JP7090280B2 - Sunlight shielding window and building wall structure equipped with it - Google Patents

Description

Patent Law Article 30, Paragraph 2 Applicable Publication date: December 4, 2017 Publication address (1) http: // www. mlit. go. jp / jutakukentiku / house / house / house_house_tk4_000083. html (2) html: // www. mlit. go. jp / jutakukentiku / house / jutakukentiku_house_tk4_000146. html (3) http: // www. mlit. go. jp / common / 001211773. pdf

The present invention relates to a solar shielding window provided with an inner glass and an outer glass, the outer glass of which is made of thermochromic glass, and a building wall structure provided with the same.

Conventionally, a double-glazed window having an indoor (indoor) side glass plate and an outdoor side glass plate arranged on the outdoor (outdoor) side at a distance from the indoor side glass plate has been known. (Refer to Patent Document 1), a thermochromic film is bonded to the glass plate on the outdoor side.

Japanese Unexamined Patent Publication No. 2-289782

By the way, in a double-glazed window as described in Patent Document 1, the hollow layer between the glass plate on the indoor side and the glass plate on the outdoor side is generally sealed to maintain heat insulating properties. In a double-glazed window in which the hollow layer is sealed in this way, the temperature of the hollow layer is kept higher than the temperature of the outside air when the amount of solar radiation is large, and the glass plate on the indoor side receives the heat of the hollow layer and the temperature rises. As the temperature rises, the amount of heat entering the indoor space from the glass plate on the indoor side increases.

An object of the present invention is to provide a solar radiation shielding window capable of suppressing the amount of heat intrusion with respect to the amount of solar radiation, and a building wall structure provided with the window.

The solar radiation shielding window of the present invention is a solar radiation shielding window installed in an opening of a building wall that separates an indoor space and an outdoor space, and includes an inner glass and an outer glass arranged on the outdoor side with respect to the inner glass. The outer glass is made of a thermochromic glass having a characteristic that the amount of transmitted solar radiation transmitted by an increase in glass temperature decreases, while the amount of transmitted solar radiation transmitted by a decrease in glass temperature increases. It is characterized in that a hollow layer communicating with the outdoor space is formed between the inner glass and the outer glass.
According to the solar radiation shielding window of the present invention, the transmitted solar radiation amount can be adjusted by changing the glass temperature of the thermochromic glass, whereby the solar radiation shielding rate with respect to the solar radiation amount can be adjusted. In addition, since the hollow layer formed between the inner glass and the outer glass communicates with the outdoor space, heat can be exhausted from the hollow layer to the outdoor space even when the amount of solar radiation is large, so that the heat of the hollow layer can be reduced. The amount of heat invading the indoor space from the affected inner glass can be suppressed.

In the solar radiation shielding window of the present invention, a heat blocking film that blocks infrared rays may be formed on the indoor surface of the thermochromic glass.
According to such a configuration, the heat blocking film formed on the indoor surface of the thermochromic glass blocks infrared rays transmitted through the entire thermochromic glass by absorption or reflection. For this reason, heat is conducted to the thermochromic glass from the heat blocking film whose film temperature has risen by absorbing infrared rays, and the infrared rays reflected by the heat blocking film are returned to the thermochromic glass again, so that the thermochromic glass can be used. The rise in glass temperature can be promoted. As a result, when the amount of solar radiation from the sun increases and the outside temperature rises, the amount of solar radiation shielded by the outer glass is rapidly increased compared to, for example, thermochromic glass in which a heat blocking film is not formed on the indoor surface. It is possible to suppress the amount of heat invading the indoor space from the solar radiation shielding window.
Further, since infrared rays are blocked by the heat blocking film formed on the indoor surface of the thermochromic glass, it is possible to suppress the temperature rise of the hollow layer and the inner glass located on the indoor side of the heat blocking film.

In the solar radiation shielding window of the present invention, the heat blocking film may be composed of a heat ray absorbing film having a property of transmitting visible light and absorbing infrared rays.
According to such a configuration, the influence of the heat ray absorbing film on the visible light transmitted through the thermochromic glass can be suppressed, and the infrared rays transmitted through the thermochromic glass can be absorbed by the heat ray absorbing film. By absorbing infrared rays in this way, the temperature of the heat ray absorbing film rises, heat is conducted from the heat ray absorbing film to the thermochromic glass, and the temperature rise of the thermochromic glass can be promoted.

In the solar radiation shielding window of the present invention, the infrared transmittance of the heat ray absorbing film may be lower than the infrared transmittance of the thermochromic glass.
According to such a configuration, the infrared rays transmitted through the thermochromic glass can be blocked by the heat ray absorbing film, so that the amount of heat invading from the solar shielding glass into the indoor space can be suppressed.

In the solar radiation shielding window of the present invention, the visible light transmittance of the heat ray absorbing film may be higher than the visible light transmittance of the thermochromic glass.
According to such a configuration, the visible light transmitted through the thermochromic glass can be transmitted to the heat ray absorbing film, and the influence of the heat ray absorbing film on the visible light can be suppressed.

In the solar radiation shielding window of the present invention, the heat shielding film may be composed of a heat ray reflecting film having a property of transmitting visible light and reflecting infrared rays.
According to such a configuration, the influence of the heat ray reflecting film on the visible light transmitted through the thermochromic glass can be suppressed, and the infrared rays transmitted through the thermochromic glass can be reflected by the heat ray reflecting film. By reflecting infrared rays and returning them to the thermochromic glass in this way, it is possible to promote an increase in the glass temperature of the thermochromic glass.

In the solar radiation shielding window of the present invention, the infrared transmittance of the heat ray reflecting film may be lower than the infrared transmittance of the thermochromic glass.
According to such a configuration, infrared rays transmitted through the thermochromic glass can be blocked by the heat ray reflecting film, so that the amount of heat invading from the solar shielding glass into the indoor space can be suppressed.

In the solar radiation shielding window of the present invention, the visible light transmittance of the heat ray reflecting film may be higher than the visible light transmittance of the thermochromic glass.
According to such a configuration, the visible light transmitted through the thermochromic glass can be transmitted to the heat reflecting film, and the influence of the heat ray reflecting film on the visible light can be suppressed.

The building wall structure of the present invention is a building wall structure in which the above-mentioned solar radiation shielding window of the present invention is installed at an opening of the building wall, and the solar radiation is between the building wall and the outer glass of the solar radiation shielding window. A communication port for communicating the hollow layer of the shielding window to the outdoor space is configured, and the outdoor surface of the outer glass is arranged at a position flush with the outer wall surface of the building wall or at a position closer to the indoor side. It is characterized by being done.
According to the building wall structure of the present invention, the gas flow rate flowing from the outdoor space into the hollow layer is suppressed as compared with the case where the outdoor surface of the outer glass is arranged at a position protruding to the outdoor side from the outer wall surface of the building wall, for example. be able to. As a result, the temperature of the hollow layer is excessively lowered, and it is possible to suppress the excessive increase in the amount of transmitted solar radiation transmitted through the thermochromic glass affected by this temperature. The balance with the exhaust heat of the hollow layer can be stabilized, and the solar heat acquisition rate in the indoor space can be reduced.

According to the present invention, it is possible to provide a solar radiation shielding window capable of suppressing the amount of heat intrusion with respect to the amount of solar radiation and a building wall structure provided with the window.

The schematic diagram which shows the solar radiation shielding window which concerns on embodiment of this invention. The graph which shows the spectral transmittance of the solar radiation shielding window which concerns on the said embodiment. The graph which shows the spectral characteristic of the heat-shielding film of the solar-shielding window which concerns on the said embodiment. The graph which shows the relationship between the glass temperature and the amount of solar radiation of the solar radiation shielding window which concerns on the said embodiment. The schematic diagram which shows the arrangement of the thermochromic glass of the solar radiation shielding window which concerns on the said embodiment. The graph which shows the relationship between the glass temperature of the solar radiation shielding window and the solar heat acquisition rate which concerns on the said embodiment.

[Structure of this embodiment]
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In FIG. 1, the solar radiation shielding window 1 according to the present embodiment is composed of a double-glazed window installed in an opening 3 of a building wall 2 separating an indoor space and an outdoor space, and is composed of an inner glass 6 and an inner glass 6. It is provided with an outer glass 7 arranged on the outdoor side. The upper edge, the lower edge, and the left and right vertical edges of the inner glass 6 are attached to the window frame 4 (frame body), and the left and right vertical edges of the outer glass 7 are attached to the window frame 4. The outer glass 7 is arranged at a distance L in the prospective direction with respect to the inner glass 6, whereby a hollow layer 8 is formed between the inner glass 6 and the outer glass 7.

The inner glass 6 is made of a rectangular plate-shaped transparent glass, and the outer glass 7 is a rectangular plate-shaped thermochromic glass 20 and a heat blocking film attached to the indoor surface 22 of the thermochromic glass 20. It is configured as a solar shielding glass provided with a sheet-shaped heat blocking film 30. The heat blocking film 30 is attached to the entire surface of the indoor surface 22 exposed to the hollow layer 8. The outdoor surface 21 of the thermochromic glass 20 is exposed to the outdoor space, and the heat blocking film 30 or the like is not attached.
In FIG. 1, the outdoor surface of the outer glass 7, that is, the outdoor surface 21 of the thermochromic glass 20, is arranged at a position flush with the outer wall surface 2A of the opening 3 of the building wall 2. A communication port 9 for communicating the hollow layer 8 to the outdoor space is formed between the upper and lower edges of the outer glass 7 and the building wall 2, respectively, and two communication ports 9 located above and below the outer glass 7 are formed. The hollow layer 8 can be ventilated by taking in outdoor air from one of the communication ports 9 into the hollow layer 8 and discharging the air from the hollow layer 8 from the other.
Here, if the opening area of the communication port 9 is too large, the amount of heat exhausted from the hollow layer 8 increases, and the glass temperature of the thermochromic glass 20 of the outer glass 7 becomes almost the same as the outside air temperature (outdoor temperature). , The glass temperature of the thermochromic glass 20 is less likely to rise due to the sunlight of the sun 5. On the other hand, if the opening area of the communication port 9 is too small, the amount of heat exhausted from the hollow layer 8 is small, the inner glass 6 receives the heat of the hollow layer 8 and the glass temperature rises, and the amount of heat invading the indoor space increases. It gets bigger. In the present embodiment, the opening area of the communication port 9 is an exhaust heat amount that minimizes the total amount of the heat intrusion amount due to the convective radiation from the solar radiation shielding window 1 to the indoor space and the transmitted solar radiation amount transmitted through the solar radiation shielding window 1. Therefore, it is set in consideration of the relationship with the capacity of the hollow layer 8 and the characteristics of the outer glass 7.

The thermochromic glass 20 is configured by providing a thermochromic layer containing a transition metal oxide such as vanadium dioxide in transparent glass. The thermochromic glass 20 causes a thermochromic phenomenon in which the transmittance of the amount of solar radiation changes due to a change in the glass temperature. It has the property of increasing the amount of transmitted solar radiation. In the present embodiment, the thermochromic glass 20 has a characteristic that the visible light transmittance mainly changes with a change in the glass temperature.

The graph of FIG. 2A shows the spectral transmittance of the thermochromic glass 20. In this graph, the vertical axis is the transmittance (%) of solar radiation, the horizontal axis is the wavelength of solar radiation (nm), and the transmittance when the glass temperature is 20 ° C, 40 ° C, 50 ° C, 70 ° C. The relationship between wavelengths is shown for each line type.
Here, in the present embodiment, the wavelength range of visible radiation has a short wavelength limit of 360 nm to 400 nm and a long wavelength limit of 760 nm to 830 nm, and this wavelength range is defined as the visible light region. Further, as for the wavelength range of infrared radiation, the wavelength range in which the wavelength of the monochromatic light component is longer than the wavelength of visible radiation and the short wavelength limit is 760 nm to 830 nm is defined as the infrared region.

In the graph of FIG. 2A, the visible light transmittance in the visible light region of the thermochromic glass 20 changes more than the infrared transmittance in the infrared region in response to the change in the glass temperature from 20 ° C to 70 ° C. .. Specifically, the change in visible light transmittance is large when the wavelength is about 600 nm in the visible light region, and the visible light transmittance is about 65% at a glass temperature of 20 ° C., while the glass temperature is 70 ° C. In, the visible light transmittance is about 15%, and a change range of the visible light transmittance of about 50% can be seen. On the other hand, when the wavelength is about 1000 nm in the infrared region, the change in infrared transmittance is large, and the infrared transmittance is about 62% at a glass temperature of 20 ° C., while the infrared transmittance is transmitted at a glass temperature of 70 ° C. The rate is about 47%, and a change in infrared transmittance of about 15% is observed. As described above, the visible light transmittance changes by about 50% in response to the change in the glass temperature of the thermochromic glass 20 from 20 ° C to 70 ° C, while the infrared transmittance changes by only about 15%.

Further, in the graph of FIG. 2A, when the glass temperature of the thermochromic glass 20 is 20 ° C., the wavelength in the visible light region is about 800 nm and the visible light transmittance is about 73%, whereas the wavelength in the infrared region is about 73%. The infrared transmittance is about 70% at about 1600 nm. From this, when the glass temperature is lowered, the visible light transmittance and the infrared transmittance of the thermochromic glass 20 are about the same (including a difference of several percent). On the other hand, when the glass temperature of the thermochromic glass 20 is 70 ° C., the visible light transmittance is about 15% at a wavelength of about 600 nm in the visible light region, whereas the infrared transmittance is about 31% at a wavelength of about 1700 nm in the infrared region. Is. From this, when the glass temperature rises, the visible light transmittance of the thermochromic glass 20 becomes lower than the infrared transmittance.

The heat blocking film 30 is mainly composed of a sheet-shaped heat ray absorbing film as a heat ray absorbing film having a property of absorbing infrared rays (heat rays).
The heat ray absorbing film has a structure in which a resin film such as polyester is laminated, but may not have the above structure as long as it has a structure capable of exhibiting the above-mentioned characteristics and the later-described characteristics.

The graph of FIG. 3A shows the spectral characteristics of the heat ray absorbing film. In this graph, the vertical axis is the transmittance / absorption rate (%) of solar radiation, the horizontal axis is the wavelength of solar radiation (nm), and the relationship between the transmittance and wavelength of the heat ray absorbing film is shown by a solid line. The relationship between the transmittance of the absorbent film and the wavelength is shown by a dotted line.
In the graph of FIG. 3A, it can be seen that the heat ray-absorbing film has a property of absorbing a large amount of infrared rays and not transmitting much, while transmitting visible light without absorbing much. Further, the visible light transmittance of the heat ray absorbing film is higher than the visible light transmittance of the thermochromic glass 20, and the infrared transmittance of the heat ray absorbing film is lower than the infrared light transmittance of the thermochromic glass 20. You can see that there is.

The graph of FIG. 2B shows the spectral transmittance of the outer glass 7 of the present embodiment in which a heat ray absorbing film is attached as a heat blocking film 30 to the indoor surface 22 of the thermochromic glass 20. In this graph, the vertical axis is the transmittance (%) of solar radiation, the horizontal axis is the wavelength of solar radiation (nm), and the transmittance when the glass temperature is 20 ° C, 40 ° C, 50 ° C, 70 ° C. The relationship between wavelengths is shown for each line type.
In the graph of FIG. 2 (B), the change range of the visible light transmittance of the solar shielding glass 10 is the same as the change range of the visible light transmittance of the thermochromic glass 20 shown in the graph of FIG. 2 (A). It can be seen that the range of change above the degree is maintained. Further, since the visible light transmittance in the graph of FIG. 2 (B) is suppressed to a decrease of about 10% as compared with the visible light transmittance in the graph of FIG. 2 (A), the thermochromic glass 20 is used. It can be seen that even if the heat ray absorbing film is attached to the indoor surface 22, the influence on the visible light transmittance of the outer glass 7 is small.
On the other hand, in the graph of FIG. 2 (B), the infrared transmittance of the outer glass 7 is significantly lower than the infrared transmittance of the thermochromic glass 20 shown in the graph of FIG. 2 (A). It is presumed that the reduced transmittance is absorbed by the heat ray absorbing film, the film temperature of the heat ray absorbing film rises, and heat is conducted to the thermochromic glass 20.

The outer glass 7 having a heat ray absorbing film as a heat blocking film 30 attached to the indoor surface 22 of the thermochromic glass 20 acts as follows. Here, it is assumed that the outside air temperature (outdoor temperature) is higher than the room temperature (indoor temperature).
As shown in FIG. 1, when the thermochromic glass 20 receives solar radiation from the sun 5, the thermochromic glass 20 transmits visible light and infrared rays according to its transmittance and directly absorbs infrared rays that are not transmitted.
Next, when the heat ray absorbing film receives the solar radiation transmitted through the thermochromic glass 20, the heat ray absorbing film transmits visible light and absorbs infrared rays according to its transmittance. Visible light transmitted through the heat ray absorbing film is incident on the indoor space, but infrared rays are absorbed by the heat ray absorbing film and hardly incident on the indoor space. Therefore, the amount of solar radiation received by the outer glass 7 (window surface solar radiation received by the outdoor surface 21). The rate of heat penetration into the indoor space relative to the amount) is kept low. Further, since the film temperature of the heat ray absorbing film rises due to the absorbed infrared rays, when the film temperature becomes higher than the glass temperature of the thermochromic glass 20, heat conduction is promoted to promote the rise of the glass temperature.

When the amount of solar radiation on the window surface 21 received by the outdoor surface 21 of the outer glass 7 increases as the solar radiation from the sun 5 increases, the glass temperature of the thermochromic glass 20 directly absorbs the solar radiation and conducts heat from the heat ray absorbing film. It rises rapidly by acquiring heat. Therefore, the visible light transmittance of the thermochromic glass 20 rapidly decreases, and the visible light shielding rate increases. Further, when the solar radiation from the sun 5 is weakened and the amount of solar radiation on the window surface 21 received by the outdoor surface 21 of the outer glass 7 is reduced, the amount of the thermochromic glass 20 directly absorbing the solar radiation is reduced and the heat ray absorbing film is used. The amount of heat acquired is also reduced, and the glass temperature of the thermochromic glass 20 is lowered. Therefore, the visible light transmittance of the thermochromic glass 20 is high, and the visible light shielding rate is low. In this way, the solar radiation shielding window 1 shields solar radiation according to the amount of solar radiation.

The graph of FIG. 4 shows the relationship between the amount of solar radiation (W / m ² ) on the window surface and the glass temperature (° C.) received by the outdoor surface 21 of the outer glass 7 as described above under an outside temperature of 30 ° C. and a room temperature of 25 ° C. The relationship between the amount of solar radiation on the window surface (W / m ² ) and the glass temperature (° C.) in the thermochromic glass 20 alone to which the heat blocking film 30 is not attached is shown.
The glass temperature of the thermochromic glass 20 alone rises from about 30 ° C. to about 46 ° C. while the amount of solar radiation on the window surface increases from 100 W / m ² to 900 W / m ² . On the other hand, the glass temperature of the outer glass 7 (thermochromic glass 20 + heat ray absorbing film) increased from about 31 ° C to about 55 ° C while the amount of solar radiation on the window surface increased from 100 W / m ² to 900 W / m ² . Ascend to. From this, it can be seen that the rate of increase in the glass temperature with respect to the amount of solar radiation on the window surface is higher in the outer glass 7 than in the thermochromic glass 20 alone.

FIG. 5 schematically shows one in which the distance L between the inner glass 6 and the outer glass 7 in the solar radiation shielding window 1 is set to 100 mm and 30 mm, and one in which the hollow layer 8 is sealed. Here, the one in which the distance L is set to 100 mm as shown in FIG. 5 (A) is referred to as the solar radiation shielding window 1A, and the one in which the distance L is set to 30 mm as shown in FIG. 5 (B) is referred to as the solar radiation shielding window 1B. As shown in FIG. 5 (C), the hollow layer 8 sealed (distance L is 12 mm) is referred to as a solar radiation shielding window 1C. In the solar radiation shielding window 1A, the outer glass 7 is located on the outdoor side of the outer wall surface 2A, and in this case, the outer glass 7 is outdoors as compared with the case where the outer glass 7 is on the indoor side of the outer wall surface 2A. Convection heat transfer increases because it is susceptible to the wind. In the solar radiation shielding window 1B, the outer glass 7 is located on the indoor side of the outer wall surface 2A. The solar radiation shielding window 1C without the communication port 9 is given as a reference for comparison with the solar radiation shielding windows 1A and 1B having the communication port 9.
The graph of FIG. 6 shows the relationship between the solar heat acquisition rate (%) and the glass temperature (° C.) when the above-mentioned solar radiation shielding windows 1A to 1C are installed in the openings 3 of the building wall 2, respectively. The solar heat acquisition rate is the heat acquisition rate of the indoor space with respect to the window surface solar radiation amount (solation amount) received by the outdoor surface 21 of the outer glass 7, and the glass temperature is the temperature of the thermochromic glass 20 of the outer glass 7. Assuming summer conditions, the environmental conditions were an outside air temperature of 35 ° C., a room temperature of 25 ° C., a window surface solar radiation of 800 W / m ² , and a window size of 2 m in vertical dimension and 1 m in width dimension.
In the graph of FIG. 6, the glass temperature of the solar radiation shielding window 1A having a distance L of 100 mm is between 45 ° C. and 50 ° C., whereas the glass temperature of the solar radiation shielding window 1B having a distance L of 30 mm is 55. It is between ° C. and 60 ° C., which is higher than the glass temperature of the solar radiation shielding window 1A. Further, the solar heat acquisition rate of the solar shielding windows 1A and 1B is lower than 30%, and the solar heat acquisition rate of the solar shielding window 1B is further lower than the solar heat acquisition rate of the solar shielding window 1A. On the other hand, the glass temperature of the solar shielding window 1C in which the hollow layer 8 is sealed is between 60 ° C. and 65 ° C., and the solar heat acquisition rate is higher than 30%. Is higher than the glass temperature and the solar heat acquisition rate of the solar shielding windows 1A and 1B.
From this, it can be seen that in the solar shielding windows 1A and 1B having the communication port 9, heat intrusion into the indoor space is suppressed by the exhaust heat of the hollow layer 8 into the outdoor space. Further, the solar radiation shielding window 1B has a smaller amount of transmitted solar radiation because the glass temperature of the thermochromic glass 20 is higher than that of the solar radiation shielding window 1A. As a result of the decrease in the total amount of solar radiation, it can be seen that the solar heat acquisition rate is low.

In the above solar radiation shielding window 1, the heat blocking film 30 attached to the indoor surface 22 of the thermochromic glass 20 has been described as a heat ray absorbing film, but it is not a heat ray absorbing film but a heat ray having a property of mainly reflecting infrared rays. A sheet-shaped heat ray reflecting film as a reflective film may be used.
The heat ray reflecting film has a structure in which a resin film such as polyester is laminated, but may not have the above structure as long as it has a structure capable of exhibiting the above-mentioned characteristics and the later-described characteristics.

The graph of FIG. 3B shows the spectral characteristics of the heat ray reflecting film. In this graph, the vertical axis is the transmittance / reflectance (%) of solar radiation, the horizontal axis is the wavelength of solar radiation (nm), and the relationship between the transmittance and wavelength of the heat ray reflective film is shown by a solid line. The relationship between the reflectance of the reflective film and the wavelength is shown by a dotted line.
In the graph of FIG. 3B, it can be seen that the heat ray reflecting film has a characteristic that visible light is transmitted without being reflected so much, while infrared light is reflected so much that it is not transmitted so much. Further, it can be seen that the visible light transmittance of the heat ray reflecting film is lower than the infrared transmittance of the thermochromic glass 20.

The solar radiation shielding window 1 to which the outer glass 7 having the heat ray reflecting film attached as the heat shielding film 30 on the indoor surface 22 of the thermochromic glass 20 is attached to the window frame 4 acts as follows. Here, it is assumed that the outside air temperature is higher than the room temperature.
As shown in FIG. 1, when the thermochromic glass 20 receives solar radiation from the sun 5, the thermochromic glass 20 transmits visible light and infrared rays according to its transmittance and directly absorbs infrared rays that are not transmitted.
Next, when the heat ray reflecting film receives the solar radiation transmitted through the thermochromic glass 20, the heat ray reflecting film transmits visible light and reflects infrared rays according to its transmittance. Visible light transmitted through the heat ray reflecting film is incident on the indoor space, but infrared rays are reflected by the heat ray reflecting film and the amount of incident on the indoor space is small. The heat penetration rate is kept low. Further, the infrared rays reflected by the heat ray reflecting film are returned to the thermochromic glass 20 again, and the thermochromic glass 20 absorbs the reflected infrared rays, so that the increase in the glass temperature of the thermochromic glass 20 is promoted.

When the solar radiation from the sun 5 increases and the amount of solar radiation on the window surface 21 received by the outdoor surface 21 of the outer glass 7 increases, the glass temperature of the thermochromic glass 20 directly absorbs the solar radiation and is reflected by the heat ray reflecting film. It rises rapidly by absorbing the emitted infrared rays. Therefore, the visible light transmittance of the thermochromic glass 20 rapidly decreases, and the visible light shielding rate increases. Further, when the solar radiation from the sun 5 is weakened and the amount of solar radiation on the window surface 21 received by the outdoor surface 21 of the outer glass 7 is reduced, the amount of the thermochromic glass 20 directly absorbing the solar radiation is reduced and the heat ray reflecting film is formed. The amount of reflected infrared rays is also reduced, and the glass temperature of the thermochromic glass 20 is lowered. Therefore, the visible light transmittance of the thermochromic glass 20 is high, and the visible light shielding rate is low. In this way, the solar radiation shielding window 1 shields solar radiation according to the amount of solar radiation.

[Effect of this embodiment]
(1) In the present embodiment, the solar radiation shielding window 1 includes an inner glass 6 and an outer glass 7, and the outer glass 7 reduces the amount of transmitted solar radiation transmitted by an increase in the glass temperature, while lowering the glass temperature. It is composed of a thermochromic glass 20 having a property of increasing the amount of transmitted solar radiation transmitted by the glass, and a hollow layer 8 communicating with the outdoor space is formed between the inner glass 6 and the outer glass 7. It is characterized by. Since it has the above configuration, the transmitted solar radiation amount can be adjusted by changing the glass temperature of the thermochromic glass 20, and thereby the solar radiation shielding rate with respect to the solar radiation amount can be adjusted. Further, since the hollow layer 8 formed between the inner glass 6 and the outer glass 7 communicates with the outdoor space, heat can be exhausted from the hollow layer 8 to the outdoor space even when the amount of solar radiation is large, so that the hollow layer 8 is hollow. The amount of heat invading the indoor space from the inner glass 6 affected by the heat of the layer 8 can be suppressed.
(2) By attaching the heat blocking film 30 to the indoor surface 22 of the thermochromic glass 20, the heat blocking film 30 can block infrared rays transmitted through the entire thermochromic glass 20 by absorption or reflection, and is absorbed or reflected. It is possible to promote an increase in the glass temperature of the thermochromic glass 20 by utilizing the infrared rays. As a result, when the amount of solar radiation of the sun 5 increases, the amount of solar radiation shielded by the outer glass 7 can be quickly increased, and the amount of heat invading from the outer glass 7 into the indoor space can be suppressed.
(3) When the heat blocking film 30 is composed of a heat ray absorbing film having a property of transmitting visible light and absorbing infrared rays, it is possible to suppress the influence of the heat ray absorbing film on the visible light transmitted through the thermochromic glass 20. At the same time, the infrared rays transmitted through the thermochromic glass 20 can be absorbed by the heat ray absorbing film, and the increase in the glass temperature of the thermochromic glass 20 can be promoted.
(4) Since the infrared transmittance of the heat ray absorbing film is lower than the infrared transmittance of the thermochromic glass 20, the infrared rays transmitted through the thermochromic glass 20 can be blocked by the heat ray absorbing film, and the outer glass 7 can be moved to the indoor space. The amount of heat intrusion can be suppressed.
(5) Since the visible light transmittance of the heat ray absorbing film is higher than the visible light transmittance of the thermochromic glass 20, the visible light transmitted through the thermochromic glass 20 can also be transmitted to the heat ray absorbing film. The influence of the heat ray absorbing film on visible light can be suppressed.
(6) When the heat blocking film 30 is composed of a heat ray reflecting film having a property of transmitting visible light and reflecting infrared light, it is possible to suppress the influence of the heat ray reflecting film on the visible light transmitted through the thermochromic glass 20. At the same time, the infrared rays transmitted through the thermochromic glass 20 can be reflected by the heat ray reflecting film, and the increase in the glass temperature of the thermochromic glass 20 can be promoted.
(7) Since the infrared transmittance of the heat ray reflecting film is lower than the infrared transmittance of the thermochromic glass 20, the infrared rays transmitted through the thermochromic glass 20 can be blocked by the heat ray reflecting film, and the outer glass 7 can be moved to the indoor space. The amount of heat intrusion can be suppressed.
(8) Since the visible light transmittance of the heat ray reflecting film is higher than the visible light transmittance of the thermochromic glass 20, the visible light transmitted through the thermochromic glass 20 can also be transmitted to the heat reflecting film. The influence of the heat ray reflecting film on visible light can be suppressed.
(9) Since the outdoor surface 21 of the outer glass 7 is arranged at a position flush with the outer wall surface 2A and the solar radiation shielding window 1 is installed in the opening 3 of the building wall 2, the building wall structure is configured. For example, compared to the case where the outdoor surface 21 of the outer glass 7 is arranged at a position protruding to the outdoor side of the outer wall surface 2A of the building wall 2, the outer glass 7 can be configured to be less affected by the outdoor wind, and is outdoors. It is possible to suppress an excessive flow of gas flowing from the space into the hollow layer 8. As a result, the temperature of the hollow layer 8 can be suppressed from being excessively lowered, and the amount of transmitted solar radiation transmitted through the thermochromic glass 20 affected by this temperature can be suppressed from becoming excessively large, and the transmission transmitted through the solar radiation shielding window 1 can be suppressed. The balance between the amount of solar radiation and the exhaust heat of the hollow layer 8 can be stabilized, and the solar heat acquisition rate in the indoor space can be reduced.

[Modification example]
In the above embodiment, the communication ports 9 are formed vertically with respect to the outer glass 7, but it may be formed so that the hollow layer 8 can be ventilated so as to be able to exhaust heat. One or more communication ports 9 may be formed side by side on only one side, and one or more communication ports 9 may be formed side by side between the vertical side edge of the outer glass 7 and the building wall 2. You may.
Further, the communication port 9 may be provided with an opening / closing lid for opening / closing the communication port 9. In this case, for example, in winter when the outside air temperature is low and the room temperature is high, the communication port 9 is closed by the opening / closing lid. The heat insulating property of the hollow layer 8 may be enhanced.
In the above embodiment, the outdoor surface 21 of the outer glass 7 is arranged at a position flush with the outer wall surface 2A in FIG. 1, but as shown in FIG. 5B, for example, with respect to the outer wall surface 2A. The outer glass 7 may be arranged at a position closer to the indoor side, and even in this case, the outer glass 7 can be configured to be less susceptible to outdoor wind. Further, when the glass temperature of the thermochromic glass 20 and the amount of exhaust heat of the hollow layer 8 can be kept within an appropriate range, the outer glass 7 is arranged on the outdoor side with respect to the outer wall surface 2A as shown in FIG. 5 (A). You may.
In the above embodiment, the heat blocking film 30 is attached to the indoor surface 22 of the thermochromic glass 20 of the outer glass 7, but it is necessary to heat block infrared rays by the heat blocking film 30, and the glass of the thermochromic glass 20. If it is not necessary to promote the increase in temperature, the configuration of the heat blocking film 30 may be omitted.
In the above embodiment, the heat ray absorbing film has the spectral characteristics shown in FIG. 2 (A), but is not limited to these characteristics, and can transmit visible light and raise the glass temperature of the thermochromic glass 20. It suffices to have the property of absorbing infrared rays. Further, in the above embodiment, the heat ray reflecting film has the spectral characteristics shown in FIG. 2 (B), but is not limited to these characteristics, it transmits visible light and raises the glass temperature of the thermochromic glass 20. It suffices to have the property of reflecting infrared rays to the extent possible.
In the above embodiment, the heat ray absorbing film has a higher visible light transmittance than the visible light transmittance of the thermochromic glass 20, but may be about the same. Further, in the above embodiment, the visible light transmittance of the heat ray reflecting film is higher than that of the thermochromic glass 20, but it may be about the same.
In the above embodiment, since the heat-shielding film 30 is attached to the indoor surface 22 of the thermochromic glass 20, the characteristics of the solar-shielding glass 10 can be adjusted or changed by replacing the heat-shielding film 30 with another heat-shielding film 30. For example, the heat ray reflecting film can be replaced with a heat ray absorbing film.
In the above embodiment, the heat blocking film 30 is attached to the entire surface of the indoor surface 22 exposed to the hollow layer 8, but may be partially attached, for example, considering the incident angle of solar radiation. Then, it may be attached to the upper and lower halves of the thermochromic glass 20 or the like.
In the above embodiment, the heat-shielding film 30 is attached to the indoor surface 22 of the thermochromic glass 20, but the present invention is not limited to this, and a heat-shielding film formed by sputtering or the like may be used.
The solar radiation shielding window 1 according to the embodiment is configured as a double-glazed window provided with an inner glass 6 and an outer glass 7. For example, the inner glass 6 and the outer glass 7 are immovable to a frame material such as a window frame 4. It may be a fixed window (FIX window) fixed to the window, or may be various windows in which the inner glass 6 and the outer glass 7 are attached to a frame material such as a window frame 4 so as to be openable and closable. When the window provided with the outer glass 7 is composed of a window that can be opened and closed such as a sliding window, the communication port is formed by opening the window so as to have an opening area suitable for exhausting heat of the hollow layer 8. You may. Further, the solar radiation shielding window 1 may be configured by arranging an outer glass 7 having a thermochromic glass 20 on the outdoor side of the existing window and forming a hollow layer 8 communicating with the outdoor space.

1 (1A-1C) ... Solar shielding window, 2 ... Building wall, 2A ... Outer wall surface, 20 ... Thermochromic glass, 21 ... Outdoor surface, 22 ... Indoor surface, 3 ... Opening, 30 ... Heat blocking film, 4 ... Window Frame (frame body), 5 ... Sun, 6 ... Inner glass, 7 ... Outer glass, 8 ... Hollow layer, 9 ... Communication port, L ... Distance.

Claims (8)

It is a solar shielding window installed in the opening of the building wall that separates the indoor space and the outdoor space.
It is provided with an inner glass and an outer glass arranged on the outdoor side with respect to the inner glass.
The outer glass is made of a thermochromic glass having a characteristic that the amount of transmitted solar radiation transmitted by an increase in glass temperature decreases, while the amount of transmitted solar radiation transmitted by a decrease in glass temperature increases.
A hollow layer communicating with the outdoor space is formed between the inner glass and the outer glass .
A heat blocking film that blocks infrared rays is formed on the indoor surface of the thermochromic glass.
The outdoor surface of the thermochromic glass is exposed and arranged on the outdoor side.
The thermochromic glass transmits infrared rays according to its infrared transmittance and directly absorbs infrared rays that are not transmitted.
A solar-shielding window that features that. In the solar shielding window according to claim 1 ,
The solar shielding window is characterized in that the heat blocking film is composed of a heat ray absorbing film having a property of transmitting visible light and absorbing infrared rays. In the solar shielding window according to claim 2 ,
A solar shielding window characterized in that the infrared transmittance of the heat ray absorbing film is lower than the infrared transmittance of the thermochromic glass. In the solar shielding window according to claim 2 or 3 .
A solar shielding window characterized in that the visible light transmittance of the heat ray absorbing film is higher than the visible light transmittance of the thermochromic glass. In the solar shielding window according to claim 1 ,
The solar shielding window is characterized in that the heat blocking film is composed of a heat ray reflecting film having a property of transmitting visible light and reflecting infrared rays. In the solar shielding window according to claim 5 ,
A solar shielding window characterized in that the infrared transmittance of the heat ray reflecting film is lower than the infrared transmittance of the thermochromic glass. In the solar shielding window according to claim 5 or 6 .
A solar shielding window characterized in that the visible light transmittance of the heat ray reflecting film is higher than the visible light transmittance of the thermochromic glass. The building wall structure in which the solar radiation shielding window according to any one of claims 1 to 7 is installed at an opening of the building wall.
Between the building wall and the outer glass of the solar shielding window, a communication port for communicating the hollow layer of the solar shielding window to the outdoor space is configured.
A building wall structure characterized in that the outdoor surface of the outer glass is arranged at a position flush with or closer to the indoor side with respect to the outer wall surface of the building wall.

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