JP2016141596A - Laminated glass, and multi-layered glass - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide laminated glass in which deterioration of a light direction conversion sheet due to ultraviolet light is suppressed.SOLUTION: The laminated glass includes: a light direction conversion sheet through which at least a part of the light going to the inside of a room from the outside thereof is transmitted while converting the direction of the light; a first glass sheet which is disposed on the outside of the light direction conversion sheet; a first adhesive layer for sticking the light direction conversion sheet to the first glass sheet; a second glass sheet which is disposed on the inside of the light direction conversion sheet; and a second adhesive layer for sticking the light direction conversion sheet to the second glass sheet. The first glass sheet contains an ultraviolet light absorber.SELECTED DRAWING: Figure 1

Description

  The present invention relates to laminated glass and multilayer glass.

  As the window glass, one including a light redirecting sheet is known (see, for example, Patent Document 1). The light redirecting sheet redirects and transmits at least part of the light traveling from the outside to the room. For example, the light redirecting sheet changes the direction of light from, for example, diagonally downward to diagonally upward. Outdoor light such as sunlight can be taken into the interior of the room, and the sense of brightness in the room can be improved.

JP 2009-280464 A

  Conventionally, the light redirecting sheet may be deteriorated by ultraviolet rays.

  This invention is made | formed in view of the said subject, Comprising: The main objective is to provide the laminated glass which suppressed the deterioration of the light direction change sheet | seat by an ultraviolet-ray.

In order to solve the above problems, according to one aspect of the present invention,
A light redirecting sheet that redirects and transmits at least part of the light traveling from the outside to the interior;
A first glass plate disposed on the outdoor side with respect to the light redirecting sheet;
A first adhesive layer that bonds the light redirecting sheet and the first glass plate;
A second glass plate disposed indoors with reference to the light redirecting sheet;
A second adhesive layer that bonds the light redirecting sheet and the second glass plate;
The first adhesive layer is provided with a laminated glass containing an ultraviolet absorber.

  According to one embodiment of the present invention, a laminated glass in which deterioration of the light redirecting sheet due to ultraviolet rays is suppressed is provided.

It is sectional drawing which shows the outer peripheral part of the multilayer glass containing the laminated glass by 1st Embodiment of this invention. It is sectional drawing which shows the outer peripheral part of the multilayer glass containing the laminated glass by 2nd Embodiment of this invention. It is sectional drawing which shows the outer peripheral part of the multilayer glass containing the laminated glass by 3rd Embodiment of this invention. It is sectional drawing which shows the outer peripheral part of the multilayer glass containing the laminated glass by 4th Embodiment of this invention.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. In the drawings, the same or corresponding components are denoted by the same or corresponding reference numerals, and description thereof is omitted.

[First Embodiment]
FIG. 1 is a cross-sectional view showing an outer peripheral portion of a multilayer glass including a laminated glass according to the first embodiment of the present invention. In FIG. 1, the left side is the outdoor side, and the right side is the indoor side.

  The double-glazed glass is attached to an opening such as a window and allows outdoor light such as sunlight to pass through the room. The window may be, for example, a building window or a vehicle window. The multilayer glass has a laminated glass 10, a counter glass plate 20, a spacer 50, a primary seal 51, a secondary seal 52, a sealed space 53, and a Low-E film 60.

  In addition, although the laminated glass 10 of this embodiment is integrated in a multilayer glass, this invention is not limited to this. For example, the laminated glass 10 may be attached to an opening such as a window alone.

  The laminated glass 10 transmits outdoor light such as sunlight into the room. The laminated glass 10 includes a first glass plate 11, a first adhesive layer 12, a light redirecting sheet 13, a second adhesive layer 14, and a second glass plate 15 in this order from the outdoor side toward the indoor side.

  The first glass plate 11 is disposed on the outdoor side with respect to the light redirecting sheet 13. The first glass plate 11 is untempered glass, chemically tempered glass, heat tempered glass, or the like. Untempered glass is obtained by forming molten glass into a plate shape and slowly cooling it. Examples of the molding method include a float method and a fusion method. Chemically tempered glass is obtained by strengthening the glass surface by generating a compressive stress on the glass surface by an ion exchange method or the like. Thermally tempered glass strengthens the glass surface by rapidly cooling a uniformly heated glass plate from a temperature near the softening point and generating a compressive stress on the glass surface due to the temperature difference between the glass surface and the inside of the glass. .

  The first adhesive layer 12 bonds the light redirecting sheet 13 and the first glass plate 11. The first adhesive layer 12 is made of a thermoplastic resin, a thermosetting resin, an ultraviolet curable resin, or the like. The first adhesive layer 12 is preferably composed of at least one selected from a vinyl polymer, an ethylene-vinyl monomer copolymer, a styrene copolymer, a polyurethane resin, a fluororesin, and an acrylic resin. A typical example of the thermoplastic resin is polyvinyl butyral resin (PVB). As the thermosetting resin, ethylene-vinyl acetate copolymer resin (EVA) is typical. When the 1st contact bonding layer 12 is comprised with a thermoplastic resin or a thermosetting resin, adhesion | attachment is performed by heat processing. Moreover, when the 1st contact bonding layer 12 is comprised with an ultraviolet curable resin, adhesion | attachment is performed by ultraviolet irradiation.

  The light redirecting sheet 13 redirects and transmits at least part of the light traveling from the outside to the room. Since the light direction changing sheet 13 changes the direction of light from, for example, diagonally downward to diagonally upward, outdoor light such as sunlight can be taken into the interior of the room, and the sense of brightness in the room can be improved.

  In addition, although the light direction change sheet | seat 13 of this embodiment changes the direction of the perpendicular direction of light from the downward direction to an upward direction, you may change the direction of the horizontal direction of light depending on the indoor structure.

  The light redirecting sheet 13 redirects and transmits at least part of the light traveling from the outside to the room. The light redirecting sheet 13 may be a general one, and is composed of, for example, a transparent sheet having a plurality of prism structures (uneven structure) formed on the surface thereof, a transparent sheet having concave grooves formed in the sheet, or the like. The light redirecting sheet 13 has a light redirecting surface having an uneven structure, and light is redirected on the light redirecting surface.

  The light redirecting sheet 13 is disposed between the first glass plate 11 and the second glass plate 15 and is disposed inside the laminated glass 10. Therefore, damage to the light redirecting sheet 13 can be prevented, the penetration resistance of the laminated glass 10 is improved, and the crime prevention effect is improved.

  The concave portion of the concavo-convex structure may be filled with a filler. The refractive index of the filler is different from the refractive index of the transparent sheet. As the refractive index difference is larger on both sides of the light redirecting surface, total reflection is more likely to occur on the light redirecting surface. The filler is selected so that total reflection is likely to occur. In other words, the filler is selected so that the refractive index difference becomes larger when the filler is filled in the recess than when the filler is not filled. Further, the light redirecting sheet 13 can be flattened by filling the concave portions of the concave-convex structure of the light redirecting sheet 13 with the filler.

  The second adhesive layer 14 bonds the light redirecting sheet 13 and the second glass plate 15. Similar to the first adhesive layer 12, the second adhesive layer 14 is made of a thermoplastic resin, a thermosetting resin, an ultraviolet curable resin, or the like.

  The second glass plate 15 is disposed on the indoor side with respect to the light redirecting sheet 13. Similar to the first glass plate 11, the second glass plate 15 is untempered glass, chemically tempered glass, heat tempered glass, or the like.

  The second glass plate 15 may be a template glass, frosted glass, or the like, and may have an uneven surface. In this case, the second glass plate 15 may be untempered glass excellent in workability. The template glass is obtained by transferring a template pattern of a roll onto the surface of a glass plate. The frosted glass is obtained by blasting the surface of a glass plate and further chemically treating it.

  The surface on the indoor side of the second glass plate 15 (the surface facing the opposing glass plate 20 in the second glass plate 15 in FIG. 1) is an uneven surface, and the uneven surface may form a light scattering surface. Since the refractive index is different between the left and right sides of the uneven surface, light is scattered when passing through the uneven surface, and glare caused by the uneven structure of the light redirecting sheet 13 can be alleviated.

  The uneven surface as the light scattering surface may be disposed on the outdoor side with respect to the light redirecting sheet 13. Incident light on the light redirecting sheet 13 can be scattered, and glare caused by the uneven structure of the light redirecting sheet 13 can be reduced. In this case, the 1st glass plate 11 may be a template glass, frost glass, etc., the surface of the outdoor side in the 1st glass plate 11 may be an uneven surface, and the said uneven surface may form a light-scattering surface.

  By the way, light from outside reaches the light redirecting sheet 13 after passing through the first adhesive layer 12.

  Therefore, the first adhesive layer 12 includes an ultraviolet absorber. Deterioration of the light redirecting sheet 13 due to ultraviolet rays can be suppressed.

  As an ultraviolet absorber, a general thing can be used, for example, a benzotriazole type, a benzophenone type, a salicylate type, a cyanoacrylate type, a triazine type, an oxanilide type, a nickel complex type, an inorganic type, etc. can be used. As an inorganic type, for example, particles of zinc oxide, titanium oxide, cerium oxide, zirconium oxide, mica, kaolin, sericite and the like can be used.

  The ultraviolet transmittance in the first adhesive layer 12 is, for example, 0.7% or less, preferably 0.2% or more. The ultraviolet transmittance is measured based on ISO 9050.

  Similar to the first adhesive layer 12, the second adhesive layer 14 may include an ultraviolet absorber. The material of the second adhesive layer 14 and the material of the first adhesive layer 12 can be made common, and the management cost and the manufacturing cost can be reduced.

  In addition, although the laminated glass 10 of this embodiment has two glass plates, you may have three or more sheets. For example, the laminated glass may have a third glass plate bonded to the first glass plate 11 on the outdoor side of the first glass plate 11. Moreover, the laminated glass 10 may have a 4th glass plate adhere | attached with a 2nd glass plate in the indoor side rather than the 2nd glass plate 15. FIG.

  The counter glass plate 20 faces the laminated glass 10. The counter glass plate 20 is disposed, for example, on the indoor side (right side in FIG. 1) of the laminated glass 10. The counter glass plate 20 is chemically tempered glass, heat tempered glass, untempered glass, laminated glass, or the like.

  The spacer 50 keeps the distance between the laminated glass 10 and the counter glass plate 20. The spacer 50 is formed in a frame shape and surrounds the sealed space 53. The spacer 50 has a hollow portion 55. The hollow portion 55 and the sealed space 53 communicate with each other, and the hollow portion 55 is filled with a desiccant 56. The sealed space 53 can be dried.

  The primary seal 51 is disposed between the laminated glass 10 and the spacer 50, seals the space therebetween, and bonds the space therebetween. Further, the primary seal 51 is disposed between the spacer 50 and the counter glass plate 20, seals the space therebetween, and bonds the space therebetween.

  The secondary seal 52 is disposed so as to surround the spacer 50, seals between the laminated glass 10 and the counter glass plate 20, and adheres between them.

  The sealed space 53 forms a heat insulating layer. The sealed space 53 is filled with dry air or inert gas. The air pressure in the sealed space 53 may be the same as the atmospheric pressure, or may be smaller than the atmospheric pressure. The sealed space 53 may be evacuated. In this case, a pillar that keeps the interval between the laminated glass 10 and the counter glass plate 20 may be provided inside the sealed space 53.

  The multilayer glass may have a Low-E film 60. The Low-E film 60 is formed on at least one of the facing surface of the laminated glass 10 facing the facing glass plate 20 and the facing surface of the facing glass plate 20 facing the laminated glass 10.

  The Low-E film 60 restricts the passage of heat by suppressing radiant heat transfer. The Low-E film 60 is formed, for example, on the facing surface of a glass plate on the indoor side (the counter glass plate 20 in FIG. 1) among the two glass plates facing each other with the sealed space 53 interposed therebetween. Thus, the type in which the Low-E film 60 is disposed on the indoor side of the sealed space 53 is referred to as a heat insulation type. On the other hand, a type in which the Low-E film 60 is disposed outside the sealed space 53 is referred to as a heat shield type. When the same Low-E membrane is used, the heat transfer rate (Japanese Industrial Standard JIS R 3107) is the same for the heat insulation type and the heat insulation type, but the solar heat acquisition rate (Japanese Industrial Standard JIS R 3106) is different. . The heat-insulating solar heat acquisition rate is larger than the heat-shielding solar heat acquisition rate. The heat insulation type captures sunlight in winter, and the heat insulation type cuts strong sunlight in summer.

  The surface on which the Low-E film 60 is formed may be an uneven surface, but is preferably a flat surface from the viewpoint of film formability. Of the two glass plates facing each other across the sealed space 53, the facing surface of the outdoor glass plate (second glass plate 15 in FIG. 1) is an uneven surface, and the uneven surface forms a light scattering surface. In this case, the facing surface of the indoor glass plate may be a flat surface, and the Low-E film 60 may be formed on the flat surface.

  In this case, since the uneven surface as the light scattering surface is formed inside the multilayer glass, the uneven surface as the light scattering surface is formed on the exposed surface on the outdoor side of the multilayer glass. The effect which prevents adhesion is also acquired.

  The uneven surface as the light scattering surface may be formed on the exposed surface on the indoor side of the multilayer glass, but is preferably formed inside the multilayer glass as shown in FIG. The exposed surfaces on both the outdoor side and the indoor side of the multilayer glass are preferably flat surfaces.

The Low-E film 60 may be a general film, for example, a laminated film including a transparent dielectric film, an infrared reflective film, and a transparent dielectric film in this order. Typical examples of the transparent dielectric film include metal oxides and metal nitrides. Typical metal oxides include zinc oxide and tin oxide. A typical example of the infrared reflecting film is a metal film or a semiconductor film. Silver (Ag) is typical as the metal film, and F-added SiO ₂ is typical as the semiconductor film. Here, one or more infrared reflective films may be formed between the transparent dielectric films.

  The method for forming the Low-E film 60 is not particularly limited. As a method for forming the Low-E film 60, for example, a dry coating method is used. Examples of the dry coating method include a PVD method and a CVD method. Among PVD methods, vacuum deposition method, sputtering method, and ion plating method are preferable, and among these, sputtering method is possible because it can produce a film having excellent adhesion and flatness, and is widely used commercially. Is particularly preferred.

  The thickness of the Low-E film 60 is not particularly limited, and can be selected according to required performance, film configuration, and the like.

  The Low-E film 60 may be accommodated in the sealed space 53 and may not protrude from the sealed space 53. Since the sealed space 53 is isolated from the atmosphere, contact between moisture in the atmosphere and the Low-E film 60 can be prevented, and deterioration of the Low-E film 60 can be limited.

  The light redirecting sheet 13 of the present embodiment is disposed between the first glass plate 11 and the second glass plate 15 and is incorporated into the laminated glass 10. Therefore, the following effects (A) to (B) can be obtained.

  (A) Trimming processing of the light redirecting sheet 13 is unnecessary. This trimming process is performed when the light redirecting sheet 13 is attached to the surface of the second glass plate 15 facing the counter glass plate 20. In this case, the light redirecting sheet 13 is processed to be smaller than the spacer 50 so as not to hinder the adhesion between the second glass plate 15 and the spacer 50. On the other hand, according to the present embodiment, the light redirecting sheet 13 is disposed on the side opposite to the spacer 50 with the second glass plate 15 as a reference, so that a trimming process is unnecessary.

  (B) Cleaning of the laminated glass 10 is easy. This cleaning process is performed to clean the adhesion surface before assembling the multilayer glass. When the light redirecting sheet 13 is attached to the surface of the second glass plate 15 facing the facing glass plate 20, the light redirecting sheet 13 is exposed to the cleaning liquid. On the other hand, according to the present embodiment, the light redirecting sheet 13 is protected from the cleaning liquid by being sandwiched between the first glass plate 11 and the second glass plate 15, and the selection of the cleaning liquid and the cleaning brush is easy. It is.

  In addition, although the multilayer glass of this embodiment does not further have a glass plate on the opposite side (the indoor side in FIG. 1) to the laminated glass 10 on the basis of the opposing glass plate 20, it may further have a glass plate. Good. This glass plate and the counter glass plate 20 may be bonded via an adhesive layer, or may be bonded via a spacer.

[Second Embodiment]
The double-glazed glass of the first embodiment is a heat insulating double-glazed glass, and the laminated glass 10 is disposed on the outdoor side of the sealed space 53 and the counter glass plate 20 is disposed on the indoor side of the sealed space 53. .

  On the other hand, the multilayer glass of the present embodiment is a heat insulating multilayer glass, and the laminated glass 10A is disposed on the indoor side of the sealed space 53A and the opposing glass plate 20A is disposed on the outdoor side of the sealed space 53A. Is done.

  FIG. 2 is a cross-sectional view showing the outer peripheral portion of the multilayer glass including the laminated glass according to the first embodiment of the present invention. In FIG. 2, the left side is the outdoor side, and the right side is the indoor side.

  The multilayer glass has a laminated glass 10A, a counter glass plate 20A, a spacer 50A, a primary seal 51A, a secondary seal 52A, a sealed space 53A, and a Low-E film 60A.

  In addition, although the laminated glass 10A of this embodiment is integrated in a multilayer glass, this invention is not limited to this. For example, the laminated glass 10A may be attached alone to an opening such as a window.

  Laminated glass 10A has first glass plate 11A, first adhesive layer 12A, light redirecting sheet 13A, second adhesive layer 14A, and second glass plate 15A in this order from the outdoor side toward the indoor side.

  The light redirecting sheet 13A is disposed between the first glass plate 11A and the second glass plate 15A, and is disposed inside the laminated glass 10A. Therefore, damage to the light redirecting sheet 13A can be prevented.

  By the way, light from outside reaches the light redirecting sheet 13A after passing through the first adhesive layer 12A.

  Therefore, the first adhesive layer 12A includes an ultraviolet absorber. Therefore, similarly to the first embodiment, the deterioration of the light redirecting sheet 13A due to ultraviolet rays can be suppressed.

  In addition, although the laminated glass 10A of this embodiment has two glass plates, it may have three or more.

  The facing glass plate 20A faces the laminated glass 10A. The facing glass plate 20A is disposed, for example, on the outdoor side (left side in FIG. 2) of the laminated glass 10A.

  The Low-E film 60A is formed on the facing surface of the laminated glass 10A facing the facing glass plate 20A, and is disposed on the indoor side of the sealed space 53A. Thus, a heat insulating double-layer glass is obtained.

  The surface on which the Low-E film 60A is formed may be an uneven surface, but is preferably a flat surface from the viewpoint of film formability. In this case, the facing surface of the facing glass plate 20A facing the laminated glass 10A may be an uneven surface, and the uneven surface forms a light scattering surface.

  In this case, since the uneven surface as the light scattering surface is formed inside the multilayer glass, the uneven surface as the light scattering surface is formed on the exposed surface on the outdoor side of the multilayer glass. The effect which prevents adhesion is also acquired.

  The uneven surface as the light scattering surface may be formed on the exposed surface on the indoor side of the multilayer glass, but is preferably formed inside the multilayer glass as shown in FIG. The exposed surfaces on both the outdoor side and the indoor side of the multilayer glass are preferably flat surfaces.

  The light redirecting sheet 13A of the present embodiment is disposed between the first glass plate 11A and the second glass plate 15A, and is incorporated into the laminated glass 10A. Therefore, the following effects (C) to (D) can be obtained. (C) Trimming processing of the light redirecting sheet 13A is unnecessary. This trimming process is performed when the light redirecting sheet 13A is attached to the surface of the first glass plate 11A facing the facing glass plate 20A. (D) Cleaning of the laminated glass 10A is easy. In addition, a general thing can be used as a washing | cleaning method of the laminated glass 10A with the Low-E film | membrane 60A.

  In addition, although the multilayer glass of this embodiment does not further have a glass plate on the opposite side (outdoor side in FIG. 2) to the laminated glass 10A on the basis of the opposing glass plate 20A, it may further have a glass plate. Good. This glass plate and the counter glass plate 20A may be bonded via an adhesive layer, or may be bonded via a spacer.

[Third Embodiment]
The double-glazed glass of the first embodiment is a heat insulating double-glazed glass, and the laminated glass 10 is disposed on the outdoor side of the sealed space 53 and the counter glass plate 20 is disposed on the indoor side of the sealed space 53. .

  On the other hand, the double-glazed glass of the present embodiment is a heat-shielding double-glazed glass, and the laminated glass 10B is disposed outside the sealed space 53B and the opposing glass plate 20B is disposed inside the sealed space 53B. Established.

  FIG. 3 is a cross-sectional view showing the outer peripheral portion of the multilayer glass including the laminated glass according to the first embodiment of the present invention. In FIG. 3, the left side is the outdoor side, and the right side is the indoor side.

  The multilayer glass has a laminated glass 10B, a counter glass plate 20B, a spacer 50B, a primary seal 51B, a secondary seal 52B, a sealed space 53B, and a Low-E film 60B.

  In addition, although the laminated glass 10B of this embodiment is integrated in a multilayer glass, this invention is not limited to this. For example, the laminated glass 10B may be attached to an opening such as a window alone.

  Laminated glass 10B has first glass plate 11B, first adhesive layer 12B, light redirecting sheet 13B, second adhesive layer 14B, and second glass plate 15B in this order from the outdoor side toward the indoor side.

  The light redirecting sheet 13B is disposed between the first glass plate 11B and the second glass plate 15B, and is disposed inside the laminated glass 10B. Therefore, damage to the light redirecting sheet 13B can be prevented.

  By the way, light from the outside reaches the light redirecting sheet 13B after passing through the first adhesive layer 12B.

  Therefore, the first adhesive layer 12B includes an ultraviolet absorber. Therefore, similarly to the first embodiment, the deterioration of the light redirecting sheet 13B due to ultraviolet rays can be suppressed.

  In addition, although the laminated glass 10B of this embodiment has two glass plates, you may have three or more sheets.

  The counter glass plate 20B is opposed to the laminated glass 10B. The counter glass plate 20B is disposed, for example, on the indoor side (right side in FIG. 3) than the laminated glass 10B.

  The Low-E film 60B is formed on the surface of the laminated glass 10B that faces the counter glass plate 20B, and is disposed outside the sealed space 53B. Therefore, a heat shield type multi-layer glass is obtained.

  The surface on which the Low-E film 60B is formed may be an uneven surface, but is preferably a flat surface from the viewpoint of film formability. In this case, the facing surface of the facing glass plate 20B facing the laminated glass 10B may be an uneven surface, and the uneven surface forms a light scattering surface.

  In this case, since the uneven surface as the light scattering surface is formed inside the multilayer glass, the uneven surface as the light scattering surface is formed on the exposed surface on the outdoor side of the multilayer glass. The effect which prevents adhesion is also acquired.

  The uneven surface as the light scattering surface may be formed on the exposed surface on the indoor side of the multilayer glass, but is preferably formed inside the multilayer glass as shown in FIG. The exposed surfaces on both the outdoor side and the indoor side of the multilayer glass are preferably flat surfaces.

  The light redirecting sheet 13B of the present embodiment is disposed between the first glass plate 11B and the second glass plate 15B, and is incorporated into the laminated glass 10B. Therefore, the following effects (E) to (F) can be obtained. (E) Trimming processing of the light redirecting sheet 13B is unnecessary. This trimming process is performed when the light redirecting sheet 13B is attached to the surface of the second glass plate 15B facing the counter glass plate 20B. (F) Cleaning of the laminated glass 10B is easy. In addition, a general thing can be used as a washing | cleaning method of the laminated glass 10B with the Low-E film | membrane 60B.

  In addition, although the multilayer glass of this embodiment does not have a glass plate further on the opposite side (inner side in FIG. 3) from the laminated glass 10B on the basis of the opposing glass plate 20B, it may have a glass plate further. Good. This glass plate and the counter glass plate 20B may be bonded via an adhesive layer or may be bonded via a spacer.

[Fourth Embodiment]
The double-glazed glass of the first embodiment is a heat insulating double-glazed glass, and the laminated glass 10 is disposed on the outdoor side of the sealed space 53 and the counter glass plate 20 is disposed on the indoor side of the sealed space 53. .

  On the other hand, the double-glazed glass of the present embodiment is a heat-shielding double-glazed glass, and the laminated glass 10C is disposed on the indoor side of the sealed space 53C and the opposing glass plate 20C is disposed on the outdoor side of the sealed space 53C. Established.

  FIG. 4 is a cross-sectional view showing the outer peripheral portion of the multilayer glass including the laminated glass according to the first embodiment of the present invention. In FIG. 4, the left side is the outdoor side, and the right side is the indoor side.

  The multilayer glass has a laminated glass 10C, a counter glass plate 20C, a spacer 50C, a primary seal 51C, a secondary seal 52C, a sealed space 53C, and a Low-E film 60C.

  In addition, although the laminated glass 10C of this embodiment is integrated in a multilayer glass, this invention is not limited to this. For example, the laminated glass 10C may be attached alone to an opening such as a window.

  Laminated glass 10C includes first glass plate 11C, first adhesive layer 12C, light redirecting sheet 13C, second adhesive layer 14C, and second glass plate 15C in this order from the outdoor side toward the indoor side.

  The light redirecting sheet 13C is disposed between the first glass plate 11C and the second glass plate 15C, and is disposed inside the laminated glass 10C. Therefore, damage to the light redirecting sheet 13C can be prevented.

  Incidentally, the light from the outside reaches the light redirecting sheet 13C after passing through the first adhesive layer 12C.

  Therefore, the first adhesive layer 12C contains an ultraviolet absorber. Therefore, similarly to the first embodiment, the deterioration of the light redirecting sheet 13C due to ultraviolet rays can be suppressed.

  In addition, although the laminated glass 10C of this embodiment has two glass plates, it may have three or more.

  The counter glass plate 20C faces the laminated glass 10C. The counter glass plate 20C is disposed, for example, on the outdoor side (left side in FIG. 4) of the laminated glass 10C.

  The Low-E film 60C is formed on the surface of the counter glass plate 20C facing the laminated glass 10C, and is disposed outside the sealed space 53C. Therefore, a heat shield type multi-layer glass is obtained.

  The surface on which the Low-E film 60C is formed may be an uneven surface, but is preferably a flat surface from the viewpoint of film formability. In this case, the facing surface of the laminated glass 10C facing the counter glass plate 20C may be an uneven surface, and the uneven surface forms a light scattering surface.

  In this case, since the uneven surface as the light scattering surface is formed inside the multilayer glass, the uneven surface as the light scattering surface is formed on the exposed surface on the outdoor side of the multilayer glass. The effect which prevents adhesion is also acquired.

  The uneven surface as the light scattering surface may be formed on the exposed surface on the indoor side of the multilayer glass, but is preferably formed inside the multilayer glass as shown in FIG. The exposed surfaces on both the outdoor side and the indoor side of the multilayer glass are preferably flat surfaces.

  The light redirecting sheet 13C of the present embodiment is disposed between the first glass plate 11C and the second glass plate 15C, and is incorporated into the laminated glass 10C. Therefore, the following effects (G) to (H) can be obtained. (G) Trimming processing of the light redirecting sheet 13C is unnecessary. This trimming process is performed when the light redirecting sheet 13C is affixed to the surface of the first glass plate 11C facing the counter glass plate 20C. (H) Cleaning of the laminated glass 10C is easy.

  In addition, although the multilayer glass of this embodiment does not further have a glass plate on the opposite side (inner side in FIG. 4) to the laminated glass 10C on the basis of the opposing glass plate 20C, it may further have a glass plate. Good. This glass plate and the counter glass plate 20C may be bonded via an adhesive layer, or may be bonded via a spacer.

  As mentioned above, although the embodiment etc. of the laminated glass and the multilayer glass were explained, the present invention is not limited to the above-mentioned embodiment etc. Improvements are possible.

10 laminated glass 11 first glass plate 12 first adhesive layer 13 light redirecting sheet 14 second adhesive layer 15 second glass plate 20 opposing glass plate 50 spacer 51 primary seal 52 secondary seal 53 sealed space 60 Low-E film

Claims (10)

A light redirecting sheet that redirects and transmits at least part of the light traveling from the outside to the interior;
A first glass plate disposed on the outdoor side with respect to the light redirecting sheet;
A first adhesive layer that bonds the light redirecting sheet and the first glass plate;
A second glass plate disposed indoors with reference to the light redirecting sheet;
A second adhesive layer that bonds the light redirecting sheet and the second glass plate;
The first adhesive layer is a laminated glass containing an ultraviolet absorber.   The laminated glass according to claim 1, wherein the light redirecting sheet has a concavo-convex structure, and the concave portion of the concavo-convex structure is filled with a filler. Laminated glass according to claim 1 or 2,
An opposing glass plate facing the laminated glass;
A multilayer glass comprising a spacer that forms a sealed space between the laminated glass and the counter glass plate.   The multilayer glass according to claim 3, wherein a Low-E film is formed on at least one of a facing surface of the laminated glass facing the facing glass plate and a facing surface of the facing glass plate facing the laminated glass.   The multilayer glass according to claim 4, wherein a surface on which the Low-E film is formed is a flat surface.   The at least one of the opposing surface with the said opposing glass plate in the said laminated glass and the opposing surface with the said laminated glass in the said opposing glass plate is an uneven surface, The said uneven surface forms a light-scattering surface. The multilayer glass of any one of -5. One of the facing surface of the laminated glass facing the facing glass plate and the facing surface of the facing glass plate facing the laminated glass is a flat surface, and a Low-E film is formed on the flat surface,
The other of the facing surface of the laminated glass facing the facing glass plate and the facing surface of the facing glass plate facing the laminated glass is an uneven surface, and the uneven surface forms a light scattering surface. 6. The multilayer glass according to any one of 6 above.   The multilayer glass according to any one of claims 3 to 7, wherein exposed surfaces on both the outdoor side and the indoor side of the multilayer glass are flat surfaces.   The said opposing glass plate is a multilayer glass of any one of Claims 3-8 arrange | positioned on the outdoor side on the basis of the said laminated glass.   The said opposing glass plate is a multilayer glass of any one of Claims 3-8 arrange | positioned indoors on the basis of the said laminated glass.

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