MD908Z - Absorber for solar collector - Google Patents

Abstract

The invention relates to the field of solar engineering and can be used in solar collectors for water heating and thermal energy production.The absorber for solar collector comprises three troughs, each consisting of a portion in the form of a circular arc in section (4), fixed between them with the convex part directed inward along longitudinal lines (5) with the formation of a channel (9) for circulation of the thermal agent, and side portions, made at the level of the lines (5). The side portions of the adjacent troughs (4) are fixed between them with the formation of longitudinal ribs (10), placed at an angle of 120° relative to each other.

Description

The invention relates to the field of solar technology and can be used in solar collectors for heating water and producing thermal energy.

The absorber panel for the flat solar collector is known, which is made of aluminum profile, to which a copper pipe for the circulation of the thermal agent is mounted from the back in the hole of the profile channel [1].

The disadvantages of this absorber panel are that the incidence at high angles of direct sunlight or ambient light on the flat surface of the absorber panel leads to low absorption values of incident radiation fluxes, and the process of manufacturing the absorber panel does not ensure adequate thermal contact between the copper pipe and the aluminum profile.

The absorber panel for the flat solar collector is known, which includes a surface for absorbing incident solar radiation, the channel through which the heated thermal agent circulates in the form of a metal pipe, which is placed behind the thin metal corrugated foil or sheet, in which the heat transfer to the heated thermal agent in the channel is done through thermal bridges, which have rigid mechanical and thermal contacts with the tips of the corrugated foil and with the pipe with the heated thermal agent [2].

The disadvantage of this absorber panel is the reduced heat transfer surface from the corrugated foil through the thermal bridges made of small-diameter wire and the outer surface of the pipe (channel) with heated heat carrier. The corrugated aluminum or copper foil has a thickness of 0.03 mm and a length of 1250 mm, which creates great difficulties in forming rigid mechanical and thermal contacts with the tips of this foil, as well as in ensuring the mechanical rigidity of the structural element formed by the corrugated foil. At the same time, the formation of thermal contacts of the wire thermal bridges with the corrugated tips of the foil presents a very difficult technological problem, which undoubtedly increases the cost of such solar collectors, since it is necessary to make hundreds of thermal contacts with the corrugated foil.

The closest solution is the absorber panel of the flat solar thermal collector, consisting of two interconnected corrugated plates, which together form the circulation channels of the heated thermal agent, which have the shape of pipes consisting of two semi-cylindrical sheet metal surfaces with longitudinal external horizontal ribs, which together with the half-surface of the channel form the surface for absorbing the energy of the incident solar flux. The flat portions and horizontal ribs have mechanical contact points in the middle of the flat parts of the absorber elements. The size of the absorber panel in the solar thermal collector between the contact points of the flat portions determines the surface for absorbing (capturing) solar energy and has an impact on the mechanical rigidity of the collector [3].

The disadvantages of this solution consist in the reduced capacity to absorb the heat of the incident solar flux due to the small area of the absorbing surface and the low efficiency of lateral irradiation, as well as the small value of the ratio between the absorbing surface and the volume of the heated thermal agent in the pipe of the absorbing panel, which influences the dynamics of the heating process of the thermal agent.

The problem that the present invention solves consists in increasing the capacity and uniformity of absorption of solar radiation throughout the day without tracking the sun.

The absorber for the solar collector includes three gutters, each with a circular arc-shaped portion in section, fixed to each other with the convex part directed inward along longitudinal lines with the formation of a channel for the circulation of the heat carrier, and with side portions, made at the level of the lines. The side portions of the adjacent gutters are fixed to each other with the formation of longitudinal ribs, located at an angle of 120° to each other. The side portions of the gutters can be made at an angle of 30° to the chord of the circular arc-shaped portion of the gutters.

This combination of elements ensures the conditions for uniform absorption of solar radiation by the absorber, due to the fact that it includes three longitudinal ribs located at an angle of 120°. One rib of the absorber is oriented towards the zenith. As a result, at small angles of incidence of the solar radiation flux, the energy is absorbed by the rib oriented in the plane of the zenith point section. When the sun rises, the rate of flux absorption by the ribs located at angles of 120° to the longitudinal rib oriented towards the zenith increases. When reaching the zenith position, the energy is absorbed only by the ribs located at an angle of 120°. When passing the zenith point, the share of energy absorbed by the rib oriented towards the zenith begins to increase again. Thus, during the day, a redistribution of the shares of the radiation flux captured between the longitudinal ribs of the absorber occurs. As a result, the amplitude of the variation of the captured power of the radiation flux does not exceed the value of 0.067, while in the case of the closest solution this variation of the average power constitutes about 0.36 of the maximum value of the power when the sun is at the zenith.

The invention is explained by the drawings in Fig. 1-7, which represent:

- Fig. 1, diagram of the absorber for the solar collector, cross-section;

- Fig. 2, diagram of the absorber for the solar collector with the angle of the arc-shaped portion of the gutter greater than 60° and less than or equal to 180° with indication of the longitudinal ribs;

- Fig. 3, diagram of the absorber for the solar collector with the angle of the arc-shaped portion of the gutter greater than 60° with indication of the longitudinal ribs executed at an angle of 30° to the chord of the arc-shaped portion of the gutters;

- Fig. 4, the geometric diagram of the gutter with the lateral portion made at an angle of 30° to the chord of the arc-shaped portion of the gutters;

- Fig. 5, diagram of making the absorber for the solar collector by cutting six gutters from the pipe with diameter D;

- Fig. 6, diagram of making the absorber for the solar collector by cutting three gutters from the pipe with diameter D;

- Fig. 7, diagram of making the absorber for the solar collector by cutting two gutters from the pipe with diameter D.

The absorber for the solar collector includes three gutters, each with a circular arc-shaped portion in section 4, fixed to each other with the convex part directed inward along longitudinal lines 5 with the formation of a channel 9 for the circulation of the heat carrier, and with side portions, made at the level of the lines 5. The side portions of the adjacent gutters 4 are fixed to each other with the formation of longitudinal ribs 10, located at an angle of 120° to each other. The dimensions of the longitudinal ribs 10 are determined by the central angle of the side portion 7 and the distance between the longitudinal lines 5 and the edge of the gutter 2. The side portions of the gutters can be made at an angle of 30° to the chord of the circular arc-shaped portion of the gutters.

The absorber for the solar collector works as follows.

In the morning the sun is to the left of the absorber, which is positioned so that the vertical longitudinal rib 10 is oriented towards the zenith (see fig. 1). The sun during this period of the day is also to the left of the absorber shown in fig. 2 and 3. In this position, the solar radiation flux is absorbed by the illuminated surface on the left of the vertical plane of symmetry of the absorber, namely by the arc-shaped portion in the section 4 of the trough, which forms the channel 9 for the circulation of the heated heat carrier of the absorber. The heat absorbed by this portion is transmitted to the heat carrier, which circulates through the channel 9. From the channel 9 the heated heat carrier is transmitted to the consumer. This process continues until the moment corresponding to the passage of the sun past the zenith point. After the sun passes the zenith point, the solar radiation is absorbed by the arc-shaped portion in section 4 of the gutter, which forms the channel 9 of the absorber, located to the right of the section plane passing through the zenith point (see Fig. 1). The sun during this time of day is located to the right of the vertical plane passing through the zenith point and the absorber shown in Fig. 2 and 3. The heat absorbed by the surface of section 4 located to the right of the vertical plane passing through the zenith point and the longitudinal rib coinciding with this plane is transmitted to the heat carrier, which circulates through channel 9. From channel 9, the heated heat carrier is transmitted to the consumer. The fixing of sections 4 along lines 8 ensures the mechanical rigidity of the absorber construction. The displacement of the fixing lines 8 from the channel 9 of circulation of the heat carrier ensures the protection of the absorber construction when the volume of the heat carrier changes due to the variation of its temperature, for example as a result of its freezing. The lines 5 represent the boundaries of the channel 9 with the heat carrier. In various positions of the sun on the celestial vault on the portions 4 there are areas where the sun's rays fall perpendicularly. As a result, a high degree of uniform absorption of the radiation of the incident light flux is ensured throughout the day, which also ensures the solution of the problem of the invention.

In the proposed absorber intended for use in the flat solar thermal collector, the aforementioned disadvantages are eliminated by modifying the constructive design of the absorber regarding the formation of the circulation channel 9 of the heat carrier and the solar radiation absorption surface and the spatial location of the ribs 10, which ensures an increase in the solar energy absorption surface, including for large values of the lateral solar irradiation angle. The absorber is made of three troughs, each with a circular arc-shaped portion in section 4, which have the arc length , where is the angle of the circular arc-shaped portion, R - the radius of the circumference of the cross-section of the pipe with diameter D. The troughs are made by cutting the pipe with diameter D on the line, which represents the edge of the trough 2. Six, three or two troughs can be made from a pipe with diameter D. The absorber is manufactured by rigidly fixing three gutters, which are mounted with the convex surface facing inwards and the concave surface facing outwards. The gutters are mounted and fixed in the absorber by gluing, welding or gluing along the longitudinal lines 5. When three gutters are mounted and their rigid mechanical fixing along the lines 5, the circulation channel 9 for the thermal agent is formed, which in cross section has the shape of an equilateral curvilinear triangle. The length of the side of this curvilinear triangle is equal to the length of the arc-shaped portion of a circle with an angle equal to 60°. The concave surfaces of two gutters, which are oriented outwards, represent the solar radiation absorption surfaces, and their chords form an angle of 60°. The third gutter represents the back of the absorber and its surface facing outwards is not exposed to the sun's rays, as it is shaded by the first two gutters with external surfaces absorbing solar radiation. If three gutters are made from the pipe with diameter D, when they are mounted in the absorber, three longitudinal ribs 10 are formed by the lateral portions of the gutters. If three gutters are cut from the pipe, the angle of the arc-shaped portion is 120°, and when only two gutters are made from the pipe, this angle is equal to 180°. When three gutters are mounted, the lines 5 will always coincide with the edges of the arc-shaped portions of the gutter with an angle equal to 60°. The portions of the surface of the gutters for which the angle is greater than 60° contribute to increasing the surface of absorption of solar radiation, as a result of the formation of the longitudinal ribs 10 of the absorber. At the same time, the longitudinal ribs of the absorber formed by the gutters contribute to increasing the mechanical rigidity of the absorber. The mechanical rigidity is ensured by the longitudinal ribs 10 and by the shape of the channel 9. One of the gutters of the absorber is shaded from solar radiation by two others, which are intended to absorb this radiation, since they are oriented towards the sun. In order to reduce heat losses, the concave surface of the shaded gutter is covered with thermal insulation material. The spatial orientation of the longitudinal ribs 10 forms the symbol of an inverted Y. Increasing the height of the ribs 10 by increasing the angle of the arc-shaped portion of the trough above 60° ensures an increase in the absorption surface without increasing the cross-sectional area of the channel 9. This constructive embodiment of the absorber with longitudinal ribs 10 contributes to increasing the ratio of the absorption surface area to the volume of the heat carrier in the channel 9.

The absorber can be made of metal sheet gutters and gutters made of optically transparent material, but with obvious properties of thermal insulation material. Gutters made of thermal insulation material have the same geometric profile or one identical to the profile of metal sheet gutters. The concave surfaces of metal sheet gutters can be covered with a selective absorbing layer, which contributes to increasing the absorption performance of incident solar radiation. Gutters made of thermal insulation material line the absorber made of metal sheet and thus ensure the reduction of heat losses due to thermal convection processes by increasing the value of the thermal resistance coefficient of the absorber. The thermal insulation gutter shaded by the solar radiation-capturing gutters can also be made of optically non-transparent material. There are no special requirements for the thermal insulation material regarding the rigidity to ultraviolet radiation, because it is shaded by the thermally conductive absorption surfaces made of metal. This leads to an increase in the efficiency of solar energy absorption and its transfer to the thermal agent, which has direct contact with the channel walls, as a result of the reduction of convection losses of thermal energy on the absorber surface.

The absorber with the spatial configuration of the inverted Y symbol can be provided with an envelope of optically transparent material. This envelope is made, for example, by wrapping the absorber with a film of transparent plastic or other material, for example glass, which is rigid for the ultraviolet component of the sunlight spectrum, so it is stabilized. Providing the absorber with a transparent envelope for solar radiation leads to an increase in the efficiency of the absorber as a result of the reduction of convection losses of the thermal energy provided by the envelope.

The increase in the capacity and uniformity of solar energy absorption of the absorber throughout the day without tracking the sun is conditioned by the fact that the absorber is made of three cylindrical troughs mounted with the concave solar energy absorption surfaces on the outside, and with the convex surfaces on the inside, forming a geometric figure similar to the inverted Y symbol with the vertical longitudinal rib oriented towards the zenith. In the center of the inverted Y figure is the channel 9 for the heat carrier with the cross-sectional area of the curvilinear triangle formed by the arc-shaped portions of the gutter equal to 60°, and the lateral portions of the gutters corresponding to the angles ( -60°)/2 form three longitudinal ribs 10 located at equal angles, where is the angle of the arc-shaped portion of the gutter, made by cutting the pipe with diameter D. The value of this angle is within the limits of 60° < 180°, and the most reasonable values from the point of view of the use of consumable material in the manufacture of the absorber are considered to be the values of the angles equal to: =120° and =180°.

The increase in the efficiency of the heat transmitted to the thermal agent circulating through channel 9 of the absorber with longitudinal ribs 10 is ensured thanks to the direct thermal contact of the thermal agent with the heat transfer surface, and the reduction in the heating time of the thermal agent is ensured by the higher value of the ratio of the absorption surface to the volume of the thermal agent in channel 9.

Increasing the efficiency of the absorber is also ensured by placing it in an envelope made of optically transparent thermal insulation material, for example, by wrapping the absorber with a plastic film, which reduces heat convection losses on the outer surface of the absorber, or by lining the metal absorber with gutters of the same shape, made of plastics with low thermal conductivity, of which two lining elements covering the concave absorption surfaces are optically transparent.

Simplification of the construction and manufacturing technology, as well as increasing the mechanical rigidity of the absorber as a result of the stresses caused by phenomena http://natural..dc/exempul, low temperatures, is achieved by using gutters with a broken line cross-sectional profile, in which the lateral portions of the gutters can be made at an angle of 30° to the chord of the arc-shaped portion of the gutters.

The result of the invention is to increase the efficiency of the absorber without tracking the sun. The use of concave surfaces for absorbing solar radiation, as well as the inclusion in the absorber construction of three longitudinal ribs 10 located at an angle of 120° to each other, contributes to a much smaller variation of the solar flux captured by the absorber depending on the position of the sun on the celestial vault. The installation of three troughs with convex surfaces inside when making the absorber ensures a better ratio of the solar radiation absorption surface to the volume of the heated thermal agent in the circulation channel 9. This contributes to improving the heat transfer conditions in the proposed absorber in comparison with the closest solution, as well as reducing the heating time of the thermal agent. This ensures the intensification of heat transfer processes in the proposed absorber. The proposed solution for the constructive realization of the absorber also ensures the simplification of the production technology of these components used in solar collectors, because the absorber can be made of standard elements made of thin metal strips by bending their side portions at an angle of 30°. The fixing of the gutters and the sealing of the channel 9, through which the thermal agent circulates in the absorber, is done by local welding on the longitudinal line 5, which determines the inner boundary of the longitudinal rib, therefore on the bending line of the side portions of the gutters or by moving this gutter fixing line to the periphery of the longitudinal ribs. This manufacturing solution excludes damage to the absorber when it is mounted in the solar collectors. Due to this property, the reduction of operating costs and losses of thermal agent during its pouring and leakage depending on the season is ensured. Forming a tire by wrapping an optically transparent film on the longitudinal ribs of the absorber makes it possible to reduce heat loss through convection, as well as increase the thermal efficiency of the absorber with minimal costs and technological efforts.

Also, the result of the invention is that the absorber allows obtaining a uniform characteristic of the absorption of the solar radiation flux energy throughout the day for all positions of the sun on the celestial vault. This is impossible for flat solar thermal collectors, because in order to ensure uniform capture of solar radiation throughout the day, it is necessary for the absorption surface to follow the sun.

For example, for the absorber geometry with the equivalent value of the absorption surface for the case of the equilateral triangle profile oriented with one vertex of the triangle at the zenith, which also presents the similar section of the absorber, the maximum deviation of the solar radiation flux absorbed during the entire day does not exceed 14% of the maximum possible absorption value by a flat surface, which follows the sun. As a result of the harmonic nature of the evolution of the absorbed solar radiation flux, the absorber will absorb about 93% of the maximum value characteristic for the case of the sun's positioning at the zenith and the respective orientation of the absorber.

For flat collectors, the daily average of the absorbed energy power is 0.637 of the solar radiation flux value at the zenith position of the sun. For the proposed absorber, the amplitude of the oscillations of the absorbed flux during the day is at the level of 0.067 of the solar radiation flux amplitude at the zenith position, while for the case of the absorber with a flat surface and the installation of the heat transfer medium circulation pipe behind this capture surface, in the absence of sun tracking actions, the value of the captured solar radiation power varies from zero to the maximum value characteristic for the positioning of the sun at the zenith point.

Since during the day there are three periods of oscillation of the magnitude of the radiation flux absorbed by the proposed absorber, the average value of the absorbed solar radiation flux is 0.933 of the maximum value. For these reasons, the proposed absorber will have a higher efficiency of capturing solar radiation during a day compared to the absorber according to the closest solution. Quantitatively, this efficiency is characterized by the following ratio: (0.933/0.63)=1.465. So, the absorbers made based on the proposed solution ensure an increase of over 46% of the capacity to absorb solar radiation during the day compared to the absorbers used in flat solar thermal collectors.

The possibility of making absorbers from thin metal strips by bending the side portions at a 30° angle simplifies the manufacturing technology, ensuring a good ratio between the solar radiation absorption surface and the volume of the heated thermal agent.

The totality of the indicated features of the proposed technical solution for the constructive realization of the absorber ensures the solution of the problem of increasing the uniformity of absorption of solar radiation throughout the day without tracking the sun.

1. RU 2177129 C1 2001.12.20

2. RU 2461782 C1 2012.09.20

3. RU 2272969 C2 2006.03.27

Claims (2)

1. Absorber for the solar collector, which includes three gutters, each with a portion in the shape of an arc of a circle in section (4), fixed to each other with the convex part facing inward along longitudinal lines (5) with the formation of a channel (9) for the circulation of the thermal agent, and with lateral portions, made at the level of the lines (5), at the same time the lateral portions of the adjacent gutters (4) are fixed to each other with the formation of longitudinal ribs (10), placed at an angle of 120° to each other. 2. Absorber for the solar collector according to claim 1, wherein the lateral portions of the gutters (4) are made at an angle of 30° to the chord of the arc-shaped portion of the gutters (4).