KR200416121Y1 - Insulating Material for preventing from forming Dewdrops - Google Patents

Abstract

The present invention relates to an insulation reinforcing material for preventing dew condensation. It prevents heat loss inside and outside by delaying and blocking heat transfer from inside and outside due to conduction, convection, and radiation phenomena, so that it can minimize energy consumption for heating and cooling. It relates to a heat-resistant reinforcing material for preventing condensation including all moisture permeable functions that can discharge the generated water.

The present invention and the heat insulating plate comprising a cavity of the shell structure forming a space in which the air layer is formed; It is characterized in that it comprises a moisture-permeable membrane adhered to at least one of the one side and the other side of the cavity to discharge moisture on one side, and to block air on the other side.

Moisture-permeable membrane, insulation, foam, building interior materials

Description

Insulating Material for Preventing from Forming Dewdrops

1 is a view showing a conventional wall,

Figure 2 is a cross-sectional view of the wall showing a preferred embodiment of the condensation preventing insulation reinforcement according to the present invention,

Figure 3 is a perspective view showing a heat insulating reinforcement for preventing condensation according to the present invention,

Figure 4 is an enlarged view of the moisture-permeable membrane in the condensation prevention insulation reinforcing material according to the present invention,

Figure 5a is an enlarged view showing a laser perforated membrane in the condensation prevention insulation reinforcing material according to the present invention,

Figure 5b is a side view of the laser perforated membrane in the condensation preventing insulation reinforcement according to the present invention,

6 is a view showing a padded fiber plate in the condensation prevention insulation reinforcing material according to the present invention,

Figure 7 is a view showing a variety of applications of the foam foam in another condensation prevention insulation reinforcement in the present invention.

* Explanation of symbols for main parts of the drawings

1: wall 2: insulation reinforcement

3: finish material 4: insulation material

21: moisture-permeable membrane 22: foam foam

221: Cavity

The present invention relates to a heat insulating reinforcement material that can reinforce the heat insulating function of building insulation material, and reinforces the heat insulating function of the heat insulating material by delaying and blocking heat transfer inside and outside by conduction, convection, and radiation phenomena. The present invention relates to an anti-condensation insulation reinforcing material including all moisture permeable functions.

1 is a cross-sectional view showing a wall in a conventional building.

Referring to FIG. 1, a wall of a conventional building is installed on an interior wall surface 1 formed as concrete using cement, a heat insulating material 4 fixed on the outside of the interior wall surface 1, and an outdoor side of the wall. We include finish material 3 to become

The interior wall surface 1 is formed as concrete in the walls of the building to partition the interior or support the superstructure in the building, and the finishing material 3 constitutes the exterior of the building. Wherein the finishing material is wooden plywood, or in the case of a general concrete building brick or other concrete structure corresponds to this. And the heat insulating material (4) is installed between the interior wall surface (1) and the finishing material (3) to prevent heat transfer between both sides, through the indoor wall surface (1) through the indoor heat and finishing material (3) In order to prevent heat transfer between indoors and outdoors, styrofoam having a thickness of 60T is most commonly applied.

Here, the heat insulating material 4 prevents heat transfer to the outside of the room so that the room can maintain a proper temperature, and in such a manner, to have a heat resistance in the heat transfer to perform the heat insulation function. Therefore, the heat insulating material 4 blocks the thermal conduction by using a synthetic resin such as styrofoam formed of a material having high heat resistance.

However, the conventional heat insulating material as described above has only a heat insulating function of heat conduction among three methods, such as convection in which heat is transferred through a flow of a fluid such as air, conduction in which heat is transferred through a medium, and radiation in which heat is transmitted by radiant heat. As it has, there is no heat insulation effect due to the flow of external air through the wall or radiation by solar light, and this difference is such that the heat transfer by convection and radiation to the extent of reinforcement through the interior wall or finishing material inside the wall. As it prevents the interior wall and the thickness of the finishing material is thick, there is a problem that also increases the construction cost.

Therefore, in recent years, to solve the above problems of styrofoam by using an insulation material such as a paper material or a membrane formed of a material having a function of windproof or heat reflection for insulation by radiation and convection. However, the insulation of the paper material or aluminum membrane has the effect of windproof and heat reflection, but due to the lack of moisture permeation, when water condensation occurs on the surface due to the temperature difference between both sides, the moisture is absorbed and heat transfer. Since it serves as a medium, there is a problem that the insulation function is lost.

The present invention was devised to solve the conventional problems as described above, the object of the present invention is to discharge the water generated during the heat insulation function of the heat insulator to the outside, the wind-proof function and radiation heat prevention function that can block the air flowing from the outside It is an object of the present invention to provide a heat-resistant reinforcing material containing a moisture-permeable membrane to have.

Another object of the present invention is to form a space in which the air layer is formed in the part where the heat inside the room is in contact with the heat of the outside in order to prevent heat conduction by conduction to have a heat resistance, the foamed synthetic resin and the needle punched padding fiber shape It is an object of the present invention to provide a heat insulating reinforcement containing a foam or padding fiber shape that can be significantly reduced in thickness compared to the conventional heat insulating material.

The present invention includes the following embodiments to achieve the above object.

According to the first embodiment of the present invention, the condensation preventing insulation reinforcing material of the present invention, the insulating plate material including a cavity of the shell structure forming a space in which the air layer is formed; It is attached to at least one of the one side and the other side of the cavity to discharge moisture on one side, and includes a moisture-permeable membrane for blocking the air on the other side.

According to a second embodiment of the present invention, the condensation preventing insulation reinforcing material of the present invention, in the first embodiment, the heat insulating plate material is a foamed plastic foam molded, such as cotton including a micro-cavity therein The fiber body having a structure includes at least one of the padded fiber boards thinly stacked.

According to a third embodiment of the present invention, the condensation preventing insulation reinforcement of the present invention, in the embodiment 1, wherein the moisture-proof membrane in the condensation preventing insulation reinforcement is a polymer membrane, polyolefin membrane, vinyl or nonwoven membrane, the Any one selected from the group consisting of an aluminum coating membrane coated with aluminum on the surface of the polymer membrane or the nonwoven membrane and perforated with a plurality of micropores, and an aluminum powder deposition membrane deposited by spraying aluminum grains on the polymer membrane or the nonwoven membrane. It is characterized by one.

According to the fourth embodiment of the present invention, the condensation preventing insulation reinforcing material of the present invention, in the third embodiment, the moisture-permeable membrane is formed in white so that its surface can reflect radiant heat.

According to a fifth embodiment of the present invention, the condensation preventing insulation reinforcement of the present invention, in the second embodiment, the padding fiber plate in the condensation preventing insulation reinforcement is formed by entangled fiber yarn or through a needle punching (Needle Punching) process It is characterized by having a fiber structure in which a plurality of pore layers are formed to form an air layer.

According to the sixth embodiment of the present invention, the condensation preventing insulation reinforcement of the present invention, in the second embodiment, the cavity structure of the foam foam in the condensation preventing insulation reinforcement is formed of a plurality of triangles and inverted triangles triangular structure At least any one of a bubble structure formed of a plurality of circles, a bee structure formed of a polygonal shape and a honeycomb shape of an overall shape, a square structure made of a grid-shaped square structure, and a diamond structure formed of a diamond shape; It is characterized by one.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the condensation preventing insulation reinforcing material according to the present invention will be described in detail.

Figure 2 is a cross-sectional view of the wall showing a preferred embodiment of the heat-resistant reinforcing material for preventing condensation according to the present invention.

Condensation prevention insulation reinforcement according to the present invention is applied to all walls that are built by various types of construction methods in various types of buildings using all the construction methods or various dry and wet methods known to the workers in the same field. One possible double, it will be described in detail for the condensation preventing insulation reinforcing material according to the present invention for example shown in FIG.

Referring to Figure 2, the wall of the building partitions the interior or the interior wall surface (1) for supporting the upper portion of the building, the insulation provided to one side of the interior wall surface to perform a thermal insulation function, and one side of the thermal insulation material (4) It is provided with a heat insulating reinforcing material (2) for reinforcing the heat insulating function of the heat insulating material (4) and to discharge moisture, and a finishing material (3) for forming the outer surface of the building on the outside of the heat insulating reinforcing material (2). .

Here, at least one of the interior wall surface (1) and the heat insulating material (4), the heat insulating material (4) and the heat insulating reinforcing material (2), the heat insulating reinforcing material (2) and the finishing material (3), a separate wooden board, such as additional support configuration It can be installed but this is omitted because the description is known.

The heat insulating material 4 prevents heat transfer by conduction between the interior wall surface 1 and the finish material 3 to increase the heating and cooling efficiency of the room. In this case, the heat insulating material 4 has a predetermined space between the interior wall surface 1 and the finishing material 3 to block heat conduction on both sides.

The thermal insulation reinforcing material (2) solves the problem of the conventional thermal insulation by reinforcing the thermal insulation function of the thermal insulation material (4) and performing a moisture permeation function. That is, the insulation 4 is due to the temperature difference between the warm indoor air and low-temperature outdoor air condensation phenomenon occurs that the moisture contained in the air is formed of water droplets, the insulation reinforcing material (2) is a heat insulating reinforcement (22) By blocking the heat transfer by heat conduction, convection and radiation of the heat insulating material (4), and also through the moisture-permeable membrane (21, 23) to be described later to discharge the moisture generated by the heat insulating material (4) to the outdoor side It is possible to improve and continuously maintain the thermal insulation function of the heat insulator 4 and its detailed configuration will be described later.

Figure 3 is a perspective view showing an embodiment of the anti-condensation insulation reinforcing material according to the present invention, Figure 4 is a view showing a padded fiber board, Figure 5 is an enlarged view of the moisture-permeable membrane in an embodiment of the anti-condensation insulation reinforcing material according to the present invention. to be.

3 to 5, the condensation preventing insulation reinforcing material according to the present invention is the first and second moisture-permeable membranes (21, 23) to block the outside air, and discharge the moisture inside, and the first and Insulating plate (22) that is bonded to the inside of the second moisture-permeable membrane (21, 23) to insulate.

Here, the first and second moisture-permeable membranes 21 and 23 (hereinafter referred to as moisture-permeable membranes) are highly directional, about 0.5-10 microns, which are processed by applying high pressure and high heat to polyethylene microfibers. Fiber is a special fiber formed of up to 64 multi-layer structure (see Figure 3) has the characteristics shown in Table 1 below, which is based on the product description provided by the manufacturer (Dupont, trade name: Tyvek).

Specification / weight 1.5M × 100M (150SQM) / 9.5㎏, no load influence on underground installation Breathable 250G / M ² .HOUR, no condensation in the insulation system The tensile strength Longitudinal direction: 34.4㎏, Width direction: 49.5㎏ Workability There is no change according to temperature, so it is possible to work in four seasons durability 70 years or more when used in roofs / walls Water resistance 133cm or more (KS K0591) Environmental Sorted into poly series and can be continuously recycled

As described above, the moisture-permeable membrane 21 applied to the present invention has both moisture-permeability and water resistance, and its thickness is very thin (1 mm or less). In addition, the moisture-permeable membrane 21 has been described as an example of a polymer membrane, the polymer membrane is a non-woven polypropylene sheet of a spunbonded (non-woven) spunbonded (polypropylene sheet) heat adhesive and polyolefin polymer Combining the coating of the material has the advantage of moisture control and windproof.

Therefore, the moisture-permeable membrane 21 is discharged to the other side due to the moisture generated by the temperature difference of one side when the heat insulation by the coupling with the heat insulating plate 22 which will be described later does not occur condensation as in the prior art of air or gas It performs the heat insulation function and the windproof function by the convection which heat transfer is performed by the flow. In addition, the moisture-permeable membrane 21 has a white color in addition to the function of the moisture-permeable to reflect the radiant heat of the sun, it is also preferable to perform the thermal insulation function by radiation.

Here, the moisture-permeable membrane 21 includes both a polymer membrane, a polyolefin membrane, a membrane such as vinyl or nonwoven fabric, an aluminum coating membrane, and an aluminum powder deposition membrane, and preferably any one of them is selected.

Wherein the aluminum coating membrane is coated with aluminum on the surface of the polymer membrane and polyolefin membrane, vinyl or non-woven membrane, and the surface is perforated with a laser to increase the heat insulation effect by forming a moisture-permeable passageway This is as shown in Figures 5a and 5b below.

Figure 5a is an enlarged view showing a laser perforated membrane in one embodiment of the anti-condensation insulating reinforcing material according to the present invention, Figure 5b is a side view of the laser perforated membrane in an embodiment of the anti-condensation insulating material for condensation according to the present invention.

5A and 5B, the moisture-proof reinforcing material for preventing condensation according to the present invention, the moisture-permeable membranes 21 and 23 include the polymer and other membranes as described above, and the double aluminum coating membrane also has the same moisture-permeable function. This is possible. To explain this, the polymer, polyolefin, vinyl or non-woven fabric is coated with aluminum on the membrane, and by using a laser on the surface of the plurality of holes for fine moisture permeation to discharge the moisture remaining in the insulation to the outside. . In general, the aluminum coating membrane has not been applied as a moisture-permeable or general insulation material because there is no passage of moisture as the aluminum micro-coated surface of the membrane is coated with all the unique micropores of each membrane. In the present invention, the movement of water in both sides is made possible by drilling a plurality of micropores using a laser.

In addition, the aluminum powder deposition membrane in the moisture-permeable membrane is deposited by evenly spraying aluminum grains on the surface of the polymer membrane, polyolefin membrane, vinyl or nonwoven membrane, the surface color is varied from the unique gloss color of the metal to white .

In addition, the first and second moisture-permeable membranes 21 and 23 may be bonded to the front and rear surfaces of the foam foam 22 at the same time or may be bonded to only one of the front and rear surfaces.

The insulation plate 22 includes a foam foam 22 in which plastic resin is foamed, and the foam foam 22 is formed by foaming synthetic resin to form a cavity 221 having an independent shell structure. It is manufactured to have a space to be formed and adhered to the moisture-permeable membrane 21 by an adhesive or adhesive tape on the front and back. Therefore, the foam foam 22 forms the air layer having the lowest thermal conductivity between the heat insulating material 4 and the finish material 3 in the wall, so that heat transferred from the wall 1 is transferred to the air layer. Let it be slowed down.

In addition, as another application example of the present invention, the heat insulating plate material 22 may achieve the object of the present invention by applying a padded fiber board having a micro cavity in addition to the foam having the shell structure as described above using a synthetic resin. See FIG. 6). Here, the padding fiber plate is formed of a thin plate laminated with a fiber-like structure having a cotton-like structure including a micro-cavity therein after passing through a cylinder in which a polymer raw material is engaged with a myriad of pins through a needle punching process.

Figure 7 is a view showing a variety of applications of the insulating plate in the condensation preventing insulation reinforcing material according to the present invention.

Referring to FIG. 7, the foam foam 22 according to the present invention may configure the cavity 221 as various shapes. Among the various application examples shown, a triangular structure having a triangular and inverted triangular cavity 221, a bubble structure in which a cavity 221 is formed in a shape in which a plurality of circles are connected, and a cavity 221 is formed in a polygonal space. The honeycomb structure is formed in a honeycomb shape, and is arranged in a horizontal and longitudinal shape, so that the cavity 221 is a rectangular structure made of a lattice-shaped rectangular structure, and the cavity 221 is a diamond structure arranged in a diamond shape; do.

In addition, the padding fiber plate is formed as a fiber structure in which a plurality of pore layers are formed through a needle punching (Needle Punching) process or the fiber yarn is tangled and laminated in a thin plate.

The various application examples of the insulation board material including the foam foam 22 and the padding fiber board is about 3mm in thickness, and the thickness thereof is very thin compared to the heat insulating material 4 such as styrofoam, which is 6 cm in size. Therefore, the insulation reinforcement according to the present invention is very thin, so that even when applied to the wall with the heat insulating material, the thickness of the wall is not rapidly increased, so that those skilled in the art can be easily applied.

The present invention is capable of performing all of the heat insulating functions by convection, radiation, and conduction as compared to the heat insulating function by conduction in the existing heat insulator as described above, and discharge the moisture generated by the temperature difference between indoor and outdoor. It is possible to increase the heat insulation effect.

The present design is very thin (1/8 ~ 1/10) compared to the existing insulators such as styrofoam, so the thickness of the structure of the building can be made very thin, and all the heat transfer methods by convection, radiation, and conduction are applied. As the heat insulation is possible, there is an effect that can be applied alone or with a very thin heat insulating material as compared to the conventional art.

Claims (6)

An insulation plate comprising a cavity forming a space in which an air layer is formed; Condensation prevention insulation reinforcing material comprising a moisture-permeable membrane is bonded to at least one of the one side and the other side of the cavity to discharge moisture on one side, and block the air on the other side. The method of claim 1, wherein the heat insulating plate Condensation is characterized in that any one of the shell structure is formed of a shell structure in which the air layer is formed and foamed foamed with plastic resin, and a padded fiber board in which a fiber body having a cotton-like structure including a micro-cavity therein is thinly laminated. Preventive insulation reinforcement. The moisture-permeable membrane of any one of claims 1 to 2, wherein the condensation preventing insulation reinforcing material is Deposition of a polymer membrane, a polyolefin membrane, a vinyl or nonwoven membrane, an aluminum coating membrane coated with aluminum on the surface of the polymer membrane and the nonwoven membrane and perforated with a plurality of micropores, and spraying aluminum grains on the polymer membrane or the nonwoven membrane. The condensation preventing insulation reinforcement, characterized in that any one selected from the group consisting of aluminum powder deposition membrane. The method of claim 3, wherein the moisture-permeable membrane The condensation preventing insulation reinforcing material, characterized in that the surface is formed in white so that it can reflect the radiant heat. The method of claim 2, The padding fiber board in the condensation prevention insulation reinforcement Condensation prevention insulation reinforcement, characterized in that the fiber yarn is formed by tangling or needle punching (Needle Punching) process has a plurality of pore layers are formed to form an air layer. According to claim 2, wherein the cavity structure of the foam foam in the insulating condensation preventing material is A triangular structure formed of a plurality of triangles and inverted triangles, a bubble structure formed of a plurality of circles, a bee structure formed of a polygonal shape in a honeycomb shape, a rectangular structure made of a grid-shaped square structure, Condensation prevention insulation reinforcement, characterized in that at least any one of the diamond structure is formed in a diamond shape.

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