An air flap structure for a motor vehicle air-conditioning module includes at least two air outlet openings, a shaft, and a drive. The at least two air outlet openings each have an assigned closure flap configured to close and open the assigned air outlet opening. The shaft has therein the closure flaps arranged and is configured to rotate therewith. The closure flaps are rotatable into a closed and an opened position by a rotational movement of the shaft. The drive is configured to drive the shaft and configured to generate the rotational movement thereof. With respect to imaginary planes at both ends of the shaft, perpendicular to the shaft, the drive is arranged outside the axially outwardly facing sides of said two imaginary planes. A driving force of the drive is introduced onto the shaft exclusively between two adjacent air outlet openings of the at least two air outlet openings.

The present invention relates to an air conditioner for a vehicle, which can remarkably improve resistance against an air flow in an air passageway, thereby enhancing efficiency. The air conditioner for a vehicle includes: a case having an air inlet, an air outlet, and an air passageway formed therein; a blower unit for blowing air to the air inlet; and a cooling means and a heating means disposed in the air passageway of the case in an air flow direction in order, wherein the air outlet of the case includes a floor outlet and vent outlets, the floor outlet and the vent outlets are arranged below the heating means in a height direction, and the floor outlet is arranged within a range of the width of the heating means.

A bearing location for rotatably supporting a shaft on a carrier structure about a rotation axis may include a bearing opening disposed in the carrier structure. The bearing opening may include an cylindrical inner bearing face on an inner periphery arranged coaxially with the rotation axis. The inner bearing face may interact with a cylindrical outer bearing face disposed on an outer periphery of the shaft. An annular seal may be arranged coaxially with the rotation axis and may include a labyrinth seal have at least one annular rib and at least one annular groove. An inner sealing gap and an outer sealing gap may be disposed radially between walls of the rib and walls of the groove. The inner sealing gap and the outer sealing gap may each extend annularly and may be arranged coaxially with the rotation axis.

A vehicle air-conditioning device may achieve comfortable heating of a vehicle interior by starting a compressor, an indoor blower and heat generating means at appropriate timing. The vehicle air-conditioning device includes a compressor which compresses a refrigerant, a radiator disposed in an air flow passage to let the refrigerant radiate heat, a heat absorber which lets the refrigerant absorb heat, and an indoor blower which blows the air through the air flow passage. The vehicle interior is heated by heat radiated from the radiator. The vehicle air-conditioning device includes a heating medium-air heat exchanger of a heating medium circulating circuit disposed in the air flow passage to heat air supplied to the vehicle interior. On a basis of an outdoor air temperature, the timing to start the compressor, the indoor blower and the heating medium circulating circuit is controlled.

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.

An air flap for an air conditioning system of a motor vehicle may include a bearing section defining a pivot axis for mounting the air flap on a housing and at least one flap wing integrally formed on the bearing section. The at least one flap wing may extend from the pivot axis at least one of radially towards an outside and in a circumferential direction relative to the pivot axis at least in regions. At least one of the at least one flap wing and the bearing section may include an outer skin and at least one inner region delimited from the outer skin towards a respective inside. At least one of the at least one flap wing and the bearing section may be composed of a plastic. The plastic may be exclusively a foamed plastic in the at least one inner region.

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.

An air conditioning device includes a casing that provides multiple air passages, a blower fan that suctions an air from the multiple air passages and blows out the air in the casing, a suction side partitioning member that is disposed on a suction side of the blower fan in the casing and separates air flows from the multiple air passages from each other, and a blowing side partitioning member that is disposed on a blowing side of the blower fan in the casing and separates the air flows from the multiple air passages from each other. The suction side partitioning member and the blowing side partitioning member are disposed so that a relative position of the blowing side partitioning member to the suction side partitioning member is deviated in a rotation direction of the blower fan.

A vehicle air-conditioning device may achieve comfortable heating of a vehicle interior by starting a compressor, an indoor blower and heat generating means at appropriate timing. The vehicle air-conditioning device includes a compressor which compresses a refrigerant, a radiator disposed in an air flow passage to let the refrigerant radiate heat, a heat absorber which lets the refrigerant absorb heat, and an indoor blower which blows the air through the air flow passage. The vehicle interior is heated by heat radiated from the radiator. The vehicle air-conditioning device includes a heating medium-air heat exchanger of a heating medium circulating circuit disposed in the air flow passage to heat air supplied to the vehicle interior. On a basis of an outdoor air temperature, the timing to start the compressor, the indoor blower and the heating medium circulating circuit is controlled.

A defrost airflow assembly for a heating, ventilation, and air-conditioning (HVAC) case, having a defrost channel starting in a mixing chamber and terminating in a defrost outlet with a defrost door, a demist channel starting in the mixing chamber and terminating in a demist outlet with a demist door, and a bypass channel connected directly with the pre-door defrost channel, the post-door defrost channel, the pre-door demist channel and post-door demist channel. The first bypass channel is configured to allow airflow from the mixing chamber to the defrost outlet when the defrost door is in the closed position and the demist door is in the open position.