RU2552597C1 - Flexible solar element - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: solar element includes cathode and anode, each having external and internal flexible layers, at that these cathode and anode are located such that their internal layers are opposite each other with clearance filled by the electrolyte, at that the external layer of the cathode is made out of transparent polymer material, and its internal layer is made out of carbon nanotubes, the external layer of the anode is made out of conducting material, and its internal layer is made out of nanoparticles of solid state material, dye-sensitised.

EFFECT: simplified process of solar elements manufacturing, reduced price, and increased flexibility.

11 cl, 1 dwg

Description

The invention relates to solar cells (SE) and can be used in alternative energy to convert solar energy into electrical energy.

Currently, silicon-based solar cells are the most common. They have a relatively high efficiency, but their cost is high.

So-called “Gretzel cells" - SCs sensitized with dye can be considered as alternative to silicon SCs. Structurally, the Gretzel cell consists of a plate of electrically conductive glass, on which a layer of titanium dioxide, which is a semiconductor, is deposited. On top of the titanium dioxide layer is a layer of a special organic dye, and current collectors are connected to the glass. The peculiarity of the dye is that under the influence of sunlight it emits electrons. Through a semiconductor layer, electrons can only move in one direction — toward the current collector. Thus, when the threshold value of the number of emitted electrons is reached, an electric current is generated, which flows from the upper layer of the cell to the lower. The design involves the use of transparent conductive electrodes, which are used as glass plates coated with a layer of indium oxide with tin. The use of such plates does not allow the SC to be flexible, which limits its use.

A known design of solar cells with a cathode based on indium oxide with tin [Seigo Ito et al. "High-efficiency (7.2%) flexible dye-sensitized solar cells with Ti-metal substrate for nanocrystalline-TiO ₂ photoanode" Http: // pubs .rsc.org / en / content / articlelanding / 2006 / cc / b608279c #! divAbstract]. A titanium foil is used as the anode, and the cathode includes a flexible substrate of polyethylene naphthalate, on which a layer of indium oxide with tin is coated, coated with a layer of platinum. The electrolyte contains 1-butyl-3-methylimidazolium iodide, guanidinium thiocyanate, 4-tert-butylpyridine in a mixture with acetonitrile and valeronitrile. The electrolyte is located between the cathode and the anode, and the SC is a sandwich cell.

The described SC has disadvantages due to the use of transparent electrodes based on indium oxide with tin, which include their fragility and lack of flexibility, which leads to cracking of the coating and does not allow to organize in-line production of SC on a flexible basis, as well as the high cost of indium and platinum, which significantly increases the cost of solar cells.

The closest analogue of the proposed SC is a dye-sensitized flexible SC containing a cathode, anode and an electrolyte located between the cathode and the anode [US Application No.20150151101, IPC H01L 31/0216, H01L 31/18]. The cathode is made in the form of a flexible polymer substrate with a layer of carbon nanotubes (CNTs) deposited on it and a photosensitive layer of semiconductor - titanium dioxide nanoparticles sensitized by a light-absorbing dye. The anode is made in the form of a flexible polymer substrate, on which a conductive layer of deposited metals, such as platinum, palladium, silver or gold, is applied. As the electrolyte, the redox pair iodide / triiodide is used.

The electrolyte fills the gap between the cathode and the anode and ensures the flow of electric current between them. The carbon nanotube layer is made sufficiently thin and transparent, so that sunlight passes through it and enters the dye sensitized semiconductor layer. The dye molecules, absorbing sunlight, go into an excited state and give an electron to a semiconductor - titanium dioxide. Through a layer consisting of particles of titanium dioxide, electrons reach an electrode having a conductive layer of carbon nanotubes, and then through an external circuit fall on the anode. At the anode, electrons are transferred to iodine molecules located in the electrolyte, with the formation of iodine ions. Iodine ions in turn transfer the missing electrons to the dye molecules.

The prototype has the following disadvantages.

Firstly, it is difficult to manufacture. So, in the manufacture of the cathode, a layer of titanium dioxide nanoparticles sensitized with a dye is preformed on a metal foil, the formed layer is dried, baked at a temperature of about 500 ° C. The baked layer is removed from the foil and transferred onto a polymer substrate coated with CNTs. With this manufacturing method, it is difficult to ensure reliable electrical contact of the titanium dioxide layer with the substrate and the CNT layer deposited on it, which is necessary for efficient electron transfer.

Secondly, it has a high cost due to the use of precious metals in the conductive layer of the anode.

The invention solves the problem of simplifying the manufacturing technology of solar cells, reducing its cost and increasing flexibility.

The problem is solved by the fact that the proposed SC, including a cathode and anode, each of which has an external and internal flexible layers, and the said cathode and anode are arranged so that their inner layers are opposite each other with a gap filled with an electrolyte, while the external the cathode layer is made of a translucent polymer material, and its inner layer is made of carbon nanotubes, the outer layer of the anode is made of electrically conductive material, and its inner layer is made of semiconductor nanoparticles dye sensitized egg material.

It is advisable to use a metal foil as a layer of electrically conductive material. The use of metal foil as the basis for the photosensitive layer of the semiconductor makes it possible to bake the said layer at high temperature in the manufacture of solar cells, which ensures good electrical contact between the particles of the semiconductor and, as a result, its high electrical conductivity.

The foil can be made of metal selected from the series: titanium, or iron, or tungsten, or molybdenum, etc.

Translucent polymer material can be selected from the range: polyethylene terephthalate, or polyethylene naphthalate, or polyimide, or polymeric hydrocarbon, or cellulose, or polycarbonate, or polystyrene.

The semiconductor material may be selected from the series: titanium dioxide, or zinc oxide, or niobium pentoxide, or tungsten trioxide, or tin dioxide, or magnesium oxide.

A colorant based on a ruthenium salt, for example N3 or N719, can be used in SC.

A porphyrin complex, for example, a component of hemoglobin or chlorophyll, or perovskite, or coumarin, merocyanine, or other organic dyes specially developed for use in SE, can be used as a dye.

The electrolyte may contain a redox pair iodide / triiodide (I ^- / I ^3- ).

The named redox iodide / triiodide pair can be dissolved in acetonitrile or in a liquid or solid polymer, for example a polyethylene oxide-based polymer.

The layer of nanoparticles of the dye sensitized semiconductor material should be made in such a way that its neighboring nanoparticles or most of them are in contact with each other, providing electron conductivity.

SE can be placed in a sealed transparent case, for example, made of a polymer film.

Figure 1 shows the design of solar cells, where: 1 is an electrolyte, 2 is a cathode, 3 is an anode, 4 is a layer of translucent polymer material, 5 is a layer of CNTs, 6 is a layer of conductive material, 7 is a layer of nanoparticles of semiconductor material sensitized with dye.

Electrolyte 1 is located in the gap between the electrodes: cathode 2 and anode 3. The electrolyte is, for example, the redox pair iodide / triiodide (I ^- / I ^3- ) in a solution of acetonitrile or in a liquid or solid polymer, for example, a polymer on based on polyethylene oxide.

The translucent electrode SE - cathode 2 consists of a layer of flexible polymer translucent material 4 and a conductive layer of CNT 5, also translucent. The layer of polymer material may be polyethylene terephthalate, or polyethylene naphthalate, or polyimide, or polymer hydrocarbon, or cellulose, or polycarbonate, or polystyrene, or other suitable material.

The lightproof electrode SE - anode 3 consists of a layer of conductive material 6, for example a metal foil, and a layer of nanoparticles of a semiconductor material sensitized with dye 7. The foil can be made of titanium, or steel, or tungsten, or molybdenum. The semiconductor material may be: titanium dioxide (TiO ₂ ), or zinc oxide (ZnO), or niobium pentoxide (Nb ₂ O ₅ ), or tungsten trioxide (WO ₃ ), or tin dioxide (SnO ₂ ), or magnesium oxide (MgO ), or other suitable material. As a colorant, a colorant based on a ruthenium salt, for example N3 or N719, can be used. Or, specially designed organic dyes can be used, for example, hemoglobin or chlorophyll, or perovskite, or coumarin, merocyanine, and others.

The layer of nanoparticles of the semiconductor material should provide a high level of conductivity for electrons. To make this layer, a paste prepared from nanoparticles of semiconductor and ethyl alcohol is applied to a conductive material, for example, a metal foil, after which it is heated to the appropriate temperature at which the alcohol evaporates and the nanoparticles sinter among themselves. For example, titanium dioxide nanoparticles are sintered at a temperature of 400 ° C.

The electrolyte is placed between a layer of CNT 5 of the cathode and a layer of nanoparticles of a semiconductor material sensitized by dye 7 of the anode.

The proposed SC works as follows (on the example of a SC containing an iodide / triiodide redox pair as an electrolyte, a titanium foil as a layer of conductive material, a polyethylene terephthalate film as a layer of translucent polymer material, and titanium dioxide as a semiconductor material, as a dye, a dye based on the ruthenium salt N 719 Di-tetrabutylarmmonium cis-bis (isothiocyanato) bis (2,2′-bipyridyl-4,4′-dicarboxylato) ruthenium- (II)).

The light emitted by the sun passes through the translucent cathode 2 and electrolyte 1 to layer 7 of the opaque anode 3. Layer 7 consists of nanoparticles of a semiconductor material - titanium dioxide and dye molecules based on ruthenium salt. The dye molecules absorb the photons of the light incident on them, at the same time go into an excited state and emit electrons. Electrons emitted by dye molecules are injected into the conduction band of the semiconductor material TiO ₂ . In this case, the dye molecule is oxidized, forming a positively charged ion, and an electric current flows from top to bottom to the titanium foil 6. Positively charged dye ions, in turn, compensate for the lack of an electron by oxidizing iodide in the electrolyte to triiodide. On the layer of carbon nanotubes 5, the triiodide is reduced to iodide. Then, iodide passes through the electrolyte to a layer of nanoparticles of a semiconductor material sensitized by a dye, where it reduces oxidized dye molecules.

As a result of the described processes, a potential difference arises between the cathode and the anode, namely, between the layer of carbon nanotubes of the cathode and the metal foil of the anode, due to which an electric current occurs when the external circuit is closed.

SE can be placed in a translucent sealed case made, for example, of a polymer film sealed at the edges. Such a case protects against external influences and the service life of solar cells can be increased.

The proposed flexible solar cell is relatively cheap, since it does not include expensive materials, is technologically advanced to manufacture, and is not prone to bending damage.

Claims (11)

1. A solar cell comprising a cathode and anode, each of which has an outer and inner flexible layer, said cathode and anode being arranged so that their inner layers are opposite each other with a gap filled with electrolyte, and the outer layer of the cathode is made of translucent polymer material, characterized in that the inner layer of the cathode is made of carbon nanotubes, while the outer layer of the anode is made of electrically conductive material, and its inner layer is made of nanoparticles of semiconductor m dye sensitized material. 2. The solar cell according to claim 1, characterized in that the polymeric material is selected from the series: polyethylene terephthalate, or polyethylene naphthalate, or polyimide, or polymeric hydrocarbon, or cellulose, or polycarbonate, or polystyrene. 3. The solar cell according to claim 1, characterized in that the layer of electrically conductive material is a metal foil. 4. The solar cell according to claim 1, characterized in that the semiconductor material is selected from the series: titanium dioxide, or zinc oxide, or niobium pentoxide, or tungsten trioxide, or tin dioxide, or magnesium oxide. 5. The solar cell according to claim 3, characterized in that the metal foil is made of metal selected from the series: titanium, or steel, or tungsten, or molybdenum. 6. The solar cell according to claim 1, characterized in that a colorant based on a ruthenium salt, for example N3 or N719, is used. 7. The solar cell according to claim 1, characterized in that an organic dye is used, for example coumarin or merocyanine, or a porphyrin complex, which is part of hemoglobin or chlorophyll, or perovskite. 8. The solar cell according to claim 1, characterized in that the electrolyte contains a redox pair iodide / triiodide, 9. The solar cell according to claim 8, characterized in that the redox pair iodide / triiodide is dissolved in acetonitrile. 10. The solar cell according to claim 8, characterized in that the redox pair iodide / triiodide is dissolved in a liquid or solid polymer, for example a polymer based on polyethylene oxide. 11. The solar cell according to claim 1, characterized in that the layer of nanoparticles of the semiconductor material sensitized by the dye is made in such a way that its neighboring nanoparticles are in contact with each other.

Images