JPH05147983A - Light transmittance variable glass - Google Patents

Abstract

PURPOSE:To provide the light transmittance variable glass which is automatically adjustable in light transmittance, is relatively easy in formation to a larger area and reduces electric power consumption. CONSTITUTION:The adequate transmittance Cn of the EC glass corresponding to a read solar battery output Vn is calculated (S100, S110). The adequate transmittance Cn of this time and the previously calculated adequate transmittance Cn-1 are compared. (S120). A specified positive voltage is impressed for the prescribed time t to the EC glass (S130, S140) to supply the prescribed quantity of electricity to the EC glass in order to increase the density of the EC glass when the adequate transmittance Cn of this time is smaller than the adequate transmittance Cn-1 of the previous time. On the other hand, a specified negative voltage is impressed (S150, S160) to the EC glass for the prescribed time t in order to decrease the coloration of the EC glass when the adequate transmittance Cn of this time is larger than the adequate transmittance Cn-1 of the previous time. There is no need for the impression of the voltage when the two adequate transmittances Cn and Cn-1 are equal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable light transmittance glass which can adjust the transmittance of sunlight into a room and is used as a light control glass such as a window glass.

[0002]

2. Description of the Related Art Conventionally, a liquid crystal blind glass in which a solar cell and a liquid crystal element are combined, as disclosed in, for example, Japanese Patent Application Laid-Open No. 62-115416, has been used to adjust the transmittance of sunlight into the room. is there. This is because a liquid crystal element is sandwiched between two plate glasses on which electrodes are formed by a transparent conductive film, and a solar cell is arranged around these plate glasses so that the liquid crystal element and the solar cell are separated by a transparent conductive film. It is electrically connected. Then, depending on the magnitude of the applied voltage, each state of opaque, semitransparent, and transparent is obtained, and the transmittance is adjusted and used.

[0003]

However, since a liquid crystal element is used, a semitransparent or opaque state cannot be maintained unless a voltage is applied, and power is always required. Also, since it is difficult to increase the area of one liquid crystal element, it is necessary to prepare multiple liquid crystal elements for use in window glass, etc., and to supply the voltage from the solar cell to each liquid crystal element. It becomes necessary to prepare electrodes for doing so. Further, depending on the type of liquid crystal, there is a disadvantage that the optical anisotropic property changes depending on the direction of the molecular alignment.

Therefore, the present invention has an object to solve the above-mentioned problems, and it is possible to automatically adjust the transmittance of sunlight to the indoor side, etc., and it is relatively easy to increase the area and the power consumption is high. It is to provide a glass having a small light transmittance.

[0005]

In order to achieve such an object, the present invention has the following constitution as a means for solving the problem. That is, as shown in FIG. 1 (a), the variable light transmittance glass according to claim 1 is an electrochromic glass that causes a reversible change in light transmittance by being attached and decolored by applying a voltage. A solar cell electrically connected to the electrochromic glass, and based on the output of the solar cell, the amount of electricity supplied from the solar cell to the electrochromic glass is controlled, and the light transmittance of the electrochromic glass is controlled. And an electric quantity control means for changing the electric quantity.

Further, the variable light transmittance glass according to claim 2 is, in addition to the one described in claim 1, as shown in FIG. Further, it is characterized by comprising a proper transmittance calculating means for calculating a proper transmittance of the electrochromic glass, and the electric quantity control means controls the electric quantity based on the calculated proper transmittance.

The variable light transmittance glass according to claim 3 is an optical sensor for detecting light transmitted through the electrochromic glass, in addition to the glass according to claim 2, as shown in FIG. 1 (c). And based on the output of the optical sensor,
An actual transmittance calculating unit for calculating an actual transmittance of the electrochromic glass is provided, and the electric amount control unit controls the electric amount so that the calculated actual transmittance becomes the proper transmittance. Characterize.

[0008]

According to the variable light transmittance glass according to claim 1 configured as described above, the output of the solar cell changes according to the amount of solar radiation, and the electric quantity control means changes the output of the solar cell. Based on this, the amount of electricity supplied from the solar cell to the electrochromic glass is controlled. The electrochromic glass is attached and decolored according to the supplied amount of electricity, and the light transmittance changes. Also, since electrochromic glass is used, it is relatively easy to increase the area, and
Once the predetermined transmittance is reached, the power consumption is low because the degree of coloring of electrochromic glass is constant and the transmittance does not change even if voltage is not applied, unless it is necessary to increase or decrease the transmittance. End

According to the variable light transmittance glass of the second aspect, the appropriate transmittance calculating means calculates the appropriate transmittance of the electrochromic glass according to the output of the solar cell based on the output of the solar cell. Then, the amount control means controls the amount of electricity supplied to the electrochromic glass based on the calculated appropriate transmittance, so that the transmittance of the electrochromic glass is adjusted to an appropriate value according to the amount of solar radiation at that time. can do.

Further, according to the variable light transmittance glass of the third aspect, the light sensor detects light transmitted through the electrochromic glass, and based on the output of the light sensor, the actual transmittance calculating means is electrochromic. Calculate the actual transmission of the glass. Then, the electricity amount control means controls the electricity amount supplied to the electrochromic glass so that the calculated actual transmittance becomes the proper transmittance calculated by the proper transmittance calculating means. Therefore,
The actual transmittance that changes as the electrochromic glass is worn and decolored can be accurately grasped, and if feedback control is performed so that the actual transmittance becomes an appropriate transmittance, more accurate control becomes possible.

[0011]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 2 is an explanatory diagram showing the overall structure of the variable light transmittance glass of the first embodiment of the present invention. The variable light transmittance glass includes an electrochromic glass (hereinafter simply referred to as EC glass) 1, a solar cell 3, a storage battery 5, and a control device 7.

In the EC glass 1, a colored layer 11 and an electrolyte layer 13 are arranged in the center, both layers 11 and 13 are sandwiched from both sides by a transparent conductive film 15, and they are further sandwiched between two sheets of glass 17. It is sandwiched. As the colored layer 11, for example, a WO ₃ film or the like is used, and when a voltage is applied to the transparent conductive film 15, a redox reaction occurs between the WO ₃ film which is the colored layer 11 and the electrolyte layer 13. For example, when a positive voltage is applied, tungsten bronze is formed to color the colored layer 11 blue, and the color becomes darker according to the amount of electricity supplied. Conversely, when a negative voltage is applied, the amount of tungsten bronze decreases according to the amount of electricity supplied, the color becomes lighter, and finally the color disappears.

As the material of the colored layer 11, IrO ₃ , MoO ₃ , a rare earth-phthalocyanine complex, etc. may be used in addition to the above WO ₃ . Also, the EC glass 1 itself
The configuration is not limited to the above as long as the same electchromic effect can be obtained. The electric power generated by the solar cell 3 is temporarily stored in the storage battery 5, and the transparent conductive film 15 of the EC glass 1 is subjected to predetermined control described later via the control device 7.
Is configured to be supplied to. Further, a diode 9 that prevents a current from flowing backward from the storage battery 5 to the solar cell 3 is interposed between the solar cell 3 and the storage battery 5.

FIG. 2 is a schematic diagram of the case where the variable light transmittance glass of this embodiment is used for a sunroof 21 of an automobile 20. As shown in FIG. 2A, the sunroof 21
EC glass 1 is arranged in the center of the solar cell 3, and solar cells 3 are arranged on both sides thereof. As shown in FIG. 2B, a storage battery 5 and a control device 7 are installed below the solar cell 3.

The respective parts are connected as shown in FIG. 2, and are further compactly housed in the sunroof 21 alone. Next, the operation of the first embodiment will be described with reference to the flow charts of FIGS. When the amount of solar radiation changes, the output from the solar cell 3 also changes correspondingly. FIG. 4A shows an example of an output that changes with time.

In this embodiment, every fixed time (t1, t2,
At t3, ..., The supplied electricity amount control process shown in FIG. 5 is performed. First, the output Vn of the solar cell 3 is read (step 100, hereinafter simply referred to as S100. The same applies hereinafter), and the appropriate transmittance Cn of the EC glass 1 corresponding to the solar cell output Vn is calculated (S110).

The correspondence relationship between the solar cell output Vn and the proper transmittance Cn is shown in FIG.
It is obtained as shown in (b) and is stored in a memory (not shown) in the control device 7. That is, since the solar cell output Vn is almost proportional to the amount of solar radiation, the solar cell output Vn
The correspondence is set so that the higher the n, the lower the appropriate transmittance of the EC glass 1. In S110, based on this correspondence, the appropriate transmittance Cn corresponding to the solar cell output Vn read in S100 is obtained. As shown in the figure, the appropriate transmittances C1, C2 and C3 are determined according to the outputs V1, V2 and V3, respectively.

Next, the proper transmittance Cn calculated this time is compared with the proper transmittance Cn-1 calculated last time. (S12
0). When the proper transmittance Cn of this time is smaller than the proper transmittance Cn-1 of the previous time, a constant positive voltage is applied for a predetermined time Δt in order to make the coloring of the EC glass 1 deeper (S130, S140), a predetermined amount of electricity is supplied to the EC glass 1. On the other hand, when the proper transmittance Cn of this time is larger than the proper transmittance Cn-1 of the previous time, a constant negative voltage is applied for a predetermined time Δt in order to make the coloring of the EC glass 1 lighter (S150, S160). ).

A method of calculating the predetermined time Δt will be described. FIG. 4C shows the case where the constant voltage applied in S140 and S160 is supplied to the EC glass 1.
It is a graph which shows the correspondence of time and the transmittance of EC glass 1. This correspondence is also obtained in advance by a feeling test or the like and is stored in the memory in the control device 7.

For example, in FIG. 4 (b), when the appropriate transmittance Cn becomes small as C1 → C2, FIG. 4 (c)
Referring to, the time X2 to reach the transmittance C2 and the transmittance C1
It can be seen that the EC glass 1 has an appropriate transmittance C2 if a positive voltage is applied by Δt1 which is the difference from the time X1 for reaching the temperature. Therefore, in S130, time X2 to time X
Subtract 1 to obtain the predetermined time Δt, and in S140, apply a positive voltage for the predetermined time Δt.

On the other hand, in FIG. 4B, the proper transmittance C
When n decreases from C2 to C3, referring to FIG. 4 (c), the time X3 to reach the transmittance C3 and the transmittance C2
It can be seen that the EC glass 1 has an appropriate transmittance C3 when a negative voltage is applied by Δt2, which is the difference from the time X2 for reaching. Therefore, in S150, time X2 to time X3
To obtain a predetermined time Δt, and in S160, a predetermined time Δt
A constant negative voltage is applied for t.

A predetermined time Δt in S140 or S160
After applying the voltage of, the appropriate transmittance Cn of this time is stored in order to prepare for the next comparison process in S120 (S10).
170) and returns to S100 to repeat the following processing. On the other hand, in the comparison processing of S120, the proper transmittance C of this time
If n and the previous proper transmittance Cn-1 are equal, S1
The process proceeds to S170 without executing the processes of 30 and below.

In this way, the proper transmittance Cn of the EC glass 1 is calculated according to the output Vn of the solar cell 3, and the amount of electricity supplied to the EC glass 1 is controlled based on the proper transmittance Cn. Therefore, the transmittance of the EC glass 1 can be made appropriate in accordance with the amount of solar radiation at each time. Moreover, since the EC glass 1 is used, it is relatively easy to increase the area, and the sunroof 21 can be configured with one EC glass 1.

Further, once the predetermined transmittance is reached, the coloring degree of the EC glass 1 is constant without applying a voltage unless the amount of solar radiation or the like changes to increase or decrease the transmittance. Since the transmittance does not change, the power consumption can be reduced. Further, in the conventional one using liquid crystal, there is a disadvantage that the optical anisotropy characteristic changes depending on the direction of the molecular alignment depending on the type of liquid crystal, but the light transmittance variable glass does not have such a disadvantage.

Next, the second embodiment will be described. In the above-described first embodiment, the energization time to the EC glass 1 is changed according to the appropriate transmittance, and the coloring degree of the EC glass is integrated at regular time intervals. There may be an error in the transmittance. In the second embodiment, as shown in FIG. 6, an optical sensor 30 is provided on the lower surface of the EC glass 1 so that the light transmitted through the EC glass 1 can be detected. Therefore, the actual transmittance of the EC glass 1 can be detected by the output of the solar cell 3 corresponding to the light that does not pass through the EC glass 1 and the output of the optical sensor 30 corresponding to the light that passes through the EC glass 1. It is intended to prevent the above-mentioned error by using this actual transmittance. The same parts as those in the first embodiment are designated by the same reference numerals, and detailed description thereof will be omitted.

Next, the operation of the second embodiment will be described with reference to the flowchart of FIG. First, the output V of the solar cell 3
n is read (S200), and E corresponding to the output Vn is read
The proper transmittance Cn of the C glass 1 is calculated (S210).
Then, the proper transmittance Cn is determined (S220).

When the calculated proper transmittance Cn is equal to the maximum transmittance Cmax which is the transmittance of the EC glass 1 when it is not colored at all, in order to completely erase the color of the EC glass 1, The negative voltage is applied only for the set fixed time (S240). However, once erased, next,
The proper transmittance Cn calculated in S210 is the maximum transmittance Cma.
It is not necessary to apply a negative voltage until it becomes smaller than x.
Therefore, after the processing of S240, the erasing flag FL is set to 1 (S250) to return to the processing of S200, and it is further determined whether the erasing flag FL is 0 before executing the processing of S240. Judge (S230) and erase flag FL
When is 0, the process proceeds to S240 and the erasing flag FL
If is 1 instead of 0, the process returns to S200 without performing the processes from S240.

On the other hand, when the calculated proper transmittance Cn is smaller than the maximum transmittance Cmax, the erasing flag FL is reset to 0 (S260), and then the output Sn of the optical sensor 30 is read (S270). .. Then, the actual transmittance Ct is calculated on the basis of the output Vn of the solar cell 3 and the output Sn of the optical sensor 30 (S280), and the difference between the proper transmittance Cn and the actual transmittance Ct is obtained to make the determination ( S290).

When the absolute value of the difference between the proper transmittance Cn and the actual transmittance Ct is smaller than the predetermined value ε, that is, both transmittances Cn,
When Ct is almost equal, the process directly returns to S200 and the following processes are repeated. When the proper transmittance Cn is larger than the actual transmittance Ct by a predetermined value ε or more, a constant positive voltage is applied for a predetermined time in order to make the coloring of the EC glass 1 deeper (S300), and then the process returns to S200. .. on the other hand,
When the actual transmittance Ct is larger than the appropriate transmittance Cn by a predetermined value ε or more, a constant negative voltage is applied for a predetermined time in order to thin the coloring of the EC glass 1 (S310), and then S200.
Return to.

As described above, based on the actual transmittance Ct calculated from the output Sn of the optical sensor 30 corresponding to the light transmitted through the EC glass 1, the difference between the actual transmittance Ct and the proper transmittance Cn is eliminated. Feedback control is performed.
Therefore, it is possible to accurately grasp the actual transmittance that changes as the EC glass 1 is worn and decolored, and more accurate control becomes possible.

The present invention is not limited to the embodiments as described above, and can be carried out in various modes without departing from the gist of the present invention.

[0032]

As described in detail above, according to the variable light transmittance glass of the first aspect, since the electrochromic glass is used, it is relatively easy to increase the area and once the predetermined transmittance is obtained. Once reached, unless the need to increase or decrease the transmittance, the degree of coloring of the electrochromic glass is constant and the transmittance does not change without application of a voltage, so that the power consumption is low.

According to the variable light transmittance glass of the second aspect, the appropriate transmittance of the electrochromic glass is calculated according to the output of the solar cell, and the electrochromic glass is calculated based on the calculated appropriate transmittance. If the amount of electricity supplied to the electrochromic glass is controlled, the transmittance of the electrochromic glass can be made appropriate according to the amount of solar radiation at that time.

Further, according to the variable light transmittance glass of the third aspect, the transmittance of the electrochromic glass is calculated by calculating the transmittance based on the output of the optical sensor which detects the light transmitted through the electrochromic glass. The actual transmittance that changes by erasing can be accurately grasped, and more accurate control is possible by controlling the amount of electricity supplied so that the calculated actual transmittance becomes the above-mentioned proper transmittance. Becomes

[Brief description of drawings]

FIG. 1 is a block diagram illustrating a basic configuration of the present invention.

FIG. 2 is an explanatory diagram showing an overall configuration of a variable light transmittance glass according to the first embodiment of the present invention.

3A is a schematic configuration diagram when the variable light transmittance glass of the first embodiment is used for a sunroof, and FIG. 3B is a partially detailed explanatory diagram thereof.

4A is a graph showing an example of a solar cell output that changes with time, FIG. 4B is a graph showing a correspondence relationship between the solar cell output and an appropriate transmittance, and FIG. 4C is a constant voltage applied to an EC glass. It is a graph which shows the correspondence of the time and the transmittance at the time of supplying.

FIG. 5 is a flowchart showing a supplied electricity amount control process in the first embodiment.

FIG. 6 is a schematic configuration diagram when the variable light transmittance glass of the second embodiment is used for a sunroof.

FIG. 7 is a flowchart showing a power supply amount control process in the second embodiment.

[Explanation of symbols]

Vn ... Solar cell output, Cn ... Proper transmittance,
Ct ... Actual transmittance, 1 ... EC glass, 3 ... Solar cell, 5 ... Storage battery, 7 ... Control device,
11 ... Colored layer, 13 ... Electrolyte layer, 15 ... Transparent conductive film, 17 ... Glass, 30 ... Optical sensor

Claims (3)

[Claims] 1. An electrochromic glass that wears and decolors upon application of a voltage to cause a reversible change in light transmittance, a solar cell electrically connected to the electrochromic glass, and a solar cell of the solar cell. Based on the output, controls the amount of electricity supplied from the solar cell to the electrochromic glass,
A variable light transmittance glass, comprising: an electric quantity control means for changing the light transmittance of the electrochromic glass. 2. An appropriate transmittance calculating means for calculating an appropriate transmittance of the electrochromic glass according to the output of the solar cell based on the output of the solar cell, wherein the electrical quantity control means calculates the appropriate transmittance. The variable light transmittance glass according to claim 1, wherein the amount of electricity is controlled on the basis of: 3. An optical sensor for detecting light transmitted through the electrochromic glass, and an actual transmittance calculating means for calculating an actual transmittance of the electrochromic glass based on an output of the optical sensor. 3. The variable light transmittance glass according to claim 2, wherein the quantity of electricity is controlled by the quantity of electricity control means so that the calculated actual transmittance becomes the proper transmittance.