JP6344066B2 - Daylighting system - Google Patents

Description

  The present invention relates to a daylighting system for capturing light such as sunlight.

For example, as disclosed in Patent Document 1, development of an optical film for taking outside light indoors is in progress. This optical film takes in external light so that the optical path of incident light is directed toward the indoor ceiling. By taking outside light indoors, it is possible to reduce the power consumption of the lighting device, and as a result, it can contribute to the reduction of CO ₂ . Moreover, since the optical path of the outside light taken in indoors is bounced up, an indoor person does not feel dazzling.

Special table 2013-514552

  By the way, the position of the sun changes according to a time zone and a season. That is, the incident direction of external light when entering the optical film changes. Therefore, the optical film of Patent Document 1 cannot sufficiently perform daylighting throughout the year and even throughout the day of a certain day. On the other hand, the direct light transmitted through the optical film without correcting the optical path makes the indoor person feel dazzling.

  The present invention has been made in consideration of such points, and an object thereof is to provide a daylighting system capable of exhibiting a sufficient daylighting function and antiglare function for incident light from various directions. And

A first daylighting system according to the present invention comprises:
A first daylighting film;
A second daylighting film disposed away from the first daylighting film in a first reference direction parallel to the normal direction of the first daylighting film, and
The first daylighting film has a plurality of first reflecting surfaces arranged in a second reference direction that is non-parallel to the first reference direction,
The second daylighting film has a plurality of second reflecting surfaces arranged in the second reference direction,
In a plane parallel to both the first reference direction and the second reference direction, from the first daylighting film side toward the second daylighting film side toward the lower side in the vertical direction with respect to the horizontal direction. The angle formed by the first reflecting surface with respect to the horizontal direction is greater than the angle formed by the second reflecting surface with respect to the horizontal direction, where the angle when tilting is a positive value.

In the first or second daylighting system according to the present invention,
The angle formed by the first reflecting surface with respect to the horizontal direction in a plane parallel to both the first reference direction and the second reference direction is a positive value.
An angle formed by the second reflecting surface with respect to the horizontal direction in a plane parallel to both the first reference direction and the second reference direction may be a negative value.

A second daylighting system according to the present invention comprises:
A first daylighting film;
A second daylighting film disposed horizontally apart from the first daylighting film,
The first daylighting film has a plurality of first reflecting surfaces arranged in a vertical direction,
The second daylighting film has a plurality of second reflecting surfaces arranged in the vertical direction,
In a plane parallel to the vertical direction, the angle when tilting from the first daylighting film side toward the second daylighting film side toward the lower side in the vertical direction with respect to the horizontal direction is set as a positive value. The angle formed by the first reflecting surface with respect to the horizontal direction is larger than the angle formed by the second reflecting surface with respect to the horizontal direction.

In a second daylighting system according to the invention,
The angle formed by the first reflecting surface with respect to the horizontal direction in a plane parallel to the vertical direction is a positive value.
An angle formed by the second reflecting surface with respect to the horizontal direction in a plane parallel to the vertical direction may be a negative value.

  In the first or second daylighting system according to the present invention, the first daylighting film in the horizontal direction and at least partially above the first daylighting film and the second daylighting film and in the horizontal direction An awning may be provided in at least a portion of the position between the second daylighting films.

  The first or second daylighting system according to the present invention is an awning that is positioned vertically above the second daylighting film and extends from the second daylighting film side toward the first daylighting film side. You may make it provide further.

  In the first or second daylighting system according to the present invention, the upper end in the vertical direction of the first daylighting film may be located below the upper end in the vertical direction of the second daylighting film.

  In the first or second daylighting system according to the present invention, the lower end in the vertical direction of the second daylighting film may be located below the upper end in the vertical direction of the first daylighting film.

  In the first or second daylighting system according to the present invention, the lower end in the vertical direction of the second daylighting film is located at the same position in the vertical direction as the lower end in the vertical direction of the first daylighting film, or You may be located in the downward direction in the perpendicular direction rather than the lower end in the perpendicular direction of the said 1st daylighting film.

  In the first or second daylighting system according to the present invention, the second daylighting film forms a partition member that partitions an area, and the first daylighting film forms a wall member provided outside the room. Also good.

A third daylighting system according to the present invention comprises:
A first daylighting film;
A second daylighting film disposed away from the first daylighting film in a first reference direction parallel to the normal direction of the first daylighting film, and
The first daylighting film has a plurality of first reflecting surfaces arranged in a second reference direction that is non-parallel to the first reference direction,
The second daylighting film has a plurality of second reflecting surfaces arranged in the second reference direction,
In a plane parallel to both the first reference direction and the second reference direction, the first reflecting surface and the second reflecting surface are inclined in opposite directions.

  ADVANTAGE OF THE INVENTION According to this invention, sufficient lighting function and glare-proof function can be exhibited with respect to the incident light from various directions.

FIG. 1 is a diagram for explaining an embodiment of the present invention and schematically showing a daylighting system. FIG. 2 is a longitudinal sectional view showing an example of a wall member of a veranda. FIG. 3 is a longitudinal sectional view showing an example of the partition member. FIG. 4 is a perspective view showing an example of a daylighting film. FIG. 5 is a longitudinal sectional view showing the first daylighting film and the second daylighting film in a cross section along the vertical direction. FIG. 6 is a longitudinal sectional view showing a modification of the daylighting film. FIG. 7 is a longitudinal sectional view showing another modification of the daylighting film. FIG. 8 is a longitudinal sectional view showing still another modified example of the daylighting film. FIG. 9 is a longitudinal sectional view showing still another modified example of the daylighting film. FIG. 10 is a longitudinal sectional view schematically showing the daylighting system, and is a diagram for explaining the operation of the daylighting system. FIG. 11 is a view corresponding to FIG. 10 and a longitudinal sectional view showing a modification of the daylighting system. 12 is a view corresponding to FIG. 4 and a longitudinal sectional view showing a second daylighting film of the daylighting system of FIG. FIG. 13 is a diagram corresponding to FIG. 11 and is a diagram for explaining a method of using the daylighting system of FIG. 11. FIG. 14 is a diagram for explaining another application example of the daylighting system. FIG. 15 is a diagram for explaining still another application example of the daylighting system.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the drawings attached to the present specification, for the sake of illustration and ease of understanding, the scale, the vertical / horizontal dimension ratio, and the like are appropriately changed and exaggerated from those of the actual product.

  Further, as used in the present specification, the shape and geometric conditions and the degree thereof are specified, for example, terms such as “parallel”, “orthogonal”, “identical”, etc. are not limited to strict meanings, Interpretation should include the extent to which similar functions can be expected.

  Further, in the present specification, the terms “sheet”, “film”, and “plate” are not distinguished from each other only based on the difference in designation. For example, the “sheet” is a concept including a member that can be called a film or a plate. Therefore, a daylighting film cannot be distinguished only based on the difference in name with a member that can be called a daylighting sheet or daylighting plate.

  Further, the “film surface (sheet surface, plate surface)” means the target film shape (sheet-like member) when the target film-like (sheet-like, plate-like) member is viewed as a whole and globally. , Plate-like member). Moreover, the normal line direction with respect to a film-like (sheet-like, plate-like) member is a normal direction to the film surface (sheet surface, plate-like) of the film-like (sheet-like, plate-like) member. Point to.

  FIGS. 1-13 is a figure for demonstrating one Embodiment and its modification by this invention. Among these, FIG. 1 is a side sectional view showing a daylighting system. The daylighting system 10 includes a first daylighting film 11, a second daylighting film 12 disposed away from the first daylighting film 11 in a first reference direction d1 parallel to the normal direction nd of the first daylighting film 11, and ,have. The first daylighting film 11 has a plurality of first reflecting surfaces 11a arranged in a second reference direction d2 that is non-parallel to the first reference direction d1. The second daylighting film 12 has a plurality of second reflecting surfaces 11b arranged in the second reference direction d2. In the plane parallel to both the first reference direction d1 and the second reference direction d2, the first reflecting surface 11a and the second reflecting surface 12a are not parallel but are inclined with respect to each other.

  This daylighting system 10 is a device that changes and captures the optical path of external light. In one embodiment described below, the daylighting system 10 deflects an optical path of outside light and takes the light from the outdoors to the inside. In particular, the following daylighting system 10 is devised to exhibit a sufficient daylighting function and antiglare function for incident light from various directions. In addition, the daylighting system 10 described below can efficiently take in external light from various directions into a region located behind the awning 7 even in a situation where the awning 7 such as a kite is installed. Various ideas have also been made.

  In the present embodiment, as an example in which the daylighting system 10 can be suitably used, the daylighting system 10 is applied to deflecting and taking outside light into the living room 1 through the partition member 5 that partitions the area. . The partition member 5 is a transparent member that partitions the outdoors and the interior. As shown in FIG. 1, the partition member 5 extends between the wall 2 and the floor 4 depending from the ceiling 3. The living room 1 is connected to a veranda 6 through a partition member 5, and an awning 7 extends from the living room 1 side above the veranda 6. A transparent wall member 8 is installed at the tip of the veranda 6.

  The first daylighting film 11 of the daylighting system 10 forms part of the wall member 8 provided on the veranda 6. As an example, as shown in FIG. 2, the first daylighting film 11 is held so as to be held between a pair of transparent supports 15 made of glass, resin, or the like. That is, the wall member 8 is formed by a pair of transparent supports 15 and the first daylighting film 11 located between the supports 15. Since the wall member 8 is disposed outdoors, the pair of support bodies 15 function not only as a support material but also as a protection material for protecting the first daylighting film 11 from wind and rain.

  Further, the second daylighting film 12 of the daylighting system 10 forms a part of the partition member 5. As an example, the 2nd daylighting film 12 is joined to the transparent support body 15 which consists of glass, resin, etc. via the joining layer 16, as shown in FIG. That is, the partition member 5 is formed by the support 15, the second daylighting film 12, and the bonding layer 16 that bonds them. In this partition member 5, the second daylighting film 12 is preferably laminated to the support 15 from the side of the living room 1 for the purpose of protecting the second daylighting film 12 from wind and rain.

  In the illustrated example, the upper end 11b in the vertical direction of the first daylighting film 11 is located below the upper end 12b in the vertical direction of the second daylighting film 12 in the vertical direction. As shown in FIG. 1, the awning 7 is located at least partially above the first daylighting film 11 and the second daylighting film 12 in the vertical direction. The awning 7 is at least partially located between the first daylighting film 11 and the second daylighting film 12 in the horizontal direction.

  In the present embodiment, the partition member 5 and the wall member 8 each extend in the vertical direction. The film surfaces of the first and second daylighting films 11 and 12 extend in the vertical direction. Accordingly, the first reference direction d1 parallel to the normal direction nd of the first daylighting film 11 is along the horizontal direction in the illustrated embodiment. The first reflecting surface 11a of the first daylighting film 11 is arranged in the vertical direction, and similarly, the second reflecting surface 12a of the second daylighting film 12 is also arranged in the vertical direction. Therefore, the second reference direction d2 which is the arrangement direction of the first reflection surface 11a and also the arrangement direction of the second reflection surface 12a is along the vertical direction in the illustrated embodiment.

  As described above, the first reflecting surface 11a and the second reflecting surface 12a are inclined with respect to each other in a plane parallel to both the first reference direction d1 and the second reference direction d2. That is, in a plane parallel to both the first reference direction d1 and the second reference direction d2, the angle formed by the first reflecting surface 11a with respect to the second reference direction d2 is second with respect to the first reference direction d1. This is different from the angle formed by the reflecting surface 12a. Therefore, in the present embodiment, the inclination angle of the first reflection surface 11a and the inclination angle of the second reflection surface 12a are excellent in lighting efficiency and prevention with respect to incident light from various directions, as will be described in detail later. It can be adjusted independently so as to exhibit a glare function.

  In particular, as shown in FIG. 1, in a plane parallel to both the first reference direction d1 and the second reference direction d2, the horizontal direction from the first daylighting film 11 side to the second daylighting film 12 side is obtained. Assuming that the angle when tilting downward in the vertical direction is a positive value, the angle θa formed by the first reflecting surface 11a with respect to the horizontal direction that is the second reference direction d2 is the second reflecting surface 12a being horizontal. The angle θb is larger than the angle θb formed with respect to the first reference direction d1. According to such a configuration, by combining the first reflecting surface 11a and the second reflecting surface 12a, incident light from various directions can be effectively deflected and taken into the living room 1 with high efficiency. Become.

  Further, the first reflecting surface 11a and the second reflecting surface 12a in the illustrated embodiment are inclined in the opposite directions. Referring to FIG. 1, the first reflecting surface 11 a is inclined from the first daylighting film 11 side toward the second daylighting film 12 side so as to be directed downward in the vertical direction with respect to the horizontal direction. On the other hand, the 2nd reflective surface 12a inclines so that it may go to a perpendicular direction upper direction with respect to a horizontal direction toward the 2nd daylighting film 12 side from the 1st daylighting film 11 side. Therefore, as described above, in a plane parallel to both the first reference direction d1 and the second reference direction d2, the horizontal direction from the first daylighting film 11 side to the second daylighting film 12 side. If the angle when tilting downward in the vertical direction is a positive value, the angle θa formed by the first reflecting surface 11a with respect to the horizontal direction, which is the second reference direction d2, is a positive value, and the second reflecting surface The angle θb formed by 12a with respect to the horizontal direction which is the second reference direction d2 is a negative value. According to such a configuration, as will be described in detail later, excellent daylighting efficiency and anti-glare function can be exhibited with respect to incident light from various directions.

  Next, specific configurations of the first daylighting film 11 and the second daylighting film 12 will be described.

  The first daylighting film 11 and the second daylighting film 12 can be configured identically with respect to other points, except that the angles of the reflecting surfaces 11a and 12a are different. FIG. 4 shows an example of the first daylighting film 11, and FIG. 5 shows the first daylighting film 11 and the second daylighting film 12 in the first reference direction d1 and the second reference direction d2. It is shown in a cross section parallel to both. The first daylighting film 11 shown in FIG. 5 is the same as the first daylighting film 11 of FIG.

  In the example shown in FIGS. 4 and 5, the first daylighting film 11 has a plurality of first portions 21 and second portions 22 arranged in the second reference direction d2. The first portions 21 and the second portions 22 are alternately arranged in the second reference direction d2. The first portion 21 and the second portion 22 extend linearly in a direction along the film surface of the first daylighting film 11 and not parallel to the first reference direction d1. In the illustrated example, the first portion 21 and the second portion 22 extend linearly in a third reference direction d3 that is parallel to the film surface of the first daylighting film 11 and orthogonal to the first reference direction d1. In the application example shown in FIG. 1, the third reference direction d3 extends in the horizontal direction perpendicular to the first reference direction d1.

  The first daylighting film 11 shown in FIGS. 4 and 5 includes a light control layer 20 including a first portion 21 and a second portion 22, and a base material layer 29 laminated with the light control layer 20. ing. In the present embodiment, the base material layer 29 is provided due to a manufacturing method of the light control layer 20 described later, but is not a particularly essential component. Therefore, as an example, it can be formed from a simple transparent or translucent resin film.

  On the other hand, the light control layer 20 further includes a sheet-like base portion (land portion) 23 that supports the first portion 21 and the second portion 22 in addition to the first portion 21 and the second portion 22. The base portion 23 is formed integrally with the first portion 21, and forms the light control layer body 24 together with the first portion 21. In other words, the light control layer 20 of the first daylighting film 11 includes the light control layer body 24 formed with a plurality of grooves 24 a and the second portions 22 formed in the plurality of grooves 24 a of the light control layer body 24, respectively. And have. A portion between the adjacent grooves 24 a in the light control layer main body 24 defines the first portion 21.

  In FIG. 5, as the main cutting surface of the first daylighting film 11, the second reference direction d <b> 2, which is the arrangement direction of the first part 21 and the second part 22, and the normal direction to the sheet surface of the first daylighting film 11, The first daylighting film 11 is shown in a cross section parallel to both of the first reference directions d1. As shown in FIG. 5, the second portion 22 includes a bottom surface 25 that forms part of the surface of the light control layer 20 opposite to the base material layer 29 side, a first side surface 26 that extends from the bottom surface 25, and a second side. 2 side surfaces 27. In the illustrated example, the distance between the first side surface 26 and the second side surface 27 approaches each other as the distance from the bottom surface 35 increases along the normal direction to the sheet surface of the first daylighting film 11. Are connected to each other.

  In the illustrated example, the second portions 22 are arranged at equal intervals along the second reference direction d2. The second portion 22 extends in the third reference direction d3 without changing the cross-sectional shape. Further, the multiple second portions 22 included in the first daylighting film 11 are configured identically. With the configuration of the second portion 22 described above, in the illustrated example, the first portions 21 included in the first daylighting film 11 are arranged at equal intervals along the second reference direction d2 to change the cross-sectional shape. Without extending, it extends in the third reference direction d3 and is configured identically.

  The arrangement pitch p along the second reference direction d2 of the second portions 22 in the cross section shown in FIG. 5 can be, for example, 1 mm or less, and the second portion along the first reference direction d1. The height h of 22 can be 1 mm or less. Moreover, the thickness of the 1st daylighting film 11 along the 1st reference direction d1 can be 100 micrometers or more and 2 mm or less. Further, the ratio of the height h of the second portion 22 along the first reference direction d1 to the width w of the second portion 22 along the second reference direction d2, that is, the aspect ratio represented by h / w is It is preferably larger than 1, more preferably 5 or more. The aspect ratio is preferably 10 or less in consideration of production stability.

  Next, materials of the first portion 21 and the second portion 22 will be described. The first portion 21 is formed to be transparent. In this specification, “transparent” means that the visible light transmittance is 50% or more. However, the visible light transmittance of the first portion 20 in the present embodiment is preferably 70% or more, and more preferably 90% or more.

  In this specification, the visible light transmittance is determined by depositing a material that will be a part to be measured on a PET film (product number: Cosmo Shine A4300, thickness 100 μm) made by Toyobo with a thickness of 1 μm. , Specified as an average value of transmittance at each wavelength when measured within a measurement wavelength range of 380 nm to 780 nm using a spectrophotometer (manufactured by Shimadzu Corporation "UV-2450", JISK0115 compliant product) . Similarly, for the heat ray transmittance described later, a material that forms a part to be measured is formed on a PET film (product number: Cosmo Shine A4300, thickness 100 μm) made by Toyobo Co., Ltd. with a film thickness of 1 μm. It is specified as an average value of transmittance at each wavelength when measured within a measurement wavelength range of 900 nm to 2500 nm using a photometer (“UV-2450” manufactured by Shimadzu Corporation, JISK0115 compliant product).

  In the present embodiment, the base portion 23 is formed integrally with the first portion 21 using the same material as the first portion 21. As a material used for the light control layer body 24 forming the first portion 21 and the base portion 23, for example, a resin material, particularly an ionizing radiation curable resin that is cured by irradiation with ionizing radiation can be used. Examples of the ionizing radiation curable resin include an ultraviolet curable resin, an electron beam curable resin, a visible light curable resin, and a near infrared curable resin. Specific examples of the resin material include an epoxy resin and an acrylic resin.

  The second portion 22 has a refractive index different from that of the first portion 21. For this reason, the 1st side surface 26 which makes the refractive index interface of the 2nd part 22 and the 1st part 21 functions as the 1st reflective surface 11a. The first reflecting surface 11a can also totally reflect light traveling from the predetermined direction toward the second portion 22 via the first portion 21. In the illustrated example, the second portion 22 is formed using a transparent material. As a transparent material, the material illustrated as a material which can be used for the 1st part 21, for example can be used.

  In addition, the 1st daylighting film 11 which consists of the above structures can be manufactured as follows. First, the light control layer body 24 that forms the first portion 21 and the base portion 23 is manufactured using a curable material such as epoxy acrylate having a characteristic of being cured by irradiation with ionizing radiation such as an electron beam or ultraviolet rays. . Specifically, a mold roll having a convex portion corresponding to the configuration (arrangement, shape, etc.) of the groove 24a of the light control layer body 24, in other words, a concave portion corresponding to the configuration (arrangement, shape, etc.) of the first portion 21. A mold roll having is prepared. A sheet that forms the base material layer 29 is fed between the mold roll and the nip roll, and a curable material is supplied between the mold roll and the base material layer 29 in accordance with the feeding of the sheet. Thereafter, the curable material is pressed with a mold roll and a nip roll so that the liquid curable material supplied onto the base material layer 29 is filled in the concave portion of the mold roll. At this time, the curable material is supplied onto the substrate layer 29 so as to be thicker than the depth of the concave portion of the mold roll, that is, the mold roll and the substrate layer 29 are not in contact with each other. The base portion (land portion) 33 is formed integrally with the first portion 21 from a curable material. After filling the uncured and liquid curable material between the base material layer 29 and the mold roll as described above, the light control layer main body is obtained by irradiating light to cure (solidify) the curable material. 24 can be formed.

  Next, the 2nd part 22 is produced using the uncured and liquid composition which will make the 2nd part 22 by hardening. As the curable material that forms the second portion 22 by being cured, a curable material such as urethane acrylate having a characteristic of being cured by ionizing radiation can be used. First, the composition is supplied onto the light control layer body 24 formed in advance. Thereafter, the groove 24a formed between the adjacent first portions 21, that is, the portion corresponding to the convex portion of the mold roll is filled with the composition using a doctor blade, and the groove 24a is filled. The excess composition overflowing outside is scraped off. Then, the 2nd part 22 is formed by irradiating the composition between the 1st parts 21 with ionizing radiation, and making it harden | cure. Thereby, the 1st daylighting film 11 which has the base material layer 29, the base part 23 provided on the base material layer 29, and the 1st part 21 and the 2nd part 22 provided on the base part 23. Is produced.

  Next, the 2nd daylighting film 12 is comprised similarly to the 1st daylighting film 11 in the daylighting system 10 shown by FIG. That is, the second daylighting film 12 includes a base layer 29 and a light control layer 20 provided on the base layer 29. The light control layer 20 is provided on the base layer 29. A base portion 23, and a first portion 21 and a second portion 22 provided on the base portion 23. However, the second daylighting film 12 is disposed so that the same daylighting film as the first daylighting film 11 is turned upside down, so that the inclination angle θb of the second reflecting surface 12a is inclined to the first reflecting surface 11a. The angle θa is different.

  According to such a structure, the 1st daylighting film 11 and the 2nd daylighting film 12 can be formed with the daylighting film of a single structure, and can enjoy cost merit. Moreover, the above-described relationship between the inclination angle θa of the first reflection surface 11a and the inclination angle θb of the second reflection surface 12a can be satisfied while enjoying the cost advantage. That is, in the daylighting system 10 shown in FIG. 5, the first daylighting film 11 side is directed to the second daylighting film 12 side in a plane parallel to both the first reference direction d1 and the second reference direction d2. Assuming that the angle when tilting downward in the vertical direction with respect to the horizontal direction is a positive value, the angle θa formed by the first reflecting surface 11a with respect to the horizontal direction which is the second reference direction d2 is the second The reflection surface 12a is larger than the angle θb formed with respect to the first reference direction d1 which is the horizontal direction. Further, the first reflecting surface 11a and the second reflecting surface 12a are inclined in opposite directions with respect to a second reference direction d2 parallel to the vertical direction.

  However, the first daylighting film 11 and the second daylighting film 12 described above are merely examples, and various changes can be made. Here, an example of a modification will be described with reference to FIGS. 6 to 9 exemplify the first daylighting film 11 as a representative, the following modifications can be similarly applied to the second daylighting film 12 as described below. .

  For example, the 1st side surface 26 which forms the 1st reflective surface 11a or the 2nd reflective surface 12a does not need to be formed in linear form. For example, the first side surface 26 forming the first reflecting surface 11a or the second reflecting surface 12a is formed in a polygonal line shape as shown in FIG. 6 in a cross section parallel to both the first reference direction d1 and the second reference direction d2. Alternatively, it may be formed in a curved shape as shown in FIG. When the daylighting films 11 and 12 shown in FIGS. 6 and 7 are used, incident light from various directions can be deflected in a narrower angle range by reflection at the first side surface 26. It becomes.

  If the first reflecting surface 11a or the second reflecting surface 12a is not a straight line such as a polygonal line or a curved line in a cross section parallel to both the first reference direction d1 and the second reference direction d2, the reflecting surface The inclination angles θa and θb of 11a and 12a are specified as angles formed by straight lines passing through both ends of the reflecting surfaces 11a and 12a along the first reference direction d1 with respect to the first reference direction d1.

  Moreover, although the 1st reflective surface 11a or the 2nd reflective surface 12a showed the example formed as the refractive index interface of the 1st part 21 and the 2nd part 22 which consist of mutually different refractive indexes, it is not restricted to this. . For example, the second portion 22 itself may be formed of a reflective material. Further, a reflective material may be provided between the first portion 21 and the second portion 22, and the first reflective surface 11a or the second reflective surface 12a may be formed of the reflective material. Further, as shown in FIG. 8, a reflective layer 30 made of a reflective material, for example, a metal material, may be provided in the groove 24 a of the light control layer body 24 with the second portion 22 as a gap. In the example shown in FIG. 8, the first reflective surface 11 a or the second reflective surface 12 a is formed by the reflective layer 30. The reflective layer 30 can be formed in the groove 24a by, for example, ink jet printing.

  Further, the second portion 22 may be a simple gap 31, and the first reflecting surface 11 a or the second reflecting surface 12 a may be formed by the refractive index interface between the first portion 21 and the gap 31. In this example, the groove 24a of the light control layer body 24 forming the gap 31 can be formed in a linear shape extending along the first reflecting surface 11a or the second reflecting surface 12a as shown in FIG. .

  Moreover, you may make it the 2nd part 22 consist of the main part which functions as a binder, and the functional containing material disperse | distributed in the main part. A part of the light traveling from the first portion 21 toward the second portion 22 is incident on the second portion 22 without being reflected by the reflecting surfaces 11a and 12a. In the first daylighting film 11, there is also light that directly enters the second portion 22 without passing through the first portion 21. The functional inclusion may exhibit various functions with respect to the light incident on the second portion 22. The functional content contained in the second portion 22 is dispersed in the main portion 32a in expectation of various functions, and as an example, a heat ray absorbing material or a coloring material can be used. On the other hand, the material used for the main part can be a material having a refractive index different from that of the first portion 21, for example, a resin material, in particular, a cured product of an ionizing radiation curable resin that is cured by irradiation with ionizing radiation. . However, if it has a functional inclusion, the same material as that used for the first portion may be used as long as the refractive index of the second portion changes depending on the functional inclusion.

  Next, the operation of the daylighting system 10 will be described mainly with reference to FIG.

  The daylighting system 10 according to the present embodiment can effectively deflect the optical path of incident light incident from various directions and take it into the living room 1 with high efficiency. For example, when the light taken in by the daylighting system 10 is sunlight that mainly falls from the sun, the incident angle to the daylighting system 10 installed at a specific position varies depending on the season and time zone. And the lighting system 10 by this Embodiment can exhibit both a lighting function and a glare-proof function effectively also with respect to such sunlight.

  First, for example, when the altitude of the sun is high around noon, the incident lights L101 to L103 to the daylighting system 10 travel in a direction greatly inclined with respect to the horizontal direction that is the first reference direction d1. As shown in FIG. 10, a part L103 of such light passes between the front end portion 7a of the shade 7 and the upper end of the wall member 8 and enters the veranda 6 to illuminate the veranda 6 brightly. In particular, it can be used effectively.

  On the other hand, the other lights L101 and L102 greatly inclined with respect to the horizontal direction enter the wall member 8 including the first daylighting film 11. The wall member 8 is not simply formed transparent and does not take light into the veranda 6, but can guide light to the living room 1 by adjusting the light path by the first daylighting film 11. As described above, the first daylighting film 11 has the first reflecting surface 11a having a relatively large inclination angle θa. Here, the angle of inclination of the reflecting surface is such that the light incident side to the light exit side are within the plane parallel to both the first reference direction d1 that coincides with the horizontal direction and the second reference direction d2 that coincides with the vertical direction. The angle when tilting toward the indoor side toward the lower side in the vertical direction with respect to the horizontal direction is a positive value. Therefore, as shown in FIG. 10, the traveling direction of the light L101 and L102 transmitted through the first daylighting film 11 is inclined with respect to the horizontal direction by being reflected by the first reflecting surface 11a having a relatively large inclination angle θa. Make the angle relatively small.

  In particular, when the inclination angle θa with respect to the horizontal direction of the first reflecting surface 11a takes a positive value, the light L101, L102 reflected by the first reflecting surface 11a and transmitted through the first daylighting film 11 from the outdoor side to the indoor side is transmitted. The magnitude of the angle formed by the optical path with respect to the horizontal direction is smaller after reflection than before reflection. Here, the magnitude of the angle is an absolute value of the angle. That is, as shown in FIG. 10, the light L101 and L102 incident on the first daylighting film 11 from the direction greatly inclined with respect to the horizontal direction is reflected by the first reflecting surface 11a, so that the inclination is relatively small. As light along the horizontal direction, the light travels indoors and travels toward the second daylighting film 12 located closer to the living room 1 than the first daylighting film 11.

  In the present embodiment, in this embodiment, the upper end 12b of the second daylighting film 12 is positioned above the upper end 11b of the first daylighting film 11 in the vertical direction. Therefore, the lights L101 and L102 bounced up by the first daylighting film 11 can reach the second daylighting film 12 forming a part of the partition member 5.

  The second daylighting film 12 has a second reflecting surface 12a having a relatively small inclination angle θb. Therefore, the lights L101 and L102 traveling in a direction not greatly inclined with respect to the horizontal direction pass between the second reflecting surfaces 12a arranged in the second reference direction d2 and are not reflected by the second reflecting surface 12a. , Can enter the living room 1. That is, in the daylighting system 10, when the inclination angle θb of the second reflecting surface 12a is set smaller than the inclination angle θa with respect to the horizontal direction of the first reflecting surface 11a, the first daylighting from the direction greatly inclined with respect to the horizontal direction. The light paths of the light L101 and L102 incident on the film 11 are adjusted so as to be directed to the second daylighting film 12 by reflection on the first reflecting surface 11a, and further pass between the second reflecting surfaces 12a in the second daylighting film 12. Thus, the light can be collected.

  In particular, when the inclination angle θb of the second reflecting surface 12a with respect to the horizontal direction takes a negative value, the light bounced up by the reflection at the first reflecting surface 11a, especially the first value where the inclination angle θa takes a positive value. The light L101, L102 reflected in a direction that forms a relatively small angle with respect to the horizontal direction on the reflecting surface 11a is promoted to be transmitted through the second daylighting film 12 without being reflected by the second reflecting surface 12a. be able to.

  In the example shown in FIG. 1, an opening 9 for taking in external light is formed in the tip 7 a of the sunshade 7 and the tip 6 a of the veranda 6. And the partition member 5 is spaced apart in the horizontal direction from the opening 9, and partitions the living room 1 which should take in light. Therefore, if the daylighting system 10 is not applied, light from a direction inclined to a certain extent with respect to the horizontal direction does not reach the partition member 5 that partitions the living room 1.

  On the other hand, according to the daylighting system 10 arranged in the region from the opening 9 to the partition member 5, even the light traveling in the direction greatly inclined with respect to the horizontal direction is a wall member installed in the opening 9 or in the vicinity thereof. 8 can be guided to the partition member 5 by reflection on the first daylighting film 11. Then, the partition member 5 can take up the optical path of the light traveling toward the floor 4 of the living room 1 toward the ceiling 3 and take it into the living room 1. That is, even light traveling in a direction greatly inclined with respect to the horizontal direction can be collected with high efficiency. In addition, the lights L101 and L102 taken into the living room 1 are directed toward the ceiling 3 of the living room 1. Therefore, instead of or in addition to illumination by a lighting fixture or the like, the light collected in the living room 1 can be effectively used as the illumination light of the living room 1. Moreover, it is possible to effectively prevent a person in the living room 1 from feeling dazzled by the lights L101 and L102.

  Next, when the altitude of the sun is low in the morning or evening, the incident lights L104 and L105 entering the daylighting system 10 travel in a direction slightly inclined with respect to the horizontal direction that is the first reference direction d1. As shown in FIG. 10, such a part L104 of the light passes between the front end 7 a of the awning 7 and the upper end of the wall member 8 and enters the veranda 6. The light L104 is incident on the partition member 5 without reaching the floor of the veranda 6 because the optical path is not inclined with respect to the horizontal direction. In the present embodiment, the lower end 12 c of the second daylighting film 12 is positioned below the upper end 11 b of the first daylighting film 11 in the vertical direction. Therefore, such light L104 can reach the second daylighting film 12 forming a part of the partition member 5.

  A part L105 of the light traveling in a direction slightly inclined with respect to the horizontal direction that is the first reference direction d1 is incident on the wall member 8. The first daylighting film 11 included in the wall member 8 has a first reflecting surface 11a having a relatively large inclination angle θa. Therefore, the light L105 traveling in a direction not greatly inclined with respect to the horizontal direction passes between the first reflecting surfaces 11a arranged in the second reference direction d2, and is reflected by the first reflecting surface 11a without being reflected by the first reflecting surface 11a. It can go to the member 5. In particular, when the inclination angle θa of the first reflecting surface 11a takes a positive value, most of the morning and evening sunlight falling on the gentle inclination angle of the first reflecting surface 11a arranged in the second reference direction d2 It is possible to pass through and to the partition member 5.

  In the present embodiment, the lower end 12 c of the second daylighting film 12 is positioned below the upper end 11 b of the first daylighting film 11 in the vertical direction. Therefore, such light L105 can reach the second daylighting film 12 forming part of the partition member 5. Furthermore, according to the present embodiment, the lower end 12c of the second daylighting film 12 is the same position in the vertical direction as the lower end 11c of the first daylighting film 11, or is more vertical than the lower end 11c of the first daylighting film 11. Located below. According to such a form, it is promoted that the light L105 that has passed through the first daylighting film 11 reaches the second daylighting film 12 that forms part of the partition member 5.

  Next, the lights L104 and L105 traveling in a direction not greatly inclined with respect to the horizontal direction are incident on the second daylighting film 12 included in the partition member 5, and the optical path is corrected. The second daylighting film 12 has a second reflecting surface 12a having a relatively small inclination angle θb. Therefore, as shown in FIG. 10, the traveling directions of the light L104 and L105 reflected by the second reflecting surface 12a having a relatively small inclination angle θa and transmitted through the second daylighting film 12 have an inclination angle with respect to the horizontal direction. Make it relatively large. That is, the light L104, L105 whose optical path is corrected by the second reflecting surface 12a of the second daylighting film 12 is bounced up by the reflection at the second reflecting surface 12a and heads toward the ceiling 3. Therefore, instead of or in addition to illumination by a lighting fixture or the like, the light collected in the living room 1 can be effectively used as the illumination light of the living room 1. Moreover, it is possible to effectively prevent a person in the living room 1 from feeling dazzled by the lights L101 and L102.

  In particular, when the inclination angle θb with respect to the horizontal direction of the second reflecting surface 12a takes a negative value, the light L104, L105 reflected by the second reflecting surface 12a and transmitted through the second daylighting film 12 from the outdoor side to the indoor side. The magnitude of the angle formed by the optical path with respect to the horizontal direction, that is, the absolute value of the angle is greater after reflection than before reflection. That is, as shown in FIG. 10, the light L104, L105 that has entered the second daylighting film 12 from a direction that does not significantly tilt with respect to the horizontal direction is reflected by the second reflecting surface 12a, and thus has a relatively large tilt. As light along the vertical direction, the light travels toward the ceiling 3 of the living room 1.

  As described above, in the present embodiment, in a plane parallel to the vertical direction, from the first daylighting film 11 side toward the second daylighting film 12 side, the vertical direction is directed downward with respect to the horizontal direction. The inclination angle θa formed by the first reflection surface 11a with respect to the horizontal direction is larger than the inclination angle θb formed by the second reflection surface 12a with respect to the horizontal direction, with the inclination angle when inclined as a positive value. According to such a daylighting system 10, by combining the first daylighting film 11 and the second daylighting film 12, the optical path of light incident at various incident angles can be effectively adjusted and taken in with high efficiency. That is, a sufficient daylighting function and antiglare function can be exhibited for light incident at various incident angles.

  Moreover, according to this Embodiment, the 1st reflective surface 11a and the 2nd reflective surface 12a incline in the reverse direction. According to such a daylighting system, the daylighting function and the antiglare function can be more effectively exhibited with respect to light incident at various incident angles. In particular, if the daylighting system 10 is installed so that the inclination angle θa of the first reflecting surface 11a has a positive value and the inclination angle θb of the second reflecting surface 12a has a negative value, light incident at various incident angles can be obtained. In contrast, the daylighting function and the antiglare function can be exhibited extremely effectively.

  Furthermore, according to the present embodiment, even light that is greatly inclined with respect to the horizontal direction can be captured after the optical path is effectively adjusted up to a region separated from the opening 9 for capturing external light. That is, even if the awning 7 such as a cocoon protrudes, even the light greatly inclined with respect to the horizontal direction can be taken in by adjusting the optical path, thereby realizing highly efficient daylighting.

  Note that various modifications can be made to the above-described embodiment. Hereinafter, an example of modification will be described with reference to the drawings as appropriate. In the following description and the drawings used in the following description, the same reference numerals as those used for the corresponding parts in the above-described embodiment are used for parts that can be configured in the same manner as in the above-described embodiment, and overlapping Description to be omitted is omitted.

  In embodiment mentioned above, as shown in FIG. 3, the division member 5 has the support body 15, the 2nd daylighting film 12, and the joining layer 16 which joins the support body 15 and the 2nd daylighting film 12. As shown in FIG. An example is shown. However, as shown in FIG. 2, the partition member 5 may include a pair of support bodies 15 and a second daylighting film 12 disposed between the pair of support bodies 15.

  Moreover, in embodiment mentioned above, as shown in FIG. 2, the example which the wall member 8 has the 1st daylighting film 11 arrange | positioned between a pair of support body 15 was shown. However, as shown in FIG. 2, the wall member 8 may include a support 15, a first daylighting film 11, and a bonding layer 16 that joins the support 15 and the first daylighting film 11. .

  Furthermore, in embodiment mentioned above, although the 2nd daylighting film 12 showed the example which forms a part of division member 5, it is not restricted to this example. For example, the second daylighting film 12 may be formed as a sheet-like member that can be wound, for example, a roll-up curtain, and disposed on the room side of the partition member 5.

  Furthermore, as shown in FIGS. 11 to 13, the second daylighting film 12 may constitute a slat of the blind 40. The blind 40 has a plurality of slats 42 and a mounting box 41 arranged in the vertical direction. As shown in FIG. 11, the blind 40 is arranged such that the slats 42 are located on the side of the compartment member 5 in the room. As shown in FIG. 12, each slat 42 is formed as a second daylighting film 12. The slat 42 is supported so that the direction of the plate surface can be changed and the slat 42 can be pulled up into the mounting box 41. As shown in FIGS. 11 and 12, when the blind 40 is held in a fully closed state and each slat 42 is raised, an assembly of a large number of slats 42 functions in the same manner as the second daylighting film 12 described above. To come. However, as shown in FIG. 13, when guiding the light splashed by the first reflecting surface 11 a of the first daylighting film 11 into the living room 1, the slats 42 of the blind 40 are not fully closed, The slats 42 may be inclined so as to follow the traveling direction of the light.

  Furthermore, although the application example of the daylighting system 10 was shown as embodiment mentioned above, it is not limited to the application to daylighting to the living room 1 via the veranda 6 mentioned above. As shown in FIG. 14, as typically in a school, light incident on a window 58 installed in a hallway 56 is transmitted to a room 51 on the opposite side of the window 58 across the hallway 59, for example, a classroom. It may be applied to daylighting. In the example shown in FIG. 14, a window 58 is fitted into the opening 59 of the hallway 56, and the first daylighting film 11 forms this window 58. On the other hand, the second daylighting film 12 forms a window 55 that partitions the hallway 56 and the room 51.

  Further, as shown in FIG. 15, the above-described daylighting system is used for daylighting the substantial living area 62 of the living room 61 that is separated from the window of the living room 61 by installing furniture 63 such as a chiffon. 10 can also be applied. In the example shown in FIG. 15, a window 68 is fitted into an opening 69 of a living room 61 provided for taking in external light, and the first daylighting film 11 forms this window 68. The second daylighting film 12 is arranged like a screen on the furniture 63.

  In addition, although the some modification with respect to embodiment mentioned above was demonstrated above, naturally, it is also possible to apply combining several modifications suitably.

DESCRIPTION OF SYMBOLS 1 Living room 2 Wall 3 Ceiling 4 Floor 5 Partition member 6 Veranda 6a Tip part 7 Sunshade 7a Tip part 8 Wall member 9 Opening 10 Daylighting system 11 1st daylighting film 11a First reflective surface 11b Upper end 11c Lower end 12 Second daylighting film 12a 1st 2 reflective surface 12b upper end 12c lower end 15 support 16 bonding layer 20 light control layer 21 first part 22 second part 22a main part 23 base part 24 light control layer main body 24a groove 25 bottom face 26 first side face 26a steep slope 26b gentle slope 27 Second side 28 Top surface 29 Base layer 30 Reflective layer 31 Gap 40 Blind 41 Mounting box 42 Slat 51 Room 55 Window 56 Corridor 58 Window 59 Opening 61 Living room 62 Living area 63 Furniture 68 Window 69 Opening

Claims (9)

A first daylighting film;
A second daylighting film disposed away from the first daylighting film in a first reference direction parallel to the normal direction of the first daylighting film, and
The first daylighting film has a plurality of first reflecting surfaces arranged in a second reference direction that is non-parallel to the first reference direction,
The second daylighting film has a plurality of second reflecting surfaces arranged in the second reference direction,
In a plane parallel to both the first reference direction and the second reference direction, from the first daylighting film side toward the second daylighting film side toward the lower side in the vertical direction with respect to the horizontal direction. the angle of the case where the inclination as a positive value, the angle formed by the first reflecting surface with respect to the horizontal direction, the much larger than the angle formed by the second reflecting surface with respect to the horizontal direction,
The position of at least a portion that is at least partially above the first daylighting film and the second daylighting film and is between the first daylighting film and the second daylighting film in the horizontal direction. A daylighting system with an awning .   A first daylighting film;
  A second daylighting film disposed away from the first daylighting film in a first reference direction parallel to the normal direction of the first daylighting film, and
  The first daylighting film has a plurality of first reflecting surfaces arranged in a second reference direction that is non-parallel to the first reference direction,
  The second daylighting film has a plurality of second reflecting surfaces arranged in the second reference direction,
  In a plane parallel to both the first reference direction and the second reference direction, from the first daylighting film side toward the second daylighting film side toward the lower side in the vertical direction with respect to the horizontal direction. The angle formed by the first reflecting surface with respect to the horizontal direction is greater than the angle formed by the second reflecting surface with respect to the horizontal direction, with the angle when tilting being a positive value.
  The lighting system in which the lower end in the vertical direction of the second daylighting film is located below the upper end in the vertical direction of the first daylighting film.   A first daylighting film;
  A second daylighting film disposed away from the first daylighting film in a first reference direction parallel to the normal direction of the first daylighting film, and
  The first daylighting film has a plurality of first reflecting surfaces arranged in a second reference direction that is non-parallel to the first reference direction,
  The second daylighting film has a plurality of second reflecting surfaces arranged in the second reference direction,
  In a plane parallel to both the first reference direction and the second reference direction, from the first daylighting film side toward the second daylighting film side toward the lower side in the vertical direction with respect to the horizontal direction. The angle formed by the first reflecting surface with respect to the horizontal direction is greater than the angle formed by the second reflecting surface with respect to the horizontal direction, with the angle when tilting being a positive value.
  The second daylighting film forms a partition member that partitions the region;
  The daylighting system in which the first daylighting film forms a wall member provided outside the room.   The angle formed by the first reflecting surface with respect to the horizontal direction in a plane parallel to both the first reference direction and the second reference direction is a positive value.
  4. The angle formed by the second reflecting surface with respect to the horizontal direction in a plane parallel to both the first reference direction and the second reference direction is a negative value. 5. The daylighting system according to item.   The position of at least a portion that is at least partially above the first daylighting film and the second daylighting film and is between the first daylighting film and the second daylighting film in the horizontal direction. The daylighting system according to any one of claims 2 to 4, wherein a sunshade is provided.   The daylighting system according to any one of claims 1 to 5, wherein an upper end of the first daylighting film in the vertical direction is located below the upper end of the second daylighting film in the vertical direction. .   The lower end in the vertical direction of the second daylighting film is located below the upper end in the vertical direction of the first daylighting film in the vertical direction, according to any one of claims 1 and 3-5. Daylighting system.   The lower end in the vertical direction of the second daylighting film is located at the same position in the vertical direction as the lower end in the vertical direction of the first daylighting film, or is more vertical than the lower end in the vertical direction of the first daylighting film. The daylighting system according to claim 1, which is located below in the direction.   The second daylighting film forms a partition member that partitions the region;
  The daylighting system according to any one of claims 1, 2, and 4 to 8, wherein the first daylighting film forms a wall member provided outside the room.

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