An air handling system of a vehicle comprises a housing defining an inlet section. The inlet section includes a first inlet portion and a second inlet portion. The first inlet portion includes a first recirculation inlet configured to receive recirculated air originating from a passenger compartment of the vehicle and a first ambient air inlet configured to receive ambient air originating from an ambient environment. The second inlet portion includes a second recirculation inlet configured to receive recirculated air originating from the passenger compartment of the vehicle and a second ambient air inlet configured to receive the ambient air originating from the ambient environment. A first air distribution door and a first baffle door are disposed in the inlet section to selectively control a distribution of the recirculated air and the ambient air entering the first inlet portion. A second air distribution door and a second baffle door are disposed in the inlet section to selectively control a distribution of the recirculated air and the ambient air entering the second inlet portion.

A blower unit includes a casing defining a first passage and a second passage, a first internal-external air switching member, a second internal-external air switching member, and a partition defining an opening. During a two-layer internal/external air mode, the first internal-external air switching member opens an external air inlet and closes an internal air inlet and the second internal-external air switching member closes the external air inlet and opens the internal inlet, so that the external air is directly introduced into the first passage through the external air inlet and the external air in the second passage is introduced into the first passage through the opening of the partition and the internal air is directly introduced into the second passage through the internal air inlet and the internal air in the first passage is introduced into the second passage through the opening of the partition.

This disclosure relates to a system and method for isolating an interior of a motor vehicle from poor outdoor air quality. More particularly, this disclosure relates to a system and method configured to identify conditions associated with poor outdoor air quality and to respond to those conditions by isolating the interior of the motor vehicle from the outdoor environment. An example system includes a selector configured to permit a user to select a drive mode of the motor vehicle, a location system configured to detect a location of the motor vehicle, and a controller configured to issue one or more commands to isolate an interior of the motor vehicle from an environment outside the motor vehicle based on either a selected drive mode or a detected location.

In a mobility including a negative pressure space and method for controlling a pressure of the mobility in which the mobility is used a general vehicle in normal times, and when a special situation such as transferring infectious disease patients occurs, an internal space includes a general space and a negative pressure space by a partition wall, so that the infectious disease patients are safely transferred through the negative pressure space and the spread of infectious diseases is prevented. As a result, the usability of a vehicle is increased, and it is possible to respond to such special situation.

A vehicle thermal management system, may include a heating, ventilation, and air conditioning (HVAC) subsystem including an HVAC casing in which a heater core and an evaporator are received; and a cooling subsystem including a coolant loop through which a coolant circulates, wherein the heater core is located on the downstream side of the evaporator in an air flow direction, and the coolant loop is thermally connected to the heater core. The HVAC subsystem includes: an air mixing chamber located on the downstream side of the heater core within the HVAC casing; a discharge pipe fluidically communicating with the air mixing chamber, and being opened to the outside of a passenger compartment; and a flap configured for selectively opening and closing the discharge pipe.

A method for operating an air conditioning system for a vehicle for transporting persons. The air conditioning system, depending on the current number of passengers in a passenger compartment of the vehicle (level of occupation), controls a fresh air volume flow to be introduced into the passenger compartment from outside the vehicle in order to maintain a predefined minimum ambient air quality. The air conditioning system determines a total water mass flow, which is currently produced by the passengers in the passenger compartment, on the basis of air-conditioning measurement values and a current value for at least one operating parameter of the air conditioning system. From the total water mass flow and a predefined value for a water mass flow produced by a single passenger, the system determines the current number of passengers in the passenger compartment. There is also described an air conditioning arrangement for carrying out the method.

An apparatus for heating an operator cab of a vehicle or machine comprises a cab air heating unit and a cab air duct for conducting air toward an interior region of the cab from the cab air heating unit. An external air intake for conducting external air to an inlet side of the cab air heating unit includes a condensing conduit extending through at least part of the cab air duct. In use, when the condensing conduit is subject to a flow of external air at a temperature below that of the air passing through the cab air duct, an outer surface of the condensing conduit acts as a condensing surface on which moisture in air passing through the cab air duct condenses. This removes moisture from the air before it is introduced into the cab.

Provided is an air-conditioning device for a vehicle, including: a cooling device configured to cool air passing through a duct; a heater core, which is arranged in the duct on a downstream side of airflow with respect to the cooling device, and is configured to use an engine coolant as a heat source to heat the air; a water valve provided in a coolant circulation system on an upstream side of the heater core; and a controller configured to control those components, in which the controller is configured to decrease an opening amount of the water valve in a predetermined cooling mode. The control is configured to, when the opening amount of the water valve is decreased, decrease a rotational speed of a compressor of the cooling device, and increase a target evaporator temperature of an evaporator of the cooling device, thereby decreasing cooling performance of the cooling device.

The present invention relates to an air conditioner for a vehicle, which includes a cold air passageway and a warm air passageway, and two blowers disposed in the air passageways, thereby rapidly ventilating the interior of the vehicle using the two blowers.

An air treatment system is described, for a closable room of a vehicle, comprising: an air conditioning device provided with a fan and connectable to the room; an inlet opening for outside air, connected to the air conditioning device; a filtration device for filtering the outside air entering from the inlet opening; a recirculation port; a valve assembly provided with a shutter member, interposed between the inlet opening, the recirculation port and the air conditioning device and movable between a plurality of operating positions, in which it varies the shares of air coming from the inlet opening and the recirculation port; and a control unit to adjust the operating position of the shutter member so as to control the shares of air being drawn from the inlet opening and from the recirculation port and to maintain a predetermined value of overpressure in the room with respect to the outside.