NL8000986A - PAINT FOR APPLICATION OF SPECTRAL-SELECTIVE COATINGS AND METHOD OF PREPARING THE SAME, SOLAR HEAT ABSORBING DEVICE AND SOLAR COLLECTOR CONTAINING SUCH A DEVICE. - Google Patents

Description

1; yr * ^ ^ ^ i N.Q. 28664 -1-

Paint for applying spectral selective coatings and method of preparation thereof, solar heat absorbing member and solar collector containing such member.

The invention relates to a paint for applying spectral-selective coatings, to a method of preparing such a paint, to a solar heat-absorbing element containing such a spectral-selective coating, and to a solar collector contains such a body.

From the book of F. Daniels "Direct use of the sun's energy",

Yale University Press, New Haven, London, 1964, chapter 12, biz. 209-223, it is known to produce solar heat absorbing members by applying a layer of a black semiconductor with a thickness of 0.1-lyum on a plate with reflective metal surface. This black semiconductor layer absorbs sunlight (wavelength 0.3-2.5 yium) almost completely, but does not absorb or emit heat radiation (wavelength> 2.5 yum). The reflective metal layer also does not emit heat radiation. As a result, the temperature of the plate becomes higher and higher and it is suitable to be incorporated in a solar collector.

According to an article by Henry Y.B. Mar et al. In Thin Solid Films 39 (1976) pp. 95-103, black coatings can be applied to metal surfaces by electroplating or in the form of a paint containing the desired pigment together with a polymeric binder in an organic solvent, which solvent is removed by drying and optionally stoving after the application of the paint, so that a layer of black pigment in binder remains on the metal. The electrolytically applied layers provide the best optical efficiency, but applying pigments in the form of a paint is much cheaper.

According to US patent 4 011 190, small particles of reflective metal are coated with a layer of a selective black material, after which the coated particles are processed into a paint by means of a liquid carrier and an organic polymer, which are applied to any material, such as metal, wood or masonry. The particles of reflective metal used are, for example, flakes, powder or dust of the metal. For example, the reflective metal particles are coated with the layer of black selective material by electroless chemical deposition of an 80 0 0 9 86%. -2- of another metal and oxidation or sulfidation of the metal layer thus deposited. "

According to US patent 4-082 4-13, a selective radiation absorbing member is manufactured by applying a layer of a mixture of metal particles and a dielectric material on a substrate 5 of metal or glass, the concentration of the metal in this layer from one interface to another gradually varies from 0 to 100%. The dielectric material is generally transparent to radiation, although it can also absorb some radiation, while the metal absorbs and reflects the radiation. The heat built up in the coated substrate is dissipated by means of a heat transfer agent, which flows through a tube which is in thermal contact with the layer or with the substrate on which the layer is applied.

It has been found that a very inexpensive and easy to handle paint for applying spectral selective coatings consists of spectral selective pigment, reflective metal particles and binder and optionally other components, whether or not in a liquid carrier. Thus, this paint does not contain reflective metal particles coated with a black pigment layer, as described in U.S. Patent 4,011,190. This has the advantage of coating metal particles separately with a very thin layer of spectrally selective material. which is the most technologically difficult step in the preparation of the paint has become superfluous. The pigment, metal particles and binders used in the paints according to the invention can be conventional commercial products which can be easily processed into a paint. Thus, the preparation and application of such paint is also possible in areas where the application of advanced technologies is not possible.

The results obtained with the paint according to the invention are approximately the same as with the paints according to U.S. Patent 4,011,190. For example, paints have been prepared in which the pigment volume concentration of metal chips 20% and of black pigment 10% and 35% respectively 20%, this concentration being based on the total non-volatile content of the paint. Substrates coated with paints thus prepared had an sunlight absorption coefficient (pi) of about 0.84 to 0.90 and an emission δ 800 0 9 86-3 coefficient (0 between 0.35 and 0, 50.

In the paint according to the invention, spectral-selective pigments are usually used with high absorption pigments for solar radiation. These include, among others, conventional black pigments, such as copper oxide-chromium oxide, iron oxide-manganese oxide-copper oxide, molybdenum oxide and lead oxide, or also the sulfides of the metals present in these oxides, in particular lead sulfide. Carbon blacks and organic dyes and pigments are also suitable, while mixtures of one or more of these materials can also be used.

As raw material for the reflective metal particles, for example, aluminum, nickel, copper and zinc or alloys of these metals, in particular copper and zinc, or also stainless steel are used.

The metal particles are often used in the form of flakes. Particularly flakes of aluminum, copper or copper-zinc alloys are preferred, because they yield excellent results and, moreover, are low cost and are available as a commercial product. When drying and / or stoving the paint, the flakes are preferably oriented parallel to the surface of the substrate.

The binders used in the paints according to the invention can be conventional binders for this purpose. As examples may be mentioned polyethylene, polypropylene, ethylene-propylene copolymers, ethylene-propylene-diene terpolymers, silicone resins, such as methylphenylpolysiloxane polymer, alkyd resins, polyester resins, styrene-butadiene copolymers, polyacrylates, vinyl resins, chlorinated resins, phenoxy resins, phenol resin, elastomeric hydrofluorocarbons, siloxane-modified alkyd resins or polyester resins, inorganic silicates and organic silicic acid esters.

Silicone resins, siloxane-modified alkyd resins and polyester resins and fluorocarbon elastomers have the advantage of being resistant to high temperatures and adverse weather conditions.

Other components may also be present in the paint according to the invention, such as auxiliary agents, for example dispersants, wetting agents, thickening agents, siccatives, antifouling agents and flow agents.

When a liquid carrier is used in the paint, it consists, for example, of an organic solvent or water. Suitable organic solvents are, for example, aliphatic, cycloaliphatic and aromatic hydrocarbons and chlorinated hydrocarbons, alcohols, ketones and esters. Water is used, for example, as a liquid carrier in the case of using aqueous binder dispersions These binder dispersions usually contain 5 emulsifying or wetting agents and other auxiliary agents.

When a binder with a sufficiently low viscosity is used, the paint need not contain any or little liquid carrier.

The concentration of the spectral selective pigment and the reflective metal particles in the paint according to the invention is expressed in the pigment volume concentration (pvk) used in the paint industry, based on the total content of non-volatile components.

The pvk of the spectral selective pigment is generally 1-60%, especially 5-30%, and preferably 20%. The pvk of the reflective metal particles is generally 5-95%, in particular 10-80% and preferably 20-4-0%.

The preparation of a paint according to the invention can take place in the usual manner. For example, the spectral selective pigment is dispersed in a portion of the binder or of the binder solution such that the largest particles are less than, for example, 10 µm. Then, the remaining amount of binder or binder solution is added to the dispersion obtained with stirring and then the reflective metal particles are added as such or in the form of a paste. In some cases, the metal particles or paste are pre-wetted with an amount of solvent to facilitate stirring.

The paint according to the invention is applied to a substrate in the usual manner and then dried and, if desired, enamelled. Metal, wood, masonry, plastic or other material can be used as the substrate for the paint. If desired, a layer is applied to the substrate, in particular if it is a substrate of metal or plastic, which effects protection against corrosion and / or better adhesion of the spectrally selective paint layer.

The thickness of the applied paint layer can vary within wide limits and is, for example, after drying 5-100 µm and in particular 20-50 µm,

Substrates with spectral selective coatings based on the paint according to the invention are excellent for installation in 800 0 9 86 --- Vos -5- all kinds of solar collectors.

Tests with the coated substrates have shown that coating layers when heated at 200 ° C for 1A days have excellent durability, especially when using silicone resins and siloxane-modified alkyd resins and polyester resins. It was also found that no degradation in the durability of the coating layer could be observed after testing in an atlas weatherometer after 10 cycles. These tests were performed without a glass plate which blocks ultraviolet light, which glass plate is generally present in solar collectors in which the coated substrates are incorporated.

The following examples further illustrate the invention.

The formulations described in these examples were formulated in the manner described above.

Example I.

A paint of the following composition was prepared: component wt% soy alkyd resin 20.09 pigment Ferro Black F 6331a ^ 12.90

Cu / Zn flakes 30.28 20 gasoline 34.55 acetone 0.22

Bentone 34 b) 0.37

Pb naphthenate, 32¾ Pb 0.29

Co-naphthenate, 10% Co 0.12 Ca-naphthenate, 4% Ca 1.18 100.00.

The pvk of the pigment was 10%, of the Cu / Zn flakes 20%.

The paint was applied to an aluminum plate using a straightening knife. The thickness of the layer after drying was 30-40 µm. After drying for 30 days, o6 = 0.88 and £ = 0.47 were measured.

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Example II.

A paint of the following composition was prepared: component wt% styrene-butadiene copolymer 10.30 35 chlorinated paraffin 1.14 pigment Ferro Black F 6331a ^ 17.32 aluminum flakes 9.73 800 0 9 86 -6-xylene 55.28 solvent from aluminum paste 5.24 silicone oil 0.01

Coloral F c) 0.98 5 100.00.

The pvk of the pigment was 20%, of the aluminum also 20%.

The paint was applied to an aluminum plate using a smoothing knife. The thickness of the layer after drying was 30-40 µm. After drying for 14 days the following were measured: ai. = 0.90 and £ = 0.44.

s 10 Example III.

A paint of the following composition was prepared: constituent wt.% Siloxan-modified polyester resin 19.75 pigment Ferro Black F 6331a ^ 23.03 15 aluminum flakes 19.36 ethyl glycol acetate 13.16 xylene 15.92 solvent from aluminum paste 8.30

Bentone 38 * ^ 0.26 20 anti-settling agent 0.22 100.00.

The pvk of the pigment was 16%, of the aluminum 24%.

The paint was applied to an aluminum plate using a smoothing knife. The layer was pre-dried at 20 ° C for 30 minutes and then baked at 200 ° C for 60 minutes. The thickness of the obtained layer was 40-50 yam. Then measured = 0.84 and £ = 0.41.

a) iron oxide-manganese oxide-copper oxide pigment, sold by Ferro Holland b) quaternary ammonium modified bentonite 30 c) modified soy lecithin.

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Claims (7)

Paint according to claim 1, characterized in that the spectral selective pigment is a ferric oxide-manganese oxide-copper oxide pigment, a copper oxide-chromium oxide pigment or a carbon black. 3. Paint according to claims 1 and 2, characterized in that the reflective metal particles are particles of aluminum, nickel, copper, zinc, copper-zinc alloy or stainless steel. 4 ·. Paint according to claim 3, characterized in that the reflective metal particles are flakes of aluminum, copper or copper-zinc alloys. Paint according to one or more of the preceding claims, characterized in that the binder is a siloxane-modified alkyd resin or polyester resin, a silicone resin or an elastomeric fluorocarbon. 6. A method of preparing a paint for applying spectral selective coatings, characterized in that a spectral selective pigment is combined with a binder and optionally a liquid carrier and metal particles are added to the pigment dispersion formed. Solar heat absorbing member, characterized by a coating based on a paint according to one or more of claims 1 to 5. Solar collector, comprising a solar heat absorbing member according to claim 7. 800 0 9 86