JP2007120237A - Power generation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power generation system strong against strong wind, reducing installation cost, and arranging a solar battery on a rooftop slab. <P>SOLUTION: The film-like solar battery 2 is stuck to the rooftop slab 90 by an adhesive via at least elastic mortar 81, and this film-like solar battery 2 is used as a power source. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a power generation system in which solar cells are installed on a roof slab.

When considering solar power generation, the installation location is optimal on the rooftop, but when installing solar cells on the rooftop for strong wind and earthquake resistance measures, a strong mounting base is required, and the panel on the solid base The upper solar cell is installed and a tilted gantry is used in order to increase power generation efficiency (see Patent Document 1).
JP 2004-204535 (FIG. 1, abstract)

  However, the gantry with the above-mentioned strong inclination leads to an increase in installation cost.

  Therefore, an object of the present invention is to obtain a power generation system in which a solar cell is installed on a roof slab, which is resistant to strong winds and has a low installation cost.

  In order to solve the above problems, in the present invention, a film-type solar cell is attached to a roof slab with an adhesive via at least an elastic mortar, and a power generation system using the film-type solar cell as a power source is provided. Thereby, since it adheres to a roof slab with an adhesive, it can be made into a power generation system that is strong against strong winds and low in installation cost. In addition, by attaching a film-type solar cell to the roof slab with an adhesive through an elastic mortar, the flexible characteristics of the elastic mortar are different from those of the film-type solar cell and the roof slab due to the difference in thermal expansion coefficient. Absorbs distortion caused by

  In addition, if a film-type solar cell is attached to a roof slab with an adhesive through at least elastic mortar and asphalt for waterproofing construction in order, and the power generation system using the film-type solar cell as a power source, the adhesive to the roof slab Because it is attached at, it can be a power generation system that is strong against strong winds and low in installation costs. In addition, by attaching a film-type solar cell to the roof slab with an adhesive through an elastic mortar, the flexible characteristics of the elastic mortar are different from those of the film-type solar cell and the roof slab due to the difference in thermal expansion coefficient. Absorbs distortion caused by Waterproofing asphalt improves waterproof performance.

  Moreover, if the asphalt roofing is installed in asphalt roofing and the power generation system has the longitudinal direction of the film-type solar cell aligned with the longitudinal direction, the asphalt roofing mainly expands and contracts in the longitudinal direction. Film-type solar cells can also be applied in the longitudinal direction of asphalt roofing to prevent excessive distortion.

  Further, if the film-type solar cell is attached to the roof slab with an adhesive via at least an elastic mortar, waterproof asphalt, and a heat insulating material in this order, and the film-type solar cell is used as a power generation system, the roof slab Because it is attached with an adhesive, it can be a power generation system that is strong against strong winds and low in installation costs. In addition, by attaching a film-type solar cell to the roof slab with an adhesive through an elastic mortar, the flexible characteristics of the elastic mortar are different from those of the film-type solar cell and the roof slab due to the difference in thermal expansion coefficient. Absorbs distortion caused by Asphalt for waterproofing construction improves waterproofing performance, and insulation improves thermal insulation performance.

  In addition, if the heat insulating material with a single slope or both slopes is used as a power generation system, it can contribute to the elimination of waterproof deterioration phenomenon such as a water pool due to a sloped roof, and since a heat insulating material with a slope is adopted, It becomes possible to improve the power generation efficiency of the film-type solar cell and to prevent dirt.

  In addition, if the power generation system has the same elasticity as that of the film-type solar cell, the distortion of the film-type solar cell is reduced.

  In addition, if the power generation system with waterproof performance is added to the elastic mortar, the waterproof performance is improved by the double waterproof effect due to the addition of the waterproof mortar to the waterproof construction asphalt. be able to.

  In addition, if the power generation system uses a commercial power source as a power source together with the film type solar cell, it is possible to deal with a larger amount of power, and the range of use of the power generation system is expanded.

  Moreover, if it is set as the electric power generation system which connected the storage battery via the charge / discharge controller to the said film-type solar cell, it can be set as a self-supporting stable power supply.

  Further, if the film type solar cell is a power generation system integrated with a steel plate, the film type solar cell can be handled easily.

  According to the present invention, since the film-type solar cell is attached to the roof slab with an adhesive, the power generation system can be made strong against strong winds and low in installation cost. In addition, by attaching the film-type solar cell to the roof slab with an adhesive through the elastic mortar, the flexible characteristics of the elastic mortar are different from those of the film-type solar cell and the roof slab due to the difference in coefficient of thermal expansion. Can absorb distortion caused by. In addition, it is an energy saving system that can contribute to 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 power generation system using solar cells as an embodiment according to the present invention. A power generation system 1 using solar cells includes film solar cells 2, 2, and 2, and these film solar cells 2. , 2 and 2 are connected together and connected to a commercial power source 5 and a load 7 through a commercial interconnection point 6 via a power conditioner 4. Although it is desirable to provide the connection box 3, it is possible to omit the installation by connecting to the power conditioner 4.

  The power conditioner 4 supplies power to the load 7 through the commercial connection point 6 when the power generation voltage of the film solar cell 2 is high, and does not supply power to the commercial connection point 6 when the power generation voltage is low. Make adjustments.

  In this way, the power of the commercial power supply is supplemented during the daytime when sunlight is present, and the load is driven by the power of the commercial power supply at night when there is no sunlight.

  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 a cross-sectional view in FIG. 4, it is integrated with a steel plate for convenience of handling. That is, as shown in FIG. 3, it is set as the unit module of the film-type solar cell 2 which consists of a solar cell of 4 sheets series and 2 sheets 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 film type solar cell sheet 2 is used, the steel plate and the deformation after laying can be endured.

  FIG. 5 is a longitudinal cross-sectional view showing a state in which the steel sheet integrated unit module 20 of the film type solar cell is attached to the roof slab, and FIG. 6 is a state in which the film type solar cell of FIG. 5 is attached. The longitudinal cross-sectional view which shows a principal part is shown in FIG. 7, The top view which shows the principal part of the sticking arrangement | positioning state of the film type solar cell corresponding to FIG.

  However, although the steel sheet integrated unit module 20 of the film type solar cell is easy to handle, in this embodiment, not the steel plate integrated unit module but the upper and lower surfaces of the solar cell are made of ethylenetetrafluoroethylene (ETFE). In some cases, it may be desirable to use a film-type solar cell covered with an adhesive such as ethylene bisol acetate (EVA) on the lower surface. This will be described below in terms of a film-type solar cell while considering both unit modules.

  5 to 7, a caulking material 94, an asphalt waterproofing layer 92, and a holding mortar 91 are applied or overlaid on the roof slab 90 of a concrete roof. In addition, between the holding mortar 91, the expansion joint is narrowly inserted for distortion prevention. The inner wall of the roof edge is a lathed mortar finish 93. Further, a breach cast concrete headstone 95 or the like is bonded to the edge of the roof.

  Here, a heat insulating material 83 made of foam polystyrene, hard urethane foam or the like is laid and stuck on the presser mortar 91. This heat insulating material 83 is inserted for improving the heat insulating performance of the building and can be omitted. Here, the asphalt 82 for waterproofing work formed by asphalt roofing using a sheet for infiltrating the asphalt into the felt to form a waterproof layer is further disposed. Up to this point, the configuration is the existing roof slab.

  Furthermore, in this embodiment, an elastic mortar 81 with waterproof performance is adhered and disposed on the asphalt 82 for waterproofing work as a backing material, that is, a pasting base for the steel sheet integrated unit module 20 of the film solar cell 2. The steel plate integrated unit module 20 should be attached in the longitudinal direction of asphalt roofing, because asphalt roofing mainly expands and contracts in the longitudinal direction. The reason is that the influence of the tensile force of the film solar cell 2 can be reduced.

  This elastic mortar 81 has a thickness of about 3 to 5 mm, and the expansion coefficient is the same as that of the film type solar cell 2. This makes it possible to cope with the expansion and contraction of asphalt roofing. By adopting the elastic mortar 81, it becomes possible to cope with cracks in the roof slab concrete and the holding mortar, so that the influence of the tensile force on the film type solar cell can be reduced. Moreover, since the elastic mortar 81 has added waterproof property, it can contribute to the improvement of the existing roof waterproof property. That is, since the elastic mortar 81 further imparted with waterproofness is added on the asphalt 82 for waterproofing work, it can contribute to the improvement of the waterproof performance by the double waterproof effect. The gap of the elastic mortar 81 is connected by a reinforcing sheet 84.

  In this embodiment, the film-type solar cell 2 is attached to the roof slab 90 with an adhesive via at least the elastic mortar 81 to form a power generation system using the film-type solar cell 2 as a power source. Since it is attached to the roof slab 90 via the elastic mortar 81, the elastic mortar 81 can be attached to the roof slab 90. The flexible characteristic absorbs strain due to the difference between the film solar cell 2 and the roof slab 90 due to the difference in thermal expansion coefficient.

  Further, the film-type solar cell 2 is adhered to the roof slab 90 with an adhesive through at least the elastic mortar 81 and the waterproof asphalt 82 in this order, and the film-type solar cell 2 is used as a power source. Asphalt 82 for use improves waterproof performance.

  Also, if the asphalt roofing 82 is installed by asphalt roofing, and the power generation system has the longitudinal direction of the film solar cell aligned with the longitudinal direction of the asphalt roofing, the asphalt roofing mainly expands and contracts in the longitudinal direction. Therefore, excessive distortion can be prevented by sticking the film type solar cell 2 in the longitudinal direction of asphalt roofing.

  Further, the film-type solar cell 2 is adhered to the roof slab 90 with an adhesive through at least the elastic mortar 81, the waterproof asphalt 82, and the heat insulating material 83 in this order, and the power generation system using the film-type solar cell 2 as a power source Then, the heat insulating performance can be further improved by the heat insulating material 83.

  Also, if the heat insulating material 83 is a power generation system with one slope or both slopes, it can contribute to the elimination of waterproof deterioration phenomenon such as a water pool due to a sloped roof, and since a heat insulating material with a slope is adopted, a film is used. It is possible to improve the power generation efficiency of the solar cell and to prevent the contamination.

  Further, if the power generation system with waterproof performance is added to the elastic mortar 81, the waterproof performance is improved by the double waterproof effect by adding the waterproof mortar to the waterproof construction asphalt 82. Can be achieved.

  Further, if the power generation system is configured so that the elasticity of the elastic mortar 81 is the same as that of the film solar cell 2, the distortion of the film solar cell is reduced.

    Moreover, if it is set as the power generation system which used the commercial power supply 5 as a power supply with the film-type solar cell 2, it can respond to a bigger electric power and the range of utilization of a power generation system will spread.

  Further, FIG. 8 shows another embodiment of a power generation system using a film-type solar cell as a self-supporting power source. This is a film-type solar cell 2, 2, 2 connected to a storage box 9 via a connection box 3 for electrically connecting them together and a charge / discharge controller 8, thereby providing a self-supporting stable power source. . An optical sensor 10 and a load 7 are further connected to the charge / discharge controller 8. Although it is desirable to provide the connection box 3, the connection box 3 can be omitted by connection with the charge / discharge controller 8.

  As described above, by attaching a film-type solar cell on the roof slab, a conventional solar panel mounting base is not required, and installation can be saved and costs can be reduced. Moreover, wind resistance can be easily obtained by sticking a film type solar cell to a roof slab. If film-type solar cells are attached with elastic mortar with waterproof performance, the influence of tensile force on film-type solar cells can be reduced, and waterproofing is added to the elastic mortar, contributing to improvement of existing roof waterproof performance. it can.

  As described above, the power generation system using the film-type solar cell according to the present invention can save labor and cost for installation, and has great industrial applicability as a contribution to global warming countermeasures.

It is a block diagram of the electric power generation system using the film type solar cell as one embodiment by this invention. It is an external view of an example of the film type solar cell sheet 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 longitudinal cross-sectional view which shows the example which stuck and arranged the film type solar cell shown in FIG. 3 on the roof slab. It is a longitudinal cross-sectional view which shows the principal part of the sticking arrangement | positioning state of the film type solar cell of FIG. It is a top view which shows the principal part of the sticking arrangement | positioning state of the film type solar cell corresponding to FIG. It is a block diagram of the electric power generation system using the film type solar cell which connected the storage battery as another embodiment by this invention, and was used as the self-supporting power source.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Power generation system, 2 Film type solar cell, 3 Junction box, 4 Power conditioner, 5 Commercial power supply, 6 Commercial connection point, 7 Load, 8 Charge / discharge controller, 9 Storage battery, 10 Optical sensor, 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, 81 elastic mortar, 82 asphalt for waterproofing construction, 83 heat insulating material, 84 reinforcement sheet, 90 roof slab, 91 presser Mortar, 92 asphalt waterproofing layer, 93 lacquered mortar finish, 94 caulking material, 95 Breccast concrete gangue.

Claims (10)

  A power generation system, wherein a film-type solar cell is attached to a roof slab with an adhesive at least via an elastic mortar, and the film-type solar cell is used as a power source.   A power generation system characterized in that a film-type solar cell is attached to a roof slab with an adhesive via an elastic mortar and a waterproof asphalt in order, and the film-type solar cell is used as a power source.   The power generation system according to claim 2, wherein the asphalt for waterproofing work is installed by asphalt roofing, and the longitudinal direction of the film solar cell is aligned with the longitudinal direction thereof.   A power generation system characterized in that a film type solar cell is attached to a roof slab with an adhesive via an elastic mortar, waterproof asphalt, and a heat insulating material in this order, and the film type solar cell is used as a power source.   The power generation system according to claim 4, wherein the heat insulating material has a single slope or a double slope.   The power generation system according to any one of claims 1 to 5, wherein the elasticity of the elastic mortar is the same as that of a film-type solar cell.   The power generation system according to claim 1, wherein waterproofing performance is added to the elastic mortar.   The power generation system according to any one of claims 1 to 7, wherein a commercial power source is used as the power source together with the film type solar cell.   8. The power generation system according to claim 1, wherein a storage battery is connected to the film-type solar cell via a charge / discharge controller. The power generation system according to any one of claims 1 to 9, wherein the film-type solar cell is integrated with a steel plate.

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