A moisture detection and regulation system is disclosed for a vehicle interior component having a section of material with a moisture absorbent material structure. The system includes a sensing device configured to detect a level of moisture in the section of material. The system also includes a moisture removal element configured to dissipate moisture from the section of material. The system additionally includes an electronic controller fixed to the vehicle structure and in operative communication with each of the sensing device and the moisture removal element. The controller is configured to receive a signal from the sensing device indicative of the detected level of moisture in the section of material and activate the moisture removal element when the detected level of moisture is equal to or greater than a predetermined threshold level of moisture. A vehicle having such a moisture detection and regulation system is also disclosed.

A seat air conditioner is applied to a seat disposed in a vehicle interior space and includes a seat back portion which supports an upper body side of a user and a seat cushion portion that supports a lower body side of the user. The seat air conditioner includes multiple air flow ducts provided in at least one of the seat back portion or the seat cushion portion and define an air flow passage for air to be blown out from the seat or air to be drawn into the seat. Some of the multiple air flow ducts are configured to be independent from the other air flow ducts such that air, which is different in temperature from the air flowing through the other air flow ducts, is allowed to flow through the some air flow ducts.

A cushion cover for a ventilation seat includes: a first adhesive layer including an upper surface coupled to a lower surface of a cushion part of the ventilation seat, the lower surface of the cushion provided with an air flow channel; a non-permeable layer made of a non-permeable material and including an upper surface coupled to a lower surface of the first adhesive layer to block the air flow channel of the lower surface of the cushion part from outside; and a protective layer coupled to a lower surface of the non-permeable layer to direct friction between the non-permeable layer and a seat structure.

A vehicle air conditioning apparatus is provided. The vehicle air conditioning apparatus includes: a plurality of seat air conditioning units configured to selectively perform cooling or heating for corresponding seats installed in a cabin, respectively; and a plurality of exhaust ducts for discharging, outside the cabin, part of air used in the plurality of seat air conditioning units. At least part of the plurality of exhaust ducts is merged.

A vehicle air conditioning apparatus is provided which includes: a plurality of seat air conditioning units configured to selectively perform cooling or heating per corresponding seat among a plurality of seats installed in a cabin, respectively; and a plurality of exhaust ducts for discharging, outside the cabin, part of air used in the plurality of seat air conditioning units. An exhaust duct of a given one of the plurality of seat air conditioning units is connected to an air inlet of another seat air conditioning unit.

A blower comprising: (a) a housing including: (i) one or more eyelets, and (ii) an inlet (b) one or more clips, wherein the one or more eyelets, one or more clips, or both assist in connecting the blower to a cushion of a seat, a ventilated trim bag, or both.

An airflow turning device with airflow control channels for an outlet of a heating, ventilation, and air conditioning (HVAC) case that directs airflow to a plurality of different vehicle outlets. The airflow control channels extend from an inner upstream side of the outlet to an outer downstream side of the outlet. Different ones of the plurality of channels have different lengths to generate a varied pressure drop at the outer downstream side in response to airflow blown into the plurality of channels from the inner upstream side.

In a seat air-conditioning device, a refrigeration cycle, a warm air blower, and a cold air blower are housed in a housing disposed between a seat face of a seat and a vehicle interior floor. A condenser is disposed on an upstream side in an air blowing direction and the warm air blower is disposed on a downstream side in an air blowing direction in a warm air flow path extending in a predetermined direction. An evaporator is disposed on a downstream side of the cold air blower in an air blowing direction in the cold air flow path extending in a predetermined direction.

A method for thermally conditioning a space adjacent a seat assembly includes activating a heating element positioned within the seat assembly beneath a seat covering. A fluid module that includes a fluid supply device and a thermoelectric element is activated to direct heated air from the fluid module to a space adjacent the seat assembly through a distribution system formed at least partially in the seat cushion. After a period of time, the heating element is deactivated.

An on-board device includes: an air-conditioning unit configured to perform air conditioning by blowing air-conditioning air into a vehicle cabin from an at outlet port that faces the vehicle cabin, and perform, in accordance with remote control, pre-air conditioning for air-conditioning the vehicle cabin before an occupant gets into a vehicle; a seat moving unit configured to move a vehicular seat in a seat front-rear direction, the vehicular seat being disposed such that a front face of a seat back faces the air outlet port; and a control unit configured to, when the remote control is perforated for performing the pre-air conditioning, control the air-conditioning unit such that the pre-air conditioning is performed, and control the seat moving unit such that the vehicular seat moves to a seat front side.