JP4548028B2 - Vacuum insulation - Google Patents

Description

The present invention relates to a vacuum heat insulating material using a radiant heat conduction-suppressing film having an excellent infrared reflection effect.

  In recent years, there has been an active movement to promote energy conservation as a countermeasure against global warming, which is a global environmental problem, and for thermal and thermal equipment, there is a demand for thermal insulation with excellent thermal insulation performance from the viewpoint of effective use of heat. It has been. In particular, when a heat insulating material is used in a high temperature region exceeding 150 ° C., the energy saving effect is remarkably exhibited, and therefore, application to a printing machine, a copying machine, a liquid crystal projector, and a semiconductor manufacturing apparatus is expected.

  In the high temperature region exceeding 150 ° C., unlike the room temperature region, the radiant heat conduction component by infrared rays cannot be ignored, so that the heat insulating performance of the heat insulating material is deteriorated. Therefore, a technique for suppressing heat conduction due to radiation is required.

  As a technique for suppressing radiant heat, a heat insulating film in which a metal foil layer and a protective layer are provided on the top of a plastic film has been reported (for example, see Patent Document 1).

  In addition, a heat insulating laminate film in which an outer shell material of a vacuum heat insulating material has an infrared reflecting function has been reported (for example, see Patent Document 2).

  FIG. 6 is a cross-sectional view of a conventional heat insulating film described in Patent Document 1. The heat insulating film 1 is a plastic film 3 having a surface layer 2 of high-purity metal having large crystal grains, and a thin metal layer 4 having a low thermal emissivity has ultra-flat crystal grains on the smooth surface of the surface layer 2. In this way it is layered.

  Further, a protective layer 5 is formed on the surface of the thin metal layer 4 so as to allow the surface of the thin metal layer 4 to be stably maintained while allowing free transmission of infrared rays and far infrared rays. Since the heat rays composed of infrared rays and far infrared rays to penetrate into the heat insulating film 1 repeat total reflection within the layer of the metal thin layer 4 having ultra-flat crystal grains, and then reflect toward the outside, It is said that a high heat insulation effect can be obtained.

FIG. 7 is a cross-sectional view of a conventional heat insulating laminate film described in Patent Document 2. This heat insulating laminate film is obtained by bonding a protective layer 5, a far-infrared reflective layer 6, a gas barrier layer 7, and a heat welding layer 8 with an adhesive 9. Since this heat insulating laminate film uses a far-infrared transmitting substance for the protective layer and a metal foil for the far-infrared reflecting layer, it is said that a high far-infrared reflectance can be obtained.
JP-A-5-164296 JP-A-5-193668

  However, in the configuration of Patent Document 1, a method for joining the metal thin layer and the protective layer is not disclosed, and the feasibility is poor. If an adhesive is used, infrared rays and far-infrared rays are absorbed by the adhesive and conducted as heat to the thin metal layer, resulting in a reduction in infrared reflection effect.

  Further, in the configuration of Patent Document 2, since a far-infrared transmitting substance is used for the protective layer, infrared rays can reach the far-infrared reflecting layer, but the definition of the infrared transmitting substance is unclear, The adhesive between the protective layer and the far-infrared reflective layer is also unclear because it is only defined as an adhesive that does not impair the far-infrared transmission effect.

This invention solves the said conventional subject, and it aims at providing the vacuum heat insulating material using the radiation heat conduction suppression film which has the outstanding infrared reflective effect.

In order to solve the above problems, the vacuum heat insulator of the present invention has less vacuum heat insulator der in which the resin film and the infrared reflective layer is also provided in the multi-layer has been radiation heat conduction suppressing film surface with an adhesive The resin film is made of a fluorine-based resin film or a polyphenylene sulfide film, the infrared reflection layer is made of a metal foil, and the adhesive is partially applied to the surface of the resin film or the infrared reflection layer and bonded. The part and the non-adhesive part form a geometric pattern, and the adhesive application rate with respect to the effective area of the radiant heat conduction-suppressing film is 25% or more and 80% or less of the whole .

Thereby, the infrared rays that have passed through the resin film are incident on the bonded portion and the non-bonded portion of the adhesive, respectively. At this time, a part of the infrared light incident on the bonded portion is absorbed by the infrared absorbing action of the adhesive and is conducted as heat to the infrared reflecting layer. However, since there is no adhesive in the non-bonded portion, no infrared absorption occurs. Thus, by partially apply | coating an adhesive agent, the infrared absorption factor of a radiation heat conduction suppression film can be reduced, and the heat conduction by radiation can be suppressed. Therefore, an increase in heat conduction due to radiation of the heat insulating material can be suppressed, and an excellent heat insulating effect is exhibited.

The vacuum heat insulating material of the present invention, I least vacuum heat insulator der also has the resin film and the infrared reflective layer provided on the multi-layer has been radiation heat conduction suppressing film surface with an adhesive, the resin film is a fluorine-based resin A film or a polyphenylene sulfide film, the infrared reflecting layer is made of a metal foil, the adhesive is partially applied to the surface of the resin film or the infrared reflecting layer, and an adhesive portion and a non-adhesive portion are geometric patterns The adhesive application rate with respect to the effective area of the radiant heat conduction-suppressing film is 25% or more and 80% or less of the whole , the adhesive is partially applied, and the adhesive part and the non-adhesive part Therefore, it is possible to provide a film having an excellent infrared reflection effect that reduces the infrared absorption rate and does not peel off the resin film. In addition, the adhesive part and the non-adhesive part form a geometric pattern, and the non-adhesive part is uniformly dispersed in any part of the film, so no matter where the infrared rays generated from the heat source are irradiated, The film can be efficiently reflected, and the adhesive portions are uniformly dispersed, so that the mechanical strength of the film can be made uniform. Moreover, since the adhesive application rate with respect to the effective area of the radiant heat conduction suppression film is 25% or more and 80% or less of the whole, the non-adhesive portion is secured in the adhesive portion while ensuring the adhesive strength between the resin film and the infrared reflective layer In, infrared rays can be reflected efficiently. Further, when the resin film is a fluorine-based resin, infrared reflection by the infrared reflection layer can be performed more efficiently, and the effects of heat resistance, corrosion resistance, and chemical resistance can be imparted to the radiant heat conduction suppression film. In addition, when the resin film is a polyphenylene sulfide film, it is possible to perform infrared reflection on the infrared reflection layer more efficiently like the fluororesin film, and to impart heat resistance and flame resistance effects to the radiant heat conduction suppression film. can do. Moreover, since an infrared reflective layer consists of metal foil, a high reflectance and gas barrier property can be added to a radiant heat conduction suppression film. Moreover, by suppressing radiant heat conduction with the radiant heat conduction suppressing film, an increase in heat conduction due to radiation of the heat insulating material can be suppressed, and an excellent heat insulating effect is exhibited.

  The invention according to claim 1 is a radiation heat conduction suppression film having an infrared reflectance of 50% or more, in which at least an infrared absorption rate of a resin film and an infrared reflection layer are multilayered by an adhesive. The adhesive is partially applied to form an adhesive part and a non-adhesive part.

  Thereby, by covering the infrared reflective layer with a resin film, the infrared reflective layer can be protected against oxidative degradation and external impact, and electrical insulation can be imparted to the radiant heat conduction suppressing film.

  Moreover, the infrared rays that have passed through the resin film are incident on the bonded portion and the non-bonded portion of the adhesive, respectively. At this time, a part of the infrared light incident on the bonded portion is absorbed by the infrared absorbing action of the adhesive, but no infrared light is absorbed because there is no adhesive in the non-bonded portion.

  Thus, by apply | coating an adhesive agent partially, the infrared absorption factor of a radiation heat conduction suppression film can be reduced, and the heat conduction by radiation can be suppressed.

  In addition, there is no particular designation regarding the method and shape of forming the adhesive and non-adhesive parts of the adhesive. Printing technologies such as solvent etching, photoresist etching, gravure printing, offset printing, flexographic printing, and screen printing May be used.

  In addition, the structure of the radiant heat conduction suppression film consists of a resin film and an infrared reflective layer that are multilayered with an adhesive. By increasing the number of resin films and infrared reflective layers, the abrasion resistance of the radiant heat conduction suppressive film is increased. And corrosion resistance can be improved.

In addition, since the adhesive is applied so that the bonded portion and the bonded portion form a geometric pattern , the non-bonded portion is uniformly dispersed in any part of the film. Can be efficiently reflected no matter where it is irradiated, and since the adhesive portions are uniformly dispersed, the mechanical strength of the film can be made uniform.

  The geometric pattern is a pattern made of a triangle, a rectangle, a rhombus, a polygon, a circle, or the like.

Moreover, the adhesive application rate with respect to the effective area of the radiant heat conduction-suppressing film is 25% or more and 80% or less of the whole.

  The effective area of the radiant heat conduction suppression film is the area of the infrared reflective layer where the infrared reflection effect appears, and the adhesive application rate is the ratio of the adhesive application area to the effective area of the radiant heat conduction suppression film It is.

  Thereby, in a non-bonding part, infrared rays can be reflected efficiently, ensuring adhesive strength of a resin film and an infrared reflective layer in a bonding part.

In addition, the resin film is a fluororesin or polyphenylene sulfide film .

  Since the fluororesin has relatively little absorption of 2 μm to 25 μm, which is an infrared wavelength, and can further suppress the absorption of infrared rays by the resin film, the infrared reflection in the infrared reflection layer can be more efficiently performed.

  In addition, examples of the fluororesin include ETFE film, FEP film, PFA film, and CTFE film, and these films are excellent in corrosion resistance and chemical resistance as well as heat resistance. Moreover, the effect of corrosion resistance and chemical resistance can be imparted.

  Polyphenylene sulfide film, like fluororesin film, has relatively little absorption of infrared wavelength compared to other resins, and can further suppress infrared absorption by resin film, so that infrared reflection at the infrared reflection layer can be further suppressed. It can be done efficiently.

  Moreover, since the polyphenylene sulfide film is excellent in heat resistance and flame retardancy, it can impart heat resistance and flame retardancy effects to the radiant heat conduction suppression film.

The infrared reflecting layer is a metal foil. By using a metal foil obtained by thinly extending a metal, a high reflectance and gas barrier property can be added to the radiant heat conduction suppression film.

Moreover, the vacuum heat insulating material of the present invention is provided with the radiant heat conduction suppression film on the surface, and by suppressing radiant heat conduction with the radiant heat conduction suppressing film, it is possible to suppress an increase in heat conduction due to radiation of the heat insulating material. And an excellent heat insulating effect is exhibited.

The vacuum heat insulating material of the present invention, polystyrene foam and polyurethane foam, and the foam plastic-based insulation material, such as phenol foam, glass wool, rock wool, one of the insulation inorganic-based insulation material such as glass powder, a gas barrier property It is a vacuum heat insulating material that is covered with a jacket material and decompressed inside .

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 shows a cross-sectional view of the radiant heat conduction-suppressing film in Embodiment 1 of the present invention, and FIG. 2 is applied in the form of dots as an example of adhesive partial application in Embodiment 1 of the present invention. The schematic diagram of an adhesive agent is shown.

  In FIG. 1, the radiant heat conduction suppression film 10 is configured such that a resin film 11 having an infrared absorption rate of less than 25% and an infrared reflection layer 12 are laminated by an adhesive 9. In FIG. 2, the adhesive 9 is printed such that the bonded portion 13 and the non-bonded portion 14 are in a dot shape.

  About the radiation heat conduction suppression film 10 comprised as mentioned above, the operation | movement and an effect | action are demonstrated below.

  The resin film 11 protects the infrared reflective layer against oxidative deterioration and external impact, and also has an effect of imparting electrical insulation to the radiant heat conduction suppressing film, and the effect of suppressing radiant heat conduction continues for a long period of time. It is.

  Infrared rays generated from the heat source pass through the resin film 11 and enter the bonding portion 13 or the non-bonding portion 14 of the adhesive 9. At this time, a part of the infrared light incident on the bonding portion 13 is absorbed by the infrared absorbing action of the adhesive 9 and becomes heat, but the infrared light incident on the non-bonding portion 14 is absorbed because there is no adhesive 9. It goes to the infrared reflective layer 12 without being reflected and is reflected on the surface of the infrared reflective layer 12. Then, the reflected infrared light passes through the adhesive portion 13 and the non-adhesive portion 14 of the adhesive 9 again and passes through the resin film 11.

  As described above, in the present embodiment, the radiant heat conduction suppression film 10 is partially coated with the adhesive 9 to form the bonded portion 13 and the non-bonded portion 14, thereby forming the resin film 11 and the infrared reflection. While the adhesive strength with the layer 12 is secured, the proportion of infrared rays absorbed by the adhesive 9 is low, and the infrared rays that have passed through the resin film 11 and reached the infrared reflecting layer 13 are effectively reflected by the infrared reflecting layer. And can exhibit an excellent infrared reflection effect.

  The resin film 11 in the embodiment of the present invention includes, for example, an ETFE film (melting point 265 ° C., infrared absorption rate 8%), FEP film (melting point 270 ° C., infrared absorption rate 8%), PFA film (melting point 305 ° C., Infrared absorption rate 8%), PPS film (melting point 285 ° C., infrared absorption rate 10%), unstretched CPP film (melting point 170 ° C., infrared absorption rate 17%), PET film (melting point 265 ° C., infrared absorption rate 18%) In addition, PSF films (continuous use temperature 150 ° C., infrared absorption rate 10%) and PES films (continuous use temperature 180 ° C., infrared absorption rate 15%) can be used as those having no melting point. In particular, a fluororesin film or a polyphenylene sulfide film having a small absorption rate of 2 to 25 μm in the infrared wavelength region is used. And makes it possible to efficiently infrared reflection on the infrared reflective layer 12.

  Moreover, as the infrared reflective layer 12, for example, a metal foil obtained by thinly extending a metal such as an aluminum foil, a gold foil, a silver foil, a copper foil, a nickel foil, or a stainless steel foil, or a metal on which aluminum, gold, silver, copper, or nickel is deposited Although a vapor deposition film etc. can be considered, it is preferable to use an aluminum foil or a copper foil that has a high infrared reflectance and a low process cost.

  Examples of the adhesive 9 include organic adhesives such as polyurethane adhesives, epoxy adhesives, resorcinol resin adhesives, phenol resin adhesives, silicone imide adhesives, water glass, ceramics, cement, and the like. Inorganic adhesives can be used.

  Moreover, between the resin film 11 and the infrared reflective layer 12, the adhesion part 13 and the non-adhesion part 14 by the adhesive agent 9 are formed. As a formation method of the adhesion part 13 and the non-adhesion part 14, gravure is used. Printing techniques such as printing, offset printing, flexographic printing, and screen printing, etching with a solvent or light, and the like are conceivable, but in reality, it is preferable to use a printing technique with a low process cost.

  The adhesive 9 may be applied to either surface in consideration of physical properties such as flexibility and tensile strength of the infrared reflecting layer 12 and the resin film 11.

  Moreover, although the printed pattern of the adhesive portion 13 is a dot shape, depending on the usage shape of the radiant heat conduction suppression film, a geometric pattern made of a triangle, a rectangle, a rhombus, a polygon, a circle, or the like, or a non-geometric shape such as a design. A study pattern may be used.

  Moreover, although the area ratio of the adhesion part 13 and the non-adhesion part 14 can change freely according to a required adhesive strength and the degree of an infrared reflective effect, while ensuring the adhesive strength of a resin film and an infrared reflective layer In order to reflect infrared rays efficiently, the adhesive application rate is preferably 25% or more and 80% or less.

  Moreover, although the resin film 11 and the infrared reflective layer 13 were laminated | stacked by the adhesive agent 12 as the structure of the radiant heat conduction suppression film 10, the resin film 11 and the infrared reflective layer 13 do not need to be one layer, respectively.

  For example, when there are heat sources on both sides of the radiant heat conduction suppression film 10, the radiant heat conduction suppression film 10 is generated from each heat source by bonding the resin film 11 to both surfaces of the infrared reflection layer 13 with the adhesive 12. The influence of infrared rays generated from the other heat source can be eliminated.

  By attaching the radiant heat conduction suppression film 11 of the present invention as described above to a place where radiant heat conduction needs to be suppressed, an effective heat insulating effect can be obtained.

  Examples of installation locations include building materials such as roofs and walls of houses and factories, information equipment such as computers, printers, copiers, and projectors, cooking appliances such as jarpots, microwave ovens, and water heaters, and semiconductor manufacturing equipment. Any case that requires heat insulation or heat insulation is considered.

(Embodiment 2)
FIG. 3 is a cross-sectional view of the heat insulating member according to Embodiment 2 of the present invention. In FIG. 3, the radiant heat conduction suppression film 10 is attached to the surface of the heat insulating material 15 that becomes high temperature.

  The radiant heat conduction suppression film 10 can use the same configuration as that of the first embodiment of the present invention. In this embodiment, a 2 μm PPS film (infrared absorptivity 10%), a 25 μm FEP film (infrared absorptivity 8%), and a 15 μm PET film (infrared absorptivity 18%) are used as the resin film 11, respectively. A 12 μm aluminum foil was used as the reflective layer 12.

  Examples of the heat insulating material 15 include foamed plastic heat insulating materials such as polystyrene foam, polyurethane foam, and phenol foam, inorganic heat insulating materials such as glass wool, rock wool, and glass powder, and these heat insulating materials as jacket materials having gas barrier properties. It is possible to use a vacuum heat insulating material that is covered with a vacuum and the inside is decompressed.

  In addition, the attachment method to the heat insulating member is not particularly specified, and chemical bonding by an adhesive or physical bonding such as nail fastening or stitching may be used, but considering application to various heat insulating members, Chemical bonding with an adhesive is preferred.

  About the radiant heat conduction suppression film comprised as mentioned above, the result confirmed about the radiant heat conduction suppression effect when changing the adhesive application rate is shown in Example 1 to Example 9, and the comparative example is compared with Comparative Example 1 Example 13 shows. In order to clarify the effect of suppressing radiant heat conduction, a glass wool board having a thickness of 12 mm is used as the heat insulating member in the present embodiment.

  Moreover, performance evaluation made the evaluation item the radiant heat conduction suppression film surface center temperature when a halogen heater was irradiated from the perpendicular | vertical direction of the glass wool board surface of thickness 12mm.

  In addition, the evaluation standard is that a halogen heater is installed at a distance where the surface temperature of the glass wool board alone is 150 ° C., and the radiant heat conduction suppression film (Comparative Example 5 and Comparative Example 7) has an adhesive application rate of 100%. , Comparative Example 9 and Comparative Example 11) are the film surface center temperatures when the glass wool board is placed on the high temperature side surface. If a reduction effect of 10 ° C. or more was obtained from this temperature, it was judged that there was an effect of suppressing radiant heat conduction by partial application of the adhesive.

  Here, the infrared absorptance of the resin film is the infrared absorptivity obtained at 150 ° C. using the JEOL Fourier transform infrared spectrophotometer JIR5500 type and the infrared radiation unit IR-IRR200. I saw it. The infrared reflectance was measured at a relative reflection of 12 ° of the reflection device using a Hitachi infrared spectrophotometer 270-30.

Example 1
On one side of an aluminum foil having a thickness of 12 μm as an infrared reflecting layer, an adhesive made of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3), and ethyl acetate, The adhesive part and the non-adhesive part were applied using a gravure printing method so that the adhesive part was 25:75 (adhesive application rate: 25%), and a 2 μm PPS film (infrared absorptivity 10%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 82%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 117 ° C.

(Example 2)
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, It was applied using a gravure printing method so that the bonded portion and the non-bonded portion were 63:37 (adhesive application rate: 63%), and a 2 μm PPS film (infrared absorption rate 10%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 74%. When this radiant heat conduction suppression film was attached to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 123 ° C.

(Example 3)
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, It was applied using a gravure printing method so that the bonded portion and the non-bonded portion were 80:20 (adhesive application rate: 80%), and a 2 μm PPS film (infrared absorption rate 10%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 71%. When this radiant heat conduction suppression film was attached to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 125 ° C.

Example 4
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, The adhesive part and the non-adhesive part were applied using a gravure printing method so that the adhesive part was 25:75 (adhesive application rate: 25%), and a 25 μm FEP film (infrared absorptivity 8%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 84%. When this radiant heat conduction suppression film was attached to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 115 ° C.

(Example 5)
On one side of an aluminum foil having a thickness of 12 μm as an infrared reflecting layer, an adhesive made of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3), and ethyl acetate, A 25 μm FEP film (infrared absorptivity 8%) was laminated as a resin film by applying a gravure printing method so that the adhesion part and the non-adhesion part were 45:55 (adhesive application rate: 45%).

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 79%. When this radiant heat conduction suppression film was attached to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 116 ° C.

(Example 6)
On one side of an aluminum foil having a thickness of 12 μm as an infrared reflecting layer, an adhesive made of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3), and ethyl acetate, It was applied using a gravure printing method so that the bonded portion and the non-bonded portion were 63:37 (adhesive application rate: 63%), and a 25 μm FEP film (infrared absorption rate 8%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 77%. When this radiant heat conduction suppression film was attached to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 119 ° C.

(Example 7)
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, The adhesive part and the non-adhesive part were applied using a gravure printing method so that the ratio was 25:75 (adhesive application rate: 25%), and a 15 μm PET film (infrared absorptivity 18%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 64%. When this radiant heat conduction suppression film was attached to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 123 ° C.

(Example 8)
On one side of an aluminum foil having a thickness of 12 μm as an infrared reflecting layer, an adhesive made of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3), and ethyl acetate, The adhesive part and the non-adhesive part were applied using a gravure printing method so as to be 45:55 (adhesive application rate: 45%), and a 15 μm PET film (infrared absorptivity 18%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured to be 59%. When this radiant heat conduction suppression film was attached to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 126 ° C.

Example 9
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, It was applied using a gravure printing method so that the bonded portion and the non-bonded portion were 80:20 (adhesive application rate: 80%), and a 15 μm PET film (infrared absorption rate 18%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 55%. When this radiant heat conduction suppression film was attached to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 130 ° C.

(Example 10)
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, The adhesive part and the non-adhesive part were applied using a gravure printing method so that the adhesive part was 25:75 (adhesive application rate: 25%), and a 12 μm FEP film (infrared absorptivity 8%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 84%. When this radiant heat conduction suppression film was attached to a vacuum heat insulating material made of glass wool and evaluated, the radiant heat conduction suppression film surface center temperature was 107 ° C.

(Example 11)
Polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310) and polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) were deposited on the vapor deposition surface of a vapor deposition film obtained by depositing aluminum on one side of a 2 μm PPS film as an infrared reflective layer. ) And ethyl acetate are applied using a gravure printing method so that the adhesive part and the non-adhesive part are 25:75 (adhesive application rate: 25%), and a 12 μm FEP film as a resin film (Infrared absorption rate 8%) was laminated.

  The infrared reflectance of the radiant heat conduction-suppressing film of this example was measured and found to be 73%. When this radiant heat conduction suppression film was attached to a vacuum heat insulating material made of glass wool and evaluated, the radiant heat conduction suppression film surface center temperature was 121 ° C.

  Moreover, since a metal vapor deposition film was used for the infrared reflection layer, flexibility, impact resistance, and low thermal conductivity could be added to the radiant heat conduction suppression film.

(Comparative Example 1)
When the glass wool board was irradiated with heat from a halogen heater without installing a radiant heat suppression film, the surface center temperature of the glass wool board was 150 ° C.

(Comparative Example 2)
A 12 μm aluminum foil (infrared reflectance 95%) was directly placed on the glass wool board surface as an infrared reflecting layer. When this heat insulating member was irradiated with heat from a halogen heater, the center temperature of the aluminum foil surface was 98 ° C., but after 10 days had elapsed after use, the increase in the center temperature of the aluminum foil surface was confirmed, and infrared absorption due to oxidative degradation was observed. Can be estimated.

(Comparative Example 3)
A 2 μm PPS film (infrared absorptivity 10%) was temporarily fixed as a resin film on one side of a 12 μm aluminum foil as an infrared reflecting layer (adhesive application rate: 0%).

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 89%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 110 ° C., but the 2 μm PPS film easily breaks, and the 12 μm aluminum foil Was generated and lacked handling properties.

(Comparative Example 4)
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, It was applied using a gravure printing method so that the bonded portion and the non-bonded portion were 10:90 (adhesive application rate: 10%), and a 2 μm PPS film (infrared absorption rate 10%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 86%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 115 ° C. However, since the adhesion area with the aluminum foil is very small, the 2 μm PPS film is The aluminum foil of 12 μm was easily broken and wrinkled, and lacked handling properties.

(Comparative Example 5)
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, It was applied to the entire surface of the aluminum foil (adhesive application rate: 100%), and a 2 μm PPS film (infrared absorptivity 10%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 68%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 137 ° C.

(Comparative Example 6)
A 25 μm FEP film (infrared absorptivity 8%) as a resin film was temporarily fixed to one side of a 12 μm aluminum foil as an infrared reflecting layer (adhesive application rate: 0%).

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 90%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 107 ° C., but no adhesive was interposed between the FEP film and the aluminum foil. The aluminum foil had wrinkles and lacked handling properties.

(Comparative Example 7)
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, It was applied to the entire surface of the aluminum foil (adhesive application rate: 100%), and a 25 μm FEP film (infrared absorptance 8%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 69%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 134 ° C.

(Comparative Example 8)
A 15 μm PET film (infrared absorptivity 18%) as a resin film was temporarily fixed to one side of a 12 μm aluminum foil as an infrared reflecting layer (adhesive application rate: 0%).

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 85%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 114 ° C., but no adhesive was interposed between the PET film and the aluminum foil. The foil was wrinkled and had poor handling properties.

(Comparative Example 9)
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, It was applied to the entire surface of the aluminum foil (adhesive application rate: 100%), and a 15 μm PET film (infrared absorptivity 18%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 69%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 144 ° C.

(Comparative Example 10)
A 120 μm polyimide film (infrared absorptivity: 80%) was temporarily fixed as a resin film on one side of a 12 μm aluminum foil as an infrared reflecting layer (adhesive application rate: 0%).

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 45%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the radiant heat conduction suppression film surface center temperature was 165 ° C., and the temperature was higher than that without the radiant heat conduction suppression film (Comparative Example 1). I have.

  This is because the infrared absorption rate of the polyimide film is as high as 80%, and the infrared rays from the heat source are absorbed.

  Moreover, since an adhesive agent does not intervene between a polyimide film and aluminum foil, wrinkles were produced in the aluminum foil, and handling properties were lacking.

(Comparative Example 11)
On one side of a 12 μm aluminum foil as an infrared reflecting layer, an adhesive composed of polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) and ethyl acetate, It was applied to the entire surface of the aluminum foil (adhesive application rate: 100%), and a 120 μm polyimide film (infrared absorption rate 80%) was laminated as a resin film.

  It was 30% when the infrared reflectance of the radiant heat conduction suppression film of this comparative example was measured. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the surface temperature of the radiant heat conduction suppression film was 177 ° C., which was higher than that without the radiant heat conduction suppression film (Comparative Example 1). I have.

  This is because the infrared absorption rate of the polyimide film is as high as 80%, and the infrared rays from the heat source are absorbed.

(Comparative Example 12)
A 10 μm CPP film (infrared absorptivity 17%) as a resin film was temporarily fixed to one side of a 12 μm matte aluminum foil as an infrared reflecting layer (adhesive application rate: 0%).

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 45%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the surface temperature of the radiant heat conduction suppression film was 152 ° C., which was higher than that without the radiant heat conduction suppression film (Comparative Example 1). I have.

  This is because the infrared heat reflectance of the radiant heat conduction-suppressing film is 45%, so that the effect of suppressing radiant heat conduction could not be confirmed. Further, since no adhesive was interposed between the CPP film and the aluminum foil, wrinkles were generated in the aluminum foil, and the handling property was lacking.

(Comparative Example 13)
An adhesive comprising a polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310), polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3), and ethyl acetate on one surface of a 12 μm matte aluminum foil as an infrared reflecting layer. Was applied to the entire surface of the aluminum foil (adhesive application rate: 100%), and a 10 μm CPP film (infrared absorptivity 17%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 36%. When this radiant heat conduction suppression film was affixed to a glass wool board and evaluated, the surface temperature of the radiant heat conduction suppression film was 162 ° C., which was higher than that without the radiant heat conduction suppression film (Comparative Example 1). I have.

  This is because the infrared heat reflectance of the radiant heat conduction-suppressing film is 36%, so that the radiant heat conduction-suppressing effect could not be confirmed.

(Comparative Example 14)
Polyol (Mitsui Takeda Chemical Co., Ltd .: Takelac A-310) and polyisocyanate (Mitsui Takeda Chemical Co., Ltd .: Takenate A-3) were deposited on the vapor deposition surface of a vapor deposition film obtained by depositing aluminum on one side of a 2 μm PPS film as an infrared reflective layer. ) And ethyl acetate were applied to the entire aluminum deposition surface (adhesive application rate 100%), and a 12 μm FEP film (infrared absorptance 8%) was laminated as a resin film.

  The infrared reflectance of the radiant heat conduction-suppressing film of this comparative example was measured and found to be 66%. When this radiant heat conduction suppression film was attached to a vacuum heat insulating material made of glass wool and evaluated, the radiant heat conduction suppression film surface center temperature was 142 ° C.

About the radiant heat conduction suppression film comprised as mentioned above, the result (Examples 1-9 and Comparative Examples 1-13) confirmed about the radiant heat conduction inhibitory effect when changing adhesive application rate is shown in (Table 1). . Further, FIG. 4 shows the relationship between the surface center temperature of the radiant heat conduction suppressing film due to the change in the adhesive application rate, and FIG. 5 shows the relationship between the infrared reflectance of the radiant heat conduction suppressing film and the surface center temperature.

  From the results of FIGS. 4 and 5, it was confirmed that a further effect of suppressing radiant heat conduction can be obtained by partially applying the adhesive to the radiant heat conduction suppressing film having an infrared reflectance of 50% or more.

  Further, when the adhesive application rate is 80% or more, the effect of suppressing radiant heat conduction by partial application of the adhesive is reduced. In addition, when the adhesive application rate is 25% or less, the effect of suppressing radiant heat conduction by partial application of the adhesive is increased, but the adhesive strength of the radiant heat conduction suppressing film is extremely reduced. Since wrinkles are formed in the layer, handling is lacking. Therefore, the adhesive application rate is preferably 25% or more and 80% or less.

As described above, the radiant heat conduction suppression film used in the vacuum heat insulating material of the present invention can suppress infrared absorption in the adhesive layer and efficiently reflect in the infrared reflective layer by partially applying the adhesive. Therefore, it can be used in a space that requires suppression of radiant heat conduction. For example, the present invention can be applied to equipment for using heat and heat, printers, copiers, liquid crystal projectors, and semiconductor manufacturing apparatuses.

Sectional drawing of the radiation heat conduction suppression film in Embodiment 1 of this invention The schematic diagram of the adhesive agent in Embodiment 1 of this invention Sectional drawing of the heat insulation member in Embodiment 2 of this invention Characteristic diagram showing the relationship of the surface center temperature of the radiant heat conduction suppression film due to changes in the adhesive application rate Characteristic chart showing the relationship between the infrared reflectance of the radiant heat conduction suppression film and the surface center temperature Cross section of conventional heat insulation film Cross section of conventional heat insulating laminate film

Explanation of symbols

DESCRIPTION OF SYMBOLS 8 Heat welding layer 9 Adhesive 10 Radiation heat conduction suppression film 11 Resin film 12 Infrared reflective layer 13 Adhesion part 14 Non-adhesion part 15 Heat insulating material

Claims (1)

Least I vacuum heat insulator der in which the resin film and the infrared reflective layer is also provided in the multi-layer has been radiation heat conduction suppressing film surface with an adhesive, the resin film is a fluororesin film or polyphenylene sulfide film, The infrared reflective layer is made of a metal foil, the adhesive is partially applied to the surface of the resin film or the infrared reflective layer , an adhesive portion and a non-adhesive portion form a geometric pattern , and the radiant heat conduction is suppressed. The vacuum heat insulating material characterized by the adhesive application rate with respect to the effective area of a film being 25% or more and 80% or less of the whole .

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