A temperature measurement system includes: a thickness calculating unit that calculates an optical thickness of a substrate; a rotation position detecting unit that detects rotation position information of the rotary table; a substrate specifying unit that specifies a substrate based on the rotation position information; a storage unit that stores first relationship information indicating a relationship between a temperature and a thickness associated with each substrate, and second relationship information indicating a relationship between an amount of change in temperature and an amount of change in optical thickness associated with each substrate; and a temperature calculating unit that calculates a temperature of the substrate based on the optical thickness calculated by the thickness calculating unit, the substrate specified by the substrate specifying unit, the first relationship information, and the second relationship information.

In a method for determining a temperature of a revolving drum of a laundry dryer, said drum has an outer wall and thereon at least one strip-shaped delimited detection region comprising thermochromic material having a transition temperature in the range of a temperature that is to be expected and to be determined. Optical detection means arranged adjacent to the revolving part are configured, in particular as a reflected light barrier, to detect the color transition of the thermochromic material in the event of the transition temperature being exceeded or undershot. At the revolving drum the thermochromic material or, if appropriate, the color transition thereof is detected by means of the detection means. A temperature of the drum is then determined as corresponding to the transition temperature in such a way that the temperature thereof is determined as corresponding to one of the two temperature ranges below the transition temperature or above the transition temperature.

A temperature measurement system configured to measure a temperature of a target object having a first main surface and a second main surface includes a light source unit configured to emit output light penetrating the target object and including a first wavelength range and a second wavelength range; a measurement unit configured to measure a spectrum of reflected light; an optical path length ratio calculator configured to calculate an optical path length ratio between the output light of the first wavelength range and the output light of the second wavelength range; and a temperature calculator configured to calculate the temperature of the target object based on the optical path length ratio and a previously investigated relationship between the temperature of the target object and a refractive index ratio between the output light of the first wavelength range and the output light of the second wavelength range.

A system configured to inspect a processing apparatus includes a temperature adjusting device configured to adjust a temperature of a component within a processing chamber of the processing apparatus; a light source configured to emit measurement light; multiple optical elements configured to output the measurement light emitted from the light source to the component within the processing chamber of the processing apparatus as output light and configured to receive reflected light from the component during a temperature adjustment of the component by the temperature adjusting device; and a controller configured to measure temperatures of the component at measurement points respectively corresponding to the multiple optical elements based on the reflected light, and make a determination upon abnormality of the processing apparatus based on comparisons of the temperatures of the component at the respective measurement points.

Monitoring melt pool temperature in laser powder bed fusion by providing a build laser that produces a laser beam that is directed onto the melt pool and produces an incandescence that emanates from the melt pool, receiving the incandescence and producing a first image having a first spectral band and a second image having a second spectral band, and determining the ratio of said first image having a first spectral band and said second image having a second spectral band to monitor the melt pool temperature.

Systems, devices and methods for monitoring a physical property over time are disclosed. A monitoring device in accordance with the present disclosure may comprise an electronic chip assembly, at least one light source, at least one monitoring label comprising a chemical configured to absorb light depending upon at least one physical property, and at least one photodiode configured to collect light emitted by the at least one monitoring label and provide at least one measurement corresponding to the at least one physical property. The at least one measurement may correspond to a past or present status of the at least one physical property. The monitoring device may be communicatively coupled to a user device configured to run an application that collects and store the at least one measurement provided by the at least one photodiode.

A device for the layer-wise additive production of a complex three-dimensional component has a measuring mechanism for continuously monitoring quality indicators during the production of the component, wherein the measuring mechanism and a bed with a material powder are surrounded, at least in regions, by a processing cell filled with a protective gas atmosphere and the material powder of an uppermost layer can be melted in a locally limited manner in a melting zone by means of at least one laser. The measuring mechanism has the at least one laser and at least one optical sensor for the priority detection of the quality indicators in the region of the melting zone, in particular by means of Raman spectroscopy. Consequently, any construction errors in the component can be recognised, evaluated and, if necessary, corrected in a resource-saving manner without delay.

A method for determining change in temperature of an electromagnetically radiating device between un-energized and energized states without contacting the device is disclosed. The method includes establishing a reference image form the device by illuminating the device with an optical signal having a first optical characteristic and capturing the reference image from the device in an un-energized state, establishing an on image form the device by illuminating the device in an energized state, and establishing a modified on image form the device by illuminating the device in the energized state with a modified optical signal having a third illuminating optical characteristic, and comparing the reference image, the on image, and the modified on image to establish changes in reflection as a result of changes in temperature of the device during energization.

An optical sensor system, comprising refractory plasmonic elements that can withstand temperatures exceeding 2500 C. in chemically aggressive and harsh environments that impose stress, strain and vibrations. A plasmonic metamaterial or metasurface, engineered to have a specific spectral and angular response, exhibits optical reflection characteristics that are altered by varying physical environmental conditions including but not limited to temperature, surface chemistry or elastic stress, strain and other types of mechanical load. The metamaterial or metasurface comprises a set of ultra-thin structured layers with a total thickness of less than tens of microns that can be deployed onto surfaces of devices operating in harsh environmental conditions. The top interface of the metamaterial or metasurface is illuminated with a light source, either through free space or via an optical fiber, and the reflected signal is detected employing remote detectors.

A device for preventing thermal run-away in a battery. The device includes a main compartment that is divided into a plurality of sub-compartments. A layer of material separates (i) a first sub-compartment containing a first chemical from (ii) a second sub-compartment containing a second chemical. In the event that a thermal run-away event is either detected or predicted, the layer of material degrades/is degraded and allows the chemicals to mix. The chemicals form an endothermic process that cools the battery preventing, or at least delaying, the thermal run-away event.