Patent application number | Description | Published |
20080210576 | Multilayer gas sensor having dual heating zones - A gas sensor for detecting NO | 09-04-2008 |
20080265870 | Particulate Matter Sensor - A sensor apparatus to burn off contaminating particulate matter from a sensor. The sensor apparatus includes a signal electrode assembly, a detector electrode assembly, and an electrical heater. The signal electrode assembly includes a signal electrode coupled to a signal electrode insulating substrate. The detector electrode assembly includes a detector electrode coupled to a detector electrode insulating substrate. The detector electrode is positioned relative to the sensor electrode to generate a measurement of an ambient condition. The electrical heater is positioned relative to the signal and detector electrode assemblies to burn off an accumulation of contaminating particles from at least one electrode assembly of the signal and detector electrode assemblies. | 10-30-2008 |
20090056416 | Ceramic Particulate Matter Sensor With Low Electrical Leakage - A ceramic particulate matter sensor to measure particulate matter within an exhaust stream. The particulate matter sensor includes a high voltage electrode on a first conductive layer and a detection electrode on a second conductive layer within a stack of ceramic layers. The stack of ceramic layers is bonded as a single rigid structure. The detection electrode generates a measurement of particulate matter within an exhaust stream. The particulate matter sensor also includes an insulating material positioned adjacent to the second conductive layer to insulate the detection electrode from another conductive layer within the stack of ceramic layers. The particulate matter sensor also includes an electrical heater to burn off an accumulation of contaminating particulate matter from at least one electrode of the high voltage and detection electrodes. The particulate matter sensor also includes means for substantially preventing electrical leakage through the insulating material to the second conductive layer. | 03-05-2009 |
20090065370 | AMMONIA GAS SENSOR METHOD AND DEVICE - A mixed potential sensor device and methods for measuring total ammonia (NH | 03-12-2009 |
20090211333 | Sensor assembly having a flow head - A flow head for a gas sensor having a sensing element is provided. The flow head includes a body at least partially defining a cavity in thermal communication with the sensing element. The body includes an inlet port located within an annular surface of the body and an outlet port located within the annular surface of the body. The body also includes an inlet passage offset from and parallel to the cavity, wherein the inlet passage configures the inlet port and the cavity to be in fluid communication with one another. The body further includes an outlet passage offset from and parallel to the cavity, wherein the outlet passage configures the outlet port and the cavity to be in fluid communication with one another. | 08-27-2009 |
20090294285 | Co-fired gas sensor - A sensor for detecting a gas is provided. The gas sensor may have a sensing section, a heating section, and a resistance temperature detector. The resistance temperature detector may be co-fired to be integral with at least one of the sensing section and the heating section. | 12-03-2009 |
20100050739 | Sintered and bonded multilayer sensor - A gas sensor may include a sintered heating component which includes a ceramic insulating material, and a separately sintered sensing component which includes an ionically conductive material. The sensor may also include a bond attaching the sensing component to the heating component. The bond may be made of bonding material which is different from the insulating material and the ionically conductive material. | 03-04-2010 |
20100096264 | MULTILAYER CERAMIC NOx GAS SENSOR DEVICE - A mixed potential NO | 04-22-2010 |
20100122916 | Sensor with electrodes of a same material - A sensor for monitoring concentration of a constituent in a gas may include an ionically conductive layer and a sensing electrode coupled to the ionically conductive layer. The sensing electrode may be exposed to a gas. The sensor may also include a reference electrode that is exposed to the gas and made of substantially a same material as the sensing electrode. | 05-20-2010 |
20100255289 | Aluminosilicate-Based Oxide Composite Coating and Bond Coat for Silicon-Based Ceramic Substrates - An article is disclosed in one embodiment of the invention as including a silicon-based ceramic substrate and a top coat. A bond coat is provided between the silicon-based ceramic substrate and the top coat. The bond coat is derived from a mixture containing preceramic polymer precursors, such as polycarbosilanes, polycarbosilazanes, or other silicocarbon polymers and pyrolyzed preceramic polymer precursors. A filler material may also be included in the mixture to modify the coefficient of thermal expansion (CTE) of the bond coat to more closely match the CTE of the silicon-based ceramic substrate, top coat, or both. | 10-07-2010 |
20100264025 | PARTICULATE MATTER SENSOR WITH AN INSULATING AIR GAP - An electrode assembly for a particulate matter sensor in a gas environment. The electrode assembly includes an insulating tube, a conductor, and a positioning structure. The insulating tube has an outer surface and defines an interior cavity with an interior surface. The conductor is disposed within the interior cavity of the insulating tube. The conductor is electrically coupled to an electrode at a first end of the insulating tube and includes a contact portion at a second end of the insulating tube for connection to an external conductor. The positioning structure is coupled to the conductor. The positioning structure mechanically supports the conductor at a distance from the interior surface of the insulating tube to at least partially define an air dielectric gap at approximately a heater location corresponding to a heater. The positioning structure has an outer diameter approximately equal to an inner diameter of the insulating tube and has an inner diameter approximately equal to an outer diameter of the conductor. | 10-21-2010 |
20120175042 | Method For Joining Ceramic Components - A method for joining multiple ceramic components together is disclosed in one embodiment of the invention as including providing multiple ceramic components, each having a mating surface. A slip containing a mixture of alumina powder and a phosphate-containing reagent is applied to one or more of the mating surfaces. The mean particle size of the alumina powder is tailored to provide improved strength to the bond. Once the slip is applied, the ceramic components may be joined together at their mating surfaces. The joint may then be sintered to react the constituents in the mixture and thereby generate a bond between the ceramic components. | 07-12-2012 |