Patent application number | Description | Published |
20090194147 | DUAL SEAL PHOTOVOLTAIC ASSEMBLY AND METHOD - A photovoltaic assembly including first and second substrates joined together and spaced apart, on either side of an airspace, by a seal system formed of a first seal and a second seal, the second seal comprising one or more silyl terminated polyacrylate polymers. A photovoltaic functional coating is disposed over a second major surface of one of the substrates, which faces the second major surface of the other substrate. Lead wires are coupled to bus bars and/or electrical contacts affixed to the functional coating and routed out from the airspace. Affixing the seal system to the first and second substrates, in order to join the substrates together, may be accomplished by applying pressure to the substrates. | 08-06-2009 |
20090194156 | DUAL SEAL PHOTOVOLTAIC GLAZING ASSEMBLY AND METHOD - A photovoltaic glazing assembly including first and second substrates joined together and spaced apart, on either side of an airspace, by a seal system formed of a first seal and a second seal. A photovoltaic functional coating is disposed over a second major surface of one of the substrates, which faces the second major surface of the other substrate. Lead wires are coupled to bus bars and/or electrical contacts affixed to the functional coating and routed out from the airspace. Affixing the seal system to the first and second substrates, in order to join the substrates together, may be accomplished by applying pressure to the substrates. | 08-06-2009 |
20090320921 | Photovoltaic Glazing Assembly and Method - A photovoltaic glazing assembly including first and second substrates, at least one being formed of a light transmitting material. The assembly includes a photovoltaic coating over at least the central region of a surface of the first substrate or the second substrate. In some embodiments, a seal system encloses a gas space between the substrates and optionally has a thickness of between approximately 0.01 inch and approximately 0.1 inch. Certain embodiments provide a flexible and electrically non-conductive retention film over the photovoltaic coating. Additionally or alternatively, the assembly can have a peripheral seal system with relative dimensions in certain ranges. Advantageous manufacturing methods are also provided. | 12-31-2009 |
20140165484 | Glazing Unit Spacer Technology - The invention provides a spacer having an engineered wall with multiple corrugation fields including first and second corrugation fields having differently configured corrugations. Also provided are multi-pane glazing units that incorporate such a spacer. | 06-19-2014 |
20140352841 | INSULATING GLASS UNIT FILLED WITH ADSORBABLE GAS - An insulating glass unit may be fabricated by filling the space between opposed panes of glass with multiple types of gases and then sealing the gases in the space. A spacer containing a gas adsorption material may be positioned between the panes of glass to seal the gases in the space. In some examples, the gas adsorption material is configured to selectively adsorb one of the gases introduced into the space but substantially none of another of the gases introduced into the space. As a result, the gas pressure in the insulating glass unit may reduce below the initial filling pressure after fabrication of the unit due to adsorption. Such gas pressure reduction may be useful, for example, if the insulating glass unit is going to be used at a higher elevation location where the air pressure is lower. | 12-04-2014 |
Patent application number | Description | Published |
20130318892 | INSULATING GLASS UNIT WITH ASYMMETRICAL BETWEEN-PANE SPACES - An insulating glass unit may include at least three panes of transparent material and at least two spacers positioned between different panes of the unit. For example, a first spacer may hold a first pane of transparent material a first separation distance from a second pane of transparent material and a second spacer may hold the second pane of transparent material a second separation distance from a third pane of transparent material. In some examples, the insulating glass unit is configured so that the first separation distance is greater than the second separation distance. In such examples, the insulating glass unit may have a comparatively larger first between-pane space and a comparatively smaller second between-pane space. In some applications, the insulating glass unit may exhibit thermal and sound insulating properties approximately equal to a triple-pane insulating glass unit while having size characteristics approximately equal to a double-pane insulating glass unit. | 12-05-2013 |
20130319598 | ASYMMETRICAL INSULATING GLASS UNIT AND SPACER SYSTEM - An insulating glass unit may include a spacer positioned between opposing panes of material to define a between-pane space. The spacer may seal the between-pane space from gas exchange with a surrounding environment and hold the opposing panes in a spaced-apart relationship. In some examples, the spacer includes a primary sealant layer, a secondary sealant layer, and a gas diffusion barrier layer positioned between the primary sealant layer and the secondary sealant layer. The gas diffusion barrier layer may define a first side and a second side opposite the first side. Depending on the application, the first side of the gas diffusion barrier layer may be positioned in contact with the primary sealant layer while the second side of the gas diffusion barrier layer is positioned in contact with the secondary sealant layer. | 12-05-2013 |
20140083026 | INSULATING GLASS UNIT WITH ASYMMETRICAL BETWEEN-PANE SPACES - An insulating glass unit may include at least three panes of transparent material and at least two spacers positioned between different panes of the unit. For example, a first spacer may hold a first pane of transparent material a first separation distance from a second pane of transparent material and a second spacer may hold the second pane of transparent material a second separation distance from a third pane of transparent material. In some examples, the insulating glass unit is configured so that the first separation distance is greater than the second separation distance. In such examples, the insulating glass unit may have a comparatively larger first between-pane space and a comparatively smaller second between-pane space. In some applications, the insulating glass unit may exhibit thermal and sound insulating properties approximately equal to a triple-pane insulating glass unit while having size characteristics approximately equal to a double-pane insulating glass unit. | 03-27-2014 |
Patent application number | Description | Published |
20080205829 | Ultra-high density connector - Techniques for ultra-high density connection are disclosed. In one embodiment, an ultra-high density connector includes a bundle of substantially parallel elongate cylindrical elements, where each cylindrical element is substantially in contact with at least one adjacent cylindrical element. Ends of the elongate cylindrical elements are disposed differentially with respect to each other to define a three-dimensional interdigitating mating surface. At least one of the elongate cylindrical elements has an electrically conductive contact positioned to tangentially engage a corresponding electrical contact of a mating connector. | 08-28-2008 |
20080245424 | Micro fluid transfer system - A micro fluid transfer system for transferring fluid within a micro-environment, wherein the micro fluid transfer system comprises: (a) an elongate body having first and second ends and an outer surface; (b) a plurality of bores formed within the elongate body, the bores extending along at least a portion of a length of the elongate body for carrying fluid therein; and (c) at least one interconnecting slot intercepting at least two of the plurality of bores within the elongate body at a strategic, pre-determined location and orientation so as to fluidly connect the at least two bores and to define a plurality of potential fluid passageways through the elongate body. The micro fluid transfer system further comprises at least one access slot intercepting one of the plurality of bores within the elongate body at a strategic, pre-determined location and orientation so that the access slot and the bore are in fluid communication with one another, the access slot further defining additional potential fluid passageways within the elongate body. The micro fluid transfer system further comprises at least one rod disposed within each of the plurality of bores, the rod being selectively positioned to define a particular pre-determined fluid passageway and subsequent fluid flow path and to manipulate and control fluid flow through the fluid flow path. | 10-09-2008 |
20090204195 | Multi-Element Probe Array - A multi-element probe array suitable for sensing or stimulating is disclosed. In one embodiment, the multi-element probe array includes a plurality of microfibers extending longitudinally and oriented substantially parallel to form a bundle. Probe elements are defined by a first subset of the microfibers displaced in a forward direction along the longitudinal axis relative to spacer elements defined by a second subset of the microfibers. Interface elements and communication elements are disposed on the probe elements. | 08-13-2009 |
20100112865 | Ultra-High Density Connector - Techniques for ultra-high density connection are disclosed. In one embodiment, an ultra-high density connector includes a bundle of substantially parallel elongate cylindrical elements, where each cylindrical element is substantially in contact with at least one adjacent cylindrical element. Ends of the elongate cylindrical elements are disposed differentially with respect to each other to define a three-dimensional interdigitating mating surface. At least one of the elongate cylindrical elements has an electrically conductive contact positioned to tangentially engage a corresponding electrical contact of a mating connector. | 05-06-2010 |
20100116869 | Electrical Microfilament to Circuit Interface - Devices and methods for electrical interconnection for microelectronic circuits are disclosed. One method of electrical interconnection includes forming a bundle of microfilaments, wherein at least two of the microfilaments include electrically conductive portions extending along their lengths. The method can also include bonding the microfilaments to corresponding bond pads of a microelectronic circuit substrate to form electrical connections between the electrically conductive portions and the corresponding bond pads. A microelectronic circuit can include a bundle of microfilaments bonded to corresponding bond pads to make electrical connection between corresponding bonds pads and electrically-conductive portions of the microfilaments. | 05-13-2010 |
20110310577 | ELECTRICAL MICROFILAMENT TO CIRCUIT INTERFACE - Devices and methods for electrical interconnection for microelectronic circuits are disclosed. One method of electrical interconnection includes forming a bundle of microfilaments, wherein at least two of the microfilaments include electrically conductive portions extending along their lengths. The method can also include bonding the microfilaments to corresponding bond pads of a microelectronic circuit substrate to form electrical connections between the electrically conductive portions and the corresponding bond pads. A microelectronic circuit can include a bundle of microfilaments bonded to corresponding bond pads to make electrical connection between corresponding bonds pads and electrically-conductive portions of the microfilaments. | 12-22-2011 |
Patent application number | Description | Published |
20090062639 | Automated vessel repair system, devices and methods - Systems, devices and automated methods for minimally invasive surgery. A device is fabricated of bio-compatible semiconductor elements, and can be assembled, delivered, navigated and implanted by automated methods, using Nuclear Magnetic Resonance (NMR) technology. | 03-05-2009 |
20140046146 | ANALYSIS & CLEARING MODULE, SYSTEM AND METHOD - Modules, systems and methods for clearing substances from a living body are disclosed. A module may include an instructions receiver configured to receive wireless transmissions of instructions from a master controller located outside of the body when the module is inside the body; an energy receiver configured to receive wireless transmission of non-destructive energy from the master controller located outside of the body when the module is inside the body; an energy converter configured to convert the non-destructive energy received to destructive energy; and an energy emitter configured to emit the destructive energy. | 02-13-2014 |
20150230878 | Automated Vessel Repair System, Devices and Methods - Systems, devices and automated methods for minimally invasive surgery. A device is fabricated of bio-compatible semiconductor elements, and can be assembled, delivered, navigated and implanted by automated methods, using Nuclear Magnetic Resonance (NMR) technology. | 08-20-2015 |