JP2007231613A - Double glazing device with built-in blind - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a double glazing device with a built-in blind which adequately has lighting to the inside of a room and solar power generation. <P>SOLUTION: The blind with a plurality of louvers 14 is arranged in a hollow part 13 of a double glazing which is a frame body 11 and is supported by and formed of two sheets of glasses 12. A solar battery cell 16 for converting light to electricity is mounted on one surface of the louver 14 of the blind and a lighting surface part for reflecting light and introducing the light to the inside of the room on the other surface of the louver 14. Accordingly, both the lighting to the inside of the room and the solar power generation are adequately carried out in addition to functions (heat insulation/sound proofing/burglarproofing or the like) of a conventional double glazing, and freedom of selection of designs and door locking function are provided in the double glazing device. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a blind built-in multilayer glass device in which a blind is built in a hollow portion of a multilayer glass body.

  In general, windows used in individual buildings such as detached houses, art museums, libraries, large buildings, and condominiums are used for lighting and ventilation, and most of them are ordinary glass windows. And when adjusting light quantity, curtains and blinds are used, and shutters are used for security measures.

  In recent years, double glazing such as pair glass (registered trademark) has been used in place of ordinary glass, and double sashes have been widely adopted. For example, there is a multi-layer glass with a built-in louver for heat shielding and light shielding, and there is one in which the louver is not brought into contact with the glass surface regardless of the installation inclination of the multi-layer glass (see, for example, Patent Document 1). ).

On the other hand, solar power generation friendly to the global environment has attracted attention. Small solar cells are used in calculators and wristwatches, but full-scale solar power generation facilities of medium-sized or larger have been lagging in terms of installation location and installation costs. Solar cells are placed on the roof, but the spread is still delayed. In view of this, a blind for adjusting the amount of light has a photovoltaic power generation function, and light that has been cut for awning is used for photovoltaic power generation (for example, see Patent Document 2). .
JP 2001-32649 A JP 2003-201795 A

  However, since the thing of patent document 1 is a multi-layer glass with a built-in louver, it can be shielded from heat and light and can take measures against crime, but the light that has been shielded cannot be used effectively. On the other hand, although the thing of patent document 2 can use the light cut for the sunshade for photovoltaic power generation, you have to provide a shutter for a glass window and a crime prevention measure separately.

  Also, in order to adjust the amount of light collected into the room, the blinds must be manually opened and closed. Therefore, it is necessary to open and close the blind each time the amount of solar radiation changes. On the other hand, the power generated by the solar battery changes depending on the amount of solar radiation and the open / close state of the blinds. Don't be. Conversely, when giving priority to indoor lighting, the blind must be manually opened and closed so that the illuminance in the room is maintained at a predetermined illuminance.

  An object of the present invention is to provide a blind built-in multilayer glass device capable of appropriately performing both indoor lighting and solar power generation.

  A double-glazed glass device with a built-in blind according to the invention of claim 1 is provided with a double-glazed glass body formed by supporting two glasses with a frame and having a hollow portion, and a plurality of glass devices disposed in the hollow portion of the double-glazed glass body. A blind having a plurality of louvers, a solar cell that is attached to one side of the louver and converts light into electricity, and is formed on the other side of the louver to reflect light and capture the reflected light into the room And a daylighting surface portion.

  According to a second aspect of the present invention, there is provided a blind built-in double-layer glass apparatus according to the first aspect of the present invention, further comprising an electric motor that opens and closes the blind by rotating the louver within a range of 360 °. .

  According to a third aspect of the invention, there is provided the blind built-in multilayer glass device according to the first aspect of the present invention, wherein any one of the plurality of louvers has a lighting surface portion formed on one side and the other side. It is characterized by being.

  A blind built-in multilayer glass device according to a fourth aspect of the present invention is the invention according to any one of the first to third aspects, wherein the electric motor is driven based on the illuminance in the room or the power generation amount of the solar battery cell. A control device for adjusting the louver angle of the blind is provided.

  According to a fifth aspect of the present invention, there is provided the blind built-in multilayer glass device according to the fourth aspect of the invention, wherein the control device is configured such that the illuminance in the room or the power generation amount of the solar battery cell is set to a preset value. The louver angle of the blind is adjusted.

  According to a sixth aspect of the present invention, there is provided the blind built-in multilayer glass device according to the fourth aspect of the invention, wherein the control device is configured so that the illuminance in the room or the power generation amount of the solar battery cell becomes a maximum value. The angle is adjusted.

  According to a seventh aspect of the present invention, there is provided the blind built-in multilayer glass device according to the fourth aspect of the invention, wherein the control device has a predetermined function value with the illuminance in the room and the power generation amount of the solar cell as variables. The louver angle of the blind is adjusted to a maximum value.

  The double-glazed built-in blind glass according to the invention of claim 8 is the invention according to any one of claims 1 to 4, wherein the control device is arranged such that the illuminance at a place where a person is present in the room becomes a maximum value. The louver angle of the blind is adjusted.

  According to a ninth aspect of the present invention, there is provided the blind built-in multilayer glass according to any one of the first to fourth aspects, wherein the control device is configured so that the illuminance at a place where a person is in the room becomes a maximum value. The louver angle of the blind is adjusted, and when the illuminance at the place where the person is in the room is not more than a predetermined value, the lighting device in the room is turned on.

  According to the present invention, focusing on windows that have recently been diversified as places where a large area can be secured, a blind is incorporated in the double-glazed glass, solar cells are mounted on one side of the louver of the blind, and the other side is mounted. The daylighting surface part for reflecting light and taking the reflected light into the room is formed, so that both daylighting and solar power generation can be performed appropriately, and there is freedom of design selection and door lock function. Can be made.

  Moreover, since the electric power generated by the solar cell and the illuminance by the lighting are controlled by adjusting the blind louver angle, both the indoor lighting and the solar power generation can be appropriately controlled. As a result, a comfortable and new lifestyle can be realized, solar power generation can be promoted, and the environmental load can be reduced.

(First embodiment)
FIG. 1 is a cross-sectional view of a blind built-in multilayer glass device according to the first embodiment of the present invention, and FIG. 2 is a front view from the direction of arrow A in FIG. As shown in FIG. 1, the multilayer glass body is formed by supporting two glasses 12 by a frame body 11, and a blind portion is built in a hollow portion 13 formed by the frame body 11 and the two glass sheets 12. Yes. The blind has a plurality of louvers 14, and each louver 14 is fixed to a rotation shaft 15 and is formed to open and close by rotation of the rotation shaft 15.

  A solar battery cell 16 is mounted on one surface of each louver 14, and light is converted into electricity by the solar battery cell 16, stored in a storage battery (not shown), and supplied to a load. Moreover, the lighting surface part 17 is formed in the other surface of the louver 14, light is reflected by this lighting surface part 17, and the reflected light is taken in indoors. In FIG. 1, all the louvers 14 are shown with the solar cells 16 attached thereto, but any one of the plurality of louvers 14 is not equipped with the solar cells 16 and is made of ordinary glass. It may be a surface. Thereby, the visibility of a normal window glass can be ensured and the indoor environment can be improved.

  As shown in FIG. 2, an electric motor 18 that opens and closes the blind is provided inside the frame body 11, and the driving mechanism 19 is driven by the electric motor 18 to rotate the angle of the blind louver 14 within a range of 360 °. It can be made to. The angle of the louver 14 can be rotated within a range of 360 ° because the solar cell 16 is mounted on one surface of the louver 14 and the lighting surface portion 17 is formed on the other surface of the louver 14. This is because it is not symmetrical, and the amount of power generation and the lighting state due to the change in the angle of the louver 14 are different in a range of 360 °.

  The drive mechanism 19 has a gear mechanism in which, for example, each louver 14 moves in the same direction in association with the same angle by driving the electric motor 18. Thereby, each louver 14 in the multilayer glass body performs the same movement. Further, the louver 14 can be electrically moved in the up and down direction, whereby the louver 14 is wound up and down. In addition, a wattmeter 20 for detecting generated power by the solar battery cell is provided inside the frame body 11.

  FIG. 3 is a cross-sectional view of the louver 14. The louver 14 is made of laminated glass in consideration of crime prevention, soundproofing and light shielding. Thereby, the louver 14 is given strength. Moreover, the photovoltaic cell 16 is vapor-deposited on the surface of the laminated glass of one side of the louver 15, the other side is left as a laminated glass surface, the filter 21 is put in the intermediate layer of the laminated glass, and the lighting surface part 17 is provided on the other side. Form. The daylighting surface portion 17 formed on the other surface of the laminated glass can adjust the light function by the filter 21 inserted in the intermediate layer, and can adopt a favorite color and design. For example, it is possible to produce a design by writing pictures and characters on the filter 21. Thereby, a variety of blind forms can be enjoyed while generating power or daylighting.

  In this manner, the louver 14 generates power by the solar battery cell 16 mounted on one side thereof, and can shine light to the interior of the room by the daylighting surface portion 17 of the laminated glass on the other side of the louver 14.

  FIG. 4 is an overall configuration diagram of a blind built-in multilayer glass device according to the first embodiment of the present invention. An illuminometer 22 is provided at a predetermined place in the room, and the illuminance in the room measured by the illuminometer 22 is input to the operation panel 23 and displayed on the display unit of the operation panel 23. The electric power generated by the solar power generation cell 16 is detected by the wattmeter 20, and the detected electric power is input to the operation panel 23 and displayed on the display unit in the same manner.

  In the first embodiment of the present invention, solar cells 16 mounted on a plurality of louvers 14 housed in the hollow portion 13 of the multilayer glass body are connected in series to take out generated power. Therefore, the power measured by the wattmeter 20 is the power generated by these series-connected solar cells 16.

  The operation panel 23 is provided with a manual / automatic selection switch for the opening / closing operation of the blind louver 14. When manual operation is selected, the manual operation PB of the operation panel 23 causes the manual operation PB to pass through the control device 24. The electric motor 18 is driven and the louver 14 is manually operated. On the other hand, when automatic is selected, the control device determines the type of automatic control, drives the electric motor 18 according to the type of automatic control, and automatically controls the operation of the louver 14.

  In the first embodiment of the present invention, hoisting / lowering operation of the louver 14 and forward / reverse operation of the louver 14 are prepared as the types of manual operation, and set value control, maximum Assume that three automatic control types of value control and two-element control are prepared.

  The louver 14 hoisting / lowering operation is an operation of winding or lowering the louver 14 in either the upper or lower direction, and the forward / reverse operation of the louver 14 is an operation of adjusting the opening / closing angle of the louver.

  The set value control is a control type for controlling the power generation amount of the solar battery cells 16 or the room illuminance to be a predetermined set value, and the maximum value control is the power generation amount of the solar battery cells 16 or the room illuminance. It is a control type that is controlled so as to become the maximum value, and the two-element control is a control that adjusts the louver angle so that the value of a predetermined function whose variables are the illuminance in the room and the power generation amount of the solar battery cell becomes the maximum value. It is.

  FIG. 5 is a flowchart showing the processing contents of the control device 24. First, it is determined whether or not automatic is selected with the selection switch of the operation panel 23 (S1). When automatic is selected and the automatic mode is selected, the type of automatic control is determined. That is, it is determined whether or not the automatic control type is set value control (S2). If it is set value control, the set value control is performed (S3). If it is determined in step S2 that the control is not set value control, it is determined whether or not it is two-element control (S4). If it is two-element control, two-element control is performed (S5). If it is determined in step S4 that the control is not two-element control, it is determined that the control is maximum value control (S6), and maximum value control is performed (S7). That is, the maximum value control is performed when automatic is selected by the selection switch but neither the set value control nor the two-element control is selected.

  On the other hand, when the automatic is not selected in the determination of step S1, it is determined that it is manual (S8). This is because there are two control modes selected by the selection switch, automatic and manual, and when automatic is not selected, it can be determined that the operation is manual. In the manual operation, it is determined whether the hoisting / lowering PB is on (S9). When the hoisting / lowering PB is on, it is determined whether the hoisting or lowering is performed, and the hoisting or lowering operation is performed (S10). For example, in the case of lowering, the blind louver 14 is wound upward as shown in FIG.

  If it is determined in step S9 that the hoisting / lowering PB is not on, it is determined whether the forward / reverse rotation PB is on (S11). When the forward rotation / reverse rotation PB is ON, it is determined whether the rotation is normal rotation or reverse rotation, and the forward rotation or reverse rotation operation is performed (S12). For example, when closing a door, as shown in FIG. 7, the louver 14 is adjusted to a position parallel to the glass 12, and the blind louver 14 is used in place of a shutter or curtain. Thereby, soundproofing, crime prevention, and privacy measures can be taken.

  FIG. 8 is a flowchart showing the contents of the set value control in step S3 of FIG. First, it is determined whether or not the power set value control is performed (S1). Whether or not the power set value control is performed is determined based on whether or not the power set value control is selected on the operation panel 23. In the case of power set value control, the power set value P0 set on the operation panel 23 is read (S2), and the power value P measured by the wattmeter 20 is read (S3). Then, it is determined whether or not the deviation | P−P0 | between the electric power value P and the electric power setting value P0 is within a predetermined value ε1 (S4), and when the deviation | P−P0 | is within the predetermined value ε1. The louver angle is fixed at the current angle (S5).

  If the deviation | P−P0 | is not within the predetermined value ε1 in the determination in step S4, the louver angle is changed by a predetermined angle (S6). Then, it is determined whether or not the louver 14 has made one revolution (S7), and if it has not made one revolution, the process returns to step S3. That is, the processes in steps S3 to S6 are repeated until the louver 14 makes one rotation, and the power value P at the changed louver angle is stored.

  When the louver 14 makes one revolution, the louver angle at which the deviation | P−P0 | is minimized is extracted from the power values P at the respective louver angles obtained by making the louver 14 make one revolution. The louver angle is fixed (S8). Accordingly, when the deviation | P−P0 | does not satisfy the predetermined value ε1 or less, the louver angle at which the deviation | P−P0 | is minimized is controlled.

  On the other hand, when it is not power setting value control by determination of step S1, it is determined whether it is illumination intensity setting value control (S9). If it is not illuminance set value control, the process ends. That is, when the set value control is selected, but neither the power set value control nor the illuminance set value control is selected, the process ends.

  In the case of illuminance set value control, the illuminance set value L0 set on the operation panel 23 is read (S10), and the illuminance value L measured by the illuminometer 22 is read (S11). Then, it is determined whether or not the deviation | L−L0 | between the illuminance value L and the illuminance setting value L0 is within a predetermined value ε2 (S12), and when the deviation | L−L0 | is within the predetermined value ε2. The louver angle is fixed at the current angle (S13).

  If the deviation | L−L0 | is not within the predetermined value ε2 in the determination of step S11, the louver angle is changed by a predetermined angle (S14). Then, it is determined whether or not the louver 14 has made one revolution (S5), and if it has not made one revolution, the process returns to step S11. That is, the processes in steps S11 to S14 are repeated until the louver 14 makes one rotation, and the illuminance value L at the changed louver angle is stored.

  When the louver 14 makes one revolution, the louver angle at which the deviation | L−L0 | is minimized is extracted from the illuminance values L at the respective louver angles obtained by making the louver 14 make one revolution. The louver angle is fixed (S16). Thus, when the deviation | L−L0 | does not satisfy the predetermined value ε2 or less, the louver angle at which the deviation | L−L0 | is minimized is controlled.

  Thereby, in the case of power set value control, the louver angle is adjusted so that the generated power value P in the solar battery cell 16 becomes the power set value P0 in accordance with the sunshine conditions at that time. On the other hand, in the case of illuminance set value control, the louver angle is adjusted so that the illuminance value L in the room becomes the illuminance set value L0 in accordance with the sunshine conditions at that time.

  Next, FIG. 9 is a flowchart showing the contents of the maximum value control in step S7 of FIG. First, it is determined whether or not power maximum value control is performed (S1). Whether or not the power maximum value control is performed is determined by whether or not the power maximum value control is selected on the operation panel 23. In the case of power maximum value control, the current power value P and louver angle θ are read and stored (S2). Then, the louver angle θ is changed by a predetermined angle (S3), and it is determined whether or not the louver 14 has made one revolution (S4), and if it has not made one revolution, the process returns to step S2. That is, the processes of steps S2 and S3 are repeated until the louver 14 makes one rotation, and the power value P at the changed louver angle θ is stored.

  When the louver 14 makes one rotation, out of the power values P at each louver angle θ obtained by one rotation of the louver 14, the louver angle at the louver angle θ1 when the power value P is the maximum value Pm. Is fixed (S5). As a result, the generated power P in the solar battery cell 16 becomes the maximum power value Pm under the current sunshine conditions.

  Then, considering that the sunshine condition changes with time, it is determined whether or not a certain time has passed (S6). As this fixed time, a time when a change in sunshine conditions is assumed is set. When the predetermined time has elapsed, it is determined whether or not the power maximum value control has ended (S7). If the power maximum value control has not ended, the process returns to step S2, and the processes of steps S2 to S7 are repeated. As a result, it is possible to control the maximum electric power value following the change in the sunshine conditions.

  On the other hand, if it is not the power maximum value control in the determination of step S1, it is determined whether or not the illumination intensity maximum value control is performed (S8). If it is not illuminance maximum value control, the process ends. That is, when the maximum value control is selected, but neither the power maximum value control nor the illuminance maximum value control is selected, the process is terminated.

  In the case of the maximum illumination value control, the current illumination value L and the louver angle θ are read and stored (S9). Then, the louver angle θ is changed by a predetermined angle (S10), and it is determined whether or not the louver 14 has made one revolution (S11), and if it has not made one revolution, the process returns to step S9. That is, the processes of steps S9 and S10 are repeated until the louver 14 makes one rotation, and the illuminance value L at the changed louver angle θ is stored.

  When the louver 14 makes one rotation, among the illuminance values L at each louver angle θ obtained by one rotation of the louver 14, the louver angle is set at the louver angle θ2 when the illuminance value L is the maximum value Lm. Fix (S12). Thereby, the illuminance value L under the current sunshine condition becomes the illuminance maximum value Lm.

  Then, considering that the sunshine condition changes with time, it is determined whether or not a certain time has passed (S13). As this fixed time, a time when a change in sunshine conditions is assumed is set. When the predetermined time has elapsed, it is determined whether or not the maximum illuminance value control has ended (S14). If the maximum illuminance value control has not ended, the process returns to step S9, and the processes of steps S9 to S14 are repeated. Thereby, it is possible to control the maximum illuminance value following the change in the sunshine conditions.

  Next, FIG. 10 is a flowchart showing the contents of the two-element control in step S5 of FIG. First, it is determined whether or not it is two-element control (S1). If it is not two-element control, the process ends. That is, when the automatic mode is selected as the control mode but the two-element control is not selected, the process is terminated.

  In the case of two-element control, the current power value P, illuminance value L, and louver angle θ are read and stored (S2). Then, the louver angle θ is changed by a predetermined angle (S3), and it is determined whether or not the louver 14 has made one revolution (S4), and if it has not made one revolution, the process returns to step S2. That is, the processes in steps S2 and S3 are repeated until the louver 14 makes one rotation, and the power value P and the illuminance value L at the changed louver angle θ are stored.

  When the louver 14 makes one rotation, the louver angle θ3 is set to a louver angle θ3 at which the value of a predetermined function Z (P, L) having the indoor illuminance value L and the generated power P of the solar battery cell as variables is the maximum value. Fix (S5). The function Z (P, L) is expressed by the following equation (1), for example.

Z = α · P + β · L (1)
α is a weighting factor of the power value P, and β is a weighting factor of the illuminance value L. By selecting the weighting factors α and β, the two-element control in which the power value P or the illuminance value L is equalized or the two-element control in which either the power value P or the illuminance value L is prioritized can be achieved. As a result, it is possible to control the power generation and the daylighting in the middle.

  Next, considering that the sunshine condition changes with time, it is determined whether or not a certain time has passed (S6). As this fixed time, a time when a change in sunshine conditions is assumed is set. When the fixed time has elapsed, it is determined whether or not the two-element control is finished (S7). If the two-element control is not finished, the process returns to step S2, and the processes of steps S2 to S7 are repeated. This enables two-element control that follows changes in sunshine conditions.

  Here, a case has been described in which a plurality of louvers housed in one multilayer glass body are moved in the same direction by the same angle in conjunction with the motor 18, but the motors are respectively connected to the plurality of louvers. The louvers may be moved individually, or a plurality of louvers may be grouped to provide electric motors for each group, and the louvers may be moved for each group.

  Further, when a plurality of louvers are moved in conjunction with each other, they may be moved in conjunction with a plurality of louvers in another multilayer glass body. For example, the opening / closing operation of the louver is performed by one operation on the louvers of the multiple glass bodies of the plurality of windows. In this case, an individual mode in which the louver is individually moved for each multilayer glass body and an interlocking mode in which the louvers are moved collectively for a plurality of multilayer glasses are prepared, and the individual mode and the interlocking mode are switched on the operation panel 23. The louvers of each multilayer glass body may be moved. Thereby, the operation of the louver in the double-glazed glass body of the high place window can be easily performed. Furthermore, it is also possible to select door lock, daylighting, and power generation from outside by linking with home automation.

  According to the first embodiment of the present invention, focusing on recently diversified windows as a place where a large area where solar cells can be installed can be secured, the solar cells are accommodated in the multilayer glass body. It is installed in a blind louver, and the louver has freedom of design selection and a door lock function, so that it is possible to achieve both energy saving and environmental load reduction in modern buildings. Moreover, since the angle of the louver is controlled in consideration of the efficiency of the solar battery cell and the daylighting in the room, both the solar power generation and the daylighting in the room can be appropriately performed.

(Second Embodiment)
FIG. 11 is an overall configuration diagram of a blind built-in multilayer glass device according to the second embodiment of the present invention. In the second embodiment, a human sensor 25 is additionally provided to the first embodiment shown in FIG. 4, and set value control and maximum value control are used as the types of automatic control of the control device 24. In addition to the two-element control, a manned illumination control for brightly controlling a place where a person is present in the room is additionally provided. The same elements as those in FIG. 4 are denoted by the same reference numerals, and redundant description is omitted.

  The human sensor 25 detects a place where a person is present in the room and inputs it to the control device 24. When the manned illuminance control is selected as the automatic control type on the operation panel 23, the control device 24 performs the manned illuminance control so that the place where the person is detected detected by the human sensor 25 becomes bright.

  FIG. 12 is a flowchart showing the contents of manned illuminance control in the second embodiment of the present invention. First, it is determined whether or not it is manned illuminance control (S1). If it is manned illuminance control, whether or not the human sensor 25 detects a person in the room, that is, whether or not there is a person in the room. Is determined (S2).

  When there is a person in the room, the illuminance value La of the place closest to the person's place is read and the blind louver angle θ is read and stored (S3). Then, the louver angle θ is changed by a predetermined angle (S4), and it is determined whether or not the louver 14 has made one revolution (S5), and if it has not made one revolution, the process returns to step S3. That is, the processes in steps S3 and S4 are repeated until the louver 14 makes one rotation, and the illuminance value La at the changed louver angle θ is stored.

  When the louver 14 makes one rotation, among the illuminance values La at each louver angle θ obtained by one rotation of the louver 14, the louver angle is set at the louver angle θa when the illuminance value La is the maximum value Lm. Fix (S6). As a result, the illuminance value La under the current sunshine condition becomes the illuminance maximum value Lm.

  Then, considering that the sunshine condition changes with time, it is determined whether or not a certain time has passed (S7). As this fixed time, a time when a change in sunshine conditions is assumed is set. When a certain time elapses, it is determined whether or not the manned illuminance control is finished (S8). When the manned illuminance control is not finished, the process returns to step S3, and the processes of steps S3 to S8 are repeated. Thereby, the manned illumination control which followed the change of the sunlight conditions is attained, and the place where a person exists can be brightened.

  FIG. 13 is an overall configuration diagram showing another example of a blind built-in multilayer glass device according to the second embodiment of the present invention. In contrast to the one shown in FIG. 11, instead of the human detection sensor 25 and the illuminance meter 22, a lighting-off remote controller 28 of a lighting fixture 27 incorporating the illuminance meter 26 is provided, and the control device 24 is turned on / off. The louver angle of the blind is adjusted so that the illuminance detected by the illuminance meter 26 of 28 is the maximum value. When the illuminance is less than a predetermined value, the indoor lighting device 27 is turned on.

  FIG. 14 is a flowchart showing the contents of another example of manned illuminance control in the second embodiment shown in FIG. First, it is determined whether or not it is manned illuminance control (S1), and when it is manned illuminance control, the illuminance value Lb is read from the illuminometer 26 incorporated in the lighting remote controller 28 of the lighting fixture 27 and blinded. Is read and stored (S2). Then, the louver angle θ is changed by a predetermined angle (S3), and it is determined whether or not the louver 14 has made one revolution (S4), and if it has not made one revolution, the process returns to step S2. That is, the processes in steps S2 and S3 are repeated until the louver 14 makes one rotation, and the illuminance value Lb at the changed louver angle θ is stored.

  When the louver 14 makes one rotation, among the illuminance values Lb at each louver angle θ obtained by one rotation of the louver 14, the louver angle is set at the louver angle θb when the illuminance value Lb is the maximum value Lm. Fix (S5). Thereby, the illuminance value Lb under the current sunshine condition becomes the illuminance maximum value Lm. Then, it is determined whether or not the illuminance value Lb at that time is equal to or greater than the specified value Lr (S6). Thereby, the place where a person exists can be brightened.

  When the determination in step S6 is equal to or greater than the specified value Lr, or after the processing in step S7, it is determined whether or not a certain time has elapsed in consideration of the change in the sunshine condition with time (S8). When a certain time elapses, it is determined whether or not the manned illuminance control is finished (S9). When the manned illuminance control is not finished, the process returns to step S2, and the processes of steps S2 to S9 are repeated. Thereby, the manned illumination control which followed the change of the sunlight conditions is attained, and the place where a person exists can be brightened.

  According to the second embodiment of the present invention, a person detection sensor for detecting the presence of a person or a device carried by a person recognizes the place where the person is present, and the illuminance meter increases the illuminance at the place where the person is present. So that the place where people are can be brightened.

Sectional drawing of the double glazing apparatus with a built-in blind concerning the 1st Embodiment of this invention. The front view of the double glazing apparatus with a built-in blind concerning the 1st Embodiment of this invention. Sectional drawing of the louver in the 1st Embodiment of this invention. 1 is an overall configuration diagram of a blind built-in multilayer glass device according to a first embodiment of the present invention. The flowchart which shows the processing content of the control apparatus in the 1st Embodiment of this invention. Sectional drawing of the blind built-in multilayer glass apparatus which shows the state which wound down the louver of the blind below. Sectional drawing of the double glazing apparatus with a built-in blind which shows the state which used the louver of the blind instead of a shutter or a curtain. The flowchart which shows the content of the setting value control of step S3 of FIG. The flowchart which shows the content of the maximum value control of step S5 of FIG. The flowchart which shows the content of the two element control of step S7 of FIG. The whole block diagram of the double glazing apparatus with a built-in blind concerning the 2nd Embodiment of this invention. The flowchart which shows the content of the manned illumination intensity control in the 2nd Embodiment of this invention. The whole block diagram which shows another example of the double glazing apparatus with a built-in blind concerning the 2nd Embodiment of this invention. The flowchart which shows the content of the other example of manned illumination intensity control in 2nd Embodiment shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 ... Frame, 12 ... Glass, 13 ... Hollow part, 14 ... Louver, 15 ... Rotating shaft, 16 ... Solar cell, 17 ... Daylighting surface part, 18 ... Electric motor, 19 ... Drive mechanism, 20 ... Wattmeter, 21 ... Filter, 22 ... Illuminance meter, 23 ... Operation panel, 24 ... Control device, 25 ... Human sensor, 26 ... Illuminance meter, 27 ... Lighting equipment, 28 ... Light-off remote controller

Claims (9)

A double-glazed glass body formed by supporting two glasses with a frame and having a hollow portion, a blind having a plurality of louvers disposed in the hollow portion of the double-glazed glass body, and one surface of the louver A blind built-in multilayer comprising: a solar battery cell that is mounted and converts light into electricity; and a daylighting surface portion that is formed on the other surface of the louver and reflects the light and takes the reflected light into the room. Glass equipment. 2. The blind built-in multilayer glass device according to claim 1, further comprising an electric motor that rotates the louver within a range of 360 [deg.] To open and close the blind. 2. The blind built-in multilayer glass device according to claim 1, wherein any one of the plurality of louvers has a daylighting surface portion formed on one side and the other side. 4. The control device according to claim 1, further comprising: a control device that drives the electric motor and adjusts a louver angle of the blind based on the illuminance in the room and the amount of power generated by the solar battery cell. 5. Double-glazed device with built-in blinds. 5. The blind built-in multilayer according to claim 4, wherein the control device adjusts the louver angle of the blind so that the illuminance in the room or the power generation amount of the solar battery cell becomes a preset value. Glass equipment. 5. The blind built-in multilayer glass device according to claim 4, wherein the control device adjusts the louver angle of the blind so that the illuminance in the room or the power generation amount of the solar battery cell becomes a maximum value. The said control apparatus adjusts the louver angle of the said blind so that the value of the predetermined function which makes the illumination intensity in the said room and the electric power generation amount of the said photovoltaic cell a variable becomes a maximum value. The double-glazed device with a built-in blind. 5. The blind built-in composite according to claim 1, wherein the control device adjusts a louver angle of the blind so that an illuminance at a place where a person is present in the room becomes a maximum value. 6. Layer glass equipment. The control device adjusts the louver angle of the blind so that the illuminance of the place where the person is present in the room becomes the maximum value, and when the illuminance of the place where the person is present is equal to or less than a predetermined value, The blind built-in multilayer glass device according to any one of claims 1 to 4, wherein:

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