A thermal management system for an electric vehicle includes an interior air conditioning part including an air inflow part, an air discharge part, a cooling core, a heating core arranged between the cooling core and the air discharge part, and an adjustment door. The adjustment door is selectively adjustable to control whether air from the cooling core may flow into the heating core. A heat transfer line connects an electric part core to the heating core for transferring that heat of the electric part to the heating core, in order to allow heat dissipation of the electric part through the heating core.

There is provided with a moving body control apparatus. An image capturing unit captures a periphery of a moving body through a transmitting portion. A heater is capable of heating the transmitting portion. An air-conditioning unit switches an air-conditioning state in the moving body between an inside air circulation state and an outside air introduction state. A control unit controls the heater. An ambient temperature detection unit detects an ambient temperature. The control unit starts the operation of the heater when the ambient temperature is not more than a predetermined temperature threshold. The predetermined temperature threshold of the case in which the air-conditioning state is set to the inside air circulation state is higher than the predetermined temperature threshold in the case in which the air-conditioning state is set to the outside air introduction state.

A vehicle cabin thermal management system includes a first heat exchange system adapted to operate primarily based upon a convective mode of heat transfer within a vehicle cabin, a second heat exchange system adapted to operate primary based upon a non-convective mode of heat transfer within the vehicle cabin, and a controller in communication with the first heat exchange system and the second heat exchange system, wherein the controller controls a thermal output of the second heat exchange system, and wherein the controller controls the first heat exchange system to reduce the operating level of the first heat exchange system in response to the controller operating the second heat exchange system.

A heating apparatus includes: a motor control unit, having an inverter and a controller that are connected to each other; an electric heater; and a motor, having three-phase windings, where ends of the three-phase windings are connected to the inverter, the other ends of the three-phase windings are connected to a connection point, and the connection point is connected to the electric heater. Therefore, the electric heater can be controlled by using the motor control unit that controls the motor, without a need to independently dispose a control circuit for controlling the electric heater, so that a quantity of controllers, a weight of the heating apparatus, a required occupation space of the heating apparatus, and costs of the heating apparatus can be reduced.

A computer includes a processor and a memory, the memory storing instructions executable by the processor to receive first input to sanitize a vehicle passenger cabin via a passenger cabin heater, output one or more candidate initiation times at which to begin actuation of the heater, and, then, actuate the heater to a temperature above a specified sanitization threshold according to the initiation time identified in a second input.

An apparatus and method for melting snow and/or ice on a vehicle comprises a precipitation sensor, a surface temperature sensor, an ambient temperature sensor, a heater, and a programmable controller. The programmable controller comprises a memory unit and a processor to store and execute a cut-off surface temperature Tc, and program modules, respectively. A heater control module is configured to deactivate the heater based on the surface temperature being greater than the cut-off surface temperature. The heater could be an electric heater and a hydronic heater. The electric heater is electrically coupled to at least any one of, an alternator, an onboard power system, and a remote power source, via a relay. Further, the heater control module is configured to activate the heater based on an ambient temperature being lower than freezing point of water and precipitation being present outside the vehicle, thereby melting snow and/or ice on the vehicle.

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.

A control system includes a manual-type air conditioner, and a control device which causes the manual-type air conditioner to execute remote air conditioning in response to a command from outside of a vehicle. The control device starts actuation of the manual-type air conditioner with a maximum temperature as a target blowout temperature of an air-conditioning air and a maximum air quantity as a target air quantity in response to a trigger command of the remote air conditioning, and gradually changes and reduces the target air quantity while gradually changing the target blowout temperature toward a target intermediate temperature with elapse of time. The control device changes the target blowout temperature and the target air quantity respectively to a set blowout temperature and a set air quantity at a time of previous disembarkment, when boarding of a user to the vehicle is detected.

Vehicle comprising a passenger compartment and a system for cleaning the passenger compartment comprising at least one measuring member for measuring the level of dirtiness of said passenger compartment, at least one heating member configured to heat the ambient air of the passenger compartment to a temperature higher than 40° C. in order to desorb the impurities in the passenger compartment, at least one ventilation member configured to remove the ambient air and the desorbed impurities to outside the passenger compartment and at least one control member configured to activate the heating member if the measured level of dirtiness is above a predetermined maximum level of dirtiness.

A vehicle (100) includes a battery (2), an air conditioner (AC), a first temperature adjustment circuit (4) including a first pump (EWP1) configured to supply a heat medium to the battery (2) and a chiller (11), a second temperature adjustment circuit (6) including a second pump (EWP2) configured to supply the heat medium to a power conversion device (5) and a radiator (12), a coupling passage (8, 9) configured to connect the first temperature adjustment circuit (4) and the second temperature adjustment circuit (6) to form a coupling circuit (7), an electromagnetic switching valve (EWV) configured to switch between a circulation state in which the heat medium can circulate through the coupling circuit (7) and a non-circulation state in which the heat medium cannot circulate through the coupling circuit (7), a first temperature sensor (S1) configured to acquire a temperature of the battery (2), and a control device (10) configured to select a mode based on at least the temperature of the battery (2). The control device (10) performs a control based on a basic control map (MapI) after selecting a series mode of a special control map (MapII).