Smart window apparatus, systems, and related methods for use with vehicles are disclosed. A disclosed apparatus includes control circuitry configured to obtain data associated with a vehicle that is parked, determine, based on the data, a status of the vehicle associated with relatively high cabin temperature or an unattended occupant in the vehicle, and open a vehicle window via a window actuator to cool the vehicle cabin. The control circuitry is also configured to detect, based on the data, an event in an environment associated with the vehicle while the vehicle window is open and adjust the vehicle window via the window actuator in response to the detection.

A barrier door for a protective enclosure includes a lower section and an upper section operably coupled with the lower section, and a ventilation system disposed within the lower section. The ventilation system includes one or more blowers and a plenum. The ventilation system is configured to direct air one or more of into or out of the protective enclosure.

There is provided a vehicle comprising a thermal conditioning system and a cabin. The thermal conditioning system comprises a fan (102), a first heat exchanger (104), an outside air duct (112), a cabin air duct (114), a sensor, and a control unit (122). The fan is configured to generate a flow of air. The first heat exchanger is arranged to transfer heat to the flow of air. The thermal conditioning system is configured to be operated in a first mode and a second mode. In the first mode, the fan rotates in a first direction to direct the flow of air along a first flow path. In the second mode, the fan rotates in a second direction opposite to the first direction to direct the flow of air along a second flow path. The sensor is arranged to provide a signal representative of a temperature of a part of the vehicle. The control unit is configured to switch the thermal conditioning system between the first mode and the second mode based on the signal.

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.

A heating, ventilation, and air conditioning (HVAC) system for a vehicle may include a heating body positioned inside an HVAC duct of the vehicle, formed between a first electrode portion and a second electrode portion having polarities opposite to each other. The heating body is configured to generate heat when the heating body is electrified to increase a temperature of an air being transported through the HVAC duct.

A vehicle window vent is shaped and sized to fit in the opening left when the vehicle window is lowered or retracted. The vent fits in the opening, and its edges are captured by channels that hold the window when the window is closed. Along one edge, the vent comprises a channel, similar to the window-opening channel, so that the vent can accept an edge of the window. Thus, when the window is opened and then partially closed on the vent, the window and vent together are held securely in the window opening. The vent comprises louvered openings to allow air in and out of the vehicle. The openings may be covered with screen or mesh to prevent insects from entering the vehicle. Other features may be provided as well. An efficient method for manufacturing the vents is also described and claimed.

A barrier door may include a section including an outer stationary portion and an inner movable portion disposed within the outer stationary portion, an actuator, and a controller. The actuator may move the inner movable portion between different positions to control flow of air between a protective enclosure and a volume outside of the protective enclosure. The controller may monitor one or more operating characteristics of the actuator and may modify an operational status of the actuator to control the flow of the air between the protective enclosure and the volume outside of the protective enclosure based at least in part on the one or more operating characteristics.

Smart window apparatus, systems, and related methods for use with vehicles are disclosed. A disclosed apparatus includes control circuitry configured to obtain data associated with a vehicle that is parked, determine, based on the data, a status of the vehicle associated with relatively high cabin temperature or an unattended occupant in the vehicle, and open a vehicle window via a window actuator to cool the vehicle cabin. The control circuitry is also configured to detect, based on the data, an event in an environment associated with the vehicle while the vehicle window is open and adjust the vehicle window via the window actuator in response to the detection.

A vehicle ventilation control system includes: a reception unit that receives an instruction signal input by a user via wireless communication; and a control unit that controls ventilation inside a vehicle based on the instruction signal, in which the control unit performs ventilation control to control the ventilation based on the instruction signal input during a period after the user gets out of the vehicle to next boarding.

A tractor cab fresh air intake includes a pair of air intake covers mounted to a plurality of body panels. Each air intake cover has an air intake opening adjacent a lower end. The body panels may be attached to a pair of C-posts of a tractor cab frame. Air outlet openings adjacent the upper end of each air intake cover extend through the body panels into the pair of C-posts.