A passenger seat comprises a backrest, a seat element and a size increasing mechanism which is configured to convert a weight acting on the seat element when a user sits in the passenger seat into an increase in the depth of a seat pan of the seat element that can be used by the user from a rest-position depth to a to an operational-position depth.

The invention relates to a chair (1) which comprises a support (6), a seat element (5), a back element (4), a leg element (3), a spring mechanism and a weight-controlled working adjusting element for the spring mechanism.

A vehicle seat that includes: a seat cushion that is configured to be raised and lowered in a seat vertical direction; a buckle that is attachable to an attachment location that is not subject to the raising or lowering of the seat cushion, and that retains a tongue provided at an elongated belt shaped webbing, in a state in which in the webbing is worn over at least a pelvis area of the occupant; and a lifting device that is actuated, in a case in which a collision of a vehicle has been detected, so as to move the occupant, in a case in which the occupant is sitting on the seat cushion, toward an upper side of the seat at a location further toward a rear side of the seat than a central portion of the seat cushion in a front-rear direction of the seat.

A gas spring device of an office chair has a gas spring for height adjustment by means of a movable component and at least one sensor element, which is configured to detect a load and to generate a sensor signal depending on the detected load. In addition, the gas spring device has an electronic circuit adapted to generate user data depending on the at least one sensor signal. The user data represents one or more facts about the usage of the office chair. The at least one sensor element has at least one position sensor which is configured to detect a position of the movable component and to generate a position signal depending on the detected position.

A seat cushion is provided. The seat cushion includes a first cushion comprising a top side and a bottom side. The bottom side or the top side includes a contoured area and the contoured area has a convex or a concave shape.

A gas spring device of an office chair has a gas spring for height adjustment by means of a movable component and at least one sensor element, which is configured to detect a load and to generate a sensor signal depending on the detected load. In addition, the gas spring device has an electronic circuit adapted to generate user data depending on the sensor signal. The user data represents one or more facts about the usage of the office chair. The at least one sensor element has at least one of the following: A force sensor for detecting a force acting on the gas spring in the direction of a longitudinal axis of the gas spring and generating a force signal therefrom and/or at least one deformation sensor for detecting a deformation of the gas spring device and to generate a deformation signal therefrom.

The present disclosure provides a system for correcting a passenger's posture in an autonomous vehicle, wherein the system includes a camera configured to measure a distance between a headrest and a head of the passenger, a plurality of body pressure sensors configured to be uniformly embedded across an entire area of the seat and sense body pressures of the passenger, a pressurizing device configured to be expandably installed inside a seatback and press between T10 and T12 of a thoracic spine of the passenger, and a controller configured to control an operation of the pressurizing device on the basis of the distance measured by the camera and a scapular pressure of the passenger, which is sensed by the plurality of body pressure sensors.

A seat is provided which enables real-time estimation of a posture of a seated person. One aspect of the present disclosure provides a seat including a seat main body, at least one 3-axis acceleration sensor arranged in the seat main body, and an estimation device that estimates a posture of a seated person on the seat main body. The estimation device includes a storage that stores a learning model built by machine learning of input data based on a sensor output from the at least one 3-axis acceleration sensor and teacher data based on information on the posture of the seated person or a posture transition of the seated person, and an estimator that uses the learning model to estimate the posture of the seated person or the posture transition of the seated person from the sensor output.

A seat cushion is provided. The seat cushion includes a first cushion comprising a top side and a bottom side. The bottom side or the top side includes a contoured area and the contoured area has a convex or a concave shape.

A pressure-sensing chair according to one embodiment of the present invention comprises: a first electrode having a first conductive region formed in a first direction; a second electrode having a second conductive region formed in a second direction; a sensing sheet including an intermediate layer arranged between the first electrode and the second electrode; a first elastic body arranged on the sensing sheet and having a first elastic modulus; and a plurality of second elastic bodies arranged in the first elastic body and having a second elastic modulus, which is greater than the first elastic modulus.