RU2075706C1 - Solar energy collector - Google Patents

Abstract

FIELD: heating water in heating systems and hot water supply systems. SUBSTANCE: solar energy collector has housing with heat-insulating base and transparent coat forming chamber where absorber is mounted; absorber is made in form of flow-through passages which are brought in communication with collecting zigzag pipe lines on two sides with inlet and outlet branch pipes connected to their tops. Passages and pipe lines are formed by laying the plates made from thin-sheet material one on another; plates are fastened over perimeter and between passages and heat-insulating gaskets are introduced. Absorber is made in form of duct. Heat-insulating gaskets are fitted on adjacent edges of side walls of absorber and housing. Flexible transparent coat is located on heat-insulating gaskets; heat-insulating base has front reflecting surface. Untight areas in housing and in absorber may be sealed up means of paste or adhesive. Front reflecting surface of heat-insulating base may be made from "carymat". Heat-insulating base may be connected with base of absorber forming air gap between them. Flexible transparent coat may be made in form of pack tightened on housing forming air gap with rear surface of heat-insulating base. Coat may be reinforced. Side walls of absorber may be connected with respective wall of housing forming air gap between them. EFFECT: enhanced efficiency. 7 cl, 1 dwg

Description

 The present invention relates to solar engineering and can be used for heating water in heating systems and hot water supply.

 Currently, the problem of using environmentally friendly, affordable and cheap energy sources has become quite acute. A special place among these sources of energy is solar energy. Solar energy collectors with an absorber formed by superposing plates of sheet material on top of one another, which are currently used to convert solar energy to heat (for heating the coolant), are not effective enough for several reasons.

 The closest for technical reasons (prototype) is a solar energy collector containing a body of heat-insulating material with a transparent coating of two glass layers forming a cavity and installed in the latter absorber made in the form of flow channels communicated on both sides with prefabricated zigzag shaped pipelines with two outlet pipes connected to their tops, while the channels and pipelines are formed by superimposing on each other two plates of sheet material fastened together along the perimeter and between the channels, and between the plates in the spaces between the channels, bypass channels inclined to their axes are made having a diameter equal to the diameter of the flow channels (USSR patent N 2000525, class F 24 J 2/24, 1993).

 However, the known technical solution is not effective due to the low use of the useful area of the absorber and the heat-insulating properties of the housing. In addition, it is impossible to use a coating with a melting point lower than the temperature of the absorber or the walls of the casing in the collector due to the possibility of its melting as a result of overheating and, as a result, makes it necessary to use expensive coatings that are hard with a high melting point. The collector is expensive and structurally and technologically sophisticated in the performance of both the absorber and the housing.

 A new achievable technological result of the invention is to increase the efficiency of the collector by increasing its heat-insulating properties and manufacturability.

 A new technical result is achieved in that in a known solar energy collector comprising a housing with a heat insulating base and a transparent coating forming a packet, and an absorber installed in the latter, made in the form of flow channels communicated on both sides with prefabricated zigzag pipelines connected to their tops inlet and outlet nozzles, while the channels and pipelines are formed by superimposing on each other plates of sheet material, fastened around the perimeter and between the channels, in Unlike the prototype, heat-insulating gaskets were introduced, the absorber is box-shaped, and heat-insulating gaskets are installed on the corresponding edges of the side walls of the absorber and the housing, the transparent coating is flexible and placed on heat-insulating gaskets, and the heat-insulating base is made with a front reflective surface.

 Leaks in the housing and the absorber can be sealed with mastic or adhesive joints.

 The heat-insulating base with the front reflective surface can be made of a tourist mat "Karimat".

 The heat-insulating base can be connected to the base of the absorber with the formation of an air gap between them.

 A flexible transparent coating can be made in the form of a package stretched over the housing with the formation of an air gap with the rear surface of the insulating base.

 The coating can be made reinforced.

 The side walls of the absorber can be connected to the corresponding wall of the housing with the formation of an air gap between them.

 In FIG. 1 is a schematic diagram of a proposed solar energy collector.

 The solar energy collector includes a housing 1 with a heat-insulating base 2, made with a front reflective surface 3, and with a flexible transparent reinforced screeds 4 coating 5, made in the form of a package, tensioned on the housing 1, using heat-insulating gaskets 6 mounted on the corresponding edges of the side walls 7, 8 of the housing 1 and the absorber 9, while the coating 5 forms a cavity 10 and an air gap 11 with the rear surface 12 of the insulating base 2, and a box-shaped absorber 9 installed in the cavity 10, filled in the form of flow channels 13, connected on both sides with prefabricated zigzag pipes 14 with inlet and outlet pipes 15 connected to their tops, and the channels 13 and pipelines 14 are formed by overlapping plates 16 of sheet material glued along the perimeter and between the channels 13. The side walls of the absorber can be connected to the corresponding wall 7 of the housing 1 with the formation of an air gap 17 between them, and the front reflective surface 3 of the insulating base 2 with the base of the absorber I'm 9 with an air gap of 18 in between. Leaks in the housing are sealed with mastic (or compound) 19.

 The solar energy collector operates as follows.

 The coolant, for example water, is fed through the inlet pipe 15 to the collection pipe 14, the zigzag shape of which ensures uniform distribution of the coolant through the channels 13, including along the periphery, which is especially important during the natural circulation of the coolant. Next, the coolant passes through the flow channels 13, where heat is removed from the plates 16 of the absorber 9 having an absorbing coating that receives solar radiation incident on the absorber 9 through a transparent coating 5, for example, of polyethylene.

 As the absorber 9, for example, a tube type adsorber in a sheet is used, in which a series of parallel pipes with a diameter of 12-15 mm are used at a distance of 50-150 mm from each other. The formation of pipes (channels 13) is as follows. On the plates 16 of sheet material, for example aluminum or its alloys, the path of the channels 13, pipelines 14 and nozzles 15 is marked with a cutting tool. After that, the plates 16 are laid on top of each other with their intended sides and rolled, fastening them. Then the formed package of aluminum or its alloy is inflated with compressed air along the intended lines, receiving channels 13, pipelines 14 and nozzles 15 of the desired diameter. The use of such a technology of forming channels 13, pipelines 14 and nozzles 15 makes it impossible for bypass channels and additional nozzles 15 (two on each side), as in the prototype, as well as the location of parallel channels 13 closer than 50 mm to each other. This is due to the fact that during inflation, an increase in the area of channels 13 and pipelines 14 due to material from pressed plates 16 can lead to their skew and the entire absorber 9.

 Then the inlet and outlet nozzles 15 are connected mainly with mastic or adhesive joints (such as compound) 19 to the hydraulic manifolds.

 Washer channels 13 absorber 9 coolant is heated and consumed for various household and technical needs.

The thermal efficiency of the collector increases due to:
a box-shaped absorber 9, which provides a large useful area for receiving solar energy by the absorber 9 due to the surface of its walls 8 and, as a result, the possibility of solar energy reaching the latter in the most efficient way (close to normal) when the Sun is at a small angle to the horizon, for example, sunset
the presence of a front reflective surface 3 at the heat-insulating base 2, mainly from a tourist mat "Karimat" in Izhevsk, which provides a reflection of more than 96% of infrared radiation from the absorber 9 back to it;
the presence of additional air gaps 11, 18, ensuring the conservation of heat in the absorber 9, together with the heat-insulating base 2 from the front reflective surface 3.

 The presence of an air gap 17 between the walls 7, 8 of the housing 1 and the absorber 9, as well as the presence of the walls 8 (box-shaped) of the absorber 9 itself, makes it possible to abandon the use of the walls 7 of the housing from heat-insulating material, and then their possible implementation from aluminum, which does not increase the dimensions of the collector with the introduction of additional walls 8 of the absorber while maintaining the thermal insulation properties of the side sections of the collector. All of the above makes it possible to increase the efficiency of the collector, its efficiency by not less than 10% increasing, under equal external conditions, the temperature of heating the coolant.

 In addition, the side walls 8 of the absorber 9 provide, together with the heat-insulating coating 6, reinforcement (creating support) of the flexible transparent coating 5, which increases the strength and reliability of the latter, and, accordingly, eliminates the need for additional reinforcement with screeds 4 or reduces the required number of screeds 4 made, for example, in the form of a frame, mesh, etc.

The presence on the edges of the walls 7, 8 of the housing 1 and the absorber 9 of heat-insulating gaskets 5, as well as the air gap 17 between them, makes it possible to use material with a melting temperature lower than the maximum heating temperature (up to 130 ^o C) of the absorber as a flexible transparent coating 5 6, for example a formaldehyde film with a softening point of 125 ^° C. and the like.

Similarly, the air gap 18 between the heat-insulating base 2 and the base of the absorber 9 allows the use of a heat-insulating base 2 of a material with a melting point lower than the maximum heating temperature of the absorber 6 (130 ^o C), for example, of polyurethane foam, which has a low temperature resistance of up to 120 ^o C or expanded polystyrene up to 60 ^o C, etc.

 All this, in aggregate, allows to increase the reliability, efficiency and manufacturability of the proposed collector while at the same time using more affordable, cheaper and less heat-resistant materials as a heat-insulating base 2 and flexible coating 5.

The use of a prototype polyurethane foam housing (even if it were possible constructively) does not allow the absorber to be heated to a temperature higher than 120 ^o C (the proposed collector is up to 130 ^o C), as well as a heat-resistant double glass coating, which makes the prototype less effective and more expensive.

 The use of flexible transparent coating 5 in the form of a package allows you to pull it like a “stocking” on the housing 1 and heat-insulating gaskets 6, refusing, at the same time, the need for fixing the coating 5, thereby simplifying the manufacturing technology of the collector. In the light, the coating 5 stretched over the collector "sits down" and tightens the collector.

 The use of mastic or adhesive compounds (19) for sealing leaks in the housing 1 and absorber 9 allows to increase the life of the collector due to the absence of corrosion in those places when using welded joints to eliminate leaks.

 Based on the above, the claimed compound has the following achievable technical result.

1. Improving the efficiency of the collector by increasing its heat-insulated properties and using a box-shaped coolant by at least 10%
2. Improving the manufacturability of manufacturing by at least 10% due to the use of a coating in the form of a bag and an absorber without bypass channels, due to the possibility of its production by blowing rolled sheets with the planned lines of channels, pipelines and pipes.

 3. Expanding the range and cost of materials used for coating and thermal insulation due to materials with a lower melting point.

 4. Increasing the corrosion resistance of the collector due to the use of welded joints for sealing, and the use of mastic and adhesive joints, bypass channels and additional inlet and outlet pipes while increasing the heating medium heating efficiency.

 At present, the enterprise NPO Astrophysics has issued design documentation for the claimed solar energy collector, on the basis of which small-scale samples of a useful model of the solar energy collector have been created.

Claims (7)

 1. A solar energy collector comprising a housing with a heat-insulating base and a transparent coating forming a cavity, and installed in the latter, an absorber made in the form of flow channels communicated on both sides with prefabricated zigzag pipelines and input and output pipes connected to their tops, while channels and pipelines are formed by superimposing on each other plates of sheet material bonded around the perimeter and between the channels, characterized in that heat-insulating sheets are inserted into it subcontroller and absorber is configured in the form of a box, wherein the insulating spacers are mounted on adjacent edges of the side walls of the absorber and casing clearcoat is flexible and is placed on heat insulating gaskets, thermal insulating base is made with the front reflecting surface.  2. The collector according to claim 1, characterized in that the leaks of the housing and the absorber are sealed with mastic or adhesive joints.  3. The collector according to claims 1 and 2, characterized in that the heat-insulating base with a reflective face is made of a tourist mat "Karimat".  4. The collector according to claims 1 to 3, characterized in that the insulating base is connected to the base of the absorber with the formation of an air gap between them.  5. The collector according to claims 1 to 4, characterized in that the flexible transparent coating is made in the form of a package stretched over the housing with the formation of an air gap with the rear surface of the insulating base.  6. The collector according to claims 1 to 5, characterized in that the coating is reinforced.  7. The collector according to claims 1 to 6, characterized in that the side walls of the absorber are connected to the corresponding wall of the housing with the formation of an air gap between them.