A temperature difference measuring apparatus includes: a bottomed tubular package in which a top face side is opened; a MEMS device disposed on an inner bottom face of the package, the MEMS device comprising at least one thermopile that measures a temperature difference, which is generated in the MEMS device by inflow heat through a bottom of the package; and a heat quantity increasing unit configured to increase a heat quantity flowing out from the MEMS device onto the top face side of the bottomed tubular package.

A temperature difference measuring apparatus includes: a bottomed tubular package in which a top face side is opened; a MEMS device disposed on an inner bottom face of the package, the MEMS device comprising at least one thermopile that measures a temperature difference, which is generated in the MEMS device by inflow heat through a bottom of the package; and a heat quantity increasing unit configured to increase a heat quantity flowing out from the MEMS device onto the top face side of the bottomed tubular package.

A temperature sensor comprising an elongated hollow body, such as a carrier pipe, a shaped part arranged at one end of the hollow body, and a coupling element which is thermally coupled to a measuring element. The shaped part is used for thermally insulating the coupling element from the hollow body.

A temperature sensor comprising an elongated hollow body, such as a carrier pipe, a shaped part arranged at one end of the hollow body, and a coupling element which is thermally coupled to a measuring element. The shaped part is used for thermally insulating the coupling element from the hollow body.

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.

An assembly for detecting a temperature of an electrically conductive element comprises a temperature probe and a heat conductor separate from the temperature probe and made of an electrically insulating and heat-conductive material. The heat conductor surrounds the temperature probe at least in sections and has a bearing surface bearing against the electrically conductive element.

Provided herein is a differential temperature sensor which utilizes multiple temperature sensors to quickly and accurately calculate ambient fluid temperature with a reduced response time. The provided systems and methods utilize a first fluid temperature sensor and a second probe temperature sensor to account for the thermal impact of the device on the ambient fluid temperature and the effect of heat within the device, or temperature difference between the probe and fluid temperature, on the first fluid temperature sensor measurement.

A method of manufacturing a thermometer probe includes: obtaining a hollow housing having an open end and a curved inner surface; obtaining a flexible detecting component having an adhesive layer; obtaining an insertion component; detachably attaching the flexible detecting component to the insertion component; inserting the insertion component, having the flexible detecting component attached thereto, through the open end of the hollow housing and into the hollow housing such that the adhesive layer is disposed between the insertion component and the inner surface; and adhering, via the adhesive layer, the flexible detecting component to the curved inner surface.

A method of manufacturing a thermometer probe includes: obtaining a hollow housing having an open end and a curved inner surface; obtaining a flexible detecting component having an adhesive layer; obtaining an insertion component; detachably attaching the flexible detecting component to the insertion component; inserting the insertion component, having the flexible detecting component attached thereto, through the open end of the hollow housing and into the hollow housing such that the adhesive layer is disposed between the insertion component and the inner surface; and adhering, via the adhesive layer, the flexible detecting component to the curved inner surface.

A temperature detection module 10 includes: a temperature sensor 50; a sensor holder 30 for holding the temperature sensor 50 such that movement is possible in a separation and contact direction in which the temperature sensor 50 is separated from and brought into contact with a measurement target; and a biasing member 70 that is attached to the sensor holder 30 and biases the temperature sensor 50 such that a detection surface comes into contact with a measurement target. The sensor holder 30 includes: a base portion 31; and a accommodating portion 40 that extends in the separation and contact direction from the base portion 31 and holds the temperature sensor 50 such that movement is possible in the separation and contact direction. The accommodating portion 40 includes a gap that allows inclination of the temperature sensor 50 between the accommodating portion 40 and the temperature sensor 50.