An air-conditioning device includes: a heating cycle configured to circulate the heating medium through a heater core, the heater core being configured to heat blown air; an auxiliary heating device configured to heat the heating medium by an electric heater; a refrigeration cycle configured to circulate cooling medium discharged from a compressor through a condenser, the condenser being configured to heat the heating medium; refrigeration cycle control means configured to operate the refrigeration cycle such that temperature of the heating medium reaches target heating-medium temperature; auxiliary heating device control means configured to operate the auxiliary heating device such that the temperature of the heating medium reaches the target heating-medium temperature; and switching means configured to stop the operation of the refrigeration cycle in the state in which the temperature of the heating medium is equal to or higher than the threshold value.

A radiant heating system includes a radiant heating element, a steering wheel position monitoring device and a controller configured to control the radiant heating element in response to steering wheel position data received from the steering wheel position monitoring device. A method of controlling operation of a radiant heating system is also disclosed.

Vehicle air conditioning device comprising a bypass pipe which passes a radiator and an outdoor expansion valve, and opening/closing valves. A control device executes a heating mode to open solenoid valve 30 and close solenoid valve 40, and a dehumidifying and heating mode to close the solenoid valve 30, open solenoid valve 40, let a refrigerant radiate heat in outdoor heat exchanger 7, let the refrigerant absorb heat in heat absorber 9, and generate heat in auxiliary heater 23. When changing from the heating mode to the dehumidifying and heating mode, the control device sends the refrigerant to receiver drier portion 14, controls a compressor to reduce a difference between pressures before and after the solenoid valve 40, opens solenoid valve 40, closes solenoid valve 30, shuts off the outdoor expansion valve, and shifts the compressor to control in the dehumidifying and heating mode.

An air conditioner for a vehicle includes an air conditioning case having a first air passageway and a second air passageway partitioned by a separator therein; a PTC heater disposed in each of the first air passageway and the second air passageway to generate heat by electric energy; and a control unit for controlling operation of the PTC heater. The control unit individually controls discharge temperature of the first air passageway and discharge temperature of the second air passageway of the PTC heater, and if target discharge temperature of the first air passageway and target discharge temperature of the second air passageway are different from each other, the control unit calculates and outputs a compensation value for the PTC heater output of at least one of the first air passageway and the second air passageway. The PTC heater therefore has a reduced output when controlling for dual temperatures.

A controller unit for an aircraft control system may include a circuit board and a positive temperature coefficient device. The circuit board may include conductive traces and a plurality of mounted electronic components forming a circuit. The positive temperature coefficient device may be configured to provide overcurrent protection for the circuit. The controller unit may be located in explosion-restricted areas of the aircraft.

A method for regulating comfort in a passenger compartment of a vehicle, the passenger compartment including a seat, a radiant panel, and a heating device for the seat; the method being implemented by a controller having a memory containing a pre-established map. The method includes the following steps: acquiring a data item that is characteristic of the state of the passenger compartment, the characteristic data item including the temperature of the passenger compartment; determining, from the map, an optimal comfort level as a function of the characteristic data item; reading, in the map, regulation values associated with the optimal comfort level, the regulation values including values representative of the operating power of the radiant panel and of the heating device for the seat; and transmitting the read regulation values to the radiant panel and to the heating device.

In a vehicular air conditioning device, a heater core is disposed on a circulation passage for cooling water for cooling a motor, and an inverter configured to control an output of the motor by changing a carrier frequency, and heats conditioning air. An air conditioning controller sets a required calorific value of the motor and the inverter according to a vehicle compartment temperature requested by a passenger. A carrier frequency changing unit sets a carrier frequency at which a calorific value of the motor and the inverter is made equal to the required calorific value, out of carrier frequencies capable of implementing a target output of the motor to be set depending on a traveling state of a vehicle. An electric power conversion device converts direct-current power of a battery into alternating-current power at the set carrier frequency, and supplies the alternating-current power to the motor.

A vehicular heat management system includes a heat medium circuit, a heat source portion, and a device. A heat medium cooling an engine circulates in the heat medium circuit. The heat source portion heats the heat medium. The device is configured to function and heat the heat medium when the heat medium flowing into the device is at or above a predetermined temperature. When the engine is being warmed up, heat generated by the heat source portion is supplied to the device in preference to the engine. According to this, since the heat generated by the heat source portion is supplied to the device in preference to the engine when the engine is being warmed up, the engine can be warmed up early.

A system and method for configuring parameters for a variable gaseous appliance, comprise a sensor for detecting a composition of the gaseous fuel in a fuel tank. A first set of instructions are executable on a processor for receiving a signal from the sensor and analyzing the gaseous fuel based on the Wobbe Index, methane index, and inert gas percentage, to produce a gaseous fuel analysis. A second set of instructions are executable on the processor for producing a signal for configuring parameters of the engine for running the engine based on the gaseous fuel analysis.

A heating device includes: a heater that generates heat when electrical power is supplied; and at least two switching elements connected to the heater in series, the switching elements being configured to switch supply and interruption of electrical power to the heater by being switched on and off, wherein a first switching element of the at least two switching elements is kept at on state while switching operation of a second switching element is repeated between on and off.