RU2738738C1 - Planar roof panel with corrugated thermal photodetector - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to construction, in particular to corrugated thermal photodetector built into structural elements of roofs of buildings and serves to convert solar radiation into thermal energy. Corrugated thermal photoreceiver has inclination angle of corrugated surface equal to 90°, and selective coating for reduction of optical losses, is a guiding cavity for heat carrier flow. Panel body made of polymer material, in form of roof with locks and hydraulic nozzles for direct connection of panels to each other, has face glazing for gas heat insulation, rear heat insulation in the form of an air gap, a heat carrier flow divider, a thin slot along the entire length of the panel housing for the corrugated thermal photodetector attachment.EFFECT: technical result consists in providing complete hydraulic protection of roof.1 cl, 2 dwg

Description

The invention relates to agriculture, in particular to heat supply of agricultural and individual objects in an autonomous mode or parallel to the existing heating network, serves to convert solar radiation into thermal energy and is embedded in structural elements of roofs of buildings and structures.

Known roofing panel with a solar module, which includes a body in the form of a curved surface, photoelectric converters and a current collection cable (RF patent No. 2194827, IPC E04D 13/18, 20.12.2002). Photovoltaic converters connected to a photovoltaic module are placed on a base recessed relative to the upper surface of the panel at a depth of 20 mm and protected to the upper surface of the base with a sealing curing composition, the level of solar radiation transmission of which is not less than 30% in the range of operation of photovoltaic converters.

The disadvantage of the known roof panel with a solar module is the lack of the possibility of using thermal energy, the conversion efficiency of which from solar energy is much higher than conversion to electrical energy, which leads to the need for additional installation of a solar thermal module for hot water supply and heating of buildings. Also an important disadvantage of the known roofing panel is the lack of attachment to structural elements of the roof and the use of a material as a body that differs from recycled plastic, which increases the cost of manufacturing the panel.

A hybrid roofing solar panel is known, in which, along with electrical energy at the exit from the panel, the consumer also receives thermal energy in the form of a heated coolant (RF patent No. 2612725, IPC H02S 10/30, 03/13/2017). The number of photovoltaic converters in the known roofing solar panel is reduced due to the use of a solar radiation concentrator, and the heat removed from the photovoltaic converters heats the heat carrier, which flows through a metal-plastic tube, which is located in the roofing panel housing directly behind the photovoltaic converters.

The disadvantages of the well-known hybrid roofing solar panel are high material consumption and weight, which increases the cost of the structure and the weight acting on its roof, which must be taken into account when designing a building, the large depth of the module limits the scope of application of the known roofing panels due to the specific requirements for structural and non-standard roof elements, low reliability of fastening of roofing panels, since under wind load there is a risk of tearing, displacement and deformation of roofing panels, which must be taken into account with their large mass, low temperature of the coolant, a high value of which will be difficult to achieve due to poor thermal contact with photovoltaic converters, and also a low coefficient of thermal conductivity of the used metal-plastic pipes and body material, which will cause high heat losses and low heating temperature of the coolant. Also, the disadvantages of solar panels are the complexity of installing and fixing the panels when using a single metal-plastic pipe for all panels, the inability to use the thermosiphon effect and the movement of the coolant under the action of gravity due to the horizontal arrangement of heat removal pipes.

The closest in technical essence to the invention (prototype) is a solar collector, which is used as an element of the roof of the building roof and serves to heat the coolant and consists of a body and a heat-absorbing element, which is a metal sheet with a developed surface facing the coolant (RF patent No. 2183801, IPC F24J 2/04, F24J 2/22, 20.06.2002). On the body of the solar collector there are fasteners for connecting the collectors to each other, as well as for attaching them to the roof frame. As part of the known solar collector, a device is used, the heat-sensing element of which occupies almost the entire volume of the heat exchanger, but the heat-sensing element (pipes) occupies only a part of the roof surface.

The disadvantages of the known solar collector are the lack of front thermal insulation of the collector, which leads to significant heat losses from the front surface of the solar collector, the lack of heat insulation of the outlet pipelines, which also leads to heat losses from the removed coolant, high material consumption of the structure, which leads to an increase in the cost and weight of the entire structure , the need to use a waterproofing coating under it, since the design of the collector does not imply complete protection from precipitation, an unpresentable type of roof, which is especially important after a significant time of operation and the beginning of degradation processes of the unprotected surface of the solar collector, the unreasonableness of using the developed surface of the collector, which is unnecessarily complicated, weighted , and the use of material only increases the total mass, which loads the structural elements of the roof and uneven washing and heat removal from the radiator surface, which is difficult to organize in the presented design, as well as the use of thermosyphon operation of the coolant, as well as the flow of the coolant under the action of gravity.

The technical objective of the present invention is the production of thermal energy for heating objects of agricultural and individual use using a planar roof panel, a corrugated thermal photodetector, which has increased optical and thermal efficiency, and the body has increased thermal insulation and performs the protective function of the roof of buildings.

As a result of using the invention, it becomes possible to supply buildings with thermal energy autonomously and parallel with the existing thermal network using a building module in the form of a roofing panel, which generates thermal energy in the form of a heat carrier heated to a high temperature and at the same time, due to the use of the shape of the panel body in the form of a roof , performs the protective functions of buildings from external influences. The use of recycled plastic in the panel body has a positive effect on the environment, as well as the cost of manufacturing and using roofing panels. The corrugated structure with the selective coating of the roof panel's thermal photo detector reduces the optical loss of the panel and also increases the generation of thermal energy in the morning and evening hours. The front glazing, as well as the rear thermal insulation of the heat carrier of the roofing panel, also reduces the heat loss of the heat carrier.

The above technical result is achieved by the fact that in the proposed planar roofing panel with a corrugated thermal photodetector, containing a corrugated thermal photodetector with rear thermal insulation, according to the invention, the thermal photodetector has an inclination angle of the corrugated surface equal to 90 °, a selective coating to reduce optical losses and is a guiding cavity for coolant flow, and the panel body made of polymer material, in the form of a roof with locks and hydraulic fittings for direct connection of the panels to each other without intermediate pipelines, has front glazing for gas thermal insulation, rear thermal insulation in the form of an air gap, a flow divider for efficient separation of flows coolant, a thin groove along the entire length of the panel body for attaching a corrugated thermal photodetector, while the panel body provides full hydraulic protection of the building roof, is securely attached to the roof beam with a by means of holes in the housing and ensures the movement of the gaseous coolant during the thermosyphon operation of the panel, as well as the liquid coolant under the influence of its gravity, when the coolant is released from the extreme roofing panels in a row directly into the heated coolant reservoir installed in the inner space.

The essence of the invention is illustrated by drawings, where Fig. 1 shows a general diagram of a planar roofing panel with a corrugated thermal photodetector assembled (top view, glass is shown completely transparent), FIG. 2 - Drawings of a planar roofing panel with a corrugated thermal detector assembly, showing a front view; three sections showing the inlet and outlet openings, the coolant and the gas layer; and also a detail section showing a corrugated heat detector with a selective coating applied.

A planar roofing panel with a corrugated thermal photodetector consists of a housing 1, the shape of which in the form of a tile provides the protective and construction functions of the building, is made of polymer material, for example, recycled plastic, has locks 2 for connecting the panels to each other and built-in hydraulic fittings 3 in special upper openings 4 for direct flow of gaseous heat carrier 5 with the thermosyphon effect from the upper part of the housing 1 of one panel to the lower part of the housing 1 of the other panel through the corresponding lower openings 6. The use, for example, of recycled polyethylene in the structure of the housing 1 of the roofing panel allows to reduce the total cost of the panel and reduce environmental pollution. The side edges of the housings 1 of the panels form locks 2, thanks to which all the roofing panels in the formed rows are in the same plane, which makes it possible to switch the hydraulic fittings 3 without connecting pipelines, which makes it possible to minimize losses when moving the coolant 5 from one roofing panel to another. The movement of the heat transfer fluid 5 under the action of gravity occurs from the lower part of the housing 1 of the panel through the lower openings 6 to the upper part of the housing 1 of the other panel through the built-in hydraulic connections 3 and the upper openings 4. Using a flow-through system where the heat transfer fluid 5 moves under the action of gravity from above down, and the connection of the roofing panels to each other occurs without pipelines directly in the buildings 1, simplifies and reduces the cost of the design of the hydraulic system and reduces heat losses when moving the coolant 5 between the roofing panels. To create a thermosyphon effect in the system of roofing panels, a coolant 5 is used in the form of gases or low-boiling freons, which makes it possible to do without circulation pumps. The hydraulic connections 3 are hermetically inserted into the lower openings 6 by superimposing the lower rear part of the roofing panel on the upper front part of another roofing panel so that the transparent parts of the roofing panels are not shaded. The coolant 5, thanks to the flow divider 7 of the housing 1, washes the corresponding areas of the corrugated thermal photodetector 8, the surface of which has an angle of inclination of the adjacent faces of 90 ° and a selective coating 9, which reduces optical losses, increases the production of heat energy in the morning and evening hours, due to normal fall rays on the surface of the corrugated thermal photodetector 8 (and not tangentially), and in the daytime due to the mutual reflection of the sun's rays on its neighboring faces, which reduces losses for reflection of solar radiation throughout the day, and also ensures the direction of the flow of the coolant 5 as in thermosiphon operation, and when cooled by the heat carrier 5, moving under the action of gravity. Also, the corrugated surface of the thermal photodetector 8 directs the coolant 5 to the exit from the housing 1 of the panel, which improves the washing of the corrugated thermal photodetector 8 itself and the heat removal with the coolant 5. Also, due to the washing of the entire surface of the corrugated thermal photodetector 8, the thermal contact of the coolant 5 and the inner part of the corrugated thermal photodetector 8 , which increases the efficiency of heating the coolant 5 and the thermal efficiency of the roofing panel. The area of the radiation-receiving surface of the corrugated thermal photodetector 8 of the considered roofing panel is larger in comparison with the flat photodetector, which provides heating of a larger surface of the thermal photodetector 8. The corrugated thermal photodetector 8 is made of metal materials with a high thermal conductivity coefficient (aluminum, copper) and is hermetically installed in a special groove 10 , which runs along the entire length of the panel body 1, which ensures its reliable fixation and sealing of the coolant 5. Due to the gas layer 11 between the corrugated thermal photodetector 8 and tempered glass with a reduced iron oxide content and high optical transparency 12, heat losses through the front surface of the roofing panel are reduced, and heat losses through the rear surface of the roofing panel body 1 are reduced due to the air gap 13 on the rear side, which can also be filled with a material with low thermal conductivity. The heat-insulating gas layer 11 can be filled with various transparent gases with a low coefficient of thermal conductivity and high optical transparency. In addition to the single glazing of the body 1 of the roof panel, double glazing with a double gas layer 11 can be used, which will further reduce heat losses through the face of the roof panel. Due to low thermal and optical losses, the temperature of the heat carrier 5 reaches high temperatures, which can subsequently be used in heat supply to consumers. Fastening the body 1 of a planar roofing panel with a corrugated thermal photodetector 8 to the roof is rigid with the help of holes 14 in the upper part of the body 1, into which self-tapping screws are screwed into a wooden roof beam, which provides rigid fixation of the panels against wind load. The durability of planar roofing panels with corrugated thermal photodetector is ensured at the level of traditional roofing materials. The heated heat carrier 5 can be used by the consumer. Cooling of corrugated thermal photodetectors 8 of roof panels occurs from top to bottom due to the gravity of the liquid heat carrier 5. When using a gaseous heat carrier 5, cooling of the thermal photodetector 8 is achieved due to the thermosiphon effect - under the influence of solar radiation, an ascending convective flow of the heated heat carrier 5 is formed, due to which the natural circulation of the heat carrier 5 from the bottom to the top. The outlet of the coolant 5 from the extreme roofing panels can occur in two directions directly into the reservoir of the heated coolant in the interior of the building space, which excludes lengthy pipelines that are a source of heat losses: through the upper row of roofing panels during the thermosiphon operation of the coolant 5 or through the lower row of roofing panels when moving coolant 5 by gravity.

The proposed planar roofing panel with a corrugated thermal photodetector operates as follows.

The roofing panel with a corrugated thermal photodetector 8 is attached to the southern slope of the building roof using self-tapping screws through holes 14, which are located in the body 1 of the roofing panel. The roofing panels are joined together using side locks 2 on the side surfaces, and the hydraulic movement of the coolant 5 is provided using the lower 6 and upper 4 holes, with hydraulic fittings 3 installed in the upper holes 4. Solar radiation falling on the surface of the roofing panel using corrugated thermal photodetector 8 converts into heat that part of the solar radiation that absorbs its selective coating 9, and the preservation of its high temperature is ensured by a transparent heat-insulating gas layer 11, which is formed using tempered glass with a reduced iron oxide content and high optical transparency 12, which also is a protective and sealing component for this gas layer 11. The heated corrugated thermal photodetector 8, fixed in the groove 10 of the case 1 of the panel, is washed by the coolant 5, which flows through the lower holes 6 of the case 1 of the panel and washes the inner surface spine of the corrugated thermal photodetector 8, thus taking away thermal energy. With the help of the flow divider 7 and the corrugated surface of the thermal photodetector 8, the heat carrier 5 during thermosyphon operation is directed to the upper outlet openings 4, into which the hydraulic fittings 3 are installed, through which the coolant 5 further flows into the lower openings 6 of the next roofing panel in the direction of movement of the coolant 5. Rear thermal insulation of the heat carrier 5 is provided by the air gap 13, in which a material with low thermal conductivity can also be placed. When heating the coolant 5, which moves under the gravity of the coolant 5, its movement occurs in the opposite direction - through the lower holes 6 of the upper panel into the hydraulic fittings 3 and the upper holes 4 of the lower roofing panel. After heating the coolant 5 and leaving the roofing panels, it accumulates in a heat-insulated tank inside the building through the upper or lower row of roofing panels (depending on the type of coolant and its mode of operation), after which it can be used by the consumer.

Claims (1)

A planar roof panel with a corrugated thermal photodetector, containing a corrugated thermal photodetector with rear thermal insulation, characterized in that the thermal photodetector has a slope angle of the corrugated surface equal to 90 °, a selective coating to reduce optical losses and is a guiding cavity for the coolant flow, and the panel body, made of polymeric material, in the form of a roof with locks and hydraulic fittings for direct connection of panels to each other without intermediate pipelines, has front glazing for gas thermal insulation, rear thermal insulation in the form of an air gap, a flow divider for efficient separation of coolant flows, a thin groove along the entire length panel housings for attaching a corrugated thermal photodetector, while the panel housing provides full hydraulic protection of the roof of the building, is securely attached to the roof beam using holes in the housing and ensures the movement of gaseous heat during the thermosyphon operation of the panel, as well as the liquid heat carrier under the influence of its gravity, when the heat carrier is released from the extreme roofing panels in a row directly into the heated heat carrier tank installed in the interior of the house space.

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