RU2366867C1 - Solar module with stationary concentrate - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention concerns heliotechnology and creation of solar modules with photoelectric or heat radiation receivers and stationary concentrators allowing for module operation in stationary mode through the whole year. Solar module with stationary concentrate includes reflecting circular-cylinder side walls of R radius at both sides of the module symmetry plane, delimiting radiation intake plane in concentrator with symmetry plane passing through the plane centre of radiation receiver with two-sided work surface of d width, parallel to intake plane; and secondary circular-cylinder reflectors of r=0.5d radius. In concentrator cross-section, reflecting side walls are shaped along circles of R radius with circle centres located at the intake plane. One end of circle with R radius passes through end points of radiation receiver plane of 2d width, where circles of side walls and secondary reflectors meet and parametrical angle lines pass. Parametrical angles comprise angle γ with the symmetry axis, their crossing points with the intake plane represent second ends of circles with R radius. Central angle of arc with R radius does not exceed 30 angular degrees, and centres of secondary circular-cylinder reflectors are positioned along the radiation receiver edges.

EFFECT: increased radiation concentration at large parametrical angles.

1 dwg

Description

The invention relates to the field of solar technology and for the creation of solar modules with photovoltaic or thermal radiation detectors and stationary concentrators, allowing the modules to be operated in stationary mode all year round.

A known solar module (analogue) with a concentrator (RF patent No. 2191329, publ. 10/20/2002 Bull. No. 29), in which the side wall of the concentrator is made of a reflective circular cylinder, mating with a secondary circular cylindrical reflector mounted under the radiation receiver with a two-sided working surface .

The main disadvantages of this module with a concentrator are that the module must be oriented to the sun, which complicates the design of the solar installation, increases its cost and increases operating costs.

The closest in technical essence to the present invention is a solar module having lateral reflecting circular cylindrical walls of radius R located on both sides of the plane of symmetry of the module, limiting the plane of radiation input into the concentrator, the plane of symmetry of the module passes through the center of the plane of the radiation receiver with a double-sided working surface with a width d and parallel to the entrance plane, and secondary circular cylindrical reflectors of radius r = 0.5d (D.S. Strebkov, E.V. Tveryanovich “Concentrato s solar radiation ", M., it is" Typography Russian Agricultural Academy ", 2007, s.197-198).

The known technical solution in comparison with the known analogue has a higher concentration, a symmetrical working profile of the concentrator, within a limited parametric angle (± 27.5 °) such a module can operate in a stationary mode, which requires its location in space as follows: input plane should be facing the South and located at an angle of latitude to the horizon, and the longitudinal axis of the concentrator should be oriented West-East.

The disadvantages of the prototype are as follows:

- the geometry of the concentrator, determined by the angles α and β, the location of the centers of the radii of the forming circles, assumes the module is stationary in the range of small parametric angles β (± 27.5 °), which implies the use of the module only with a horizontal longitudinal arrangement (the axis of the module is oriented West- East), in this case, forced circulation of the coolant through the radiation receiver is required, which requires pumping equipment and additional pipe fittings, as natural convection will not work;

- the longitudinal axis of the module according to the equatorial scheme (the longitudinal axis is located at an angle of latitude to the horizontal plane) will allow the module to work in stationary mode only within 55 ° (2 × 27.5), which means 3 hours and 40 minutes during daylight hours, which is small and not acceptable.

The task of the invention is to increase the concentration at a parametric angle of ± 60 ° and install the module according to the equatorial scheme with continuous operation in stationary mode.

As a result of using the present invention, it becomes possible to increase the average daily energy production with the possibility of natural convection circulation of the coolant.

The above technical result is achieved by the fact that in the proposed solar module with a stationary concentrator having lateral reflecting circular cylindrical walls of radius R located on both sides of the plane of symmetry of the module, limiting the plane of radiation entry into the concentrator, the symmetry plane passes through the center of the plane of the radiation receiver with a two-sided working a surface of width d and parallel to the entrance plane, and secondary circular cylindrical reflectors of radius r = 0.5d, according to the invention in the cross section of the concentrator, the lateral reflecting walls are made in circles of radius R, the centers of which are located on the entrance plane, one end of the circle of radius R pass through the extreme points of the plane of the radiation receiver with a width of 2d, in which the circles of the side walls and secondary reflectors are connected, and through which the lines of parametric angles making up the angle γ with the axis of symmetry, the intersection points of which with the entrance plane are the second end of the circles of radius R, and the central angle of the arc of radius R is no more than 30 angular degrees, and the centers of the secondary circular cylindrical reflectors are located at the edges of the radiation receiver.

The centers of the side reflectors having circle-shaped radii of radius R are located on the radiation inlet plane on opposite sides of the symmetry plane, with the central opening angle of each side wall having an angle β≤30 °.

The centers of the radii of the secondary reflectors are located at the edges of the radiation receiver.

The generators of the side walls and secondary reflectors are not mating surfaces, the circles of the secondary reflectors have end points on the plane of the radiation receiver.

The lines of parametric angles defining the angle of view of the concentrator are drawn from the extreme points of the entrance plane through the plane of symmetry to the extreme points of the plane of the radiation receiver.

All this allows you to increase the parametric angle to ± 60 ° and make the module run time up to 8 hours per day with the equatorial orientation scheme.

The drawing shows a cross section of a solar module with a stationary concentrator and a beam path.

A solar module with a stationary concentrator has lateral reflecting circular cylindrical walls 1, 2 of radius R located on both sides of the plane of symmetry 3 of the module, limiting the plane of entry 4 of radiation into the concentrator, plane of symmetry 3 passes through the center of the plane 5 of the radiation receiver 6 with a double-sided working surface of width d and parallel to the inlet plane 4, and secondary circular cylindrical reflectors 7, 8 of radius r = 0.5d. In the cross section of the concentrator, the lateral reflecting walls 1, 2 are made in circles of radius R, the centers 0 of which are located on the entrance plane 4, one end A of a circle of radius R passes through the extreme points of the plane 6 of the radiation receiver with a width of 2d, in which the circles of the side walls 1 are connected, 2 and secondary reflectors 7, 8, and through which one of the sides 9, 10 of the parametric angles that make up the angle γ with the axis of symmetry, the intersection points of which with the entrance plane are the second end B of circles of radius R, ENTRAL angle β arc radius R is a value of no more than 30 angular degrees, and centers kruglotsilidricheskih secondary reflectors are located at the edges of the radiation receiver 6.

In addition, the drawing shows the rays L ₁ and L ₂ inclined to the plane of symmetry at the maximum parametric angle γ = 60 °, and the diagram of their passage inside the concentrator, and the beam L ₃ , inclined at a smaller angle, the normals to reflective surfaces.

The module works as follows.

Solar radiation, for example, beam L ₁ , arrives at a maximum parametric angle γ = 60 ° to the plane of symmetry 3, is reflected from side wall 2 at point 6, and arrives at point A ′ (by construction) at the boundary between the circles of side wall 1 and the secondary reflector 7. The beam L _{1 is} reflected several times from the walls of the secondary reflector 7 and hits the radiation receiver 6 due to the fact that the radii of the secondary reflectors come from the extreme point 0 _{2 of} the radiation receiver 6.

Beam L ₂ , arriving at an angle of 60 ° in the middle of wall 2, is reflected and arrives at point A ′ because wall 2 has a small opening angle β≤30 °, at this opening angle the circular reflector behaves like a parabolic, reflecting rays in general focus. Further, from the walls of the secondary reflector 7, the rays after several reflections will fall on the radiation receiver 6.

Beam L ₃ arrives at an angle less than the parametric angle, is reflected from the side wall 2, is reflected from the secondary reflector 8 and hits the radiation receiver 6.

It can be shown that the geometry of the proposed hub is described by the following formulas:

Substitution of values in formulas 1-4 for given d = 1, β = 20 °, γ = 60 ° show the following values of the concentrator parameters: radius of the side wall R = 4d, radiation concentration K = 2.5, module height h = 1.4d , deflection arrow Δr = 0.24d.

For the prototype with a parametric angle γ = 60 °, the concentration will be K = 2.16.

If we set other values at d = 1, for example, β = 20 °, and the parametric angle, γ = 30 °, then we obtain the following values: R = 14.3d, K = 3.7, h = 4.9d, Δr = 0.86.

The advantages of the proposed module are that it has a higher radiation concentration at large (± 60 °) parametric angles, it can be installed according to the equatorial scheme, when the longitudinal axis of the module is installed at an angle of latitude, while the cooling fluid will circulate in the radiation receiver through the laws of free convection, rising up under the action of heating without additional pumps, which will significantly reduce the cost of a solar installation, reduce operating costs. In this case, the operating time of the module will be 120 ° / 15 deg./h = 8 hours, with a radiation concentration of 2.5.

Modules of this type are of interest for solar stations with photovoltaic converters for generating electricity, the heat of the coolant can be useful for industrial and domestic purposes.

Such modules can be used in solar refrigeration units, in which it is necessary to have a coolant temperature of 100 ° C.

Modules of this type with parametric angles of the order of 30 ° should be installed with the longitudinal axis horizontally, while it is advisable to have a parametric angle of 30 °, and not 27.5 °, as in the prototype, because when installing the modules in the place of operation, it is necessary to have a tolerance on the installation accuracy, which is ensured by an angle value of 30 ° -27.5 ° = 2.5 °.

Claims (1)

A solar module with a stationary concentrator having lateral reflecting circular cylindrical walls of radius R located on both sides of the plane of symmetry of the module, limiting the plane of radiation entry into the concentrator, the plane of symmetry passes through the center of the plane of the radiation receiver with a two-sided working surface of width d and parallel to the entrance plane, and secondary circular cylindrical reflectors of radius r = 0.5d, characterized in that in the cross section of the concentrator the lateral reflective walls are made in circles of radius R, whose centers are located on the entrance plane, one end of a circle of radius R passes through the extreme points of the plane of the radiation receiver with a width of 2d, in which the circles of the side walls and secondary reflectors are connected, and through which the lines of parametric angles that make up the angle γ with the axis of symmetry whose intersection points with the entrance plane are the second end of the circles of radius R, while the central angle of the arc of radius R is not more than 30 angular degrees, and the centers of the secondary circles lotsilidricheskih reflectors located at the edges of the radiation receiver.

Images