An air cleaning apparatus mounted to an internal automobile structure selected from an armrest, a console, a seat, a headrest, an overhead console, a handle, and a door, includes an air inflow unit arranged in the internal automobile structure, through which air inside an automobile is introduced, an air cleaning unit which is arranged in the internal vehicle structure and filters the introduced air inside the automobile, a first air flow path arranged in the internal automobile structure, through which the air, having been introduced through the air inflow unit and filtered by the air cleaning unit, is discharged to the interior of the automobile, and a second air flow path arranged in the internal automobile structure, through which blowing air, having been introduced to the internal automobile structure and not having passed through the air cleaning unit, is discharged to the interior of the automobile.

The invention relates to a thermal management system (1) for a motor vehicle, comprising: at least one sensor (13, 113) capable of measuring at least one quantity that can be used to determine at least one thermal comfort data item (TS), a predefined number of actuators (A101, A102, A103, A104), configured, respectively, for adjusting at least one parameter of an associated piece of equipment (3, 5, 7, 9) of said vehicle, and a control device (12) for controlling the actuators (A101, A102, A103, A104) on the basis of the measurements of said at least one sensor (13, 113).
According to the invention, the control device (12) comprises at least one processing means (14) for: identifying at least a first and a second piece of equipment for acting on a first and a second part of the occupant's body, respectively, if thermal regulation of the occupant is required, and controlling at least a first and a second actuator configured, respectively, for adjusting at least one parameter of the first and second pieces of equipment identified, so as to act on said parts of the occupant's body.
The invention also relates to a thermal management method implemented by such a system (1).

A heater is installed indoors and heated to a target temperature. The heater is controlled by a controller. The controller has a regular control module which heats the heater to reach the target temperature. In addition, the controller has a suppressive control module which heats the heater to a suppressed temperature lower than the target temperature by electric power suppressed so that surface moisture adhering on the surface of the heater is decreased. When an activation of the heater is ordered, the heater is heated by the suppressive control module, after that, the heater is heated by the regular control module. The surface moisture is decreased by the suppressed temperature. Therefore, generating rapid boiling and/or rapid evaporation of the surface moisture by the target temperature may be suppressed.

An HVAC comfort system operates in a cabin of a vehicle. A plurality of vehicle status parameters are measured including a cabin temperature and a seat occupancy configuration. The method detects whether the vehicle status parameters correspond to a predetermined override state. When the vehicle status parameters correspond to the predetermined override state, then a respective mandated setting is automatically activated. Unless prevented by the mandated setting, one of a plurality of HVAC modes is automatically selected in response to the cabin temperature and other inputs, wherein the HVAC modes include an extremity heating mode and a panel circulation mode. The extremity heating mode is comprised of automatic activation of a touchpoint heated surface and other outputs in response to the seat occupancy configuration. The panel circulation mode is comprised of automatic activation of one or more zones for convective cooling in response to the seat occupancy configuration and may include activating other cooling devices.

A vehicle is disclosed. The vehicle includes a passenger cabin; a steering wheel having a hub and a rim; and a ventilation system having a first air outlet for discharging a first jet of air, and a second air outlet for discharging a second jet of air. The first jet of air projects through a gap between the hub and the rim, and the second jet of air intersects and deflects the first jet of air.

A temperature regulating system for interior surfaces of a vehicle includes a heating, ventilation, and air conditioning system. An air register assembly is operably coupled to the heating, ventilation, and air conditioning system to direct air to an interior compartment. The air register assembly includes an actuation assembly for adjusting a position of the air register assembly. A target feature having a contact surface is disposed within the interior compartment. A temperature sensor is coupled to the target feature and senses a surface temperature of the contact surface. A controller communicates a notification with temperature information. A remote start device is communicatively coupled with the controller. The controller adjusts the position of the air register assembly to direct air across the contact surface of the target feature in response to a remote start signal from the remote start device.

A vehicle is disclosed. The vehicle includes a passenger cabin; a steering assembly including a steering wheel mounted on a steering column assembly; and a ventilation system having a first air outlet for discharging a first jet of air, and a second air outlet for discharging a second jet of air. The first air outlet and the second air outlet are located on the steering column and the second jet of air intersects and deflects the first jet of air.

A temperature regulating system for interior surfaces of a vehicle includes a heating, ventilation, and air conditioning system. An air register assembly is operably coupled to the heating, ventilation, and air conditioning system to direct air to an interior compartment. The air register assembly includes an actuation assembly for adjusting a position of the air register assembly. A target feature having a contact surface is disposed within the interior compartment. A temperature sensor is coupled to the target feature and senses a surface temperature of the contact surface. A controller communicates a notification with temperature information. A remote start device is communicatively coupled with the controller. The controller adjusts the position of the air register assembly to direct air across the contact surface of the target feature in response to a remote start signal from the remote start device.

A HVAC thermal conditioning system provides a macroclimate environment. An auxiliary thermal conditioning system has multiple microclimate devices in close proximity to a region of the occupant. The microclimate devices are arranged within an interior space that provides the macroclimate environment to an occupant. A controller communicates with the microclimate devices and calculates an occupant personal comfort based upon a thermal energy experienced by the occupant from thermal radiation sources, thermal convection sources, and thermal conduction sources, and to automatically command the microclimate devices in response to the calculated occupant personal comfort to achieve a desired occupant personal comfort. The automatic command adjusts and apportions the thermal conduction sources and/or thermal radiation sources to achieve the desired occupant personal comfort. A power management module adjusts the HVAC thermal conditioning system while adjusting and apportioning the thermal conduction sources and/or thermal radiation sources to achieve the desired occupant personal comfort.

A radiant heater for a vehicle may include a heat generation device which is coupled to a first surface of a steering column cover through a hinge, has one or more heat generators generating radiant heat, and can rotate with respect to the first surface of the steering column cover by the hinge so that the distance between the heat generators and a heat reception portion can be adjusted.