JP5440059B2 - Plastic film insertion laminated glass manufacturing method and plastic film insertion laminated glass - Google Patents

Description

  The present invention relates to a laminated glass produced by laminating a glass plate, a resin intermediate film, a transparent plastic film, a resin intermediate film, and a glass plate in this order, and particularly relates to a laminated glass used for an automobile window.

  A laminate of two glass plates using two resin interlayers sandwiching a plastic film, particularly a polyethylene terephthalate film, is known as a laminated glass having a heat ray reflecting function.

  Usually, the laminated glass is subjected to high-temperature and high-pressure treatment using an autoclave, and the glass plate and the polyester film are heat-sealed by a resin intermediate film.

  For example, in Patent Document 1, a flexible laminated body in which a heat ray reflective plastic film having a thin film formed on a polyester film is sandwiched between two resin intermediate films is sandwiched and laminated between two glass plates. Laminated glass is disclosed.

  In Patent Document 2, a polyethylene terephthalate film (PET film) or a polyethylene naphthalate film (PEN film) on which an infrared reflecting film is formed is heated at 199 to 204 ° C. or 227 to 243 ° C. It is disclosed that when a PET film or a PEN film is used, wrinkles are not caused by heat shrinkage.

  Furthermore, in Patent Document 3, a plastic film-inserted laminated glass using a biaxially stretched thermoplastic support film having a thickness of 30 to 70 μm and a thermal shrinkage of 0.3 to 0.6% in the stretching direction A manufacturing method is disclosed.

  Regarding a plastic film on which an infrared anti-reflection film is formed, Patent Document 4 has an infrared reflecting film made of a metal such as Ag formed on plastic, and Patent Document 5 has laminated dielectric materials having different refractive indexes. An infrared reflecting film formed on a plastic film is disclosed in Patent Document 6, and a film obtained by laminating resin films having different refractive indexes on a plastic film is disclosed.

JP-A-56-32352 JP-T-2004-503402 Japanese Patent No. 3669709 JP 2007-291529 A JP 2007-148330 A JP 2006-205729 A

  When making a laminated glass with a plastic film sandwiched between resin interlayers and sandwiching it between two glass plates, in the case of a glass plate bent into a curved shape, wrinkles occur in the plastic film and appearance defects It becomes.

  This invention makes it a subject to provide the manufacturing method which does not produce a wrinkle in a plastic film, when producing a plastic film insertion laminated glass using the glass plate bent by the curved-surface shape.

    The method for producing a plastic film-inserted laminated glass according to the present invention includes two glass plates curved by bending, two resin intermediate films, and a plastic film with an infrared reflecting film. In the method for producing a plastic film-inserted laminated glass in which a plastic film with an infrared reflecting film, a resin intermediate film, and a glass plate are laminated in this order, an opaque colored film is formed on the periphery of at least one glass plate, A laminated interlayer film is produced in steps 1 to 3, and the laminated interlayer film is inserted between two glass plates and subjected to a heating / pressurizing process.

  Step 1: The plastic film with an infrared reflecting film is cut into a predetermined shape plastic film (a plastic film having an area smaller than the area of the glass plate and the edge of the film overlapping the opaque colored film of the glass plate on the entire circumference). Process.

  Step 2: A step of stacking the two resin intermediate films and the predetermined shape plastic film so that the predetermined shape plastic film produced by cutting in Step 1 is sandwiched between the two resin intermediate films.

  Step 3: A step of heat-sealing the resin intermediate film and the resin intermediate film or the resin intermediate film and the predetermined shape plastic film at a position close to the side of the predetermined shape plastic film to form a laminated intermediate film.

  Moreover, the manufacturing method of the plastic film insertion laminated glass of this invention WHEREIN: In the manufacturing method of the said plastic film insertion laminated glass, the heating apparatus which has a heating body is used for the heat fusion of process 3, or a laser beam is used. It is a manufacturing method of the plastic film insertion laminated glass characterized by the above-mentioned.

  The plastic film-inserted laminated glass of the present invention is characterized in that the radius of curvature of two glass plates is in the range of 0.9 to 3 m, and the plastic film produced by the method for producing a plastic film-inserted laminated glass Inserted laminated glass.

  The plastic film insertion laminated glass of the present invention is the plastic film insertion laminated glass, wherein the plastic film used for the plastic film with an infrared reflecting film is polyethylene terephthalate, polyethylene naphthalate, polycarbonate, polymethyl methacrylate, polyether sulfone, A plastic film-inserted laminated glass, which is a plastic film selected from nylon, polyarylate, and cycloolefin polymer.

  Further, in the plastic film-inserted laminated glass of the present invention, in the plastic film-inserted laminated glass, the resin intermediate film is obtained by dispersing fine particles of metal or metal oxide in polyvinyl acetal, ethylene vinyl acetate, or a fusible resin thereof. It is a plastic film-inserted laminated glass characterized by being a thing.

  Further, the plastic film-inserted laminated glass of the present invention is the plastic film-inserted laminated glass, wherein the infrared reflective film of the plastic film with the infrared reflective film comprises an oxide film having a high refractive index and an oxide film having a low refractive index alternately. A plastic film-inserted laminated glass, which is a laminated multilayer film, a multilayer film of polymer thin films having different refractive indexes, or a conductive thin film.

Moreover, the plastic film insertion laminated glass of the present invention is the plastic film insertion laminated glass, wherein the oxide film is TiO ₂ , Nb ₂ O ₅ , Ta ₂ O ₅ , SiO ₂ , Al ₂ O ₃ , ZrO ₂ , MgF. _It is a plastic film-inserted laminated glass characterized by comprising two or more kinds of oxides selected from 2, or a multilayer film of polymer thin films having different refractive indexes comprising 50 layers to 200 of two types of polymer thin films alternately. It is a plastic film insertion laminated glass characterized by being a multilayer film formed by laminating layers, or the conductive thin film is made of Ag, Au, Cu, Al, Pd, Pt, Sn, In, Zn, Ti, Cd Metal film or alloy film made of metal or alloy such as Fe, Co, Cr, Ni, etc., or antimony-doped tin oxide, tin-doped oxide A plastic film-inserted laminated glass, characterized in that consists characterized by comprising a conductive metal oxide film made of indium or the like.

Moreover, the plastic film insertion laminated glass of this invention WHEREIN: The plastic film with an infrared reflecting film in the said plastic film insertion laminated glass satisfy | fills any of the following conditions (A), (B), (C) It is a plastic film insertion laminated glass characterized by the following.
(A) The thickness is in the range of 30 to 200 μm.
(B) The heat shrinkage rate is in the range of 0.1 to 3% in the temperature range of 100 to 150 ° C.
(C) When a tensile force of 10 N is applied per 1 m width of the plastic film with an infrared reflection film in a temperature range of 100 to 150 ° C., the elongation percentage of the plastic film with an infrared reflection film is 0.3% or less.

  Moreover, the plastic film insertion laminated glass of the present invention is a plastic film insertion laminated glass characterized in that the visible light transmittance specified in JIS R3212: 1998 is 70% or more in the plastic film insertion laminated glass.

  Moreover, the plastic film insertion laminated glass of the present invention is a plastic film insertion laminated glass characterized in that in the plastic film insertion laminated glass, the solar reflectance defined in JIS R3106: 1998 is 20% or more.

Further, the plastic film-inserted laminated glass of the present invention, in the plastic film-inserted laminated glass ISO13837: plastic film, wherein the total solar radiation transmittance defined in 2008 (Total Solar Transmittance) T _TS is less than 50% Inserted laminated glass.

  The present invention relates to a plastic-inserted laminated glass produced by using two glass plates curved in the same shape by a laminated film in which a plastic film with an infrared reflecting film is sandwiched between two resin intermediate films. The manufacturing method of the plastic film insertion laminated glass with a favorable external appearance which does not produce is provided.

  In particular, when making laminated glass using curved glass with different radii of curvature, such as glass used in automobile and vehicle windows, and depending on the location and direction, infrared reflection is also possible. This makes it possible to produce a plastic film-inserted laminated glass that does not wrinkle the plastic film with a film.

  Since the produced plastic film-inserted laminated glass has an infrared reflecting film, it reflects the heat rays of sunlight and is excellent in heat insulation.

The schematic plan view of the plastic film insertion laminated glass of this invention. FIG. 2 is a cross-sectional view along the line aa ′ in FIG. 1. The edge part schematic sectional drawing of the plastic film insertion laminated glass of FIG. The top view which shows the place where the plastic film 22 with an infrared reflecting film is cut | judged by the predetermined-shaped plastic film 25. FIG. The top view and sectional drawing of the intermediate film laminated body obtained by pinching | interposing the plastic film cut | judged in the predetermined shape with the resin intermediate film and the resin intermediate film. The top view and sectional drawing of the lamination | stacking intermediate film obtained by heat-sealing resin intermediate film 23 and resin intermediate film 23 '. The top view and sectional drawing of the lamination | stacking intermediate film obtained by heat-seal | fusing the resin intermediate film 23 and the predetermined-shaped plastic film 25. FIG. FIG. 3 is a schematic cross-sectional view showing a heat fusion apparatus in which resin intermediate films 23 and 23 ′ sandwiching a predetermined shape plastic film 25 are sandwiched between a heating body 31 and a pressing portion 32 of a heater 30 and partially heat-sealed. FIG. 3 is a schematic cross-sectional view showing a heat fusion apparatus in which resin intermediate films 23 and 23 ′ sandwiching a predetermined-shaped plastic film 25 are sandwiched between two heaters and partially heat-sealed. The schematic sectional drawing which shows the heat sealing | fusion apparatus which heat-seal | fuses the resin intermediate films 23 and 23 'which pinched | interposed the plastic film 25 of the predetermined shape with a laser beam. The schematic sectional drawing which shows the deaeration method using a roll. The schematic plan view which shows the deaeration method using a tube. FIG. 11 is a schematic cross-sectional view showing a deaeration method using a tube (cross section taken along line gg ′ in FIG. 10). The schematic plan view which shows the deaeration method using a vacuum bag. The schematic sectional drawing which shows the deaeration method using a vacuum bag (cross section of hh 'of FIG. 12).

  The manufacturing method of the plastic film insertion laminated glass of this invention manufactures the curved plastic film insertion laminated glass 1 as shown in FIG. 1, FIG.

  As shown in FIG. 2, a laminated film 28 having a configuration in which a plastic film 14 having a predetermined shape formed by cutting a plastic film with an infrared reflecting film is sandwiched between resin interlayers 11 and 12 as shown in FIG. It is a laminated glass formed by bonding two glass plates 10 and 13 that are used and bent.

  As the shapes of the two glass plates 10 and 13 that have been bent, there are glass plates having different radii of curvature depending on places such as a spherical surface, an elliptical spherical surface, or a front glass of an automobile.

  The curvature radius of the curved glass plate is desirably 0.9 m to 3 m.

  If the curvature radius is smaller than 0.9 m, wrinkles of the plastic film 14 having a predetermined shape are likely to occur in the mating process. Therefore, the curvature radius is desirably 0.9 m or more.

  The reason why the radius of curvature is 3 m or less is that when the radius of curvature increases, the glass plate has a shape close to a flat surface, and there is almost no effect of the present invention that wrinkles of the predetermined shape plastic film 14 do not occur. This is because the effect of the present invention appears when the radius is 3 m or less.

  When the glass plate 10 is disposed on the outdoor side, it is desirable to use the glass plate 10 positioned on the outdoor side, as shown in FIG. 2, in which an opaque colored film 15 is formed in the peripheral portion.

  The use of the outdoor glass plate 10 on which the opaque colored film 15 is formed is that when sunlight hits the edge 4 of the predetermined shape plastic film 14, the light is scattered at the edge 4 and the edge 4 is only noticeable. This is because there is a risk of disturbing driving.

  The colored film 15 is desirably provided on the mating surface of the glass plate 10 located on the outdoor side.

  The shape of the predetermined shape plastic film 14 is such that the edge 4 of the predetermined shape plastic film overlaps the opaque colored film 15 of the glass plate 10 on the entire circumference and is cut to an area smaller than the area of the glass plate 10 or 13. It is preferable to use those prepared.

  It is colored that the edge 4 of the predetermined shape plastic film 14 overlaps the opaque colored film 15 of the glass plate 10 on the entire circumference, and the shape of the predetermined shape plastic film 14 is similar to the see-through portion 5 of the glass plate 10. This is desirable because CAD data for forming the film 15 can be used.

  FIG. 3 shows a schematic cross section of the end of the plastic-inserted laminated glass. The dimension d1 (dimension from the glass edge 2 to the plastic film edge 4) is larger than the dimension d2 (dimension from the glass edge 2 to the colored film edge 3). ) Is small and d3 = d2−d1 is preferably 5 mm or more in order to prevent sunlight from being scattered at the edges of the plastic film.

  For the resin intermediate films 11 and 12, a hot melt type adhesive such as polyvinyl butyral (PVB) or ethylene vinyl acetate (EVA) is preferably used.

  When the resin intermediate film 12 is on the indoor side, the resin intermediate film 12 used on the indoor side has fine metal particles such as Ag, Al, Ti, metal nitride, metal oxide fine particles, ITO, ATO, AZO, When conductive transparent oxide fine particles such as GZO and IZO are mixed, metal fine particles such as Ag, Al and Ti, metal nitride and metal oxide fine particles, and conductive materials such as ITO, ATO, AZO, GZO and IZO The transparent transparent oxide fine particles are preferable because they absorb infrared rays and can improve the heat insulating property of the plastic-inserted laminated glass.

  As the plastic film with an infrared reflecting film, those prepared by a stretching method are suitable, and are made of polyethylene terephthalate, polyethylene naphthalate, polycarbonate, polymethyl methacrylate, polyether sulfone, nylon, polyarylate, cycloolefin polymer, or the like. A plastic film selected from plastic films having an infrared reflective film (not shown) formed thereon is used.

  In particular, the crystalline polyethylene terephthalate film (PET film) formed by the biaxial stretching method has excellent heat resistance and can be used in a wide range of temperature environments, and is highly transparent and produced in large quantities. Therefore, the quality is stable and suitable.

  In addition, depending on the plastic film inserted between the intermediate films, adhesion with the intermediate film may be poor, or when an infrared reflective film is formed, white turbidity may occur, and by forming a hard coat film at the interface, These problems can be solved.

  When a conductive thin film is used for the infrared reflecting film, the conductive thin film is a metal or alloy such as Ag, Au, Cu, Al, Pd, Pt, Sn, In, Zn, Ti, Cd, Fe, Co, Cr, or Ni. For example, a metal film or an alloy film made of, or a conductive metal oxide film made of antimony-doped tin oxide, tin-doped indium oxide, or the like is preferably used.

  In addition, it is preferable to use a dielectric multilayer film having a different refractive index or a resin multilayer film having a different refractive index as an infrared reflecting film laminated on the plastic film because it transmits electromagnetic waves used in broadcasting and communication.

  A dielectric multilayer film having a different refractive index or a resin multilayer film having a different refractive index is formed by alternately laminating a laminated film having a refractive index n1 and a laminated film having a refractive index n2 (n2 ≠ n1). It is a multilayer film.

When a multilayer film formed by alternately stacking a high refractive index oxide film and a low refractive index oxide film is used as the infrared reflective film, TiO ₂ , Nb ₂ O ₅ , Ta ₂ O ₅ , SiO ₂ , A film made of at least one dielectric selected from Al ₂ O ₃ , ZrO ₂ , and MgF ₂ is preferably used.

In particular, when SiO ₂ is used for a film having a low refractive index and one or more kinds of dielectrics selected from TiO ₂ , Nb ₂ O ₅ , and Ta ₂ O ₅ are used for a film having a high refractive index, 4 to 11 A multilayer film of layers is preferable because a suitable infrared reflection film that reflects near infrared rays can be formed.

  Furthermore, in order to effectively perform the heat insulation performance, the infrared reflective film made of a dielectric film has a dielectric film of 4 layers or more and 11 layers or less so as to satisfy the following conditions (1) and (2). It is desirable to have a maximum value of reflection exceeding 50% in a wavelength range of 900 nm to 1400 nm.

(1) Count the dielectric films in order from the plastic film side, the maximum value of the refractive index of the even-numbered layer is n _emax , the minimum value is n _emin , the maximum value of the refractive index of the odd-numbered layer is no _max , and the minimum value is when the _n omin, n _emax <n omin or n _omax <n _emin.

(2) When the refractive index of the i-th layer is n _i and the thickness is d _i , 225 nm ≦ n _i · d _i ≦ 350 nm with respect to infrared rays having a wavelength λ of 900 to 1400 nm.

  When a multilayer film consisting of two different polymer thin films with different refractive indexes is used as an infrared reflective film, polyethylene terephthalate, polyethylene naphthalate, polycarbonate, polymethyl methacrylate, polyether sulfone, nylon, polyarylate, cycloolefin A polymer or the like is preferably used, and the total number of multilayer films in which two types of polymer layers are alternately stacked is preferably 50 to 200 layers.

  The conductive thin film and the dielectric film are preferably formed by a PVD method, a sputtering method, or the like, and the polymer thin film is preferably formed by a roll coating method, a flow coating method, a dipping method, or the like.

Furthermore, when producing a plastic insertion laminated glass using a curved glass plate, the plastic film with an infrared reflecting film satisfies any of the following conditions (A), (B), and (C): Preferably it is.
(A) The thickness is in the range of 30 to 200 μm.
(B) The heat shrinkage rate is in the range of 0.1 to 3% in the temperature range of 100 to 150 ° C.
(C) When a tensile force of 10 N is applied per 1 m width of the plastic film with an infrared reflection film in a temperature range of 100 to 150 ° C., the elongation percentage of the plastic film with an infrared reflection film is 0.3% or less.

  When producing a plastic film-inserted laminated glass using a curved glass plate, the thickness of the plastic film with an infrared reflecting film is set to a range of 30 to 200 μm. This is because wrinkles are likely to occur, and if it exceeds 200 μm, the shape of the plastic film with an infrared reflecting film does not follow the curved surface of the glass plate, and wrinkles are generated.

  Furthermore, the plastic film with an infrared reflective film is at a temperature of 100 to 150 [deg.] C., and the thermal shrinkage is preferably in the range of 0.1 to 3% in this temperature range.

  If the thermal shrinkage rate of the plastic film with an infrared reflecting film at 90 to 150 ° C. is smaller than 0.1%, the film with the infrared reflecting film is loosened around the curved glass plate, resulting in wrinkled appearance defects. Occur.

  On the other hand, if the thermal shrinkage rate is greater than 3%, the infrared reflective film cannot withstand the shrinkage of the film, and an appearance defect that cracks and becomes a crack occurs.

  When the thermal shrinkage rate of the plastic film with an infrared reflecting film is specified in JIS relating to a transparent plastic film, it is preferably performed according to the corresponding JIS, for example, according to JIS C2318: 2007. .

  The measurement temperature of the heat shrinkage rate is, for example, 150 ° C. in JIS C2318, but it is desirable to determine the measurement temperature in accordance with the temperature setting conditions for the alignment process. It is preferable to measure the shrinkage rate.

  Moreover, in order to prevent wrinkles from occurring in the plastic film with an infrared reflecting film, when the tensile force of 10 N per 1 m width is applied to the plastic film with an infrared reflecting film in a high temperature range of 90 to 150 ° C., the elongation percentage is increased. Is preferably 0.3% or less.

  The tensile force of 10N applied per 1m width of the plastic film with the infrared reflecting film is that the plastic film with the infrared reflecting film sandwiched between the intermediate films is made high temperature and high pressure by an autoclave, When the glass plate is heat-sealed, this corresponds to a tensile force that is generated in the plastic film with an infrared reflecting film and is intended to stretch the plastic film with the infrared reflecting film.

  The elongation percentage of the plastic film with an infrared reflecting film is measured by the following procedures 1 to 5.

  Procedure 1: A plastic film with an infrared reflecting film is cut into a length of 15 mm and a width of 5 mm to obtain a measurement sample. Attach fixing jigs to both ends of the measurement sample. The measurement sample is exposed between the fixing jigs at both ends, and the exposed length of this measurement material is set to 10 mm.

  Procedure 2: A load with a tensile force of 10 N per 1 m width is applied to the measurement sample. In the case of the measurement sample shown in Procedure 1, a load of 0.05 N is applied.

Procedure 3 Measure the length L ₀ of the measurement sample between the fixing jigs.

  Procedure 4 It heats to the measurement temperature between 90-150 degreeC by 5 degreeC / min, and measures the length L between the fixing jigs of the measurement sample at this measurement temperature.

Procedure 5 Elongation rate (%) is calculated by (L ₀ -L) / L × 100.

  The plastic film insertion laminated glass 1 shown in FIGS. 1 and 2 is manufactured by the following steps 1 to 5.

  In addition, by steps 1 to 3, a laminated intermediate film 28 having a configuration in which the plastic film 14 having a predetermined shape is sandwiched between the two resin intermediate films 11 and 12 is produced.

  Step 1: A plastic film with an infrared reflecting film is formed into a plastic film having a predetermined shape (a plastic film having an area smaller than the area of the glass plate and the edge of the plastic film having a predetermined shape overlaps the opaque colored film of the glass plate on the entire circumference) The process of cutting.

  Step 2: A step of overlapping the two resin intermediate films 11 and 12 and the predetermined shape plastic film 14 so that the predetermined shape plastic film 14 is sandwiched between the two resin intermediate films 11 and 12.

  Step 3: At a position close to the side of the predetermined shape plastic film 14, the resin intermediate film 11 and the resin intermediate film 12 or the resin intermediate films 11 and 12 and the predetermined shape plastic film 14 are heat-sealed to form a laminated intermediate. Step of forming film 28.

  Step 4: The laminated intermediate film 28 obtained in Step 3 is placed between two curved glass plates 10 and 13 to form a glass plate laminate, and the space between the two glass plates 10 and 13 is deaerated. Process.

  Process 5: The process of pressurizing and heating the glass plate laminated body after deaeration and bonding.

  Steps 1 to 5 are performed as follows.

  In step 1, as shown in FIG. 4, the plastic film 22 with an infrared reflecting film is cut into a plastic film 25 having a predetermined shape, and the unnecessary portion 26 is removed.

  For cutting the plastic film 22 with the infrared reflecting film, it is preferable to use a linear or circular cutter knife or a laser cutter that cuts by scanning with laser light. In particular, it is preferable to use a cutting device that moves the cutter knife by numerical control.

  The predetermined shape plastic film 25 is preferably similar to the see-through portion 5 of the plastic film-inserted laminated glass 1 shown in FIG.

  In order to cut the plastic film 25 having a predetermined shape into a shape similar to the see-through portion 5, the plastic film 22 with the infrared reflection film is overlapped on the glass plate 10 which is bent and cut to obtain the plastic film 25 having a predetermined shape.

  However, when the glass plate 10 is used for a front window of an automobile, the glass plate 10 often has a complicated surface shape with different curvatures depending on the location, and the plastic film 22 with an infrared reflecting film is cut on the curved surface of the glass plate 10. Therefore, it is easy to cut the plastic film 22 with the infrared reflecting film in accordance with the shape of the see-through portion in the flat plate shape before the glass plate 10 is bent. 25 is obtained.

  Therefore, the cutting of the plastic film 22 with the infrared reflecting film is desirably performed in accordance with a flat plate-shaped see-through portion before the glass plate 10 is bent.

  In step 2, as shown in FIG. 5, resin intermediate films 23 and 23 ′ are stacked on both sides of the predetermined shape plastic film 25, and the intermediate film stack 20 is manufactured.

  In step 3, as shown in FIG. 6, a linear heat-sealed portion 29 is formed between the resin intermediate films 23 and 23 'in the vicinity of the center of the side of the predetermined-shaped plastic film 25 of the intermediate film laminate. The laminated intermediate film 28 is produced by heat fusion.

  Alternatively, as illustrated in FIG. 7, the resin intermediate films 23 and 23 ′ are overlapped on both sides of the predetermined shape plastic film 25, so that the heat fusion portion 29 ′ is formed near the center of the side of the predetermined shape plastic film 25. Alternatively, the resin intermediate film 23 may be heat-fused to the predetermined shape plastic film 25 to produce a laminated intermediate film 28 '.

  The heat fusion parts 29 and 29 'are preferably formed in a linear shape, but may be a dotted line or a dotted shape.

  In FIG. 7, the resin intermediate film 23 is heat-fused to the predetermined shape plastic film 25. However, the resin intermediate film 23 'is fixed to the predetermined shape plastic film 25, or both the resin intermediate films 23 and 23' are predetermined shapes. You may heat-fuse to the plastic film 25.

  The linear heat-sealed portions 29 and 29 ′ are preferably formed in the vicinity of the center of the side of the predetermined-shaped plastic film 25 where wrinkles are likely to occur.

  In the production of the laminated intermediate films 28 and 28 ', when the plastic film 25 having a predetermined shape is overlapped with the bent glass plates 10 and 13 in step 4, the generation of wrinkles generated in the vicinity of the sides of the plastic film can be prevented.

  In order to prevent the occurrence of wrinkles sufficiently effectively, it is preferable that the lengths of the linear heat-sealing portions 29 and 29 'be 5 mm or more. Further, in order to prevent a degassing failure between the resin intermediate films 23 and 23 ', it is preferable that the length of the linear heat-sealing portions 29 and 29' is 300 mm or less.

  The heat fusion parts 29 and 29 'are preferably formed near the center of all sides of the plastic film 25 having a predetermined shape. However, the curvature of the bent glass plate is larger than 3 m, and the plastic film is wrinkled. In the case of a side where there is no risk of occurrence, it may not be formed.

  As shown in FIG. 8 a, the heat fusion part 29 can be formed by using an electric heater 30 and pressing a heating body 31 of the electric heater against the resin intermediate film 23.

  As shown in FIG. 8b, the heating body 31 may be pressed from both sides of the resin intermediate film and heated by using two electric heaters 30.

  Further, as shown in FIG. 8C, the heat fusion part 29 may be formed by condensing the laser beam 33 on the surface where the resin intermediate films 23 and 23 ′ are in contact with each other with a convex lens 34 or the like. When heating with a laser beam, the surface of the resin intermediate film is pressed with a transparent plate 35 such as a glass plate so that the light is not scattered on the embossed surface of the resin intermediate film 23, and the laser beam is in the middle of the resin. It is desirable not to scatter on the surface of the film.

  The heat fusion part 29 ′ in which the resin intermediate film 23 ′ and the plastic film 25 having a predetermined shape are heat-sealed can also be formed in the same manner as the heat fusion part 29.

  In step 4, the laminated intermediate film 28 or 28 'produced in steps 1 to 3 is used to overlap the glass plate 10, the laminated intermediate film 28, and the glass plate 13 to form a glass plate laminated body 40. Deaeration with the plate 13 is performed.

  Deaeration is not particularly limited, but a method of pressing and degassing from both sides of the glass plate laminate 40 with a pressing roll 41 as shown in FIG. 9, as shown in FIGS. 10 and 11, A method of attaching a tube 42 made of rubber-based resin around the glass plate laminate 40 and exhausting air from the exhaust nozzle 43 to deaerate the inside of the vacuum bag 44 as shown in FIGS. The glass plate laminated body 40 can be put in and the air can be exhausted from the exhaust nozzle 45. A vacuum pump (not shown) can be preferably used for exhausting air.

  In step 5, the glass plate laminate 40 in the degassed state in step 4 is heated and pressurized by an autoclave device. The temperature range of the heat and pressure treatment is 90 to 150 ° C., and the pressure is preferably 1 MPa or less, and it is preferably performed for about 30 minutes.

  In Step 1 to Step 3, a laminated intermediate film having a continuous resin intermediate film may be produced by using a continuous roll of resin intermediate film. In this case, the laminated intermediate film 20 and the glass plate may be overlapped from the state in which the resin intermediate film is continuous before the step 3 or 4 and cut into a shape as shown in FIG.

  A window required for driving an automobile by setting the visible light transmittance specified in JIS R3212: 1998 to 70% or more with the plastic film-inserted laminated glass of the present invention produced by steps 1 to 5. It is preferable because it can be used.

Further, a plastic film-inserted laminated glass of the present invention, JIS R3106: 1998 to those solar reflectance defined is 20% or more and ISO thirteen thousand eight hundred and thirty-seven: total solar transmittance as defined in 2008 (Total Solar Transmittance) T _TS When the ratio is 50% or less, an indoor thermal environment is preferable, energy consumed for air conditioning is reduced, and a window member preferable for energy saving is provided.

  Hereinafter, with reference to the drawings, the present invention will be described in detail by way of examples and comparative examples. In addition, this invention is not limited to the Example shown below.

Example 1
1 and 2, a plastic film insertion laminated glass 1 in which a glass plate 10, a resin intermediate film 11, a plastic film 14 having a predetermined shape on which an infrared reflecting film is formed, a resin intermediate film 12, and a glass plate 13 are laminated. Produced.

  As the curved glass plates 10 and 13, an outdoor side glass plate and an indoor side glass plate, which are used as glass for a front window of an automobile, were used.

  The glass plates 10 and 13 are made by bending float glass having a size of 1100 mm × 1800 mm and a thickness of 2 mm. The glass plate 10 used on the outdoor side is screen-printed with a ceramic paste on the concave side, fired, and colored. A film was formed. For the glass plate 13 used on the indoor side, a green heat ray absorbing glass having a thickness of 2 mm was used.

  The width of the colored film (d2 in FIG. 3) was 30 mm at the minimum and 200 mm at the maximum.

  The curvature radius of the curved glass plate was between 0.9 m and 1 m, the peripheral portion was 0.9 m, and the central portion was 1 m.

  As the resin intermediate films 11 and 12, PVB films having a thickness of 0.38 mm were used.

  A PET film having a thickness of 100 μm was used as the plastic film with an infrared reflecting film.

  On one side of the PET plastic film, a hard coat film mainly composed of an acrylic resin in which tin-doped indium oxide (ITO) fine particles are dispersed is used as an infrared absorption layer (not shown) to a thickness of 5 μm after curing. In this way, it was applied by a roll coating method, and an infrared reflection film was further formed thereon.

As the infrared reflection film, a dielectric multilayer film is used, and a TiO ₂ film (thickness 105 nm), a SiO ₂ film (thickness 175 nm), a TiO ₂ film (thickness 105 nm), a SiO ₂ film (thickness 175 nm), A TiO ₂ film (thickness 105 nm), a SiO ₂ film (thickness 175 nm), a TiO ₂ film (thickness 105 nm), a SiO ₂ film (thickness 175 nm), and a TiO ₂ film (thickness 105 nm) are formed on the hard coat film. Films were formed sequentially by sputtering.

  A silane coupling agent was applied to the surface of the PET plastic film where the infrared reflective film was not formed.

  When the thermal shrinkage rate of the plastic film with an infrared reflecting film was measured according to JIS C2318: 2007, 0.6% in the MD direction (longitudinal direction of the film), TD direction (width direction orthogonal to the MD direction) 0. 3%.

  Steps 1 to 5 were performed as follows, and the plastic-inserted laminated glass shown in FIGS. 1 and 2 was produced.

<Process 1>
A plastic film 22 with an infrared reflecting film in which a hard coat film, an infrared reflecting film and a coating film of a silane coupling agent are formed on a PET film using a thin blade cutter knife made of stainless steel has a predetermined shape as shown in FIG. Cut into a plastic film 25.

  The shape of the predetermined shape plastic film 25 is similar to that of the see-through portion 5 in FIG. 1, and the size of the overlap width (d3 shown in FIG. 3) of the predetermined shape plastic film 25 and the colored film 15 is 10 mm.

<Process 2>
The intermediate film laminate 20 shown in FIG. 5 was formed by stacking the resin intermediate films 23 and 23 ′ and the predetermined shape plastic film 25 so as to sandwich the predetermined shape plastic film 25.

<Process 3>
In the vicinity of the edge of the predetermined shape plastic film 25 of the intermediate film laminate 20 formed in the step 2, the two resin intermediate films 23 and 23 'are heat-sealed, and as shown in FIG. A heat fusion part 29 was formed in the vicinity of the center of the laminated intermediate film 28.

  The heat fusion was performed using the apparatus shown in FIG. 8a. The area pressed against the resin intermediate film 23 of the heating body 31 is 10 mm × 200 mm, the temperature of the heating body is heated to 45 ° C., and pressed against the resin intermediate film 23 with a force of 1 N per square centimeter for 20 seconds. The heat fusion part 29 shown in FIG. 6 was formed.

  <Step 4> The laminated intermediate film 28 produced in Step 3 is overlaid on the curved outdoor glass 10, and further the curved indoor glass 13 is overlaid thereon, and the resin intermediate film protruding from the edge of the curved glass plate is cut with a cutter. The glass plate laminate 40 was formed by cutting with a knife.

  In the formation of the glass plate laminate 40, the laminated intermediate film 28 was laminated on the curved outdoor glass 10 so that d3 shown in FIG.

  The infrared reflective film formed on the plastic film with the infrared reflective film is disposed so as to be in contact with the resin intermediate film 11 on the outdoor side of FIG. 2, and the hard coat layer that absorbs infrared rays is formed on the resin intermediate film 12 on the indoor side. I made contact.

  The glass plate laminate 40 was degassed by using a tube 42 shown in FIGS. 10 and 11 and connecting the exhaust nozzle 43 to a vacuum pump (not shown). The tube 42 was made of rubber resin.

<Step 5>
The glass plate laminate 40 is placed in an autoclave while being deaerated using the tube 42 shown in FIGS. 10 and 11, and subjected to pressurization (0.2 MPa) and heating (95 ° C.) for 15 minutes, and then glass. The plate laminate 40 was taken out from the autoclave.

  The tube 42 is removed from the glass plate laminate 40, and the glass plate laminate 40, from which the tube 42 has been removed, is again placed in the autoclave, subjected to pressure (1 MPa) and heating (140 ° C.) for 30 minutes, and the plastic insertion shown in FIG. Laminated glass 1 was produced.

  The produced plastic film-inserted laminated glass 1 has a predetermined-shaped plastic film 14 with no wrinkles and no appearance defect, has a visible light transmittance of 73% as defined in JIS R3211-1998, and is a windshield of an automobile. Can be suitably used.

Further, JIS plastic film-inserted laminated glass of this embodiment R3106: solar reflectance as defined in the 1998 21%, also, ISO 13 837: total solar transmittance as defined in 2008 (Total Solar Transmittance) T _TS is 48%.

Example 2
Using a transparent PVB film having a thickness of 0.76 mm in which tin oxide (ATO) particles doped with antimony are dispersed in the resin intermediate film 13, and using a transparent PET film having a thickness of 80 μm as a plastic film with an infrared reflection film, As an infrared reflecting film, an Nb2O5 film (thickness 115 nm), an SiO2 film (thickness 175 nm), an Nb2O5 film (thickness 115 nm), an SiO2 film (thickness 175 nm), and an Nb2O5 film (thickness 115 nm) are sequentially formed by sputtering. A film was formed.

  A hard coat film mainly composed of an acrylic resin in which ATO fine particles are dispersed is applied by a roll coating method so as to have a thickness of 5 μm after curing, and an infrared reflection film is formed on the hard coat film. did.

  Others were made in the same manner as in Example 1 to produce a plastic film-inserted laminated glass.

  In addition, the thermal contraction rate of the plastic film with an infrared reflective film was 130 ° C., the MD direction was 0.7%, and the TD direction was 0.4%.

  The produced plastic film-inserted laminated glass 1 has a predetermined-shaped plastic film 14 with no wrinkles and no appearance defect, has a visible light transmittance of 73% as defined in JIS R3211-1998, and is a windshield of an automobile. Can be suitably used.

Further, JIS plastic film-inserted laminated glass of this embodiment R3106: solar reflectance as defined in the 1998 21%, also, ISO 13 837: total solar transmittance as defined in 2008 (Total Solar Transmittance) T _TS is 48%.

Example 3
Except for using an infrared reflecting film formed by laminating a thin film of zinc oxide and silver on a PET film by a sputtering method on an infrared reflecting film of a plastic film with an infrared reflecting film, all the same as in Example 1 A plastic film-inserted laminated glass 1 was produced.

  The plastic film-inserted laminated glass 1 produced in this example had no wrinkles in the predetermined shape plastic film and no appearance defect.

  Furthermore, the visible light transmittance defined in JIS R3211-1998 also has 70%, and can be suitably used as a windshield for automobiles.

Example 4
The infrared absorbing layer formed on the plastic film with the infrared reflecting film was used as an infrared reflecting film formed by sequentially laminating indium oxide, silver, indium oxide, silver, and indium oxide by a sputtering method.

  A plastic film-inserted laminated glass 1 was produced in the same manner as in Example 1 except for the above.

  The plastic film-inserted laminated glass 1 produced in this example had no wrinkles in the predetermined-shaped plastic film 14 and had no appearance defect.

The solar radiation reflectance defined in JIS R3106: 1998 of the heat insulating laminated glass 1 of this example was 24%, and the visible light transmittance defined in JIS R3212: 1998 was 71%. Moreover, ISO 13837: total solar transmittance as defined in 2008 (Total Solar Transmittance) T _TS was 46%.

  The thermal contraction rate of the plastic film 22 with an infrared reflecting film of this example is 0.7% in both the MD direction and the TD direction at 130 ° C., and the elongation rate is 0% in both the MD direction and the TD direction at 130 ° C. Met.

Example 5
Plastic film-inserted laminated glass in the same manner as in Example 1 except that a multilayer film formed by alternately laminating two types of polymer thin films having different refractive indexes was used for the infrared reflective film of the plastic film with the infrared reflective film. Was made.

  Polymethylmethacrylate was used for the polymer film having a low refractive index, and polyethylene terephthalate was used for the polymer film having a high refractive index. A low refractive index layer formed using PMMA is called a PMMA layer, and a high refractive index layer formed using polyethylene terephthalate is called a PET layer.

  The PMMA layer was formed by applying a solution obtained by dissolving PMMA in 2-methoxyethyl acetate by a roll coating method. The refractive index was 1.49.

  The PET layer was coated while melting PET pellets with an extruder. The refractive index of the PET layer was 1.65.

  The infrared reflective layer 7 is formed by alternately stacking 20 layers of 0.144 μm PMMA layers and 0.159 μm PET layers, and alternately alternating 0.165 μm PMMA layers and 0.183 μm PET layers. Repeatedly layered 10 layers, and further laminated 15 layers of 0.187 μm PMMA layer and 0.207 μm PET layer alternately, and further layered 158 μm PMMA layer and 0.175 μm PET layer. 15 layers were alternately stacked repeatedly, and further, a 0.172 μm PMMA layer and a 0.191 μm PET layer were alternately stacked repeatedly 15 layers each. The polymer thin film has a total of 150 layers.

  The thermal contraction rate of the film 22 with an infrared reflective film of this example was 130 ° C., and 1.1% in both the MD direction and the TD direction.

  The plastic film-inserted laminated glass 1 produced in this example had no wrinkles in the predetermined-shaped plastic film 14 and had no appearance defect.

Moreover, the solar light reflectance prescribed | regulated to JIS R3106: 1998 of the plastic film insertion laminated glass produced in the present Example was 20%, and the visible light transmittance prescribed | regulated to JIS R3212: 1998 was 73%. Moreover, ISO 13837: total solar transmittance as defined in 2008 (Total Solar Transmittance) T _TS was 49%.

Comparative Example 1
A plastic film-inserted laminated glass was produced in the same manner as in Example 1 except that in Step 3 of Example 1, the laminated interlayer film 28 was formed without forming the heat-sealing portion 29.

  In the produced plastic film-inserted laminated glass, wrinkles were observed at the periphery of the plastic film having a predetermined shape, and it was not suitable for practical use due to poor appearance.

DESCRIPTION OF SYMBOLS 1 Plastic film insertion laminated glass 2 Plastic film insertion laminated glass edge 3 Colored film edge 4 Plastic film edge 5 Plastic film insertion laminated glass perspective part 10 Glass plates 11 and 12 Resin intermediate film 13 Glass plate 14 Predetermined shape plastic film 15 Colored film 20 Intermediate film laminate 22 Plastic film 23 with infrared reflection film, 23 'Resin intermediate film 25 Predetermined shape plastic film 26 Unnecessary part 28, 28' Laminated intermediate film 29, 29 'Thermal fusion part 30 Heater 31 Heating body 32 Holding part 33 Laser beam 34 Convex lens 35 Transparent plate 40 Glass plate laminate 41 Pressing roll 42 Tube 43, 45 Exhaust nozzle 44 Vacuum bag

Claims (13)

Two glass plates curved by bending, two resin intermediate films, and a plastic film with an infrared reflective film are a glass plate, a resin intermediate film, a plastic film with an infrared reflective film, a resin intermediate film, glass In the method for producing a plastic film-inserted laminated glass laminated in the order of the plates, an opaque colored film is formed on the periphery of at least one glass plate, and a laminated interlayer film is produced in the following steps 1 to 3, A method for producing a plastic film-inserted laminated glass, wherein a laminated interlayer film is inserted between two glass plates and subjected to heating and pressing.
Step 1: The plastic film with an infrared reflecting film is cut into a predetermined shape plastic film (a plastic film having an area smaller than the area of the glass plate and the edge of the film overlapping the opaque colored film of the glass plate on the entire circumference). Process.
Step 2: A step of stacking the two resin intermediate films and the predetermined shape plastic film so that the predetermined shape plastic film produced by cutting in Step 1 is sandwiched between the two resin intermediate films.
Step 3: A step of heat-sealing the resin intermediate film and the resin intermediate film or the resin intermediate film and the predetermined shape plastic film at a position close to the side of the predetermined shape plastic film to form a laminated intermediate film.   The method for producing a laminated plastic film-inserted glass according to claim 1, wherein a heating device having a heating element or a laser beam is used for the heat fusion in step 3.   The plastic film-inserted laminated glass produced by the production method according to claim 1 or 2, wherein the radius of curvature of the two glass plates is in a range of 0.9 to 3 m.   The plastic film used for the plastic film with an infrared reflecting film is one plastic film selected from polyethylene terephthalate, polyethylene naphthalate, polycarbonate, polymethyl methacrylate, polyether sulfone, nylon, polyarylate, and cycloolefin polymer. The plastic film-inserted laminated glass according to claim 3.   5. The plastic according to claim 3 or 4, wherein the resin interlayer is polyvinyl acetal, ethylene vinyl acetate, or a fusion resin in which fine particles of metal or metal oxide are dispersed. Film-inserted laminated glass.   The infrared reflection film of the plastic film with the infrared reflection film is a multilayer film in which an oxide film having a high refractive index and an oxide film having a low refractive index are alternately laminated, or a multilayer film of polymer thin films having different refractive indexes, or The plastic film-inserted laminated glass according to any one of claims 3 to 5, which is a conductive thin film. 7. The oxide film is made of two or more oxides selected from TiO ₂ , Nb ₂ O ₅ , Ta ₂ O ₅ , SiO ₂ , Al ₂ O ₃ , ZrO ₂ , and MgF _2. The laminated plastic film glass described in 1.   7. The plastic film-inserted laminated glass according to claim 6, wherein the multilayer film of polymer thin films having different refractive indexes is a multilayer film in which 50 to 200 layers of two types of polymer thin films are alternately laminated.   The conductive thin film is a metal film or alloy film made of a metal or alloy such as Ag, Au, Cu, Al, Pd, Pt, Sn, In, Zn, Ti, Cd, Fe, Co, Cr, Ni, or antimony The plastic film-inserted laminated glass according to claim 6, comprising a conductive metal oxide film made of doped tin oxide, tin-doped indium oxide, or the like. The plastic film according to any one of claims 3 to 9, wherein the plastic film with an infrared reflecting film satisfies any of the following conditions (A), (B), and (C): Inserted laminated glass.
(A) The thickness is in the range of 30 to 200 μm.
(B) The heat shrinkage rate is in the range of 0.1 to 3% in the temperature range of 100 to 150 ° C.
(C) When a tensile force of 10 N is applied per 1 m width of the plastic film with an infrared reflection film in a temperature range of 100 to 150 ° C., the elongation percentage of the plastic film with an infrared reflection film is 0.3% or less.   11. The plastic film-inserted laminated glass according to claim 3, wherein the visible light transmittance defined in JIS R3212: 1998 is 70% or more, and is used for a vehicle window.   The plastic film-inserted laminated glass according to any one of claims 3 to 11, wherein the solar reflectance defined in JIS R3106: 1998 is 20% or more. ISO13837: total solar transmittance as defined in 2008 (Total Solar _{Transmittance) T TS} plastic film-inserted laminated glass according to any one of claims 3 to 12, characterized in that 50% or less.

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