RU2507353C1 - Solar energy thermoemission system of building power supply - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: solar energy thermoemission system of building power supply comprises external fences, covered with decorative fences from outside, reinforced with contour reinforcement, to form an air gap between them and bearing fences of the building, and the gap communicates with atmosphere via holes, a roof cover on the bearing structure of the roof. The air gap communicates with the room of the attic via slots, and with external air - via holes arranged in the lower part of decorative fences, the roof cover and decorative fences consist of rectangular sections, each represents a photothermoelectric converter comprising a photo cell attached by its rear side to the external side of the body of the thermoelectric converter, the rear side of which is equipped with vertical ribs, made of dielectric material with high heat conductivity, into the massif of which there is contour reinforcement placed, made of elements of the thermoelectric converter representing paired wire sections made of different metals, soldered at the ends to each other, forming zigzag-shaped rows, arranged in such a manner that the left parts of wire sections with left soldered ends are bent at the angle of 90° and are arranged near the external surface of the body of the thermoelectric converter in parallel to it, not touching it, and the right parts of the wire sections with the right soldered ends are arranged in the massif of the ribs, the extreme wire sections of extreme zigzag-shaped rows of thermoelectric converters and output terminals of photo cells are connected via appropriate unipolar headers of electric charges with an accumulating unit.

EFFECT: higher efficiency and reliability of a solar energy thermoemission system of building power supply.

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Description

The present invention relates to construction and can be used in the manufacture of decorative fencing of external walls and roofing to reduce heat loss of buildings, the joint utilization of these heat losses, solar energy, heat and cold outside air in the summer and winter periods to produce electrical energy.

Known ventilated wall element containing internal vertical slotted cavities between the supporting structure of the fence, connected through stiffeners with its outer surface (decorative fence), communicating with the atmosphere through the holes in it [RF Patent No. 2181821, Mcl. E04C 2/26, E04B 2/42, 2002].

Known ventilated roofing, including the base of the roof and ready-made mastic elements placed on it, forming ventilated cavities [RF Patent No. 2079615, Mcl. E04D13 / 00, 1997].

The main disadvantages of the known ventilated wall element and roofing are the insufficient strength of the decorative fence and mastic elements, the inability to utilize the heat of the outside air, the heat loss of the building and solar energy, which reduces their reliability and efficiency.

Closer in technical essence to the present invention is a laminated panel of a ventilated wall fence, including a supporting inner layer (supporting fence) and an outer concrete layer of dense structure (decorative fence), reinforced with contour mesh reinforcement, a middle layer of large-porous material with through voids (slots) air gaps), communicating with the atmosphere through a system of exhaust openings and channels [RF Patent No. 2221119, Mcl. E04C 2/26, E04B 2/14, 2004].

The main disadvantages of the known laminated panel of a ventilated wall enclosure are the complexity and massiveness of its design and the inability to utilize the heat of the outside air, the heat loss of the building and solar energy, which reduces its reliability and efficiency.

The technical result of the invention is to increase the efficiency and reliability of the heliotherm emission system of power supply of the building.

The technical result is achieved by a heliothermal power supply system of a building, including external fences, externally coated with decorative fencing, a roof covering on the roof supporting structure, a storage unit, and decorative fencing reinforced with contour reinforcement is installed to form an air gap between them and the outer fencing of the building, which communicates with placing the attic through slots, and with outside air through openings located at the bottom of the decorative fencing, the roofing and decorative fencing consist of rectangular sections, each of which is a photothermoelectric converter, consisting of a photocell connected with its back to the outside of the thermoelectric converter housing, the back of which is provided with vertical ribs made of a dielectric material with high thermal conductivity, in the array of which contour reinforcement is placed, consisting of elements of a thermoelectric converter consisting of paired wire segments made of different metals, welded together at the ends, forming zigzag rows arranged in such a way that the left parts of the wire segments with the left soldered ends are bent at an angle of 90 ° and are located close to the outer surface of the thermoelectric converter case without touching it, and the right parts of the wire segments with the right soldered ends are located in the array of ribs, the extreme wire segments of the extreme zigzag rows are thermoelectric iCal converters and the output terminals are connected via respective photocells pole collectors of electric charges from the storage unit.

Figure 1-5 shows the proposed heliothermal power supply system of the building (figure 1 is a General view, figure 2-5 are the main nodes).

The proposed solar thermal power supply system of the building (GTESES) contains external fences 1, a roofing 2 on a roof supporting structure (not shown) and a storage unit 3 placed, for example, on an attic floor 4, and the external fences of building 1 are covered externally with decorative fences 5 reinforced contour reinforcement, with the formation between them and the fence of the building 1 (the connection nodes between the bearing fences 1 and the decorative fences 5 are not shown) of the air gap 6, which communicates with by placing the attic 7 through slots 8, and with outside air through openings 9 located in the lower part of the decorative fences 5, while the roofing 2 and decorative fences 5 consist of rectangular sections 10, each of which is a photothermoelectric converter (FTEP), consisting of a photocell 11 connected with its back to the outside of the thermoelectric converter (TEC) 12, the back of which is provided with vertical ribs 13 made of dielectric material with high thermal conductivity, in the array of which there is a contour reinforcement consisting of elements 14 of TEC 12, which are paired wire segments 15 and 16, made of different metals Ml and M2, welded together at the ends, forming zigzag rows 17, arranged in such a way that the left parts of the wire segments 15 and 16 with the left soldered ends are bent at an angle of 90 ° and are located near the outer surface of the housing of the thermoelectric converter (TEC) 12 parallel to it, without touching it, and the right parts of the wire of the segments 15 and 16 with the right soldered ends are located in the array of ribs 13, the extreme wire segments 15 and 16 of the extreme zigzag rows 17 of TEC 12 and the output terminals (not shown) of the photocells 11 are connected to unipolar collectors of electric charges 18, 19 and 18a, 19a, respectively, which, in turn, are connected to the storage unit 3.

The proposed GTESESZ is based on the property of solar cells 11, when exposed to sunlight, to convert perceived solar energy into electrical and thermal energy [A.S. USSR No. 1603152, IPC F24J 2/32, 1990]. Since the contour reinforcement of the sections 10 of the decorative fence 5 and the roofing 2 is made in the form of zigzag rows 17 made of paired wire segments 15 and 16 made of different metals Ml and M2, welded together at the ends, then when heating (cooling) some the soldered ends of the wire segments 15 and 16 of the elements 14 of the TEC 12 outside and cooling (heating) the opposite of the soldered ends of the elements with air rising in the gaps 6 in the summer (winter time), on the opposite soldered ends of the paired wire Hezk 15 16 elements 14 different temperatures are set, as a result of which thermoelectricity appears in zigzag rows 17 [S. G. Kalashnikov. Electricity. - M .: Nauka, 1970, p. 502-506]. In this case, the zigzag rows 17 in sections 10 simultaneously perform the function of contour reinforcement, increasing the strength properties of the roofing 2 and decorative fences 5.

GTESESZ works as follows. In the summer, outside air enters the air gap 6 between the decorative fences 5 and the external fences 1 through openings 9 located at the bottom of the decorative fences 5 (for example, at the base of the building), and moves along the air gap 6 from the bottom up, while reducing the amount of heat coming from the sun's rays into the building, and cooling the back side of sections 10 of decorative fences 5 (ribs 13 of sections 10, in which are located the right parts of paired wire segments 15 and 16 of elements 14 of TEP 12 with soldered ends and surfaces between the ribs 13), after which this air flow through the slots 8 enters the attic room 7, in which it is washing the back side of the sections 10 of the roof covering 2 (ribs 13, in which are the right parts of the pair of wire segments 15 and 16 with soldered ends and the surface between the ribs 13) and also cools it. In parallel to the above-described process of cooling the right ends of the elements 14 of the TEC 12 outside the sections 10 (FTEC) located on the solar side, in solar cells 11 under the influence of sunlight, solar energy is converted into electrical energy, which is supplied through the terminals (not shown) and collectors 18a and 19a into the storage unit 3, and thermal energy, which due to thermal conductivity enters the TEC 12 sections 10 of decorative fencing 5 and roofing 2 made of a dielectric material with high heat by one. In this case, the TEC material 12 is additionally heated by the heat of the surrounding air, as a result of which intense heating occurs through the heat conduction of the left parts of the wire segments 15 and 16 with the welded ends of the elements 14 of the TEC 12, which are bent at an angle of 90 ° (parallel arrangement of the left parts of the elements 14 relative to the outer surface of the housing TEC 12 is selected from the condition of increasing the contact surface of the segments 15, 16 and increase the structural strength of the sections 10). The ribbed design of the rear side of the sections (FTEP) 10, in the material of the ribs 13 of which the elements 14 of the TEP 12 are placed, ensures their isolation from atmospheric moisture and at the same time significantly increases the heat exchange surface of the section (FTEP) 10 with air moving in the channel 6. Last provides intensive removal of heat generated in the photocells 11 and perceived from the outside air, improving the operation of the photocells 11, increases the temperature difference on the junctions of the elements 14, which increases, respectively, the production of photo and thermoelectricity wa. Simultaneously with the heat transfer process as a result of heating the left soldered ends of the wire segments 15, 16 of the elements 14 of the TEC 12 and cooling their right soldered ends of their temperatures become different and in the zigzag rows 17 there is thermoelectricity, which from the sections (FTEC) 10 through the unipolar collectors of electric charges 18 and 19 enters the storage unit 3, from where it is supplied to the consumer (not shown). The process of electricity generation in sections (FTEP) 10, located in the shade, occurs only due to the heat of the surrounding air, as described above.

In winter, cold outside air also enters the air gap 6 between the decorative fences 5 and the outer fences 1 through the holes 9 located in the lower part of the decorative fences 5, and moves along the air gap 6 from the bottom up, while taking in the heat coming from the outer fences 1 buildings, and heating the back side of sections 10 of decorative fences 5 (ribs 13 of sections 10, in which are the right parts of paired wire segments 15 and 16 of elements 14 of TEP 12 with soldered ends and the surface between the ribs 13), after which the heated air stream through the slots 8 enters the attic room 7, in which it is washing the back side of the sections 10 of the roof covering 2 (ribs 13, in which are the right parts of the pair of wire segments 15 and 16 with soldered ends and the surface between the ribs 13) and also heats it. In parallel with the above-described process of heating the right ends of the elements 14 of the TEC 12 outside the sections (FTEC) 10 located on the sunny side, in solar cells 11 under the influence of sunlight, solar energy is converted into electrical energy, which is supplied through the terminals (not shown) and collectors 18a and 19a into the storage unit 3, and thermal energy, which as a result of contact of the outer surface of the solar cells 11 with the outside air is scattered in it due to convection. In parallel to the above-described process of heating the right ends of the elements 14 of the TEC 12 sections (FTEP) 10 of the decorative fences 5 and the roofing 2, inside the sections 10 under the influence of cold outside air cooling the photocell 11 and the TEC 12 made of a material with high thermal conductivity, cooling by thermal conductivity the left parts of the pair of wire segments 15 and 16 with the welded ends of the elements 14 of the TEC 12, which are bent at an angle of 90 °. At the same time, with the decrease in heat losses of the building as a result of cooling of the left soldered ends of the wire segments of the TEC elements and heating of the right soldered ends of the wire segments of the TEC elements, their temperatures become different and thermoelectricity appears in the zigzag rows 17, which from the sections (FTEC) 10 through unipolar collectors of electric charges 18 and 19 enters the storage unit 3, from where it is supplied to the consumer (not shown). The process of electricity generation in sections (FTEP) 10, located in the shade, occurs only due to the heat loss of the building similar to the above.

The magnitude of the difference in electric potential on the collectors 18a, 19a and 18, 19, the strength of the electric current depends on the characteristics of the solar cells 11, the duration and intensity of solar radiation, the characteristics of the pairs of metals Ml and M2, of which the wire segments 15 and 16 are made, the number of elements 14 in zigzag rows 17 and their number in sections (FTEP) 10, temperature differences at the right and left soldered ends of elements 14 of TEP 12, number of sections (FTEP) 10 in decorative fencing 5 and roofing 2. The resulting electric current can be used Vat for the building lighting, hot water and heating attic.

Thus, the proposed GTESESZ provides both summer and winter time, reducing the heating of the building's external fencing, reducing heat loss from them into the environment, utilizing solar energy, heat and cold air, heat loss of the building to produce electrical energy that can be used to lighting needs, hot water supply and heating of attic rooms (in winter), thereby reducing energy consumption, which, ultimately, increases the efficiency and reliability of the building’s power supply.

Claims (1)

The heliothermal power supply system of the building, including the external fences, externally covered with decorative fences reinforced with contour reinforcement, with the formation of an air gap between them and the building's supporting fences, communicating with the atmosphere through the openings, the roof covering on the roof supporting structure, characterized in that the air gap communicates with by placing the attic through slots, and with outside air through openings located at the bottom of decorative fences, roofing and The corporate fencing consists of rectangular sections, each of which is a photothermoelectric converter, consisting of a photocell connected with its back to the outside of the thermoelectric converter housing, the back of which is provided with vertical fins made of dielectric material with high thermal conductivity, in the array of which a contour is placed fittings consisting of elements of a thermoelectric converter, which are paired olochnye segments made of different metals welded at the ends to each other, forming a zig-zag rows, arranged so that the left portion of wire segments with left soldered ends bent at an angle of ⁹⁰ ° and are located near the outer surface of the housing of the thermoelectric transducer parallel to it, without touching it , and the right parts of the wire segments with the right soldered ends are located in the array of ribs, the extreme wire segments of the extreme zigzag rows of thermoelectric converters and the output s terminal photocells are connected via respective pole collectors of electric charges to the storage unit.

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