JP6548108B2 - Heat ray shielding unit and heat ray shielding method - Google Patents

Description

  The present invention relates to a heat ray shielding unit and a heat ray shielding method for effectively shielding infrared rays (heat rays), and more particularly to a heat ray shielding unit and a heat ray shielding method capable of controlling infrared ray shielding according to the season.

  Various kinds of heat ray shielding materials have been proposed which are applied to a light receiving window or the like provided on the side of a building and have a function of shielding heat rays. For example, Patent Document 1 discloses a light control sheet which is entirely composed of a light transmitting portion made of a light transmitting material which transmits sunlight and a light shielding portion group made of a light absorbing material which absorbs sunlight. It is disclosed that the light shielding portion group is formed by arranging a plurality of light shielding portions made of a light absorbing material at a predetermined pitch in one direction in the sheet. In the case of this light control sheet, it is possible to change the amount of sunlight uptake according to the change of the south middle altitude, so while intercepting the sunlight uptake into the room in summer, the sunlight uptake is taken in winter. Many things can be done.

  However, in the case of the light control sheet described above, since all the sunlight is shielded by the light shielding portion group, not only the heat rays but also the amount of visible light taken in is reduced in summer, and sufficient brightness can not be ensured. There's a problem. Of course, it is also possible to secure the brightness by reducing the area in which the light shielding portion group is formed, but in that case, the amount of heat rays taken in is also increased, so that the infrared shielding property is impaired.

  On the other hand, Patent Document 2 discloses a light transmitting portion having a plurality of grooves on one surface, and a heat ray absorbing portion having transparent heat ray absorbing particles formed in the grooves and transmitting black particles and visible light. A heat ray control sheet comprising the According to this heat ray control sheet, in the summer when the incident angle of sunlight is large, it is possible to block the uptake of heat rays by the heat ray absorbing particles while capturing a suitable amount of visible light. On the other hand, in winter when the incident angle of sunlight is small, sunlight is incident from an angle close to perpendicular to the surface of the heat ray control sheet, so that visible light and heat rays can be sufficiently captured in the light transmitting portion.

JP, 2010-259406, A JP, 2014-085408, A

  As described above, the heat ray control sheet in Patent Document 2 can control the uptake amount of both visible light and heat rays according to the incident angle of sunlight, so in the summer, the uptake amount of visible light is secured appropriately It is possible to obtain heat ray shielding properties and visible light transparency according to the season, for example, by blocking heat rays and sufficiently capturing not only visible rays but also heat rays in winter. However, such effects may be diminished depending on the place where the heat ray control sheet is installed. That is, since the south middle altitude of the sun varies depending on the latitude, the incident angle of sunlight will be different at different latitudes even in the same summer or winter season, and appropriate heat ray shielding and visible light at specific locations. Even if transparency can be realized, there may be a problem that similar effects can not be obtained at other points different in latitude from the point.

  The present invention has been made in view of such circumstances, and a main object thereof is to provide a heat ray shielding unit and a heat ray shielding method capable of solving the above-mentioned problems.

In order to solve the problems described above, the heat ray shielding unit according to one aspect of the present invention is a heat ray shielding unit in which a plurality of light transmission plates transmitting sunlight are stacked directly or indirectly, On each of the plates, a plurality of strip-like heat ray shielding portions made of conductive metal oxide particles transparent to visible light are formed in parallel with each other , and at least one of the plurality of light transmitting plates is Position adjustment is possible in the parallel direction of the said heat ray shielding part .

In the above aspect, the distance between the plurality of light transmission plates may be adjustable .

  In the above aspect, an air gap may be provided between the plurality of light transmission plates.

  In the above aspect, the heat ray blocking portion is formed on the surface of each of the plurality of light transmitting plates, and in the plurality of light transmitting plates, the surfaces on which the heat ray blocking portions are formed are opposed to each other. It may be laminated.

  In the above-mentioned mode, it may further have a scale provided for position adjustment of the light transmission plate.

  In the above-mentioned mode, at least one copy of a plurality of heat ray blocking parts formed in at least one of a plurality of above-mentioned light transmission plates may be connected.

  In the above aspect, the conductive metal oxide fine particles may be one or more selected from the group consisting of ATO fine particles and ITO fine particles.

  In the above aspect, the plurality of light transmission plates may be stacked via an intermediate film.

  In the above aspect, the heat ray shielding portion may be formed by filling the conductive metal oxide fine particles in a plurality of grooves formed on the surface of the light transmitting plate.

  Furthermore, in the above aspect, the plurality of light transmission plates may be configured to be attachable and detachable.

  Further, a heat ray shielding method according to one aspect of the present invention is a heat ray shielding method for shielding a heat ray using a heat ray shielding unit in which a plurality of light transmission plates transmitting sunlight are stacked directly or indirectly. In each of the light transmitting plates, a plurality of strip-shaped heat ray shielding portions made of conductive metal oxide particles transparent to visible light are formed in parallel with each other, and at least a plurality of the light transmitting plates The heat shielding is controlled by positioning one of the heat shielding units in the parallel direction.

  ADVANTAGE OF THE INVENTION According to this invention, the uptake amount of a heat ray can be changed according to a season, ensuring visible light transmittance.

BRIEF DESCRIPTION OF THE DRAWINGS The front view which shows the structure of the heat ray blocking unit which concerns on embodiment of this invention. 1. AA sectional view taken on the line of FIG. BB sectional drawing of FIG. Sectional drawing which shows typically the mode of uptake | capture of the sunlight in the heat ray blocking unit which concerns on embodiment of this invention. Sectional drawing which shows typically the mode of uptake | capture of the sunlight in the heat ray blocking unit which concerns on embodiment of this invention. BRIEF DESCRIPTION OF THE DRAWINGS Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on embodiment of this invention. BRIEF DESCRIPTION OF THE DRAWINGS Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on embodiment of this invention. Side surface sectional drawing which shows the structure of the modification of the heat ray blocking unit which concerns on embodiment of this invention. Side surface sectional drawing which shows the structure of the modification of the heat ray blocking unit which concerns on embodiment of this invention. Side surface sectional drawing which shows the structure of the modification of the heat ray blocking unit which concerns on embodiment of this invention. Side surface sectional drawing which shows the structure of the modification of the heat ray blocking unit which concerns on embodiment of this invention. Side surface sectional drawing which shows the structure of the modification of the heat ray blocking unit which concerns on embodiment of this invention. Side surface sectional drawing which shows the structure of the modification of the heat ray blocking unit which concerns on embodiment of this invention. Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on other embodiment of this invention. Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on other embodiment of this invention. Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on other embodiment of this invention. Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on other embodiment of this invention. Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on other embodiment of this invention. Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on other embodiment of this invention. Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on other embodiment of this invention. Side surface sectional drawing which shows the structure of the heat ray blocking unit which concerns on other embodiment of this invention.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. Each embodiment shown below is an example of a heat ray shielding unit for embodying the technical idea of the present invention, and the technical idea of the present invention is not limited to the following. Absent. The technical concept of the present invention can be variously modified within the technical scope described in the claims.

FIG. 1 is a front view showing a configuration of a heat ray shielding unit according to an embodiment of the present invention. 2 is a cross-sectional view taken along the line A-A of FIG. 1, and FIG. 3 is a cross-sectional view taken along the line B-B of FIG. In addition, below, let the up-down direction of the paper surface of FIG. 1 be the up-down direction of a heat ray blocking unit.
As shown in FIGS. 1 to 3, the heat ray shielding unit 1 includes two rectangular light transmission plates 3a and 3b disposed opposite to each other, and an outer frame member for holding the periphery of the light transmission plates 3a and 3b. It has 2 and. The light transmission plates 3a and 3b are disposed at a predetermined distance by a rectangular parallelepiped spacer 34 provided at an appropriate position between the light transmission plates 3a and 3b, and thereby between the light transmission plates 3a and 3b. A void 41 is provided in the housing. Since the air gap 41 is an air layer, a heat insulating effect can be obtained. The spacer 34 is made of transparent silicon resin or the like, and has high transparency to visible light. In addition, the spacer 34 is not limited to rectangular solid shape, Various shapes, such as cylindrical shape or spherical shape, are employable.

  The distance between the light transmission plates 3a and 3b is appropriately set according to the material, thickness and the like of the light transmission plates 3a and 3b. For example, when the light transmission plates 3a and 3b are float glass and the thickness thereof is 3 mm, the distance between the light transmission plates 3a and 3b is about 1 to 2 times the thickness of the light transmission plates 3a and 3b, that is, 3 mm It is set to about 6 mm. As described later, the distance between the light transmitting plates 3a and 3b can be appropriately adjusted in order to obtain desired heat ray shielding properties and visible light transmittance.

  The light transmitting plates 3a and 3b are made of a material that transmits sunlight, for example, a light transmitting resin plate such as acrylic and polycarbonate, or a glass plate, and have a thickness of about 3 mm to 10 mm. Here, these light transmitting plates 3a and 3b may be made of the same material, or may be made of different materials. For example, when the heat ray shielding unit 1 is installed as a lighting window of a building, the light transmitting plate provided inside the building is a translucent resin plate and is provided outside the building, that is, on the side directly receiving sunlight. It is assumed that the light transmitting plate is a glass plate or the like. In the present embodiment, when the light transmitting plates 3a and 3b are irradiated with sunlight, heat is dissipated by the air gap 41 provided between them. Therefore, even when at least one of the light transmission plates 3a and 3b is formed of a glass plate, it is possible to suppress the occurrence of breakage or the like due to thermal cracking.

  On one surface of the light transmission plates 3a and 3b, a plurality of rectangular grooves which are long in the vertical direction in cross section are extended so as to be parallel to each other along the short side direction of the light transmission plates 3a and 3b The heat ray shielding portion 31 having a low transmittance to the heat ray is embedded in the groove. In the present embodiment, the plurality of strip-shaped heat ray shielding portions 31, 31, ... in the light transmission plate 3a and the plurality of strip-shaped heat ray shielding portions 31, 31, ... in the light transmission plate 3b are provided at the same pitch. There is. However, these may be provided at different pitches.

  Each heat ray shielding portion 31 is formed by filling a dispersion obtained by dispersing transparent conductive metal oxide fine particles in a solvent into the groove and solidifying the groove. Here, antimony tin oxide (ATO) fine particles can be used as the transparent conductive metal oxide fine particles. However, the present invention is not limited thereto, and indium tin oxide (ITO), titanium oxide, aluminum oxide, cerium oxide, hafnium oxide, silicon oxide, zirconium oxide, tantalum oxide, yttrium oxide, tungsten oxide, and the like as main components. Fine particles of metal oxide can be used. In addition, these metal oxides may be used independently, and 2 or more types may be mixed and used.

  The dispersion liquid may contain cellulose nanofibers having a fiber diameter of about 1 to 100 nm. By containing cellulose nanofibers finer than the wavelength of visible light in the dispersion, visible light can be transmitted without being scattered, and the intensity of the heat ray shielding portion 31 can be maintained.

  In the present embodiment, the heat ray shielding portion 31 has a property of reflecting a wavelength within the range of the infrared region (about 780 nm or more) among the wavelengths contained in sunlight. The conductive metal oxide fine particles forming the heat ray shielding portion 31 have an average particle diameter (average value of particle size distribution) to the extent of causing Mie scattering to light in a wavelength region of the range. Mie scattering is the scattering of light that occurs when the particle size is comparable to the wavelength of light (greater than 1/10 of the wavelength of light). In this embodiment, it is assumed that Mie scattering is caused to light having a wavelength of about 780 nm to 2.5 μm, so the average particle diameter of the conductive metal oxide fine particles is about 78 nm to 2.5 μm. It is.

  The light transmitting plates 3a and 3b are disposed such that the surfaces on which the heat ray shielding portions 31 are formed face each other. Thus, the heat ray shielding portion 31 is confined in the heat ray shielding unit 1. In this case, since the heat ray shielding portion 31 is not exposed to the outside, it is possible to avoid the occurrence of a defect such as damage in the heat ray shielding portion 31.

  Note that the plurality of heat ray shielding portions 31, 31, ... may be formed substantially in parallel with each other, and may not be completely formed in parallel.

  As shown in FIG. 3, on the lower end side of the light transmission plate 3a and the upper end side of the light transmission plate 3b, position adjustment members 33, 33 capable of freely changing the height thereof are respectively provided. As a result, the light transmission plate 3a is positioned above the light transmission plate 3b by the height of the position adjustment member 33. Therefore, as shown in FIG. 2 and FIG. 3, in the light transmission plates 3a and 3b, the heat ray shielding portions 31 are shifted by the height of the position adjustment member 33 in the long side direction of the light transmission plates 3a and 3b. It will be done. In the present embodiment, the height of the position adjustment member 33 is about two thirds of the height of the heat ray shielding portion 31, and the heat ray shielding portion 31 of the light transmitting plate 3a and the heat ray shielding portion of the light transmitting plate 3b 31 is shifted so as to overlap approximately one third in the height direction in a front view.

  As described above, although the relative position of the light transmission plates 3a and 3b is adjusted by the position adjustment member 33 in the present embodiment, various known position adjustment mechanisms may be employed other than that. it can. When the light transmission plates 3a and 3b can be fixed by holding the outer frame member 2, the position adjustment member 33 may not be provided.

  FIG. 4A and FIG. 4B are cross-sectional views schematically showing the state of taking in sunlight when it is irradiated with sunlight. In these FIGS. 4A and 4B, sunlight is irradiated from the right to the left toward the paper surface. Among sunlight, visible light passes through the heat ray shielding portion 31, and heat rays are absorbed or reflected by the heat ray shielding portion 31. The dashed arrows in FIGS. 4A and 4B indicate the hot wire.

  As can be seen by comparing FIG. 4A with FIG. 4B, when the incident angle of sunlight is large (FIG. 4A), a large amount of heat rays are generated by the heat ray shielding portion 31 as compared with the case where the incident angle is small (FIG. 4B). It is absorbed or reflected. In other words, when the incident angle of sunlight is small, a large amount of heat rays pass through the light transmission plates 3a and 3b as compared with the case where the incident angle is large. Therefore, relatively many heat rays are blocked in summer when the south middle altitude is high, and a relatively large amount of heat rays pass through the light transmission plates 3a and 3b in the same low winter season. On the other hand, as for visible light, although the amount of light passing through the heat ray shielding part 31 increases in summer compared to winter in summer, although the transmittance slightly decreases, a sufficient amount of light transmission plate is used in summer and winter. Pass 3a and 3b. As a result, it is possible to control the amount of heat rays taken in according to the season while keeping the visible light transmittance high.

  In addition, although the heat ray shielding part 31 has the low transmittance | permeability of a heat ray, it is not zero. Therefore, a part of the heat ray passes through the heat ray shielding portion 31. Of the heat rays that have passed through the heat ray shielding portion 31 of the light transmission plate 3a, a portion that does not collide with the heat ray shielding portion 31 of the light transmission plate 3b passes through the heat ray shielding unit 1, but Much of the portion that collides with the heat ray shielding portion 31 is absorbed or reflected by the heat ray shielding portion 31. That is, in the case of the present embodiment, the heat ray shielding portion 31 of the light transmission plate 3a and the heat ray shielding portion 31 of the light transmission plate 3b function as double shielding regions.

  As described above, in the present embodiment, by relatively shifting the light transmission plates 3a and 3b in the parallel direction of the heat ray shielding portions 31 in each light transmission plate, the heat ray shielding portion 31 and the light transmission in the light transmission plate 3a The heat ray blocking portions 31 of the plate 3b are shifted in the parallel direction. In the case of the heat ray shielding unit 1 shown in FIG. 1, the heat ray shielding portion 31 of the light transmitting plate 3a and the heat ray shielding portion 31 of the light transmitting plate 3b are three minutes in the height direction (parallel direction of the heat ray shielding portion 31) in front view It is shifted to overlap by about 2 degrees. However, this is merely an example, and the amount of deviation is determined at what latitude point the heat ray shielding unit 1 is installed, at what angle it is installed, and how much heat ray shielding property is It is decided appropriately depending on whether it should be realized. That is, since the incident angle of the sun varies depending on the latitude, when it is intended to realize the same heat ray blocking property at a plurality of points having different latitudes, it is necessary to install the light transmission plates 3a and 3b with a shift amount according to the latitudes is there. Further, the installation angle of the heat ray shielding unit 1 differs between, for example, the case where it is installed as a daylighting window on the side of a building and the case where it is installed as a skylight or glass for solar power generation on the roof surface of the building. The preferred amount of deviation of Furthermore, it may differ depending on the application to what extent the heat ray shielding property is required, and it is preferable that the amount of deviation can be appropriately changed according to the application. Thus, since the suitable shift | deviation amount of the heat ray shielding part 31 changes with various factors, in order to respond | correspond to the factor, it is preferable that the said shift amount can be adjusted. Therefore, in the present embodiment, an arbitrary deviation amount is realized by changing the height of the position adjustment member 33. When the height is increased, the light transmission plate 3a is pushed upward by that amount, and the amount of deviation is increased. FIG. 5 is a cross-sectional view showing the configuration of the heat ray shielding unit 1 when the amount of displacement of the heat ray shielding portion 31 is increased as described above. In the example shown in FIG. 5, the heat ray blocking portion 31 of the light transmitting plate 3a and the heat ray blocking portion 31 of the light transmitting plate 3b are shifted to such an extent that there is no overlapping region in front view. In this case, although the transmittance of visible light decreases, the heat ray shielding property can be further enhanced. Further, as shown in FIG. 6, the heat ray shielding portions 31, 31 may be completely overlapped in a front view by making the amount of deviation zero.

  In addition, the displacement amount of the heat ray shielding part 31 may be fixed when manufacturing the heat ray shielding unit 1 in a factory etc. and may not be able to be adjusted after that, and may be adjusted when installed after shipping May be configured.

  As shown in FIG. 1, on the left side of the lower end of the front surface of the light transmitting plate 3a, graduations 32 are printed at predetermined intervals along the long side direction. Further, although not shown, the same scale is printed on the surface of the light transmission plate 3b. By using the scale 32 of the light transmission plates 3a and 3b, accurate position adjustment can be performed. For example, each area is divided into groups according to the height of the latitude, and a suitable shift amount of the heat ray shielding portion 31 is calculated for each group, and the rule of the scale adjustment (the light transmission plate 3a The scale of the scale and which scale of the light transmission plate 3b are to be aligned are specified in advance. And when installing the heat ray blocking unit 1, the height of the position adjustment member 33 is adjusted according to the rule of the scale alignment defined with respect to the group to which the area of the installation location belongs. Thereby, it becomes possible to realize the shift amount of the heat ray shielding portion 31 suitable for each group.

  In the case where the light transmitting plates 3a and 3b are respectively made of materials having different coefficients of thermal expansion, the amount of displacement of the heat ray shielding portion 31 changes when sunlight is irradiated. When the heat absorption amount is large, the amount of displacement becomes large, and as a result, the area for shielding the heat ray is expanded, and the heat ray shielding property is enhanced. As described above, by forming the light transmitting plates 3a and 3b with materials having different coefficients of thermal expansion, it is possible to obtain a heat ray shielding unit capable of self adjusting the heat ray shielding property.

  When the spacer 34 provided between the light transmitting plates 3a and 3b thermally expands, a phenomenon may occur in which the distance between the light transmitting plates 3a and 3b is increased. In this case, when the heat absorption amount is increased, the distance is further expanded, and as a result, the area for shielding the heat ray is expanded in the thickness direction, and the heat ray shielding property can be enhanced. Also by this, it is possible to obtain a heat ray shielding unit capable of self adjusting the heat ray shielding property.

  When the distance between the light transmitting plates 3a and 3b is increased, the distance between the heat ray shielding portion 31 in the light transmitting plate 3a and the heat ray shielding portion 31 in the light transmitting plate 3b is expanded, and Scattered light can easily pass through. Therefore, while maintaining the heat ray shielding property, it is possible to enhance the visible light transmittance. Therefore, when installing the heat ray blocking unit 1 in the place where high visible light transmittance is required, it is desirable to increase the distance between the light transmitting plates 3a and 3b.

  As described above, the heat ray shielding properties and the visible light transmittance may change according to the distance between the light transmitting plates 3a and 3b. Therefore, it is preferable to appropriately set the distance between the light transmission plates 3a and 3b in accordance with the installation place or the application. The setting of the distance can be easily realized by changing the shape of the outer frame material, the size of the spacer, and the like. The control of the heat ray shielding property and the visible light transmission property may be performed by adjusting the shift amount of the heat ray shielding portion 31 as described above, and alternatively or together with the distance between the light transmitting plates 3a and 3b. You may do by adjustment.

(Shape of heat ray blocking part)
In the embodiment described above, the heat ray shielding portion 31 has a rectangular shape which is long in the vertical direction in a cross sectional view, but the shape is not limited to this shape, and various shapes can be adopted. For example, as shown in FIG. 7, the heat ray shielding portion 31 may have a triangular shape in a cross sectional view. Further, as shown in FIG. 8, the heat ray shielding portion 31 may have a substantially semicircular shape in a cross sectional view. In addition, various polygonal shapes or shapes having curves or the like can be used. Even when any shape is adopted, the desired displacement of the heat ray shielding portion 31 can be obtained by adjusting the positions of the light transmission plates 3a and 3b in the same manner as described above. It is possible to control the transmittance and the heat shielding property.

  In addition, each of the light transmitting plates 3a and 3b may have the heat ray shielding portion 31 having a different shape. For example, as shown in FIG. 9, the heat ray blocking portion 31 of the light transmitting plate 3a has a rectangular shape which is long in the vertical direction in cross section, and the heat ray blocking portion 31 of the light transmitting plate 3b is similarly rectangular having a long length in the thickness direction. You may In addition to this, as shown in FIG. 10, even if the heat ray shielding portion 31 of the light transmitting plate 3a has a rectangular shape in a cross sectional view and the heat ray shielding portion 31 of the light transmitting plate 3b has a triangular shape as well. Good. Even in any combination, the desired displacement of the heat ray shielding portion 31 can be obtained by adjusting the positions of the light transmission plates 3a and 3b in the same manner as described above, and the visible light transmittance and It becomes possible to control the heat ray shielding property.

(Intermediate layer)
In the embodiment described above, the air gap 41 is provided as an intermediate layer between the light transmission plates 3a and 3b, but such an intermediate layer may not be provided. FIG. 11 is a cross-sectional view showing the configuration of the heat ray shielding unit when the intermediate layer is not provided as such. As shown in FIG. 11, the light transmission plates 3a and 3b may be in contact with each other. In this case, for example, by sliding the light transmission plate 3a on the surface of the light transmission plate 3b, the position adjustment in the vertical direction can be performed.

  In addition, an intermediate film made of transparent resin or the like may be provided between the light transmission plates 3a and 3b. FIG. 12 is a cross-sectional view showing the configuration of a heat ray shielding unit provided with such an intermediate film. In the example shown in FIG. 12, an intermediate film 42 is provided between the light transmitting plates 3a and 3b. The intermediate film 42 functions as a buffer material and can also function to prevent scattering when the light transmission plates 3a and 3b are broken.

(Production method)
As a method of forming the heat ray shielding part 31 with respect to the light transmissive plates 3a and 3b, various methods can be employed. For example, after a groove is formed on the surface of the light transmitting plates 3a and 3b with a laser, the heat ray shielding portion 31 is formed by filling the groove containing the conductive metal oxide fine particle in the groove and solidifying the groove. Can. Alternatively, the groove may be formed by pattern molding using a press die, a heat roller or the like, and the heat ray shielding portion 31 may be formed by filling the groove and solidifying the dispersion in the same manner.

(Other embodiments)
When the heat ray shielding unit is irradiated with sunlight, a temperature difference may occur between the vicinity of the center and the peripheral portion of the light transmitting plate that constitutes the heat ray shielding unit, and heat cracking may occur. In order to suppress the occurrence of such thermal cracking, it is preferable that a heat radiation countermeasure be taken in the heat ray shielding unit. As one of the measures against heat radiation, it is conceivable to convert the absorbed heat into electric energy and release it using the Seebeck effect. FIG. 13 is a side cross-sectional view showing the configuration of a heat ray shielding unit that enables such thermal energy to be converted into power energy and released. As shown in FIG. 13, in the case of this modification, a linear heat ray shielding portion 32 extending in the vertical direction is provided on the light transmitting plate 3b side, and the heat ray shielding portion 32 makes a plurality of light transmitting plates 3b. The heat ray shielding parts 31, 31, ... are connected. In this case, the heat ray shielding portions 31, 31, ... connected by the heat ray shielding portion 32 function as a thermoelectric element, and between the heat ray shielding portion 31 at high temperature and the heat ray shielding portion 31 at low temperature Current flows to dissipate heat. It should be noted that the heat ray blocking portions 31, 31 ... on the light transmitting plate 3a side may be connected instead of the light transmitting plate 3b as described above, and the heat ray blocking portions 31, 31 of both of the light transmitting plates 3a and 3b , ... may be linked. Moreover, all the heat ray blocking parts 31, 31, ... in the light transmission plate may not be connected, and only a part of them may be connected. That is, at least a part of the heat ray shielding portions 31, 31, ... in at least one of the light transmission plates may be connected.

  In the case where the heat ray shielding portion 31 is configured to include ATO, since the ATO is configured of antimony and tin, it is considered that the above-mentioned Seebeck effect is exhibited by these two types of metals. Similarly, when the heat ray shielding portion 31 is configured to include ITO, since the ITO is configured by indium and tin, it is considered that the above-described Seebeck effect is exhibited by these two types of metals. In order to further enhance the Seebeck effect, it is preferable to include copper, iron, chromel, constantan or the like generally used as a material of a thermocouple in the heat ray shielding portion 31.

  Moreover, in the heat ray blocking unit according to the embodiment described above, the light transmitting plates 3a and 3b are disposed such that the surfaces on which the heat ray blocking portions 31 are formed are opposed to each other. Absent. For example, as shown in FIG. 14, the light transmission plate 3 a may be disposed such that the surface on which the heat ray shielding portion 31 is formed is on the outside. Of course, the light transmission plate 3b may be disposed in the same manner.

  Moreover, although the heat ray blocking unit of embodiment mentioned above is provided with two light transmissive plates, this invention is not necessarily limited to this number, and should just be provided with two or more sheets. For example, as shown in FIG. 15, in addition to the light transmitting plates 3a and 3b, another light transmitting plate 3c may be provided. In this case, by appropriately adjusting the mutual shift amount of the heat ray shielding portions 31 formed in the light transmitting plates 3a to 3c, the visible light transmittance and the heat ray shielding property suitable for the latitude of the installation point, etc. It will be possible to get.

  In the embodiment described above, although the heat ray shielding portion 31 is embedded in the groove provided on the surface of the light transmitting plates 3a and 3b, as shown in FIG. It may be fixed on the surface of the plates 3a, 3b. In this case, as shown in FIG. 17, the above-described intermediate film 42 may be provided between the light transmitting plates 3a and 3b. FIG. 17 shows an example in which an intermediate film 42 is formed by the first intermediate film 42a provided on the light transmission plate 3a side and the second intermediate film 42b provided on the light transmission plate 3b side. . In the case of this configuration, it is possible to adjust the shift amount of the heat ray shielding portion 31 by, for example, integrally adjusting the position of the light transmission plate 3a and the first intermediate film 42a in the vertical direction. When the adhesive which can be stuck is applied to the bonding surface of the first intermediate film 42a and the second intermediate film 42b, the adhesiveness of the first intermediate film 42a and the second intermediate film 42b after position adjustment is It is preferable because it increases. The intermediate film may be formed on only one of the light transmitting plates 3a and 3b.

  Moreover, in each embodiment mentioned above, although light transmissive plate 3a, 3b has comprised the rectangular shape, it is not necessarily limited to this, It is possible to employ | adopt various shapes, such as a square and a circle. Further, the main surfaces of the light transmitting plates 3a and 3b may be flat or curved.

  Moreover, in each embodiment mentioned above, although each heat ray shielding part 31 has comprised the strip | belt shape continuous from one edge part of the short side direction of light transmission plate 3a, 3b to the other edge part, it is the one part It does not matter if it has a discontinuous band shape in which the

  Moreover, although the aspect by which the heat ray blocking unit 1 is independently provided in the opening part of a building etc. is illustrated in each embodiment mentioned above, the heat ray blocking unit 1 is provided so that the existing light collection window etc. may adjoin. It may be In this case, the heat ray shielding unit 1 may be fixed by being attached to the light receiving window or the like.

  Moreover, the suction cups adsorbed to the surface of the light transmission plate may be provided at both ends or one end of the spacer 34 provided between the plurality of light transmission plates in each embodiment described above. By using this suction cup, when the light transmitting plate is moved in the vertical direction, it is possible to fix the light transmitting plate at the position after the movement. In that case, the position adjustment member 33 shown in FIG. 3 may not be provided.

  In each of the embodiments described above, the light transmitting plate is made of a hard material such as an acrylic plate, a polycarbonate plate or a glass plate, but is made of a soft material such as a silicone resin. May be In this case, no gap is provided between the plurality of light transmitting plates, and two of them are directly bonded or bonded via an intermediate film. And these light transmission boards are not pinched by an outer frame material like the case of each embodiment mentioned above, but one light transmission board is used by being bonded together to the existing daylighting window. FIG. 18 to FIG. 20 are side sectional views showing the configuration of the heat ray shielding unit in the case where the light transmitting plate is made of such a soft material. In the example shown in FIG. 18, the heat ray shielding portions 51 are formed in the light transmitting plates 5a and 5b each made of a transparent silicon resin having a thickness of about 1 mm in the same manner as each of the embodiments described above. And the adhesive material which can be stuck is applied to the field where heat ray blocking part 51 is not formed, and after the position adjustment is performed so that the shift amount of heat ray blocking part 51 becomes appropriate, the said faces are pasted The light transmitting plates 5a and 5b are bonded together by being combined. This adhesive material can be attached again, and after the light transmission plate 5a is peeled off from the light transmission plate 5b and readjustment of the shift amount of the heat ray shielding portion 51 is performed, the light transmission plates 5a and 5b are again You can also paste them together. That is, the light transmitting plates 5a and 5b are configured to be attachable and detachable. Moreover, the adhesive material which can be stuck is apply | coated also to the surface of the heat ray blocking part 51 currently formed in the light transmission board 5b, and the heat ray blocking unit is stuck by the existing lightening window etc. by the adhesive material. As a result, the heat ray shielding unit is fixed to the light receiving window, and appropriate heat ray shielding properties and visible light transmittance can be obtained. In this example, although the heat ray blocking portion 51 is formed on the surfaces of the light transmitting plates 5a and 5b, the heat ray blocking portion 51 is formed in the light transmitting plates 5a and 5b as in the example shown in FIG. It may be buried.

  In the example shown in FIG. 19, a plurality of grooves 52 are extended in parallel to the heat ray blocking portion 51 at appropriate places on the bonding surfaces of the light transmitting plates 5a and 5b. When the light transmitting plates 5a and 5b are bonded together, air intrudes into the groove 52, and as a result, the inside of the groove 52 becomes an air layer. Heat dissipation is achieved by this air layer. In addition, when the groove 52 is formed, there is also an advantage that it is not necessary to separately provide an air vent hole or the like when bonding the light transmitting plates 5a and 5b. Although the grooves 52 are formed in both of the light transmitting plates 5a and 5b in this example, they may be formed in only one of them.

  Further, in the example shown in FIG. 20, a transparent intermediate film 53 is provided between the light transmission plates 5a and 5b. The intermediate film 53 is attached to the surface of the light transmission plate 5a on which the heat ray blocking portion 51 is not formed. Then, after the position adjustment is performed so that the displacement amount of the heat ray shielding portion 51 becomes appropriate, the intermediate film 53 is bonded to the surface of the light transmitting plate 5b where the heat ray shielding portion 51 is not formed. A heat shielding unit is configured. A groove 52 is provided in the light transmission plate 5b, and an air layer is formed by the groove 52, so that heat is dissipated.

  As described above, when the light transmitting plate is made of a soft material such as silicon resin, the heat ray shielding unit can be stored in a roll shape, so space saving can be achieved during storage. it can. In addition, workability can be improved, such as facilitating processing to an appropriate size.

  Note that a new embodiment can be obtained by combining the above-described embodiments.

  The heat ray shielding unit of the present invention is useful as, for example, a daylighting window provided in a building or a windshield of a car. In addition, the heat ray shielding method of the present invention is useful as a heat ray shielding method for controlling the amount of heat rays taken in from the light receiving window or the windshield.

DESCRIPTION OF SYMBOLS 1 Heat ray shielding unit 2 Outer frame material 3a, 3b, 3c Light transmission plate 31 Heat ray shielding part 32 Scale 33 Position control member 34 Spacer 41 Air space 42 Intermediate film 5a, 5b Light transmission plate 51 Heat ray shielding part 52 Groove 53 Intermediate film

Claims (12)

A heat ray shielding unit in which a plurality of light transmission plates transmitting sunlight are stacked directly or indirectly,
In each of the light transmitting plates, a plurality of strip-like heat ray shielding portions made of conductive metal oxide particles transparent to visible light are formed in parallel with each other ,
At least one of the plurality of light transmitting plates is configured to be positionally adjustable in the parallel direction of the heat ray shielding portion,
Heat ray shielding unit. The distance between the plurality of light transmission plates is adjustable.
The heat ray blocking unit according to claim 1. An air gap is provided between the plurality of light transmission plates,
The heat ray blocking unit according to claim 1 . The heat ray shielding portion is formed on the surface of each of the plurality of light transmitting plates,
The plurality of light transmission plates are stacked so that the surfaces on which the heat ray blocking portions are formed face each other.
The heat ray blocking unit according to any one of claims 1 to 3. It further comprises a scale for adjusting the position of the light transmission plate,
The heat ray blocking unit according to any one of claims 1 to 4. At least a portion of the plurality of heat ray shielding portions formed on at least one of the plurality of light transmitting plates are connected;
The heat ray blocking unit according to any one of claims 1 to 5. The conductive metal oxide fine particles are at least one selected from the group consisting of ATO fine particles and ITO fine particles.

The heat ray blocking unit according to any one of claims 1 to 6. A plurality of the light transmitting plates are stacked via an intermediate film,
The heat ray blocking unit according to any one of claims 1 to 7. The heat ray shielding portion is formed by filling the conductive metal oxide particles in a plurality of grooves formed on the surface of the light transmitting plate.
The heat ray blocking unit according to any one of claims 1 to 8. The plurality of light transmitting plates are made of materials having different coefficients of thermal expansion,
The heat ray blocking unit according to any one of claims 1 to 9. The plurality of light transmission plates are configured to be attachable and detachable.
The heat ray blocking unit according to claim 1. A heat ray shielding method for shielding a heat ray using a heat ray shielding unit in which a plurality of light transmission plates transmitting sunlight are laminated directly or indirectly.
In each of the light transmitting plates, a plurality of strip-like heat ray shielding portions made of conductive metal oxide particles transparent to visible light are formed in parallel with each other,
Controlling the shielding of the heat rays by adjusting at least one of the plurality of light transmitting plates in the parallel direction of the heat ray shielding units,
Heat shielding method.

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