A seat device for a vehicle includes: a support member detachably attached to a floor of the vehicle; an occupant seat movably supported by the support member and provided with an electrical component; and a wireless power supply mechanism configured to supply electric power to the electrical component. The wireless power supply mechanism includes a power transmitting unit attached to the floor, and a power receiving unit attached to the support member so as to face the power transmitting unit and configured to receive the electric power wirelessly from the power transmitting unit.

A method for automatically controlling an emotional environment in a vehicle is provided. The method includes generating reflected wave information by radiating an electromagnetic wave toward a rear seat of the vehicle and receiving a reflected wave. A degree of activity is determined based on the reflected wave information and at least one device installed within the vehicle is operated based on the degree of activity.

A vehicle interior assembly, such as a vehicle seat or a steering wheel, includes a cover assembly covering a frame. The cover assembly includes a vinyl or non-woven textile cover and an electrically conductive coating layer (“ECCL”) within an A-surface of the cover. The ECCL may function as a heater, a capacitive touch control, or lighting. Another cover assembly includes first and second ECCLs within an A-surface of a cover. The first ECCL functions as a heater and the second ECL functions as a capacitive touch control. Another cover assembly includes an ECCL and a Positive Temperature Coefficient (PTC) coating layer within an A-surface of a cover. The ECCL functions as a heater dependent on current received from a power source via the PTC coating layer. The PTC coating layer regulates the current received by the ECCL from the power source dependent on a temperature of the PTC coating layer.

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.

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.

A ventilated seat system for a vehicle includes a seating assembly including a seatback operably coupled to a seat base. A blower is coupled to the seating assembly. The blower generates a sound transmission when activated. The blower includes a housing defining an inlet and an outlet. A first metamaterial silencer is coupled to an interior surface of the housing proximate to the inlet, and a second metamaterial silencer is coupled to the interior surface of the housing proximate to the outlet. Each of the first metamaterial silencer and the second metamaterial silencer reduces the sound transmission generated by the blower.

Proposed are a blower for a ventilation seat having a warm-air-blowing function and a vehicular ventilation seat including the same. The blower moves air supplied to the vehicular ventilation seat. The blower includes a housing having an accommodation space formed therein and including an inlet receiving air and an outlet discharging air, a motor mounted in the housing, an impeller mounted in the housing and configured to be driven by the motor to move air, a printed circuit board mounted in the housing, and a heater mounted in the housing so as to be connected to the printed circuit board and configured to heat the air flowing through the housing.

A method of heating a vehicle member, comprising at least one first electrical heating unit and at least one second electrical heating unit, the method comprising: a first step with a step consisting of supplying current to the first electrical heating unit until at least one zone reaches a setpoint temperature, and with a step consisting of determining a first electrical energy supplied to the first electrical heating unit, a second step with a step consisting of supplying the first electrical heating unit in order to keep the priority area of the member at the setpoint temperature and with a step consisting of delivering to the second electrical heating unit a second electrical energy, calculated based on the first electrical energy.

The invention concerns a cushion or cushioning comprising, a cover an outer covering layer, a middle foam layer and an inner mesh layer. The cushion also includes an electric circuit connected to an electric generator, the circuit being made from conductive ink deposited on a support layer. The circuit extends opposite the complex; a block of elastically compressible padding, the support layer being formed either by the inner layer, or by an additional mesh layer interposed between the inner layer and the block.

A microclimate control system for a seated occupant includes a seat having a cushion and a back respectively including a first array of pressure sensors and a second array of pressure sensors. The first array of pressure sensors provides a cushion occupant output. The second array of pressure sensors provides a back occupant output. The cushion and back occupant outputs correspond to load distributions from the seated occupant. At least one thermal effector is configured to provide thermal conditioning to the seated occupant. A controller is in communication with the first and second arrays of pressure sensors and with the at least one thermal effector. The controller includes an occupant personal parameters algorithm configured to extract occupant personal parameters based upon the cushion and back occupant outputs. The occupant personal parameters include at least two of an occupant weight, an occupant height, and an occupant gender. The occupant personal parameter algorithm estimates an occupant clothing insulation value from the occupant personal parameters. The controller is configured to regulate the at least one thermal effector based upon the occupant clothing insulation value.