Patent application number | Description | Published |
20130003299 | PACKAGING OF POWER SUPPLY USING MODULAR ELECTRONIC MODULES - An enclosure for a power supply is disclosed. The enclosure may include a control compartment configured to receive one or e control components, a transformer compartment positioned adjacent to the con c compartment and configured to receive a transformer, and a power cell compartment positioned adjacent to the control compartment and the transformer compartment. The power cell compartment may be configured to receive a plurality of power cells arranged into a plurality of pods. The power cells may be received in the power cell compartment such that each power cell in a first pod is adjacent to at least two other power cells in the first pod. A voltage difference between adjacent power cells in a pod may be less than an acceptable voltage tolerance. | 01-03-2013 |
20150249299 | SECURING AND LOCKING SYSTEM FOR AN ELECTRONIC MODULE - Embodiments include an electronic module having a chassis, a locking member rotatably connected to the chassis, and a bus bar system comprising a plurality of bus bars. The electronic module includes a plurality of power plug connectors configured such that each of the plurality of bus bars is connected to at least one power plug connector, wherein each of the power plug connectors is configured to receive at least a portion of a system bus thereby establishing an electrical connection between each of the plurality of bus bars and the system bus. The locking member is configured to connect the electronic module to the system bus such that the plurality of power plug connectors establish an electrical connection between the bus bar system and the system bus and wherein the locking member is configured to lock to the chassis once the electrical connection has been established. | 09-03-2015 |
20150303661 | ARC Fault Path For Mitigation Of ARC Fault In Power Supply Enclosure - An enclosure for a power supply is provided. An aspect includes a first compartment and a second compartment located adjacent to the first compartment. Another aspect includes an intermediate pressure relief flap located inside the enclosure in between the first compartment and the second compartment, and a top pressure relief flap located on an external surface of the second compartment. Another aspect includes the intermediate pressure relief flap and the top pressure relief flap configured to be closed in the absence of an arc fault in the enclosure, and the intermediate pressure relief flap and the top pressure relief flap configured to open based on the presence of the arc fault in the enclosure, such that plasma from the arc fault vents from the first compartment into the second compartment via the opened intermediate pressure relief flap and out of the second compartment via the opened top pressure relief flap | 10-22-2015 |
Patent application number | Description | Published |
20090001356 | ELECTRONIC DEVICES HAVING A SOLUTION DEPOSITED GATE DIELECTRIC - An electronic device comprises a solution deposited gate dielectric, the gate dielectric comprising a dielectric material formed by polymerizing a composition comprising a polymerizable resin and zirconium oxide nanoparticles. | 01-01-2009 |
20090004771 | METHODS FOR MAKING ELECTRONIC DEVICES WITH A SOLUTION DEPOSITED GATE DIELECTRIC - A method of making an electronic device comprises solution depositing a dielectric composition onto a substrate and polymerizing the dielectric composition to form a gate dielectric. The dielectric composition comprises a polymerizable resin and zirconium oxide nanoparticles. | 01-01-2009 |
20110092015 | Mixed Solvent Systems for Deposition of Organic Semiconductors - Compositions that contain an organic semiconductor dissolved in a solvent mixture are described. More specifically, the solvent mixture includes an alkane having 9 to 16 carbon atoms in an amount equal to 1 to 20 weight percent and an aromatic compound in an amount equal to 80 to 99 weight percent. The semiconductor material is dissolved in the solvent mixture in an amount equal to at least 0.1 weight percent based on a total weight of the composition. Methods of making a semiconductor device using the compositions to form a semiconductor layer are also described. | 04-21-2011 |
20130256640 | ASSEMBLY AND ELECTRONIC DEVICES INCLUDING THE SAME - An assembly includes a dielectric layer in contact with a semiconductor layer. The dielectric layer includes a cross-linked polymeric material having isocyanurate groups, wherein the dielectric layer is free of zirconium oxide particles. The semiconductor layer includes a non-polymeric organic semiconductor material, and is substantially free of electrically insulating polymer. Electronic components and devices including the assembly are also disclosed. | 10-03-2013 |
20130313339 | NOZZLE AND METHOD OF MAKING SAME - Nozzle and a method of making the same are disclosed. The method includes (a) providing a microstructured mold pattern defining at least a portion of a mold and comprising a plurality of replica nozzle holes and replica planar control cavities; (b) molding a first material into a nozzle forming microstructured pattern using the microstructured mold pattern, with the nozzle forming microstructured pattern comprising a plurality of nozzle hole forming features and planar control cavity forming features; (c) forming a second material into a nozzle pre-form using the nozzle forming microstructured pattern, with the nozzle pre-form comprising a plurality of nozzle pre-form holes and sacrificial planar control cavities; and (d) forming a nozzle from the nozzle pre-form, said forming the nozzle comprising removing enough of the second material to remove the sacrificial planar control cavities so as to form a top surface of the nozzle pre-form into a planar top surface of the nozzle, and to form each of the nozzle pre-form holes into a nozzle through hole. | 11-28-2013 |
20150204291 | FUEL INJECTORS WITH IMPROVED COEFFICIENT OF FUEL DISCHARGE - Nozzles and method of making the same are disclosed. The disclosed nozzles have at least one nozzle through-hole therein, wherein the at least one nozzle through-hole exhibits a coefficient of discharge, C | 07-23-2015 |
20150211462 | FUEL INJECTOR NOZZLES WITH AT LEAST ONE MULTIPLE INLET PORT AND/OR MULTIPLE OUTLET PORT - Nozzles and method of making the same are disclosed. The disclosed nozzles have at least one nozzle through-hole therein, wherein the at least one nozzle through-hole has (i) a single inlet opening along an inlet face and multiple outlet openings along an outlet face or (ii) multiple inlet openings along an inlet face and a single outlet opening along an outlet face. Fuel injectors containing the nozzle are also disclosed. Methods of making and using nozzles and fuel injectors are further disclosed. | 07-30-2015 |
Patent application number | Description | Published |
20100284086 | STRUCTURES, SYSTEMS AND METHODS FOR HARVESTING ENERGY FROM ELECTROMAGNETIC RADIATION - Methods, devices and systems for harvesting energy from electromagnetic radiation are provided including harvesting energy from electromagnetic radiation. In one embodiment, a device includes a substrate and one or more resonance elements disposed in or on the substrate. The resonance elements are configured to have a resonant frequency, for example, in at least one of the infrared, near-infrared and visible light spectra. A layer of conductive material may be disposed over a portion of the substrate to form a ground plane. An optical resonance gap or stand-off layer may be formed between the resonance elements and the ground plane. The optical resonance gap extends a distance between the resonance elements and the layer of conductive material approximately one-quarter wavelength of a wavelength of the at least one resonance element's resonant frequency. At least one energy transfer element may associated with the at least one resonance element. | 11-11-2010 |
20110277805 | DEVICES FOR HARVESTING ENERGY FROM ELECTROMAGNETIC RADIATION - Methods, devices and systems for harvesting energy from electromagnetic radiation are provided including harvesting energy from electromagnetic radiation. In one embodiment, a device includes a substrate and one or more resonance elements disposed in or on the substrate. The resonance elements are configured to have a resonant frequency, for example, in at least one of the infrared, near-infrared and visible light spectra. A layer of conductive material may be disposed over a portion of the substrate to form a ground plane. An optical resonance gap or stand-off layer may be formed between the resonance elements and the ground plane. The optical resonance gap extends a distance between the resonance elements and the layer of conductive material approximately one-quarter wavelength of a wavelength of the at least one resonance element's resonant frequency. At least one energy transfer element may be associated with the at least one resonance element. | 11-17-2011 |
20120080073 | DEVICES, SYSTEMS, AND METHODS FOR HARVESTING ENERGY AND METHODS FOR FORMING SUCH DEVICES - Energy harvesting devices include a substrate coupled with a photovoltaic material and a plurality of resonance elements associated with the substrate. The resonance elements are configured to collect energy in at least visible and infrared light spectra. Each resonance element is capacitively coupled with the photovoltaic material, and may be configured to resonate at a bandgap energy of the photovoltaic material. Systems include a photovoltaic material coupled with a feedpoint of a resonance element. Methods for harvesting energy include exposing a resonance element having a resonant electromagnetic radiation having a frequency between approximately 20 THz and approximately 1,000 THz, absorbing at least a portion of the electromagnetic radiation with the resonance element, and resonating the resonance element at a bandgap energy of an underlying photovoltaic material. Methods for forming an energy harvesting device include forming resonance elements on a substrate and capacitively coupling the resonance elements with a photovoltaic material. | 04-05-2012 |
20130249771 | APPARATUSES AND METHOD FOR CONVERTING ELECTROMAGNETIC RADIATION TO DIRECT CURRENT - An energy conversion device may include a first antenna and a second antenna configured to generate an AC current responsive to incident radiation, at least one stripline, and a rectifier coupled with the at least one stripline along a length of the at least one stripline. An energy conversion device may also include an array of nanoantennas configured to generate an AC current in response to receiving incident radiation. Each nanoantenna of the array includes a pair of resonant elements, and a shared rectifier operably coupled to the pair of resonant elements, the shared rectifier configured to convert the AC current to a DC current. The energy conversion device may further include a bus structure operably coupled with the array of nanoantennas and configured to receive the DC current from the array of nanoantennas and transmit the DC current away from the array of nanoantennas. | 09-26-2013 |