A thermocouple may have a first thermoelement wire formed of a first material and a first sheath covering at least part of the first thermoelement wire. The first sheath may provide thermal insulation and may be formed of a third material, different from the first material, that is subject to oxidation in response to exposure to a surrounding material. The thermocouple may further have a second sheath covering at least a first portion of the first sheath. The second sheath may act as a barrier between the first portion of the first sheath and the surrounding material and may be formed of a fourth material that is resistant to oxidation in the surrounding material. The first thermoelement wire may be joined, at a junction, with one of the first sheath, and a second thermoelement wire formed of a second material different from the first material.

A temperature sensing assembly includes a sheath defining an interior space, a first temperature sensor and a second temperature sensor. The first temperature sensor has first and second conductors extending within the interior space of the sheath and joined at a first junction point. The first conductor is constructed of a first material and the second conductor is constructed of a second material that is different than the second material. The second temperature sensor has third and fourth conductors extending within the interior space of the sheath and joined at a second junction point. The third conductor is constructed of a third material and the fourth conductor is constructed of a fourth material that is different than the fourth material. The first material is different than each of the third and fourth materials. The first junction point is adjacent to the second junction point.

A temperature sensing assembly includes a sheath defining an interior space, a first temperature sensor and a second temperature sensor. The first temperature sensor has first and second conductors extending within the interior space of the sheath and joined at a first junction point. The first conductor is constructed of a first material and the second conductor is constructed of a second material that is different than the second material. The second temperature sensor has third and fourth conductors extending within the interior space of the sheath and joined at a second junction point. The third conductor is constructed of a third material and the fourth conductor is constructed of a fourth material that is different than the fourth material. The first material is different than each of the third and fourth materials. The first junction point is adjacent to the second junction point.

The present disclosure relates to a temperature sensing device having a plurality of thermocouple arrangements, each of the thermocouple arrangements having a forward conductor and a plurality of return conductors electrically connected with the forward conductor, the return conductors having a different conductive material than the respectively associated forward conductor, electrical junctions or groups of electrical junctions of the return conductors to the respectively associated forward conductor being arranged at different longitudinal positions of the respectively associated forward conductor, and consecutive longitudinal positions of the electrical junctions or of groups of the electrical junctions of all thermocouple arrangements in the longitudinal direction of all forward conductors alternating between different forward conductors. Further, the present disclosure relates to a method of producing a temperature sensing device.

The present disclosure relates to a temperature sensing device having a plurality of thermocouple arrangements, each of the thermocouple arrangements having a forward conductor and a plurality of return conductors electrically connected with the forward conductor, the return conductors having a different conductive material than the respectively associated forward conductor, electrical junctions or groups of electrical junctions of the return conductors to the respectively associated forward conductor being arranged at different longitudinal positions of the respectively associated forward conductor, and consecutive longitudinal positions of the electrical junctions or of groups of the electrical junctions of all thermocouple arrangements in the longitudinal direction of all forward conductors alternating between different forward conductors. Further, the present disclosure relates to a method of producing a temperature sensing device.

A low thermal conductivity fixed thermocouple with a heat sink package specifically designed for electrically heated vacuum furnaces having an overall cylindrical hot zone diameter of 36 inches or less, and preferably containing all metal reflective radiation shields or graphite felt insulation packages that experience high conductive losses in the low temperature ranges during vacuum heating which result in large discrepancies between the furnace temperature readings and the actual workload temperature.

A low thermal conductivity fixed thermocouple with a heat sink package specifically designed for electrically heated vacuum furnaces having an overall cylindrical hot zone diameter of 36 inches or less, and preferably containing all metal reflective radiation shields or graphite felt insulation packages that experience high conductive losses in the low temperature ranges during vacuum heating which result in large discrepancies between the furnace temperature readings and the actual workload temperature.

An infrared thermopile sensor includes a silicon cover having an infrared lens, an infrared sensing chip having duo-thermopile sensing elements, and a microcontroller chip calculating a temperature of an object. The components are in a stacked 3D package to decrease the size of the infrared thermopile sensor. The infrared sensing chip and the microcontroller chip have metal layers to shield the thermal radiation. The conversion from wrist temperature to body core temperature uses detected ambient temperature and fixed humidity or imported humidity level to calculate the body core temperature based on experimental data and curve fitting. The skin temperature compensation can be set differently for different sex gender, different standard deviation of wrist temperature and external relative humidity reading.

An infrared thermopile sensor includes a silicon cover having an infrared lens, an infrared sensing chip having duo-thermopile sensing elements, and a microcontroller chip calculating a temperature of an object. The components are in a stacked 3D package to decrease the size of the infrared thermopile sensor. The infrared sensing chip and the microcontroller chip have metal layers to shield the thermal radiation. The conversion from wrist temperature to body core temperature uses detected ambient temperature and fixed humidity or imported humidity level to calculate the body core temperature based on experimental data and curve fitting. The skin temperature compensation can be set differently for different sex gender, different standard deviation of wrist temperature and external relative humidity reading.

A temperature sensing assembly includes a sheath defining an interior space, a first temperature sensor and a second temperature sensor. The first temperature sensor has first and second conductors extending within the interior space of the sheath and joined at a first junction point. The first conductor is constructed of a first material and the second conductor is constructed of a second material that is different than the second material. The second temperature sensor has third and fourth conductors extending within the interior space of the sheath and joined at a second junction point. The third conductor is constructed of a third material and the fourth conductor is constructed of a fourth material that is different than the fourth material. The first material is different than each of the third and fourth materials. The first junction point is adjacent to the second junction point.