RU195335U1 - FLAT SUNNY COLLECTOR - Google Patents

Abstract

The utility model relates to solar energy (solar technology) used to collect and convert solar rays and solar energy into thermal energy in solar collectors and its further transfer to heating systems, hot water supply or technological heating of water. A flat solar collector consisting of a cover glass, a highly selective absorber with an absorbent coating, containing tubes for conveying the heat carrier, a thermoplastic seal configured to attach the cover glass and the absorber to each other, so that there is a sealed space between the cover glass and the absorber filled with gas low thermal conductivity, additionally contains a polyurethane housing, and the housing is covered with a protective layer from the outside. Ohm is the creation of a relatively inexpensive in the production and operation of a flat solar collector with increased thermal insulation and reduced heat loss. 3 s.p. f-ly, 2 ill.

Description

The utility model relates to solar energy (solar technology) used to collect and convert solar rays and solar energy into thermal energy in solar collectors and its further transfer to heating systems, hot water supply or technological heating of water.

Currently, two types of solar collectors are widely used: flat and vacuum (heat pipes).

The flat collector is a heat exchanger placed in a thermally insulated housing, one of the sides of which is made transparent. The surface of the heat exchanger facing the light-transmitting material is coated with a solar-absorbing coating, black paint or a special selective coating (usually black nickel or titanium oxide spraying) to increase efficiency. The transparent element is usually made of tempered glass with a low content of metals, or special corrugated polycarbonate. The back of the panel is coated with a heat-insulating material (e.g. polyisocyanurate). The tubes along which the coolant is distributed are made of cross-linked polyethylene or copper. The panel itself is airtight, for which the holes in it are sealed with silicone sealant. [found 10/20/2018] Found on the Internet: <URL: https: //www.atmosfera.ua/geliosistemy/tipy-solnechnyx-kollektorov/>

The disadvantages of flat solar collectors are the lack of thermal insulation of the case, and therefore increase heat loss, especially when the collectors work at low temperatures.

The vacuum collector (heat pipe) has a device similar to household thermoses. Only the outer part of the tube is transparent, and a highly selective coating that captures solar energy is applied to the inner tube. A vacuum is created between the outer and inner glass tubes. It is the vacuum layer that makes it possible to save about 95% of the captured thermal energy. In vacuum solar collectors, heat pipes have been used, acting as a heat conductor. When the unit is irradiated with sunlight, the liquid located in the lower part of the tube, when heated, turns into steam. Vapors rise to the top of the tube (condenser) where, when condensed, they transfer heat to the collector. Using this scheme allows you to achieve greater efficiency (compared with flat collectors) when working in low temperature and low light conditions, [found 10/20/2018] Found from the Internet: <URL: https://ru.wikipedia.org/wiki/Solar_collect >

The disadvantage of vacuum collectors is low (compared to flat) efficiency.

The known design of the solar thermal absorber element, which is part of the solar collector, with a sealed evacuated or filled with an inert gas, the space between the absorber and glass. The solar heat absorber element includes a cover glass and a highly selective absorber with an absorbent coating, containing tubes for conveying the coolant. The element further includes a thermoplastic seal that is capable of attaching the cover glass and the absorber to each other, so that between the cover glass and the absorber there is a sealed space filled with gas with low thermal conductivity (US 20150233606, F24J 2/05, F25B 27/00, published on 08.20.2015).

The disadvantage of the analogue is the general complexity in production, when the package itself is made of a heat exchanger, glass and sealant and evacuated (or filled with gas with low thermal conductivity), then placed in a thermally insulated case. The manufacture, sealing and thermal insulation of the body, as well as the final assembly of the collector, are quite laborious and lengthy processes that require additional production and storage space, including for warehousing packages and cases before final assembly.

The inventive utility model is aimed at eliminating the above disadvantages, namely: the creation of a relatively inexpensive in the production and operation of a flat solar collector with increased thermal insulation and reduced heat loss.

The technical result is achieved by the fact that a flat solar collector consisting of a cover glass, a highly selective absorber with an absorbent coating, containing tubes for conveying the heat carrier, a thermoplastic seal configured to attach the cover glass and the absorber to each other, so that there is between the cover glass and the absorber airtight space filled with gas with low thermal conductivity, according to a utility model further comprises a polyurethane housing a.

In an airtight space filled with gas with low thermal conductivity of a flat solar collector, a reduced pressure (vacuum) can be created.

The case of a flat solar collector can be coated on the outside with a protective layer.

The thermoplastic seal of the flat solar collector may be part of the housing.

The device of the inventive flat solar collector is shown in the figures:

FIG. 1 - flat solar collector with thermoplastic seal, section, where

1 - covering glass,

2 - highly selective absorber with an absorbent coating,

3 - tubes for transporting coolant,

4 - thermoplastic seal,

5 - housing.

FIG. 2 - flat solar collector with thermoplastic seal, assembly drawing, where

1 - covering glass,

2 - highly selective absorber with an absorbent coating,

3 - tubes for transporting the coolant 5 - case.

The problem is solved in that the case of the solar collector is made by casting polyurethane in a rigid form. The liquid components of the polyurethane foam are poured into a rigid, often metallic or other form (possibly combined from metal and fluoroplastic or other material) that can withstand the pressure of expanding polyurethane foam. The fill form is made in the form of a complex figure. After pouring the liquid components and after a certain time, usually 30-50 minutes, the polymer expands and hardens. The mold opens and a solid polymer case is removed from it. At a density of 45-70 kg / m3 and a thickness of more than 35 mm, the hardened polymer has sufficient hardness and thermal conductivity, allowing you to save heat. Thus, as a result of one technological process, a durable part is obtained having high thermal performance. Further, filled with gas with low thermal conductivity, and in the particular case of execution, the evacuated element of the solar heat absorber, consisting of a cover glass (1) of an ultra-transparent material (glass), a highly selective absorber with an absorbent coating (2) - plates with tubes for transporting the heat carrier ( 3), on the upper part of which a heat-absorbing selective coating (absorber) and a thermoplastic seal (4) are applied — a frame repeating the contour of the glass and the plate and located between them, and the frame not only fixes the distance between the plate and glass, but also hermetically closes the space between them, is installed in the finished case (5). The element of the solar heat absorber is fixed in the niche of the polymer body by any known suitable method: using mechanical fasteners, glue, sealant, etc.

The polymeric polyurethane body is subject to degradation under the influence of ultraviolet radiation, therefore, the surface is covered with a protective layer, and in the preferred embodiment, the protective layer is applied to the mold, and then, after it hardens, the components of the heat-insulating housing are poured into the same mold with the formed protective layer. The coating may be of any suitable material or polymer, for example, liquid rubber or Silor-based polymer.

The use of such protection increases the durability and technological performance of the collector.

The preferred option is to fill the polymer into the mold in which the heat exchanger is placed, and then solidify the casing with the heat exchanger already placed in it, which further simplifies the production process.

The most preferred option is to place the heat exchanger in the form of a cover glass and plate and fill the polyurethane, the polyurethane creating a layer (6) around the perimeter between the glass and the panel, thus replacing the thermoplastic seal. In such a housing, it is advisable to leave channels for subsequent filling with gas, and in the particular case, the evacuation of the airtight space between the glass and the plate.

Practical tests showed that the body made by molding polyurethane foam, has sufficient rigidity and has high thermal parameters. Tests also showed that the inventive case contributes to faster heating of the coolant. The temperature of heating the coolant by the end of the test time (12 hours 30 minutes from the time the sun came out and heating started) was higher than that of a conventional flat collector by 10% and 14% higher than that of a tubular collector. On the morning of the next day, at the time of the start of the new test, the temperature in the collector with a polyurethane foam body had lower temperature loss per night (the time when the sun did not heat the heat exchanger for 11 hours 30 minutes) by 12% compared to a conventional flat collector and 7 % compared with a tubular vacuum manifold.

The technical result is the creation of a relatively inexpensive in the production and operation of a flat solar collector with increased thermal insulation and reduced heat loss.

Claims (4)

1. A flat solar collector consisting of a cover glass, a highly selective absorber with an absorbent coating, comprising tubes for conveying a heat carrier, a thermoplastic seal configured to attach the cover glass and the absorber to each other, so that there is a sealed space between the cover glass and the absorber, filled gas with low thermal conductivity, characterized in that it further comprises a polyurethane housing. 2. Flat solar collector according to claim 1, characterized in that a low pressure (vacuum) is created in an airtight space filled with gas with low thermal conductivity. 3. Flat solar collector in paragraphs. 1-2, characterized in that the casing is coated on the outside with a protective layer. 4. Flat solar collector in paragraphs. 1-3, characterized in that the thermoplastic seal is part of the housing.

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