A temperature probe and method for determining a temperature in a gas flow are disclosed. The probe includes a probe body. A free flow temperature sensor a free flow temperature of the gas flow and a total temperature sensor measures a total temperature of the gas flow. The method includes measuring a flow temperature in a free gas flow, providing a static gas volume in which essentially all kinetic energy of the flowing gas is recovered and converted into thermal energy, and measuring a total temperature in the static gas volume. An accurate determination of the total temperature of a gas flow, which is representative of a specific total enthalpy, can thereby be achieved while detecting fast and transient temperature changes.

A method of predicting temperature of at least one location in a fluid flow system that has a heating system for heating fluid. The method includes obtaining a mass flow rate of fluid flow of the fluid flow system, obtaining at least one of a fluid outlet temperature and a fluid inlet temperature of a heater of the heating system, obtaining power provided to the heater, and calculating temperature at the at least one location based on a model of the fluid flow system and the obtained mass flow rate, fluid outlet temperature, and fluid inlet temperature.

A susceptor for use in a heated fluid flow system is provided. In one form, a susceptor is arranged within a conduit and adapted to absorb radiant energy from at least one heating element and inhibit the radiant energy from being absorbed by the at least one wall of the conduit and/or other components. In another form, the susceptor absorbs and inhibits the radiant energy from being absorbed by the outer wall of the conduit.

This temperature measuring device includes: a case which has a bottomed tubular shape with a closed portion at one end and an opening at the other end, and in which a temperature sensing part is disposed on the side of the closed portion; an infrared temperature sensor unit in which an infrared temperature detection unit that has a light-receiving surface receiving an infrared ray and detects the received infrared ray and outputs the ray in the form of an electrical signal is disposed opposite the temperature sensing part while being spaced therefrom inside the case; and a connection terminal unit which has in the interior thereof a circuit unit that acquires the electrical signal and that generates temperature information so that the temperature information is outputted to an external device, wherein the connection terminal unit can be disposed at a position spaced from the heat source.

The present invention relates to a wireless communication assembly (1) for a sensor (2) for measuring a magnitude in a motor vehicle. The sensor (2) comprises, at a first end portion (3), an element sensing (5) the magnitude to be measured in the motor vehicle and, at a second end portion (4), an electrical connector (6) electrically connected to the sensing element (5).

According to the invention, the wireless communication unit (1) comprises: a transmission module (7) intended to be removably connected to the electrical connector (6) of the sensor (2), the transmission module (7) comprising means of wireless communication (8), and a receiving module at a location remote from the transmission module (7) and comprising means of wireless communication for receiving data transmitted by the transmission module (7).

A temperature sensor includes a metal tube having an opening tip portion, a temperature sensing element for measuring a temperature, a pair of lead wires contacting with a surface of the temperature sensing element, an insulating support material for insulating the pair of lead wires from the metal tube, and a coating material for covering the temperature sensing element, lead tip portions of the pair of lead wires, and a tip surface of the insulating support material at the opening tip portion of the metal tube.

The coating material has a property of not allowing measurement target gas to pass through and contains oxide and at least one of platinum, platinum alloy, and platinum-containing oxide that are dispersed in the oxide.

A sensing device (100) senses a physical quantity of a fluid having a high temperature. A tube-like element (110) surrounds at least a part of a MI-cable (102) between a sensing end of the MI-cable and a sealing flange element (106) attached to the MI-cable. A major part of the inner surface of the tube-like element is at a predefined distance from the outer surface of the Mineral Insulated cable forming a gap (112) between the mineral insulated cable and the tube-like element. The tube-like element and gap increases robustness against thermal expansions and thermal shock due to rapid temperature change of the fluid.

A temperature sensor includes a temperature detector, an element electrode wire, a lead wire, and an intermediate member. Each of the lead wire and the intermediate member is made of a Ni-based alloy or an Fe-based alloy. The element electrode wire and the intermediate member are welded together in such a manner that opposing surfaces, facing each other abut against each other to constitute an element-side weld. The intermediate member and the lead wire are welded together such that they overlap each other in a longitudinal direction Z to constitute a lead-side weld. The lead wire is extended closer to the temperature detector than the element-side weld is located. A gap between the element electrode wire and the lead wire at least in the longitudinal direction Z is filled with a filler. The element electrode wire, the element-side weld, and the lead wire are fixed to one another by the filler.

Systems and methods are provided to detect a failed thermocouple. A temperature in a gas path of a gas turbine engine may be measured, where the temperature is based on a signal generated by a thermocouple during a startup of the gas turbine engine and/or during an idle period that immediately follows the startup, and the thermocouple protrudes into the gas path. A failure of the thermocouple may be detected if the temperature is determined to be less than a threshold temperature.

A sensing element for a temperature sensor including a base with a platinum meander applied thereto. An alumina diffusion barrier (ADB) covers the meander to provide protection against contamination and structural stabilization, wherein the alumina diffusion barrier is a contiguous polycrystalline layer fabricated from alumina and approximately 1% by weight of a rutile additive to be substantially devoid of network porosity. The contiguous polycrystalline layer includes grains with a typical grain size being in a range of 0.5-3 m. A method for fabricating an alumina diffusion barrier includes the steps of: combining a nano-alumina and nano-rutile powder to create a formulation; applying the formulation to the platinum meander to form a layer; and sintering the layer to create a contiguous polycrystalline layer covering the platinum meander.