RU2109229C1 - Method for manufacture of selective surface structure on products adapted for efficient absorption of solar radiation - Google Patents

Abstract

FIELD: manufacture of solar energy converters. SUBSTANCE: method involves creating microprojections disposed in close relation one with respect to another and consisting of smaller projections, with height of microprojections being up to 5 microns and cross sizes within the range of 1-1.5 microns. Microprojections are created on metal surface by heating and ionic bombardment combined with deposition by, for instance, cathodic spraying of atoms of one or two metals different from mentioned metal. Product may be manufactured from any metal or alloy. Absorption coefficient of layer reached 95%, natural radiation reduced to 2-15%. Optical characteristics of absorbing layer did not change at angles of 0-60 deg from normal. Absorbing layer deposited on copper surface did not break during thermal cycling by vacuum heating from room temperature to temperature of 100 C. EFFECT: increased radiant-heat energy conversion coefficient, wider range of conversion temperature limits and metals used in the process and employment of clean technologies. 5 cl, 2 dwg

Description

 The invention relates to a technology for converting solar energy into thermal energy and can be used in the manufacture of solar thermal converters.

A known method of manufacturing a selective absorbing film for a thermal solar collector US N 4777936, according to which on the surface of the product is applied a film that selectively absorbs solar radiation. The first, lower layer of the film is made of nickel directly deposited on the surface of the product. The second layer is made of cobalt, and the third layer is made of cobalt oxide. The selective absorption coefficient of the film is 0.91-0.96, and the emissivity 0.06-0.10 at a temperature less than 400 ^o C.

 To implement this method, certain specific materials are required, both for the manufacture of the coating and for the manufacture of the substrate, in order to avoid exfoliation of the film due to the difference in the coefficients of thermal expansion. This limits the scope of the method. In addition, it cannot be used at high temperatures. First, there will be diffusion processes leading to the mixing of layers and the deterioration of their selective optical properties. Secondly, the difference in the thermal expansion coefficients of the oxide and metal layers of the film will lead to delamination of the film with increasing temperature and, as a result, to the loss of working capacity of the film. In addition, an increase in temperature will cause the decomposition of cobalt oxide and the film to lose its selective properties.

 A known method of producing a coating for the selective absorption of radiant energy US N 4442829, which consists in the fact that on the surface of the aluminum product create a film of aluminum oxide. Metallic particles are introduced into the micropores of the oxide film by an electrochemical method. The resulting coating has a high absorption coefficient of radiant energy in the visible and near infrared parts of the spectrum.

 However, such a coating can only be created on aluminum and, due to the low melting point of aluminum, cannot be used at high temperatures. Its production is carried out by environmentally unsafe electrochemical methods. The coating cracks when heated due to the large difference in the coefficients of thermal expansion of aluminum and aluminum oxide. The destruction of the coating will also occur due to the expansion of metal particles in the pores of the coating during heating. Finally, the area of the metal-filled pores will be significantly smaller than the surface of the coating as a whole. This will limit the absorbed part of the incident solar radiation and make it difficult to transfer heat from the metal particles heated by the sun to the product. In addition, aluminum quickly corrodes when in contact with water, so its use in solar plants for heating water is impractical.

Closest to the invention is a method of manufacturing a transducer of radiant energy to thermal SU N 741811, according to which a plate of metal (stainless steel or tungsten) is heated to 450-550 ^o C and create a relief surface by supplying it with hydrogen and tungsten hexafluoride. As a result of chemical interaction between them, tungsten is deposited on the wafer in the form of single-crystal protrusions up to 5 microns high. The structure of such protrusions effectively absorbs and converts solar rays incident on the surface into heat. At an angle of 15-30 ^o to the normal to the surface, the crystalline structure looks completely black and has a high absorption capacity. At large angles, the surface looks bright, and its absorption is greatly reduced.

 For different frequencies of the converted radiation, which must be absorbed by the tungsten protrusions, it is necessary, according to this method, to change the ratio between the height and thickness of the protrusions. This was achieved by etching the converter in a solution of hydrogen peroxide and ammonium hydroxide.

 This method cannot be considered environmentally friendly, since materials such as tungsten hexafluoride are used, and the method of electrochemical etching is used to expand the scope of the method.

 In addition, for the implementation of this method uses non-technological material - tungsten, which is almost impossible to machine and use in large quantities to build solar thermal power plants. If the elements of the solar thermal absorber absorbing solar radiation are made of stainless steel coated with tungsten protrusions, then it will be impossible to heat such elements with solar radiation to high temperatures. Due to the difference in linear expansion coefficients, the tungsten protrusions will separate from stainless steel when heated, and the coating will break.

Another disadvantage of this converter, limiting its effectiveness, is the single-crystal structure of tungsten microprotrusions. The side faces of single crystals up to 5 microns in size reflect light well. As a result, the range of angles of incidence of the radiation, in which the converter has good selective properties, is extremely narrow (0-30 ^o ).

 The technical result of the claimed invention is to increase the efficiency of conversion of radiant energy into thermal energy, to increase the temperature limit of conversion, expand the range of metals used and use environmentally friendly technology.

 To obtain this technical result by the proposed method, a metal product is heated and an absorbent structure consisting of closely spaced microprotrusions is formed on its surface. Such a structure is created by cleaning the surface with ion or electron irradiation and subsequent bombardment by energy atomic particles of the surface of an article containing atoms of two or more elements.

 The result is achieved if the surface is bombarded by atoms and ions sprayed from separately located targets. To better control the relief development process, irradiation of the surface with an atomized stream of atoms and ions is supplemented by bombardment with energy ions of an inert gas. To accelerate the creation of microprotrusions in the case of using inert gas ions, the flow of atomized particles to the surface is replaced or supplemented by the flow of vaporized atoms.

 To simplify the technology of creating a relief, irradiating the surface of the product with streams of atomized and vaporized atoms can be eliminated and microprotrusions can be grown on the surface of the corresponding alloy by irradiating it with inert gas ions.

 In FIG. 1 is a diagram of a selective absorbent structure consisting of microprotrusions 1 created on the surface of an article 2; in FIG. 2 - distribution of atoms of the product 3 and foreign atoms 4, delivered to the surface during processing.

 An example implementation of the method. Metal, such as copper, products were placed in plasma. Plasma ions bombarded the surface of product 1 and cleaned it of oxides and contaminants. After cleaning the surface for 30 minutes, the heating of the product did not stop, and a stream of atomized copper and iron atoms from separate sources was directed to the product. The time to create an absorbent structure on the surface was 2-3 hours.

 The absorbing layer was a structure consisting of microprotrusions with a height of up to 5 μm and transverse dimensions of 1-3 μm. Microprotrusions had a finely divided structure; their surface was not smooth, but consisted of even smaller protrusions.

 The absorption coefficient of the layer reached 90-95%. Own radiation decreased to 7-15%.

 In order to make it easier to control the process of microprotrusion growth and to form a relief with optimal parameters, bombardment of the product surface with a stream of atomized atoms was supplemented by bombardment with argon ions with an energy of 200-300 eV. In this case, the flow of atomized copper atoms to the surface of the product could be reduced or eliminated altogether.

 An absorbing layer with approximately the same parameters, but for a time 2-3 times less was obtained if the stream of atomized copper atoms was replaced by a stream of copper atoms vaporized from a special source.

 When choosing a metal alloy as a product material, for example, a copper-nickel alloy (Cu-Ni 20 at.%) Or a copper-iron alloy (Cu-Fe 20 at.%), The absorbing layer was formed by irradiating the heated and cleaned surface only with argon ions .

 Thus, regardless of the manufacturing options, an environmentally friendly processing method is used in all cases.

 Metals or alloys for the manufacture of the workpiece and for participation in the formation of the relief can be selected any with the exception of alkaline and alkaline earth. The implementation of the method is possible, however, it is associated with great technical difficulties if metals and alloys have a low melting point, for example, Wood's alloy, and high vapor pressure at relatively low temperatures, for example zinc.

The absorbing layer, made in the described way, on copper did not collapse during thermal cycling by heating in vacuum from room temperature to a temperature of 700 ^o C. The number of cycles was 1000, the total test duration was 800 hours

 The structure of surface microprotrusions, their average sizes and the distances between them easily vary with temperature and flow parameters of fast corpuscular particles bombarding the surface of the product. The formation of a highly developed relief causes a high absorption capacity. The same protrusions that form the surface topography, due to their size, suppress their own infrared radiation from the product heated by the sun. As a result, most of the radiant energy is converted into heat, that is, the efficiency of the solar thermal converter increases.

This is due to the fact that the surface protrusions have a fine-grained structure and consist of even smaller protrusions, the efficiency of the converter is also increased as a result of the fact that they absorb incident radiation with approximately equal efficiency in a wide range of angles: 0-60 ^o from normal to the surface.

The shape of the microprotrusions does not change upon prolonged heating to temperatures of about 0.7 T _pl , where T _pl is the melting point of the least fusible metal that is part of the surface layer. This makes it possible, with appropriate selection of components, to use an absorbing layer for effective heliothermal conversion in the entire temperature range, where the wavelength of intrinsic thermal radiation differs significantly from the wavelengths of visible light.

 All of the above makes it very promising to use the proposed method in high-temperature solar thermal power plants.

Claims (5)

 1. A method of manufacturing a selective surface structure on products for the effective absorption of solar radiation, which consists in the fact that the metal product is heated and relief is created on its surface by growing microprotrusions on it, characterized in that the surface of the product is cleaned by ion or electron irradiation to form microprotrusions from surface oxides and compounds, and then bombarded with a stream of energetic atomic particles and ensure the presence on the surface of the product during the bombardment atoms of two or more elements.  2. The method according to claim 1, characterized in that the bombardment of the surface of the product with energetic particles and the presence on the surface during the bombardment of atoms of two or more elements is achieved by irradiating the surface with a stream of energetic ions and atoms sprayed from separately located targets.  3. The method according to claim 2, characterized in that, in order to better control the growth of microprotrusions and the formation of a relief with optimal parameters, the bombardment of the surface of the product with a stream of atomized atoms and ions is supplemented by bombardment with energetic inert gas ions.  4. The method according to claim 3, characterized in that in order to accelerate the process of creating microprotrusions, the stream of atomized atoms and ions to the surface is replaced or supplemented by a stream of evaporated atoms.  5. The method according to claim 1, characterized in that the presence of two or more elements on the surface of the atoms ensures that a metal alloy is selected as the material of the product, and inert gas ions are selected as the bombarding energetic atomic particles.

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