, the upper inclined portion is formed by cutting to the point spaced downward from the upper end of the front upper end; It is also achieved by a heat insulator, characterized in that it comprises a lower inclined portion formed by cutting from the bottom of the front to a point spaced upwardly from the bottom of the back.

On the other hand, the above object is, in the heat insulating material to be installed on the wall, the rear groove formed to a predetermined depth at a position spaced a predetermined distance from the one side end of the rear surface is formed to extend vertically, at the rear surface between the rear groove and one side end A rear coupling portion in which a rear protrusion protruding to a height lower than a rear surface is vertically extended; The front groove formed at a predetermined depth is vertically formed at a position spaced a predetermined distance from the other end of the front side to be unevenly coupled to the rear coupling portion, and is vertically extended, and is lower than the front at the front side between the front groove and the other end. A front engaging portion in which the protruding front projection extends vertically; An upper inclined portion formed by cutting from an upper end of the back to a point spaced downward from an upper end of the front; It is achieved by a heat insulator, characterized in that it comprises a lower inclined portion formed by cutting from the bottom of the front to a point spaced upwardly from the bottom of the back.

According to the present invention, even if any one of the heat insulator is wet or wet, the adjacent heat insulator is a structure in which the front coupling part and the back coupling part are unevenly coupled to each other by 'B', 'B', so that the water or moisture is blocked to insulate the heat insulating material. Or keep the condition as safe as possible from moisture, and even if dew or infiltrated water, etc., formed on the outer surface of the heat insulating material flows down from the upper side of the heat insulating material to the lower side, the water is not flowed back by the beveled joint formed by the upper and lower inclined portions. By not having a structure, the insulation can maintain a safe construction condition from moisture or moisture, as well as block the movement of water to the inner wall to ensure the stability of the building for a long time, and the performance degradation of the insulation in advance It has the effect of preventing it.

The heat insulating material according to the present invention will be described by dividing into a first embodiment, a second embodiment and a third embodiment, but the final structure in which the first embodiment and the second embodiment are combined is the third embodiment, and thus, the first embodiment. After the example and the second embodiment have been described, the third embodiment will be briefly described with reference to FIGS. 4 to 6.

First Embodiment

As shown in FIG. 4, the rear coupling part 104 and the front coupling part 107 are respectively formed at both ends of the heat insulating material 101 so that the rear coupling part 104 formed at one end of the heat insulating material 101 is different. As shown in FIG. 5, the front coupling part 107 formed at the other end of one heat insulating material 101 is unevenly coupled.

That is, the rear coupling part 104 is formed at one end of the heat insulating material 101 and the front coupling part 107 is molded at the other end thereof to have a structure in which adjacent heat insulating materials 101 are unevenly coupled to each other.

Here, the heat insulating material 101 disposed on both ends of the wall 108 of the heat insulating material 101, the rear coupling portion 104 or the front coupling portion 107 is formed only at one of the one end and the other end, both ends are It is desirable to allow finishing.

The rear coupling part 104 is formed such that the rear groove 102 is formed at a predetermined depth at a position spaced a predetermined distance from one side end of the rear surface, and extends in a vertical direction as shown in FIG. 4.

In addition, since the rear recess 102 is molded, the rear protrusions 103 are protruded at a height lower than the rear surface of the rear surface between one side end, and the rear protrusions 103 also extend along the vertical direction.

On the other hand, the front coupling portion 107 is unevenly coupled to the rear coupling portion 104, the front groove 105 is formed to a predetermined depth at a position spaced a predetermined distance inward from the other end of the front surface, this front groove ( 105 also extends in the vertical direction.

And, since the front groove 105 is molded, the front protrusion 106 is protruded to a lower height than the front surface in the front face between the front groove 105 and the other end, and the front protrusion 106 is also in the vertical direction. It is extended along.

Therefore, as shown in FIGS. 4 and 5, the insulating material 101 adjacently constructed is one of the back coupling part 104 and the front coupling part 107 which are unevenly coupled to each other by the structure in which the uneven coupling is performed. When the heat insulator 101 is wet or wet, the phenomenon that water flows into the adjacent heat insulator 101 is prevented by the 'd'-shaped joint 109 in which' a 'and' b 'are combined. Will be.

Second Embodiment

As shown in FIGS. 4 and 6, the second embodiment is a structure for preventing moisture and moisture from penetrating toward the inner wall 112 with respect to the connection portion of the heat insulating material 101 disposed at the upper and lower ends. .

That is, the upper inclined portion 110 is formed by cutting from the upper end of the rear surface of the heat insulating material 101 to the point spaced downward from the upper end, and cutting down the point spaced upwardly from the lower bottom of the rear surface of the heat insulator 101. The upper inclined portion 110 of the heat insulating material 101 formed at the bottom by forming the portion 111 is in contact with the lower inclined portion 111 of the heat insulating material 101 constructed at the top to form oblique connection portions 113. By doing so, when water flows down to the outer surface of the heat insulator 101 as shown in FIG. 6, the water does not flow back through the connecting portion, thereby preventing penetration into the inside.

In addition, even when the upper heat insulator 101 is wet, after the water moves to the lower end of the heat insulator 101, through the connecting portion 113 formed by the upper, lower inclined portion (110) 111 overlapping. As the water flows out to the outside as shown in FIG. 6, the drainage effect of water and moisture can be obtained.

Here, the heat insulating material 101 to be constructed at the top end of the wall 108, the upper end may have a flat surface, and the lower inclined portion 111 may be molded only at the lower end, and the heat insulating material is constructed at the bottom end of the wall 108 101 may have the lower end having a flat surface, and the upper inclined portion 110 may be molded only at the upper end.

Third Embodiment

The third embodiment is a structure in which both the first embodiment and the second embodiment are combined, and the rear coupling part 104 and the front coupling part 107 of the first embodiment are formed at both ends of the heat insulating material 101. Adjacent construction of the heat insulating material 101, the back coupling portion 104 and the front coupling portion 107 is to be concave-convex to prevent the moisture and moisture is moved to the adjacent heat insulating material (101).

In addition, the upper inclination portion 110 and the lower inclination portion 111 of the second embodiment are formed on the upper end and the lower end of the heat insulator 101, and the insulator 101, which is constructed up and down, is inclined with each other. When it is formed to the outer side of the heat insulating material 101 or penetrated moisture and water flows down the outer side, it is to be blocked back to the connection portion to penetrate into the inner wall.

Meanwhile, reference numeral 114 in the drawing is an outer wall finishing material, and in the third embodiment, the upper end of the heat insulating material 101, which is constructed at the top of the wall 108 on which the heat insulating material 101 is constructed, is flat, and only the bottom slope is inclined. The lower portion of the heat insulating material 101 to be molded at the bottom 111 is formed flat, and the upper inclined portion 110 is formed only at the upper end so that the upper portion 111 is molded. It is preferred to allow 113 to be formed.

In addition, the heat insulating material 101 is constructed at one end of the heat insulating material 101 is installed on both side ends of the wall 108, the one end is formed flat and the front coupling portion 107 is formed only at the other end, the wall ( The heat insulating material 101 formed at the other end of the heat insulating material 101 to be installed at both ends of the 108 is configured to have the other end flat and to form the back coupling part 104 only at one end. The joints 109 are formed such that the joints 109 are unevenly coupled to each other to prevent the adjacent heat insulating material 101 from being wet with water through the heat insulating material 101.

1 is a view showing a construction structure of a heat insulating material consisting of a conventional single member.

FIG. 2 shows a cross section of FIG. 1; FIG.

3 shows a longitudinal section of FIG. 1;

4 is a view showing a construction structure of the heat insulating material according to the present invention.

5 shows a cross section of FIG. 4;

6 shows a longitudinal section of FIG. 4;

<Description of the symbols for the main parts of the drawings>

101: insulation 102: back recess

103: back protrusion 104: back coupling portion

105: front groove 106: front protrusion

107: front coupling portion 108: wall

109: seam 110: upper inclined portion

111: lower slope 112: inner wall

113: connection portion 114: exterior wall finishing material

Claims (3)

In the heat insulating material which is constructed in a wall, A rear recess formed at a predetermined depth is vertically formed at a position spaced a predetermined distance from one side end of the rear surface, and a rear protrusion protruding to a height lower than the rear surface from the rear surface between the rear recess and one side is vertically formed. A coupling part; The front groove formed at a predetermined depth is vertically formed at a position spaced a predetermined distance from the other end of the front side to be unevenly coupled to the rear coupling portion, and is vertically extended, and is lower than the front at the front side between the front groove and the other end. Insulating material, characterized in that the protruding front projection comprises a front coupling portion extending vertically. In the heat insulating material which is constructed in a wall, An upper inclined portion formed by cutting from an upper end of the back to a point spaced downward from an upper end of the front; Insulating material, characterized in that it comprises a lower inclined portion formed to be cut from the bottom of the front to a point spaced upwardly from the bottom bottom. In the heat insulating material which is constructed in a wall, The rear recess formed at a predetermined depth is vertically extended at a position spaced a predetermined distance inwardly from one side end of the rear surface, and the rear protrusion protruding to a height lower than the rear surface from the rear surface between the rear recess and the one end is vertically extended. A rear coupling portion; The front groove formed at a predetermined depth is vertically formed at a position spaced a predetermined distance from the other end of the front side to be unevenly coupled to the rear coupling portion, and is vertically extended, and is lower than the front at the front side between the front groove and the other end. A front engaging portion in which the protruding front projection extends vertically; An upper inclined portion formed by cutting from an upper end of the back to a point spaced downward from an upper end of the front; Insulating material, characterized in that it comprises a lower inclined portion formed to be cut from the bottom of the front to a point spaced upwardly from the bottom bottom.

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