Examples are disclosed that relate to mapping a plurality of temperatures across an area. One example provides a temperature sensing device including a flexible support and a temperature sensing structure having a plurality of individually readable temperature sensing junctions. The temperature sensing structure includes a line of a first conductive material extending across an area of the support, and a plurality of lines of a second conductive material each intersecting the line of the first junction material at a corresponding sensing junction.

A light diffusing fiber including one or more segments, and a thermochromic coating on at least a portion of the light diffusing fiber. The thermochromic coating is opaque at a first temperature, and is transparent at a second temperature. A system for detecting the temperature of an apparatus including the apparatus, a light diffusing fiber thermally coupled to the apparatus, and a light source optically coupled to the light diffusing fiber. A method for detecting the temperature of an apparatus including thermally coupling a light diffusing fiber to the apparatus, optically coupling a light source to the light diffusing fiber, and monitoring the light diffusing fiber for transmitted light.

The invention relates to a multipoint sensor for determining a temperature profile of a medium and to a method for producing said multipoint sensor. The multipoint sensor includes a tubular sheath having a closed end region; at least two cylindrical spacers produced from a material having a high thermal conductivity and arranged in an axially-spaced manner in the interior of the sheath. Each spacer includes a recess for holding a temperature-sensitive component of an elongate temperature sensor. Each spacer, with the exception of the spacer closest to the closed end region, has through-bores for feeding through the elongate temperature sensors fastened to the preceding spacers. The number of through-bores of a spacer corresponds to the number of preceding spacers. A filling material, is arranged between the spacers and surrounds each of the elongate temperature sensors. The filling material has a lower thermal conductivity than the material of the spacers.

A method and system to determine a hot cargo load condition of a cargo load in a refrigerated container includes providing a plurality of sensors disposed within the refrigerated container, operating the refrigeration unit with a set of desired operational parameters corresponding to the cargo load, analyzing a plurality of sensor readings corresponding to the plurality of sensors via a processor, creating a temperature distribution profile of the refrigerated container corresponding to the plurality of sensor readings via the processor, retrieving a historical temperature distribution profile corresponding to the cargo load via a historical database, comparing the temperature distribution profile to the historical temperature distribution profile via the processor, and identifying the hot cargo load condition in response to the temperature distribution profile exceeding the historical temperature distribution profile via the processor.

The invention relates to a method for the open-loop and/or closed-loop control of a heating of a cast or rolled metal product, comprising the following steps: determining the total enthalpy of the metal product from a total of the free molar enthalpies (Gibbs free energy) of all phases and/or phase fractions currently present in the metal product; determining a temperature distribution within the metal product by means of a dynamic temperature calculation model by using the determined total enthalpy; and open-loop and/or closed-loop controlling of the heating of the metal product according to at least one initial variable of the temperature calculation model.

Disclosed is a temperature distribution measuring device for measuring the temperature distribution or the heat generation distribution in a sample. An embodiment collects a reflection signal the reflectivity of which changes on the basis of a bias signal applied to a sample, detects a signal of interest, which has been reflected from a region of interest in the sample, from the reflected signal, converts the signal of interest to a frequency range signal, calculates the relative amount of change in reflectivity of the sample by using a direct current component extracted on the basis of filtering of the frequency range signal and a frequency component of the bias signal, and acquires a thermal image of the sample on the basis of the relative amount of change in reflectivity.

A sensor sheet has a planer shape to be disposed on a surface of a vehicle seat. The sensor sheet includes: a pliable planar main body capable of being disposed along the surface of the vehicle seat; a plurality of detecting portions provided in the main body; and a wiring line that is configured to supply power to each of the detecting portions, wherein each of the plurality of detecting portions is configured to transmit information detected from the surface of the vehicle seat to a controller through a wired or wireless communication, wherein the main body has an air permeability to enable circulation of air in a thickness direction, and wherein the plurality of detecting portions are arranged at a suitable interval in a surface direction of the main body.

An apparatus includes a enclosure assembly including an enclosure assembly-leading end and an opposed enclosure assembly-lagging end, and a temperature emulation assembly mounted within the enclosure assembly and including a temperature emulation assembly-leading end located proximate to the enclosure assembly-leading end and a temperature emulation assembly-lagging end spaced away from the enclosure assembly-lagging end. The enclosure assembly thermally isolates the temperature emulation assembly. The enclosure assembly permits conductive heat transfer to the temperature emulation assembly only through the enclosure assembly-leading end.

An apparatus includes a printed wiring board including multiple layers including inner and outer layers. At least one of the inner layers includes an integral temperature sensor matrix. The temperature sensor matrix includes multiple temperature sensors arrayed over at least part of area occupied by the at least one of the layers. A method includes measuring information corresponding to temperatures in the temperature sensor matrix, and outputting indications of the information. The information may be displayed, e.g., as a thermal image of the printed wiring board.

A temperature sensing system senses a temperature in the monitor space. The temperature sensing system includes a first detector, a second detector, and a processing unit. The first detector detects a temperature on a ceiling and outputs first information about the temperature on the ceiling. The second detector detects infrared radiation emitted from a floor and outputs second information about the infrared radiation from the floor. The processing unit calculates, based on at least the first information and the second information, a spatial temperature distribution which includes a component in a height direction with respect to the monitor space between the ceiling and the floor.