RU2014118543A - SUNNY MODULE WITH HUB - Google Patents

Abstract

1. A solar module with a concentrator having a working surface on which solar radiation is incident, a concentrator and a radiation receiver, a deflecting optical system of main mirror reflectors made in the form of blinds made of flat mirror facets with input and output beams is installed on the working surface characterized in that at the output of the deflecting optical system, additional mirror reflectors are installed, the input angles β, the output rays β for the main mirror reflectors, the input angles β and β e For additional mirror reflectors, the angle φ and φ of the slope of the main and additional mirror reflectors are related by the relations: β = 2φ-tg (2tgφ), β = 2φ-β = φ, β = 2φ-β, where φ and φ are the angles of inclination of the main and additional mirror reflectors counted from the vertical to the working surface counterclockwise, β, β and β are the angles of entry and exit of the rays, measured from the vertical to the working surface counterclockwise, the distance α between the main mirror reflectors on the working surface and the width of the main mirror reflectors corresponds to the relation α = dsinφ, for which for any angle φ the lower edge of the main mirror reflector and the upper edge of the next main mirror reflector are the width of the additional mirror reflectors d satisfies the relation: where d is the width of the main mirror reflectors and the receiver with a width A = B · ctgβ is established along the rays β, β in the plane perpendicular to the exit plane of the rays, where B is the width of the optical deflecting system. 2. A solar module with a concentrator according to claim 1, characterized in that

Claims (12)

1. A solar module with a concentrator having a working surface on which solar radiation is incident, a concentrator and a radiation receiver, a deflecting optical system of main mirror reflectors made in the form of blinds made of flat mirror facets with input and output beams is installed on the working surface characterized in that at the output of the deflecting optical system additional mirror reflectors are installed, the input angles β ₀ , the output rays β ₁ for the main mirror reflectors, the input angles β ₀ and β ₂ for additional mirror reflectors, the angle φ and φ _{1 of the} slope of the main and additional mirror reflectors are related by the relations: β ₀ = 2φ-tg (2tgφ), β ₁ = 2φ-β ₀ = φ ₁ , β ₂ = 2φ ₁ -β ₀ , where φ and φ ₁ are the angles of inclination of the main and additional mirror reflectors, counted from the vertical to the working surface counterclockwise, β ₀ , β ₁ and β ₂ are the angles of entry and exit of the rays, measured from the vertical to the working surface counterclockwise, the distance α between the main mirror reflectors on the working surface and the width of the main mirror reflectors satisfies the relation α = dsinφ, for which for any angles φ the lower face of the main mirror reflector and the upper face of the next main mirror reflector are in the same vertical plane, the width of the additional mirror reflectors d ₁ satisfies the ratio:

where d is the width of the main mirror reflectors, and a receiver with a width of A = B · ctgβ _{1 is} installed along the rays β ₁ , β ₂ in the plane perpendicular to the exit plane of the rays, where B is the width of the optical deflecting system. 2. A solar module with a concentrator according to claim 1, characterized in that the module contains two mounted counter-symmetric deflecting optical systems with an angle between the main mirror reflectors equal to 2φ-2β ₀ and with an angle between the input surfaces equal to 180 ° -2β ₀ , and a two-sided common receiver with a width of A = Bctgβ ₁ · cosβ ₀ , which is installed in the plane of symmetry of the module and is equipped with a symmetrical flat mirror reflector of size 2A · sinβ ₀ . 3. A solar module with a concentrator according to claim 1, characterized in that the module comprises a flat mirror reflector of size B parallel to the plane of exit of the rays and remote from the plane of exit of the rays by a distance equal to the width of the receiver

4. A solar module with a concentrator according to claim 3, characterized in that the module contains two mounted counter-symmetric deflecting optical systems with an angle between the main mirror reflectors equal to 2φ-2β ₀ and with an angle between the input surfaces equal to 180 ° -2β ₀ , and two-way common receiver wide $$A=\frac{B}{2}ctg{\beta }_{\mathrm{one}}\cos {\beta }_0$$

which is installed in the plane of symmetry of the module and is equipped with a symmetrical flat mirror reflector of size 2A · sinβ ₀ . 5. A solar module with a concentrator according to claim 1, characterized in that the module contains a flat mirror reflector of size $$\frac{2}{3}B$$

parallel to the exit plane of the rays, remote from the exit plane of the rays at a distance $$A=\frac{\mathrm{one}}{3}Bctg\beta$$

equal to the width of the receiver, as well as an additional axisymmetric mirror reflector of size $$\frac{\mathrm{one}}{3}B$$

mounted in the exit plane of the rays. 6. A solar module with a concentrator according to claim 5, characterized in that the module contains two mounted counter-symmetric deflecting optical systems with an angle between the main mirror reflectors equal to 2φ-2β ₀ and an angle between the input surfaces of 180 ° -2β ₀ , and two-way common receiver wide $$A=\frac{\mathrm{one}}{3}Bctg{\beta }_{\mathrm{one}}\cos {\beta }_0$$

which is installed in the plane of symmetry of the module and is equipped with a symmetrical flat mirror reflector of size 2A · sinβ ₀ . 7. A solar module with a concentrator according to claim 1, characterized in that the module contains a mirror cylindrical reflector with a radius R with an axis located on the contact line of the exit surface of the deflecting optical system and the receiver with a receiver width of A = R = Bcosβ ₁ . 8. A solar module with a concentrator according to claim 7, characterized in that the module contains two mounted counter-symmetric deflecting optical systems with a corner between the main mirror reflectors equal to 2φ-2β ₀ and an angle between the input surfaces of 180 ° -2β ₀ , and a two-sided common receiver with a width of A = R = Bcosβ ₁ · cosβ ₀ , which is installed in the plane of symmetry of the module and is equipped with a symmetrical flat mirror reflector of size 2A · sinβ ₀ . 9. A solar module with a concentrator according to claim 1, characterized in that the module comprises a flat mirror reflector that is mounted at an acute angle $$\psi =\frac{{\beta }_{\mathrm{one}}}{2}+{45}^{\circ }$$

to the normal of the exit surface of the rays in such a way that all the rays reflected from it are orthogonal to the receiver of width A = B · ctgΨ. 10. A solar module with a concentrator according to claim 9, characterized in that the module contains two mounted counter-symmetric deflecting optical systems with an angle between the main mirror reflectors equal to 2φ-2β ₀ and with an angle between the input surfaces equal to 180 ° -2β ₀ , and a two-sided common receiver with a width of A = Bctg cos · cosβ ₀ , which is installed in the plane of symmetry of the module and is equipped with a symmetrical flat mirror reflector of size 2A · sinβ ₀ . 11. A solar module with a concentrator according to claim 1, characterized in that the module comprises a flat mirror reflector that is mounted at an acute angle Ψ to the normal to the surface of the output of the rays, connected to a second mirror reflector with a width $$\frac{Btg{\beta }_{\mathrm{one}}}{tg\psi +tg{\beta }_{\mathrm{one}}}=Atg{\beta }_{\mathrm{one}}$$

parallel to the exit plane of the rays with an angle β ₁ , and the receiver has a width

. 12. A solar module with a concentrator according to claim 11, characterized in that the module contains two mounted counter-symmetric deflecting optical systems with an angle between the main mirror reflectors equal to 2φ-2β ₀ , and with an angle between the input surfaces equal to 180 ° -2β ₀ , and two-way common receiver wide $$A=\frac{B\cos {\beta }_0}{tg\psi +tg{\beta }_{\mathrm{one}}}$$

which is installed in the plane of symmetry of the module and is equipped with a symmetrical flat mirror reflector of size 2A · sinβ ₀ .