RU94676U1 - FLAT SUNNY COLLECTOR - Google Patents

Abstract

 1. Flat solar collector, consisting of a translucent transparent coating and an absorber made of a polymer translucent material with internal channels, a heat exchange system containing internal channels of the absorber and collector pipes, openings communicating the internal cavities with the atmosphere, and heat insulation that are tightly mounted on the end sides of the absorber sheet absorber, characterized in that the translucent transparent coating is made on both sides of the absorber and spaced from it throughout its plane at a distance A fence prevents convective heat transfer between the absorber and the transparent coating; a fence is located around the perimeter of the absorber and the transparent coating; the limiting pins with low thermal conductivity are evenly located between the absorber and the light-transmitting coating; a U-shaped profile with a shelf height equal to the thickness is hermetically fixed along the outer perimeter of the solar collector a collector pipe and a double sheet of transparent coating at a distance providing a clearance between the guard and the shelf, sufficient for the size heat insulation. ! 2. The collector according to claim 1, characterized in that the fence is made of a flexible polymer film fixed by an adhesive joint. ! 3. The collector according to claim 1, characterized in that the fence is made in the form of a U-shaped profile fixed by soldering or gluing on the sides of the absorber to the depth of its transverse dimension with a shelf height equal to the air gap made of a polymer material with low thermal conductivity and sufficient heat resistance, and the profile is oriented by its shelf �

Description

The solar collector refers to the field of conversion of solar energy into thermal energy using the latter for public and domestic needs of the population. It can be used as the main or additional heater in the hot water supply system. It can be used in systems with natural (thermosiphon type) or forced circulation of the coolant.

The simplest and cheapest way to use solar energy is to heat household water in the so-called flat solar collectors.

A known design of a flat solar collector, which consists of a housing, an element that absorbs solar radiation, a coolant circulation system, a transparent coating and a heat insulating layer (US Pat. RF No. 2298739, 2269726, 2325599, 2330217, 2350852, F24J 2/24).

The absorbing element is called an absorber; it is a sheet of metal with good thermal conductivity, coated with a selective absorbing coating. The more incident energy is transferred to the coolant flowing in the collector, the higher its efficiency. You can increase it by using special optical coatings that do not emit heat in the infrared spectrum.

The absorber is connected with a heat-conducting system made in the form of a tubular coil attached by soldering, welding to the absorber. A standard solution for increasing collector efficiency was the use of an absorber made of sheet copper due to its high thermal conductivity.

The transparent element is usually made of tempered glass with a reduced metal content.

The flat collector housing is usually made of metal and insulated with mineral wool (or the like) from the absorber.

Known (patent RU 2348869, IPC F24J 2/00, 2/46, 2009) design of a flat vacuum manifold made with the possibility of evacuation and vacuum sealing, which contains at least one absorber, in particular a plate absorber, at least one pipe, which is at least partially thermally connected with the specified at least one absorber, supporting a structure made, in particular, of metal and provided with a perimeter frame, and at least one first transparent wall, particular flat the glass panel, in particular the perimeter of the first transparent wall and the supporting structure, in particular the first supporting surface of the frame, overlap, in particular, on the perimeter section.

These design of a flat solar collector (as well as a vacuum tubular) has several serious disadvantages:

- the risk of brittle fracture of the transparent glass coating as a result of hail or accidental mechanical damage;

- a large weight of the structure (from 20 to 50 kg. / m ² ), which is due to the materials used (glass, metal);

- a significant thickness of the insulating coating is 50-100 mm, which leads to an increase in the overall dimensions (thickness) of the solar collector body and, accordingly, weight;

- significant weight and a high risk of mechanical damage to such collectors limit their use in mobile (tourist) installations;

- significant weight, rigid shape and overall dimensions of the collectors limit their use as an aesthetic design of private households;

in the manufacture of vacuum manifolds, high-tech special equipment is required (metalworking, vacuum, etc.)

- due to the high cost of materials, production costs, installation of collectors, the final cost of the solar collector is high;

- The final cost of the generated thermal energy by the solar collector in the conditions of central Russia is several times higher than that obtained by traditional methods (burning fossil fuels).

Solar collectors are known in which, in order to eliminate the above drawbacks, various polymeric materials are used as structural materials for the housing, the element that absorbs solar radiation, coolant circulation systems, and transparent coatings (US Pat. RF No. 2330218, 2329437, 87784, 84093, 79989, 48039 , 48038, IPC F24J 2/46).

Closest to the claimed one is the design of the solar collector (patent RU 48039, IPC F24J 2/46, 2005), comprising a housing in which a heat-absorbing panel and transparent thermal insulation are placed above it. Thermal insulation of the bottom and sides of the heat-absorbing panel is placed inside the case, and the heat-absorbing panel is made of an opaque heat-resistant and ultraviolet-resistant polymer material in the form of a flat plate, to the lower surface of which a heat-resistant wave-like sheet of polymer material is attached by welding, thereby forming semicylindrical longitudinal channels for coolant pumping. A heat-absorbing panel from two end sides containing channels is connected to the collector pipes made of heat-resistant plastic using adhesive or welded joints with the possibility of through-flow of the coolant. Transparent thermal insulation is made of sheet or honeycomb heat-resistant and UV-resistant transparent polymeric material, and the thermal insulation inside the housing is made of foam material with low thermal conductivity coated on the side facing the heat-absorbing panel reflecting the thermal radiation of the foil. The case and fasteners are made of a polymer material that is resistant to ultraviolet radiation and weather conditions. The internal air cavity of the solar collector, formed as a result of a sealed adhesive or welded joint of transparent thermal insulation and the casing, is in communication with the surrounding atmosphere through perforated holes in the casing of the solar collector.

The disadvantages of this design are:

- the presence of a separately made housing that increases weight and reduces the manufacturability of the structure;

- the design of the welded absorber is difficult to implement without special equipment;

- thermal insulation of the lower side of the absorber, made over its entire area, increases the weight of the structure and the consumption of materials.

The proposed structural solution is aimed at increasing efficiency, reducing heat loss, simplifying the design and improving manufacturability, reducing the cost of manufacturing a solar collector.

The technical result obtained by the implementation of the claimed design of the solar collector is as follows:

1. Reducing the weight of the solar collector to 4-7 kg / m ² ;

2. Reducing the cost of the solar collector;

3. The lack of sophisticated technological equipment in production;

4. High maintainability, ease of installation;

5. High mechanical resistance of the solar collector (not afraid of hail and shock);

6. The high efficiency of the type of thermal insulation used makes it possible to reduce the thickness of the collector to 40-50 mm and at the same time allow the production of thermal energy at low ambient temperatures.

This technical result is achieved in that a flat solar collector consisting of a translucent transparent coating and an absorber made of a polymer translucent material with internal channels, a heat exchange system containing internal channels of the absorber and collector pipes sealed on the end faces of the absorber sheet, openings communicating internal cavities with atmosphere, thermal insulation of the absorber, according to the invention, a translucent transparent coating is made on both sides of the absorber and it is separated from it over its entire plane by a distance that prevents convective heat transfer between the absorber and the transparent coating, a fence is located around the perimeter of the absorber and the transparent coating, the limiting pins with low thermal conductivity are evenly located between the absorber and the light-permeable coating, the outer perimeter of the solar collector is hermetically fixed П -shaped profile with a shelf height equal to the thickness of the collector pipe and a double sheet of transparent coating at a distance that provides clearance ezhdu fencing and shelf, large enough to hold the insulation.

The fence can be made of a flexible polymer film fixed with an adhesive joint.

The fence can be made in the form of a U-shaped profile fixed by soldering or gluing on the sides of the absorber, to the depth of its transverse dimension, with a shelf height equal to the size of the air gap made of a polymer material with low thermal conductivity and sufficient heat resistance, and the profile is oriented with its shelf to the center of the solar collector,

Cellular polycarbonate or other similar polymeric multilayer material with a size of internal channels of 6-8 mm, having good heat resistance and resistance to solar radiation, is used as a translucent material and a case material.

It is known that the thermal conductivity of the air gap of a thickness of not more than 10 mm (in which there are no convective flows) is equated to the thermal conductivity of vacuum insulation. Thus, the use of this material allows, in addition to transmitting the light flux to the absorber from both sides, to effectively insulate the solar collector body.

The figure shows a General view of the proposed solar collector.

The collector consists of translucent panels 1, placed on both sides of the absorbent 2, plastic collector pipes 3, tightly worn on the end sides of the absorbent 2, a U-shaped plastic profile 4, framing a solar collector around the outer perimeter, a U-shaped profile 5, placed in the gap between the translucent panel 1 and the absorbent 2, the heat insulator 6, the limiting pins 7 and the U-shaped metal staples 8.

Translucent panels 1 are located on both sides of the absorber 2 of the solar collector, simultaneously perform the function of the casing and are 6-8 mm away from the absorber sheet, this air gap serves as another layer of thermal insulation. In connection with this design feature, it becomes possible to increase the thermal power of the solar collector by concentrating the light flux (mirrors) from the back of the collector (not shown in the figure).

As the material of absorbent 2, cellular polycarbonate or other similar polymeric two-layer material with an internal channel size (not shown) of 4-8 mm is used, which has good heat resistance and is coated externally with a layer of heat-resistant selective absorbing coating having a high conversion efficiency of solar energy into heat. To remove thermal energy from the absorbent sheet, coolant (water or antifreeze) is passed through its internal channels.

Due to the larger contact area of the heat carrier with the absorbent material than in a tubular heat exchanger, the requirements for the thermal conductivity of the absorbent material are reduced. Thus, the use of polymeric materials (plastics) characterized by low thermal conductivity is justified.

On the end sides of the absorbent sheet 2 (with the outputs of the internal channels), plastic collector pipes 3 are tightly fitted, in which longitudinal holes are preformed for the length of the absorbent sheet and a width of 1 mm. Pipes 3 are put on the absorbent sheet with an interference fit, which, when adhesive material is added to the seam, reliably seals the joint. The size of the sheet of absorbent 2 is selected so that its width is equal to the width of the translucent panels 1, and the length of the absorber 2 together with the collector tubes 3 is equal to the length of the translucent panels 1.

Between the absorber 2 and the translucent panels 1, in order to prevent changes in the air gap, welding or adhesive joints are fixed with restrictive pins 7 of a height equal to the air gap (6-8 mm) made of a polymer material with low thermal conductivity, sufficient strength, and heat resistance.

To prevent the ingress of heat insulator 6 (mounting foam, mineral wool) in the gap between the translucent panels 1 and the absorber 2, a fence is made around the perimeter of the latter. The fence can be made of a flexible polymer film fixed with an adhesive joint. When filling the space between the external U-shaped profile 4 and the flexible enclosure with a foamed heat insulator (mounting foam) 6, the latter expands during polymerization, deforms the flexible enclosure and securely fixes the absorber 2 with the required technological gap between the outer translucent panels 1.

The fence can also be made in the form of a U-shaped profile 5 with a shelf height of 6-8 mm (equal to the air gap), made of a polymer material with low thermal conductivity, fixed by soldering or by gluing on the sides of the absorber, to the depth of its transverse size sufficient heat resistance. Moreover, the profile shelf faces the center of the solar collector.

Along the outer perimeter, the solar collector is framed by a U-shaped plastic profile 4 with a shelf height equal to the thickness of the collector pipes 3 and a double sheet of translucent panel 1, under which there is thermal insulation 6 (mineral wool, mounting foam). U-shaped profile 4 performs a supporting and aesthetic functions (can also be metal).

For communication with the atmosphere in the outer U-shaped plastic profile 4, through holes are made (not shown in the figure), through which during the assembly of the solar collector it can be filled with thermal insulation (mounting foam). For preliminary fixation of the absorber 2 and two external translucent panels 1 in a strong package, U-shaped metal brackets 8 are used, worn on this package with an interference fit. Before mounting the external U-shaped profile 4 they are removed.

Thus, the proposed solar collector can be technologically made from sheet polymer materials and plastic pipes without the use of metals and glass, which will reduce the cost and increase consumer properties compared to solar collectors of traditional designs.

Claims (3)

1. Flat solar collector, consisting of a translucent transparent coating and an absorber made of a polymer translucent material with internal channels, a heat exchange system containing internal channels of the absorber and collector pipes, openings communicating the internal cavities with the atmosphere, and heat insulation that are tightly mounted on the end sides of the absorber sheet absorber, characterized in that the translucent transparent coating is made on both sides of the absorber and spaced from it throughout its plane at a distance A fence prevents convective heat transfer between the absorber and the transparent coating; a fence is located around the perimeter of the absorber and the transparent coating; the limiting pins with low thermal conductivity are evenly located between the absorber and the light-transmitting coating; a U-shaped profile with a shelf height equal to the thickness is hermetically fixed along the outer perimeter of the solar collector a collector pipe and a double sheet of transparent coating at a distance providing a clearance between the guard and the shelf, sufficient for the size heat insulation. 2. The collector according to claim 1, characterized in that the fence is made of a flexible polymer film fixed by an adhesive joint. 3. The collector according to claim 1, characterized in that the fence is made in the form of a U-shaped profile fixed by soldering or gluing on the sides of the absorber to the depth of its transverse dimension with a shelf height equal to the air gap made of a polymer material with low thermal conductivity and sufficient heat resistance, and the profile is oriented with its shelf to the center of the solar collector.