Disclosed is a solar power station, comprising a first light-receiving device having a substantially planar first working surface, a second light-receiving device having a second working surface substantially perpendicular to the first working surface, and a first drive mechanism. The first and second working surfaces are configured so that sunlight (SS) strikes the first working surface after passing through the second working surface or passes through the first working surface and then strikes the second working surface. The second light-receiving device is fixed on the first drive mechanism. The first drive mechanism is used to drive the second working surface to move or rotate relative to the first working surface according to the movement of the sun.

An energy collection system including a collection apparatus having a light concentrating lens is disclosed. The light concentrating lens can include a light receiving surface and a light exiting surface opposite the light receiving surface. The light exiting surface includes a curved shape configured to direct light passing through the lens to a focal point. The energy collection system further includes a concentrator apparatus having a conduit and an energy absorbing medium within the conduit to convert the solar energy to thermal energy.

An energy collection system including a collection apparatus having a light concentrating lens is disclosed. The light concentrating lens can include a light receiving surface and a light exiting surface opposite the light receiving surface. The light exiting surface includes a curved shape configured to direct light passing through the lens to a focal point. The energy collection system further includes a concentrator apparatus having a conduit and an energy absorbing medium within the conduit to convert the solar energy to thermal energy.

An optical solar enhancer comprises a panel that has a top surface and a bottom surface and an imaginary central plane that extends between the top surface and the bottom surface. The panel includes a plurality of generally parallel features configured to variably increase radiant energy entering the top surface at an acute angle relative to the central plane such that the effect is strongest at lower angles (early morning and late day sun) and weakest at higher angles (mid-day sun) and then redirect the increased radiant energy through the bottom surface.

An optical solar enhancer comprises a panel that has a top surface and a bottom surface and an imaginary central plane that extends between the top surface and the bottom surface. The panel includes a plurality of generally parallel features configured to variably increase radiant energy entering the top surface at an acute angle relative to the central plane such that the effect is strongest at lower angles (early morning and late day sun) and weakest at higher angles (mid-day sun) and then redirect the increased radiant energy through the bottom surface.

A solar energy utilization device, comprising a light energy utilization device (200) and a convex light concentrating device (100). The convex light concentrating device (100) is filled with a transparent liquid (130). The convex light concentrating device (100) has a light-transmissive convex sidewall (110) provided obliquely, and sunlight can be transmitted to the transparent liquid (130) from the light-transmissive convex sidewall (110). A first light energy utilization part (210) is provided at the bottom of an accommodating cavity, and sunlight transmitted from the transparent liquid (130) to the light-transmissive convex sidewall (110) forms a total internal reflection phenomenon, so that the convex light concentrating device (100) more conveniently concentrates the sunlight onto the first light energy utilization part (210).

A solar energy utilization device, comprising a light energy utilization device (200) and a convex light concentrating device (100). The convex light concentrating device (100) is filled with a transparent liquid (130). The convex light concentrating device (100) has a light-transmissive convex sidewall (110) provided obliquely, and sunlight can be transmitted to the transparent liquid (130) from the light-transmissive convex sidewall (110). A first light energy utilization part (210) is provided at the bottom of an accommodating cavity, and sunlight transmitted from the transparent liquid (130) to the light-transmissive convex sidewall (110) forms a total internal reflection phenomenon, so that the convex light concentrating device (100) more conveniently concentrates the sunlight onto the first light energy utilization part (210).

A Fresnel spot lens desalinization system includes a Fresnel spot lens (FSL) disposed above a heating element. The heating element has a collector plate and a rod portion; The FSL concentrates solar energy onto the collector plate. A condenser vessel is connected to the collector plate. The rod portion extends into the condenser vessel having a heat resistant exterior shell. The rod portion projects interiorly of the condenser vessel at a downward angle and includes a top portion that is connected to a flat head of the heating element. The flat head receives the solar energy generated from FSL The concentrated solar energy increases the temperature of the heating element inside the condenser vessel to vaporize the salt water to steam and transfer the steam into a condensing tube to condense the steam into pure water.

A swimming pool cover with lenses is disclosed. The swimming pool cover uses lenses to focus ambient solar energy into the water of a swimming pool. In one embodiment, a plurality of rectangular lenses is connected at their edges by a minimal amount of connecting or gusset material, in order to create an impermeable sheet, while maximizing the amount of incident solar energy absorbed by the swimming pool water. The swimming pool cover also protects detritus from falling into the swimming pool, while at the same time, reduces the amount of heat loss through evaporation. In another embodiment, the gusset material connects a plurality of lenses, varying in both size and shape.

A method is provided for using asymmetrically focused photovoltaic conversion in a hybrid parabolic trough solar power system. Light rays received in a plurality of transverse planes are concentrated towards a primary linear focus in an axial plane, orthogonal to the transverse planes. T band wavelengths of light are transmitted to the primary linear focus, while R band wavelengths of light are reflected towards a secondary linear focus in the axial plane. The light received at the primary linear focus is translated into thermal energy. The light received at the secondary linear focus is asymmetrically focused along a plurality of tertiary linear foci, orthogonal to the axial plane. The focused light in each tertiary linear focus is concentrated into a plurality of receiving areas and translated into electrical energy. Asymmetrical optical elements are used having an optical input interfaces elongated along rotatable axes, orthogonal to the axial plane.