DE102015216994A1 - Photovoltaic glass with independent light traps - Google Patents

Abstract

The present invention relates to photovoltaic glass for a solar cell. The photovoltaic glass has on its surface independent annular structures, i. H. independent light traps, wherein an outer diameter of the ring is in the range of 0.1 5 mm and an included angle between the inner ring and the outer ring is less than or equal to 90 °, so that reflection and refraction of light rays occur several times within an independent annular structure ,

Description

Technical area

The present invention relates to photovoltaic glass used for photovoltaic solar cells, and more particularly to high-permeability photovoltaic glass having independent light traps.

Background of the invention

The energy shortage has become a core problem that is currently hampering the development of countries around the world. As a green energy source that can be used sustainably, the solar energy is available in excess and does not cause environmental pollution. Thus, in terms of a long-term strategy, the development and use of solar energy is an important step in achieving sustainable development for all countries. The use of solar energy is currently being realized around the world in two ways: one is to use a heat collector to convert the solar radiant energy into heat energy, such as solar hot water heating, etc .; the other is to use a solar cell to convert solar energy into electrical energy, ie, photovoltaic power generation, such as a solar cell, etc. In the facility that converts light energy into heat energy or in the facility that converts light energy into electrical energy, is a solar housing assembly a required arrangement, and such solar housing assembly must have a high transmittance of light (a transmittance greater than or equal to 91%, a Fe ₂ O ₃ content of less than or equal to 150 ppm), must be waterproof, no serious decrease in the Show performance when exposed to the natural environment for a long time, must have a high mechanical strength against external forces and thermal stress, must have a certain corrosion resistance, have a small coefficient of expansion, etc. Currently, only new types of solar photovoltaic glass and permeable plastic plates meet the aforementioned requirements. However, it is known that a transparent plastic plate is not suitable for being used as a cover plate because it is subject to wear and has a low softening point and a large coefficient of thermal expansion, while the new type of solar photo-voltaic glass is widely used as the material for the solar housing assembly because it has a stable chemical behavior and almost no wear.

The solar cell is also referred to as a "solar chip" or "photocell," which is a photoelectric semiconductor layer that uses sunlight to directly generate electricity. Once light is shone, it can immediately output voltage and can generate power when there is a circuit. It is referred to in physics as solar photovoltaic (abbreviated PV) and short as photovoltaic. The solar cell includes photovoltaic glass, a solar cell layer, etc., which photovoltaic glass is used to protect the power generating body (for example, solar cell layers), and must have a high transmittance of light (over 91% as mentioned above) and must be ultra white and be tempered; whereas the solar cell layer is mainly used for power generation. The conversion efficiency of a solar cell layer is an essential aspect that influences the performance of the solar cell. There are many factors that are known today that affect the conversion efficiency of the solar cell, such as the intensity of sunlight, the cell material, the standard of manufacturing technology, etc. Due to the effect of the various factors, it is already difficult in the industry, the conversion efficiency also only to increase 1% currently in studying the conversion efficiency of solar cell layer.

As is known from the structure of a solar cell, the transmittance of the photovoltaic glass directly affects the conversion efficiency of the solar cell. Thus, if the transmittance of the photovoltaic glass can be increased, the photoelectric conversion efficiency of the solar cell will increase.

In order to realize low reflection, low absorption, and high transmittance of light, Patent Document 1 discloses an optical element for controlling surface topography to change specular reflection. It uses optics that attenuate specular reflections for electromagnetic waves along the surface of an object and reduces the overall reflection and acts as a light trap or light trapping zone. The optic contains a conical relief that is able to reflect and absorb, and has several cones of different heights, which are irregularly arranged on their surface. The height of the surface relief is between 0.1 microns and 2 millimeters and the shape of the base units of the surface relief is a pyramid or triangle cone or polygon cone, each of the base units having a base area of 0.04 square microns to 8 square millimeters.

Non-Patent Literature Document 2 discloses the application of a light trap in a crystalline silicon solar cell. It discloses the use of the light trap to reduce reflection, with conventional light traps containing pyramid units, where the apex angle of each cube is the pyramid units tetragonal pyramidal unit 70 ° 23 '. The unit can reduce the reflection to 1/3 of a smooth surface, and it can be seen from another calculation for the optical properties of the unit that 11% of the light is reflected by the secondary reflection and refracted a third time. Thus, it can be calculated that the reflection of the unit is 9.04%.

Patent Document 2 discloses a light trap technology with a glass sphere aperture portion, wherein an aperture array is fabricated on a thin plate made of a certain material. Metal reflection layers are deposited on sidewalls of the apertures on two surfaces of the thin plate, and then various materials required for the thin film solar cell are sequentially applied to the surface of the thin plate. A glass ball is placed on top of each opening on the top surface of the thin plate. These glass spheres, which are close to each other, form a surface array of glass spheres capable of dividing sunlight into an array of low intensity light rays. Light rays can pass through the openings of the thin plate and are trapped between the thin plate and an extremely thin photovoltaic cell plate under the thin plate. They are repeatedly absorbed and converted into electrical energy, so that a light trap is formed.

The foregoing Patent Document 1 and Non-Patent Publication 2 use a conical / pyramidal projection as a light trap structure, while Patent Document 3 uses a light trap structure of an aperture array. According to the disclosure of these patents and the non-patent document, they can change the reflection of the secondary reflection at most to 1%. In other words, the transmittance of light is not unexpectedly increased to a great extent using this technology.

Patent document 1: CN1157929A
Non-patent document 2: Application of a light trap in a crystalline silicon solar cell (development of laser and photoelectronics, Vol. 41, Number 5, 2004, pages 56-58 and 44) ,
Patent 3: CN102623578A ,

Overview of the invention

Due to the problems in the prior art, the present invention provides a photovoltaic glass having independent light trapping zones for use in solar cells, wherein special independent light trapping structures are used to reduce the light reflection, thereby greatly increasing the light transmittance and further the photoelectric conversion efficiency of the solar cell layers is increased.

In accordance with one aspect of the present invention, a photovoltaic glass is provided for use in solar cells. The photovoltaic glass has independent annular structures on its surface, i. H. the independent light traps, wherein an outer diameter of the ring is in a range of 0.1 ~ 5 mm, and an angle between the inner ring and the outer ring is less than or equal to 90 °, so that the reflection and refraction of light within a independent annular structure is done several times.

Preferably, in the photovoltaic glass of the present invention, smaller light traps are provided in voids of the independent light traps, so that the light transmittance is improved.

Preferably, in the photovoltaic glass of the present invention, the smaller light traps have the shape of a concave pointed cone.

Preferably, in the photovoltaic glass of the present invention, the independent light traps are arranged close to each other in the form of a honeycomb structure.

Preferably, in the photovoltaic glass of the present invention, the independent light traps are arranged in the form of a square.

According to another aspect of the present invention, there is provided a method of manufacturing a photovoltaic glass according to the present invention, comprising the steps of:
Machining an impeller with combined independent light trap structures using a special processing device;
Rolling up a roller using the impeller and mounting the roller on a trowel;
Embossing the photovoltaic glass using the trowel.

Due to the particular annular light trap structures used, the photovoltaic glass having independent light traps according to the present invention can capture 99.8% of the light impinging on the glass interface for the first time, that is, it can capture 96% of the reflected light that is generated for the first time while existing photovoltaic glass products can capture only about 30% ~ 40% of the reflected light entering the glass interface for the first time. Thus, the photovoltaic glass of the present invention makes it possible to guide more light through the photovoltaic glass to be connected to the photoelectric Participate conversion process, whereby the power generation rate of the solar cell is increased.

The statistics show that solar cells of about 30,000,000 kw were produced in China by the end of 2011, which is about half of the world's total production, and photovoltaic glass of 300 million square meters is required accordingly. If manufacturers of the respective solar cell assemblies sell the photovoltaic glass of the present invention at a price 2% -3% higher than the market price (the cost of the photovoltaic glass is only 8% of the total cost), the profit of the respective photovoltaic glass manufacturers may be 2% -3 % and the corresponding manufacturers of solar cell assemblies can become more profitable by 1.5% to 2.7%. Therefore, the present invention has a high commercial value and has prospects of market development.

Brief description of the drawings

1 is a structural diagram of a solar cell.

2 Fig. 12 is a schematic view of the light passage through the photovoltaic glass of the present invention.

3 Fig. 12 is a drawing showing the independent light trap structures of the photovoltaic glass of the present invention.

4 Fig. 12 is a drawing showing a planar arrangement of the independent light trap structures of the photovoltaic glass of the present invention.

5 Fig. 15 is a drawing showing the surface structure of the photovoltaic glass of the present invention.

6 shows a perspective of the small traps that are generated at the empty spaces of the respective light traps.

LIST OF REFERENCE NUMBERS

1

photovoltaic glass

2

solar cell layer

3

substratum

4

adhesives

5

seal rubber

6

frame

10

independent light trap

12

small trap

Detailed description of the invention

Some terms are used throughout the application documents to refer to specific components. As those skilled in the art will recognize, different terms may be used for the same component, so the present application is not intended to distinguish those components which differ only in their name but not function. In the present application documents, the terms "comprise", "comprise" and "with" are used in an open manner so that they are to be interpreted as meaning "but not limited to ...". Further, the terms "about," "substantially," or "approximately" as used in this specification include a tolerance that is acceptable in the industry.

In the following descriptions, for purposes of explanation, many specific details are set forth in order to provide a more thorough understanding of the present invention. However, it will be apparent to those skilled in the art that the apparatus, methods and apparatus of the present invention may be practiced without these specific details. Designations such as "embodiment" or "example", which are referred to in this specification, denote these specific features, structures or properties described with reference to said embodiment or said example, and are at least in said embodiment or said embodiment Example, but they are not necessarily included in other embodiments or examples.

The present invention will now be further described with reference to the preferred embodiments and figures.

1 is a structural diagram of a solar cell. The solar cell includes a photovoltaic glass 1 , which serves as a housing of the solar cell and protects it, a solar cell layer 2 used as a semiconductor device for directly converting solar energy into electrical energy, a substrate 3 , an adhesive 4 , a sealing rubber 5 and a frame 6 etc. As mentioned in the previous text, according to the structure of FIG 1 shown solar cell the photovoltaic glass 1 one of the important components of the solar cell, which not only functions to protect and transmit light and as the cell electrode, but also has important properties such as increasing the light utilization rate and increasing the cell efficiency. The translucence of the photovoltaic glass 1 directly affects the photoelectric conversion efficiency of the solar cell, so that the present invention is aimed at increasing the light transmittance of the photovoltaic glass 1 aims.

Many effective methods of increasing the photoelectric conversion efficiency of a cell have been proposed at present, such as the quantum dot structure, the wavelength conversion structure and the light trapping structure, etc. The present invention provides a novel light trapping structure with respect to the existing photovoltaic glass (the light trapping structure is considered a "light trap"). This means that when light falls on the structure, all or most of the light rays will not be reflected back, different surfaces will have different light trap effects, and will affect the photovoltaic cell differently), ie, an annular mirror design that allows reflection and reflection Refracting light several times within a single independent annular structure. The independent annular structure is referred to as "an independent light trap" in the present application. Furthermore, the ability to diffuse incident light through the light trap structure is an important aspect in determining the quality of the light trap structure. Not only can a good light trap structure scatter many beams of light and cause the scattered light to be distributed in a wide angular range, so that the optical absorption length for more light beams can be increased, but also causes incident light having different angles to be absorbed into the solar cell absorption area occurs, so that the cell can fully exploit obliquely incident sunlight in the actual use to increase the power generating capacity. The existing photovoltaic glass has hill-shaped protrusions that are made on its surface and distributed irregularly, but such structures can capture only a small portion of the reflected light. In order to completely capture the reflected light and increase the light transmittance, the present invention employs and distributes several of the aforementioned independent light trap units densely over the entire surface of the photovoltaic glass 1 , so that almost all the reflected light into the solar cell layer 2 occurs after repeated reflection and refraction of the light rays, whereby the light transmittance of the photovoltaic glass is greatly increased. As a result, the photoelectric conversion efficiency of the solar cell is increased, and a pronounced effect in actual use is achieved.

5 Fig. 12 is a drawing showing the surface structure of the photovoltaic glass according to the present invention. As in 5 is shown, retains the bottom surface of the photovoltaic glass 1 on the other hand, the top surface (ie, the top surface) has patterns impressed by a special embossing means. The patterns are independent annular structures, ie independent light traps 10 , These independent light traps 10 are arranged close to each other in the form of a honeycomb structure and are uniformly and continuously distributed on the top surface.

3 Figure 12 shows a planar structure of an independent light trap according to the present invention, wherein an included angle between the inner and outer rings of the annular structure is less than 90 °. The outer diameter of the ring is determined by the thickness of the photovoltaic glass. In an example of the present invention, the outer diameter of the ring is set to 0.1 ~ 5 mm.

4 Fig. 12 is a drawing showing a planar arrangement of the independent light trap structures of the photovoltaic glass according to the present invention. As in 4 shown are the independent light traps 10 arranged close to each other in the form of a honeycomb structure, whereby the surface is utilized to the maximum. There may be some small traps to increase light transmission 12 at intersections between rings of independent light traps 10 getting produced.

6 Fig. 12 shows a perspective of the small traps made on voids of the respective independent light traps. As in 6 shown has each of the little traps 12 the shape of a concave pointed cone to increase the light transmission.

In this embodiment, the independent light traps 10 arranged close to each other in the form of a honeycomb structure, but the arrangement of the independent light traps is not limited to this honeycomb structure. For example, a square arrangement may also be used. However, arrangements such as the square array do not have the high efficiency of the arrangement of the honeycomb structure, though they can be easily manufactured, so that they are not preferable to the present invention.

In the present invention, the special annular light trap structure is used to process the photovoltaic glass and other transmissive materials of the solar cell. Since the photovoltaic glass according to the present invention has the specific independent light trap structures, most light rays entering the glass can be reflected twice, three times, four times or more, so that light rays reflected back to the atmosphere can be significantly reduced the transmission of light rays is increased accordingly.

The principle of transmittance of the photovoltaic glass according to the present invention will be described in detail below. According to a physical principle, when light passes from one medium to another medium, as long as the media have different densities, light is reflected and refracted. When the incident light on the oblique surface of the light trap structure of the photovoltaic glass is once reflected and refracted, some of the reflected light enters the adjacent oblique surface, resulting in a second incidence of light, so that the amount of incident light is increased. Meanwhile, incident light having different angles is generated in the process of repeated incidence, so that a light scattering effect is achieved.

2 Fig. 10 is a schematic view of the light passage in the photovoltaic glass according to the present invention. As in 2 is shown, when a light beam S on the inclined surface AB of the independent light trap 10 according to the present invention, this is reflected and refracted, whereby a reflected light beam S1 and a refracted light beam S2 are generated. When the reflected light beam S1 to an adjacent oblique surface of the independent light traps 10 continues running, ie an inclined surface BC, the reflected light beam S1 is reflected and refracted again, whereby the reflected light beam S3 and the refracted light beam S4 (not shown in the figure) are generated. The reflected light beam S3 is reflected and refracted again at another interface, whereby the reflected light beam S5 and the refracted light beam S6 are generated, etc. Since the independent light traps 10 on the surface of the photovoltaic glass 1 Because of their unique structure, the majority of light rays are refracted several times, significantly reducing the amount of light rays reflected back into the atmosphere.

When in the present invention, as in 2 2, the first reflection and refraction occur, about 96% of the incident light rays are refracted at the oblique surface of a structure of independent light traps, while about 4% of the light rays are reflected at the oblique surface. The approximately 4% of the light rays that have been reflected are again reflected and refracted at the adjacent oblique surface of the structure of independent light traps. After repeated reflection and refraction, approximately 3.64% of the approximately 4% of the light rays (ie, 4% × 96% = 3.64%) are trapped while only 0.16% of the light rays are thrown back into the atmosphere.

In order to further produce the patterns of the independent light trap structures, the present inventor has developed a corresponding special device and a special cutter which can easily machine the impeller. As for rolling a roll using the impeller, this is a conventional technique. The inventor has often experimented and finally realized the stamping of conical patterns of 0.15 mm using a roller with a diameter of 300 mm.

Then, the new photovoltaic glass can be manufactured with independent light traps by replacing the roller in the existing photovoltaic production line with the roller according to the present invention.

The manufacturing process of the photovoltaic glass having structures of independent light traps according to the present invention will be briefly described below.

The inventor of the present application uses the aforementioned special equipment and the special cutter to machine an impeller according to the structures of independent light traps. Then the impeller is used to unroll the roller. Finally, the roller is mounted on a trowel to emboss transparent panels such as glass, PMMA, PET, etc.

As for the technique, the conventional roller is manufactured by an etching method, so that the manufacturing process is complicated and costly. The above-mentioned method used in the present invention can reduce costs and is also simple and reliable.

Based on the descriptions of the previous embodiment, those skilled in the art will recognize that various changes and substitutions may be made to the specific embodiment of the present invention without departing from the spirit and scope of the present invention. These changes and substitutions are within the scope defined by the claims of the present invention.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• CN 1157929 A [0008]
• CN 102623578 A [0008]

Cited non-patent literature

• Application of a Light Trap in a Crystalline Silicon Solar Cell (Development of Laser and Photoelectronics, Vol. 41, Number 5, 2004, pages 56-58 and 44) [0008]

Claims (8)

Photovoltaic glass for a solar cell, characterized in that the photovoltaic glass has on its surface independent annular structures, ie independent light traps, wherein an outer diameter of the ring is in the range of 0.1 5 mm, and an included angle between the inner ring and the outer ring is less than or equal to 90 °, so that reflection and refraction of light rays occur several times within an independent annular structure. The photovoltaic glass according to claim 1, characterized in that smaller light traps are provided in voids of the independent light traps for improving the light transmittance. The photovoltaic glass according to claim 2, characterized in that the smaller light traps have the shape of a concave pointed cone. The photovoltaic glass according to any one of claims 1-3, characterized in that the independent light traps are arranged close to each other in the form of a honeycomb structure. The photovoltaic glass according to any one of claims 1-3, characterized in that the independent light traps are arranged in the form of a square. A solar cell with photovoltaic glass according to any one of claims 1-5, which serves as a housing part and for protection. A device for producing patterns on a photovoltaic glass, characterized in that each of the patterns has an independent annular structure, ie a structure of independent light traps, wherein an outer diameter of the ring is in the range of 0.1 ~ 5 mm and an included angle between the inner ring and the outer ring is less than or equal to 90 °. A method of producing photovoltaic glass according to any one of claims 1-5, characterized in that it comprises the steps of: processing an impeller with combined structures of independent light traps using the means for processing according to claim 7; Rolling a roller using the impeller and mounting the roller in a trowel; Embossing the photovoltaic glass using the trowel.

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