RU2145045C1 - Liquid solar heater - Google Patents

Abstract

FIELD: household washing units, shower sets, hot-water supply systems of buildings. SUBSTANCE: solar heater has liquid-filled tank with inlet and outlet branch pipes, overlaid with one or two layers of optically transparent insulation (glass or cellophane) from side of falling sun rays positioned with air gap relative to surface of tray floating in tank, facing it and absorbing energy of sun rays. One or several perforated flanges with pipe connections are installed on tray bottom surface which contacts liquid. Inlet end of flexible hose is set on every pipe connection, and outlet end of hose is coupled to at least one of outlet branch pipes of tank. EFFECT: higher rate of liquid heating. 6 cl, 2 dwg

Description

 The present invention relates to solar technology, in particular, to a device for heating liquid (water) with solar radiation energy, used mainly in household washing units, shower units for summer and farm estates. The device can also be used in hot water systems of buildings and special facilities, as well as for heating rooms with liquid heat carriers, including water.

 Known solar liquid heater containing a thermally insulated liquid filled tank with inlet and outlet nozzles, blocked from the side of incident sunlight by one or more layers of optically transparent insulation. The heat-absorbing surface of the tank facing the sun, which acts as a converter of energy of optical radiation into heat, is blackened or coated with a layer of material selectively absorbing optical radiation / 1 /.

 The disadvantages of the described water heater are due to the fact that its effective operation is possible only when the tank is completely filled with liquid, that is, under conditions of its continuous flow under pressure, which limits the effective use, for example, in domestic washing units, in hot water systems of buildings and other applications due to the formation during operation of an air gap separating the surface of the transducer heated by the sun from the surface of the water.

 Known solar liquid heater / 2 /, selected by us as a prototype, containing a thermally insulated tank filled with liquid with inlet and outlet pipes, blocked from the side of the sun by one or more layers of insulation transparent to the sun, located with an air gap relative to it and absorbing the energy of sunlight on the surface of a baking sheet floating in a tank made of a heat-conducting material with a blackened inner surface.

 The disadvantages of the prototype are due to the formation of a temperature gradient between the conductively heated layer of liquid adjacent to the bottom of the floating pan and the layer of colder liquid at the bottom of the tank, from where it is selected through the lower outlet pipe, which increases the heating time of the liquid.

 The aim of the invention is the creation of a solar fluid heater of increased efficiency with an increased heating rate of the consumed fluid.

 This goal is achieved by the fact that in the solar heater the liquid filling the tank with inlet and outlet nozzles, closed on the side of the incident sunlight by at least one layer of optically transparent insulation, located with an air gap relative to it and absorbing the energy of the sun's rays, the surface of the floating the baking sheet tank, on the liquid contact surface of the bottom of the baking sheet in contact with the liquid or near it, an open inlet end of a flexible hose is installed, the opposite outlet end of which It is connected to at least one of the outlet pipes located at the bottom of the tank.

 The goal is also achieved by the fact that the open inlet end of the flexible hose is mated through a fitting with a permeable liquid permeable flange mounted and secured to the surface of the bottom of the pan contacting the liquid.

 The goal is achieved by the fact that a perforated flange with a fitting and a flexible hose attached to it is installed on the outer surface of the bottom of the floating pan with an offset relative to the longitudinal axis of the outlet pipe mounted on the outside of the bottom of the tank.

 Another means of achieving the goal is that the outlet pipe mating with the bottom of the tank is equipped with a fitting protruding into the inner cavity of the tank and connected to the output end of the flexible hose.

 The achievement of the technical result also contributes to the fact that the flexible hose is made in the form of at least one coil of a spiral located in the volume of liquid.

 And, finally, another way to achieve a technical result is that two, three or more perforated flanges with fittings connected to the inlet ends of the flexible hoses, the outlet ends of which are connected to one or more lower outlet nozzles of the tank.

 The proposed embodiments of the solar fluid heater according to the invention are presented in the drawings.

 FIG. 1. Solar fluid heater with one perforated flange and a flexible hose, side view, partially in section.

 FIG. 2. Solar fluid heater with three perforated flanges, flexible hoses and outlet pipes, side view, partially in section.

 Shown in FIG. 1 and 2, the solar liquid heater is made in the form of a rectangular heat-insulated tank 1, filled with liquid 2, for example water. The tank has an inlet pipe 3 with a shut-off valve and two, three (see Fig. 2) or more output pipes 4 and 5 located in the upper and lower parts of the tank, one of which (for example, the upper pipe 4) can be used for drainage liquid when the tank is full, and pipe 5 is for continuous or discrete consumption (drain) of the heated liquid.

 The outlet pipe 5 also has a shut-off valve 6 and can be paired with a retina nozzle 7 or a hose nozzle (not shown in FIG.), Forming a shower unit.

 The tank 1 is made of a suitable plastic or sheet metal, for example stainless steel. The outer walls of the tank are covered with an insulating layer 8 (insulation).

 From the side of the incident sun rays 9 (shown by arrows), the tank 1 is blocked by at least one layer of insulation 10 transparent to optical rays, for example, sheet glass or cellophane. This insulation layer 10 forms an air gap 11 with the surface 12 of the baking sheet floating in the tank 13 facing the insulation. The surface 12 of the baking sheet 13 is coated with a ray-absorbing material, for example black paint (without gloss), which absorbs the energy of sunlight and contributes to the efficient heating of the bottom of the baking sheet 13.

 On the liquid-contacting surface of the bottom surface of the pan 13 made of light heat-conducting material, for example, aluminum or its alloys, or near it, an open inlet end 14 of the flexible hose 15 is installed, the opposite outlet end of which is connected to at least one outlet pipe 5 of the tank 1.

 In the proposed embodiment of the device, the inlet end 14 of the flexible hose 15 is mated through a fitting 16 with a perforated flange 17, which ensures the passage of liquid, mounted and fixed on the bottom surface of the baking sheet 13 in contact with the liquid, for example, by contact welding or by means of epoxy resin.

 The flange 17 with the nozzle 16 is made thin-walled from the same material from which the floating pan 13 is made. The perforated flange 17 with the nozzle 16 and the flexible hose 15 connected to it is installed and fixed on the outer surface of the bottom of the floating pan 13 with an offset relative to the longitudinal axis of the outlet 5 mounted on the outside of the tank 1. In this case, the outlet pipe 5 is also provided with a fitting 18 protruding into the internal cavity of the tank 1, to which the end 19 of the flexible hose 15 is connected.

 The flexible hose 15 is made, for example, of silicone rubber, in the form of at least one coil of a spiral freely positioned in the volume of liquid in the tank 1, thus eliminating the bending and blocking of the hose channel during the drain (consumption) of the liquid and lowering the pan 13 to the extreme lower position in the tank when operating the solar heater.

 The second embodiment of the solar fluid heater (see figure 2) provides for the installation and fixing on the surface of the bottom of the baking sheet 20 in contact with the liquid of two, three or more perforated flanges 21, 22 and 23 with fittings connected to the output ends of the flexible hoses 24, 25 and 26, the output ends of which are connected to two 27 and 28 or a large number of output nozzles of the tank 29. The output nozzles 27 and 28 have one 30 or two 31 and 32 fittings, respectively.

 In addition, in the second embodiment of the solar fluid heater (see FIG. 2), two 33 and 34 transparent layers of optical rays can be used, covering the tank 29 and the pan 20.

 It is advisable to make the insulation layer 33 from window glass, which, along with transmitting solar radiation, provides environmental resistance (rain, snow, dust, etc.) when used in showers, washing units and devices for hot water supply to buildings, and insulation layer 34 - from cellophane or thin window glass (thickness 1.5 - 3.0 mm), excluding convective heat transfer between the blackened bottom of the pan 20 and the environment.

 This embodiment of the device is preferred for use in the design of hot water installations in buildings. It can also be used for a solar water heater in a washing unit, which, in addition to using it as a shower unit, also provides for the autonomous supply of heated water to a traditional sink (wash basin, dishwashing, etc.).

 Heating and consumption of liquids, such as water, using the proposed solar heater is as follows (see figures 1 and 2).

 When filling the tank 1 or 29 with liquid (water) through the inlet pipe 3, for example, from the water supply network, the floating pan 13 or 20 pops up and rises to its highest position in the tank, determined by the level of the upper outlet pipe 4, together with the perforated flange 17 (or flanges 21, 22, 23, Fig. 2) with fittings and inlet ends of the flexible hoses 15, 24, 25 and 26.

The sun's rays 9 pass through an optically transparent layer of insulation 10 (or arrows) for them (or an insulation layer 33 and 34, Fig. 2) and are absorbed on the surface of the floating baking sheets 13 and 20 covered with ray-absorbing material, heating them to a temperature of 70-90 ^o C. Due to the conductive heat transfer and high thermal conductivity of the baking sheet material and the perforated flanges 17, 21, 22, 23 with fittings mounted on them, the energy of solar radiation, converted into heat, is transferred to the adjacent volume of liquid, heating it.

 In this case, due to the overlapping surface of the baking sheets 13 and 20 facing the sun (or the tank) with layers of optically transparent insulation 10, 34 and 33, an air gap 11 is formed, which significantly reduces (see Fig. 2) the convective heat transfer of the bottom of the baking sheets 13 or 20 with the environment (the "greenhouse effect" appears), which contributes to the rapid accumulation of heat and efficient heating of the liquid adjacent to the baking sheets.

 However, the liquid 2 in the lower part of the tank, where the outlet pipes 5, 27, 28 are located, remains relatively cold for a long time due to unsatisfactory diffusion processes of the heated liquid and insufficient conductive heat transfer.

 The heated liquid adjoining the baking sheets 13 or 20 through the openings of the perforated flanges 17 or 21, 22, 23 and the corresponding fittings with the open tap of the outlet pipe 5 or pipes 27 and / or 28 enters through the flexible hoses 15 or 24, 25, 26 ( stock of heated liquid).

 Thus, the preparation of heated liquid for consumption is significantly reduced both in discrete and continuous flow mode due to the absence of the need to heat the entire volume of liquid in the tank. This advantage allows us to design solar fluid heaters with tanks of increased depth, which is important when using them for hot water supply of buildings.

 In addition, the efficiency of the solar heater is significantly increased due to an increase in the temperature gradient between the bottom of the pan 13 or 20 and the layer of the consumed liquid adjacent to them, due to the mixing of its lower layers with the upper ones at the drain through perforated flanges 17 or 21, 22, 23.

 The heating efficiency of the liquid is also increased due to additional heat transfer from the heated baking sheets 13 and 20 to the volume of the liquid due to the branched (perforated) walls of the flanges and fittings that are in thermal contact simultaneously with the baking sheets and the liquid.

 The use of flexible hoses in the form of at least one coil of a spiral connected by the inlet and outlet ends to the fittings, as well as the displacement of the longitudinal axes of the lower outlet pipe relative to the flanges with fittings, allows the maximum use of the heated volume of liquid when lowering the trays 13 and 20 to the lowest position .

 Thus, the advantages of the proposed device stem from the possibility of a significant increase in operating efficiency and an increase in the heating rate of the consumed liquid both in continuous and in short-term (discrete) operation mode of the solar heater.

Literature:
1. USSR author's certificate N 282819, cl. F 24 J 3/02, 1970

 2. RF patent N 2108520, class. F 24 J 2/04, publ. 04/10/98, Bull. N 10.

Claims (6)

 1. Solar liquid heater, containing a liquid-filled tank with inlet and outlet nozzles, closed from the side of the incident sunlight by at least one layer of transparent insulation for optical rays, located with an air gap relative to the surface of the baking sheet, which is facing it and absorbs energy from sunlight, in the tank, characterized in that on the contact surface with the liquid of the bottom of the specified pan or near it there is an open inlet end of the flexible hose opposite the outlet hydrochloric end of which is associated with at least one disposable in the bottom of the tank outlet fittings.  2. The solar fluid heater according to claim 1, characterized in that the open inlet end of the flexible hose is mated through a fitting with a permeable fluid permeable flange mounted and secured to the bottom surface of the baking sheet in contact with the fluid.  3. Solar fluid heater according to claims 1 and 2, characterized in that the perforated flange with a fitting and a flexible hose connected to it is installed on the outer surface of the bottom of the floating pan with an offset relative to the longitudinal axis of the lower outlet pipe mounted on the outside of the bottom of the tank.  4. Solar fluid heater according to claims 1 to 3, characterized in that the outlet pipe mating with the bottom of the tank is equipped with a fitting protruding into the inner cavity of the tank and connected to the output end of the flexible hose.  5. Solar fluid heater according to claims 1 to 4, characterized in that the flexible hose is made in the form of at least one coil of a spiral located in the volume of fluid.  6. Solar fluid heater according to claims 1 to 5, characterized in that two, three or more perforated flanges with fittings connected to the input ends of the flexible hoses, the output ends of which are connected to one or more, are installed on the surface of the bottom of the pan contacting with the liquid the number of lower outlet nozzles of the tank.

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