| Patent application number | Description | Published |
|---|
| 20090160928 | MULTIPLE-BEAM RASTER OUTPUT SCANNER WITH A COMPENSATING FILTER - A printing system includes a multiple-beam generator array configured to generate multiple beams. A collimator lens is positioned to receive the multiple beams, and an aperture stop is located where the multiple beams are spatially coincident with each other. A scanning optical system is positioned to receive the beams from the aperture stop, and a recording medium receives the beams from the scanning optical system. A filter is located where the multiple beams are spatially coincident with each other, whereby each of the multiple beams may be filtered by the supplied filter. | 06-25-2009 |
| 20090314344 | Solar Cell Production Using Non-Contact Patterning And Direct-Write Metallization - Photovoltaic devices (i.e., solar cells) are formed using non-contact patterning apparatus (e.g., a laser-based patterning systems) to define contact openings through a passivation layer, and direct-write metallization apparatus (e.g., an inkjet-type printing or extrusion-type deposition apparatus) to deposit metallization into the contact openings and over the passivation surface. The metallization includes two portions: a contact (e.g., silicide-producing) material is deposited into the contact openings, then a highly conductive metal is deposited on the contact material and between the contact holes. The device wafers are transported between the patterning and metallization apparatus in hard tooled registration using a conveyor mechanism. Optional sensors are utilized to align the patterning and metallization apparatus to the contact openings. An extrusion-type apparatus is used to form grid lines having a high aspect central metal line that is supported on each side by a transparent material. | 12-24-2009 |
| 20100206302 | Rotational Trough Reflector Array For Solar-Electricity Generation - A rotational trough reflector solar-electricity generation device includes a trough reflector that rotates around a substantially vertical axis. A strip-type photovoltaic (PV) device, or other solar-energy collection element, is fixedly mounted along the focal line of the trough reflector. A tracking system rotates the trough reflector such that the trough reflector is aligned generally parallel to the incident sunlight (e.g., in a generally east-west direction at sunrise, turning to generally north-south at noon, and turning generally west-east at sunset). A disc-shaped support structure is used to distribute the reflector's weight over a larger area and to minimize the tracking system motor size. Multiple trough reflectors are mounted on the disc-shaped support to maximize power generation. Flat mirrors are disposed at the end of the troughs to increase power in “hot” PV sections that are connected in series. | 08-19-2010 |
| 20100206356 | Rotational Trough Reflector Array For Solar-Electricity Generation - A rotational trough reflector solar-electricity generation device includes a trough reflector that rotates around a substantially vertical axis. A strip-type photovoltaic (PV) device is fixedly mounted along the focal line of the trough reflector. A tracking system rotates the trough reflector such that the trough reflector is aligned generally parallel to the incident sunlight (e.g., in a generally east-west direction at sunrise, turning to generally north-south at noon, and turning generally west-east at sunset). A disc-shaped support structure is used to distribute the reflector's weight over a larger area and to minimize the tracking system motor size. Multiple trough reflectors are mounted on the disc-shaped support to maximize power generation. | 08-19-2010 |
| 20100206357 | Two-Part Solar Energy Collection System With Replaceable Solar Collector Component - A two-part solar energy collection system for installation on a planar support surface (e.g., a rooftop) includes a permanent positioning component including a base structure and a replaceable solar collector component including solar energy collection elements fixedly mounted on a support frame. Each collection element includes an optical element arranged to focus solar radiation onto a focal line, and a linearly-arranged solar energy collector (e.g., PV cells) fixedly maintained on the focal line. The replaceable solar collector component is secured to a rotating platform of the base structure such that the focal lines of the solar energy collection elements are maintained in a plane that is substantially parallel to the support surface, and the rotating platform and replaceable solar collector component are collectively pivoted by a positioning system around a rotational axis to align the PV cells) parallel to the received sunlight beams. | 08-19-2010 |
| 20100206379 | Rotational Trough Reflector Array With Solid Optical Element For Solar-Electricity Generation - A rotational trough reflector solar-electricity generation device includes a trough reflector that rotates around a substantially vertical axis and includes a solid optical element having a linear parabolic convex surface that serves as a base for automatically positioning a mirror to focus sunlight onto a focal line, and a flat aperture surface that serves to support a strip-type photovoltaic (PV) receiver on the focal line. A tracking system rotates the trough reflector such that the trough reflector is aligned generally parallel to the incident sunlight (e.g., in a generally east-west direction at sunrise, turning to generally north-south at noon, and turning generally west-east at sunset). A disc-shaped support structure is used to distribute the reflector's weight over a larger area and to minimize the tracking system motor size. Multiple trough reflectors are mounted on the disc-shaped support to maximize power generation. | 08-19-2010 |
| 20110058241 | ULTRA-SHORT PULSE SCANNING OPTICAL SYSTEM - A scanning optical system including an optical source configured to generate an ultra-short light pulse, a dispersion compensation system disposed such that the ultra-short light pulse travels through the dispersion compensation system, an optical deflector configured to rotate about an axis such that the ultra-short light pulse is deflected through a scan angle, and an f-theta scan lens having a group delay (GD) variation versus relative pupil height and group delay dispersion (GDD) variation versus the scan angle that are substantially minimized. The f-theta scan lens is disposed such that the ultra-short pulse is incident on the f-theta scan lens. | 03-10-2011 |
| 20110100418 | Solid Linear Solar Concentrator Optical System With Micro-Faceted Mirror Array - A concentrating solar collector includes a solid optical structure a flat front surface, and PV cells and a micro-faceted mirror array disposed on the opposing rear surface. The micro-faceted mirrors are arranged in a sawtooth arrangement to reflect sunlight toward the front surface at angles that produces total internal reflection (TIR) and redirection of the sunlight onto the PV cells. The micro-faceted mirror array reflects sunlight onto the PV cells in an extended focus region of concentrated light that has a substantially uniform or homogeneous irradiance distribution pattern. The optical structure is a solid dielectric sheet either processed to include micro-faceted surfaces with reflective material formed thereon, or having a dielectric film including the micro-faceted mirror array adhered thereon. In one embodiment, three PV cells and four micro-faceted mirror arrays are disposed in an interleaved pattern with two side mirrors are disposed on side edges of the optical structure. | 05-05-2011 |
| 20110100419 | Linear Concentrating Solar Collector With Decentered Trough-Type Relectors - A linear concentrating solar collector includes two trough-type reflectors having respective curved reflective surfaces that define respective focal lines, and are connected along a common edge in a decentered arrangement such that the focal lines are parallel and spaced-apart, and such that solar radiation reflected by the curved reflective surfaces is concentrated and overlaps in a defocused state. In one embodiment a solar cell is disposed in the overlap region to receive the all of the reflected radiation from the curved reflective surfaces in a defocused state. An optional solid optical structure is used to support and position the trough-type reflectors and solar cell, and to facilitate self-forming of the curved reflective surfaces. In other embodiments, two solar cells are mounted on the rear surface of the optical element, and the curved reflective surfaces reflect sunlight at angles that produce total internal reflection of the sunlight onto the solar cells. | 05-05-2011 |
