WO2013011746A1 - Take-up type solar cell - Google Patents

Abstract

This take-up type solar cell is provided with: a cell sheet that can be taken up, said cell sheet having a film-like solar cell; a take-up unit that is capable of taking up and housing the cell sheet; an acquiring unit, which acquires information from the outside; and a control unit, which performs take-up control and/or pullout control of the cell sheet by driving the take-up unit when predetermined conditions are met on the basis of information obtained from the acquiring unit.

Description

Rewind-type solar cell Cross-reference of related applications

This international application claims priority based on Japanese Patent Application No. 2011-159951 filed with the Japan Patent Office on July 21, 2011, and is based on Japanese Patent Application No. 2011-159951. The entire contents are incorporated herein by reference.

The present invention relates to a take-up solar cell that has a battery sheet and can wind and store the battery sheet.

The output of the solar cell is approximately proportional to the area of the solar cell module. Therefore, a large installation area is required to obtain a large amount of power.
For example, in an urban area, it is installed on a residential roof or a building roof. In such a solar cell, a solar cell module in which a solar light irradiation surface side is formed of a glass plate is housed in an aluminum case and attached to an inclined base.

However, this type of solar cell requires a large amount of labor for transportation because of its large area and weight.
As a method for solving such a problem, a flexible solar cell module sheet (hereinafter referred to as “battery sheet”) has been proposed (see, for example, Patent Document 1). Such a battery sheet is light in weight, and can be wound and accommodated in a roll shape.

JP-A-11-145503

However, the conventional technology only discloses a housing structure for facilitating transportation or protecting the battery sheet, and has not yet reached a configuration for automatically determining the winding timing of the battery sheet. .

The present invention has been made in order to solve the above-described problems, and its purpose is to automatically determine the winding timing of a flexible battery sheet so that it can be used for various scenes. It is to provide a solar cell.

The winding solar cell of the present invention made to achieve the above-described object includes a battery sheet, a winding unit, an acquisition unit, and a control unit. The battery sheet can be wound up and is wound and accommodated by a winding portion.

Particularly in the present invention, the acquisition unit acquires information from the outside, and based on the information from the acquisition unit, when a predetermined condition is satisfied by the control unit, the winding unit is driven to wind the battery sheet. At least one of the control and the drawer control is executed.

Note that the winding control is to wind up the battery sheet to the winding unit, and includes not only winding up all of the drawn battery sheet but also winding up partway. Similarly, the pull-out control is for pulling out the battery sheet from the winding unit, and includes not only pulling out all of the wound battery sheets but also pulling them out halfway.

If it does in this way, based on the information from an acquisition part, the timing of winding-up and drawing-out of a battery sheet will be judged automatically.
In addition, you may make it laminate | stack the electric power generation film which converts the kinetic energy containing a vibration into an electrical energy on a battery sheet. It is conceivable that the power generation film is configured by using a technique disclosed in Japanese Unexamined Patent Application Publication Nos. 2009-247106 and 2011-193665. In this way, the battery sheet generates power by vibration or the like, not only in the expanded state, but also in the wound state, so that power generation can be performed more efficiently.

Such an apparatus can be used in various scenes.
For example, the structure installed so that a battery sheet may cover the ground surface in the state pulled out from the winding-up part can be considered. In this case, the acquisition unit acquires at least one of rainfall information, humidity information, wind power information, and sunshine information. A control part performs winding-up control of a battery sheet, if predetermined conditions are satisfied based on the information from an acquisition part. In this way, the winding timing of the battery sheet is determined based on information such as whether it is raining, whether the humidity is high, whether the wind is strong, and whether there is sunshine necessary for power generation. can do. As a result, installation in grounds, parking lots, parks, etc. is realized.

More specifically, the acquisition unit acquires at least rainfall information and humidity information, and when the control unit determines that it is raining based on the rainfall information, according to the dryness of the ground surface based on the humidity information, It is conceivable to execute the winding control of the battery sheet. If it does in this way, the winding-up timing of a battery sheet can be judged according to the dryness of the ground surface.

Further, for example, a configuration in which the battery sheet is installed so as to cover the sea surface in a state where the battery sheet is pulled out from the winding unit may be considered. In this case, the acquisition unit acquires at least one of wave height information, wind power information, and sunshine information. A control part performs winding-up control of a battery sheet, if predetermined conditions are satisfied based on the information from an acquisition part. If it does in this way, winding-up timing of a battery sheet can be judged by information on whether a wave is high, whether a wind is strong, and whether there is sunshine required for power generation. As a result, installation at sea is realized.

More specifically, it is conceivable that the acquisition unit acquires at least wave height information, and the control unit executes winding control of the battery sheet according to the wave height based on the wave height information. In this way, the winding timing of the battery sheet can be determined according to the wave height on the sea surface.

Furthermore, for example, a configuration in which the battery sheet is installed so as to cover the window of the vehicle in a state where the battery sheet is pulled out from the winding unit is conceivable. In this case, the acquisition unit acquires ignition information indicating whether the vehicle is in an ignition-on state or an ignition-off state, and the control unit acquires a battery seat when a predetermined condition is satisfied based on information from the acquisition unit. At least one of the winding control and the drawer control is executed. If it does in this way, winding-up timing of a battery sheet can be judged with information on ON / OFF of an ignition switch. As a result, installation on the vehicle window is realized. Moreover, a battery sheet becomes a sunshade and a blindfold, and the crime prevention effect is acquired. The ignition-on state is a state in which power is supplied to a power supply line (so-called ignition power supply line) for operating a power source (an internal combustion engine or a motor) in the vehicle. In this state, power is not supplied to the line.

More specifically, it is conceivable that the control unit performs the winding control of the battery sheet when it is determined that the vehicle is in the ignition-on state based on the ignition information. This is convenient because the battery sheet is accommodated during traveling.

More specifically, it is conceivable that the control unit performs the control of pulling out the battery sheet when it is determined that the vehicle is in the ignition off state based on the ignition information. This is convenient because, for example, the battery sheet is pulled out during parking.

Further, for example, a configuration in which the battery sheet is installed so as to spread toward the rear of the vehicle by traveling of the vehicle in a state where the battery sheet is pulled out from the winding unit may be considered. In this case, the acquisition unit acquires the vehicle speed information, and the control unit executes at least one of the winding control and the drawer control of the battery sheet when a predetermined condition is satisfied based on the information from the acquisition unit. In this way, power generation while the vehicle is running becomes possible.

More specifically, based on the vehicle speed information, the control unit may perform battery sheet pull-out control when the vehicle speed exceeds a predetermined speed, and perform battery sheet winding control when the vehicle speed falls below the predetermined speed. It is done. If it does in this way, a battery sheet will be utilized according to a vehicle speed.

Furthermore, for example, a configuration in which the battery sheet is installed so as to cover the window of the building in a state where the battery sheet is pulled out from the winding unit is conceivable. In this case, the acquisition unit acquires the image information related to the approach of the person, and the control unit executes at least one of the winding control and the drawer control of the battery sheet when a predetermined condition is satisfied based on the information from the acquisition unit. To do. If it does in this way, winding-up timing of a battery sheet can be judged with information on whether a person approached. As a result, installation on the windows of the building is realized. In addition, the battery sheet is shaded or blindfolded, and a power saving effect and a crime prevention effect are obtained.

More specifically, it is conceivable that the control unit executes winding control of the battery sheet when it is determined that the person is approaching based on the image information. In this way, since the battery sheet is wound up when a person approaches, the crime prevention effect is conspicuous.

More specifically, when the control unit determines that there is no person based on the image information, it can be considered that the control for pulling out the battery sheet is executed. This is convenient because the battery sheet is pulled out when there is no person.

Further, for example, a configuration in which the battery sheet is installed on a support column extending toward the air so as to spread in the wind in a state where the battery sheet is pulled out from the winding unit may be considered. In this case, the acquisition unit acquires wind power information, and the control unit executes at least one of winding control and pulling-out control of the battery sheet when a predetermined condition is satisfied based on information from the acquisition unit. If it does in this way, since a battery sheet spreads in space, space can be used effectively.

More specifically, based on the wind power information, the control unit executes the battery sheet pull-out control in the wind range where the battery sheet spreads in the wind, and executes the battery sheet take-up control when the wind range is exceeded. It is possible. In this way, the battery sheet can be used to generate power only when the wind power is appropriate.

Furthermore, for example, a configuration in which the battery sheet is installed in the building so as to be a banner on the wall surface of the building in a state where the battery sheet is pulled out from the winding unit may be considered. In this case, the acquisition unit acquires wind power information, and the control unit executes at least one of winding control and pulling-out control of the battery sheet when a predetermined condition is satisfied based on information from the acquisition unit. If it does in this way, installation to a building will be realized. Further, it is possible to advertise by placing an advertisement on the tip of the battery sheet.

By the way, it is set as the structure provided with the electrical storage part which accumulate | stores the electric power generated with a battery sheet, and a control part is good also as performing at least one among winding control and drawing-out control using the electric power accumulate | stored in the electrical storage part. This is convenient because it is not necessary to supply power separately.

In addition, as a structure of the said winding part, a winding part adheres the end of a battery sheet, the winding roll which winds up a battery sheet from the said one end, and driving | running rotation of a winding roll so that a battery sheet may be wound up The structure which has a winding drive part to be made can be considered.

At this time, the winding unit may be provided in parallel with the winding roll, and may include a tension roll that generates tension in the winding direction across the width direction of the battery sheet when winding the battery sheet with the winding roll. . If it does in this way, meandering at the time of winding of a battery sheet can be controlled.

And, in the configuration having such a tension roll, it is possible to have a pull-out drive section that drives and rotates the tension roll to pull out the battery sheet. In this way, battery sheet pull-out control can be realized relatively easily.

FIG. 1A is a schematic plan view of a take-up solar cell, and FIG. 1B is a schematic side view of the take-up solar cell. It is explanatory drawing which shows the specific example which installs a winding-type solar cell in a ground. It is a flowchart which shows the sheet | seat control process based on rainfall information and humidity information. 4A is a flowchart showing a sheet control process based on wind power information, and FIG. 4B is a flowchart showing a sheet control process based on sunshine information. It is a flowchart which shows the sheet | seat control process based on rainfall information and humidity information. It is a flowchart which shows the sheet control processing based on wave height information. It is a schematic plan view of the winding type solar cell of 2nd Embodiment. FIG. 8A is an explanatory view showing a specific example of installing a wind-up solar cell on a vehicle, FIG. 8A is an explanatory view showing a state where a battery seat is installed so as to cover a vehicle window, and FIG. It is explanatory drawing which shows a mode that the winding type solar cell was installed in the rear part. It is a flowchart which shows the sheet | seat control process based on ignition information. It is a flowchart which shows the sheet | seat control process based on speed information. It is explanatory drawing which shows the specific example which installs a winding-type solar cell in the window of a private house. It is a flowchart which shows the sheet | seat control process based on a human figure information. It is explanatory drawing which shows the specific example which installs a winding-type solar cell in a support | pillar. It is a flowchart which shows the sheet | seat control process based on wind power information.

10: Winding part, 11: Battery sheet, 12: Housing, 13: Winding roll, 14, 15: Tension roll, 16: Power generation film, 21: Winding motor, 22, 23, 24: Clutch, 25: Drawer motor, 30: control unit, 31: sensor group, 40: power storage unit, 41: terminal, 50: ground, 51: turf portion, 61: vehicle, 62: window, 71: private house, 72: window, 81: support

Embodiments of the present invention will be described below.
[First Embodiment]
As shown in FIGS. 1A and 1B, the take-up solar cell 1 includes a take-up unit 10, a control unit 30 that controls the take-up unit 10, and a power storage unit 40 that stores a part of the generated power. ing.

The winding part 10 is a structure for accommodating the battery sheet 11 which has flexibility. The battery sheet 11 is formed by bonding protective sheets to both surfaces of a film-like solar cell. The take-up unit 10 includes a housing 12, a take-up roll 13, and two tension rolls 14 and 15 in order to accommodate the battery sheet 11. The tension roll 15 is disposed so as to overlap the lower side of the tension roll 14.

The take-up roll 13 is rotated by a take-up motor 21. The driving force of the take-up motor 21 is transmitted to the take-up roll 13 through the clutch 22. Thereby, the speed and torque of the winding roll 13 are controlled.

The tension rolls 14 and 15 are provided in parallel with the take-up roll 13 and serve as a guide when the battery sheet 11 is taken up by the take-up roll 13. Specifically, clutches 23 and 24 are respectively attached to the tension rolls 14 and 15, and tension acts in the winding direction over the width direction of the battery sheet 11 during winding. Thereby, meandering of the battery sheet 11 is suppressed when the battery sheet 11 is taken up by the take-up roll 13.

The control unit 30 is configured as a so-called computer system, and includes a CPU, a ROM, a RAM, an I / O, and a bus line connecting them. A sensor group 31 is connected to the control unit 30. Thereby, the control part 30 performs the sheet | seat control process mentioned later based on the signal from the sensor group 31, and winds up the battery sheet | seat 11 when predetermined conditions are satisfied.

The power storage unit 40 is configured to store a part of the power generated by the battery sheet 11. The electric power generated by the battery sheet 11 is collected by the take-up roll 13 and taken out from the terminal 41. A part of the electric power taken out from the terminal 41 is accumulated in the power storage unit 40, and the remaining part is supplied to the outside and used.

[Example 1-1]
Next, specific installation of the winding solar cell 1 will be described. As shown in FIG. 2A, is an explanatory view showing a state in which the battery sheet 11 is installed so as to cover the ground 50. Here, the plurality of winding portions 10 are arranged, and the battery sheet 11 covers the ground 50 in a state where the winding portions 10 are drawn out from the winding portions 10.

Here, an example of the sheet control processing of the winding solar cell installed on the ground 50 will be described with reference to FIG. This sheet control process is repeatedly executed by the control unit 30. Here, the description will be continued assuming that the sensor group 31 includes a rainfall sensor and a humidity sensor.

In the first S100, rainfall information is acquired. This process acquires a signal from a rain sensor included in the sensor group 31.
In continuing S110, it is judged whether it is raining. This process determines whether or not it is raining based on a signal from the rain sensor. If it is determined that it is raining (S110: YES), the process proceeds to S120. On the other hand, if it is determined that it is not raining (S110: NO), the subsequent processing is not executed and the sheet control processing is terminated.

In S120, humidity information is acquired. In this process, a signal from a humidity sensor included in the sensor group 31 is acquired. The humidity sensor measures the humidity of the ground 50.
In the next S130, it is determined whether or not the humidity is equal to or lower than a threshold value. This process is to determine the humidity of the gland 50. If the gland 50 is dried to some extent, a positive determination is made here. If it is determined that the humidity is equal to or lower than the threshold value (S130: YES), that is, if the gland 50 is somewhat dry, the battery sheet 11 is wound up in S140, and the sheet control process is terminated. On the other hand, when it is determined that the humidity exceeds the threshold (S130: NO), the process of S140 is not executed, and the sheet control process is terminated.

That is, when the ground 50 is somewhat dry (S130: YES), winding control is performed (S140) so that the ground 50 is rained. On the other hand, when the ground 50 is sufficiently damp (S130: NO), the battery sheet 11 serves as a rain guard for the ground 50.

Next, another example of the sheet control processing of the winding solar cell installed on the ground 50 will be described with reference to FIG. 4A. This sheet control process is repeatedly executed by the control unit 30. Here, the description will be continued assuming that the sensor group 31 includes a wind sensor.

In the first S200, wind power information is acquired. This process acquires a signal from a wind sensor included in the sensor group 31.
In continuing S210, it is judged whether a wind force is more than a threshold value. This process determines whether or not the wind power is so large that the battery sheet 11 is turned up. If it is determined that the wind force is greater than or equal to the threshold value (S210: YES), the winding control is performed in S220, and the sheet control process is terminated. On the other hand, when it is determined that the wind power is below the threshold (S210: NO), the process of S220 is not executed, and the sheet control process is terminated.

That is, when the wind force is large to some extent (S210: YES), the winding control is performed (S220) to protect the battery sheet 11.
Next, another example of the sheet control process for the take-up solar cell installed on the ground 50 will be described with reference to FIG. 4B. This sheet control process is repeatedly executed by the control unit 30. Here, the description will be continued assuming that the sensor group 31 includes an optical sensor.

In the first S300, sunshine information is acquired. This process acquires a signal from an optical sensor included in the sensor group 31.
In continuing S310, it is judged whether sunshine is below a threshold value. This process is to determine whether or not there is effective sunlight for power generation in the battery sheet 11. If it is determined that the sunshine is below the threshold value (S310: YES), the winding control is performed in S320, and the sheet control process is terminated. On the other hand, when it is determined that the sunshine exceeds the threshold (S310: NO), the process of S320 is not executed and the sheet control process is terminated.

That is, when the sunshine is small (S310: YES), since effective power generation cannot be performed, the winding control is performed (S220), and the ground 50 can be used at any time.

Now, let us consider a case in which a lawn portion 51 exists on the ground 50 as indicated by a broken line in FIG. 2A. In this case, the grass portion 51 is more likely to require moisture than the soil portion. Therefore, it is conceivable to set different threshold values in S130 in FIG. 3 between the wind-up battery that covers the turf portion 51 and the wind-up battery that covers the soil portion. In this way, it is possible to wind up only the battery sheet 11 covering the turf portion 51 without winding up the battery sheet 11 covering the soil portion.

Similarly, as shown in FIG. 2B, consider a case where a turf portion 51 exists on the tip side of the battery sheet 11 in the ground 50. In this case, for example, it is conceivable to execute the sheet control process shown in FIG.

Here, the processing of S400 to S420 is the same as the processing of S100 to S120 in FIG. That is, rainfall information is acquired (S400), and when it is determined that it is raining (S410: YES), humidity information is acquired (S420).

In subsequent S430, it is determined whether the humidity is equal to or lower than the first threshold value. If it is determined that the humidity is equal to or lower than the first threshold value (S430: YES), the intermediate winding control is executed in S440, and the process proceeds to S450. The midway winding control in S440 is to wind up the battery sheet 11 until the tip of the battery sheet 11 comes to the position of the two-dot chain line indicated by the symbol A in FIG. On the other hand, when it is determined that the humidity exceeds the first threshold (S430: NO), the subsequent process is not executed and the sheet control process is terminated.

In the next S450, it is determined whether the humidity is equal to or lower than the second threshold value. The second threshold is set as a value smaller than the first threshold. If it is determined that the humidity is equal to or lower than the second threshold value (S450: YES), all winding control is executed in S460, and the sheet control process is terminated. On the other hand, when it is determined that the humidity exceeds the second threshold (S450: NO), the process of S460 is not executed and the sheet control process is terminated.

That is, when the humidity is higher than the first threshold (S430: NO), when the ground 50 has sufficient moisture, the winding of the battery sheet 11 is not controlled and the battery sheet 11 is protected from rain. Use as

Further, when the humidity is equal to or lower than the first threshold value (S430: YES) and exceeds the second threshold value (S450: NO), the intermediate winding control of the battery sheet 11 is performed (S440), and only the turf portion 51 is rained. As for the soil portion, the battery sheet 11 is used as a rain guard.

Furthermore, when the humidity is equal to or lower than the second threshold (S430: YES, S450: YES), the entire winding of the battery sheet 11 is controlled so that not only the grass portion 51 but also the entire ground 50 is rained.

As detailed above, according to the present embodiment, whether it is raining, whether the humidity is high, whether the wind is strong, whether there is sunshine necessary for power generation, The winding timing of the battery sheet can be determined. As a result, installation on the ground 50 is realized.

In the sheet control process shown in FIG. 3, when the ground 50 is somewhat dry (S130: YES), the winding control is performed (S140), and the ground 50 is rained. On the other hand, when the ground 50 is sufficiently damp (S130: NO), the battery sheet 11 serves as a rain guard for the ground 50. Thereby, the ground 50 can be maintained in an optimum state.

Furthermore, in the sheet control process shown in FIG. 4A, when the wind force is somewhat large (S210: YES), the winding control is performed (S220) to protect the battery sheet 11. Thereby, the battery sheet 11 can be protected appropriately.

Further, in the sheet control process shown in FIG. 4B, when the sunshine is small (S310: YES), effective power generation cannot be performed, and therefore winding control is performed (S220). Thereby, the ground 50 can be used effectively.

Furthermore, in the sheet control process shown in FIG. 5, when the gland 50 has sufficient moisture (S430: NO), the winding control of the battery sheet 11 is not performed and the battery sheet 11 is protected from rain. Use as Further, when the humidity is equal to or lower than the first threshold value (S430: YES) and exceeds the second threshold value (S450: NO), the intermediate winding control of the battery sheet 11 is performed (S440), and only the turf portion 51 is rained. As for the soil portion, the battery sheet 11 is used as a rain guard. Furthermore, when the humidity is equal to or lower than the second threshold (S430: YES, S450: YES), the entire winding of the battery sheet 11 is controlled so that not only the grass portion 51 but also the entire ground 50 is rained. Thereby, even if there is a turf portion 51, the ground 50 can be maintained in an optimum state.

In addition, although the present Example demonstrated installation of the winding type solar cell to the ground 50, when installing in a parking lot or a park, the same sheet | seat control process is employable.
[Example 1-2]
In addition, although the above demonstrated the case where a winding type solar cell was installed in the ground 50, it is possible to install the battery sheet 11 on the sea surface similarly. In this case, the battery sheet 11 is provided with a waterproof function, and a float or the like is attached to the tip so that the battery sheet 11 floats on the sea surface. Also in this case, like the ground 50, the sea surface can be effectively used for power generation.

At this time, an example of the sheet control processing of the winding solar cell installed on the sea surface will be described with reference to FIG. This sheet control process is repeatedly executed by the control unit 30. Here, the description will be continued assuming that the sensor group 31 includes a wave height sensor.

In the first S500, wave height information is acquired. This process acquires a signal from a wave height sensor included in the sensor group 31.
In continuing S510, it is judged whether a wave height is more than a threshold value. This process determines whether the wave height is so large that the power generation by the battery sheet 11 is difficult. If it is determined that the wave height is equal to or greater than the threshold (S510: YES), winding control is performed in S520, and the sheet control process is terminated. On the other hand, when it is determined that the wave height is below the threshold (S510: NO), the process of S520 is not executed and the sheet control process is terminated.

That is, in a state where the wave height is large (S510: YES), effective power generation cannot be performed. Therefore, winding control is performed (S520), and the battery sheet 11 is accommodated and protected.
In addition, also when installing a wind-up type solar cell on the sea surface, the seat control process based on the wind power information shown in FIG. 4A and the sheet control process based on the sunshine information shown in FIG. You may make it perform.

As described in detail above, according to the present embodiment, installation of the wind-up solar cell on the sea surface is realized. Further, in the sheet control process shown in FIG. 6, when the wave height is large (S510: YES), effective power generation cannot be performed, and therefore winding control is performed (S520). Thereby, the battery sheet 11 is appropriately protected.

[Second Embodiment]
FIG. 7 is a schematic plan view of the winding solar cell of the present embodiment.
The take-up solar cell has substantially the same configuration as that of the first embodiment. Accordingly, different components will be described below, and similar components will be described with the same reference numerals.

The difference from the first embodiment is that one tension roll 14 is rotated by a drawing motor 25. The driving force of the drawing motor 25 is transmitted to the tension roll 14 via the clutch 23. Thereby, the speed and torque of the tension roll 14 are controlled. With this configuration, not only winding of the battery sheet 11 but also drawing of the battery sheet 11 is possible.

[Example 2-1]
Next, specific installation of the winding solar cell will be described. As shown in FIG. 8A, the winding unit 10 may be attached to the outside of the vehicle or may be attached to the inside of the vehicle. In any case, the battery sheet 11 covers the window like a so-called roll curtain.

At this time, an example of the sheet control processing of the retractable solar cell installed on the window of the vehicle 61 will be described based on FIGS. 9A and 9B. This sheet control process is repeatedly executed by the control unit 30. Here, the description will be continued assuming that the sensor group 31 includes a sensor for acquiring ignition information. The vehicle 61 is provided with an ignition switch, and when the ignition switch is turned on, a battery voltage is supplied to an ignition power line in the vehicle. At this time, the ignition is turned on. On the other hand, when the ignition switch is turned off, the supply of the battery voltage to the ignition power supply line is cut off. At this time, the ignition is turned off. Therefore, the sensor that acquires the ignition information acquires whether the ignition is in an ignition-on state or an ignition-off state.

In S600 of FIG. 9A, it is determined whether or not the ignition switch is turned on. If it is determined that the ignition switch is turned on (S600: YES), the winding control is executed in S610, and the sheet control process is terminated. On the other hand, if it is determined that the ignition switch is not turned on (S600: NO), the process of S610 is not executed and the sheet control process is terminated.

That is, for example, the battery sheet 11 covering the window 62 during parking is wound up by turning on the ignition switch (S600: YES, S610).
In S700 of FIG. 9B, it is determined whether or not the ignition switch is turned off. If it is determined that the ignition switch is turned off (S700: YES), the drawer control is executed in S710, and the sheet control process is terminated. On the other hand, if it is determined that the ignition switch is not turned off (S700: NO), the process of S710 is not executed and the sheet control process is terminated.

That is, the battery sheet 11 that has been stored while traveling is pulled out by turning off the ignition switch (S700: YES, S710).
In addition, although installation of the winding type solar cell to the side window 62 of the vehicle 61 was described here, it can be similarly installed to the front window and the rear window. Moreover, you may spread a battery sheet so that the upper surface of a bonnet, a roof, and a trunk may be covered.

As described in detail above, according to the present embodiment, the battery sheet 11 is installed in the vehicle so as to cover the window of the vehicle, so that the battery sheet 11 is shaded or blindfolded. Thereby, a crime prevention effect is produced.

In the seat control process shown in FIG. 9A, the battery sheet 11 covering the window during parking is wound by turning on the ignition switch (S600: YES, S610), which is convenient.

Furthermore, in the seat control process shown in FIG. 9B, the battery sheet 11 that has been stored during traveling is pulled out by turning off the ignition switch (S700: YES, S710), which is convenient.

[Example 2-2]
Moreover, the specific installation of a wind-up type solar cell is demonstrated. As shown in FIG. 8B, the drawn battery sheet 11 spreads like a cloak as the vehicle travels. That is, the front end side of the battery sheet 11 is a free end and spreads with wind.

At this time, an example of the sheet control processing of the retractable solar cell installed at the rear of the vehicle will be described. FIG. 10 is a flowchart showing the sheet control process based on the speed information. This sheet control process is repeatedly executed by the control unit 30. Here, the description will be continued assuming that the sensor group 31 includes a vehicle speed sensor.

In the first S800, speed information is acquired. This process acquires a signal from a vehicle speed sensor included in the sensor group 31.
In subsequent S810, it is determined whether or not the speed is equal to or higher than a threshold value. This process is to determine whether or not the battery sheet 11 has a vehicle speed that allows the wind to fly. If it is determined that the vehicle speed is equal to or higher than the threshold value (S810: YES), the drawer control is performed in S820, and the seat control process is terminated. On the other hand, when it is determined that the vehicle speed falls below the threshold value (S810: NO), the winding control is performed in S830, and the sheet control process is terminated.

That is, when the vehicle speed becomes equal to or higher than the threshold value during traveling (S810: YES), that is, in the case of high speed traveling, the drawer control for spreading the battery seat 11 like a cloak is performed, and when the vehicle speed falls below the threshold value (S810: NO), that is, when the vehicle is running at a low speed or stopped, the winding control is performed to accommodate the battery sheet 11.

As described in detail above, according to the present embodiment, the battery seat 11 is spread to the rear of the vehicle, so that it is possible to generate electric power while traveling. Further, according to the seat control process shown in FIG. 10, when the vehicle is traveling at a low speed or stopped (S810: NO), the battery sheet 11 is accommodated (S830), so that the battery sheet 11 is appropriately protected. Can do.

In addition, if the sheet itself is caused to emit light by power generation of the battery sheet 11, safety during traveling can be improved.
[Example 2-3]
Furthermore, specific installation of the wind-up solar cell will be described with reference to FIG.

At this time, an example of the sheet control processing of the winding solar cell installed in the window 72 of the private house 71 will be described. 12A and 12B are flowcharts showing the sheet control process based on the human figure information. This sheet control process is repeatedly executed by the control unit 30. Here, the description will be continued assuming that the sensor group 31 includes an infrared sensor.

In S900 of FIG. 12A, the image information is acquired. This process acquires a signal from an infrared sensor included in the sensor group 31.
In subsequent S910, it is determined whether there is a human figure. This process determines the approach of a person approaching the battery sheet 11. If it is determined that there is a human figure (S910: YES), winding control is performed in S920, and the sheet control process is terminated. On the other hand, if it is determined that there is no human figure (S910: NO), the process of S920 is not executed and the sheet control process is terminated.

That is, the approach of the suspicious person etc. to the battery sheet 11 is determined (S910: YES), and the battery sheet 11 is wound up (S920).
In S1000 of FIG. 12B, the silhouette information is acquired. This process acquires a signal from an infrared sensor included in the sensor group 31.

In subsequent S1010, it is determined whether there is no figure for a predetermined time. This process determines whether or not the person approaching the battery sheet 11 has not approached for a predetermined time. If it is determined that there is no human figure for a predetermined time (S1010: YES), drawer control is performed in S1020, and the sheet control process is terminated. On the other hand, if it is determined that there is a human figure within the predetermined time (S1010: NO), the process of S1020 is not executed and the sheet control process is terminated.

That is, when it is determined that there is no human figure for a predetermined time (S1010: YES), the battery sheet 11 is pulled out (S1020) and used as a sunshade or blindfold.
As described in detail above, according to this embodiment, the battery sheet 11 is shaded or blindfolded, contributing to power saving measures and crime prevention measures.

Further, in the sheet control process shown in FIG. 12A, the approach of a suspicious person or the like to the battery sheet 11 is determined (S910: YES), and the battery sheet 11 is wound up (S920), which is a further crime prevention measure.

[Example 2-4]
Moreover, the specific installation of a wind-up type solar cell is demonstrated. As shown in FIG. 13B, the battery sheet 11 spreads in the wind. However, when the wind is too strong, as shown in FIG. 13A, the battery sheet 11 flutters to reduce the power generation efficiency and cause deterioration of the battery sheet 11. On the other hand, when the wind is too weak, the battery sheet 11 does not spread well as shown in FIG.

Here, an example of the sheet control processing of the winding solar cell installed on the support column 81 standing on the ground will be described with reference to FIG. This sheet control process is repeatedly executed by the control unit 30. Here, the description will be continued assuming that the sensor group 31 includes a wind sensor.

In the first S1100, wind power information is acquired. This process acquires a signal from a wind sensor included in the sensor group 31.
In subsequent S1110, it is determined whether or not the wind force is in the optimum range. In this process, as shown in FIG. 13B, the battery sheet 11 determines the wind force that spreads in the wind. If it is determined that the wind power is within the optimum range (S1110: YES), the drawer control is performed in S1120, and the sheet control process is terminated. On the other hand, when it is determined that the wind power is not in the optimum range (S1110: NO), the winding control is performed in S1130, and the sheet control process is terminated.

That is, when the battery sheet 11 flutters as shown in FIG. 13A or when the battery sheet does not spread and hangs down as shown in FIG. 13C (S1110: NO), the winding control is performed (S1130), while FIG. In the situation where it spreads in the wind as shown (S1110: YES), the drawer control is performed (S1120).

Thereby, it is possible to generate power using the space effectively. Further, the battery sheet 11 is appropriately protected by the sheet control process shown in FIG.
[Other Embodiments]
(A) In the said 1st and 2nd embodiment, the battery sheet 11 was formed by bonding a protective sheet on both surfaces of a film-form solar cell. On the other hand, as shown in FIGS. 1A and 1B, a power generation film 16 may be laminated on the battery sheet 11. The power generation film 16 is a film that converts kinetic energy such as vibration into electric energy. In this way, the battery sheet 11 on which the power generation film 16 is laminated generates power by vibration or the like, not only in the expanded state but also in the wound state, so that power generation can be performed more efficiently.

(B) A roll-up solar cell may be installed so that the battery sheet 11 becomes a banner of the building. If it does in this way, the battery sheet 11 can be utilized as an awning of a building. Further, an advertising effect can be obtained by placing an advertisement on the tip of the battery sheet 11 or the like.

For example, the battery sheet 11 may be attached to a balloon (for example, an advertising balloon). In this case, when the wind or rain is strong, it is conceivable to wind the battery sheet by winding the balloon wire.

Furthermore, for example, the battery sheet 11 may be attached to the bag. In this case, it is conceivable to wind the battery sheet by winding the kite string when wind and rain are strong. In the sense of securing the installation area of the battery sheet, a combination may be used.

(C) A roll-up solar cell may be installed so that the battery sheet 11 is passed over the roofs of two buildings. If it does in this way, the battery sheet 11 can be utilized as an awning or rain protection of the person who walks between buildings. In addition, you may make it pass the battery sheet 11 not only to a building but to the opening-and-closing part of an open dome, the ceiling part of a greenhouse, and the roof part of an arcade.

(D) In the first embodiment, the winding solar cell is installed so that the battery sheet 11 covers the ground 50 and the like, and the configuration in which the battery sheet 11 is wound up is shown. On the other hand, the battery sheet 11 can be pulled out as in the second embodiment, and a leaf spring or the like is provided along both edges of the battery sheet 11 so that the battery sheet 11 is pulled out in the horizontal direction. If the battery sheet 11 can be pulled out, the battery sheet 11 can be pulled out to automatically cover a nearly horizontal surface such as the ground 50.

(E) The battery sheet 11 may be provided on a hat or the like, and a fashion hat for women drawn out so as to cover the neck and ears when the sun shines may be configured. If it does in this way, while improving the efficiency of electric power generation, the battery sheet | seat 11 can be functioned as an awning or rain protection.

Claims (21)

1. A windable battery sheet having a film-like solar cell;
   A winding unit capable of winding and accommodating the battery sheet;
   An acquisition unit for acquiring information from outside;
   Based on information from the acquisition unit, when a predetermined condition is satisfied, a control unit that executes at least one of winding control and pulling-out control of the battery sheet by driving the winding unit;
   A wind-up solar cell.
2. The battery sheet is a take-up solar cell in which a power generation film that converts kinetic energy including vibration into electric energy is laminated.
3. In the winding solar cell according to claim 1 or 2,
   The battery sheet is installed so as to cover the ground surface in a state where the battery sheet is pulled out from the winding part,
   The acquisition unit acquires at least one of rainfall information, humidity information, wind power information, and sunshine information,
   The said control part is a winding-type solar cell which performs winding-up control of the said battery sheet, when predetermined conditions are satisfied based on the information from the said acquisition part.
4. The wind-up solar cell according to claim 3,
   The acquisition unit acquires at least rainfall information and humidity information,
   When the control unit determines that it is raining based on the rainfall information, the control unit executes winding control of the battery sheet according to the dryness of the ground surface based on the humidity information. battery.
5. In the winding solar cell according to claim 1 or 2,
   The battery sheet is installed so as to cover the sea surface in a state of being pulled out from the winding part,
   The acquisition unit acquires at least one of wave height information, wind power information, and sunshine information,
   The said control part is a winding-type solar cell which performs winding-up control of the said battery sheet, when predetermined conditions are satisfied based on the information from the said acquisition part.
6. The wind-up solar cell according to claim 5,
   The acquisition unit acquires at least wave height information,
   The said control part is a winding-type solar cell which performs winding-up control of the said battery sheet according to the wave height based on the said wave height information.
7. In the winding solar cell according to claim 1 or 2,
   The battery sheet is installed so as to cover a vehicle window in a state where the battery sheet is pulled out from the winding unit,
   The acquisition unit acquires ignition information indicating whether the vehicle is in an ignition-on state or an ignition-off state,
   The control unit is a take-up solar cell that executes at least one of winding control and pulling-out control of the battery sheet when a predetermined condition is satisfied based on information from the acquisition unit.
8. In the winding solar cell according to claim 7,
   The said control part is a winding-type solar cell which performs winding-up control of the said battery sheet, when it determines with the said vehicle having been in the said ignition ON state based on the said ignition information.
9. The roll-up solar cell according to claim 7 or 8,
   The said control part is a winding-type solar cell which performs drawer | drawing-out control of the said battery sheet, when it determines with the said vehicle having been in the said ignition-off state based on the said ignition information.
10. In the winding solar cell according to claim 1 or 2,
    The battery sheet is installed so as to spread toward the rear of the vehicle by running the vehicle in a state where the battery sheet is pulled out from the winding portion,
    The acquisition unit acquires vehicle speed information,
    The control unit is a take-up solar cell that executes at least one of winding control and pulling-out control of the battery sheet when a predetermined condition is satisfied based on information from the acquisition unit.
11. In the winding solar cell according to claim 10,
    The control unit, based on the vehicle speed information, executes the battery sheet pull-out control when the vehicle speed becomes a predetermined speed or more, and executes the battery sheet winding control when the vehicle speed falls below the predetermined speed. battery.
12. In the winding solar cell according to claim 1 or 2,
    The battery sheet is installed so as to cover the window of the building in a state where the battery sheet is pulled out from the winding part,
    The acquisition unit acquires image information about the approach of a person,
    The control unit is a take-up solar cell that executes at least one of winding control and pulling-out control of the battery sheet when a predetermined condition is satisfied based on information from the acquisition unit.
13. The wind-up solar cell according to claim 12,
    The said control part is a winding-type solar cell which performs winding-up control of the said battery sheet, if the approach of a person is judged based on the said human figure information.
14. The wind-up solar cell according to claim 12 or 13,
    When the control unit determines that there is no person based on the human figure information, the control unit executes pull-out control of the battery sheet.
15. In the winding solar cell according to claim 1 or 2,
    The battery sheet is installed on a column extending toward the air so as to spread in the wind in a state where the battery sheet is pulled out from the winding unit,
    The acquisition unit acquires wind power information,
    The control unit is a take-up solar cell that executes at least one of winding control and pulling-out control of the battery sheet when a predetermined condition is satisfied based on information from the acquisition unit.
16. The wind-up solar cell according to claim 15,
    The control unit executes pull-out control of the battery sheet in a wind force range in which the battery sheet spreads in the wind based on the wind power information, and executes winding control of the battery sheet when out of the wind force range. Rewindable solar cell.
17. In the winding solar cell according to claim 1 or 2,
    The battery sheet is installed in the building so as to be a banner of the building wall surface in a state where the battery sheet is pulled out from the winding part,
    The acquisition unit acquires wind power information,
    The control unit is a take-up solar cell that executes at least one of winding control and pulling-out control of the battery sheet when a predetermined condition is satisfied based on information from the acquisition unit.
18. The take-up solar cell according to any one of claims 1 to 17,
    A power storage unit that stores power generated by the battery sheet,
    The said control part is a winding-type solar cell which performs at least one of the said winding control and the said drawer | drawing-out control using the electric power accumulate | stored in the said electrical storage part.
19. The take-up solar cell according to any one of claims 1 to 18,
    The winding part is
    A winding roll for fixing one end of the battery sheet and winding the battery sheet from the one end;
    A winding drive unit for driving and rotating the winding roll so as to wind up the battery sheet;
    A wind-up solar cell.
20. The take-up solar cell according to claim 19,
    The winding unit is provided in parallel with the winding roll, and has a tension roll that generates tension in the winding direction across the width direction of the battery sheet when the battery sheet is wound by the winding roll. Rewindable solar cell.
21. The take-up solar cell according to claim 20,
    A take-up solar cell having a pull-out driving unit that drives and rotates the tension roll so as to pull out the battery sheet.

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