Solar Panel Array for Improved Light Capture and Conversion

Abstract

Embodiments of the disclosure are generally related to solar panel configurations. In some embodiments, the active surface area of the solar panel is increased compared to traditional flat solar cell arrays. The increase in active surface area may increase solar panel efficiency. For example, in some embodiments, a single light ray may have portions reflected onto a plurality of solar cell surfaces to provide further opportunities for light capture and conversion to electricity.

Description

BACKGROUND

Solar power is the Holy Grail of clean energy. Harnessing the power of the sun dates back to ancient times when mirrors and lenses were used to start fires. The idea that the sun provides a continuous source of clean energy is widely accepted in theory. But the limited efficiency of photovoltaic cells has limited the application of solar energy in the real world.

Accordingly, systems and methods for improving the efficiency of solar power may be desired.

SUMMARY

Efforts to improve the efficiency of solar power focus around several techniques. These include improving the efficiency of the photovoltaic cells themselves. Some designs split and direct light wavelengths towards specific photovoltaic cells. Other systems may use lenses to focus the incoming light onto photovoltaic cells. Additionally, dynamic systems may use motors to turn and move the solar panels to ensure they are always facing the sun.

Embodiments of the present invention are generally directed to solar cell configurations and arrays thereof, each of which may be used in conjunction with any of the above techniques for improving solar power efficiency.

In some embodiments, a solar panel may be provided that includes: a solar cell pit comprising a first solar cell forming a first pit side of the solar cell pit, a second solar cell forming a second pit side of the solar cell pit, and a third solar cell forming a third pit side of the solar cell pit—each of the first solar cell, the second solar cell, and the third solar cell may be configured to convert solar energy to electricity. The first solar cell may comprise a first edge and a second edge that converge at a ninety degree angle to form a corner of the first pit side; the second solar cell may comprise a first edge and a second edge that converge at a ninety degree angle to form a corner of the second pit side; and the third solar cell may comprise a first edge and a second edge that converge at a ninety degree angle to form a corner of the third pit side. The corner of the first pit side, the corner of the second pit side, and the corner of the third pit side may be joined together such that the first edge of the first solar cell is adjacent to the second edge of the second solar cell, the first edge of the second solar cell is adjacent to the second edge of the third solar cell, the first edge of the third solar cell is adjacent to the second edge of the first solar cell, and such that the first solar cell, the second solar cell, and the third solar cell are orthogonal to one another. A light ray received by the solar cell pit that impinges on the first solar cell may be partially captured by the first solar cell to be converted to electricity and partially reflected by the first solar cell toward the second solar cell. Light reflected by the first solar cell toward the second solar cell may be partially captured by the second solar cell to be converted to electricity and partially reflected by the second solar cell toward the third solar cell and light reflected by the second solar cell toward the third solar cell may be at least partially captured by the third solar cell to be converted to electricity.

The solar panel described above may include a plurality of the solar cell pits arranged in an array. In some embodiments, the first solar cell, the second solar cell, and the third solar cell may have a rectangular configuration. In some embodiments, the first solar cell, the second solar cell, and the third solar cell may have a triangular configuration.

In still further embodiments, a system may be provided that includes three of the solar panels described above. In some embodiments, the three solar panels may each having a rectangular configuration and may be joined together such that each of the three solar panels are at 90-110 degrees relative to one another. And in some embodiments, the solar panels may be orthogonal to one another.

In still further embodiments, another system may be provided that includes three of the solar panels described above. The three solar panels may each have a triangular configuration and may be joined together such that each of the three solar panels are at 90-110 degrees relative to one another. And in some embodiments, the solar panels may be orthogonal to one another.

In further embodiments, a solar panel may be provided that includes: a solar cell pit comprising a first solar cell forming a first triangular pit side of the solar cell pit, a second solar cell forming a second triangular pit side of the solar cell pit, and a third solar cell forming a third triangular pit side of the solar cell pit—each of the first solar cell, the second solar cell, and the third solar cell configured to convert solar energy to electricity. The first solar cell may comprise a first edge and a second edge that converge at a 90-110 degree angle to form a corner of the first pit side; the second solar cell may comprise a first edge and a second edge that converge at a 90-110 degree angle to form a corner of the second pit side; and the third solar cell may comprise a first edge and a second edge that converge at a 90-110 degree angle to form a corner of the third pit side.

The corner of the first triangular pit side, the corner of the second triangular pit side, and the corner of the third triangular pit side may be joined together such that the first edge of the first solar cell is adjacent to the second edge of the second solar cell, the first edge of the second solar cell is adjacent to the second edge of the third solar cell, and the first edge of the third solar cell is adjacent to the second edge of the first solar cell.

At least some light rays received by the solar cell pit that impinge on the first solar cell may be partially captured by the first solar cell to be converted to electricity and partially reflected by the first solar cell toward the second solar cell. At least some light reflected by the first solar cell toward the second solar cell may be partially captured by the second solar cell to be converted to electricity and partially reflected by the second solar cell toward the third solar cell. And light reflected by the second solar cell toward the third solar cell may be at least partially captured by the third solar cell to be converted to electricity.

In some embodiments, a plurality of the solar cell pits may be provided that are arranged in an array.

In some embodiments, a solar panel system may be provided that includes three solar panels described above, the three solar panels may be joined together such that each of the three solar panels are at 90-110 degrees relative to one another. Optionally, the three solar panels may be orthogonal to one another.

In still further embodiments, a solar panel may be provided that includes a tessellated array of solar cell pits. Each of the solar cell pits of the array may include a first solar cell forming a first pit side of the solar cell pit, a second solar cell forming a second pit side of the solar cell pit, and a third solar cell forming a third pit side of the solar cell pit. Each of the first solar cell, the second solar cell, and the third solar cell may be configured to convert solar energy to electricity and each may comprise a first edge and a second edge that converge at a ninety degree angle to form a corner. The corners of the pit sides of the solar cell pit may be joined together such that the corners of the pit sides form a bottom of the solar cell pit and such that the pit sides are at an angle between 60-110 degrees with adjacent pit sides. The first solar cell, the second solar cell, and the third solar cell may comprise a triangular configuration or a rectangular configuration.

At least some light rays received by the solar cell pit that impinges on the first solar cell may be partially captured by the first solar cell to be converted to electricity and partially reflected by the first solar cell toward the second solar cell. At least some light reflected by the first solar cell toward the second solar cell may be partially captured by the second solar cell to be converted to electricity and partially reflected by the second solar cell toward the third solar cell. Light reflected by the second solar cell toward the third solar cell may be at least partially captured by the third solar cell to be converted to electricity.

In some embodiments, the pit sides are at an angle between 90-110 degrees with adjacent pit sides. Optionally, the pit sides are orthogonal with adjacent pit sides.

In some embodiments, a solar panel system may be provided that includes three solar panels described above, the three solar panels may be joined together such that each of the three solar panels are at 60-110 degrees with adjacent solar panels. Optionally, the three solar panels are at 90-110 degrees with adjacent solar panels. In some embodiments, the three solar panels are orthogonal to one another.

In some embodiments, the three solar panels may have a rectangular configuration. In other embodiments, the three solar panels may have a triangular configuration.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an exemplary solar cell pit configuration according to some embodiments of the present disclosure.

FIG. 2 illustrates an exemplary array of the solar cell pit configuration of FIG. 1.

FIG. 3 illustrates another exemplary solar cell pit configuration according to some embodiments of the present disclosure.

FIG. 4 illustrates an exemplary array of the solar cell pit configuration of FIG. 3.

DETAILED DESCRIPTION

The basis of the design proposed in this patent is arranging the solar panels and photovoltaic cells in a layout that better captures the initial incoming light and the subsequently reflected light. The proposed layout may add depth to the traditional panels that have all the photovoltaic cells laid flat next to one another forming large flat panels. For example, in some embodiments, instead of arranging the photovoltaic cells in a flat planar array, embodiments of the present disclosure may include a layout where cells are arranged to form solar cell pits with openings, thereby increasing the solar cell surface area of the solar panel. Optionally, a plurality of these pits may be tessellated next to one another to the size and shape of the desired panel. In some embodiments, each of the plurality pits may have a retroreflector configuration.

In some embodiments, solar cell pits may be made up of three pit sides that are orthogonal to one another. Optionally, each pit side may be planar. Each pit side may have two edges that form a corner of the pit side. In some embodiments, the edges may meet at a ninety degree angle to form the corner. Each of the ninety degree corners of the three pit sides may be joined such that each pit side is orthogonal to one another to form the bottom of the solar cell pit. In some embodiments, the three pit sides may form a pit with a corner cube configuration.

This arrangement of pit sides may increase the light energy captured from light entering each of the solar cell pits. While some light energy is captured at initial contact with one of the pit sides, a portion of the light energy may be reflected from the pit side initially contacted. When the light ray is non-normal to the pit side, this reflected light may be directed to an adjacent pit side where additional light energy may be captured. Any portion of light reflected from the adjacent pit side will impinge on the final pit side where another opportunity arises to capture light. Accordingly, the configuration may increase light capture of light energy that is reflected from one or more of the pit sides.

FIG. 1 illustrates an exemplary solar cell pit configuration 10 according to some embodiments of the present disclosure. Solar cell pit 10 may include a first pit side 100, a second pit side 102, and a third pit side 103. The first pit side 100, the second pit side 102, and the third pit side 103 may have a ninety degree corner and each of the sides 100, 102, 103 may be joined such that the sides 100, 102, 103 are orthogonal to one another. FIG. 1 also illustrates an exemplary light ray 104a. Light ray 104a initially impinges on pit side 102. A portion of light ray 104a may be captured by pit side 102 and converted to energy and a remainder portion 104b may be reflected from the surface of pit side 102. Light ray 104b may be reflected toward pit side 100 where a portion of light ray 104b may be captured by pit side 100 and converted to energy and a remainder portion 104c may be reflected from the surface of pit side 100. Light ray 104c may be reflected toward the third pit side 103 where a portion of light ray 104c may be captured by pit side 103.

As mentioned above, in some embodiments, the solar cell pits may be arranged in an array to form a solar panel. Optionally, the solar cell pits may be tessellated to form the solar panel. For example, FIG. 2 illustrates an exemplary array 110 of the solar cell pit configuration 10 of FIG. 1 to form an exemplary solar panel according to some embodiments of the disclosure.

While the pit sides 100, 102, 103 are illustrated as having a rectangular or square configuration, it should be understood that other configurations are possible. For example, FIG. 3 illustrates another exemplary solar cell pit configuration 20 according to some embodiments of the present disclosure. Solar cell pit 20 may include a first pit side 200, a second pit side 202, and a third pit side 203. The first pit side 200, the second pit side 202, and the third pit side 203 may have a triangular configuration. In some embodiments, the pit sides 200, 202, 203 may have an isosceles configuration with a ninety degree vertex angle. The sides 200, 202, 203 may be joined at the ninety degree corner and each of the sides 200, 202, 203 may be joined such that the sides 200, 202, 203 are orthogonal to one another. In such an embodiment, the solar cell pit 20 may define a triangular opening to the pit 20. Similar to pit 10 of FIG. 1, pit configuration 20 of FIG. 3 may be provided in an array to form a solar panel according to some embodiments. For example, FIG. 4 illustrates an exemplary array 210 of the solar cell pit configuration 20 of FIG. 3. As illustrated the solar panel 210 comprises a plurality of solar cell pits 20 that are tessellated.

While the exemplary embodiments illustrated in FIGS. 1-4 illustrate solar cell pits that are in a retroreflective configuration, it should be understood that other configurations are possible where the three panels are not orthogonal to one another. In some embodiments, the pit sides may be joined together at corners, where the corners of each of the pit sides is less than or greater than ninety degrees. For example, in some embodiments, the corners of the pit sides where the pit sides are joined may be between 80-120 degrees, preferably between 90-120 degrees. Additionally, while the exemplary embodiments illustrated in FIGS. 1-4 illustrate solar cell pits that comprise three sides, other embodiments may have three or more sides, e.g., four, five, six or more.

In some embodiments, the configurations described above could compound on itself, e.g., by arranging the photovoltaic cells in the same pit design on the sides of larger pits. This can continue ad infinitum. For example, three solar panels (e.g., panel 110, panel 210), each of which include a plurality of pits, may be arranged orthogonal to one another. The three solar panels may have a rectangular or triangular configuration.

The surface area of the proposed pitted design may increase the surface area over the typical flat design. For example, the embodiments illustrated in FIG. 4 may have approximately 73.2% more surface area compared to that of a traditional flat solar panel. This increase in cost and manufacturing may be offset by the increase in overall efficiency of the panel utilizing the pit configuration.

In some embodiments, the configurations and/or arrays may increase solar power efficiency, even without the use of motors. Advantageously, these static systems may reduce manufacturing, installation, and maintenance costs as these systems may be free from moving components. While this may be desirable in certain circumstances, the configurations and/or arrays described herein may also be used to improve the efficacy of solar panels that continuously move to keep facing the sun.

Claims

1. A solar panel comprising: an array comprising a first solar cell configuration, a second solar cell configuration, and a third solar cell configuration;the first solar cell configuration comprising a first side, a second side, and a third side, wherein each of the first side, the second side, and the third side are configured to convert solar energy to electricity; the first side of the first solar cell configuration comprising a first edge and a second edge that converge to form a corner of the first side;the second side of the first solar cell configuration comprising a first edge and a second edge that converge to form a corner of the second side;the third side comprising of the first solar cell configuration a first edge and a second edge that converge to form a corner of the third side;wherein the corner of the first side of the first solar cell configuration, the corner of the second side of the first solar cell configuration, and the corner of the third side of the first solar cell configuration are joined together such that the first edge of the first side is adjacent to the second edge of the second side, the first edge of the second side is adjacent to the second edge of the third side, the first edge of the third side is adjacent to the second edge of the first side;wherein light received by the first solar cell configuration that impinges on the first side of the first solar cell configuration is partially captured by the first side to be converted to electricity and partially reflected by the first side toward the second side of the first solar cell configuration;wherein light reflected by the first side of the first solar cell configuration toward the second side of the first solar cell configuration is partially captured by the second side to be converted to electricity and partially reflected by the second side toward the third side of the first solar cell configuration; andwherein light reflected by the second side of the first solar cell configuration toward the third side of the first solar cell configuration is at least partially captured by the third side to be converted to electricity;the second solar cell configuration comprising a first side, a second side, and a third side, wherein each of the first side, the second side, and the third side are configured to convert solar energy to electricity; the first side of the second solar cell configuration comprising a first edge and a second edge that converge to form a corner of the first side;the second side of the second solar cell configuration comprising a first edge and a second edge that converge to form a corner of the second side;the third side of the second solar cell configuration comprising a first edge and a second edge that converge to form a corner of the third side;wherein the corner of the first side of the second solar cell configuration, the corner of the second side of the second solar cell configuration, and the corner of the third side of the second solar cell configuration are joined together such that the first edge of the first side is adjacent to the second edge of the second side, the first edge of the second side is adjacent to the second edge of the third side, the first edge of the third side is adjacent to the second edge of the first side;wherein light received by the second solar cell configuration that impinges on the first side of the second solar cell configuration is partially captured by the first side to be converted to electricity and partially reflected by the first side toward the second side of the second solar cell configuration;wherein light reflected by the first side of the second solar cell configuration toward the second side of the second solar cell configuration is partially captured by the second side to be converted to electricity and partially reflected by the second side toward the third side of the second solar cell configuration; andwherein light reflected by the second side of the second solar cell configuration toward the third side of the second solar cell configuration is at least partially captured by the third side to be converted to electricity;the third solar cell configuration comprising a first side, a second side, and a third side, wherein each of the first side, the second side, and the third side configured to convert solar energy to electricity; the first side of the third solar cell configuration comprising a first edge and a second edge that converge to form a corner of the first side;the second side of the third solar cell configuration comprising a first edge and a second edge that converge to form a corner of the second side;the third side of the third solar cell configuration comprising a first edge and a second edge that converge to form a corner of the third side;wherein the corner of the first side of the third solar cell configuration, the corner of the second side of the third solar cell configuration, and the corner of the third side of the third solar cell configuration are joined together such that the first edge of the first side is adjacent to the second edge of the second side, the first edge of the second side is adjacent to the second edge of the third side, the first edge of the third side is adjacent to the second edge of the first side;wherein light received by the third solar cell configuration that impinges on the first side of the third solar cell configuration is partially captured by the first side to be converted to electricity and partially reflected by the first side toward the second side of the third solar cell configuration;wherein light reflected by the first side of the third solar cell configuration toward the second side of the third solar cell configuration is partially captured by the second side to be converted to electricity and partially reflected by the second side toward the third side of the third solar cell configuration; andwherein light reflected by the second side of the third solar cell configuration toward the third side of the third solar cell configuration is at least partially captured by the third side to be converted to electricity;wherein the third side of the first solar cell configuration is adjacent to the first side of the second solar cell configuration and the second side of the third solar cell configuration; andwherein the first side of the second solar cell configuration is adjacent to the second side of the third solar cell configuration.

2. The solar panel of claim 1, wherein each of the first side, the second side, and the third side of the first solar cell configuration, the first side, the second side, and the third side of the second solar cell configuration, and the first side, the second side, and the third side of the third solar cell configuration have a square configuration.

3. The solar panel of claim 1, wherein each of the first side, the second side, and the third side of the first solar cell configuration, the first side, the second side, and the third side of the second solar cell configuration, and the first side, the second side, and the third side of the third solar cell configuration have a triangular configuration.

4. The solar panel of claim 1, wherein the first side, the second side, and the third side of the first solar cell configuration are orthogonal to one another, wherein the first side, the second side, and the third side of the second solar cell configuration are orthogonal to one another, and wherein the first side, the second side, and the third side of the third solar cell configuration are orthogonal to one another.

5. A solar panel comprising: a first side, a second side, and a third side, each of the first side, the second side, and the third side configured to convert solar energy to electricity;the first side comprising a first edge and a second edge that converge to form a corner of the first side;the second side comprising a first edge and a second edge that converge to form a corner of the second side;the third side comprising a first edge and a second edge that converge to form a corner of the third side;the first side, the second side, and the third side defining a four-sided opening;wherein the corner of the first side, the corner of the second side, and the corner of the third side are joined together such that the first edge of the first side is adjacent to the second edge of the second side, and the first edge of the second side is adjacent to the second edge of the third side;wherein at least some light received through the four-sided opening of that impinge on the first side is partially captured by the first side to be converted to electricity and partially reflected by the first side toward the second side;wherein at least some light reflected by the first side toward the second side is partially captured by the second side to be converted to electricity and partially reflected by the second side toward the third side; andwherein light reflected by the second side toward the third side is at least partially captured by the third side to be converted to electricity.

6. The solar panel of claim 5, wherein the first side is a rectangular configuration.

7. The solar panel of claim 6, wherein the first side is a square configuration.

8. The solar panel of claim 5, wherein the first side is a triangular configuration.

9. A solar panel comprising: a tessellated array of solar cell configurations, each of the solar cell configurations of the tessellated array comprising: a first side of the solar cell configuration, a second side of the solar cell configuration, and a third side of the solar cell configuration, each of the first side, the second side, and the third side configured to convert solar energy to electricity and each comprising a first edge and a second edge that converge at a ninety degree angle to form a corner, wherein the corners of the sides of the are joined together such that the corners of the sides form a bottom of the and such that the sides are at an angle between 60-110 degrees with adjacent sides, and the first side, the second side, and the third side defining a three or more sided opening of the solar cell configuration;wherein at least some light received by the solar cell configuration through the three or more sided opening of the solar cell configuration that impinges on the first side is partially captured by the first side to be converted to electricity and partially reflected by the first side toward the second side;wherein at least some light reflected by the first side toward the second side is partially captured by the second side to be converted to electricity and partially reflected by the second side toward the third side; andwherein light reflected by the second side toward the third side is at least partially captured by the third side to be converted to electricity.

10. The solar panel system of claim 9, wherein the sides are at an angle between 90-110 degrees with adjacent sides.

11. The solar panel system of claim 10, wherein the sides are orthogonal with adjacent sides.

12. The solar panel system of claim 9, wherein the sides are not orthogonal with adjacent sides.

13. The solar panel system of claim 9, wherein the first side, the second side, and the third side define a five sided opening of the solar cell configuration.