A temperature control system and a driving method thereof, and a liquid crystal apparatus are provided. In the temperature control system, an input voltage adjustment circuit is respectively coupled to a control signal output end of a control circuit, a power signal output end, and an input end of a signal amplification circuit, and is configured to control the signal strength of a basic electrical signal transmitted to the input end of the signal amplification circuit under the control of a control signal output from the control signal output end; the signal amplification circuit is configured to output a corresponding target electrical signal to a heating element according to the basic electrical signal, and the heating element is configured to adjust the heating temperature according to the target electrical signal; a temperature sensing circuit is respectively coupled to the heating element and the control circuit, and is configured to convert a sensed sensing signal into a feedback signal and transmit the feedback signal to the control circuit; and the control circuit is configured to control the control signal output from the control signal output end according to the received feedback signal.

A temperature control system and a driving method thereof, and a liquid crystal apparatus are provided. In the temperature control system, an input voltage adjustment circuit is respectively coupled to a control signal output end of a control circuit, a power signal output end, and an input end of a signal amplification circuit, and is configured to control the signal strength of a basic electrical signal transmitted to the input end of the signal amplification circuit under the control of a control signal output from the control signal output end; the signal amplification circuit is configured to output a corresponding target electrical signal to a heating element according to the basic electrical signal, and the heating element is configured to adjust the heating temperature according to the target electrical signal; a temperature sensing circuit is respectively coupled to the heating element and the control circuit, and is configured to convert a sensed sensing signal into a feedback signal and transmit the feedback signal to the control circuit; and the control circuit is configured to control the control signal output from the control signal output end according to the received feedback signal.

An induction heating system can be adapted for shrink fitting a plurality of different assemblies. A plurality of tooling units associated to respective ones of the assemblies, each one having an appropriately configured induction coil and holder, can be provided. A computer can be used to control the delivery of electrical power to the induction coil in accordance with a heating recipe, and can be provided with an input device for inputting an assembly identifier allowing the computer to operate the control based on the right heating recipe.

An induction heating system can be adapted for shrink fitting a plurality of different assemblies. A plurality of tooling units associated to respective ones of the assemblies, each one having an appropriately configured induction coil and holder, can be provided. A computer can be used to control the delivery of electrical power to the induction coil in accordance with a heating recipe, and can be provided with an input device for inputting an assembly identifier allowing the computer to operate the control based on the right heating recipe.

A sensor system includes a sensor and a plurality of panels connected to each other in a loop around the sensor. A duct is positioned to direct air towards the sensor. A heating element is disposed in the duct. First and second valves are disposed in the duct and spaced from each other along the duct. The first and second valves are selectively actuatable between an open position permitting airflow through the duct and a closed position blocking airflow through the duct. A computer is communicatively coupled to the heating element and the first and second valves. The computer is programmed to, upon determining a first difference between one respective panel temperature and an ambient temperature is greater than a first threshold, actuate the second valve to the closed position and maintain the first valve in the open position. The computer is further programmed to actuate the heating element to a first heating level based on the first difference.

A sensor system includes a sensor and a plurality of panels connected to each other in a loop around the sensor. A duct is positioned to direct air towards the sensor. A heating element is disposed in the duct. First and second valves are disposed in the duct and spaced from each other along the duct. The first and second valves are selectively actuatable between an open position permitting airflow through the duct and a closed position blocking airflow through the duct. A computer is communicatively coupled to the heating element and the first and second valves. The computer is programmed to, upon determining a first difference between one respective panel temperature and an ambient temperature is greater than a first threshold, actuate the second valve to the closed position and maintain the first valve in the open position. The computer is further programmed to actuate the heating element to a first heating level based on the first difference.

A dental furnace, in particular for the pre-drying of dental restoration parts or for the debinding of dental restoration parts, with a heating chamber and at least one electric heating element, a power control device for the heating element, a temperature detection device with which the temperature in the heating chamber can be detected is provided. The temperature detection device is designed in particular as a thermocouple or as an optical temperature measuring system for direct detection of the temperature of the dental restoration system. A process control device is connected to the temperature sensing device and to the power control device for controlling the power control device. The process control device comprises a current control device with which, in particular in the absence of a measuring signal of the temperature detection device, the power control device can be controlled.

According to one aspect, a cooking apparatus having a main fuel manifold that provides fuel to at least one manual burner and at least one control valve, and at least one controlled fuel manifold in fluid communication with the at least one control valve, each controlled fuel manifold for providing fuel to at least one controlled burner. The cooking apparatus also includes at least one thermocouple, each thermocouple monitoring at least one measured temperature within the cooking apparatus. The cooking apparatus also includes an input device for receiving a desired temperature set-point. The cooking apparatus also includes a controller having a microprocessor operable to compare the at least one measured temperature and the temperature set-point. In response to the comparison, the controller will selectively adjust the at least one control valve to restrict an amount of fuel flowing to the at least one controlled fuel manifold.

According to one aspect, a cooking apparatus having a main fuel manifold that provides fuel to at least one manual burner and at least one control valve, and at least one controlled fuel manifold in fluid communication with the at least one control valve, each controlled fuel manifold for providing fuel to at least one controlled burner. The cooking apparatus also includes at least one thermocouple, each thermocouple monitoring at least one measured temperature within the cooking apparatus. The cooking apparatus also includes an input device for receiving a desired temperature set-point. The cooking apparatus also includes a controller having a microprocessor operable to compare the at least one measured temperature and the temperature set-point. In response to the comparison, the controller will selectively adjust the at least one control valve to restrict an amount of fuel flowing to the at least one controlled fuel manifold.

A temperature display and/or control system is disclosed for a cooing apparatus, such as a grill, comprising a plurality of individual zones to provide individual zone temperatures. Each zone of the grill is associated with a temperature sensor, such as a thermocouple, and a visual indicator to indicate the zone temperature, such as control knob bearing a multi-color LED. A controller obtains a signal from the temperature sensor indicating a raw temperature and converts the raw temperature to an actual zone temperature based on a temperature profile selected for the zone. The temperature profile is configurable for each zone based on a configuration of the zone in order to maintain an accurate temperature conversion despite alterations to an environment.