An on-board device includes: an air-conditioning unit configured to perform air conditioning by blowing air-conditioning air into a vehicle cabin from an at outlet port that faces the vehicle cabin, and perform, in accordance with remote control, pre-air conditioning for air-conditioning the vehicle cabin before an occupant gets into a vehicle; a seat moving unit configured to move a vehicular seat in a seat front-rear direction, the vehicular seat being disposed such that a front face of a seat back faces the air outlet port; and a control unit configured to, when the remote control is perforated for performing the pre-air conditioning, control the air-conditioning unit such that the pre-air conditioning is performed, and control the seat moving unit such that the vehicular seat moves to a seat front side.

A device for tilting and swiveling a seat of a vehicle is provided. The device performs a tilting operation for relaxation by cooperation of a seat back and a seat cushion as well as a swiveling operation for rotating the seat in an indoor direction for conversion between passengers or rotating the seat in an outdoor direction for getting on and off vehicle assistance.

Systems, methods, tangible non-transitory computer-readable media, and devices associated with the operation of a vehicle are provided. For example a vehicle computing system can receive occupancy data that includes information associated with occupancy of a vehicle that includes seats. One or more states of the vehicle can be determined. The states of the vehicle can include a disposition of any object that is within the vehicle. Further, a configuration of the seats in the vehicle can be determined based on the occupancy data and the states of the vehicle. The configuration can include a disposition of the seats inside the vehicle. Furthermore, at least one of the seats can be adjusted based on the configuration that was determined.

A vehicle seating assembly is provided that includes a pivot bracket coupled to a vehicle floor and disposed at a front of a seat frame, a gear assembly and a locking disk assembly disposed around an axis of rotation defined by the pivot bracket, wherein the gear assembly and the locking disk assembly are configured to each alternatively move the seating assembly from a sitting position to a standing position, and a track assembly disposed on the vehicle floor and between opposing side brackets of a seat frame. The track assembly includes a cam assembly movable between a locked position and an unlocked position. The vehicle seating assembly further includes a crank assembly extending between the pivot bracket and the cam assembly and configured to move the cam assembly from the locked position to the unlocked position.

Vehicle (100) having a body (1), the body comprising a door (2R) movable between a closed position and an open position. A piece of equipment (3R, 90R) is mounted at an inner side of the door in such a manner that when the door opens, said piece of equipment moves to take up an open position in which at least part of said piece of equipment is outside the body of the vehicle (100). The piece of equipment (3R, 90R) may comprise a seat cushion (36), a plurality of shelves, or a box. The vehicle further comprises a equipment positioning mechanism (60) capable of moving said piece of equipment relative to the door (2R).

A vehicle seat operating device has a reclining lever, a lifting lever and a getting in/out support lever for rotating a vehicle seat in a horizontal plane. A reclining lever operation surface and a lifting lever underside operation surface are accessible from a side of the seat. The getting in/out support lever has a recess section which is formed toward the front, and an operation surface which is a ceiling surface of the recess is accessible from the front. Side access to the operation surface is blocked by an out sidewall located on a seat width direction outer side of the operation surface. The getting in/out support lever is easily distinguished from the other two levers because accessible directions are different.

A revolveable door chair for a vehicle includes a support frame including a base, a side member extending upwardly from the base, and a chair support. The side member is pivotally mounted to a vehicle support. A ground support leg is pivotally connected to the base. A chair is positioned in the support frame. The chair rests in the chair support.

Disclosed is an anti-pinch control system. The anti-pinch control system includes a motor configured to generate driving force for moving a seat of a vehicle, a current measurement sensor configured to measure a current value generated in the motor, a hall sensor configured to measure a revolution per minute (RPM) of the motor, and a controller configured to derive an average of current values measured by the current measurement sensor during an edge generating time during which a specific number of edges are generated by the hall sensor, and to set, to an anti-pinch value, a value obtained by adding a rising value, corresponding to current that increases when a pinch occurs in the seat, to the average, wherein the controller derives the average for each specific RPM and updates the anti-pinch value.

An electric seatback-folding device for emergency escape enables a controller to accurately recognize whether a seatback (or a seatback frame) is in a locked state or an unlocked state using a microswitch. Folding of the seatback for emergency escape is smoothly performed without malfunction or a control error by operation of a motor in response to a current control signal of the controller.

A single motor dual-motion actuator and method for a vehicle seat includes a pin actuator rotatable in the first rotatable direction from a pin actuator rest position toward a pin actuator first position and rotatable in a second rotatable direction from the pin actuator rest position toward a pin actuator second position. The actuator further includes a first actuator component and a second actuator component. The first actuator component is co-rotatable with the pin actuator from a first actuator component rest position in the first rotatable direction toward a first actuator component actuating position when the pin actuator is rotated to the pin actuator first position. The second actuator component is co-rotatable with the pin actuator from a second actuator component rest position in the second rotatable direction toward a second actuator component actuating position when the pin actuator is rotated to the pin actuator second position.