An in-vehicle air conditioning device includes a plurality of air conditioning openings provided for each of a plurality of seats of the vehicle at at least one of an upper part and a lower part of the vehicle corresponding to each seat; a plurality of airflow generators that are provided for each of the air conditioning openings and generate an airflow discharged from the air conditioning openings while controlling a temperature and an amount of the airflow; and a controller that individually controls the plurality of airflow generators, wherein at least some of the plurality of airflow generators include an air volume distribution adjustor adjusts planar distribution of a volume of air that passes through the air volume distribution adjustor, and wherein the controller control an amount of the planar distribution of the volume of air adjusted by the air volume distribution adjustor.

A vehicle air handling system includes an air duct housing, a particulate sensor, a first air blower and an electronic controller. The air duct housing has an air inlet and a passenger compartment vent. The particulate sensor is configured to detect a particulate level of particulates in the air duct housing. The first air blower is disposed in the air duct housing to move air within the air duct housing. The electronic controller is operatively coupled to the particulate sensor and the first air blower. The electronic controller is configured to operate the first air blower to reverse an air direction of the first air blower away from the passenger compartment vent upon detection of the particulate level of the particulates in the air duct housing being equal to or greater than a predetermined particulate threshold level in the air duct housing.

A humidity detector a humidity sensor detecting a relative humidity of an air inside a sensor case housing the humidity sensor. The humidity detector has an air volume obtaining section, a flow direction obtaining section, a setting section, and a correction section. The air volume obtaining section obtains air volume information correlated with an air volume of the air flowing around the humidity sensor. The flow direction obtaining section obtains flow direction information correlated with a flow direction of the air flowing around the humidity sensor. The setting section sets correction factors configuring a dynamic compensator based on the air volume information and the flow direction information. The dynamic compensator compensates for a response delay of the humidity sensor. The correction section corrects a detection value, which is detected by the humidity sensor, by using the dynamic compensator to obtain the relative humidity of the air.

An air conditioning system for motor vehicles is designed to independently cool or heat a plurality of vehicle room regions and to independently adjust discharged air volume levels in the respective vehicle room regions. The air conditioning system includes a control unit configured to, when one of the discharged air volume levels in the respective vehicle room regions is set to a maximum air volume level, dependently control the other discharged air volume level to the maximum air volume level while entering into a maximum air volume control mode.

The present disclosure relates to an air ventilator for an automobile, comprising: a housing (100) comprising a flow path (110) through which air is blown; a wind direction control unit (200) comprising a louver (210) to adjust a wind direction of the air; a function carrier (300) installed in the wind direction control unit (200); a shaft (400) comprising a coupling portion (410) formed on first side portion of the shaft (400), wherein the function carrier (300) is mounted on the coupling portion (410) such that the function carrier (300) is rotatable, and an output bevel gear (420) formed on a second side portion of the shaft (400); and a pair of dampers (500) coupled to a hinge (600) so as to be foldable, wherein each of the pair of dampers (500) comprises an input bevel gear (510) to be engaged with the output bevel gear (420).

Disclosed are climate systems and methods for control the climate systems. A climate system includes a plurality of compressors, a first heat exchanger disposed downstream of the compressors and a second heat exchanger disposed downstream of the first heat exchanger. The compressors and heat exchangers are fluidly connected by refrigerant lines to form a refrigerant circuit. The climate system also includes a controller that controls the operation of the compressors to draw back lubricant to the compressors without use of an oil equalization system.

A vehicle cabin airflow forming device includes an airflow forming unit. The airflow forming unit is configured to form airflows circulating around seating space of a seat and form, as part of the airflows, an ascending airflow on one lateral side of the seating space, and a descending airflow on the other lateral side of the seating space. The seat is provided inside a vehicle cabin, and the airflows circulate around the seating space as viewed from a front side of the seat.

The present disclosure provides a power transmission device in which stress is reduced and a vehicle air-conditioning device. An air-conditioning device has an inside/outside air door. A power transmission device drives the inside/outside air door. The power transmission device has a motor, a gear train, and a cam mechanism. A first gear of the gear train provides a rotatable member. A plurality of lock mechanisms is provided, which stops a rotation of the first gear at one end and/or the other end in a rotation direction of the first gear. The plurality of lock mechanisms provide a plurality of contacts between the first gear and a stationary link cover.

An HVAC system for use with an operator cab of a work vehicle is characterized by an air duct arrangement in communication with a first fan outlet and second fan outlet. At least one air flow diverter is positioned within the air duct arrangement for selectively diverting air flowing through the air duct arrangement. During a fresh air filter regeneration mode the at least one air flow diverter closes the air duct arrangement, the first fan is activated, and the second fan is deactivated, whereby discharge air from the first fan flows through the second fan in a reverse direction and flows through the fresh air filter.

An apparatus for improving vehicle internal air may include an air conditioner including an intake door for controlling introduction of external air into a vehicle; an electric dust collection filter to collect fine dust contained in air; and a control device to control operation of the electric dust collection filter and the intake door, based on information about a concentration of fine dust inside the vehicle, a concentration of fine dust outside the vehicle, and a vehicle speed.