A thermoelectric device comprising an elongated panel of two foam layers, and having an inserted thermoelectric string is incorporated into a seat cushion, planting pot, and battery thermal manager. Several enhancements to the string and the panel improve its durability, visual appeal, and tactile appeal over the prior art.

A motor assembly for a vehicle seat assembly is provided with an electric motor having a motor shaft for rotation in a first direction and a second direction opposite to the first direction, a first fluid transfer device driven by the motor shaft to provide fluid flow therefrom, a one-way clutch assembly driven by the motor shaft, and a second fluid transfer device driven by the motor shaft via the clutch assembly to provide fluid flow therefrom when the clutch assembly is engaged. The second fluid transfer device is decoupled from the motor shaft when the clutch assembly is disengaged. A seat assembly having the motor assembly, and a method of controlling the seat assembly are also provided.

A central electronic control unit (ECU, Ref. 14) is provided for controlling at least one bi-directional direct current (DC) motor (106) attached to a first vehicle seat and at least one electronic device attached to a second vehicle seat. The central ECU includes a micro-controller configured to receive feedback on a positional status of the bi-directional DC motor from a Hall Effect sensor (130). The micro-controller is configured to receive input instructions for the bi-directional DC motor and the electronic device. The micro-controller creates command instructions based in part on the received feedback and received input instructions. The central ECU selectively provides pulse width modulated (PWM) power to the bi-directional DC motor attached to the first vehicle seat and selectively provides power to the electronic device attached to the second vehicle seat in response to the command instructions from the micro-controller.

A central electronic control unit (ECU, Ref. 14) is provided for controlling at least one bi-directional direct current (DC) motor (106) attached to a first vehicle seat and at least one electronic device attached to a second vehicle seat. The central ECU includes a micro-controller configured to receive feedback on a positional status of the bi-directional DC motor from a Hall Effect sensor (130). The micro-controller is configured to receive input instructions for the bi-directional DC motor and the electronic device. The micro-controller creates command instructions based in part on the received feedback and received input instructions. The central ECU selectively provides pulse width modulated (PWM) power to the bi-directional DC motor attached to the first vehicle seat and selectively provides power to the electronic device attached to the second vehicle seat in response to the command instructions from the micro-controller.

A device for ventilating the occupant of a vehicle seat, comprising an air inlet receiving air from a ventilation member, and comprising a first duct integrated at least in part into the backrest of the seat, a second duct integrated into a headrest mounted on the seat and supplying at least one air outlet integrated into the headrest and expelling air coming from the ventilation member, the second duct and first duct being connected by a leak tight sliding connection.

An air conditioning system for a seat, comprising an arm rest (4a, 4b) of the seat, the arm rest having a top side, an inner wall, an outer wall, a front end, and a back end defining a hollow interior between them, means for providing air conditioned to a desired temperature, from an air source to the hollow interior of the arm rest, and a plurality of nozzles formed through the inner wall, defined between a nozzle inlet on an inner surface of the inner wall facing into the hollow interior and a nozzle outlet on an outer surface of the inner wall facing towards a seating area of a person when sitting in the seat, the nozzles providing a path through which air flows from the hollow interior, into the nozzle inlet and out of the nozzle outlet.

A sensor disposition structure in a seat includes a cushion pad and a board-like member which is disposed under the cushion pad. A concave is formed in an upper surface of the board-like member, and a sensor is disposed in the concave.

The main cushion (3) of an automobile seat (e.g. the seat pan cushion, or a backrest cushion) is provided with a shield (2). The shield surrounds at least part of the lateral sides of the main cushion and is formed of a less compressible (i.e. harder) foam than the main cushion, such that when the seat is upholstered, creases in the upholstery are reduced/prevented and gapping is avoided.

The main cushion (3) of an automobile seat (e.g. the seat pan cushion, or a backrest cushion) is provided with a shield (2). The shield surrounds at least part of the lateral sides of the main cushion and is formed of a less compressible (i.e. harder) foam than the main cushion, such that when the seat is upholstered, creases in the upholstery are reduced/prevented and gapping is avoided.

A vehicle comprising a plurality of seats, a plurality of Bluetooth modules to which Bluetooth identification information, different from each other, is assigned, configured to perform pairing with a plurality of user terminals, wherein each of the plurality of Bluetooth modules corresponds to each of the plurality of seats, a memory configured to store terminal identification information assigned to each of the plurality of user terminals and the Bluetooth identification information assigned to each of the plurality of Bluetooth modules, and a processor configured to be connected to the plurality of Bluetooth modules and the memory.