JP5948890B2 - Concentrating solar power generation module, concentrating solar power generation panel, and flexible printed wiring board for concentrating solar power generation module - Google Patents

Description

  The present invention relates to a concentrating photovoltaic power generation (CPV) that generates power by concentrating sunlight on a power generation element.

  Concentrated solar power generation (CPV) is based on a configuration in which small compound semiconductor elements with high power generation efficiency are used as power generation elements, and sunlight condensed by a light condensing unit such as a Fresnel lens is incident on the power generation elements. (For example, refer to Patent Document 1). By performing a tracking operation so that a concentrating solar power generation panel having a large number of such basic configurations always faces the sun, desired generated power can be obtained.

US Pat. No. 5,460,659

  In the conventional concentrating solar power generation apparatus as described above, for example, when a shift occurs in the tracking operation to the sun, the condensed sunlight may hit the periphery of the power generation element instead of the power generation element. There is a risk that physical deformation / damage or deterioration of the material may occur in the peripheral pattern or coverlay that is exposed to light condensed by energy collection. In particular, such deterioration is likely to occur due to long-term use.

  In view of such conventional problems, it is an object to increase the light resistance of the peripheral portion of the power generation element and suppress deterioration.

  (1) A concentrating solar power generation module according to the present invention includes a vessel-shaped housing having a bottom surface, a printed wiring board provided on the bottom surface, and a lens that is attached to the housing and collects sunlight. A concentrating solar power generation module including a concentrating portion formed by arranging a plurality of elements, wherein the printed wiring board includes an insulating base material having an insulating property and a substrate having a conductive pattern; A plurality of power generation elements provided on the substrate corresponding to each of the lens elements and electrically connected to each other through the pattern; and the power generation elements are deposited on the pattern while avoiding the power generation elements. A white-colored coverlay.

  In the concentrating solar power generation module configured as described above, the sunlight condensed by the condensing unit is incident on the power generation element. However, for example, the sunlight is generated by the deviation of the tracking operation of the sun. Even if the light is condensed at a position off the element, there is a white coverlay, which reflects light well and protects the pattern. Further, since the coverlay itself is difficult to absorb light, deterioration is suppressed. Accordingly, it is possible to suppress the deterioration of the pattern and cover lay even during long-term use.

(2) Further, in the concentrating solar power generation module of (1), the substrate is a flexible ribbon-like flexible substrate, and the flexible substrate is arranged on the bottom surface, so that the printed wiring board is arranged. May be configured.
In this case, it is possible to freely arrange a large number of power generation elements by covering the flexible substrate on the bottom surface together with the cover lay, and to protect the pattern by the cover lay.

(3) Moreover, in the concentrating solar power generation module of the above (1) or (2), for example, the coverlay is in close contact with the pattern by thermal welding.
In this case, the coverlay can be easily adhered to the pattern.

(4) Moreover, in the concentrating solar power generation module according to any one of the above (1) to (3), the thickness of the coverlay is preferably within a range of 0.01 mm to 0.09 mm.
Such a thin coverlay does not particularly impair the flexibility of the flexible substrate.

(5) In the concentrating solar power generation module according to any one of (1) to (4), for example, the thermal conductivity of the coverlay is 0.2 [W / m · K].
In this case, heat conduction by the coverlay can be suppressed.

(6) On the other hand, the concentrating solar power generation panel of the present invention is formed by assembling a plurality of concentrating solar power generation modules according to any one of the above (1) to (5).
In this case, a desired output can be secured as the power generation panel.

  (7) Moreover, the flexible printed wiring board for concentrating photovoltaic power generation modules of this invention has the insulating base material which has insulation, and an electroconductive pattern, and has the flexible board | substrate which has flexibility, and the said flexible board | substrate. A plurality of power generation elements that are arranged side by side and electrically connected to each other via the pattern, and a white coverlay that closely contacts and covers the pattern while avoiding the power generation elements .

  The flexible printed wiring board for a concentrating solar power generation module configured as described in (7) above is originally used to collect sunlight on the power generation element. Even if the light is collected at a position away from the power generating element, there is a white coverlay that reflects the light well and protects the pattern. Further, since the coverlay itself is difficult to absorb light, deterioration is suppressed. Accordingly, it is possible to suppress the deterioration of the pattern and cover lay even during long-term use.

  According to the concentrating solar power generation module, the concentrating solar power generation panel, and the flexible printed wiring board for the concentrating solar power generation module of the present invention, the light resistance of the peripheral portion of the power generation element is improved and the deterioration is reduced. Can be suppressed.

It is a perspective view which shows the concentrating solar power generation device which concerns on one Embodiment of this invention. It is a perspective view (partially fractured) which expands and shows a concentrating solar power generation module. It is an enlarged view of the III section in FIG. It is a figure which shows the outline | summary of the partial cross section of a concentrating solar power generation module in the site | part in which the electric power generation element is provided. It is the figure which planarly viewed an example of arrangement | positioning of the flexible printed wiring board stretched around on the bottom face of a housing | casing. It is an enlarged view of a power generation wiring board. It is an enlarged view of the VII part in FIG.

  FIG. 1 is a perspective view showing a concentrating solar power generation device according to an embodiment of the present invention. In the figure, a concentrating solar power generation apparatus 100 includes a concentrating solar power generation panel 1, a support 2 that supports the concentrating solar power generation panel 1 at the center of the back surface, and a gantry 3 to which the support 2 is attached. The concentrating solar power generation panel 1 includes, for example, 62 concentrating solar power generation modules 1M (vertical 7 × horizontal 9-1), excluding the central portion for connection with the support column 2, vertically and horizontally. Become. The rated output of one concentrating solar power generation module 1M is about 120 W, for example, and the entire concentrating solar power generation panel 1 has a rated output of about 7.5 kW. The gantry 3 can be rotated around the column 2 by a rotation mechanism (not shown), and the concentrating solar power generation panel 1 can be tracked so as to always face the sun.

  FIG. 2 is an enlarged perspective view (partially broken) showing a concentrating solar power generation module (hereinafter also simply referred to as a module) 1M. In the figure, the module 1M is like a lid on a vessel-shaped (bat-shaped) housing 11 having a bottom surface 11a, a flexible printed wiring board 12 provided in contact with the bottom surface 11a, and a flange 11b of the housing 11. The primary condensing part 13 attached to is provided as a main component.

  The primary condensing unit 13 is a Fresnel lens array, and a plurality of Fresnel lenses 13f as lens elements for condensing sunlight are formed in a matrix (for example, 192 in the 16 × 12 horizontal direction). Yes. Such a primary condensing part 13 can be formed, for example, by using a glass plate as a base material and forming a silicone resin film on the back surface (inside) thereof. The Fresnel lens is formed on this resin film. A connector 14 for taking out the output of the module 1M is provided on the outer surface of the housing 11.

  FIG. 3 is an enlarged view of a portion III in FIG. In FIG. 3, the flexible printed wiring board 12 includes a ribbon-shaped flexible substrate 12 f and others (details will be described later), a power generation element (solar cell) 121 thereon, and a secondary assembly provided so as to cover the power generation element 121. And an optical part 122. The same number of sets of power generation elements 121 and secondary condensing units 122 are provided at positions corresponding to the Fresnel lenses 13 f of the primary condensing unit 13. The secondary condensing unit 122 collects sunlight incident from each Fresnel lens 13 f on the power generation element 121. The secondary light collecting unit 122 is, for example, a lens. However, it may be a reflecting mirror that guides light downward while irregularly reflecting light.

  FIG. 4 is a diagram showing an outline of a partial cross section of the module 1M at a portion where the power generation element 121 is provided. In the figure, the power generation element 121 and the secondary light collecting unit 122 are located directly below the Fresnel lens 13f of the primary light collecting unit 13 so that their optical axes are aligned. When the flexible printed wiring board 12 is considered to be part of the adhesive layer, the adhesive layer 123, the aluminum reinforcing plate 124, the adhesive layer 125, the insulating base 126, and the copper foil are sequentially arranged from the bottom. A pattern 127 made of the resin, a cover lay 128 made of resin, a power generation element 121 and a secondary condensing part 122. It should be noted that the thickness shown in the figure is merely a thickness for easy viewing and is not proportional to the actual size. The insulating base 126 is made of polyimide having excellent heat resistance, for example. The pattern 127 is insulated from the housing 11 by the insulating base 126.

The lowermost adhesive layer 123 bonds the bottom surface 11a of the housing 11 and the reinforcing plate 124 to each other. The other adhesive layer 125 bonds the reinforcing plate 124 and the insulating base 126 to each other. The insulating base 126 and the pattern 127 constitute a flexible substrate 12f in a narrow sense. The pattern 127 is formed on the insulating base material 126 by etching or the like.
The cover lay 128 that is a layer of an insulating material that covers the pattern 127 is made of white resin. The coverlay 128 can be easily adhered to the pattern 127 by heat welding. “White” is adopted because of the relatively high reflectance of sunlight. Therefore, not only pure white but also a white color may be used.

  The reinforcing plate 124 can secure a certain degree of rigidity to the flexible printed wiring board 12 to the extent that flexibility is not lost, and can be easily handled during manufacturing. In addition, the reinforcing plate 124 can also prevent deformation of the entire flexible printed wiring board 12. Moreover, the heat conductivity (heat dissipation) to the bottom face 11a of the housing | casing 11 can be improved because the reinforcement board 124 is made from aluminum. The flexible printed wiring board 12 is very lightweight as a whole even if the reinforcing plate 124 is added. However, the reinforcing plate 124 is not an essential configuration and can be omitted. When the reinforcing plate 124 is omitted, the flexible substrate 12f is directly bonded to the bottom surface 11a. Further, in that case, the housing 11 ensures the functions of preventing deformation and heat dissipation of the flexible printed wiring board 12.

The thermal conductivity and thickness of each part shown in FIG. As for the thickness, the current adopted numerical value in the present embodiment and the maximum and minimum values in the assumed range are shown. In particular, for the coverlay 128, suitable numerical values are shown.

As shown in Table 1, the thickness of the cover lay 128 is preferably in the range of 0.01 mm to 0.09 mm, and such a thin cover lay 128 does not impair the flexibility of the flexible substrate 12f.
Further, the thermal conductivity of the cover lay 128 is preferably about 0.2 [W / m · K], and the heat conductivity by the cover lay 128 is suppressed by such a relatively low thermal conductivity. can do.

  In addition, the thickness of the insulating base 126 is preferably selected so that both the withstand voltage performance and the heat dissipation can be achieved. For example, if it is 0.03 mm (30 micrometers) of the said Table 1, withstand voltage performance and the heat dissipation to the housing | casing 11 can be made to make compatible. The cover lay 128, the pattern 127, the insulating base 126, and the adhesive layer 125 are all as thin as 0.03 to 0.06 mm. Therefore, as a whole, they are very thin and have flexibility.

Note that the housing 11 is made of metal, and for example, aluminum is suitable. By being made of metal, the housing 11 has good thermal conductivity. Therefore, the heat dissipation from the flexible printed wiring board 12 to the housing 11 is particularly good.
In addition to the fact that the flexible printed wiring board 12 and the like are very light, the housing 11 is made of aluminum, so that the entire concentrating solar power generation module 1M is light. It is easy to transport due to its light weight. Taking the degree of “light weight” as an example, when the length, width, and depth of the module 1M are 840 mm, 640 mm, and 85 mm, respectively, 8 kg or less can be realized.

  FIG. 5 shows an example of the arrangement of the flexible printed wiring board 12 stretched on the bottom surface 11a of the housing 11 (however, details are omitted, so that the flexible substrate 12f is substantially shown). FIG. As described above, the flexible printed wiring board 12 has a thin ribbon shape as a basic shape (shape of the flexible substrate 12f). However, by arranging the flexible printed wiring board 12 vertically and horizontally on the bottom surface 11a, the flexible printed wiring board 12 is stretched to a desired size (area). Since it can be circulated, it is suitable for a large concentrating solar power generation module 1M. In other words, the entire flexible printed wiring board 12 configured to be stretched in this way is comparable to a single substrate or a group of a plurality of substrates having the same expansion. Moreover, by being ribbon-shaped, the area of the flexible printed wiring board 12 can be stretched to a desired size while suppressing the area to the minimum necessary.

  The flexible printed wiring board 12 shown in FIG. 5 includes, for example, 12 sets of power generation wiring boards 12A and connection wiring boards 12B. The power generation wiring board 12A is formed in a U-shape (or U-shape). Such a shape may be formed by connecting linear portions, or may be formed integrally.

  The same number of power generation elements are mounted on each power generation wiring board 12A, and a predetermined voltage can be generated. In this way, the length of the power generation wiring board 12A can be sufficiently secured by forming the power generation wiring board 12A into a shape extending from the center of the bottom surface 11a to the end and returning to the center. In order to obtain a voltage, it is easy to arrange a necessary number of power generating elements and connect them in series. Further, by providing the connection wiring board 12B in the center so as to intersect the power generation wiring board 12A, the 12 sets of power generation wiring boards 12A can be easily connected to each other.

  FIG. 6 is an enlarged view of the power generation wiring board 12A. For example, 16 power generation elements 121 are mounted on the power generation wiring board 12A. All the power generation elements 121 mounted on one power generation wiring board 12A are connected in series with each other. A voltage generated by one power generation element 121 is 2.5 V, and a voltage of 40 V (2.5 V × 16) can be generated as 16 serial bodies. This voltage appears at the + side electrode P and the − side electrode N provided at the two ends of the power generation wiring board 12A.

FIG. 7 is an enlarged view of a portion VII in FIG. In FIG. 7, the hatched portion is a state in which a white coverlay 128 is attached on the pattern 127 by thermal welding.
Between the patterns 127 adjacent to each other, the power generation elements 121 are inserted in series. A diode 129 is provided in parallel with the power generation element 121 so as to form a bypass of the power generation element 121. The diode 129 is provided to short-circuit the adjacent patterns 127 when the power generation element 121 does not generate power. Thus, even if there is a power generation element 121 that does not generate power locally due to a failure or the like, power generation as a whole of the power generation wiring board 12A is not hindered. The diode 129 is attached after the cover lay 128 is deposited on the pattern 127 in order to protect it from the heat generated when the cover lay 128 is thermally welded.

  Further, positioning holes are formed in the insulating base 126, and the hole H is shown in FIG. 7 as one of them. The pattern 127 is removed in a circle around the hole H so as not to reach the edge of the hole H. By passing the columnar protrusion 11p formed on the bottom surface 11a of the housing 11 through the hole H, the power generation wiring board 12A can be positioned at a predetermined position with respect to the housing 11. A similar positioning structure can be provided for the connection wiring board 12B.

  Note that the configuration in which the hole H of the insulating base 126 and the projection 11p on the side of the casing 11 are fitted to each other is merely an example, and the flexible printed wiring board 12 is formed by forming various other fitting sections. Positioning when attaching to the bottom surface 11a of the body 11 can be configured so that it can be easily and reliably performed.

  Returning to FIG. 5, the outputs of the 12 sets of power generation wiring boards 12 </ b> A are such that the + side electrodes P (FIG. 6) are connected to each other by the connection circuit 12 Bp, and the − side electrodes N (FIG. 6) are connected to each other. Connected by 12Bn. Thus, for example, a 12V parallel circuit of 40V is configured, and the above-described 120W (3A) can be supplied as one module 1M as a whole.

  As described above, according to the configuration of the module 1M using the flexible printed wiring board 12, since the flexible printed wiring board 12 is thin and lightweight, the entire module 1M is also light and easy to handle. Moreover, since the flexible printed wiring board 12 is thin and flexible, it can be easily attached in close contact with the bottom surface 11 a of the housing 11. Further, the heat of the power generation element 121 and other flexible printed wiring boards can be reliably radiated to the housing 11 by the close contact and the thinness.

  In the concentrating solar power generation module 1M configured as described above, the sunlight condensed by the primary condensing unit 13 is incident on the power generation element 121. For example, the solar tracking operation Even if the sunlight is condensed at a position off the power generation element 121 due to the deviation, the white coverlay 128 is present there, and the light is well reflected to protect the pattern 127. Further, since the coverlay 128 itself does not easily absorb light, deterioration is suppressed. Therefore, deterioration of the pattern 127 and the coverlay 128 can be suppressed even during long-term use. In this way, the light resistance of the peripheral part of the power generation element 121 can be improved and deterioration can be suppressed.

  In addition, by extending the flexible substrate 12 f around the bottom surface 11 a together with the cover lay 128, a large number of power generation elements 121 can be arranged freely, and the pattern 127 can be protected by the cover lay 128.

  In the above embodiment, the casing 11 is made of metal. However, the casing 11 is not limited to metal, and can be made of resin. In this case, the casing 11 is particularly lightweight, and the entire concentrating solar power generation module 1M is particularly lightweight. In addition, even if it is resin, since there exists thermal conductivity, fixed heat dissipation is obtained. In particular, a resin to which an insulating filler having high thermal conductivity (for example, alumina, silica, silicon carbide, magnesium oxide, or the like) is added is preferable because it has excellent thermal conductivity and improved heat dissipation. In addition, by applying a metal coating to the surface of the resin, the thermal conductivity of the surface can be increased to the same level as that of a metal.

The arrangement of the flexible printed wiring board shown in FIG. 5 is only an example, and various modifications are possible as long as a similar output is ensured.
In the above embodiment, the secondary condensing unit 122 is mounted on the flexible substrate 12f together with the power generation element 121. However, the secondary condensing unit 122 may be provided separately from the flexible substrate 12f. The next light condensing unit itself may be omitted.

  Moreover, in the said embodiment, although the flexible printed wiring board 12 was used, the improvement of the light resistance by making a coverlay into a white type | system | group is also applied to other printed wiring boards (for example, an epoxy resin-type board | substrate and a ceramic board | substrate). Applicable.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 1 Concentration type photovoltaic power generation panel 1M Concentration type photovoltaic power generation module 11 Case 11a Bottom surface 12 Flexible printed wiring board 12f Flexible substrate 13 Primary condensing part 13f Fresnel lens (lens element)
121 Power generation element 126 Insulating base material 127 Pattern 128 Coverlay

Claims (7)

A vessel-shaped housing having a bottom surface;
A printed wiring board provided on the bottom surface;
A concentrating solar power generation module provided with a condensing unit attached to the housing and formed with a plurality of lens elements that condense sunlight, and the printed wiring board is
An insulating base material having insulation and a substrate having a conductive pattern;
A plurality of power generation elements provided on the substrate corresponding to each of the lens elements, and electrically connected to each other through the pattern;
In order to increase the light resistance of the pattern in the peripheral part when sunlight is condensed on the peripheral part of the power generating element by the light collecting part, the light is applied on the pattern, avoiding the power generating element. A concentrating solar power generation module comprising a white coverlay.   The concentrating solar power generation module according to claim 1, wherein the substrate is a flexible ribbon-like flexible substrate, and the printed wiring board is configured by arranging the flexible substrate on the bottom surface.   The concentrating solar power generation module according to claim 1 or 2, wherein the coverlay is in close contact with the pattern by thermal welding.   4. The concentrating solar power generation module according to claim 1, wherein a thickness of the coverlay is in a range of 0.01 mm to 0.09 mm.   5. The concentrating solar power generation module according to claim 1, wherein the coverlay has a thermal conductivity of 0.2 [W / m · K].   A concentrating solar power generation panel formed by assembling a plurality of concentrating solar power generation modules according to claim 1. Used in a concentrating solar power generation module comprising a vessel-shaped housing having a bottom surface and a condensing unit attached to the housing and formed with a plurality of lens elements that condense sunlight. A flexible printed wiring board for a concentrating solar power generation module provided on the bottom surface of the housing,
A flexible substrate having an insulating base material having an insulating property and a conductive pattern, and having flexibility;
On the flexible substrate, a plurality of power generation elements provided side by side corresponding to each of the lens elements, and electrically connected to each other via the pattern,
In order to increase the light resistance of the pattern in the peripheral part when sunlight is condensed on the peripheral part of the power generating element by the light collecting part, the light is closely attached to and covered with the pattern while avoiding the power generating element. A flexible printed wiring board for a concentrating solar power generation module, comprising: a white coverlay.

Images