The invention relates to a thermocouple (17) suspended from a part (26, 27) that can be locked onto a connecting section of the measuring stick, which comprises an opening in the form of a guiding cone (30) for inserting the thermocouple. The thermocouple is contained in a flexible cable (24) that can slide in a sheath (35) of the central compartment (16) which houses the thermocouple (17). A spring (34) can be added to lightly press the end of the thermocouple to the end of the housing thereof.

An arrangement for closing a container, in particular a flask, for determining evaporation properties of a liquid in the flask according to at least one standardized test. The arrangement has at least one temperature measurement system, a sensor, a closing element adapted for contacting a surface of an opening in the container for closing the container and having a through-opening through which a portion of the temperature measurement sensor is guided such that a lower end of the sensor is arranged within the container. The arrangement further includes a mechanism for adjusting a position of the lower end of the sensor along a longitudinal direction of the temperature measurement sensor.

A self-cleaning thermal conductivity sensor comprises: a bellows coupled to a support structure; a pneumatic or hydraulic cylinder; a sensor configured to measure a thermal conductivity of a fluid and extending from the pneumatic or hydraulic cylinder, wherein the sensor comprises an exposure end configured to contact the fluid during sensing by the thermal conductivity sensor, a temperature sensor, and a heat source; sensor wires connected with the thermal conductivity sensor and extending to a control system; a self-cleaning system comprising: a hood having walls extending radially outward and defining a volume; and a cleaning brush integrated with or adjacent the bottom of the support structure. In a retracted configuration, the exposure end of the sensor is positioned at a retracted position a distance from cleaning brush, and, in an extended configuration, the exposure end of the sensor extends a distance along the central axis away from the retracted position.

Disclosed is a temperature sensor for measuring a temperature of a reference material. The temperature sensor includes a thermocouple, spring, and spring housing. The thermocouple is configured to measure the temperature of the reference material. The spring is operably coupled to the thermocouple and the spring housing is configured to accommodate the spring and thermocouple within the spring housing. Additionally, the spring housing is configured to attach to the reference material and the spring applies a force on the thermocouple in a direction towards the reference material.

An energy storage system comprising at least one energy storage module adapted to supply electrical energy to a hybrid vehicle. The energy storage module comprises an enclosure, at least one battery array located within the enclosure, and an energy storage controller module located within the enclosure and electrically connected to the battery array. The energy storage module further comprises a compliant tipped thermistor which may be installed within a flexible clip. The thermistor is positioned to monitor the temperature of one or more of the batteries within the energy storage system.

The oven with a temperature probe measures the temperature of food being cooked within the oven to provide real time feedback for determining a status of the food being cooked, such as, for example, indications that the food is fully cooked, partially cooked or uncooked. The oven with a temperature probe is similar to a conventional oven, but with a telescopic tube which selectively extends into the cooking chamber of the oven. An upper end of the telescopic tube is mounted within an open interior of a hollow upper wall of the oven, and a lower end of the telescopic tube defines a probe tip, containing a temperature sensor for measuring an internal temperature of the food being cooked. When not in use, the telescopic tube collapses fully within the open interior of the hollow upper wall. A display indicates cooking status of the food, based on the measured temperature.

According to one aspect of the technique, there is provided a substrate temperature sensor configured to measure a temperature of a substrate, wherein the substrate temperature sensor is provided in a protective pipe provided to be accommodated in a recess formed at a portion of a substrate retainer on which the substrate is mounted.

A cooktop appliance includes a cooktop panel defining a cooktop surface and an aperture defined through the cooktop surface. A heating element is positioned below the cooktop panel for selectively heating a cooking utensil placed on the cooktop surface and a temperature sensing assembly is configured for monitoring the temperature of the cooking utensil, e.g., to facilitate a closed loop cooking process. The temperature sensing assembly includes a temperature sensor slidably mounted within the aperture of the cooktop panel and a drive member operably coupled to the temperature sensor for selectively moving the temperature sensor between the extended position and the retracted position.

A test fixture, for a heatsink, may include a probe assembly with a thermocouple probe configured to removably contact a bottom surface of a pedestal of the heatsink, and measure a surface temperature of the heatsink. The test fixture may include an insulator housing configured to house the probe assembly and a heater block, and to insulate the probe assembly from the heater block. The heater block may be provided within the insulator housing and may be configured to provide heat to the heatsink via the bottom surface of the pedestal of the heatsink. The test fixture may include a mounting block connected to the insulator housing and configured to connect to the heatsink.

A self-cleaning thermal conductivity sensor comprises: a bellows coupled to a support structure; a pneumatic or hydraulic cylinder; a sensor configured to measure a thermal conductivity of a fluid and extending from the pneumatic or hydraulic cylinder, wherein the sensor comprises an exposure end configured to contact the fluid during sensing by the thermal conductivity sensor, a temperature sensor, and a heat source; sensor wires connected with the thermal conductivity sensor and extending to a control system; a self-cleaning system comprising: a hood having walls extending radially outward and defining a volume; and a cleaning brush integrated with or adjacent the bottom of the support structure. In a retracted configuration, the exposure end of the sensor is positioned at a retracted position a distance from cleaning brush, and, in an extended configuration, the exposure end of the sensor extends a distance along the central axis away from the retracted position.