JP2017187098A - Laminate heat insulation film and heat insulation cover - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a laminate heat insulation film that, although dispensing with installation of a separator as a composition of a laminate, has excellent adiabaticity, that can be easily manufactured, and that is excellent in workability.SOLUTION: A laminate heat insulation film is configured such that a metal deposition film A is provided with a metal deposition layer 2a on at least one surface of a heat-resistant resin film 1a; on the metal deposition layer 2a, a metal deposition film B is laminated, the metal deposition film provided with a metal deposition layer 2b on at least one surface of a heat-resistance resin film 1b; and on a side where the metal deposition film A is not laminated, of the metal deposition film, another metal deposition film B is laminated. Between the metal deposition film A and the metal deposition film B, and the metal deposition films B, a printing pattern comprising a resin composition X is provided.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a laminated heat insulating film suitably used for coating a spacecraft, an aircraft, and their constituent members, and a heat insulating cover using the same.

Conventionally, multi-layer insulation materials covering artificial satellites are often used in the form of laminating a plurality of metal vapor-deposited sheets with a net-like separator between them so as to provide heat insulation. Has been.
This multilayer heat insulating material has a sheet-like shape, is appropriately cut, and is joined by sewing to form a certain shape and is fixed around the artificial satellite.

However, when cutting and sewing the multilayer heat insulating material, if each metal vapor deposition sheet of the multilayer heat insulating material is not bundled, a shift occurs between the metal vapor deposition sheets during handling, resulting in a decrease in workability. .
Furthermore, the sewing work itself is time-consuming and labor-intensive work, which has been a cause of high costs.

Patent Document 1 discloses a method of bundling a metal vapor-deposited sheet and a separator with a thread-like member via a heat insulating material.
However, this method requires a separator member in the same manner as in the past to provide heat insulation by forming voids, and further includes a sewing process for binding, which makes the manufacturing process of the multilayer heat insulating material complicated and costly. There was a problem of becoming.

JP 2012-132494 A

  An object of the present invention is to provide a laminated heat insulating film that has good heat insulating properties while requiring no separator as a component of the laminated body, is easy to manufacture, and has excellent workability. .

In the first invention of the present invention, the heat resistant resin is formed on the metal vapor deposition layer (2a) of the metal vapor deposition film (A) in which the metal vapor deposition layer (2a) is provided on at least one surface of the heat resistant resin film (1a). A metal vapor deposition film (B) provided with a metal vapor deposition layer (2b) is laminated on at least one surface of the film (1b),
On the side of the metal vapor deposition film (B) where the metal vapor deposition film (A) is not laminated, another metal vapor deposition film (B) is laminated, and
A laminate characterized in that a printed pattern made of the resin composition (X) is provided between the metal vapor-deposited film (A) and the metal vapor-deposited film (B) and between the metal vapor-deposited films (B). It is a heat insulating film.

Further, the second invention in the present invention is a heat-resistant resin film (1a) on a metal vapor deposition layer (2a) of a metal vapor deposition film (A) provided with a metal vapor deposition layer (2a) on at least one surface. The metal vapor deposition film (B) provided with the metal vapor deposition layer (2b) is laminated on at least one surface of the conductive resin film (1b),
On the side of the metal vapor deposition film (B) where the metal vapor deposition film (A) is not laminated, another metal vapor deposition film (B) is laminated,
Furthermore, it is a laminated heat insulating film formed by laminating a double-sided adhesive sheet (C) in which an adhesive layer (c) is provided on both sides of a metal foil on a metal vapor-deposited film (B) that is farthest from the metal-deposited film (A). There,
A laminate characterized in that a printed pattern made of the resin composition (X) is provided between the metal vapor-deposited film (A) and the metal vapor-deposited film (B) and between the metal vapor-deposited films (B). It is a heat insulating film.

  Moreover, the 3rd invention in this invention is a heat insulation cover formed by sewing the laminated heat insulation film of the 1st invention.

  Moreover, the 4th invention in this invention is a heat insulation cover in which the laminated heat insulation film of 2nd invention is joined two or more through the contact bonding layer (c).

  The fifth invention in the present invention is a covering in which an article is coated with the heat insulating cover of the third or fourth invention.

  A sixth invention in the present invention is the covering according to the fifth invention, wherein the article is a spacecraft, an aircraft, or a component thereof.

  Moreover, 7th invention in this invention arrange | positions the lamination | stacking heat insulation film of 2nd invention in the circumference | surroundings of an article | item, joins the said lamination | stacking heat insulation film with an adhesive layer (c), and is fixed to an article | item. A method for producing an insulated article.

  Moreover, the 8th invention in this invention is a manufacturing method of the heat-insulated article | item characterized by covering an article | item with the heat insulation cover of 4th invention, and fixing to an article | item with an adhesive layer (c).

  Further, the ninth invention of the present invention is the insulated article according to the seventh or eighth invention, characterized in that the heated heat capacity body is brought into contact with the metal vapor-deposited film (A) and fixed to the article. It is a manufacturing method.

  Furthermore, the tenth aspect of the present invention is the heat insulation according to the seventh or eighth aspect, characterized in that an electromagnetic wave is irradiated from the metal vapor-deposited film (A) side and subjected to electromagnetic induction heating to be fixed to the article. Is a method for manufacturing a manufactured article.

  According to the present invention, it is possible to provide a laminated heat insulating film that has good heat insulating properties while having no need to install a separator as a component of the laminated body, is easy to manufacture, and has excellent workability. became.

It is a typical sectional view of the lamination heat insulation film concerning the 1st invention of the present invention. It is a typical sectional view of the lamination heat insulation film concerning the 2nd invention of the present invention. It is a schematic diagram which shows the one aspect | mode of the grid | lattice pattern in the printing pattern by resin composition (X). It is a schematic diagram which shows another aspect of the grid | lattice pattern in the printing pattern by resin composition (X). It is a schematic diagram which shows the checkered pattern in the printing pattern by resin composition (X). It is a schematic diagram which shows the one aspect | mode of the dotted | punctate pattern in the printing pattern by resin composition (X). It is a schematic diagram which shows another aspect of a dotted | punctate pattern in the printing pattern by resin composition (X). It is typical sectional drawing which shows the one aspect | mode of the junction part of the laminated heat insulation films of 2nd invention of this invention. It is typical sectional drawing which shows another aspect of the junction part of the laminated heat insulation films of 2nd invention of this invention. It is typical sectional drawing which shows another aspect of the junction part of the laminated heat insulation films of 2nd invention of this invention.

The metal vapor deposition film (A), which is a constituent member of the laminated heat insulation film according to the first and second inventions, is a film in which a metal vapor deposition layer (2a) is provided on at least one surface of the heat resistant resin film (a). is there.
Here, the “heat resistant resin film” in the present invention refers to a film made of a resin having a glass transition temperature of 60 ° C. or higher. Examples of such materials include polyethylene terephthalate film (abbreviation: PET film), polyethylene naphthalate film (abbreviation: PEN film), polyimide film (abbreviation: PI film), and aramid film. As the heat resistant resin film (a) used in A), a polyimide film is preferable from the viewpoint of heat resistance, flexibility and processability.
Moreover, it is preferable that the thickness of a heat resistant resin film (a) is 5-100 micrometers.

Examples of the metal forming the metal vapor deposition layer (2a) include tin, indium, aluminum, zinc, gold, silver, copper, titanium, nickel, and alloys thereof. A heat-resistant resin film is formed by a conventionally known method. A vapor deposition layer can be formed on at least one surface of (a).
In the present invention, aluminum or silver is preferable from the viewpoint that a foil having high heat reflectance can be obtained.
Moreover, it is preferable that the thickness of a metal vapor deposition layer is 10 nm-1 micrometer.

  The metal vapor-deposited film (A) becomes the outermost layer when the article is covered with a plurality of heat insulating covers formed by bonding the laminated heat insulating films of the present invention.

The metal vapor deposition film (B), which is a constituent member of the laminated heat insulation film according to the first and second inventions, is a film in which a metal vapor deposition layer is provided on at least one surface of the heat resistant resin film (b).
As the heat resistant resin film (b), a polyethylene terephthalate film is preferable from the viewpoint of excellent heat resistance and low cost.
Moreover, it is preferable that the thickness of a heat resistant resin film (b) is 5-100 micrometers.
About formation of a metal vapor deposition layer, it is the same as that of the said metal vapor deposition film (A), and aluminum or silver is used preferably as a metal. The thickness of the metal vapor deposition layer is preferably 10 nm to 1 μm.

A plurality of the metal vapor-deposited films (B) are laminated on the metal vapor-deposited film (A) via a printing pattern made of the resin composition (X). That is, the said printing pattern interposes between a metal vapor deposition film (A) and a metal vapor deposition film (B) and between several metal vapor deposition films (B).
In addition, when the metal vapor deposition layer is provided only in one surface of the metal vapor deposition film (A), it is preferable to laminate | stack a metal vapor deposition film (B) on the said vapor deposition surface.
The preferable number of laminated layers of the metal vapor-deposited film (B) is 5 to 20 layers from the viewpoint of heat reflectivity and weight.
The more preferable number of layers of the metal vapor deposition film (B) is 10 to 15 layers.

The resin composition (X) is a composition containing a known synthetic resin or natural resin, and these resins are classified into thermoplastic resins, thermosetting resins and active energy ray curable resins.
In the present invention, even if the resin originally has no curability, a resin into which a thermosetting functional group has been introduced by an operation such as modification is regarded as a thermosetting resin, and a photocurable functional group. A resin having a group introduced therein is regarded as a photocurable resin.
Moreover, resin composition (X) may contain solvents or dispersion media, such as water and an organic solvent, suitably.
However, in order to suppress the occurrence of misalignment between the laminated layers, it is preferable not to include a substance that imparts lubricity, such as wax.

  As thermoplastic resins, polyolefin resins, vinyl resins, styrene / acrylic resins, diene resins, terpene resins, petroleum resins, cellulose resins, polyamide resins, polyurethane resins, polyester resins, polycarbonate resins, polyimide resins, A fluororesin etc. are mentioned.

  Thermosetting resins include functional groups that can be used for crosslinking reactions by heating, such as alcoholic hydroxyl groups, phenolic hydroxyl groups, methoxymethyl groups, carboxyl groups, amino groups, epoxy groups, oxetanyl groups, oxazoline groups, oxazine groups, aziridines. Any resin having at least one group, thiol group, isocyanate group, blocked isocyanate group, blocked carboxyl group, silanol group, etc. in one molecule, such as acrylic resin, maleic acid resin, polybutadiene resin, polyester Resin, polyurethane resin, epoxy resin, oxetane resin, phenoxy resin, polyimide resin, polyamide resin, phenolic resin, alkyd resin, amino resin, polylactic acid resin, oxazoline resin, benzoxazine resin, silicone resin, fluorine resin Etc., and the like. In addition to the above resin, the thermosetting resin in the present invention includes a compound called a “curing agent” such as a resin or a low molecular compound that reacts with the above functional group to form a chemical crosslink as necessary. May be included.

As the active energy ray-curable resin, a functional group that can be used for a crosslinking reaction by irradiation with light or an electron beam, for example, a (meth) acryloyl group (“methacryloyl group” and “acryloyl group” together with “(meta ) Acryloyl group ”, the same shall apply hereinafter), a resin having at least one epoxy group, vinyl group, oxetanyl group, etc. in one molecule. ”Or“ monomer ”also belongs to this group. Examples include acrylic (meth) acrylate, urethane (meth) acrylate, polyester (meth) acrylate, polyether (meth) acrylate, epoxy (meth) acrylate, polycarbonate (meth) acrylate, diepoxide resin, and alicyclic epoxy resin. It is done.
In addition, when performing a crosslinking reaction by irradiation of light, such as an ultraviolet-ray, it is preferable to use a photoinitiator together.

  The various resins exemplified above may be used alone or in combination of two or more.

Printing resin is suitably used as the resin composition (X). The printing ink is not limited to the colored one, and may be colorless.
Since printing ink is a resin composition excellent in printability, a print pattern can be easily formed by printing.
The formed printed pattern functions as a spacer between layers, and there is a minute space between the metal vapor-deposited film (A) and the metal vapor-deposited film (B) and between the metal vapor-deposited films (B). It contributes to the improvement of the heat insulation of the laminated heat insulation film concerning this invention.
In the present invention, it is extremely important that the layers of the metal vapor-deposited film (B), that is, the metal vapor-deposited films (B) are not adhered to each other.
If there is a space between the metal vapor-deposited films (B), the region exhibits a vacuum insulation effect in a vacuum environment such as outer space, so the heat insulation effect of the laminated heat insulation film of the present invention is It is particularly effective.
Furthermore, since the occurrence of deviation between the metal vapor deposited film (A) and the metal vapor deposited film (B) and between the metal vapor deposited films (B) can be suppressed due to the presence of the printing pattern, the subsequent process, that is, Workability in the cutting process and the sewing process can be improved.

  In addition, in the provided printing part, that is, the image line part, it cannot become a space part when laminated, but since the resin is included as a constituent component, its thermal conductivity is low, and the thermal insulation of the laminated thermal insulation film is reduced. There is no significant loss.

As the printing ink, offset ink, flexographic ink, gravure ink, ink jet ink, silk screen ink and the like can be used, and a space portion can be formed between the metal vapor deposition films (B) by patterning. Anything can be used without any particular limitation.
As a printing method, a conventionally known printing method suitable for the above various inks can be used. For example, offset printing, flexographic printing, gravure printing, ink jet printing, silk screen printing, and the like.

  As other than the printing ink, a laminating adhesive used for packaging retort foods and the like can also be preferably used.

The shape of the printing pattern is not particularly limited, such as a lattice shape, checkered pattern shape, dot shape, etc., but between the metal vapor deposition film (A) and the metal vapor deposition film (B) and between the metal vapor deposition films (B). It is preferable that the non-printing portion is appropriately formed so that the space portion is held therebetween.
Some specific examples of the printing pattern in the present invention are schematically shown in FIGS.

After printing, if necessary, the solvent or dispersion medium is volatilized, and the printed pattern is formed by curing by irradiation with heat or active energy rays.
The thickness of the print pattern is preferably 1 to 50 μm. If thickness is 1 micrometer or more, an appropriate space part can be formed between a metal vapor deposition film (A) and a metal vapor deposition film (B), and between adjacent metal vapor deposition films (B). On the other hand, if thickness is 50 micrometers or less, resin composition (X) will not flow excessively at the time of printing, and it is excellent in printability.
Moreover, it is especially preferable that the formed printed pattern has adhesiveness at room temperature (25 ° C.) from the viewpoint that generation of misalignment between layers can be more effectively suppressed. The degree of tackiness can be adjusted mainly by the selection of the resin in the resin composition (X).

The laminated heat insulating film according to the first invention of the present application can be obtained, for example, by the following steps.
(Method 1-1)
(1): One metal vapor deposition film (A) and a plurality of metal vapor deposition films (B) are prepared.
(2): A printed pattern is formed on one surface of the metal vapor-deposited film (B) by printing, and the printed pattern surface is laminated on the metal vapor-deposited film (A). When a metal vapor deposition film (A) is a single-sided vapor deposition, it superposes | stacks on the metal vapor deposition surface.
(3): Furthermore, the printed pattern surface of the other metal vapor-deposited film (B) having the print pattern formed on one surface is the outer side of the metal vapor-deposited film (B) of the laminate obtained in (2). It is laminated on the surface, that is, the surface on which the print pattern is not provided.
(4): A laminated heat insulating film is obtained by repeating the step (3) a predetermined number of times.

Alternatively, it can also be obtained by the following method.
(Method 1-2)
(1): One metal vapor deposition film (A) and a plurality of metal vapor deposition films (B) are prepared.
(2): A printing pattern is formed on one surface of the metal vapor-deposited film (A) by printing. When the metal vapor deposition film (A) is one-side vapor deposition, a printing pattern is formed on the metal vapor deposition surface.
(3): One metal vapor deposition film (B) is laminated | stacked on the printing pattern surface of the metal vapor deposition film (A) obtained by (1).
(4): A printed pattern is formed on the outer surface of the metal vapor deposited film (B) of the laminate obtained in (3), that is, the surface on which the printed pattern is not provided.
(5): Another metal vapor deposition film (B) is laminated on the printed pattern surface of the laminate obtained in (4).
(6): A laminated heat insulating film is obtained by repeating the steps (4) to (5) a predetermined number of times.

The schematic diagram of the cross section of the laminated heat insulation film concerning 1st invention obtained as mentioned above is shown in FIG.
1 is a metal vapor-deposited film (A), in which a metal vapor-deposited layer is provided only on one surface of the heat-resistant resin film (1a), and in the metal vapor-deposited film (B) Further, the heat-resistant resin film (1b) is provided with a metal vapor-deposited layer on both sides.

The heat insulating cover according to the third invention of the present application is obtained by sewing the laminated heat insulating film according to the first invention.
Specifically, a plurality of laminated heat insulating films are cut as necessary to form a heat insulating cover component so as to conform to the shape of the article to be covered, and the heat insulating cover is produced by sewing these members together. To do. The heat insulating cover is formed in a planar shape or a three-dimensional shape.
After covering the target article with this heat insulating cover, the covering is completed by sewing an appropriate portion of the heat insulating cover and fixing it around the article so as not to fall off.
Or after arrange | positioning the some laminated | multilayer heat insulation film cut | judged as needed around the articles | goods to coat | cover, they are sewn together, and a thermal insulation cover is produced and the coating | covering of articles | goods is completed simultaneously.

This heat insulating cover can be used for coating various kinds of articles, and can be preferably applied to spacecrafts, aircrafts, and their constituent members that require particularly high heat insulating properties.
Examples of spacecraft include artificial satellites, surface exploration vehicles, lunar landers, interorbital transport aircraft, and space stations.
Examples of the air body include an airplane, an airship, and a balloon.

  In the laminated heat insulating film according to the second invention of the present application, the adhesive layer (c) is provided on both sides of the metal foil on the metal vapor-deposited film (B) located at the end of the laminated heat insulating film according to the first invention. The double-sided adhesive sheet (C) is laminated.

  The schematic diagram of the cross section of the laminated heat insulation film concerning 2nd invention is shown in FIG.

Here, among the adhesive layers (c) provided on both surfaces of the metal foil, the adhesive layer in contact with the metal vapor-deposited film (B) is the adhesive layer (c-1), and the adhesive layer on the opposite side is the adhesive layer (c -2).
The adhesive layer (c-1) and the adhesive layer (c-2) may be composed of the same composition or may be composed of different compositions.

The double-sided adhesive sheet (C) in the laminated heat insulating film according to the second invention of the present application functions as an adhesive member for the article to be coated. Specifically, it is bonded to the article through the adhesive layer (c-2). Further, the adhesive layer (c-2) also has a function of joining the laminated heat insulating films according to the second invention.
On the other hand, an adhesion layer (c-1) becomes an adhesion surface to a metal vapor deposition film (B).

As the metal foil, foils made of various metals can be used. Examples of the metal include aluminum, gold, platinum, silver, copper, iron, titanium, tin, lead, nickel, nickel-chromium alloy, and stainless steel.
When the adhesiveness of the adhesive layer (c) is expressed by electromagnetic induction heating, a foil made of a metal exhibiting magnetism is preferable from the viewpoint of electromagnetic wave sensitivity, specifically, austenitic / ferritic stainless steel, A foil made of ferritic stainless steel or martensitic stainless steel can be used.
Moreover, even if it is a nonmagnetic material, the foil which consists of a metal with high electrical conductivity can also be used, and aluminum foil is used suitably as a typical thing. Such metals use heat generated by eddy currents.

  When electromagnetic induction heating is not used, the metal constituting the foil is not particularly limited, but aluminum foil is preferably used because of its low specific gravity. This is because when the flying object is operated to the outer space, it is strongly required to reduce the weight of the component as much as possible.

As the adhesive used for the adhesive layer (c-1), a thermoplastic resin-based adhesive or a thermosetting resin-based adhesive can be used. Specifically, the “resin composition (X)” is used. And an adhesive made of various thermoplastic resins or thermosetting resins exemplified in the section.
Examples of these use forms include organic solvent-soluble or water-soluble adhesives, organic solvent-dispersed or water-dispersed adhesives, and hot-melt adhesives that do not contain a solvent or dispersion medium.
As described above, the adhesive layer (c-1) serves as an adhesive surface to the metal vapor deposition film (B). Therefore, when the adhesion surface of the metal vapor-deposited film (B) is a metal vapor-deposited layer, it is preferable to use an adhesive made of a resin having excellent adhesion to the metal. Examples thereof include an adhesive made of maleated polypropylene having a polar group.

As the adhesive used for the adhesive layer (c-2), the same adhesives as those exemplified in the above “Adhesive used for the adhesive layer (c-1)” can be used.
However, the object to which the adhesive layer (c-2) of the laminated heat insulating film according to the second invention is bonded covers a plurality of types shown below.
(A): The metal vapor deposition surface of the metal vapor deposition film (A) which comprises the other laminated heat insulation film concerning 2nd invention.
(B): Heat-resistant resin film (a) surface of the metal vapor-deposited film (A) constituting another laminated heat insulating film according to the second invention.
(C): Adhesive layer (c-2) surface constituting another laminated heat insulating film according to the second invention.
(D): Article to be coated.

The case where the above (a) to (c) are to be bonded is a step in which a plurality of laminated heat insulating films according to the second invention are joined to produce a heat insulating cover. FIG. 8 shows an example of the bonding mode (a), FIG. 9 shows an example of the bonding mode (b), and FIG. 10 shows an example of the bonding mode (c).
8 to 10 are schematic diagrams when a double-sided vapor deposition type is used as the metal vapor deposition film (B).

In the present invention, a plurality of laminated heat insulation films according to the second invention may be joined in advance to prepare a heat insulation cover, and the article may be covered and fixed to the article, or a plurality of second insulation films may be provided. You may form a heat insulation cover by arrange | positioning around the articles | goods which coat | cover the laminated heat insulation film concerning invention, joining laminated heat insulation films, and fixing to the said goods.
In addition, in joining a plurality of laminated heat insulating films according to the second invention, any one of the above-mentioned (A) to (C) may be used alone, or two or more adhesive modes may be used in combination. Also good.

In the bonding mode (a), the adhesion layer (c-2) is bonded to the metal vapor deposition surface of the metal vapor deposition film (A). It is preferable to use an adhesive made of a resin excellent in adhesiveness to the adhesive, and examples thereof include an adhesive made of maleated polypropylene, which is a resin having a polar group in the molecular structure.
Moreover, in the adhesion mode of (b), the object to which the adhesive layer (c-2) is bonded is the heat resistant resin film (a) surface of the metal vapor deposited film (A), and in particular, the heat resistant resin film (a When a polyimide film is employed as a), it is also referred to as a urethane urea resin (“urea modified urethane resin”, etc.), which has good adhesiveness to this. An adhesive comprising a structure linked by a polyamine having three or more amino groups) is preferably used.
Furthermore, in the adhesion mode of (c), it is preferable that the two adhesive layers (c-2) to be bonded are made of the same adhesive.
In the case where the adhesive layer (c-2) is used for fixing to an article [adhesion mode of (d) above], as an adhesive for forming the adhesive layer (c-2), the surface of the article A material suitable for the material and properties may be appropriately selected and used, but an adhesive made of maleated polypropylene or the like, which is a resin having a polar group in the molecular structure, is preferable for adhesion to the satellite body. Used.

In consideration of workability in the operation of joining the laminated heat insulating film according to the second invention or fixing to the article, one of the preferred embodiments of the adhesive layer (c-2) has adhesiveness at room temperature (25 ° C.). Is not to. When tackiness is developed at room temperature, the workability is lowered due to the adhesive layer (c-2) sticking to an unnecessary portion, and inconvenience such as difficulty in alignment. Is inherently likely to occur.
Therefore, the adhesive layer (c-2) is formed of a heat-sensitive adhesive made of an olefin resin such as an ethylene-propylene copolymer or an ethylene-vinyl alcohol copolymer that does not exhibit tackiness at room temperature. Is one of the preferred embodiments.
The heat-sensitive adhesive refers to an adhesive that is solid and does not have tackiness at room temperature (25 ° C.), but is softened by heating and exhibits tackiness. Affixing is performed in a heat-softened state, solidifying and fixing by cooling to room temperature.

One method of fixing the adhesive layer (c-2) formed by the heat-sensitive adhesive to the article to be coated is to arrange the laminated heat insulating film according to the second invention around the object article, or 4 Cover the target article with the heat-insulating cover according to the invention, and bring the heated heat capacity body into contact with the outside of the part desired to be bonded, that is, the metal vapor-deposited film (A). ) Is softened to adhere to the target article. By cooling to room temperature, the laminated heat insulating film according to the second invention or the heat insulating cover according to the fourth invention is fixed to the target article.
The heat capacity body is preferably metallic. For example, a metal plate or roll can be used, but an electric iron or the like can be used as a specific article.

As another method for fixing the adhesive layer (c-2) formed by the heat-sensitive adhesive to the article to be coated, the laminated heat insulating film according to the second invention is arranged around the object article, or the fourth Cover the target article with the heat insulating cover according to the invention, irradiate the metal vapor deposition film (A) with electromagnetic waves on the outside of the part desired to be bonded, and apply electromagnetic induction heating to the adhesive layer (c-2) at the corresponding part Is bonded to the target article by softening. By cooling to room temperature, the laminated heat insulating film according to the second invention or the heat insulating cover according to the fourth invention is fixed to the target article.
In the case of electromagnetic induction heating, as described above, the metal foil constituting the double-sided adhesive sheet (C) is conductive even if it is a foil made of metal exhibiting magnetism and a non-magnetic material from the viewpoint of electromagnetic wave sensitivity. A foil made of a metal having a high rate is suitable.

The adhesive layer (c) [that is, the adhesive layer (c-1) and the adhesive layer (c-2)] is formed by applying an appropriate adhesive onto the metal foil and drying and curing as necessary. can do.
In coating, a conventionally known coating apparatus such as a roll coater, a comma coater, a lip coater, a die coater, a reverse coater, a silk screen, or a gravure coater can be used.

A: Metal vapor deposition film (A)
B: Metal vapor deposition film (B)
C: Double-sided adhesive sheet (C)
1a: Heat resistant resin film (1a)
2a: metal deposition layer (2a)
1b: Heat resistant resin film (1b)
2b: Metal vapor deposition layer (2b)
3: Print pattern 4: Space 5: Adhesive layer (c-1)
5 ′: Adhesive layer (c-2)
6: Metal foil 11: Laminated thermal insulation film 12 according to the first invention 12: Laminated thermal insulation film 13 according to the second invention 13: Print pattern 14: Part of the laminated thermal insulation film 15 according to the second invention 15: Laminated thermal insulation film according to the first invention Part of

Claims (10)

On the metal vapor deposition layer (2a) of the metal vapor deposition film (A) in which the metal vapor deposition layer (2a) is provided on at least one surface of the heat resistant resin film (1a), at least one of the heat resistant resin film (1b) is provided. The metal vapor deposition film (B) provided with the metal vapor deposition layer (2b) on the surface is laminated,
On the side of the metal vapor deposition film (B) where the metal vapor deposition film (A) is not laminated, another metal vapor deposition film (B) is laminated, and
A laminate characterized in that a printed pattern made of the resin composition (X) is provided between the metal vapor-deposited film (A) and the metal vapor-deposited film (B) and between the metal vapor-deposited films (B). Thermal insulation film. On the metal vapor deposition layer (2a) of the metal vapor deposition film (A) in which the metal vapor deposition layer (2a) is provided on at least one surface of the heat resistant resin film (1a), at least one of the heat resistant resin film (1b) is provided. The metal vapor deposition film (B) provided with the metal vapor deposition layer (2b) on the surface is laminated,
On the side of the metal vapor deposition film (B) where the metal vapor deposition film (A) is not laminated, another metal vapor deposition film (B) is laminated,
Furthermore, it is a laminated heat insulating film formed by laminating a double-sided adhesive sheet (C) in which an adhesive layer (c) is provided on both sides of a metal foil on a metal vapor-deposited film (B) that is farthest from the metal-deposited film (A). There,
A laminate characterized in that a printed pattern made of the resin composition (X) is provided between the metal vapor-deposited film (A) and the metal vapor-deposited film (B) and between the metal vapor-deposited films (B). Thermal insulation film.   A heat insulating cover formed by sewing the laminated heat insulating film according to claim 1.   A heat insulating cover formed by joining a plurality of laminated heat insulating films according to claim 2 via an adhesive layer (c).   A covering in which an article is covered with the heat insulating cover according to claim 3 or 4.   The covering according to claim 5, wherein the article is a spacecraft, an aircraft, or a component thereof.   A method for producing a heat-insulated article, wherein the laminated heat-insulating film according to claim 2 is arranged around the article, the laminated heat-insulating films are bonded to each other by an adhesive layer (c), and fixed to the article.   A method for producing an insulated article, characterized in that the article is covered with the heat insulating cover according to claim 4 and fixed to the article with an adhesive layer (c).   The method for producing a heat-insulated article according to claim 7 or 8, wherein the heated heat capacity body is brought into contact with the metal vapor-deposited film (A) and fixed to the article.   The method for producing a heat-insulated article according to claim 7 or 8, wherein electromagnetic waves are applied from the side of the metal vapor-deposited film (A) to be subjected to electromagnetic induction heating and fixed to the article.