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 passing through a notch provided at least in a bottom plate of a substrate retainer inserted into a process chamber in a state where the substrate is mounted on the substrate retainer.

Described is an electrical grid sensor comprising: a housing having a bottom surface and a top surface and a ring extending from and integrated with the top surface, the ring sized to accommodate a universal hook end of a standard utility hot-stick tool by way of an aperture defined by the ring. The sensor further comprising a temperature sensor inside of the housing and in communication with the bottom surface and adapted to measure a temperature at the bottom surface when energized. A magnetized element at the bottom surface is adapted to magnetically fix the bottom surface to an iron-based transformer housing. The sensor further providing a wireline extending from the temperature sensor, the wireline adapted to connect to a data consumer transmitter. The sensor is configured and arranged to be manipulated and deployed by a hot stick tool when used with a hot stick at a safe distance from high-voltage electrical grid component.

A temperature probe for a cooktop appliance includes a resilient clip configured for mounting on a cooking utensil with a module connected to the resilient clip and a temperature sensor extending from the module along a longitudinal direction. The resilient clip may include a hook portion configured to engage a rim of the cooking utensil and an offset portion that is not parallel to the hook portion. The temperature probe may include an emitter and a receiver for non-contact measurement of a diameter of the cooking utensil.

A digital thermometer for cooking includes an outer casing having a bottom wall that defines a closed lower end and a side wall that projects upwardly from the bottom wall to define an open upper end, and a housing for electronic components disposed inside the outer casing and being surrounded by the side wall of the outer casing. A printed circuit board is disposed inside the housing, and a microprocessor and a visual display component are mounted on the printed circuit board. An insulating assembly is disposed inside the outer casing and is located between the bottom wall of the outer casing and the housing containing the electronic components. A temperature sensing probe projects from the bottom wall of the outer casing for obtaining temperature readings and transmitting the temperature readings to the microprocessor. The side wall of the outer casing is spaced from the housing to define a heat vent for dissipating heat.

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.

A sensor module for mounting in a motor includes a holder adapted to be mounted in a wet chamber of the motor, a temperature sensor adapted to be mounted in a dry chamber of the motor, a rotational position sensor mounted on the holder, a connector interface adapted to be plugged into a corresponding connector, and a sealing element arranged between the rotational position sensor and the temperature sensor. The temperature sensor is spaced apart from the holder. The rotational position sensor and the temperature sensor are connected via a plurality of signal lines to the connector interface. The sealing element is sealingly penetrated by the signal lines from one of the rotational position sensor and the temperature sensor.

A system for measuring temperature in a sterilization autoclave includes a temperature transducer positionable inside a sterilization chamber of the autoclave and a receiver positionable outside the sterilization chamber. The receiver includes a reception antenna and a receiving electronic circuit connectable with a process controller of the autoclave. The receiving electronic circuit is configured to receive a temperature signal through the reception antenna, provide a control signal as a function of the temperature signal and transmit the control signal to the process controller. The temperature transducer includes a hermetically closable transducer housing, temperature probes, a transmission antenna, an electronic transduction circuit, a primary battery and an activation device.

A bathythermograph buoy and an associated method of operation are provided to measure temperature and/or optionally other parameter(s) within an ocean or another body of water. A bathythermograph buoy includes a housing and one or more sensors carried by the housing and configured to repeatedly measure one or more respective parameters as the bathythermograph buoy descends. The bathythermograph buoy of one example also includes a memory carried by the housing and configured to store representations of the one or more respective parameters measured by the one or more sensors. The bathythermograph buoy further includes a buoyancy modification device configured to increase buoyancy of the bathythermograph buoy to permit the bathythermograph buoy to ascend.

A device for measuring the temperature in a rotary kiln through which solid material passes being heated to elevated temperatures. The device features a drive as well as an elongated hollow body with means to fix a thermocouple, whereby the drive and the elongated hollow body are mounted such that they rotate jointly with the rotary kiln. The drive can move the elongated hollow body together with thermocouple through an opening in and out of the rotary kiln interior for measuring the temperature inside the rotary kiln during operation.

A temperature sensor assembly is described that includes a sensor probe including a probe head and a probe shaft. At least a tip of the sensor probe includes a material with a thermal conductivity proportionality constant greater than stainless steel. A temperature sensor is positioned within the probe shaft adjacent to the tip. A nose piece is positioned on the probe shaft opposite the probe head. The nose piece includes a material with a thermal conductivity proportionality constant greater than stainless steel. The temperature sensor assembly also includes a collar positioned around the probe shaft between the probe head and the nose piece, the collar is capable of rotating relative to the probe shaft during installation of the sensor assembly.