A seat assembly may include a seat, a first bladder assembly connected to the seat, a second bladder assembly connected to the seat, and/or an electrical control unit (ECU) configured to independently control the first bladder assembly and the second bladder assembly. The ECU may be configured to maintain a level of inflation of the first bladder assembly to provide a hugging effect to a user of the seat while inflating and deflating the second bladder assembly to guide breathing of said user.

The present invention relates to a method for adjusting at least a first movable seat element (2) of a vehicle seat 1, in which a graphic element (10) of the vehicle seat (1) to be adjusted is displayed with at least one graphic element (20) of the first seat element (2) on a display surface (13), in order to adjust the first seat element a first switching element and a second switching element are displayed on the display surface (13), wherein the first switching element comprises a first graphic arrow element (21) and the second switching element comprises a second graphic arrow element (22), which graphic arrow elements distinguish opposite directions for moving the first seat element (2), and on actuating the first switching element (21) a control signal is generated, by means of which the first seat element (2) is moved in a first direction (A) and, at the same time, the graphic element (20) of the first seat element (2) is moved. In addition, the invention relates to a device for carrying out this method.

A vehicle seat includes a seat base having a side bolster cover. A bolster is disposed under the side bolster cover. The bolster has a static bolster carrier and an operable portion that is operable relative to the bolster carrier to define a plurality of bolster positions. A flexible interior facing extends from the bolster carrier to an intermediate portion of the bolster cover, wherein a lower edge of the bolster cover is positioned below the bolster carrier such that the bolster cover conceals the bolster in each of the plurality of bolster positions.

An assist handle assembly for use in an interior of a vehicle is provided. The assist handle assembly includes an assist handle configured to be gripped by a user, a connector configured to secure the assist handle assembly to a structural component in the interior of the vehicle, a proximity sensor assembly coupled to the assist handle for generating a sensed signal indicative of a user gripping the assist handle, and a controller controlling one or more vehicle devices based on the sensed signal.

Proposed are a seat side bolster apparatus and a control method thereof. The seat side bolster apparatus of the disclosure includes a driving unit, which is provided under a foam pad of a seat cushion, is moved upwards and downwards by operation of an actuator, and presses the foam pad upwards when moving upwards, and a covering bracket, which is connected to the driving unit so as to be moved upwards and downwards together with the driving unit and to which an end of a covering enveloping the foam pad of the seat cushion is fixed.

A vehicle seat including: a seat back; a seat pan; and one or more side support elements is disclosed. Each side support element is moveable with respect to the seat back between: a stowed configuration, in which the side support element is stowed flush with, or is stowed within or behind the seat back; and a deployed configuration, in which the side support element extends outwardly from the seat back, generally in the same direction that the seat back faces, so as to offer support to the side of a vehicle user sitting in the vehicle seat. A row of two or more such vehicles seats is also disclosed, in which all of the seats of the row face in the same direction, and adjacent seats within the row are connected to each other.

To provide a technique that enables the reduction of fatigue of a vehicle occupant at low cost and without an increase in the number of parts. Without preparing a sensor in addition to a posture changing mechanism, the position of a lumbar vertebra or thoracic vertebra of each vehicle occupant is estimated by controlling the operation of the posture changing mechanism. The posture changing mechanism includes: a back side support mechanism; a first motor capable of shifting a position of the back side support mechanism with respect to a vertical direction; and a second motor capable of shifting the position of the back side support member with respect to a front-back direction. A position of a lumbar vertebra of the vehicle occupant is estimated by: while changing the vertical position of the back side support mechanism by means of the first motor, changing a forward position of the back side support mechanism at each of the different vertical positions thereof by means of the second motor so as to obtain a turnover number value of the second motor achieving a desired resistance; and comparing the turnover number values of the second motor achieving the desired resistance. A position of the thoracic vertebra is determined by calculation based on the position of the lumbar vertebra. The position of the posture changing mechanism is set based on the results of estimation of the individual positions. Thus, a fatigue reduction effect is provided on the vehicle occupant by utilizing the posture changing mechanism.

A car seat includes an actuator capable of changing an orientation of a rest surface of a seat back laterally by turning and moving at least a side portion frame that is part of the car seat frontward and rearward, and a controller configured to exercise control over the actuator. The controller includes a run-time posture support unit configured to execute a run-time posture support control under which when a car makes a turn, the actuator is regulated to cause the rest surface of the seat back to be oriented in a direction of the turn. The run-time posture support unit is configured to regulate the actuator in accordance with a placement of the seat in the car, when the run-time posture support unit executes the run-time posture support control.

The present disclosure relates to a pneumatic adjusting device for adjusting a side wing of a vehicle seat from a default position to an actuation position, the adjusting device comprising: a two-armed lever having an outer lever arm for adjusting the side wing and an inner lever arm, an inflatable balloon device, e.g. balloon, for adjusting the inner for adjusting the arm, and mechanical spring means for adjusting the inner for adjusting the arm. Hereby, it is provided that, in the default position of the adjusting device, the balloon device is inflated, in the default position, the spring means is tensioned and biases the inner lever arm into the actuation position, and in the actuation position, the spring means compresses the balloon.

A motor vehicle seat having a backrest and a seat part and an adjustable sidewall arranged on the backrest and/or the seat part, which sidewall comprises an adjustment mechanism having a stationary portion and a lever portion pivotable about a pivot axis, and having at least one fluid-fillable bladder arranged between the stationary portion and the lever portion for adjusting the relative angular position thereof, wherein the lever portion comprises two wing portions which are arranged on either side of the pivot axis, and the bladder is arranged between a first wing portion and the stationary portion, wherein a preload torsion spring engages by a first spring portion on the stationary portion, and engages by a second spring portion on the second wing portion, of the lever portion, such that it exerts a preload force which pushes the first spring portion in the direction of the stationary portion.