A vehicle seat includes a seat cushion and a seatback. The vehicle seat has a plate-shaped pressure-receiving member configured to receive a load from an occupant seated on the vehicle seat and a radio wave sensor fixed to the pressure-receiving member. The radio wave sensor is configured to acquire information about the occupant by emitting radio waves toward the occupant and detecting the radio waves reflected off the occupant. The pressure-receiving member includes a plurality of first ribs that protrudes from a backside of the pressure-receiving member, which is a side facing away from the occupant, in a direction away from the occupant, and a plurality of second ribs that protrudes from the backside in a direction away from the occupant, the plurality of second ribs crossing the plurality of first ribs. The radio wave sensor includes at least one fixing part that is fixed to the pressure-receiving member. The at least one fixing part includes a first fixing part that is fixed to a surrounded area that is surrounded by the plurality of first ribs and the plurality of second ribs on the backside.

A vehicle seat occupant classification system for use in a vehicle seat includes a weight-responsive sensor, at least one bracket member serving as a holder for the weight-responsive sensor, and an evaluation unit configured to evaluate a status of the at least one weight-responsive sensor. The bracket member is fixedly attached to the seat base. If a mechanical load at least corresponding to a first pre-determined threshold value is applied by a seat occupant, a portion of the vehicle seat comes into mechanical interaction with the at least one weight-responsive sensor, and is configured to change a status of the at least one weight-responsive sensor if a mechanical load at least corresponding to a second pre-determined threshold value is applied. Relative movement between the seat base and the at least one weight-responsive sensor is at least excluded for applied mechanical loads that are smaller than the first pre-determined threshold value.

Right and left brackets coupling a seat back frame and seat cushion frame together are configured to adjust an amount of deformation upon impact absorption. A vehicle seat frame includes a seat cushion frame, seat back frame, coupling bracket configured to couple a cushion side frame as a side frame of the seat cushion frame on one side of the vehicle seat frame and a seat back side frame as a side frame of the seat back frame on the one side, and coupling bracket configured to couple a cushion side frame as a side frame of the seat cushion frame on the other side and a seat back side frame as a side frame of the seat back frame on the other side. Deformability upon impact absorption is different between a weak portion provided at the coupling bracket and a weak portion provided at the coupling bracket.

Provided is a vehicle seat fastening structure that enables a reduced length of a bolt for fastening a movable rail and a cushion frame in a spaced-apart manner. The cushion frame includes a bottom wall extending in a seat-width direction and a seat front-rear direction. The nut includes a body having a cylindrical shape and configured to penetrate the bottom wall, a thread groove, and a flange portion projecting radially from the body. A length of the nut along a central axis thereof is greater than a separation distance between an upper surface of the movable rail and an upper surface of the bottom wall of the cushion frame in a state in which no impact is applied to the cushion frame. The flange portion is provided in an area of the nut at a distance from an insertion opening for the bolt greater than the separation distance.

A vehicle includes a frame, a passenger presence sensor mounted thereto, and a seat assembly removably connected to. The seat assembly includes a driver seat disposed on the frame and a passenger seat disposed on the frame rearward of the 5 driver seat, at least the passenger seat being selectively disposed on the frame. A rigid passenger presence responsive member (PPRM) is retained in the passenger seat and movable with respect to the frame between at least a first position and a second position responsive to a weight of a passenger seated on the passenger seat. The PPRM is coupled to the passenger presence sensor in at least one of the first and 10 second positions, the passenger presence sensor is thereby configured to detect a presence of the passenger. Removable passenger seats for a vehicle are also disclosed.

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.

A seating system for a vehicle is disclosed. The seating system includes a support surface having a surface contour formed by first springs having fixed stiffness values, a frame, and second springs having adjustable stiffness values coupling the support surface and the frame. The first springs and the second springs together control motion of the support surface in relation to motion of the frame.

A vehicle is provided that includes a safety system that can provide an alert, external to the vehicle, that can warn other vehicles, people, etc. that a driver and/or passenger(s) are exiting the vehicle. Methods and systems determine when an occupant of a vehicle is about to exit by sensing the exit movement or an exit sequence, which may be detected by internal vehicle sensors. In response to the exit sequence, the vehicle may control one or more alert features, associated with the vehicle, to provide an external alert to other vehicles and/or users outside of the vehicle that a driver and/or passenger(s) is/are about to exit.

A radio wave transmitting/receiving device is placed in a vehicle in such a way that the device is near the back of the seated person, and no discomfort is caused to the back of the seated person. The vehicle seat includes a seat cushion and a seatback connected to a rear part of the seat cushion. The seatback comprises a seatback frame including a left and a right side frame portion extending vertically, and an upper frame portion extending laterally between upper ends of the side frame portions, a pressure receiving member consisting of a plate member configured to support a back of a seated person and provided with a radio wave transmissive property, and supported by the seatback frame via an elastic member, and a radio wave transmitting/receiving device supported on a back surface of the pressure receiving member to irradiate radio wave to a seated person and receive radio wave reflected by the seated person.

A vehicle seat includes a seat cushion that includes a seat cushion frame, a riser that supports the seat cushion frame, a seat position adjusting device that moves and adjusts the seat cushion back and forth, and a load detector that detects a load applied to the seat cushion. The riser includes a bottom wall and a sidewall that extends upward from an end portion of the bottom wall. The seat position adjusting device includes an upper rail that supports the riser and slides a lower rail. The load detector is positioned between the upper rail and the bottom wall. The upper rail, the load detector, the bottom wall, and the bracket are co-clamped with a first fastening member, and the bracket is secured to the sidewall with a second fastening member.