A seat cushion airbag for a vehicle includes an airbag cushion that is formed with a center part installed in a center of or around a front part of a seat cushion of a vehicle and is located between legs of a passenger when being deployed. An extension part extends on both sides of the center part and is located above the legs of the passenger and an inflator is connected to the airbag cushion and provides an expansion force to the airbag cushion.

A seat arrangement for a vehicle includes a first seat including an airbag module having an inflatable airbag, and a second seat positionable adjacent to the first seat. The second seat includes a pivotable seatback that is pivotable between an upright use position and a forward pivoted position, and a movement mechanism associated with the seatback for moving the seatback from the use position to the pivoted position. The arrangement further includes a control system configured to actuate the movement mechanism to move the seatback of the second seat from the use position to the pivoted position when the second seat is unoccupied and upon detection of a potential vehicle impact, so that the airbag of the airbag module of the first seat may deploy between an occupant of the first seat and the seatback of the second seat.

A vehicle door interior trim assembly includes a trim panel and an armrest supported by the trim panel. The armrest includes an energy absorbing device. The energy absorbing device includes an inboard panel and an outboard panel. The outboard panel is between the inboard panel and the trim panel. The energy absorbing device has a variable crush resistance based on a temperature of the energy absorbing device. A heater is operatively coupled to the energy absorbing device.

A method of controlling an airbag inflator, may include determining, when an occupant is accommodated on a seat, whether the weight of the occupant is in which of first to fourth weight ranges sequentially allocated by a controller, performing a first logic for operating an inflator at the lowest one of three intensities by the controller when it is determined that the weight of the occupant is in the lightest first weight range, and performing a second logic for operating the inflator at the intermediate intensity or a third logic for operating the inflator at the highest intensity by the controller, according to conditions such as a position of a seat, a state of operation of a recliner, a collision condition, a collision pulse, and wearing of a belt, when it is determined that the weight of the occupant is in the third or fourth weight range.

One general aspect includes a system of restraint deployment regulation, the system includes: a memory configured to include a plurality of executable instructions and a processor configured to execute the executable instructions, where the executable instructions enable the processor to: (a) determine, based on a seat occupation sensor output, whether a non-adult occupant is occupying a vehicle seat; (b) determine, based on an in-cabin sensor output, whether a child restraint seat is mounted on the vehicle seat; and (c) based on steps (a) and (b), enable or suppress a deployment of an airbag module that corresponds with the vehicle seat.

A safety device for monitoring a technical installation with a pressure-sensitive sensor. The pressure sensitive sensor having a plurality of first and second electrodes, wherein each first electrode overlaps each second electrode in an associated coupling site. Furthermore, each first electrode is spaced apart from the associated second electrode in the associated coupling site by a pressure sensitive material. Upon application of a force at the coupling site, an electrical resistance between the associated first and second electrode changes. A measuring circuitry coupled to said plurality of first and second electrodes successively determines the electrical resistance at associated coupling sites. For determining the electrical resistance at a coupling site via the associated first and second electrode, the measuring circuitry connects the further first and second electrodes to a terminal for receiving a defined potential to enable isolated measurement of the electrical resistance at the coupling site.

An occupant classification system for a seat assembly (20) includes a plurality of sensors (32), a posture classifier and a weight classification system. The seat assembly includes a seat cushion (22) and a seat back (24). Each of the plurality of sensors (32) measures a force applied to the seat cushion (22) by an occupant of the seat assembly. The posture classifier identifies a posture of the occupant based on the distribution of forces applied to each of the plurality of sensors (32). The weight classification system identifies a weight class of the occupant based on the posture and the magnitude of forces applied to each of the plurality of sensors (32).

An occupancy sensor is provided for detecting the occupancy status of a wheeled mobility device securement system. The occupancy sensor may additionally confirm adequate “tightness” of the wheeled mobility device securement system and/or provide an indication of the magnitude of “tightness.” In one embodiment, the occupancy sensor comprises a spring-loaded follower that breaks the straight-line path of a wheeled mobility device tie down as it travels between two touch points. The follower is displaceable from an extended position to a compressed position in response to the magnitude of tension applied to the tie down. Proximity sensors are used to detect the displacement distance of the follower, thereby providing an indication of occupancy, adequate securement, and/or the magnitude of tension.

The weight sensor vehicle security device comprises a vehicle and a security circuit. The security circuit measures the weight of the operator. The operator enters a security code into the security circuit. The operator then enters a security code. The security circuit compares the measured weight of the operator to a weight of the operator that is associated and stored with the security code. If the measured and stored weights match, the security system enables the operation of the vehicle. After the vehicle travels a previously determined distance, the security circuit repeats the procedure. If the measured and stored weights do not match, the security system disables the operation of the vehicle.

One general aspect includes a system of restraint deployment regulation, the system includes: a memory configured to include a plurality of executable instructions and a processor configured to execute the executable instructions, where the executable instructions enable the processor to: (a) determine, based on a seat occupation sensor output, whether a non-adult occupant is occupying a vehicle seat; (b) determine, based on an in-cabin sensor output, whether a child restraint seat is mounted on the vehicle seat; and (c) based on steps (a) and (b), enable or suppress a deployment of an airbag module that corresponds with the vehicle seat.