JP2007113255A - Power generation system for bus stop waiting spot - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power generation system for a bus stop waiting spot by using a simple solar cell necessary for a small installation space at a low installation cost. <P>SOLUTION: The film-shaped solar cell 2 is stuck on a bus waiting spot roof surface 30a to form the power generation system by making the film-shaped solar cell 2 as a power source. Therefor, since it is stuck on the roof surface, the power generation system can be strong against strong wind as well as earthquake resistance at a low installation cost. It is not necessary for the conventional mounting holder of the solar cell, and the special installation space is also eliminated. The large roof surface 30a of the bus stop waiting spot can be effectively utilized, it can be also contributed in terms of energy saving and measures against global warming. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a power generation system for a bus stop using a solar cell.

  It is normal to use commercial power for lighting at bus stops. In addition, power supplies such as lighting during power outages have not been secured. Recently, a bus stop is provided with a wireless LAN or the like, and the operation status of the bus is displayed every moment. It is necessary to secure a stable power supply for this purpose.

On the other hand, it has been considered to arrange a solar cell panel on the roof of a building such as a house (see Patent Document 1).
JP 2001-040888 A (FIG. 1, abstract)

  However, in order to install solar cells on the roofs of these buildings, a strong mounting frame is necessary for strong winds and earthquake resistance measures, and the solar cells on the panel have been installed on the solid frame. This solid platform increases installation costs and labor. There are many places where bus stops are located in sunny places, and the installation of solar cells on the roof is desirable in terms of securing a stable power source, saving energy, and combating global warming.

  Therefore, an object of the present invention is to provide a power generation system for a bus stop using a solar cell that is simple and has a small installation space and low installation cost for the bus stop.

  In order to solve the above-described problems, in the present invention, a film-type solar cell is attached to a roof surface of a bus stop, and a power generation system for a bus stop using the film-type solar cell as a power source is provided. As a result, since it is attached to the roof surface, it is possible to provide a power generation system that is strong against strong winds, has earthquake resistance, and has low installation costs. A conventional solar cell panel mounting base is not required, and no special installation space is required. Furthermore, the wide roof surface of the bus stop can be used effectively, contributing to energy saving and global warming countermeasures.

  In addition, if the power generation system for a bus stop that sticks the film solar cell around the south slope of the roof surface of the bus stop, the power generation efficiency of the film solar cell can be increased.

  If the film solar cell is a power generation system for a bus stop where the film solar cell is connected to a light sensor, a storage battery and a load via a charge / discharge controller, the film solar cell includes a secondary battery for storing electric power, a wireless LAN relay machine and an illumination Stable power can be supplied to loads such as appliances. There is a possibility that a commercial power cable is not required by sticking and utilizing film-type solar cells on the wide roof surface of the bus stop and a self-sustaining power generation system using solar cells. It can also be used as an emergency power supply system in the event of a power failure, and can supply power to loads such as wireless LAN relays and night lighting.

  In addition, if the load is a power generation system for a bus stop including at least a wireless LAN relay as the load, it can be used as an emergency power supply system for power outages in the event of a disaster, and a wireless LAN can be used for evacuation guidance, damage status bulletins It is possible to make a great contribution to information transmission during disasters. The antenna of the wireless LAN repeater may be used for satellite communication.

  In addition, if the load is a power generation system for a bus stop including at least a wireless LAN relay machine and a display device connected thereto, the bus operation status, news, etc. are normally displayed on a display device such as an LED bulletin board or a liquid crystal display. In addition to being able to display advertisements, it can be used as an emergency power supply system for power outages in the event of a disaster, and information from disaster centers (installed in ward offices and city offices, etc.) for evacuation guidance, damage status bulletins, etc. It can be displayed using the wireless LAN, and if the evacuation area is displayed, or if the evacuee can be transported, the evacuation bus will come "when" or "to which evacuation center" The contribution to correspondence information transmission is large.

  Moreover, if it is set as the power generation system for bus stop places which also used the commercial power supply as a power supply with the said film type solar cell, it can respond to a bigger electric power and can supply more stable electric power.

  According to the present invention, a film-type solar cell is attached to the roof surface of a bus stop and the power generation system for a bus stop using the film-type solar cell as a power source. It can be a power generation system that is strong, earthquake resistant, and has low installation costs. A conventional solar cell panel mounting base is not required, and no special installation space is required. Furthermore, the wide roof surface of the bus stop can be used effectively, contributing to energy saving and global warming countermeasures.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a configuration diagram of a self-supporting bus stop power generation system using solar cells according to an embodiment of the present invention. The self-supporting power generation system 1 using solar cells includes film solar cells 2, 2, 2. A junction box 3 that electrically connects the film-type solar cells 2, 2, and 2 together, and the junction box 3 is connected to a photosensor 5 and a storage battery 6 (here, for cycle use) via a charge / discharge controller 4. Lead acid battery) and a load 9. Illustrative examples of the load 9 include a lighting fixture 7 and a wireless LAN relay 8 that is wirelessly connected to the center 10. Although it is desirable to provide the connection box 3, the connection box 3 can be omitted by connection with the charge / discharge controller 4.

  When the signal from the optical sensor 5 indicates that the optical sensor 5 is receiving light, the charge / discharge controller 4 stores the generated power of the solar battery from the connection box 3 in the storage battery 6. When the signal from the optical sensor 5 indicates that the optical sensor 5 is not receiving light, power from the storage battery 6 is supplied to the load 9.

  In this way, the storage battery 6 is charged during the daytime when sunlight is present, and a light-emitting element such as a load, such as a lamp, is turned on by electricity from the storage battery 6 at night when there is no sunlight. That is, a self-supporting power generation system using solar cells that charge the storage battery 6 with sunlight in the daytime and discharge from the storage battery 6 at night is configured.

  In this embodiment, if a commercial interconnection point is provided between the charge / discharge controller 4 and the load 9 via a power conditioner and is connected to a commercial power source, the commercial power source is used as a power source together with the film type solar cell. It can be changed to a power generation system of the form.

  The film-type solar cell 2 is a flexible solar cell formed on a plastic film 22 and is lighter than a rigid solar cell, as shown in FIG.

  In this embodiment, as shown in a plan view in FIG. 3 and an elevation view in FIG. 4, it is integrated with a steel plate for convenience of handling. That is, as shown in FIG. 3, the unit module of the film-type solar cell 2 is composed of four solar cells in series, two in parallel. As shown in FIGS. 3 and 4, the unit module of the film solar cell 2 is attached to a thin steel plate 25 with an adhesive 26, and the surface is coated with a coating material 27 to form a steel plate integrated unit module 20. Here, the steel plate 25 is a Galvalume steel plate coated with a 0.8 mm-thick fluororesin, and the adhesive 26 is ethylene bisol acetate (EVA). The coating material 27 is ethylene tetrafluoroethylene (ETFE). A conductive terminal 28 from the film type solar cell 2 extends to the terminal box 24 and the connector 23 on the back side of the steel plate 25.

  By using such a steel plate integrated unit module 20, the solar cell can be handled easily and has excellent weather resistance. Since the sheet of the film-type solar cell 2 is used, it can withstand deformation of the steel plate and further deformation after laying.

  FIG. 5 is a perspective view showing a state in which the steel sheet integrated unit module 20 of the film type solar cell is attached to the roof surface 30 a of the bus stop waiting area roof 30.

  In this example, the bus stop waiting area roof 30 has a semi-cylindrical shape (a shape obtained by cutting out a part of the outer periphery of the cylinder), and the film-type solar cell 2 is attached to a part or all of the roof surface 30a with an adhesive. is there. The area and arrangement of the film solar cell 2 can be freely selected. For example, if the right side of the bus stop roof 30 is in the south direction, the film solar cell 2 is attached with the right slope of the bus stop roof 30 as the center. It is desirable to increase the power generation efficiency of the film type solar cell 2. FIG. 5 exemplifies how the lighting fixture 7 and the wireless LAN repeater 8 are attached.

  If it is a load generation system for a bus stop including a wireless LAN relay as a load, it can be used as an emergency power supply system for power outages in the event of a disaster, and a wireless LAN can be used for evacuation guidance, breaking damage reports, parks, etc. The contribution to information transmission at evacuation sites is great. The antenna of the wireless LAN repeater may be used for satellite communication.

  Also, if the load is a bus stop power generation system including a wireless LAN relay machine and a display device connected to the wireless LAN relay as a load, the bus operation status, news and advertisements are usually displayed on a display device such as an LED bulletin board or a liquid crystal display. Can be used as an emergency power supply system for power outages in the event of a disaster, and information from the disaster center (installed at the ward office or city office, etc.) can be used wirelessly via a network for evacuation guidance, breaking news on damage, etc. It can be displayed using the LAN, and if the evacuation area can be displayed, or if the evacuee can be transported, the evacuation bus will be "when will be coming" or "to which evacuation place", etc. The contribution to is great.

  The steel sheet integrated unit modules 20 of the film-type solar cell are connected to each other by a connector 23 and connected to the connection box 3 shown in FIG.

  Thus, a conventional solar panel mounting base is not required. Moreover, wind resistance and earthquake resistance can be easily obtained by sticking directly to the bus stop waiting area roof 30. Moreover, it becomes unnecessary to provide a solar cell installation space specially. Moreover, although the sticking direction of the film-type solar cell 2 is set to be perpendicular to the longitudinal side of the bus stop waiting area roof surface 30, it can be arranged in a tile-like manner in parallel.

  In this embodiment, an example in which the steel sheet integrated unit module 20 of the film type solar cell is used because it is easy to handle has been shown. However, in another embodiment, the solar cell is not a steel plate integrated unit module. It may be desirable to use a film-type solar cell unit module in which the upper and lower surfaces of the cell are covered with ethylene tetrafluoroethylene (ETFE) and the lower surface is covered with an adhesive such as ethylene bisol acetate (EVA).

  In consideration of both unit modules, the expression “film solar cell” is used in the description of the present application except when necessary for the description of the above-described embodiment.

  As described above, the power generation system for a bus stop using a film-type solar cell according to the present invention can save installation space, labor, and installation cost, and can be used industrially as a contribution to disaster utilization and global warming countermeasures. The availability is great.

It is a lineblock diagram of the power generation system for bus stop waiting places using the film type solar cell as one embodiment by the present invention. It is an external view of an example of the sheet | seat of the film type solar cell used by this invention. It is a top view which shows an example of the unit module of the film-type solar cell made into the steel plate and an integral structure. Sectional drawing along the centerline of the film type solar cell of FIG. 3 is shown. It is a perspective view which shows the state which stuck and arranged the film type solar cell shown in FIG. 3 on the roof surface of a bus stop waiting place roof.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Power generation system, 2 Film type solar cell, 3 Junction box, 4 Charge / discharge controller, 5 Optical sensor, 6 Storage battery, 7 Lighting fixture, 8 Wireless LAN relay machine, 9 Load, 10 center, 20 Steel plate integrated unit module, 22 Plastic film, 23 connector, 24 terminal box, 25 steel plate, 26 adhesive, 27 coating material, 28 conductive terminal, 30 bus stop roof, 30a bus stop roof surface.

Claims (6)

  A power generation system for a bus stop, wherein a film solar cell is attached to a roof surface of a bus stop, and the film solar cell is used as a power source.   2. The power generation system for a bus stop according to claim 1, wherein the film type solar cell is attached around a south slope of the roof surface of the bus stop.   3. The power generation system for a bus stop according to claim 1, wherein the film-type solar cell is connected to an optical sensor, a storage battery, and a load through a charge / discharge controller.   The bus stop power generation system according to any one of claims 1 to 3, wherein the load includes at least a wireless LAN relay.   The power generation system for a bus stop according to any one of claims 1 to 3, wherein the load includes at least a wireless LAN relay machine and a display device connected thereto. The power generation system for a bus stop according to any one of claims 1 to 5, wherein a commercial power source is used as a power source together with the film type solar cell.

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