| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 250341600 | Heating of object or material | 17 |
| 20100051815 | HEAT-RADIATING PATTERN - A heat-radiating pattern and a heat-radiating pattern includes metal layers such as Au (gold) and Ag (silver). Metal layers with certain dimensions can absorb light in the visible/near IR (infrared) range and emit light in IR range as heat. The metal layers can be formed into a desired pattern and surroundings of the metal layers can be heated up locally and thereby form a portion of the heat-radiating pattern. Locally heated portions on a substrate by the heat-radiating pattern can transform a heat reactive polymer layer and perform as a local heater. | 03-04-2010 |
| 20100123080 | PROCESS AND SYSTEM FOR THE NONDESTRUCTIVE QUALITY DETERMINATION OF A WELD SEAM, AND A WELDING DEVICE - A process for the non-destructive determination of the quality of a weld seam, the process steps comprising: providing a first and a second component; connecting the first and second components by a weld seam produced by a welding operation; and measuring a surface temperature of the weld seam and surface temperatures of areas of the first and second components adjacent to the weld seam that were heated by the welding operation. A system for carrying out the process for the non-destructive determination of the quality of a weld seam, the system comprising: a measuring device, an analyzing unit, and a welding device. | 05-20-2010 |
| 20100155603 | SYSTEM FOR DETECTING AND LOCATING WATER IN A SANDWICH-TYPE STUCTURE FOR AIRCRAFTS - A system for detecting and locating water in a sandwich-type structure for aircrafts, the system including means for heating the water contained in an intermediate layer of the sandwich-type structure, and means for recording at least one image of a surface of the sandwich-type structure, the image showing particular regions of the surface, corresponding to the presence of water in the intermediate layer. The means for heating the water include a device for emitting microwaves inside the sandwich-type structure, at a frequency essentially equal to the resonance frequency of the water molecules. The invention also relates to a method implemented by the system. | 06-24-2010 |
| 20100163732 | METHOD FOR THE AUTOMATIC INSPECTION OF A WELDING SEAM BY MEANS OF HEAT FLOW THERMOGRAPHY - In a method for the automatic inspection of a welding seam using heat flow thermography, a feature vector is established which represents a time course of a detected heat flow. The feature vector is used to determine, from a series of thermal images, a first characteristic thermal image, which corresponds to a minimum heat flow through an object to be examined, and a second characteristic thermal image, which corresponds to a maximum heat flow through the object, wherein a heat flow directly from an excitation source has already dissipated. A suitable thermal image is used from the series of thermal images to detect and evaluate the welding seam in relation to defects of various defect types, for each defect type, the characteristic thermal images being used as references to determine the respective suitable thermal image. | 07-01-2010 |
| 20100230598 | SYSTEM AND METHOD FOR VALVE SEAT GAP EVALUATION - A method of detecting a gap between a valve seat insert and a port in a cylinder head may include heating the valve seat insert and the cylinder head and generating a thermal image of the valve seat insert and the cylinder head at an interface between the valve seat insert and corresponding port in the cylinder head housing the valve seat insert. The thermal image may be evaluated to determine the magnitude of a gap between the valve seat insert and the cylinder head based on a temperature at the interface between the valve seat insert and the cylinder head. | 09-16-2010 |
| 20110049368 | RADIATION DETECTOR WITH MICROSTRUCTURED SILICON - A radiation detector includes material for absorbing incident radiation, and for providing a response to heating caused by the absorption of photons from the incident radiation. The radiation detector may include multiple pixels, each with one or more layers of absorbing material. The absorbing material may include black (microstructured) silicon, which has the advantage of being a good absorber of radiation in the short wave infrared (SWIR) wavelengths (as well as ultraviolet (UV) wavelengths and visible light wavelengths). The radiation detector may include multiple pixels, each separately responding to radiation incident on that pixel, and each including black silicon (as well as possibly other absorptive materials). The pixels of the detector may each have cantilevered attachment to a frame of the detector, with differences in coefficient of thermal expansion of materials of the pixels causing deflection of parts of the pixels due to heating from absorption of radiation. | 03-03-2011 |
| 20120168628 | METHOD AND DEVICE FOR DETERMINING THE ADSORPTION OF A GAS ON MATERIALS - The invention relates to a method and to an apparatus for determining the adsorption of a gas at materials. It is the object of the invention to propose possibilities for the determining of the surface properties of materials in which statements can be obtained and very small sample volumes can be examined with sufficient measurement precision, with a reduced technical plant effort and with a reduced time effort. In the invention, a sample of a material is acted on by a gas or gas mixture within a chamber which is not transparent for electromagnetic radiation in the wavelength range between 150 nm and 25 μm. The gas or at least a gas included in a gas mixture is adsorbed at the surface of the sample and in this respect the electromagnetic radiation emitted by the sample as a consequence of the adsorption is detected by at least one optical detector which is sensitive at least in a range of the wavelength range between 150 nm and 25 μm. The measured signals of the detector (s) are in this respect detected with time resolution and are evaluated within a predefinable time interval for determining the surface temperature and/or the adsorption heat of the respective sample varying due to the adsorption. | 07-05-2012 |
| 20120298870 | METHOD FOR AUTOMATED TESTING OF A MATERIAL JOINT - In a method for automated, contactless and non-destructive testing of a material joint ( | 11-29-2012 |
| 20130099123 | TIRE SURFACE ANOMALY DETECTION - A tire surface anomaly detection system and method are disclosed. The system and method are generally based on the principle that a tire surface anomaly will have a different heat transfer rate than that of the uniform mass surrounding the tire surface anomaly. Embodiments of the present disclosure apply thermal energy to the surface of a tire and monitor the infrared energy at the surface of the tire to generate one or more infrared images of the surface of the tire. The infrared images are analyzed by an image processing system to determine and locate thermal gradients on the surface of the tire. The presence of a thermal gradient in the infrared images generally indicates the presence of an anomaly in the surface of the tire. In this manner, the present disclosure provides an objective technique for identifying, locating, and classifying tire surface anomalies. | 04-25-2013 |
| 20130134310 | CHEMICAL MAPPING USING THERMAL MICROSCOPY AT THE MICRO AND NANO SCALES - A non-destructive method for chemical imaging with ˜1 nm to 10 μm spatial resolution (depending on the type of heat source) without sample preparation and in a non-contact manner. In one embodiment, a sample undergoes photo-thermal heating using an IR laser and the resulting increase in thermal emissions is measured with either an IR detector or a laser probe having a visible laser reflected from the sample. In another embodiment, the infrared laser is replaced with a focused electron or ion source while the thermal emission is collected in the same manner as with the infrared heating. The achievable spatial resolution of this embodiment is in the 1-50 nm range. | 05-30-2013 |
| 20130181134 | METHOD AND APPARATUS FOR FILTER CONDITION INSPECTION - A method of inspecting a ceramic wall-flow filter ( | 07-18-2013 |
| 20130228690 | MID-INFRARED SPECTRAL ANALYSIS OF A FLOWING HETEROGENEOUS MATERIAL - A method of determining components of a flowing heterogeneous sample comprising obtaining a sample of material; measuring mid-infrared attenuation values of the sample and calculating in a data processing unit an indication of the component of interest in the sample from the measured mid-infrared attenuation values characterised in that the method further comprises flowing the sample; concurrently interacting mid-infrared radiation with the flowing sample in a measurement region and subsequently measuring the mid-infrared attenuation values for one or more wavebands of the interacted radiation. | 09-05-2013 |
| 20140319355 | Optical Method for Detecting Displacements and Strains at Ultra-High Temperatures During Thermo-Mechanical Testing - An ultra-high temperature optical method incorporates speckle optics for sensing displacement and strain measurements well above conventional measurement techniques. High temperature pattern materials are used which can endure experimental high temperature environments while simultaneously having a minimum optical aberration. A purge medium is used to reduce or eliminate optical distortions and to reduce, and/or eliminate oxidation of the target specimen. | 10-30-2014 |
| 20140339429 | OPTICAL NON-DESTRUCTIVE INSPECTION METHOD AND OPTICAL NON-DESTRUCTIVE INSPECTION APPARATUS - In an optical non-destructive inspection method which can perform inspection accurately in a short time. In the method, a heating laser beam source, at least one infrared detector, a control unit, and a storage unit are used. The storage unit stores a parameter state-time constant characteristic in which a parameter corresponding to a state of the measurement object is correlated with a time constant indicating the curve shape of the temperature rise characteristic that varies depending on the state of the parameter. The control unit determines the time constant based on the curve shape of the temperature rise characteristic, which extends from a heating start time point to a time point at which a saturated temperature is reached, and determines the state of the parameter of the measurement object based on the determined time constant and the parameter state-time constant characteristic. | 11-20-2014 |
| 20150083920 | Nondestructive Testing Active Thermography System and Method for Utilizing the Same - An assembly including an optically excited infrared nondestructive testing active thermography system is disclosed. The optically excited infrared nondestructive testing active thermography system includes one or more illumination sources, at least one first reflector, at least one second reflector and a computing resource. The at least one first reflector is arranged about the one or more illumination sources. The at least one first reflector has a near focal point and a far focal point. The one or more illumination sources is/are positioned at least proximate the near focal point of the at least one first reflector. The at least one second reflector is positioned at least proximate the far focal point. The computing resource is communicatively-coupled to a motor that is coupled to the at least one second reflector for manipulating the at least one second reflector between at least: a first spatial orientation and a second spatial orientation. At least one of the first spatial orientation and the second spatial orientation results in the at least one second reflector reflecting light that originates from the one or more illumination sources. The light is directed toward the at least one second reflector as a result of the light being directly propagated from the one or more illumination sources and reflected by the at least one first reflector. A method is also disclosed. | 03-26-2015 |
| 20160018324 | Nondestructive Inspection Using Hypersound - A method and apparatus for inspecting an object. The apparatus comprises a wave generator and a detection system. The wave generator is positioned away from an object. The wave generator emits an ultrasonic wave in a direction towards a location on the object such that the ultrasonic wave encounters a portion of the object. The detection system is positioned at a same side of the object as the wave generator. The detection system detects a feature response of a feature within the portion of the object to the ultrasonic wave encountering the portion of the object. | 01-21-2016 |
| 20160146670 | METHOD OF MEASURING TEMPERATURE OF A HEATED PART - A method of measuring temperature of a part heated during a heating process includes applying a non-reactive coating at a first temperature; heating the part, and thereby the coating thereon, to a second temperature greater than the first temperature; and measuring a temperature distribution of the part by measuring infrared light emitted from the heated coating using a thermal imaging device calibrated to the known emissivity of the coating. The coating is at least partially opaque and having a known emissivity of infrared light and conducts thermal energy from the underlying part. | 05-26-2016 |
