KR101193920B1 - Non-inflammable Heat Insulator for a Door and Method for Preparing the Same - Google Patents

Abstract

The present invention relates to a non-combustible heat insulating material applied to the door (door) and a method for manufacturing the same, and more specifically, to dry-mixing the reinforcing fibers made of amorphous silica powder, organic synthetic fibers and inorganic fibers, radiation shielding additives and reinforcing materials After molding by molding with a PE film or shrink film, the molded article is wrapped on 6 sides, and finally packaged with a nonwoven fabric, which is compared with a heat insulating material such as polyurethane and glass wool, which has been applied to a conventional door, especially a front door. The present invention relates to a non-combustible heat insulating material and a method of manufacturing the same, which have not only improved the shortcomings of the heat insulating material applied to a door due to its excellent thermal conductivity, hygroscopicity, non-combustible performance, and convenient handling. .

According to the present invention, the non-combustible heat insulating material applied to the door is harmless to the human body by using silica powder, and has the disadvantages of the existing organic and inorganic heat insulating materials when applied as a heat insulating material due to the incombustible performance, moisture resistance, and excellent heat insulating performance. It can be applied to thinner thickness and satisfies the legal standard, and can be applied as non-combustible insulation inside all doors (doors) such as fire doors as well as general doors and front doors.

Door, front door, door, fire door, non-combustible insulation

Description

Non-inflammable Heat Insulator for a Door and Method for Preparing the Same}

The present invention relates to a non-combustible heat insulating material applied to the door (door) and a method for manufacturing the same, and more specifically, to dry-mixing the reinforcing fibers made of amorphous silica powder, organic synthetic fibers and inorganic fibers, radiation shielding additives and reinforcing materials After molding by molding with a PE film or shrink film, the molded article is wrapped on 6 sides, and finally packaged with a nonwoven fabric, which is compared with a heat insulating material such as polyurethane and glass wool, which has been applied to a conventional door, especially a front door. The present invention relates to a non-combustible heat insulating material and a method of manufacturing the same, which have not only improved the shortcomings of the heat insulating material applied to a door due to its excellent thermal conductivity, hygroscopicity, non-combustible performance, and convenient handling. .

The thermal conductivity of windows in buildings is determined by the Rules on Building Equipment Standards, even if the construction is made with thinner insulation thickness. In addition, it showed performance over the standard and secured non-combustible performance by improving the weakness of the existing organic (polyurethane) insulation to inorganic insulation material, and secured the flammability of the existing inorganic (grass wool) insulation material by finishing wrapping with the final nonwoven fabric after wrapping the film. It improves phosphorus hygroscopicity, and relates to a non-combustible heat insulating material and a method of manufacturing the same applied to a door that does not have problems such as odor or smell compared to the existing glass wool by using environmentally friendly raw materials such as silica powder.

 The heat insulating material applied to the door of the present invention exhibits a performance of 0.024 W / mK or less, which is much superior to those of the highest grade 'ga' (heat conductivity value of 0.034 W / mK or less) whose thermal conductivity is classified above. It is a high-performance heat insulator that can secure heat permeability even if it is constructed with a thickness lower than that of the existing heat insulator, and is characterized by taking a very stable structure against fire as a non-combustible material.

 According to the `` Regional Heat Transfer Rate Table of Building Parts by Region '' prescribed in the `` Regulations on Equipment Standards of Buildings '', the 'windows and doors' of building parts are outside of apartment houses and apartment houses, and directly facing outside air. In case of facing indirectly, the heat transfer rate based on the thermal insulation performance of the building is based on the three regions of Central, Southern, and Jeju islands. This is the case for apartment houses directly facing the outside air (3.00 W / ㎡K or less).

The above criteria stipulates the technical standards for the installation of building equipment and the matters necessary for the prevention of heat loss of buildings and the rational use of energy. ㎡K and below) was revised on July 10, 2008 from the previous standard (3.84 W / ㎡K and below), and the value of heat permeation rate for each part of the building was continuously strengthened in accordance with the prevention of heat loss of the building. Insulation applied to doors also need to improve performance.

 In general, polyurethane or glass wool is most commonly used as a thermal insulation material in current doors (especially entrance doors). However, polyurethane is an organic combustible material, and has a structure that is very vulnerable to fire prevention by releasing toxic gas in case of fire. Glass wool is inorganic non-combustible material and when it is handled, glass wool gets in contact with the skin and it is avoided by users.Therefore, it is vulnerable to moisture, which lowers the thermal conductivity value. There may be a problem in the heat insulation performance of the glass wool due to the space, the urea resin contained in the glass wool binder may cause an ammonia odor in the reaction with water, causing environmental problems.

The fire door for buildings disclosed in Korean Patent Laid-Open Publication No. 2003-0042783 aims to improve the insulation and sound insulation as well as the fire resistance characteristics by forming a fireproof insulation foam layer as an inner core of the door. Insulation foam layer refers to the foaming by mixing inorganic fibers such as glass fiber, rock wool, slag fiber and latex-based water-soluble binder or foaming nitrogen foam, and curing it. However, mixing and foaming the inorganic fibers and the water-soluble binder is a very difficult part in the manufacturing process, and may cause problems in uniformity of the inorganic fibers during foaming.

The soundproofing and insulating panels disclosed in Korean Utility Model No. 20-0254827 are for soundproofing and insulating panels that can be detached and attached to a general front door, and are made by attaching panels made of styropol, sponge, etc. using adhesives, etc. Soon, due to the flammability of the fire, problems may arise that can prevent escape to the front door in the event of fire.

 Insulation and condensation prevention doors and door frames disclosed in the Republic of Korea Patent Publication No. 10-2009-0021836 in the interior of the front door and door frame in the interior of the front door and door frame by inserting an insulating material such as urethane or fiberglass to insulate the interior It keeps mentioning. However, when the inside of the front door is made of urethane or glass fiber, as mentioned above, urethane is a combustible material, and has a structure that is very vulnerable to a fireproof structure by releasing toxic gas in case of fire. When the glass wool is in contact with the skin and tingles, the user avoids its use, and it is vulnerable to moisture, which lowers the thermal conductivity value, or the moisture penetrates the glass wool, which deforms the glass wool and creates an empty space inside the door. Insulation performance may be a problem, and the urea resin included in the glass wool binder may generate an ammonia odor in response to moisture, thereby causing environmental problems.

 Therefore, it is necessary to develop a non-combustible heat insulating material applied to doors including not only excellent heat insulating performance and non-combustible performance, but also major functions such as improved handling strength, improved hygroscopicity resistance, and environmental friendliness.

Accordingly, the present invention, as a result of research efforts to solve the problems as described above, by mixing the amorphous silica powder, the reinforcing fibers made of organic synthetic fibers and inorganic fibers, radiation shielding additives and reinforcing agents dry and molded by pressing The finished molded body was finally wrapped with non-woven fabric after 6-side wrapping with PE film or LDPE shrink film, etc., which has superior thermal conductivity and hygroscopic resistance compared to the thermal insulation materials such as polyurethane and glass wool, which were applied inside the existing door, especially the front door. By securing the non-combustible performance and convenient handling to improve the disadvantages of the heat insulating material applied to the existing door to complete the invention of the non-combustible heat insulating material.

Accordingly, the present invention improves the main physical properties and functions, such as excellent heat insulation performance, handling strength improvement, hygroscopicity resistance and eco-friendliness based on the non-combustible performance, such as organic insulation and glass wool, such as polyurethane used in the existing door An object of the present invention is to provide a non-combustible insulation applied to doors (particularly entrance doors and fire doors) that have better physical properties and functions than inorganic insulation materials.

In order to achieve the above object, the present invention, 40 to 99% by weight of silica powder, 0.5 to 20% by weight of reinforcing fibers, 0 to 50% by weight of the radiation shielding additives and reinforcing materials dry mixing and press molding, such as PE film or LDPE After the six-side wrapping (wrap 1-2 times) with a shrink film, provides a non-combustible insulation applied to the door (door) characterized in that the final packaging with a non-woven fabric.

The present invention also, non-combustible insulation is bonded to the inside of the door with a water-soluble adhesive, the joint portion of the door and the non-combustible insulation is filled with paper honeycomb or urethane foam finish non-flammable prepared by any one of claims 1 to 6. Provides a method for constructing insulation.

According to the present invention, the non-combustible heat insulating material applied to the door is harmless to the human body by using silica powder, and has the disadvantages of the existing organic and inorganic heat insulating materials when applied as a heat insulating material to the door due to the incombustible performance, moisture resistance and excellent heat insulating performance. It can be applied to thinner thickness and satisfies the legal standard, and can be applied as non-combustible insulation inside all doors (doors) such as fire doors as well as general doors and front doors.

The present invention is a non-combustible heat insulating material applied to the door containing silica powder, reinforcing fibers, radiation shielding additives,

40 to 99% by weight of silica powder, 0.5 to 20% by weight of mixed fibers of inorganic and organic synthetic fibers or reinforcement fibers made of organic synthetic fibers, and 0 to 50% by weight of radiant heat shield additives and reinforcing materials (opaque agents) The non-combustible heat insulating material is mixed and molded into a press, and the manufactured molded article is wrapped on 6 sides with a shrink film such as PE film or LDPE, and then applied to a door (door) finally wrapped with nonwoven fabric. It is done.

 The present invention will be described in detail as follows.

The silica powder used in the present invention is an amorphous, very light powder with very small basic particles, a spherical shape, a large surface area, a characteristic surface characteristic, and a high purity silicon compound. The average diameter of the spherical basic particles is 5 to 50 nm. It has a size and has a large surface area due to the small particles, the value of which is in the form of a powder ranging from 40 to 400 m 2 / g.

 Silica powder is used 40 to 99% by weight in the total composition of the silica insulation. If the amount is less than 40% by weight, the thermal conductivity value measured according to the thermal conductivity measurement method of KS L 9016 thermal insulation material becomes 0.026W / mK or more, and the insulation performance is deteriorated. There is a problem in moldability that the shape of the edge portion of the molded body is relatively lowered.

 The reinforcing fiber used in the present invention uses a mixed fiber or an organic synthetic fiber of an inorganic fiber and an organic synthetic fiber, and uses a fiber having a diameter of 1 to 100 µm and a length of 6 to 40 mm, and the inorganic fiber is a glass fiber and a ceramic fiber. And the organic synthetic fiber uses a fiber such as PAN, PVA, PP.

 Reinforcing fibers use from 0.5 to 20% by weight. If the amount is less than 0.5% by weight, there is a problem in that the strength expression effect and formability by the reinforcing fiber is lowered, and when it exceeds 20% by weight, the thermal conductivity value measured based on the method of measuring the thermal conductivity of the KS L 9016 thermal insulation material is relatively high. Since this becomes 0.026 W / mK or more, there exists a problem that heat insulation performance falls. In addition, when the fiber length of less than 6 mm is used, the reinforcing effect of the fiber is inferior, and when the fiber length of 40 mm or more is used, the fiber is difficult to disperse during dry mixing with silica powder, and the agglomeration of the fiber itself occurs. A problem arises in that moldability deteriorates.

 The reinforcing fibers are evenly dispersed to form an integrated bond with the silica powder aggregates, thereby exhibiting the primary formability and strength enhancing effect of the present heat insulating material. The mixed fibers or the organic synthetic fibers of the inorganic fibers and the organic synthetic fibers alone Can be used as

Radiation shielding additives and reinforcing materials used in the present invention is an opaque agent, the opaque agent has the advantage of blocking the radiant heat by scattering the radiant heat. Radiant heat shield additives and reinforcing materials use talc, silicon carbide, iron oxide, zirconium oxide, graphite and the like, and 0 to 50% by weight of the total composition of the insulation. When the heat insulator is used at room temperature, it is not necessary to add a radiation shielding additive, but when used at high temperatures, especially fire doors, the amount thereof does not exceed 50% by weight. When it exceeds 50% by weight, the thermal conductivity value measured based on the thermal conductivity measurement method of KS L 9016 thermal insulation material becomes 0.026W / mK or more, and thus there is a problem that thermal insulation performance is deteriorated. In addition, talc, silicon carbide, iron oxide, zirconium oxide, graphite, and the like also give a function as a reinforcing material that the heat insulating material can have a certain strength as a building material.

6-side wrapping used in the present invention (wrapping) packaging is used shrink film such as PE film or LDPE, in the heat-insulating material that requires moisture resistance, the moisture permeability of the film 30 g / ㎡ or less per 24 hours or the water vapor transmission coefficient of 0.28 g / A film having a moisture resistance of not more than m 2 · h · mmHg is used, and wrapping is performed once or twice. PE film packaging wraps the silica insulation molded body with PE film and seals it with heat bonding, and shrink film packaging such as LDPE wraps the silica insulation molded body with shrink film such as LDPE and shrink wraps it using a shrink wrap machine.

The nonwoven fabric used as the final finishing material in the present invention uses a nonwoven fabric selected from polyester, viscose rayon, nylon, polypropylene and the like. Determine the usage and mixing ratio of nonwoven raw materials according to the purpose and manufacture. The final finishing package is finished by sealing or sewing thread with heat seal.

Hereinafter, the present invention will be described in more detail with reference to Examples. These examples are only for illustrating the present invention, and it will be apparent to those skilled in the art that the scope of the present invention is not to be construed as being limited by these examples.

Example 1: Measurement of physical properties of non-combustible insulation

Non-combustible insulation was applied to the door by dry mixing with the ingredients and contents as described above, the manufacturing method was based on the method described in the detailed description of the invention.

The prepared non-combustible heat insulating material was attached to the inside of the front door with a water-soluble adhesive, and the joints were filled with urethane foam, and the handle portion and the front door keys were filled with paper honeycomb or urethane foam.

[Measurement of properties]

The door with insulation was tested for door open and close repeatability according to KS F 2632 test method. The number of repetitions was tested 100,000 times according to KS F 3109 to check the state of insulation. It was.

The moisture absorption test was measured in accordance with ASTM C 1104. The moisture absorption rate was 0.6 V%, which had little effect on the insulation, such as shape deformation of the insulation.In the thermal conductivity measurement according to KS L 9016, 0.024 W / mK at 0.024 W / mK W / mK also satisfies the thermal conductivity performance.

In case of applying 10mm in thickness to the heat-transmittance rate of the building part prescribed by the rules on the facility standard of building, etc., if the thickness of 10mm is applied, the heat-transfer rate value of the door is 1.65W / ㎡K. Even if the insulation of the present invention was applied with a very low thickness, it was no problem at all.

Flame retardant performance is measured according to KS F ISO 1182 (non-flammability test method of building materials) and KS F 2271 (gas hazard test) according to the flame retardant performance standard of building interior finishing material (Notice No. 2006-476 of Ministry of Construction and Transportation). Nonflammable performance was secured as a nonflammable material.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, those skilled in the art will appreciate that such specific embodiments are merely preferred embodiments and that the scope of the present invention is not limited thereby. something to do. Accordingly, the actual scope of the present invention will be defined by the appended claims and their equivalents.

Claims (7)

40 to 99% by weight of silica powder, 0.5 to 20% by weight of mixed fibers of inorganic and organic synthetic fibers or 0 to 50% by weight of reinforcing fibers made of organic synthetic fibers, 0 to 50% by weight of radiant heat blocking additives and reinforcing materials, After wrapping six sides with shrink film such as PE film or LDPE with 30g / m² or less or moisture permeability coefficient of 0.28g / m² · h · mmHg or less per 24 hours, the final package is wrapped with nonwoven fabric. Non-combustible insulation applied to the door (door) characterized in that. According to claim 1, wherein the silica powder is a spherical amorphous high-purity silicon compound, the average particle diameter of the spherical base particles 5 ~ 50nm, the specific surface area of the door characterized in that the powder form (40 ~ 400 ㎡ / g) Nonflammable insulation applied to). According to claim 1, wherein the reinforcing fibers are mixed fibers or organic synthetic fibers of inorganic fibers and organic synthetic fibers, 1 to 100 ㎛ in diameter, 6 to 40 mm in length of the fiber, glass fibers, ceramic fibers, PAN, Nylon, PVA , Non-combustible insulation applied to the door (door), characterized in that the fiber selected from PP. The non-combustible heat insulating material according to claim 1, wherein the radiation shielding additive and the reinforcing material are selected from talc, silicon carbide, iron oxide, zirconium oxide, and graphite as an opaque agent. delete The nonwoven fabric according to claim 1, wherein the nonwoven fabric uses a nonwoven fabric selected from polyester, viscose rayon, nylon, and polypropylene, and is subjected to heat-sealed sealing or sewing thread for final finishing packaging. insulator. Non-combustible insulation is bonded to the inside of the door with a water-soluble adhesive, the joint of the door and the non-combustible insulation is filled with paper honeycomb or urethane foam non-combustible insulation prepared by any one of claims 1 to 4, Construction method.