Patent application number | Description | Published |
20090261962 | Tire Sensor Module and Method for its Manufacture - A tire sensor module having a circuit carrier, on or in which at least one sensor element is attached for measuring a measured variable, an antenna for transmitting sensor signals to a receiving unit of the vehicle, and a housing, in whose housing inner chamber the circuit carrier is received, the antenna being provided in the housing material of the housing or on a housing side of the housing. | 10-22-2009 |
20100007360 | FLUID SENSOR DEVICE - The invention provides a fluid sensor device ( | 01-14-2010 |
20100085068 | SENSOR DEVICE FOR DETECTING ELECTRICAL PROPERTIES OF A FLUID - The sensor device for detecting electrical properties of a fluid under high pressure has: a pressure-tight housing, whose cavity is connectable to a high pressure line via an opening, a sensor for electrical properties, which is situated in the cavity, glass feedthroughs, which electrically connect the contacts on an external surface of the housing to the sensor. | 04-08-2010 |
20100176969 | SENSOR SYSTEM AND METHOD FOR OPERATING A SENSOR SYSTEM - A sensor system having a sensor module and an induction unit is provided, the sensor module having a first antenna, and the induction unit having a second and a third antenna, an induction transmission of signals being provided between the first and the second antenna, and the signals being sent and/or received electromagnetically by the third antenna. | 07-15-2010 |
20100291394 | INJECTION MOLDED PLASTIC COMPONENT HAVING AN INSERT - An injection molded plastic component having at least one metallic, at least partially extrusion coated insert. It is provided that the insert has a pre-molded part, at least in the extrusion coated area, whose melting point is lower than or equal to the temperature of the plastic component during injection molding. | 11-18-2010 |
20110102000 | CAPACITIVE MEASURING PROBE AND METHOD FOR PRODUCING A CAPACITIVE MEASURING PROBE - The capacitive measuring probe has the following: two electrodes, a plastic casing which encapsulates the two electrodes, the plastic casing having at least one section made of a conductive plastic, which is electrically connected to one of the two electrodes. | 05-05-2011 |
20110156726 | MEASURING SENSOR, FUEL FEED LINE AND METHOD FOR MANUFACTURING A MEASURING SENSOR - A measuring sensor has a hollow body through which a fluid is able to flow. Two sections of a wall of the hollow body form electrodes for a capacitive and/or a resistive measurement and the electrodes are made of a conductive plastic. The measuring sensor may be used in a fuel feed line. A method for manufacturing is also described. | 06-30-2011 |
20110308304 | LIQUID SENSOR - A fluid sensor includes a metal housing body, which has a box and a flanged ring circumferentially surrounding the box. A housing jacket is formed from plastic material and disposed on an exterior side of the housing body. A sealing ring, which is situated circumferentially on top of the flanged ring, subdivides the housing jacket into two sections that are insulated from each other. | 12-22-2011 |
20120017692 | Pressure sensor and method for manufacturing a pressure sensor - A peripheral pressure sensor for a motor vehicle has a sensor chip and a gasket sealing a sensing unit of the sensor chip from the surroundings, which gasket has a pressure channel through which pressure information is transmitted to the sensing unit of the sensor chip. The peripheral pressure sensor is made by an injection molding method in which an opening in the gasket is placed on the sensing unit of the sensor chip, and subsequently an assembly of the sensor chip and the gasket is surrounded by extrusion coating such that an outer edge opposite the sensing unit and/or an outer opening in the gasket remains at least partially free. | 01-26-2012 |
20140209642 | UNIT FOR STORING A FLUID, AND METHOD FOR PRODUCING A UNIT FOR STORING A FLUID - A unit for storing a fluid includes a body, a piston, and a closure. The body has a through-channel in which the fluid is arranged. The body is impermeable to the fluid and/or constituents thereof and is configured to connect in a fluid-tight manner to a receiving device of a biochemical analysis unit. The through-channel extends from a first end to a second end. The piston is mounted to be axially movable in the through-channel and is configured to provide a fluid-tight seal relative to the body. The piston is impermeable to the fluid and/or constituents thereof and is accessible from the first end. The closure is arranged on the second end and is impermeable to the fluid and constituents thereof. The closure is connected to the body in a fluid-tight manner and is configured to burst when a pressure in the fluid exceeds a bursting pressure. | 07-31-2014 |
Patent application number | Description | Published |
20090116534 | METHOD FOR OPERATING A GAS SENSOR - The invention relates to a method for operating a sensor, in particular a sensor made of ceramic material. Said sensor is heated to a shock-resistance temperature which is higher than a specific temperature. | 05-07-2009 |
20090217745 | EXHAUST GAS SENSOR - Exhaust-gas sensors that have a sensor element, which is surrounded by two protective tubes on a side facing the exhaust gas and which is additionally protected by a porous fiber package, are already known. The fiber package is disposed between the two protective tubes and is meant to protect the sensor element from thermal shock by water droplets hitting the sensor element. When the exhaust gas sensor is used as primary catalytic converter or raw emission sensor, the sensor element can get damaged by sulfur compounds contained in the exhaust gas. In the exhaust-gas sensor according to the invention, damage to the sensor element by exhaust-gas components contained in the exhaust gas is reliably prevented. According to the invention, the adsorption means is implemented in such a way that sulfur, phosphorus or silicon compounds are trapped irreversibly. | 09-03-2009 |
20130283786 | TURBOCHARGER FOR USE IN AN INTERNAL COMBUSTION ENGINE - A turbocharger for use in an internal combustion engine has at least one turbocharger housing, at least one compressor situated inside the turbocharger housing, and at least one turbine situated inside the turbocharger housing. In addition, the turbocharger has at least one sensor device for detecting at least a portion of a gas component of an exhaust gas of the internal combustion engine. The sensor device is at least partially integrated into the turbocharger housing. | 10-31-2013 |
20140026562 | TURBINE FOR AN INTERNAL COMBUSTION ENGINE - A turbine may include a turbine housing having an inlet opening and an outlet opening, and defining a housing interior space configured to be subjected to a through-flow of exhaust gas from an internal combustion engine. A turbine rotor may be rotatably mounted in the turbine housing about an axis of rotation defining an axial direction. An exhaust gas sensor may be arranged in a measurement space of the turbine housing the exhaust gas sensor configured to determine at least one part of a gas component of the exhaust gas carried in the turbine housing. A feed line may be arranged in the turbine housing having a feed opening and a discharge line arranged in the turbine housing having a discharge opening for feeding and discharging exhaust gas at least one of in and out of the measurement space. | 01-30-2014 |
20140060926 | Contact element and method for manufacturing same - A contact element for contacting a contact point formed on a body includes: an element section on the contact point side for a force-locking connection to the contact point, an element section on the connection side for connection to an electrical connection conductor, and an intermediate section which connects the two element sections to one another for compensating for thermal expansions. At least the element sections on the contact point side and on the connection side are made of different integrally bonded materials having material properties which are adapted to the functionality of the corresponding element section. | 03-06-2014 |
Patent application number | Description | Published |
20100047515 | Honeycomb Core Having a High Compression Strength and Articles Made from the Same - This invention is directed to a honeycomb core structure having a high compression modulus. The core structure comprises (a) a plurality of interconnected walls having surfaces which define a plurality of honeycomb cells, wherein the cell walls are formed from a nonwoven sheet and (b) a cured resin in an amount such that the weight of cured resin as a percentage of combined weight of cured resin and nonwoven sheet is at least 62 percent. The nonwoven sheet further comprises fibers having a modulus of at least 200 grams per denier (180 grams per dtex) and a tenacity of at least 10 grams per denier (9 grams per dtex) wherein, prior to impregnating with the resin, the nonwoven sheet has an apparent density calculated from the equation Dp=K×((dr×(100−% r)/% r)/(1+dr/ds×(100−% r)/% r), where Dp is the apparent density of the sheet before impregnation, dr is the density of cured resin, ds is the density of solid material in the sheet before impregnation, % r is the cured resin content in the final core structure in weight %, K is a number with a value from 1.0 to 1.5. Further, the Gurley porosity of the nonwoven sheet before impregnation with the resin is no greater than 30 seconds per 100 milliliters. The invention is also directed to composite structures incorporating such folded core. | 02-25-2010 |
20100048078 | Folded Core Having a High Compression Modulus and Articles Made from the Same - This invention is directed to a folded tessellated core structure having a high compression modulus. The core structure comprises a nonwoven sheet and a cured resin in an amount such that the weight of cured resin as a percentage of combined weight of cured resin and nonwoven sheet is at least 50 percent, The nonwoven sheet further comprises fibers having a modulus of at least 200 grams per denier (180 grams per dtex) and a tenacity of at least 10 grams per denier (9 grams per dtex) wherein, prior to impregnating with the resin, the nonwoven sheet has an apparent density calculated from the equation Dp=K×((dr×(100−% r)% r)/(1+dr/ds×(100−% r)% r), where Dp is the apparent density of the sheet before impregnation, dr is the density of cured resin, ds is the density of solid material in the sheet before impregnation, % r is the cured resin content in the final core structure in weight %, K is a number with a value from 1.0 to 1.5, Further, the Gurley porosity of the nonwoven sheet before impregnation with the resin is no greater than 30 seconds per 100 milliliters. The invention is also directed to composite structures incorporating such folded core. | 02-25-2010 |
20110244175 | Honeycomb Core Having a High Compression Strength and Articles Made from the Same - This invention is directed to a honeycomb core structure having a high compression modulus. The core structure comprises (a) a plurality of interconnected walls having surfaces which define a plurality of honeycomb cells, wherein the cell walls are formed from a nonwoven sheet and (b) a cured resin in an amount such that the weight of cured resin as a percentage of combined weight of cured resin and nonwoven sheet is at least 62 percent. The nonwoven sheet further comprises fibers having a modulus of at least 200 grams per denier (180 grams per dtex) and a tenacity of at least 10 grams per denier (9 grams per dtex) wherein, prior to impregnating with the resin, the nonwoven sheet has an apparent density calculated from the equation Dp=K×((dr×(100−%r)/%r)/(1+dr/ds×(100−%r)/%r), where Dp is the apparent density of the sheet before impregnation, dr is the density of cured resin, ds is the density of solid material in the sheet before impregnation, % r is the cured resin content in the final core structure in weight %, K is a number with a value from 1.0 to 1.35. Further, the Gurley porosity of the nonwoven sheet before impregnation with the resin is no greater than 30 seconds per 100 milliliters. The invention is also directed to composite structures incorporating such folded core. | 10-06-2011 |