RU2822342C1 - Device for converting solar energy into heat - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention relates to a device for converting solar energy into heat. Device is made in form of panel, including frame, in which glass sheet is installed, and heat-insulating layer, and heat-absorbing sheets fixed between them, connected to each other with formation of channels for circulation of heat carrier, note here that said panel comprises branch pipes communicated with heat carrier inlet and outlet channels. Channel is preferably made in the form of a figure in the cross section formed by lateral sides and smaller bases of two isosceles trapeziums conjugated with their larger bases. Ratio of lengths of larger base of trapezoid to smaller base of trapezoid to height of trapezoid is preferably—6:3.2:1. Heat-absorbing sheets are preferably connected to each other by contact welding. Device preferably includes a metal sheet installed in the frame on the side of the heat-insulating layer. Frame and heat-absorbing sheets can be made of steel.

EFFECT: increased efficiency of heat energy accumulation.

5 cl, 4 dwg

Description

The technical solution relates to a roofing panel and flat-plate solar collectors used to store solar energy, used in particular for heating water.

The roof of a pitched roof of a building is known, used as a device for heating water with solar energy. The roof is made in the form of a tank in the shape and size of the pitched roof of the building and consists of roofing modules made of fiberglass, which are connected to each other using connecting elements. The roof contains a filling fitting for pumping water into a reservoir assembled from roofing modules, in which it is distributed among the roofing modules. Patent in the Russian Federation No. 199621, published 09.09.2020.

Known photovoltaic bitumen shingles, which are photovoltaic asphalt roofing tiles, which consist of a bitumen base attached to a photovoltaic module, and the bitumen base consists of a bitumen layer with a support of glass film impregnated with oxidized bitumen and bitumen self-adhesive mastic; and the photovoltaic module comprises at least one three-junction amorphous silicon solar cell and electrical connecting means. Patent in the Russian Federation No. 2493338, published on September 20, 2013.

A power supply device is known that contains several energy panels made in the form of roofing tiles, which cover part of a building, and each of which contains an energy module used for absorbing solar energy, connected to a power supply line. On one of the outer sides of the building there is at least one metal pipeline on which energy panels are installed, which are mechanically and thermally connected to the pipeline, in which a cable channel is provided for housing the power supply line and at least one channel for the passage of a liquid heat transfer medium, with the help of which thermal energy is transferred from the energy panel to the thermal energy consumer. Patent in the Russian Federation No. 2464670, published on October 20, 2012.

A solar thermal collector is known for removing heat from a solar photovoltaic panel, containing parallel channels for the passage of coolant, coolant inlet and outlet. The collector body is made of heat-insulating material, while the role of the collector housing cover is played by the hot surface of the electric solar panel adjacent to the parallel channels with the coolant. Patent in the Russian Federation No. 210191, published 03/31/2022.

Existing designs of solar collectors are characterized by the transfer of heat from the heat-receiving surface to the coolant flowing in the tubes, while the tubes with the coolant are connected to the heat-receiving surface, usually by a solder connection.

The thermal conductivity of soldered joints is largely determined by the thermal conductivity of the solder, especially when its chemical affinity to the soldered metal is weak. In the case of the formation of solid solutions between them, the thermal conductivity of solder joints may decrease compared to the thermal conductivity of solder, and it should be noted that the thermal conductivity of solders and soldered joints is an important parameter for the transfer of heat from a heated heat-receiving surface to the coolant, that is, intense heat transfer is a determining factor characteristic of the efficiency of the solar collector, and the presence of a solder joint reduces the efficiency of the solar collector, since it has a thermal conductivity coefficient different from the metal of the tubes and the heat-receiving surface.

Considering that the spectral radiation density of a body depends only on the temperature of a given body, increasing the efficiency of heat transfer from the heat-receiving surface to the coolant and accelerating it, the temperature of the heat-receiving surface decreases, which, in turn, reduces the radiation of both the heat-receiving surface and the entire heating roofing system (solar tiles), which increases the efficiency of the entire system.

The technical result of the proposed technical solution is to increase the efficiency of thermal energy storage.

Increasing the efficiency of thermal energy storage is achieved, in particular, due to the possibility of converting solar energy into heat in the maximum volume, without significant heat losses associated with the transfer of heat to the coolant, as well as due to the possibility of preserving the accumulated heat as a result of conversion until its further use for heat exchange with heat accumulator.

The technical result of the proposed technical solution is also to ensure the durability of the device.

The claimed technical result is achieved in that a device for converting solar energy into heat, made in the form of a panel, includes a frame in which a sheet of glass is installed, and a heat-insulating layer, and heat-receiving sheets fixed between them, connected to each other to form channels for coolant circulation , wherein the panel includes pipes connected to channels for the inlet and outlet of the coolant, and the channel is made in the shape of a figure, in cross section formed by the lateral sides and smaller bases of two isosceles trapezoids, conjugated by their larger bases.

Making the device for converting solar energy into heat in the form of a panel, including a frame in which a sheet of glass and heat-receiving sheets are installed, connected to each other to form channels for coolant circulation, ensures maximum transfer of solar radiation energy for heating the coolant with minimal heat loss. Due to the fact that the walls of the channels are the heat-receiving sheets themselves, heat transfer is carried out directly, thus, there is no factor influencing the decrease in coolant temperature associated with the thermal conductivity of the material through which this transfer occurs.

The glass sheet in the described design performs a protective, heat-insulating and light transmitting function.

The thermal insulation layer installed on the back side of the heat-receiving sheets provides thermal insulation of the channels with the coolant, excluding further transfer of its heat, allowing it to be stored in the volume of the panel or panels, with subsequent transfer for heat exchange with the heat accumulator.

The coolant inlet and outlet pipes provide circulation of the heated coolant for its subsequent heat exchange with the heat accumulator.

Making the channel in the shape of a figure, in cross section formed by the lateral sides and smaller bases of two isosceles trapezoids, conjugated by their larger bases, provides free thermal expansion and compression of the material of heat-receiving sheets (metal), which significantly reduces fatigue stresses in the structure and increases the safety margin, and also ensures an optimal heat transfer coefficient from the heat-receiving surface to the coolant volume placed in the channel, both in the case of forced circulation and convective heat exchange.

Preferably, the ratio of the lengths of the larger trapezoid base to the smaller trapezoid base to the height of the trapezoid is - 6:3.2:1. These parameters were determined by mathematical modeling methods as providing the most efficient heat transfer from the heat-receiving sheets to the coolant, as well as characterizing the structure with the greatest safety margin and maximum reduction in fatigue stress, which ensures the durability of the product.

The claimed channels are preferably made by stamping heat-receiving sheets, and the sheets are connected to each other by contact welding. This connection eliminates heat loss associated with the thermal conductivity of the solder, increasing the efficiency of heating the coolant, and also characterizes the device with durability due to increased reliability and tightness of the contact between the sheets.

Making heat-receiving sheets from steel, due to its high thermal conductivity, and at the same time the strength necessary to maintain the shape of the channels and the integrity of the structure, also contributes to the most efficient heat exchange with the coolant.

It is preferable to make a panel with an area of 0.25 to 0.5 square meters when used as a heating tile and 2 square meters for use in a flat-plate solar collector. Making a heat-receiving panel less than 0.25 square meters when used as a heating tile will not provide heating of the coolant from solar radiation due to the low flow of coolant through the panel. A panel larger than 0.5 square meters when used as a heating tile may be inconvenient for installation on a roof. Using a 2 square meter panel as a flat solar collector will ensure optimal water heating for average needs.

The claimed technical solution is further explained with the help of figures, which show one of the possible options for its implementation.

In fig. Figure 1 conventionally shows a diagram of the operation of a flat solar collector with the described heat-receiving panel for converting solar energy into heat and accumulating heat in its premises.

In fig. Figure 2 shows a top view of a device for converting solar energy into heat.

In fig. 3 shows a cross-sectional view A-A of a device for converting solar energy into heat.

In fig. Figure 4 shows a three-dimensional cross-sectional view of a device for converting solar energy into heat.

The following elements are indicated by numbers:

- panel (1);

- pump (2);

- heat accumulator (3);

- heat absorbing sheet (4);

- metal sheet (5);

- channels (6) for coolant circulation (8);

- pipe (7) for coolant inlet (8);

- pipe (9) for coolant outlet (8);

- thermal insulation layer (10);

- sheet (11) of glass.

Below, with reference to the figures, a preferred embodiment of the claimed technical solution is described.

The device for converting solar energy into heat is made in the form of a roofing panel (1) or a flat solar collector and includes a frame in which a glass sheet (11) and a heat-insulating layer (1) are installed, and heat-receiving sheets (4) fixed between them, connected with each other to form channels (6) for coolant circulation (8).

Panel (1) includes pipes (7), (9) connected to channels (6) for coolant inlet and outlet (8).

In the preferred embodiment, the channel (6) is made in the shape of a figure, in cross section formed by the lateral sides and smaller bases of two isosceles trapezoids, conjugate with their larger bases. The ratio of the lengths of the larger trapezoid base to the smaller trapezoid base to the height of the trapezoid is preferably - 6:3.2:1.

Preferably, the heat-sensing sheets (4) are connected to each other by resistance welding.

The panel (1) may also include a metal sheet (5) installed in the frame on the side of the thermal insulation layer (10).

The panel frame (1) can be made with grooves to accommodate the end parts of the glass sheet (11), the heat-insulating layer (10) and the heat-receiving surfaces, and includes elements in the form of bends to prevent contact between the glass sheet and the heat-receiving surfaces, and between the metal and thermal insulation layers.

The frame and heat absorbing sheets can be made of steel.

Preferably the panel is made with an area of 0.25 to 0.5 square meters. It is preferable to make a panel with an area of 0.25 to 0.5 square meters when used as a heating tile and 2 square meters for use in a flat-plate solar collector.

An example of the operation of a device for converting solar energy into heat is presented below.

The heat-receiving surface as part of a flat solar collector or heating tiles is installed on the roof of the building and is preferably connected through its nozzles to similar coatings.

Coolant (8) with a low temperature, for example, through a pump (2), is supplied through the pipe (7) for the coolant inlet (8) into the channel (6) of the panel (1). Next, the coolant (8) passes through all the panels (1), which are solar collectors, due to which it is heated, after which it exits through the pipe (9) for the coolant outlet (8) and is supplied to the heat accumulator (3), in particular, to the reservoir with water, heat exchange with which ensures heating of water in the tank. Meanwhile, having given up its heat in a similar cycle, the coolant (8) again enters through the corresponding pipe (7) into the roofing panel for further circulation.

Water heated by the sun is accumulated in a tank and then used at any time as needed.

The presented panel (1) can be used as a solar heating tile to efficiently heat indoor water.

The presented figures, the description of the design of the device for converting solar energy into heat and the method of its use do not exhaust the possible design options and do not in any way limit the scope of the proposed technical solution. Other options for execution and use are possible within the scope of the claimed formula.

Claims (5)

1. A device for converting solar energy into heat, made in the form of a panel, including a frame in which a sheet of glass is installed, and a heat-insulating layer, and heat-receiving sheets fixed between them, connected to each other to form channels for coolant circulation, and the panel includes branch pipes connected to the channels for the inlet and outlet of the coolant, characterized in that the channel is made in the shape of a figure, in cross section formed by the lateral sides and smaller bases of two isosceles trapezoids, conjugated by their larger bases. 2. A device for converting solar energy into heat according to claim 1, characterized in that the ratio of the lengths of the larger base of the trapezoid to the smaller base of the trapezoid to the height of the trapezoid is 6:3.2:1. 3. A device for converting solar energy into heat according to claim 1, characterized in that the heat-receiving sheets are connected to each other by resistance welding. 4. A device for converting solar energy into heat according to claim 1, characterized in that it includes a metal sheet installed in the frame on the side of the thermal insulation layer. 5. A device for converting solar energy into heat according to claim 1, characterized in that the frame and heat-receiving sheets are made of steel.