Class / Patent application number | Description | Number of patent applications / Date published |
374161000 |
Change of optical property
| 113 |
374160000 |
Melting or softening | 5 |
20090097528 | APPARATUS, SYSTEM, AND METHOD FOR DETECTING TEMPERATURE THRESHOLD EVENTS IN AN AFTERTREATMENT DEVICE - An apparatus, system, and method are disclosed for detecting temperature threshold events in an aftertreatment device. The system may include an aftertreatment device configured to treat an exhaust gas of an internal combustion engine and a temperature responder disposed within a region of interest of the aftertreatment device. The temperature responder is configured to melt at a threshold temperature. The system may further include two access points electrically coupled to the temperature responder and an observation module configured to measure an electrical resistance value across the two access points. The observation module detects the melting of the temperature responder based on the electrical resistance value measured across the access points. In alternate embodiments the observation module is included within an engine control module (ECM) or a service tool. | 04-16-2009 |
20120027045 | PASSIVE THERMAL MONITORING SYSTEMS AND METHODS OF MAKING AND USING THE SAME - The present invention is directed to passive thermal monitoring devices, and methods of making and using the passive thermal monitoring devices. | 02-02-2012 |
20120201270 | MULTI-STAGE TEMPERATURE INDICATING DEVICE - A multi-stage temperature indicating device having a housing having a bore formed therein having a closed end and an open end, the housing having a first neck region spaced from the closed end, a first internal cavity between the first neck region and the closed end, a second internal cavity between the first neck region and the open end; an indicator rod comprising a first stem stretch and a second stem stretch; an extension segment having a first extension stretch and a second extension stretch, the second extension stretch slidably cooperating with the first stem stretch; the indicator rod and the extension segment slidably positioned in the bore; and a fusible material retaining the indicator rod and the extension segment in the housing, wherein different portions of the fusible material soften at different predetermined temperatures, whereby upon the softening of a first portion of the fusible material allows a spring to urge the indicator rod a first distance out of the housing indicating that a first temperature has been reached and upon the softening of a second portion of the fusible material allows the spring to urge the indicator rod a second distance out of the housing indicating that a second temperature has been reached. | 08-09-2012 |
20120307865 | INTERNAL TEMPERATURE INDICATOR - A temperature indicator having a tubular structure; a float or floating particles releasably held in place in the tubular structure by a temperature dependent material that is activated at or about a critical temperature, the float or floating particles having a first density; and a fluid within the tubular structure, the fluid having a second density that is less than the first density. When the temperature indicator is heated to the critical temperature, the temperature dependent material activates and releases the float or the floating particles, which rise in the fluid so as to be visible as in indicator that the critical temperature has been reached. | 12-06-2012 |
20160161345 | EUTECTIC BASED CONTINUOUS THERMAL SENSING ELEMENT INCLUDING FIBER WRAPPED CENTER CONDUCTOR - A eutectic sensing element includes an electrically conductive core extending along a first axis to define a length. The core is coated with a coated with a eutectic material formulated to provide desirable thermal response characteristics. The eutectic sensing element further includes an insulating fiber layer disposed on an external surface of the electrically conductive. The insulating fiber layer includes a strand that extends along the length of the electrically conductive core. | 06-09-2016 |
Entries |
Document | Title | Date |
20090016406 | NOVEL METHOD FOR MONITORING AND CALIBRATING TEMPERATURE IN SEMICONDUCTOR PROCESSING CHAMBERS - The present invention provides a non-destructive method for monitoring and calibrating chamber temperature. One embodiment of the present invention provides a method for measuring temperature comprising forming a target film on a test substrate at a first temperature, wherein the target film has one or more properties responsive to thermal exposure, exposing the target film to an environment at a second temperature in a range higher than the first temperature, measuring the one or more properties of the target film after exposing the target film to the environment at the second temperature, and determining the second temperature according to the measured one or more properties. | 01-15-2009 |
20090245326 | FLUORESCENCE TEMPERATURE SENSOR - To provide a fluorescent temperature sensor wherein light is propagated reliably with an easy adjustment. A fluorescent temperature sensor for producing a temperature signal from fluorescent light of an optically excited fluorescent material includes: a light emitting device for projecting light to the fluorescent material; a photoreceiving element for receiving fluorescent light emitted from the fluorescent material | 10-01-2009 |
20090323762 | HIGH-SPEED SPECTROGRAPHIC SENSOR FOR INTERNAL COMBUSTION ENGINES - A high-speed absorption spectrographic system employs a slit-less spectroscope to obtain high-resolution, high-speed spectrographic data of combustion gases in an internal combustion engine allowing precise measurement of gas parameters including temperature and species concentration. | 12-31-2009 |
20120039357 | FIBER-OPTIC TEMPERATURE SENSOR ASSEMBLY - A fiber-optic temperature sensor assembly comprises a cap with an inner cavity. A sensor substance is received loosely in the inner cavity of the cap, the sensor substance having light-emitting properties adapted to change with specific temperature variations. An optical fiber has a first end received in the inner cavity of the cap and fusion spliced thereto, and a second end of the optical fiber being adapted to be connected to a processing unit for transmitting light signals from the sensor substance to the processing unit when the fiber-optic temperature sensor assembly is subjected to specific temperatures. A method for manufacturing the fiber-optic temperature sensor assembly is defined. | 02-16-2012 |
20120044970 | Temperature-Responsive Photonic Crystal Device - A temperature-responsive photonic crystal device comprising having a temperature-responsive photonic crystal material, whereby exposure of the device to a temperature above a predetermined threshold temperature is indicated by a detectable change in the device. | 02-23-2012 |
20120128028 | Method of Measuring the Temperature of a Sample Carrier in a Charged Particle-Optical Apparatus - A method of determining the temperature of a sample carrier in a charged particle-optical apparatus, characterized in that the method comprises the observation of the sample carrier with a beam of charged particles, the observation giving information about the temperature of the sample carrier. The invention is based on the insight that a charged particle optical apparatus, such as a TEM, STEM, SEM or FIB, can be used to observe temperature related changes of a sample carrier. The changes may be mechanical changes (e.g. of a bimetal), crystallographic changes (e.g. of a perovskite), and luminescent changes (in intensity or decay time). In a preferred embodiment the sample carrier shows two bimetals, showing metals with different thermal expansion coefficients, bending in opposite directions. The distance between the two bimetals is used as a thermometer. | 05-24-2012 |
20120155509 | ELECTRODE MEMBER, ELECTRON ENERGY ANALYZER, PHOTOELECTRON ENERGY ANALYZER, AND TEMPERATURE MEASURING APPARATUS - Disclosed is an electrode member which has spherical sections, each of which configures a part of a sphere, and a plurality of spherical electrode sections wherein the radiuses of the spherical sections are different from each other. The spherical electrode sections are disposed in a state wherein the center points of the respective spheres match each other and the spherical electrode sections are insulated from each other such that voltages can be independently applied thereto. Electron-passing openings for straightly taking out electrons, which are moving from the center point, to the outside of the electrode are formed at positions where the spherical electrode sections and a plurality of straight lines radially extending from the center point intersect each other. | 06-21-2012 |
20130301679 | Use of a Coordination Complex or Compound for the Measurement of Temperature - Use for measuring temperatures of a coordination complex presenting formula I, wherein M | 11-14-2013 |
20130322489 | SENSOR ARRANGEMENT FOR THE MEASURING OF PARAMETERS IN MELTED MATERIAL - A sensor arrangement for melted materials includes an upper part and a detachable lower part. A tube extends coaxial to a longitudinal axis of the lower part, is closed on its end facing away from the upper part, and is open on the other end. The tube is arranged on an immersion end of the lower part facing away from the upper part. A guide tube, extending coaxial to a longitudinal axis of the upper part and being open on both ends, is arranged in a guide sleeve. A pressure acting in the direction of the lower part is applied to the guide tube by an elastic body and the guide tube touches against the lower part. One opening of the guide tube and the open end of the tube of the lower part are arranged adjacent to each other and coaxial to the longitudinal axis of the lower part. | 12-05-2013 |
20130329766 | METHOD FOR CALCULATING A THERMAL PROTECTION FACTOR - The present invention relates to a method for calculating a thermal protection factor, wherein the method comprises the steps of: applying heat to a first area coated with a thermal protection material, and a second area not coated with the thermal protection material; measuring the respective saturation temperatures of the first area and second area; calculating a first energy by dividing the energy corresponding to the heat applied to the first area by the saturation temperature of the first area; calculating a second energy by dividing the energy corresponding to the heat applied to the second area by the saturation temperature of the second area; and calculating the thermal protection factor of a thermal protection material by dividing the first energy by the second energy or dividing the difference between the first energy and the second energy by the first energy. | 12-12-2013 |
20140211829 | TEMPERATURE INDICATOR FOR ELECTRICAL EQUIPMENT - A system for determining when an electrical contact or other component reaches a predetermined temperature. In operation, a trace material is dispersed into a surrounding environment (e.g., head space within a compartment above insulating oil), where the trace material is detected. A barrier may be ruptured or broken by temperature-induced gas pressure, or pierced by a spring-loaded member that is located within the same section that contains the trace material, and devices may be provided for moving the trace material through the foil barrier as the barrier is ruptured. The barrier may be opened solely by internal gas pressure. According to another embodiment, improved fail-safe operation may be achieved by providing a spring-loaded member and configuring the barrier to be ruptured by the pressure of the detectable gas material before the barrier is ruptured by the spring-loaded member. | 07-31-2014 |
20160131539 | METHOD FOR MEASURING TEMPERATURE BY REFRACTION AND CHANGE IN VELOCITY OF WAVES WITH MAGNETIC SUSCEPTIBILITY - Methods and apparatuses for determining in-situ a temperature of a substrate with a thermal sensor in a vacuum chamber are described herein. In one embodiment a thermal sensor has a transmitter configured to transmit electromagnetic waves, a receiver configured to receive electromagnetic waves, and a controller configured to control the transmitter and receiver, wherein the controller determines a temperature from a difference between the transmitted electromagnetic wave and the received electromagnetic wave. | 05-12-2016 |