A system for an aircraft includes a first fluid circuit extending from a first end to a second end, and a network comprising a plurality of networked heater assemblies disposed along the first fluid circuit between the first end and the second end. Each of the networked heater assemblies includes at least one temperature sensor, a heater element, and a local controller. The at least one temperature sensor is in communication with the first fluid circuit for periodically measuring a temperature in the first fluid circuit and generating a corresponding local temperature signal. The heater assembly selectively applies heat to the first fluid circuit based on the local temperature signal or another temperature signal on the network. The local controller receives the local temperature signal or another networked temperature signal and operates the heater assembly in response thereto to maintain the local temperature signal above a predetermined threshold.

A temperature control apparatus is provided, which is capable of, even when it is necessary to perform control by means of valves in a plurality of channels, promptly controlling a temperature of an area to be temperature-controlled promptly to a desired temperature. Passage and blockage of a heating medium passing through a first supply channel to a mixing channel, a temperature of the heating medium being controlled by a first temperature regulating unit at a predetermined temperature, and passage and blockage of a heating medium passing through a second supply channel to the mixing channel, a temperature of the heating medium being controlled by a second temperature regulating unit, are controlled by a valve unit. The valve unit includes a first spool valve and a second spool valve, which are coupled through a heat insulating layer.

A smart light switch includes a housing, a light actuator located within the housing, and a processor and memory. The processor and memory are operably connected and located within the housing. The processor is adapted to selectively turn an electrical load on and off in accordance with a program schedule stored in memory. The smart light switch further includes a data communications module operable to provide data communication across a wireless network to a remote device. The program schedule includes time periods and a set of light activation rules for each time period. The smart light switch is operable to receive the time periods from a remote device having a different set of rules than the set of light activation rules for the smart light switch.

Embodiments of the invention comprise systems and methods for using the geographic location of networked consumer electronics devices as indications of occupancy of a structure for purposes of automatically adjusting the temperature setpoint on a thermostatic HVAC control. At least one thermostat is located inside a structure and is used to control an HVAC system in the structure. At least one mobile electronic device is used to indicate the state of occupancy of the structure. The state of occupancy is used to alter the setpoint on the thermostatic HVAC control to reduce unneeded conditioning of unoccupied spaces.

A gas cooktop includes a primary gas burner, an auxiliary gas burner positioned adjacent to the primary gas burner, a fuel supply system, a griddle positioned over the primary gas burner and the auxiliary gas burner, and a temperature probe configured for receipt within the griddle proximate the auxiliary gas burner. A controller is configured to initiate operation of the fuel supply system in the auto griddle mode where a flow of fuel is supplied to operate the primary gas burner and the auxiliary gas burner at a target heat level, obtain a griddle temperature of the griddle using the temperature probe, identify a heating failure based at least in part on the griddle temperature, and implement a responsive action in response to identifying the heating failure.

A position information antenna 22b receives a position signal including position information about a sending source (satellite, base station, or the like) of a positioning radio wave. A communication antenna 22a transmits position information about a compressor 100 (air compressor) that compresses the air and receives meteorological information corresponding to the position of the compressor 100 from a server on a cloud. A controller 13 specifies the position of the compressor 100 from the position signal received by the position information antenna 22b and controls the compressor 100 on the basis of the meteorological information corresponding to the position of the compressor 100 received by the communication antenna 22a.

A method for controlling a refrigerating device of a water dispenser. The method includes: S1, controlling a refrigerating module to cool water in a cold water tank; S2, when the temperature of the water in the cold water tank is reduced to a first preset temperature, stopping the refrigerating module at the first preset time; S3, controlling the refrigerating module to work again to continue cooling the water in the cold water tank; S4, when the temperature of the water in the cold water tank is reduced to an n.sup.th preset temperature, stopping the refrigerating module at the n.sup.th preset time; and S5, determining whether the temperature of the water in the cold water tank reaches a target temperature, and if not, repeating steps S3 and S4 after reaching a predefined number. Through multi-stage refrigeration, an ultra-low temperature refrigeration is achieved.

After a temperature point of the cooling fan is set according to a plurality of temperatures corresponding to a plurality of first consecutive time intervals, control a duty cycle of the cooling fan according to the temperature point, acquire temperature variation data of the cooling fan during a plurality of second consecutive time intervals, generate a gain factor and a frequency factor of the cooling fan according to the temperature variation data, and generate a proportional gain factor, an integral time factor and a derivative time factor of a proportional-integral-derivative controller of the cooling fan according to the gain factor and the frequency factor of the cooling fan. The plurality of first consecutive time intervals are followed by the plurality of second consecutive time intervals.

A method for detecting and compensating for sediment build-up in a tank style water heater is disclosed. An illustrative but non-limiting example may include monitoring a temperature of water within a water storage tank of a water heater over time, resulting in a monitored temperature profile. The method may then include determining if the monitored temperature profile includes one or more features that indicate sediment build up in the water storage tank, and if so, provide an output that indicates sediment build up is present.

A method for providing a cooling or heating variable fan-off delay based on a Conditioned Space Temperature (CST) measured during a current variable fan-off delay period compared to CST values measured during the current variable fan-off delay period. The method may also include turning off a cooling or heating system and continuing to operate an HVAC fan until the CST reaches an Inflection Point (IP) where a rate of change of the CST with respect to time (dT/dt) equals zero plus or minus a confidence interval tolerance. The method may also include providing a cooling or heating variable differential (or offset) and/or variable fan-off delay based on the duration of the thermostat call for cooling or heating, an off cycle time, a cooling temperature split, a heating temperature rise, outdoor air temperature, supply air temperature or a rate of change with respect to time of any of these HVAC parameters.