Abstract: An optical device for collecting light and selectively outputting or concentrating the light. A layer has an optical index of referaction n1, and top, bottom and side surfaces defining an angel of inclination &phgr;. A back surface spans the top, bottom and side surface. A first layer is coupled to the bottom surface of the layer and has an index of refraction n2. The first layer index n2 causes light input through the back surface of the layer to be preferentially output into the first layer. A second layer is coupled to the bottom of the first layer and selectively causes output of light into ambient. Additional layers, such as alight polarization layer, a polarization converting layer and a post LCD diffuser layer can be used to make preferential use of polarized light of diffuse light having passed through the LCD layer to enhance viewing of the output light.

Abstract: The present invention relates to multiple reflector light or solar energy concentrators and systems using such concentrators. More particularly, the invention is concerned with an arrangement of optical elements for the efficient collection of light while minimizing complexities of optics needed to achieve light collection and concentration. At least three reflectors are involved. A concave primary reflector receives the solar energy and sends it to a secondary convex reflector positioned in the focal zone of the first reflector. In turn, the secondary reflector sends the solar energy, at least in part, to a third non-imaging reflector positioned in the focal zone of the secondary reflector. In a system, a receiver is placed in the focal zone of the third reflector. The present arrangement allows for the receiver to be in a fixed position, enhancing the ability of certain variants of the system to generate steam directly in the receiver.

Abstract: A collapsible light collection and/or transmission device having an axis of symmetry. The device includes opposing first and second body portions each having a curved inner reflective surface and an outer surface. The first body portion is pivotally coupled to the second body portion along the axis of symmetry. The present invention further includes a collapsible solar collector for collecting solar rays. The collector includes first and second body portions each having an inner reflective surface, an outer surface, a proximal end and a distal end. The collector is positionable between at least a first operative position, wherein the distal ends of the first and second body portions are separated, and a second substantially closed position, wherein the distal ends of the first and second body portions are positioned substantially adjacent to one another and the first and second body portions substantially face one another.

Abstract: A structure and method for providing a broken symmetry reflector structure for a solar concentrator device. The component of the optical direction vector along the symmetry axis is conserved for all rays propagated through a translationally symmetric optical device. This quantity, referred to as the translational skew invariant, is conserved in rotationally symmetric optical systems. Performance limits for translationally symmetric nonimaging optical devices are derived from the distributions of the translational skew invariant for the optical source and for the target to which flux is to be transferred. A numerically optimized non-tracking solar concentrator utilizing symmetry-breaking reflector structures can overcome the performance limits associated with translational symmetry.

Abstract: A nonimaging light concentrator system including a primary collector of light, an optical mixer disposed near the focal zone for collecting light from the primary collector, the optical mixer having a transparent entrance aperture, an internally reflective housing for substantially total internal reflection of light, a transparent exit aperture and an array of photovoltaic cells disposed near the transparent exit aperture.

Abstract: The present invention relates to multiple reflector light or solar energy concentrators and systems using such concentrators. More particularly, the invention is concerned with an arrangement of optical elements for the efficient collection of light while minimizing complexities of optics needed to achieve light collection and concentration At least three reflectors are involved. A concave primary reflector receives the solar energy and sends it to a secondary convex reflector positioned in the focal zone of the first reflector. In turn, the secondary reflector sends the solar energy, at least in part, to a third non-imaging reflector positioned in the focal zone of the secondary reflector. In a system, a receiver is placed in the focal zone of the third reflector. The present arrangement allows for the receiver to be in a fixed position, enhancing the ability of certain variants of the system to generate steam directly in the receiver.

Abstract: A nonimaging light concentrator system including a primary collector of light, an optical mixer disposed near the focal zone for collecting light from the primary collector, the optical mixer having a transparent entrance aperture, an internally reflective housing for substantially total internal reflection of light, a transparent exit aperture and an array of photovoltaic cells disposed near the transparent exit aperture.

Abstract: A collapsible light collection and/or transmission device having an axis of symmetry. The device includes opposing first and second body portions each having a curved inner reflective surface and an outer surface. The first body portion is pivotally coupled to the second body portion along the axis of symmetry. The present invention further includes a collapsible solar collector for collecting solar rays. The collector includes first and second body portions each having an inner reflective surface, an outer surface, a proximal end and a distal end. The collector is positionable between at least a first operative position, wherein the distal ends of the first and second body portions are separated, and a second substantially closed position, wherein the distal ends of the first and second body portions are positioned substantially adjacent to one another and the first and second body portions substantially face one another.

Abstract: A non-imaging optical system for operating on light using broken symmetry reflector surfaces (30). The theoretical upper limit for concentration of direct solar radiation at low latitudes with stationary concentrators is determined from the projected solid angle sampled by the apparent motion of the sun. Based on the fact that the solar radiation is not uniformly distributed within this projected solid angle, we derive higher concentrations which apply when rejecting the lower density radiation. Trough type systems, which have translational symmetry, cannot be ideal stationary concentrators. Efficiency is improved by using broken symmetry for surfaces of the reflector (30) and the light source or concentrator. We note that what applies to concentrators applies equally to reflectors for illumination.

Abstract: The combination that includes an LED, and a light transmitting pyramid mounted with respect to the LED to transmit light therefrom, the pyramid having at least three sides, the sides defining planes extending upwardly toward an apex that is spaced in a longitudinal direction from the LED, the planes angled in excess of 45° relative to a lateral plane normal to longitudinal direction such that essentially all LED light incident on the three sides from within the pyramid is extracted from the sides.

Abstract: An optical device for collecting light and selectively outputting or concentrating the light. A layer has an optical index of referaction n1, and top, bottom and side surfaces defining an angel of inclination &phgr;. A back surface spans the top, bottom and side surface. A first layer is coupled to the bottom surface of the layer and has an index of refraction n2. The first layer index n2 causes light input through the back surface of the layer to be preferentially output into the first layer. A second layer is coupled to the bottom of the first layer and selectively causes output of light into ambient. Additional layers, such as alight polarization layer, a polarization converting layer and a post LCD diffuser layer can be used to make preferential use of polarized light of diffuse light having passed through the LCD layer to enhance viewing of the output light.

Abstract: A non-imaging optical system for operating on light using broken symmetry reflector surfaces (30). The theoretical upper limit for concentration of direct solar radiation at low latitudes with stationary concentrators is determined from the projected solid angle sampled by the apparent motion of the sun. Based on the fact that the solar radiation is not uniformly distributed within this projected solid angle, we derive higher concentrations which apply when rejecting the lower density radiation. Trough type systems, which have translational symmetry, cannot be ideal stationary concentrators. Efficiency is improved by using broken symmetry for surfaces of the reflector (30) and the light source or concentrator. We note that what applies to concentrators applies equally to reflectors for illumination.

Abstract: An optical device for collecting light and selectively outputting or concentrating the light. A layer has an optical index of referaction n1l, and top, bottom and side surfaces defining an angel of inclination &phgr;. A back surface spans the top, bottom and side surface. A first layer is coupled to the bottom surface of the layer and has an index of refraction n2. The first layer index n2 causes light input through the back surface of the layer to be preferentially output into the first layer. A second layer is coupled to the bottom of the first layer and selectively causes output of light into ambient. Additional layers, such as alight polarization layer, a polarization converting layer and a post LCD diffuser layer can be used to make preferential use of polarized light of diffuse light having passed through the LCD layer to enhance viewing of the output light.

Abstract: A passive solar collector has a reflector or a plurality of reflectors in a tube that is in a partial vacuum and is entirely or partly transparent. An absorber collects light reflected by the reflector or plurality of reflectors and delivers energy from the collected light to a central tube where it heats a substance such as water or other fluid. The absorber is disposed at an angle to the axis of the passive solar collector. The passive solar collector is protected against overheating by one or more devices such as a getter that releases a gas to reduce the vacuum or an opaque shield that is placed so as to cover the reflector in response to an indication of overheating. Reflecting surfaces of the solar collector may be symmetrical or asymmetrical, and they may be smooth or they may have dents, protrusions, or both. The surfaces of the solar collector may be smooth, ridged with smooth curves, or ridged with sharp curves.

Abstract: A gap between absorber and reflector of a solar concentrator. A gap is required in a solar concentrator for thermal isolation reasons and the position of the receiver relative to reflector and a notch are optimized for best solar collection efficiency.

Abstract: In apparatus to extract light from an LED, the combination includes a cylindrical body consisting of light transmitting material, the body having a cylindrical outer wall; a pyramidal body having at least three sides and consisting of light transmitting material, the pyramidal body located longitudinally endwise of the cylindrical body, to expose the three or more sides, the planar sides defining planes which intersect said cylindrical body outer wall at curved edges, the cylindrical outer wall terminating at said curved edges; and an LED located in a spaced relation to the pyramidal body, and oriented to transmit light in the cylindrical body and toward the pyramidal body.

Abstract: A nonimaging solar collector. A method and article of manufacture of a solar collector includes an outer housing transparent to light, a reflector element positioned asymmetrically within the outer housing, an absorber disposed within the outer housing, and a heat conduction fin coupled to the absorber and having a wedge shape which tapers to a smaller thickness as a function of increasing radial separation from the absorber. The heat conductor fin can be positioned at a variety of angular positions.

Abstract: An optical device for collecting light and selectively outputting or concentrating the light. A layer has an optical index of referaction n.sub.1, and top, bottom and side surfaces defining an angel of inclination .phi.. A back surface spans the top, bottom and side surface. A first layer is coupled to the bottom surface of the layer and has an index of refraction n.sub.2. The first layer index n.sub.2 causes light input through the back surface of the layer to be preferentially output into the first layer. A second layer is coupled to the bottom of the first layer and selectively causes output of light into ambient. Additional layers, such as alight polarization layer, a polarization converting layer and a post LCD diffuser layer can be used to make preferential use of polarized light of diffuse light having passed through the LCD layer to enhance viewing of the output light.

Abstract: A nonimaging illumination optical device for producing a selected far field illuminance over an angular range. The optical device includes a light source 102, a light reflecting surface 108, and a family of light edge rays defined along a reference line 104 with the reflecting surface 108 defined in terms of the reference line 104 as a parametric function R(t) where t is a scalar parameter position and R(t)=k(t)+Du(t) where k(t) is a parameterization of the reference line 104, and D is a distance from a point on the reference line 104 to the reflection surface 108 along the desired edge ray through the point.

Abstract: An optical device for collecting light and selectively outputting or concentrating the light. A layer has an optical index of referaction n.sub.1, and top, bottom and side surfaces defining an angel of inclination .phi.. A back surface spans the top, bottom and side surface. A first layer is coupled to the bottom surface of the layer and has an index of refraction n.sub.2. The first layer index n.sub.2 causes light input through the back surface of the layer to be preferentially output into the first layer. A second layer is coupled to the bottom of the first layer and selectively causes output of light into ambient. Additional layers, such as alight polarization layer, a polarization converting layer and a post LCD diffuser layer can be used to make preferential use of polarized light of diffuse light having passed through the LCD layer to enhance viewing of the output light.