CARDINAL IG COMPANY Patent applications |
Patent application number | Title | Published |
20150301366 | GLAZING UNIT COMPRISING A VARIABLE LIGHT SCATTERING SYSTEM AND A PAIR OF ABSORBING ELEMENTS - The invention relates to a glazing unit comprising a substrate coated with a variable light scattering system switching between a transparent state and a translucent state comprising a scattering layer able to scatter the incident light along scattering angles greater than the critical total internal reflection angle at the interface between the substrate and the air and at least one pair of elements absorbing visible light separated from one another at least by the scattering layer. The invention also relates to the use of said glazing unit as a projection or back-projection screen. | 10-22-2015 |
20150049270 | POWER SUPPLY OF AN ELECTRICALLY CONTROLLABLE LIQUID CRYSTAL GLAZING, AND METHOD FOR POWERING SUCH A GLAZING - An electrically-controlled liquid crystal glazing unit can include a substrate carrying a liquid crystal element disposed between a first electrode and a second electrode connected to an electrical power supply. The liquid crystal element can transform from a diffusing state at zero voltage to a transparent and/or colored state at a sinusoidal AC voltage having an operating amplitude (V | 02-19-2015 |
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 |
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 |
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 |
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 |
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 |
20130215413 | SYSTEM AND METHOD FOR MEASURING PROPERTIES OF A THIN FILM COATED GLASS - A system for measuring properties of a thin film coated glass having a light source, a spectrometer, at least one pair of probes, a first optical fiber switch and a second optical fiber switch. The pair of probes includes a first probe located on one side of a glass sheet and a second probe located on the opposite side of the glass sheet, directly across from the first probe. The first and second optical fiber switches are adapted to couple either probe to the light source and/or the spectrometer. Because the design of the system is optically symmetrical, calibration may be performed without the use of a reference material such as a tile or mirror. | 08-22-2013 |
20110154635 | METHODS AND EQUIPMENT FOR ASSEMBLING TRIPLE-PANE INSULATING GLASS UNITS - Embodiments of the present invention provide methods and equipment for automatically assembling three panes of glass and corresponding spacers so that air or other gas can be injected into the two between-pane spaces. The equipment can receive two glass panes that each have spacers coupled to one of their major surfaces, along with a third glass pane having no spacer coupled to its major surfaces, and can assemble the three glass panes into a “teepee” configuration in which the two spacers each contact two of the glass panes along a common edge of the glass panes. Preferred equipment can receive a glass pane in a first orientation and rotate the glass pane 180° to a second orientation in which the glass pane's two major surfaces face opposite directions from the first orientation. Such preferred equipment can then receive a two-pane teepee from a previous piece of equipment and can add the “flipped” single glass pane to the teepee to create a three-pane teepee. | 06-30-2011 |
20090255627 | MANUFACTURING OF PHOTOVOLTAIC SUBASSEMBLIES - Some methods, and corresponding apparatus, for manufacturing photovoltaic subassemblies cause a plurality of desiccant beads to be adhered to an adhesive surface of sheet-like material; the sheet-like material is then, preferably, adhered to an exposed surface of a flexible and electrically non-conductive film, that covers a photovoltaic coating of a first substrate of the subassembly, such that the desiccant beads are held between the sheet-like material and the exposed surface. Some other methods, either alternatively or in addition to the above, include steps for applying the film, that covers the photovoltaic coating, wherein an opening, through the film, is cut, and then aligned, with lead wires of the photovoltaic coating, in the midst of applying the film. | 10-15-2009 |
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 |
20090098317 | Standard Insulating Glass Units Having Known Concentrations of a Gas and Methods for Calibrating a Measuring Device Using the Standard Insulating Glass Units - A calibration technique for a measurement device that produces a spark in an interpane space of an insulating glass unit to determine the content of an inert gas, in particular, argon. Standard calibration units are created which have the same construction as an IGU produced an assembly line. The standard calibration units are filled with varying percentages of argon/oxygen mixture. The calibration technique can be performed on an assembly line by aiming the measurement device at a particular insulating glass unit produced on the assembly line. The measurement device is activated to take a reading of the unit on the line. One of a plurality of calibration standard units of insulating glass units is selected that has substantially an identical construction as the unit on the line except that the calibration standard unit selected has a known, specific amount of certified argon gas that should be the same as the unit on the line. The measurement device is aimed at the calibration standard unit. The measurement device is activated to take a reading of the calibration standard unit. The measurement taken of the calibration standard unit is compared to the known amount of argon gas in the standard calibration unit. And, finally adjusting the calibration of the measurement device if the comparison shows a discrepancy. | 04-16-2009 |