A vehicle HVAC system delivers airflow to a vehicle occupant cabin having a front row and a rear row. The vehicle HVAC system includes a casing, a front duct, a shifter base assembly and a distribution duct. The front duct defines an airflow passageway that is fluidly coupled to the casing. The shifter base assembly is disposed in the vehicle occupant cabin and includes a base housing defining an airflow passageway that is fluidly coupled to the front duct. The distribution duct defines an airflow passageway that is fluidly coupled to the shifter base assembly and the rear row of the vehicle occupant cabin. The airflow passageways of the casing, the front duct, the base housing and the distribution duct form a continuous passageway through which air flows into the rear row of the vehicle occupant cabin.

A heating, ventilation, and air conditioning (HVAC) apparatus for an automotive vehicle may include an internal volume divided into upper and lower regions, and configured for blowing the air to a defrost vent and a front seat face vent is made through the upper region, and blowing the air to a front seat foot vent and a rear seat vent is made through the lower region.

An air handling system for a vehicle comprises a conditioning section for controlling a temperature of a flow of air, a mixing section disposed downstream of the conditioning section with respect to a direction of the flow of the air, and a delivery section disposed downstream of the mixing section with respect to the direction of the flow of the air. The delivery section includes a first chamber, a second chamber, and a third chamber. A dividing plate separates each of the second chamber and the third chamber into a first side portion to a first side of the dividing plate and a second side portion to an opposing second side of the dividing plate. The second side portion of the third chamber is configured to primarily direct the flow of the air towards a rear seat area of the vehicle.

A cab for a construction machine includes; an operator seat including a seat base and a backrest; a control box disposed along a lateral side of the operator seat; an air conditioner main body for cooling air; and a duct disposed behind the operator sea for guiding a cooling air generated in the air conditioner main body. The duct has a blowing port provided at such a position as to allow the cooling air to flow frontward along at least one of a lateral side of the seat base and a lateral side of a lower portion of the backrest and along an inner surface of the control box.

A heating, ventilation, and air-conditioning system for a vehicle includes a housing, a door supported by the housing, and a lock integral with the housing. The housing further includes a first air flow path and a second air flow path. The door moves between a first position blocking airflow from the first air flow path and a second position blocking airflow from the second air flow path. The lock is configured to automatically lock the door in the second position upon assembly of the housing.

A method of heating and cooling at least one zone of a passenger compartment in a vehicle includes the steps of (a) pumping a coolant through an auxiliary coolant loop, (b) changing a temperature of the coolant utilizing a first heat exchanger associated with a refrigerant loop via an expansion device in the cooling mode, and a second heat exchanger associated with the refrigerant loop and (c) moving air through a third heat exchanger through which coolant moves, that third heat exchanger positioned in the passenger compartment, and at least one vent positioned within at least one zone of the passenger compartment.

A method for controlling environmental parameters in a vehicle having multiple climate controlled zones is provided in the disclosure. The method includes determining whether a climate controlled zone is occupied by a user. If the climate controlled zone is not occupied by a user, then a status of non-occupied is assigned to the climate controlled zone. If the climate controlled zone is occupied by a user, then the a status of occupied is assigned to the climate controlled zone, identifies the user, and retrieves from a database a user profile linked to the identified user. The user profile includes predetermined environmental parameter settings such air temperature, air flowrate, airflow direction, and seating temperature. The controller than adjust at least one environmental parameter for the climate controlled zone to match the predetermined environmental parameter settings. A system is provided for the implementation of the method.

A method according to an exemplary aspect of the present disclosure includes, among other things, controlling a climate control system of an electrified vehicle by shutting off refrigerant flow to a rear portion of a heat pump subsystem in response to a defrost request.

A system for controlling an air conditioner for vehicles may include a sensor configured to sense surface temperature of a passenger sitting part of a rear seat of a vehicle, a reference temperature estimation device configured to estimate surface temperature of the passenger non-sitting part of the rear seat as a reference temperature, a passenger boarding recognition device configured to compare the surface temperature of the passenger sitting part sensed by the sensor, with the reference temperature estimated by the reference temperature estimation device and to judge that a passenger is seated on the rear seat when a difference between the surface temperature of the passenger sitting part and the reference temperature exceeds a critical value, and an air conditioner operation controller configured to differently control volume and temperature of air discharged from the air conditioner according to whether or not a passenger is seated on the rear seat.

In an instrument panel provided in a vehicle cabin front section, a face that projects into a vehicle cabin is formed with a T-shape in vehicle rear view. An air-conditioning unit of a vehicle air-conditioning device is provided at an inside of the instrument panel. In the vehicle air-conditioning device, a foot blower outlet provided on the instrument panel blows an air-conditioned airflow toward the feet of a front seat occupant, and an interior air intake provided on the instrument panel takes in air from inside the vehicle cabin to generate the air-conditioned airflow. The foot blower outlet is formed in a lower portion of a side wall at a vehicle width direction central portion of the instrument panel.