EA034296B1 - PHOTOELECTRIC SOLAR ENERGY CONVERSION DEVICE - Google Patents

Abstract

The invention relates to photoelectric devices of solar energy conversion. The photovoltaic solar energy conversion device has buses collecting current carriers created by light, and semiconductor photoelectric converters, which outer photosensitive surfaces are covered with three discrete layers of diamond-like carbon films, which provide 0.5 to 1% reflection coefficients from photosensitive surface area. To ensure mechanical strength, semiconductor photoelectric converters and buses are immersed in a bonding material, such as polyurethane, which is also insulating. Prior to setting of polyurethane, the surfaces of photovoltaic cells and buses are installed so that they are outside the volume of polyurethane. To protect against hail, the device is placed in a rectangular box, which has a flexible coating on the top. The device also has a pyranometer that measures the intensity of sunlight, its zero readings actuating an electric motor to cover the box with flexible coating immediately, at positive readings of the pyranometer, it rolls the coating up to open the device. Efficiency and durability of the device are increased.

Description

The invention relates to light energy, in particular to the field of converting solar light energy into electrical energy, and can be effectively used as a component of a solar power station.

State of the art

A known photovoltaic device-panel that converts solar energy (J.R. Panosyan, A.O. Arakelyan, E.V. Engibaran, S.E. Berberyan. Manufacturing technology of solar photovoltaic panels. Izv. NAS and GIUA, ser.TN, 1998, vol. 51, No. 2, pp. 165-170), consisting of photovoltaic converters and busbars collecting current carriers located on two surfaces of the network.

To increase durability, as well as to protect against hail and other destructive influences, the transducers are glued to the bottom surface of thick and unbreakable glass. To ensure the tightness of the surface of the photovoltaic cells are glued to the glass using a polymer binder, such as ethyl vinyl acetate. Tires placed on the upper surface of the glass are protected by an insulating layer.

A disadvantage of the known device is that coating the surfaces of the transducers with glass and sealing with a polymer binder reduces the efficiency of the semiconductor converters and the durability of the device, since over the years under the influence of ultraviolet rays of the sun the light transmission of the polymer binder film decreases, which, together with the inevitable reflection of the rays from the surface glass leads to a decrease in the total power and efficiency of the device.

Also known is the protective construction of a photovoltaic flat panel for solar energy conversion (USA Patent Application Publication 2010/0229916 A1, Protection System, 2010), in which the photovoltaic device is placed in a box in order to protect against impacts, or a snow layer, or strong sandstorms.

The folding and movable top protective cover of the box has a high impact resistance and, if necessary, is a closing and opening coating in accordance with the reported weather forecasts.

The disadvantage of this design is that meteorological forecasts are probabilistic in nature and may not coincide with climatic changes in the area at the moment, especially in the case of hail, which is purely local and short-term. On the other hand, the reflection of light from glass mounted on the surface of the device and its absorption from the side of the binder polymer reduces the flow of sunlight incident on the photovoltaic cells and reduces the power of the device in favorable solar time when the movable protective topcoat is rolled up to the gear motor.

In the absence of glass and a sealing binder polymer on the surface of the device, the surfaces of the solar converters oxidize very quickly and a drop in power and a significant decrease in efficiency.

A solar photovoltaic conversion device coated with diamond-like carbon films is known (RU 2244983 C1, H01L 21/205, 2005, prototype), which consists of illuminated semiconductor converters and buses collecting current carriers from their surfaces.

The photosensitive surfaces of the semiconductor converters are coated with two discrete protective layers of diamond-like carbon films and placed in a bonding medium, while the refractive indices and layer thicknesses are selected so as to provide a reflection coefficient from the surfaces of the converters over their entire photosensitive region no more than 0.02-0.05 .

Buses collecting current carriers on the opposite side are protected by an insulating layer.

The disadvantage of this device is that the reflection coefficients from two layers of diamond-like carbon films throughout the photosensitive region do not have small values, and also that the transducers are not protected from hail shocks, since silicon semiconductor wafers break from these shocks. For this reason, their surfaces are protected by glass, due to which, as well as due to the necessary use of a bonding adhesive polymer, the overall value of the efficiency of the device is reduced by 6%.

Disclosure of Invention

The objective of the invention is to increase the efficiency and durability of the device.

The essence of the invention lies in the fact that in the photovoltaic device for converting solar energy, which is located in the box and has semiconductor converters located in the bonding layer with its buses and a protection element of the converters, the outer photosensitive surfaces of which are coated with two discrete layers of diamond-like carbon films, in accordance with the invention the outer photosensitive surfaces of the transducers are coated with an additional third diamond-like carbon layer, the layers are selected so that the converter provides a surface reflectance 0.005-0.01.

The protective element of the transducers is made in the form of a flexible coating with the possibility of winding

- 1 034296 axis on the axis of the electric motor mounted on one of the vertical faces of the box and controlled by the light intensity.

The invention also consists in the fact that the bonding layer is made of durable polyurethane.

The essence of the invention also lies in the fact that the bonding layer is made of durable siloxane rubber.

The invention also lies in the fact that the bonding layer is made of tile adhesive.

The invention also lies in the fact that the flexible coating is a tarp.

The invention also lies in the fact that the flexible coating is lavsan.

A brief description of the graphic materials

The invention is illustrated by drawings, where in FIG. 1 shows sections of layers created on the photosensitive surface of a semiconductor solar energy converter;

in FIG. 2 is a schematic half-open view of an opening and closing surface of a photosensitive photoelectric device;

in FIG. 3 shows a circuit diagram of an electric motor control.

The implementation of the invention

A photovoltaic solar energy conversion device consists of semiconductor converters (1), for example silicon-based, with a potential n-junction, the outer photosensitive surfaces of which are covered by two diamond-like carbon discrete layers and on which there are parallel current-collecting busbars (2), which are electrically interconnected by a crossing tire (3). To increase the efficiency, the external photosensitive surfaces (4, 5) of the transducers are covered with an additional third diamond-like carbon discrete layer (6), while for three layers the refractive indices n and thickness d have, for example, the corresponding values of n ₁ = 2.4 and d ₁ = 50 nm; n ₂ = 1.8 and d ₂ = 30 nm; n ₃ = 1.5 and d ₃ = 98 nm and are selected in such a way that from the surface of silicon converters (1) from their entire photosensitivity range, from 0.5 to 1% low reflection coefficients are provided, which increases the efficiency of the device by 6%. For such an increase in efficiency, a reflective protective glass and a bonding polymer layer are removed from the device.

Semiconductor photoelectric converters of the device (7) are protected from hail and other damaging effects, and the protection element of the converters is made in the form of a flexible, non-reflecting light coating (8) with the possibility of winding on the axis of the electric motor (9), mounted on one of the vertical sides of the box and controlled the intensity of sunlight.

On the opposite side of the motor carrier, brakes are attached to the motor, for example magnetic contacts (10), and from the sides there are screws (11) connecting the device (7) to the box.

The device also has an electric control circuit for the operation of the gear motor, consisting of, for example, a pyranometer (12) that measures the flow of the sun's rays, a microcontroller (13) such as ATMEGA-8, and the 12th gear motor (14).

At a zero reading of the pyranometer (12), which measures the intensity of the sun's rays, which occurs in the case of clusters of hail-bearing clouds, the electric motor (14) under the control of the microcontroller (13) immediately protects the device with a flexible flexible coating (8), and with positive values of the pyranometer readings ( 12) an electric motor (14) wraps a flexible coating on the axis and opens a stream of sunlight on the photosensitive surface of the device.

On the side that does not have photosensitivity, the converters and buses connecting them to each other are immersed in a mechanically strong bonding layer, which is also insulating. Photosensitive surfaces protected by diamond-like carbon discrete three layers (4-6) are installed so as not to become covered by a bonding layer.

A mechanically strong and insulating bonding layer can be made in three versions.

In accordance with the first embodiment, the mechanically strong and insulating binder layer is polyurethane, the preliminary composition of which includes substances that create a viscous state, which, after a short time, complete the polymerization process, and the polyurethane becomes a solid, solid state. Prior to hardening, a chain of busbar-connected transducers is placed in polyurethane so that the surfaces of transducers protected by diamond-like carbon discrete three layers (4-6) are outside the polyurethane volume.

The thickness of the hardened bonding strong layer of polyurethane is about 1 cm, it can be enclosed in a plastic frame, the expansion coefficient of which does not differ from polyurethane.

In the second embodiment, the mechanically strong and bonding layer is siloxane rubber, which in its physical properties differs little from polyurethane.

According to the third embodiment, the mechanically strong and insulating bonding layer is tile adhesive, the curing time of which is longer and the elasticity is less.

The flexible coating (8) of the box protecting the device from hail can be implemented in two versions.

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In the first embodiment, the protective flexible coating is made of durable fabrics based on natural linen threads, such as tarpaulins.

In the second embodiment, the protective flexible coating is made of durable fabrics based on artificial threads, such as lavsan.

The device has great potential for use in both normal and extreme conditions.

Claims (5)

CLAIM 1. The photovoltaic solar energy conversion device (7), which is located in the box, has a protection element (8) of the converters (1) and semiconductor converters located in the bonding layer with their own buses (2, 3), the outer photosensitive surfaces of which are coated with two discrete layers (4, 5) diamond-like carbon films, characterized in that the outer photosensitive surfaces of the transducers are coated with an additional third diamond-like carbon layer (6), while the refractive indices and thicknesses The diamond-like layers are selected so that the reflection coefficient 0.005-0.01 is provided from the surfaces of the transducers (1), and the protection element (8) of the transducers is made in the form of a flexible coating with the possibility of winding on the axis of the electric motor (9), mounted on one of the vertical edges of the box and controlled by light intensity. 2. The device according to claim 1, characterized in that the bonding layer is made of durable polyurethane. 3. The device according to claim 1, characterized in that the bonding layer is made of durable siloxane rubber. 4. The device according to claim 1, characterized in that the bonding layer is made of tile adhesive. 5. The device according to claim 1, characterized in that the flexible coating (8) is a tarp.