A seat module adapted to be attached to a seat having mechanical parts and electric devices for seat operation in a motor vehicle includes at least one operating cable for activating at least one device, and a module plate formed with a mounting feature for attaching to the seat and a retention feature for attaching the at least one operating cable. An end portion of the operating cable is temporarily stowed on the module plate in a pre-assembled state where the operating cable is attached to the module plate, and the end portion of the operating cable is connected to the electric devices and/or mechanical parts of the seat in an assembled state where the module plate with the retained operating cables is securely mounted to the seat.

An example seat climate system includes a seat, a first ventilation device, a second ventilation device, and a ventilation device controller. The seat has a first ventilation layer and a second ventilation layer. The first ventilation device is connected to the first ventilation layer and has an off state and an on state. The first ventilation device moves air through the first ventilation layer when in the on state. The second ventilation device is connected to the second ventilation layer and has an off state and an on state. The second ventilation device moves air through the second ventilation layer when in the on state. The ventilation device controller is connected to the first ventilation device and the second ventilation device and includes a controller and driver.

A car seat heater has an improved energy efficiency, which includes a heating wire which is coupled to a car seat and includes a metal-plated carbon fiber, a seat temperature sensor configured to detect temperature of the heating wire, and a variable temperature controller configured to control temperature of the heating wire according to a diameter of the metal-plated carbon fiber and a thickness of a plated metal thereof.

A vehicle seating assembly includes a seat base that has a first heating element. A seat back has a second heating element. A sensor is coupled to the seat base and is configured to obtain a weight data. A user-interface assembly is operably coupled to the first and second heating elements. A controller is in communication with the sensor to receive the weight data. The controller is configured to control the first and second heating elements in response to the weight data.

A ventilated seat, a vehicle including the ventilated seat, and a method of controlling airflow in a vehicle having a ventilated seat are provided. The ventilated seat includes a seat cushion assembly and an air duct configured to interface with a heating, ventilation, and air conditioning (HVAC) module of the vehicle and provide conditioned air from the HVAC module to the seat cushion assembly. The HVAC module of the vehicle further provides conditioned air to an interior cabin of the vehicle through at least one air vent.

A conveyance seat includes a large-capacity pocket formed on the rear surface of a seat back of the seat. The pocket has: a pocket forming sheet overlapping an outer surface of a back side skin material positioned on the rear surface of the seat back; and a pocket sewn portion. The pocket sewn portion has: right and left first sewn portions and right and left second sewn portions formed at positions sandwiching an opening portion in a seat width direction to form the opening portion of the pocket in an upper end portion of the pocket forming sheet; right and left third sewn portions forming right and left outer edge portions of the pocket; and a fourth sewn portion forming a lower edge portion of the pocket. The right and left second sewn portions are disposed inside the right and left third sewn portions in the seat width direction.

A seat support is provided with a plurality of layers of a non-foam material to mount to a seat frame and to support an occupant upon the seat frame. The plurality of layers is stacked upon each other, and each of the plurality of stacked layers has a generally uniform thickness.

There is provided a conveyance seat that suppresses the deterioration of the sensitivity of a load sensor to an input load even when a heater wire and the load sensor are disposed to overlap each other. A conveyance seat includes a seat cushion that supports buttocks of an occupant; a seat back connected to the seat cushion to serve as a backrest for the occupant; a load sensor provided at the seat cushion or at a portion of the seat back; a heater wire disposed on an occupant side with respect to the load sensor; and an intermediate member that positions the heater wire. The intermediate member is disposed between the load sensor and the heater wire.

A wire harness connected to a sensor is positioned on a back surface of a pad of a vehicle seat supported by a panel. The vehicle seat (1) includes a panel (4); a pad (11, 51) supported by the panel; a skin material (12, 52) covering a front surface of the pad; and a sensor (32) provided between the front surface of the pad and the skin material for acquiring information on a seat occupant, wherein the pad is provided with a through hole (35, 58) passed from the front surface of the pad to a back surface of the pad, and a recess (45, 61) formed in the back surface of the pad and connected to the through hole, the wire harness connected to the sensor extending in the through hole and the recess.

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.