An electric dispensing kettle system with a dispensing kettle seats on to and docks to a control station. The dispensing kettle includes a weighted handle for controlled or balanced pouring. The control station provides controlled power to a heating element within the dispensing kettle with the dispensing kettle seated on to docked to the control station. The control sation includes a PID controller or control loop feedback circuit that continuously modulates power to the heating element based on actual temperature reading received from a thermocouple structure. The control station also includes an electronic dispaly that simultaneously displays an actual temperature of the steeping liquid and the target temperature of the steeping liquid within the dispensing kettle.

A device providing a temperature control and/or monitoring and a method for use of the device are disclosed. In the disclosed method and device, a controller receives a minimum temperature value and a maximum temperature value of a temperature range to be measured. The controller correlates a known output signal range of a temperature sensor to the temperature range to be measured. Further, the controller receives an output signal from the temperature sensor, and generates a measured temperature value based on the output signal of the temperature sensor.

A device providing a temperature control and/or monitoring and a method for use of the device are disclosed. In the disclosed method and device, a controller receives a minimum temperature value and a maximum temperature value of a temperature range to be measured. The controller correlates a known output signal range of a temperature sensor to the temperature range to be measured. Further, the controller receives an output signal from the temperature sensor, and generates a measured temperature value based on the output signal of the temperature sensor.

The present invention relates to a cryogenic heating system including a plurality of stages to provide accurate temperature control. The system can be used to provide non-contact heating and cooling of a test sample by use of an inert fluid. Accurate temperature control can be maintained, e.g., by use of controllers to provide temperature feedback control.

The present invention relates to a cryogenic heating system including a plurality of stages to provide accurate temperature control. The system can be used to provide non-contact heating and cooling of a test sample by use of an inert fluid. Accurate temperature control can be maintained, e.g., by use of controllers to provide temperature feedback control.

An occupant support adapted for use in a vehicle includes a cushion, a cushion cover, and a thermoelectric unit. The cushion is adapted to support an occupant on the occupant support. The cushion cover is arranged around at least a portion the cushion. The thermoelectric unit is configured to selectively heat and cool the occupant of the occupant support with conductive heat transfer through the cushion cover.

A temperature control system for a device and a temperature control method, the control method includes: a temperature detection module (1), a temperature control module (2), and a temperature adjustment module (3). The temperature detection module (1) is configured to detect and obtain a temperature of at the current moment the device. The temperature control module (2) is configured to obtain a predicted temperature at the next moment based on the temperature at the current moment and a temperature prediction model, and to output a temperature adjustment instruction to the temperature adjustment module (3) based on the predicted temperature at the next moment and a temperature threshold. The temperature adjustment module (3) is configured to adjust a temperature of the device based on the temperature adjustment instruction. The temperature control method improves the temperature stability of the device during operation and ensures the electric energy conversion efficiency of the device.

A temperature control system for a device and a temperature control method, the control method includes: a temperature detection module (1), a temperature control module (2), and a temperature adjustment module (3). The temperature detection module (1) is configured to detect and obtain a temperature of at the current moment the device. The temperature control module (2) is configured to obtain a predicted temperature at the next moment based on the temperature at the current moment and a temperature prediction model, and to output a temperature adjustment instruction to the temperature adjustment module (3) based on the predicted temperature at the next moment and a temperature threshold. The temperature adjustment module (3) is configured to adjust a temperature of the device based on the temperature adjustment instruction. The temperature control method improves the temperature stability of the device during operation and ensures the electric energy conversion efficiency of the device.

A temperature controller for a heater for a container for use in hazardous areas and a method of programming such a temperature controller. The method of programming such a temperature controller comprises the steps of writing identification data and parameter data to a memory of a portable token in an area remote from the hazardous area; transporting the token to a position in proximity to the temperature controller in the hazardous area; transmitting, by means of near field communication, the identification data and parameter data stored in the memory of the portable token to a receiver in the temperature controller; comparing the identification data received by the temperature controller with identification data stored in a memory of the temperature controller; and if said comparison of identification data is positive, and updating parameter data stored in the memory of the temperature controller with the parameter data received by the receiver.

A temperature controller for a heater for a container for use in hazardous areas and a method of programming such a temperature controller. The method of programming such a temperature controller comprises the steps of writing identification data and parameter data to a memory of a portable token in an area remote from the hazardous area; transporting the token to a position in proximity to the temperature controller in the hazardous area; transmitting, by means of near field communication, the identification data and parameter data stored in the memory of the portable token to a receiver in the temperature controller; comparing the identification data received by the temperature controller with identification data stored in a memory of the temperature controller; and if said comparison of identification data is positive, and updating parameter data stored in the memory of the temperature controller with the parameter data received by the receiver.