A vehicle ventilating/cooling system may include at least one sun-load sensor arranged within the vehicle, and a controller configured to receive a sun-load signal indicating a sun-load level from the sensor and programmed to instruct at least one cooling component to conduct a purge of vehicle cabin air in response to the sun-load level exceeding a sun-load threshold.

A temperature modulation assembly for a motor vehicle's passenger compartment includes an assembly panel having a single or a plurality of solar panels which convert sunlight into electricity and an assembly housing which includes an internal thermoelectric Peltier cooler having a heat sink on its cool side and a heat sink on its hot side and an internal fluid distribution module which draws air into the assembly housing, causes some of the air to be cooled by passing through the cool side heat sink and directed back into the passenger compartment and the rest of the air to be heated by passing through the hot side heat sink and directed back into the passenger compartment. The components of the assembly housing utilize electricity that originates at the assembly panel, and the assembly housing is structured to distribute cooled towards near the passenger seating and heated air towards the windshield.

In order to detect the amount of radiation received by or the temperature of air in the vicinity of each of body parts of an occupant in a vehicle, a radiation information calculating device includes: an acquisition unit that acquires member temperature information that reflects temperatures of members exposed to a cabin of a vehicle; a calculation unit configured to calculate plural radiation information corresponding to each of body parts of an occupant in the cabin based on the member temperature information acquired by the acquisition unit; and an output unit that outputs the plural radiation information calculated by the calculation unit. The radiation information represents an amount of radiation received by a corresponding body part of the occupant.

An HVAC system for a vehicle includes infrared skin temperature sensors for measuring actual skin temperatures of the driver and a cabin temperature sensor for measuring an actual cabin temperature of ambient air within the passenger cabin. A controller module stores a target cabin temperature. The controller module controls the HVAC system according to a first error between the target cabin temperature and the actual cabin temperature. A personalization module stores a target skin temperature, and the personalization module determines an offset to be applied to the target cabin temperature according to a second error between the target skin temperature and the actual skin temperature. Infrared temperature measurements are collected for the left and right sides of a person's face, and the actual skin temperature is selected as the one that deviates most from the actual cabin temperature.

A vehicle detector assembly for detecting solar radiation may include a housing, a fixed plate fixed to an upper surface of the housing in a flat form, a plurality of photo detectors bonded to a surface of the fixed plate, each being connected to a lead having a uniform one-directional inclination structure, and a detector cap fastened to the housing and transmitting sunlight.

A method for controlling the temperature in a vehicle cabin, while the vehicle engine is turned off, includes the following steps: importing a State-of Charge information of a vehicle traction battery, an outside temperature, and inside temperature of the cabin into an electronic controller; calculating a normal electric power required for operating an HVAC system in a Normal mode; calculating a maximum operation time of the HVAC system in the Normal mode based on the State-of-Charge information; displaying the maximum operation time on a display; reading an operator input selecting one mode of at least the Normal mode and a first Eco mode of the HVAC system, wherein in the first Eco mode the HVAC system operates at a reduced electric power compared to the Normal mode; and operating the HVAC system in accordance with the operator input. A suitable HVAC system includes an appropriate user interface.

A vehicle includes a vision system configured to output a signal indicative of exterior conditions in a vicinity of the vehicle and a temperature sensor configured to output a signal indicative of an interior temperature of the vehicle. The vehicle also includes a plurality of articulable openings arranged to allow fluid flow communication between an interior and an exterior of the vehicle. The vehicle further includes a controller programmed to adjust at least one articulable opening toward an open position in response to the interior temperature exceeding a temperature threshold. The controller is also programmed to adjust at least one articulable opening toward a closed position in response to detection via the vision system of a threat condition in the vicinity of the vehicle.

Methods and systems are provided for estimating a temperature of a cabin of a vehicle and using the estimated cabin temperature. The methods and systems obtain, via at least one temperature sensor, a surface temperature of at least a first internal surface of the cabin of the vehicle. The methods and systems estimate, via a processor and using at least the obtained surface temperature, the heat transfer from the at least one surface to cabin air within the cabin. The methods and systems estimate, via a processor and using at least the estimated heat transfer, the cabin temperature of the vehicle. The methods and systems use the estimated cabin temperature of the vehicle to control at least one feature of an air conditioning module of the vehicle.

An air control system is disclosed. The system may comprise a processing unit. The processing unit may be configured to receive a seat status, and adjust an air control device based on the received seat status.

A multi-zone air conditioner system for large vehicles may include an air conditioning device configured to partition an internal of a vehicle into a plurality of zones to independently cool each zone, a detecting device configured to include a room temperature detector for detecting a room temperature of each zone and a photo detector for detecting an amount of solar radiation, an input device configured to switch an operating state of the air conditioning device to an automatic mode or a manual mode, and a control device configured to generate a control signal for operating the air conditioning device based on a signal transmitted from the detecting device and the input device.