JP2013225536A - Photovoltaic power generation system, received light amount improving lens, and received light amount improving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve a received light amount of a solar cell whose received light amount is reduced due to a light-shielding object.SOLUTION: A solar cell string 2 is formed by connecting in series a plurality of solar cells 1a to 1f that convert incident solar energy into electric energy. A received light amount improving lens 3 is disposed adjacent to a light-shielding object 10 that blocks sunlight incident on the solar cell string 2 and produce shade. The received light amount improving lens 3 diffuses part of the sunlight that passes near the light-shielding object 10, toward the shade.

Description

  Embodiments of the present invention relate to a photovoltaic power generation system including a lens for improving the amount of received light that improves a decrease in generated current due to a light blocking object, and a method for improving the amount of received light using the lens for improving received light amount.

  In recent years, attention has been paid to renewable energy by attaching solar cells to ordinary houses or office buildings such as detached houses and condominiums. Furthermore, a mega-solar system with a large number of solar panels installed on a vast site to take on a fundamental role as a power plant is also realistic.

  This solar power generation system generates power by converting incident solar energy into electrical energy. This solar power generation system is generally composed of a solar cell string in which solar cells are connected in series in order to obtain a constant output voltage. The output current of the solar battery cell is proportional to the intensity of incident light, and the output current of the entire solar battery string is the smallest output current among all the solar battery cells connected in series. Therefore, for example, when a shadow is generated in one area of the solar cell string by a light shielding object such as an electric wire in the sky, there is a problem that the output current is extremely reduced and the stability as a power supply source is lacking.

  Therefore, various methods for improving the output current reduced by the shadow have been proposed. For example, a method has been proposed in which a member that scatters light, such as a lens, is arranged so as to cover the solar cell string so that the solar cell string is uniformly irradiated with light even when a light-shielding object is present. . However, the amount of light received by the entire solar cell string is reduced depending on the transmittance of the lens, and it is not practical to install a lens that covers the entire solar cell string because the installation cost increases.

  As another method, there has been considered a method in which a reflection plate or the like is installed in the vicinity of the solar cell string, and the reflected light is irradiated to the solar cell on which the shadow is generated to compensate the received light amount. This method is effective because it reflects light that is not originally incident on the solar cell string toward the shadow, and therefore does not reduce the amount of light received by the entire solar cell string.

JP-A-7-302927 JP-A-8-148711 JP-A-8-204219

  However, the reflected light of the reflector moves in the opposite direction to the shadow that moves with the movement of the sun. Therefore, it is not easy to make the reflected light accurately follow the shadow. In order to ensure followability, it is necessary to provide a plurality of reflectors or a drive device that changes the angle of the reflectors with the movement of the sun, which complicates the system and increases installation costs. On the contrary, by installing a reflector, the shadow of the reflector may fall on the solar cell string.

  Embodiments of the present invention have been proposed to solve the above-described problems, and are capable of following a shadow that has fallen on a solar cell string with a simple configuration and irradiating the shadow with light. The purpose is to provide a system.

  In order to achieve the above object, a photovoltaic power generation system according to an embodiment includes a solar cell string in which a plurality of solar cells that convert incident solar energy into electrical energy are connected in series, and the solar cell string. A light receiving amount improving lens disposed adjacent to a light blocking object that blocks the sunlight incident on the light generating shadow. The received light amount improving lens refracts a part of the incident sunlight and makes the incident light enter the range where the shadow of the solar cell string is generated.

It is a perspective view which shows the structure of the solar energy power generation system which concerns on 1st Embodiment. It is a side view which shows the structure of the solar energy power generation system which concerns on 1st Embodiment, and shows the state whose sun's elevation angle is 45 degrees. It is a table | surface which shows the measured value of the intensity | strength and output current of the light which injects into a photovoltaic cell, and the output current of the whole photovoltaic string, (a) is the state where the shadow of a light-shielding object does not cover the string, (b) is (C) is a table | surface which shows the measured value in the state in which the shadow of the light-shielding object was applied to the solar cell string, and the state in which the sunlight refracted by the lens for light reception improvement entered the shadow of the light-shielding object. (A) is a side view which shows the state where the shadow of the light shielding object is not applied to the string in the solar power generation system, and (b) is a side view showing the state where the shadow of the light shielding object is applied to the solar cell string. . It is a side view which shows the structure of the solar energy power generation system which concerns on 1st Embodiment, and shows the state whose elevation angle of the sun is 75 degrees. It is a schematic diagram which shows the example of a specific structure of the lens for light reception improvement. It is a perspective view which shows an example of the attachment aspect to the light-shielding object of the lens for light reception improvement. It is an example of the attachment mode of the light reception amount improvement lens to the light shielding object, (a) illustrates only the light reception amount improvement lens, and (b) enlarges the connection part between the light shielding object and the light reception amount improvement lens. FIG. It is a side view which shows the structure of the solar energy power generation system which concerns on 2nd Embodiment. It is a table | surface which shows the measured value of the intensity and output current of the light which injects into a photovoltaic cell, and the output current of the whole photovoltaic string in the photovoltaic power generation system which concerns on 2nd Embodiment. It is a perspective view which shows the structure of the solar energy power generation system which concerns on 3rd Embodiment, (a) shows the state where the shadow of the light-shielding object applied to the solar cell string, (b) received light with the lens for light reception amount improvement. Shows improved quantity.

  Embodiments of a solar power generation system according to the present invention will be described below with reference to the accompanying drawings.

[1. First Embodiment]
[1-1. Overall configuration of solar power generation system]
The overall configuration of the photovoltaic power generation system according to the first embodiment will be described with reference to FIG.

  The solar power generation system of this embodiment has a solar cell string 2 in which a plurality of solar cells 1 that convert incident solar energy into electrical energy are connected in series. The solar power generation system includes a PCS (power conditioner) (not shown) in the subsequent stage of the solar cell string 2 and converts the output power of the solar cell string 2 into appropriate power. For example, in the case of reverse power flow to the power system, the output voltage is converted to an AC voltage that matches the power system.

  The number of solar cells 1 connected in series is determined in consideration of the output voltage of a single cell and the output voltage required for the solar cell string 2. In the present embodiment, as an example, a state in which the solar cells 1a to 1f are connected in series will be described. When installed in a general household, the solar cell string 2 is usually installed along a slanted roof facing south such as a house. Alternatively, it may be installed on a rooftop of a condominium or the like in a diagonal direction from a floor surface by a stand or the like.

  In the present embodiment, it is assumed that there is a light blocking object that blocks sunlight incident on the solar cell string 2. In solar power generation systems installed in detached houses and low-rise condominiums, there is a high possibility that there will be light shielding objects around the roof or rooftop, such as electric wires and telephone poles. Alternatively, even if there is no light shielding object at the time of introduction of the solar power generation system, the light shielding object may be formed due to changes in the surrounding environment after the introduction. This embodiment demonstrates the case where the light-shielding object is the electric wire 10 hung over the solar power generation system. In FIG. 1, only a portion of the electric wire 10 positioned above the solar cell string 2 is illustrated.

  In the solar cell string 2, the solar cell 1 located in the shadow has a lower light receiving amount than the solar cell without the shadow, and therefore the output current of the solar cell 1 also decreases. As described above, in the solar cell string 2 in which the solar cells 1 are connected in series, the smallest output current among the output currents of the solar cells 1 is the overall output current. Therefore, the output current of the entire solar cell string 2 is reduced due to the presence of the electric wire 10.

  The photovoltaic power generation system of the present embodiment has a received light amount improving lens 3 for improving the lowered received light amount (hereinafter also simply referred to as the lens 3). The lens 3 is installed adjacent to the electric wire 10 along a portion of the electric wire 10 positioned above the solar cell string 2.

[1-2. Structure and operation of lens for improving received light amount]
The configuration and operation of the received light amount improving lens 3 will be described with reference to FIGS.

  The lens 3 is made of a material that transmits light, such as glass or plastic. As shown in FIG. 2, the lens 3 is a prismatic member having a substantially trapezoidal cross section. Here, the substantially trapezoid means that the side between the upper base and the lower base of the trapezoid is curved inward. In other words, the lens 3 has a shape in which the concave lens is halved. Specifically, it is the shape of one of the biconcave lenses divided into two on the plane through which the optical axis passes. Here, the “plane passing through the optical axis” is a plane that passes through the principal point (principal point / focus / node) of the biconcave lens and is orthogonal to the principal surface at the principal point. When the biconcave lens is divided into two halves, the surface passing through the optical axis becomes the short end 3a, and the opposite surface becomes the long end 3b. Therefore, the light incident on the vicinity of the short end 3a of the lens 3 travels straight, but is refracted in the direction of divergence at other portions, and the degree of refraction becomes the largest near the long end 3b. .

  In the solar power generation system of the present embodiment, the lens 3 is arranged with its lens surface facing the incident surface of the solar cell string 2. Further, the long end 3 b is installed on the side close to the electric wire 10, and the short end 3 a is installed on the side away from the electric wire 10.

  In such a solar power generation system, when the electric wire 10 blocks, for example, sunlight that should enter the solar battery cell 1c, a shadow is generated on the solar battery cell 1c as shown in FIG. The amount of light received by the battery cell 1c is lower than that of a solar battery cell with no shadow. The light passing through the vicinity of the electric wire 10, that is, the vicinity thereof, enters the solar battery cell 1b adjacent to the solar battery cell 1c. Here, when the lens 3 is installed adjacent to the electric wire 10, light passing through the vicinity of the electric wire 10 enters the lens 3. As described above, the light incident along the optical axis away from the electric wire 10 travels straight and exits toward the solar battery cell 1b as it is. Moreover, the incident light on the short end 3a side of the lens 3 is slightly refracted, but still diverges in the range of the solar battery cell 1b. The incident light on the long end 3b side of the lens 3 is greatly refracted and diverges from the solar battery cell 1b toward the solar battery cell 1c.

  In this way, a part of the light diverged by the lens 3 becomes incident light on the solar battery cell 1c, whereby the amount of light received by the battery cell 1c, which is reduced by the shadow of the electric wire 10, is improved.

  A specific aspect of the improvement in the amount of received light will be described using the measured values of the intensity and output current of light incident on the solar battery cell and the output current of the entire solar battery string 2 shown in FIG. FIG. 3A shows measured values in a state where the electric wire 10 that is a light shielding object is not present, that is, in the state shown in FIG. FIG. 3B shows measured values in a state in which the solar cell 1c is shaded by the electric wire 10, that is, in the state shown in FIG. FIG. 3C shows measured values in a state where the received light amount improving lens 3 is installed adjacent to the electric wire 10, that is, in the state shown in FIG.

As shown to Fig.3 (a), in the state which does not have a light-shielding object, in all the photovoltaic cells 1a-1f, the intensity | strength of the received light will be 1000 W / m < ² >, and it has obtained the same light reception amount. Therefore, the output current is 2.0 A in all the solar cells 1 and the output current of the solar cell string 2 is 2.0 A.

As shown in FIG.3 (b), when the electric wire 10 interrupts the sunlight which should enter into the photovoltaic cell 1c, and produces the shadow, the intensity | strength of the light which injects into the photovoltaic cell 1c is 100 W / m < ² >. To drop. Therefore, the output current of the solar battery cell 1c is reduced to 0.2A. As a result, the other solar cells cannot output 2.0 A when receiving 1000 W / m ^2, and are dragged by the output current of the solar cell 1 c. As a result, the solar cell string 2 as a whole can output only a current of 0.2 A.

On the other hand, as shown in FIG.3 (c), when the lens 3 for light reception improvement is arrange | positioned adjacent to the electric wire 10 which is a light-shielding object, about solar cell 1b, a part of sunlight which should inject | emits is diffused. Therefore, the intensity of incident light decreases from 1000 W / m ² to 500 W / m ² . Therefore, the output current also decreases from 2.0A to 1.0A. However, the intensity of the light incident on the solar cell 1c is improved from 100 W / m ² to 200 W / m ² when the light diverged by the lens 3 is incident. Therefore, the output current that has been reduced to 0.2 A due to the shadow of the electric wire 10 is recovered to 0.4 A. Therefore, the output current of the solar battery cell 2 as a whole is improved to 0.4A.

  The shadow generated by blocking the sun's light moves with the movement of the sun. The lens 3 follows the moving shadow and acts to move the range in which the light is diverged. Although FIG. 2 shows the case where the sun has an elevation angle of 45 °, FIG. 5 shows the case where the sun has moved to an elevation angle of 75 °. As the elevation angle changes, the incident angle of sunlight on the solar cell string 2 also changes, so that the shadow caused by the electric wire 10 moves from the solar cells 1c to 1b. Since the light passing through the vicinity of the electric wire 10, that is, the vicinity thereof also moves in the same manner as the shadow by the electric wire 10, it moves from the solar cell 1 b to the solar cell 1 a. Here, the lens 3 is disposed adjacent to the electric wire 10 and light passing through the vicinity of the electric wire 10 is made incident. Then, as in the case of an elevation angle of 45 °, the incident light along the optical axis away from the electric wire 10 goes straight and is emitted as it is toward the solar battery cell 1a. Moreover, the incident light on the short end 3a side of the lens 3 is slightly refracted, but still diverges in the range of the solar battery cell 1a. The incident light on the long end 3b side of the lens 3 is greatly refracted and diverges from the solar cell 1a toward the solar cell 1b.

  In this way, the light reception amount improving lens 3 is disposed adjacent to the electric wire 10 to diverge light passing through the vicinity of the electric wire 10, and the light reception amount improving lens 3 is incident on the side adjacent to the electric wire 10. By adopting a shape in which the light is diverged toward the shadow, the light diverged by the lens 3 can be made to follow the shadow moving with the movement of the sun and incident.

[1-3. Example of lens configuration for improving the amount of received light]
Specific shapes such as the curvature and focal length of the lens 3 are appropriately selected depending on the size of the solar battery cell 1 actually used, the distance from the light shielding object, and the like. Here, as an example, a specific configuration example of the lens 3 will be described with reference to FIG.

  The lens 3 is preferably configured to diverge the incident light to the outer edge of the adjacent shadow in addition to the width that should have been incident on the solar cell string 2 in the absence of the lens 3. That is, the focal length of the lens 3 is determined according to the desired incident width to the solar cell string 2.

Here, the focal length of the lens 3 is F, the lens width is Wlens, the distance from the lens 3 to the solar cell string 2 is Lcell, and the width of the light emitted from the lens 3 and incident on the solar cell string 2 is Wcell. And
The relationship between the focal length F of the lens 3 and the incident width Wcell of sunlight on the solar cell string 2 is expressed by the following formula 1.
(Formula 1)
F: Wlens = (F + Lcell): Wcell
Accordingly, the lens 3 that allows light to enter the desired incident width Wcell may have an optical structure having a focal length F that can be expressed by the following Expression 2.
(Formula 2)
F = Lcell × Wlens / (Wcell-Wlens)

  As described above, it is desirable that the lens 3 is configured to diverge up to the outer edge of the shadow falling on the solar cell 1c. However, even if the lens 3 diverges only to a part of the shadow, the amount of light received by the solar cell 1c is reduced to some extent. Can be improved. In addition, it is optimal to adjust the focal length F and the lens transmittance so that the amount of light received by the solar cell 1b and the amount of light received by the improved solar cell 1c are reduced due to light divergence by the lens 3. It is.

[1-4. Construction method]
In the present embodiment, there are various attachment modes and methods for arranging the light reception amount improving lens 3 adjacent to the light shielding object, and an example thereof will be described with reference to FIGS. 7 and 8.

  As shown in FIG. 7, the band 4 is attached to the electric wire 10 which is a light shielding object. Further, a U-shaped attachment 6 is attached to the band 4. On the other hand, a frame 5 is fitted into the lens 3 so as to surround the edge of the long end 3b. As shown in FIG. 8A, the frame 5 is a member having an L-shaped cross section, and includes a horizontal frame 5a fitted on the long side and a vertical frame 5b fitted on the short side. An inverted U-shaped attachment 7 is attached to the vertical frame 5b.

  A circular hole is provided in the center of the attachments 6 and 7, and the lens 3 is adjacent to the electric wire 10 by bolting the attachments 6 and 7 to each other through these circular holes. It is attached.

  Adjustment of the attachment position and the attachment angle of the lens 3 with respect to the electric wire 10 is performed by the following method, for example. First, the position where the U-shaped attachment 6 is attached to the band 4 is adjusted and determined while confirming the range in which the light emitted by the lens 3 is incident on the solar cell string 2 with a laser pointer or the like. Then, the fixture 6 is bolted to the inverted U-shaped fixture 7 of the vertical frame 5b. At the time of bolt fastening, the fastening angle of the fixtures 6 and 7 is adjusted and determined while confirming the incident angle to the solar cell string 2 again with a laser pointer or the like. Thus, the lens 3 is attached so as to be adjacent to the electric wire 10 while adjusting the attachment position and angle.

[1-5. effect]
(1) As described above, in the present embodiment, the photovoltaic power generation system includes the solar cell string 2 in which a plurality of solar cells 1 that convert incident solar energy into electrical energy are connected in series. And the electric wire 10 which is a light-shielding object which interrupts | blocks at least one part of the sunlight which injects into a photovoltaic cell exists, this produces a shadow in the photovoltaic cell 1, and reduces the light reception amount. On the other hand, the lens 3 for improving the amount of received light is disposed adjacent to the electric wire 10, and part of the sunlight passing through the vicinity of the electric wire 10 is diverged toward the shadow.

  In this manner, the lens 3 is disposed adjacent to the electric wire 10 that is a light shielding object. The light diverged by the lens 3 is incident on the solar cell string 2 after passing through the vicinity of the electric wire 10, that is, in the vicinity thereof, and thus moves in substantially the same manner as the shadow of the electric wire 10. Thereby, the lens 3 can follow the shadow of the electric wire 10 which moves according to time, and can irradiate light, without requiring a special adjustment mechanism. That is, a drive device and a complicated control program for following the movement of the shadow of the electric wire 10 are not required, and the number of parts and installation cost can be reduced.

(2) The lens 3 for improving the amount of received light has a shape in which the concave lens is halved. The short surface side through which the optical axis of the lens for improving received light amount passes is disposed on the side away from the electric wire 10, and the long surface side is disposed adjacent to the electric wire 10. As a result, only a part of the light incident on the lens 3 is diverged toward the shadow, so that the amount of light received by the solar battery cell that should have originally entered the lens 3 should be reduced excessively. There is no.

(3) Further, the lens 3 has a focal length such that the sunlight emitted from the lens 3 extends to the shadow range based on the distance from the electric wire 10 to the solar cell string 2 and the shadow range generated by the electric wire 10. It was determined. Thereby, the amount of light received between the solar cells 1 can be smoothed, and the output current of the entire solar cell string 2 can be further raised.

(4) The lens 3 is attached to a band that extends around the electric wire 10 via attachments 6 and 7. In that case, the attachment position and angle with respect to the electric wire 10 of the lens 3 can be easily adjusted by adjusting the attachment position of the attachment tool 6, and the attachment angle of the attachment tools 6 and 7. FIG. Moreover, since it attaches over a band instead of attaching directly to the electric wire 10, the influence which it has on the electric wire 10 can be minimized.

[2. Second Embodiment]
A photovoltaic power generation system according to the second embodiment will be described with reference to FIG.
In the second embodiment, only points different from the first embodiment will be described, and the same parts as those in the first embodiment will be denoted by the same reference numerals and detailed description thereof will be omitted.

  In the first embodiment, one light reception amount improvement lens 3 is disposed adjacent to one side of the electric wire 10. In the second embodiment, in addition to the light reception amount improvement lens 3, another light reception amount improvement lens 3 is provided. A received light amount improving lens 8 (hereinafter also simply referred to as a lens 8) is disposed adjacent to the electric wire 10 on the side opposite to the received light amount improving lens 3. That is, in the second embodiment, the received light amount improving lenses 3 and 8 are arranged on both sides of the electric wire 10. The lens 8 has the same shape as the lens 3 and is arranged so as to be line symmetric with the lens 3 with the electric wire 10 interposed therebetween.

  FIG. 9 shows a state in which the sunlight incident on the solar battery cell 1c is blocked by the electric wire 10 and a shadow is generated, as in the first embodiment. Similarly to the first embodiment, a part of sunlight incident on the solar battery cell 1b is diverged by the lens 3 and enters the solar battery cell 1c.

  Here, sunlight that should enter the solar cell 1d, which is the other cell adjacent to the solar cell 1c, is incident on the second received light amount improving lens 8. Similar to the lens 3, the light incident along the optical axis of the lens 8 away from the electric wire 10 goes straight and exits toward the solar cell 1 d as it is. Further, the incident light on the short end 8a side of the lens 8 is slightly refracted, but still diverges in the range of the solar battery cell 1d. The incident light on the long end 8b side of the lens 8 is greatly refracted and diverges from the solar battery cell 1d toward the solar battery cell 1c.

  For this reason, in addition to the light diverged by the lens 3, the light diverged by the lens 8 also enters the solar battery cell 1 c shaded by the electric wire 10. Thereby, the amount of light received by the solar battery cell 1c is further improved.

  FIG. 10 shows the intensity and output current of light incident on each of the solar cells 1 a to 1 f and the output current of the entire solar cell string 2 when the received light amount improving lenses 3 and 8 are arranged on both sides of the electric wire 10. The measured value is shown.

In addition to the solar battery cell 1b, also in the solar battery cell 1d, since a part of the sunlight to be incident is diverged, the intensity of the incident light is reduced from 1000 W / m ² to 500 W / m ² . Therefore, the output current also decreases from 2.0A to 1.0A. However, the intensity of light incident on the solar cell 1c, by light diverged by the two lenses 3 and 8 is incident, is improved from 100W / ^{m 2} to 300 W / ^{m 2.} This shows that the amount of received light is further improved as compared with the case where the lens 3 is disposed only on one side of the electric wire 10 (see FIG. 3C). As a result, the output current that has been reduced to 0.2 A due to the shadow of the electric wire 10 is also recovered to 0.6 A. Therefore, the output current of the solar battery cell 2 as a whole is improved to 0.6A.

  As described above, by arranging the light receiving amount improving lenses 3 and 8 on both sides of the electric wire 10 which is a light shielding object, the light passing through both sides of the light shielding object is incident on the shadow, and the light receiving amount is reduced. The amount of received light 1c can be further improved.

  In the first embodiment, the received light amount improvement lens 3 is adjacently disposed on one side of the electric wire 10 so that the received light amount of the solar cell 1c having a shadow can be improved to some extent. However, in order to further increase the amount of light received for improvement, if the amount of light diverging from the lens 3 and traveling toward the shadow is increased, the intensity of light incident on the solar cell 1b is lower than that of the solar cell 1c. There is a risk that. Therefore, as in the second embodiment, by providing the two light receiving amount improvement lenses 3 and 8 on both sides of the electric wire 10 that is a light shielding object, light passing through both sides of the electric wire 10 can be incident on the shadow. Therefore, the amount of light received by the solar cell 1c can be further improved without excessively reducing the amount of light received by the solar cells 1b and 1d on both sides of the solar cell 1c.

[3. Third Embodiment]
Next, a solar power generation system according to the third embodiment will be described with reference to FIG.
In the third embodiment, only points different from the first embodiment will be described, and the same parts as those in the first embodiment will be denoted by the same reference numerals and detailed description thereof will be omitted.

  This embodiment demonstrates the case where the light-shielding object which exists in a solar power generation system is the telephone pole 100 extended in the vertical direction. As shown in FIG. 11A, a part of the telegraph pole 100 blocks light that should be incident on the solar cell string 2, so that a shadow is generated so as to cut the solar cell string 2 vertically. In this embodiment, the solar cell string 2 is shown as an example in which a large number of substantially square solar cells 1 are connected in series. Although some of the solar cells have a reduced amount of light received due to the shadow, these cells are connected in series, so that the output current of the entire solar cell string is reduced.

  As shown in FIG. 11B, the received light amount improving lens 3 is attached so as to be adjacent to the telegraph pole 100 along the height direction of the telegraph pole 100. It is not necessary to attach over the entire length of the telephone pole 100, and it is only necessary to attach it to a portion that causes a shadow on the solar cell string 2. The shape of the lens 3 is a shape in which the concave lens is halved, as in the first and second embodiments. The lens surface of the lens 3 is arranged toward the incident surface of the solar cell string 2. Further, the long end 3 b is installed on the side close to the telegraph pole 100 and the short end 3 a is positioned on the side away from the telegraph pole 100.

  For attaching the lens 3 to the telephone pole 100, for example, the band 4 is stretched over and under the attachment position, and the lens 3 into which the frame 5 is fitted is attached via a fixture.

  By arranging the lens 3 adjacent to the telegraph pole 100, the light passing through the vicinity of the electric wire 10 enters the lens 3. The light that enters the position near the short end 3 a that is away from the telephone pole 100 travels straight or is slightly refracted and enters the solar cell string 2. On the other hand, the incident light on the long end 3 b side of the lens 3 is greatly refracted and diverged, and enters the shadow on the solar cell string 2. Thus, when a part of the light emitted by the lens 3 enters the shadow, the amount of light received by the solar cell 1 located in the shadow is improved, and the output current of the entire solar cell string 2 is also improved. The

  Although the shadow caused by the telephone pole 100 moves with time, the lens 3 diverges light that passes through the vicinity of the telephone pole 100 and is incident on the solar cell string 2. Moves almost the same as the shadow. Therefore, the received light amount improving lens 3 of the present embodiment can irradiate light by following the shadow of the telegraph pole 100 without requiring a special adjustment mechanism even for a vertically extending light shield. .

  In the present embodiment, the telegraph pole 100 is illustrated as a vertically extending light shield. However, the telegraph pole 100 is not limited to this, and the light pole can be similarly attached to other vertically extending light shields such as a lightning rod and a sign post.

[4. Other Embodiments]
In the above-described embodiment, a lens having a shape in which the biconcave lens is halved is used as the light reception amount improving lens. However, since the lens for improving the amount of received light achieves the purpose if the incident sunlight diverges and is emitted, it is not necessary to make the incident surface concave. Therefore, a plano-concave lens may be used instead of the biconcave lens.

  Further, in the above-described embodiment, the light receiving amount improving lens in which a band is stretched around a light shielding object such as an electric wire or a telephone pole and the frame is fitted is attached using a mounting tool. However, when attaching to a light-shielding object having a small diameter such as a lightning rod, the lens may be directly attached using an attachment tool without covering the light-shielding object with a band.

  The present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

1, 1a, 1b, 1c, 1d, 1e, 1f Solar cell 2 Solar cell string 3, 8 Lens 3a, 8a for light reception improvement Short end 3b, 8b Long end 4 Band 5 Frame 5a Horizontal frame 5b Vertical frame 6, 7 Mounting tool 10 Electric wire (shading object)
100 telephone pole (shading object)

Claims (7)

A solar cell string in which a plurality of solar cells that convert incident solar energy into electrical energy are connected in series;
A light reception amount improving lens disposed adjacent to a light blocking object that blocks the sunlight incident on the solar cell string and causes a shadow, and
The received light amount improving lens diverges a part of sunlight passing near the light shielding object toward the shadow.   The received light amount improvement lens has a shape in which a concave lens is halved, the short surface side through which the optical axis of the received light amount improvement lens passes is disposed away from the light shielding object, and the long surface side is the light shielding object. The photovoltaic power generation system according to claim 1, wherein the photovoltaic power generation system is disposed adjacently.   The received light amount improving lens is configured such that the light emitted from the received light amount improving lens has the shadow range based on a distance from the light shield to the solar cell and a shadow range caused by the light shield. The photovoltaic power generation system according to claim 1, wherein a focal length is determined so as to include the photovoltaic power generation system.   2. The received light amount improving lens is disposed two on both sides of the light shielding object, and each part diverges part of sunlight passing through both sides of the light shielding object toward the shadow. The solar power generation system as described in any one of -3.   The lens for improving the amount of received light is attached to a band spanned around the light blocking object by adjusting an attachment position and an attachment angle via an attachment. The photovoltaic power generation system according to one item.   For solar cell strings in which a plurality of solar cells that convert the energy of incident sunlight into electrical energy are connected in series, the solar cells are arranged adjacent to a light-shielding object that blocks incident sunlight and produces a shadow, A lens for improving the amount of received light of a solar power generation system, wherein a part of sunlight passing near the shade is diverged toward the shadow. For a solar battery string in which a plurality of solar cells that convert incident solar energy into electrical energy are connected in series, a lens for improving the amount of received light is provided on a light blocking object that blocks incident sunlight and produces a shadow. A method for improving the amount of light received by a photovoltaic power generation system arranged adjacent to each other,
A band is placed around the shade,
Adjust the mounting position and angle to the band via a mounting tool, and attach the lens for improving the amount of received light,
A method for improving the amount of received light of a solar power generation system, characterized in that a part of sunlight passing near the shade is diverged toward the shadow by the lens for improving the amount of received light.