The present patent application relates to a high-voltage motor vehicle electrical system comprising an electrical heating device and at least on further consumer during switching on of which, undesired electromagnetic oscillations may occur in the electrical system. According to the invention, these are suppressed by initially switching on the heating device, before the further consumer is switched on. Switching on the heating device changes the complete impedance of the electrical system such that a resonant enhancement of the interference oscillations is prevented. Preferably, the heating device is switched on only as shortly as possible (only during the switching on process of the further consumer) in order to minimize an undesired heating.

A method is provided for operating a fuel-operated vehicle heater (10) during a start phase of combustion operation. The heater includes a combustion air feed device (26) feeding air and a fuel feed device (22) feeding fuel (B) to a burner area (12) with a combustion chamber (16). An electrically energizable ignition element (32) ignites a fuel/air mixture formed. The method includes energizing the ignition element (32) in a preheating phase prior to the fuel feed, at a time of entry into an ignition phase, detecting electrical resistance of the ignition element (32) and determining a desired resistance based on the electrical resistance of the ignition element (32) detected and operating the ignition element (32) in a resistance-regulating operating mode during the ignition phase such that an actual resistance of the ignition element (32) is in the range of the determined desired resistance of the ignition element (32).

Methods and systems are provided for managing cabin conditions. A fogging metric can be determined. A control signal is generated based on the fogging metric. The system facilitates modification to the operation control of the at least one climate control device based on the control signal. Such a response can correspond to control of a target evaporator temperature of an HVAC system. The target evaporator temperature can be adjusted within a continuous range of available temperatures. As such, the operation of the evaporator can be adjustably tailored to the needs of addressing a fog factor while also maximizing efficiency of the overall system.

An information processing device that controls a vehicle including a plurality of heating devices. The information processing device executes acquiring an air conditioning request transmitted from a user terminal, and selecting a heating device to be operated, among the heating devices in which an operation is specified by the air conditioning request, based on a remaining battery amount of the vehicle.

Illustrative examples of a vehicle system and associated methods may be directed to monitoring one or more vehicle components to prevent excess temperatures or heat. A thermal controller may be configured to determine a timer based on a predicted thermal input, and based on the timer, compare a temperature of the vehicle component to a temperature threshold. The thermal controller may be further configured to send an instruction to reduce the temperature of the vehicle component based on the comparison of the temperature to the temperature threshold.

A control system for a radiant heater device includes a radiant heater device, a heater ECU that controls an energization and a deenergization of a heat generation unit, and an integrated ECU that transmits an operation prohibition command for prohibiting the energization of the heat generation unit and an operation permission command for permitting the energization of the heat generation unit to the heater ECU. The integrated ECU transmits the operation prohibition command when receiving a collision signal indicative of a vehicle collision or a prediction of the vehicle collision, and transmits the operation permission command when not receiving the collision signal. The heater ECU performs the deenergization control when a non-reception state in which the operation permission command is not received from the integrated ECU is continued for a predetermined time or more. As a result, the energization can be interrupted before an occupant is adversely affected.

An electrically driven vehicle includes: a vehicle body provided with the vehicle interior, a battery which is mounted to the vehicle body and is able to be used for running, an electric heater which executes an air-conditioning operation which uses an electrical power of the battery when air-conditioning vehicle interior, a power generation device which is at least partly removably mounted to the vehicle body and executes another air-conditioning operation other than the air-conditioning operation which uses the electrical power of the battery when air-conditioning the vehicle interior, and an air conditioning change unit which changes the use state of at least one of the electric heater and the power generation device.

A vehicle climate control system includes a heat exchanger to heat ambient air using engine waste heat, and a plurality of positive temperature coefficient (PTC) heating elements to heat air passed through the heat exchanger. The vehicle also includes a controller programmed to, while the vehicle is driven without engine propulsion, issue a command to sequentially de-energize the PTC heating elements before an upcoming engine activation. The sequential de-energization of the PTC heating elements is performed according to a schedule that is based upon a power surge dissipation time.

An air-conditioner for a vehicle includes: a first circuit in which a cooling medium circulates; a heater heating the cooling medium; a first pump disposed in the first circuit; a second circuit cooling a heat emitting portion; a second pump disposed in the second circuit; an adjustment portion controlling a circulation amount of the cooling medium flowing in the first circuit and a circulation amount of the cooling medium flowing in the second circuit; and a control portion. The vehicle includes a regenerative device, and a storage device is charged with electric energy recovered by the regenerative device. When the regenerative device is recovering the electric energy and when it is determined that power in the storage device needs to be consumed, the control portion drives the heater to heat the cooling medium such that the power in the storage device is converted into heat energy.

A vehicle includes a traction battery, a cabin, and a controller. The controller is programmed to, in response to a request to heat both the battery and the cabin, and a time to next planned usage of the vehicle exceeding a first threshold time, heat the battery and delay heating the cabin at least until the time to next planned usage is less than the first threshold time.