A seat back assembly and method of manufacture is provided. The seat back includes a foam cushion layer. A support sub-assembly is formed including a rigid support layer with a plurality of cavities and channels defined on a rear surface for receiving components and a generally smooth front surface. At least one component is retained in one of the cavities and a second component is secured on the front surface of the support layer. A trim material covers the cushion layer and secures the sub-assembly to the seat back.

An air conditioning device for a vehicle seat, the air conditioning device includes: at least one flow generator to generate an air flow; at least one air inlet opening fluidically connected to a flow inlet of the flow generator to draw in air to be temperature-controlled; at least one air outlet opening fluidically connected to a flow outlet of the flow generator to eject the temperature-controlled air; and a temperature-control device configured to control a temperature of the air drawn in through the at least one air inlet opening prior to the air being ejected from the at least one air outlet opening; the at least one air inlet opening and the at least one air outlet opening are arranged next to one another.

A passenger identification apparatus for vehicles is provided to identify a passenger through integration of a sensor that senses change in permittivity and a sensor that senses change in pressure. The apparatus includes a permittivity change sensing unit that is installed in the seat and senses change in capacitance generated by permittivity of the passenger seated on the seat and a pressure change sensing unit that is installed in the seat and senses change in pressure generated by a load of the passenger seated on the seat. A controller adjusts power supplied to the permittivity change sensing unit and the pressure change sensing unit and determines whether the passenger is seated on the seat and the type of passenger using permittivity and pressure change values sensed by the permittivity change sensing unit and the pressure change sensing unit.

A work machine including a prime mover, an electric motor, an electric motor fluid circuit, a transmission fluid circuit, a hydraulic circuit, a cooling circuit, a pump, and a controller. The electric motor may supply a portion of power of the prime mover. The electric motor fluid circuit may be adapted to remove waste heat from the electric motor. The transmission fluid circuit may be adapted to lubricate a moving part of a transmission powered by the prime mover. The hydraulic circuit may be adapted to transmit power from the prime mover to a moving component of the work machine. The cooling circuit may be absorbing waste heat from one or more of the electric motor fluid circuit, the transmission fluid circuit, and the hydraulic circuit. The control may be adapted to control diversion of a portion of waste heat from the cooling circuit to a portion of the cab.

A seat system includes a seat bottom and a seat back at a rear of the seat bottom. A thermally controlled seat belt includes a lap portion and a shoulder portion. The thermally controlled seat belt can include a porous sleeve that is connected to a seat ventilation system or a vehicle ventilation system. The seat belt can alternatively or additionally include a heating fabric or thermoelectric elements.

The disclosure relates to a seat trim structure for a vehicle seat with at least a mounting element having a plurality of integrated retaining elements, a number of detachable support members, and a number of detachable trim elements. The support members may be detachably arranged to the mounting element and the integrated retaining elements may be configured to detachably retain the number of trim elements to the mounting element.

A vehicle microclimate system includes a microclimate device that is configured to be arranged within an interior space that provides a macroclimate environment to an occupant. The microclimate device is configured to provide a microclimate environment to the occupant. The microclimate device is configured to be in close proximity to a region of the occupant having an increased thermoreceptive response compared to other occupant regions exposed to the macroclimate environment. A controller is in communication with the microclimate device. The controller is configured to determine an occupant personal comfort and automatically command the microclimate device in response to the occupant personal comfort to achieve a desired occupant personal comfort.

A vehicle microclimate system includes a microclimate device that is configured to be arranged within an interior space that provides a macroclimate environment to an occupant. The microclimate device is configured to provide a microclimate environment to the occupant. The microclimate device is configured to be in close proximity to a region of the occupant having an increased thermoreceptive response compared to other occupant regions exposed to the macroclimate environment. A controller is in communication with the microclimate device. The controller is configured to determine an occupant personal comfort and automatically command the microclimate device in response to the occupant personal comfort to achieve a desired occupant personal comfort.

The present invention relates to a fabric (30, 31) with at least one support (41, 41′), with at least two electrical function elements (70), and with at least one seam (40). It is provided that at least two of the electrical function elements (70) are in the form of strands and integrated in the seam (40).

A cover material, in particular a seat cover material, having an upper side and a lower side and at least one seam that runs over at least a part of the cover material and that is visible on the upper side. An electrically conductive element that generates an electric field is arranged on the lower side in the region where the seam runs.