An air-handling system for a motor vehicle includes a conditioning section having an evaporator core and a heater core. The conditioning section is separated into a primary zone and a secondary zone at a position disposed upstream of the heater core. The heater core extends partially into each of the primary zone and the secondary zone. A primary door assembly is disposed within the conditioning section at a position upstream of the heater core and a secondary door assembly is disposed within the secondary zone of the conditioning section at a position downstream of the primary door and upstream of the heater core.

An automatic air outlet system for supplying air into a vehicle interior of a vehicle, wherein the automatic air outlet system includes a plurality of air outlets that are motorized and may be automatically adjusted and that respectively include a plurality of setting parameters, a storage unit for storing a plurality of ventilation situations, wherein in the case of each of the plurality of ventilation situations a specific configuration of the setting parameters of each air outlet of the plurality of air outlets is specified, the configuration being adjusted to the corresponding ventilation situation, a specification unit for the purpose of specifying a ventilation situation to the plurality of ventilation situations that are stored in the storage unit, and a control unit for the purpose of controlling the plurality of air outlets such that the air outlets fulfil the ventilation situation that is specified by the specification unit.

The present disclosure provides an air conditioning device for a vehicle. The air conditioning device includes an air conditioning unit disposed in at least one of front or rear of the vehicle. The air conditioning device further includes a duct unit blowing air of the air conditioning unit into an interior and extending inside of at least one of a front pillar or a rear pillar. The air conditioning device further includes a vent unit communicating with the duct unit through a connecting duct and selectively opening and closing a discharge path of at least one of a main path, a first path, or a second path so as to discharge the blown air to a side of a roof frame.

In accordance with an aspect of the disclosure, a vehicle includes an air conditioning device. An input device is provided to receive a selection input of a user with respect to a blowing position of the air conditioning device and including a first input area, a second input area and a third input area for outputting an activation mark or a deactivation mark by the selection input, A controller is configured to control output of an activation mark or a deactivation mark of the first input area, the second input area and the third input area.

A cooling system includes air intakes, air intake fans, a duct, and an intake-air controller. The air intakes are separately formed near seats disposed side by side inside a vehicle. The air intake fans individually take in air through the air intakes. The duct guides the air taken in by the air intake fans to a battery. The intake-air controller controls a ratio of intake air flow rates in the air intake fans according to the state of a seated occupant.

A vehicle air conditioner for supplementing and regulating the air volume discharged to front seats and rear seats through a door component that controls a passage, and enabling the length of a package in the direction of a heater core to be reduced. The vehicle air conditioner has an air passage comprising: a front seat air passage through which cold air or hot air is discharged toward the front seats of a vehicle; and a rear seat air passage through which cold air or hot air is discharged toward the rear seats of the vehicle, wherein the front seat air passage comprises a front seat cooling passage and a front seat heating passage, and the rear seat path comprises a rear seat cooling passage and a rear seat heating passage, and includes: a first mixing part in which the cold air of the front seat cooling passage and the hot air of the front seat heating passage are mixed; and a second mixing part in which the cold air of the rear seat cooling path and the hot air of the rear seat heating path are mixed.

A movable body has a monitoring device that monitors a surrounding environment of the movable body through a window member. The movable body includes a heating device that heats a portion of the window member within a monitoring area of the monitoring device, an air conditioning device, and a control device. The monitoring device includes a detector that detects the surrounding environment, and a base member that faces an inner wall of the window member and is disposed such that a detection surface of the detector is located within a space between the base member and the window member. The space is in communication with the inside of the movable body, and the control device sets the driving force of the air conditioning device to be greater when a decrease in heating performance of the heating device is detected.

A wireless sensor network at a monitored location can be configured to generate sensor channel(s) of data to assess operational conditions at the monitored location. Inputs based on the sensor channel(s) of data are provided to a host system for analysis of a demand to one or more resources at the monitored location. Response messages can be generated based on the demand analysis and transmitted to actuator(s) at the monitored location to effect an adjustment to the operational conditions.

Various disclosed embodiments include illustrative heating, ventilation, and air conditioning (HVAC) cases, HVAC systems, vehicles, and methods. In an illustrative embodiment, a heating, ventilation, and air conditioning (HVAC) system includes a case, a blower disposed in the case and configured to cause air to flow, a first heat exchanger disposed in the case and configured to heat the air, and an ambient extractor port defined in the case and configured to discharge to an ambient environment exterior to a structure the air provided to the ambient extractor port.

An air conditioning system for a vehicle may include a refrigerant line through which a refrigerant circulates and an evaporator and a condenser are connected to each other; and a first core and a second core for indoor air conditioning, wherein the first core includes a first inlet and a first outlet through which a coolant passing through the evaporator is introduced and discharged, respectively, the second core includes a second inlet and a second outlet through which a coolant passing through the condenser is introduced and discharged, respectively, and the first core and the second core are connected to each other through a connection line, and the connection line is provided with a first valve selectively connecting the first core and the second core through the connection line.