The present invention discloses a seatbelt strap sensor for automobiles. The seatbelt strap sensor could detachably fasten to a strap of a seatbelt of the automobile. The strap sensor comprises a plurality of LEDs disposed within a housing, and a pressure sensor and a bracket are disposed on the rear surface of the housing. The pressure sensor is positioned against the body of a child and configured to measure the tightness of the strap of a seatbelt. The bracket has capable to tightly hold the strap sensor to the strap of the seatbelt. The LEDs are configured to illuminate different colors for indicating the tightness of the strap based on the output of the pressure sensor. The housing having indications with letters or words and symbols corresponding to the LEDs. It helps users to determine the tightness of the strap and could be adjusted optimally.

Disclosed are a rear occupant protection apparatus and a control method thereof for controlling a seat belt, or an airbag, based on the state of a rear occupant and a vehicle driving environment to safely protect the rear occupant. The rear occupant protection apparatus includes a first monitoring unit configured to monitor a state of a rear occupant, a second monitoring unit configured to monitor a surrounding situation of a subject vehicle, and a controller configured to control the first and second monitoring units, wherein the controller controls the first and second monitors units to monitor the state of the rear occupant and the surrounding situation of the subject vehicle when the rear occupant wears a seat belt, and controls the seat belt seat belt worn by the rear occupant based on at least one of the state of the rear occupant or the surrounding situation of the subject vehicle.

Disclosed are a rear occupant protection apparatus and a control method thereof for controlling a seat belt, or an airbag, based on the state of a rear occupant and a vehicle driving environment to safely protect the rear occupant. The rear occupant protection apparatus includes a first monitoring unit configured to monitor a state of a rear occupant, a second monitoring unit configured to monitor a surrounding situation of a subject vehicle, and a controller configured to control the first and second monitoring units, wherein the controller controls the first and second monitors units to monitor the state of the rear occupant and the surrounding situation of the subject vehicle when the rear occupant wears a seat belt, and controls the seat belt seat belt worn by the rear occupant based on at least one of the state of the rear occupant or the surrounding situation of the subject vehicle.

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.

A vehicle with an occupant protection function includes an occupant protection device and an occupant monitoring device. The occupant protection device is provided in the vehicle and configured to perform protection operation of supporting, with a seatbelt, an occupant in the vehicle upon collision of the vehicle. The occupant monitoring device is provided in the vehicle and configured to monitor the occupant in the vehicle. The occupant monitoring device is configured to determine whether the occupant in the vehicle is aware of the collision of the vehicle. The occupant protection device is configured to, in a case where the occupant monitoring device determines that the occupant is unaware of the collision of the vehicle, increase tension of the seatbelt gradually as compared with a case where the occupant monitoring device determines that the occupant is aware of the collision.

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.

A computer that may be programmed to: in response to receiving an indication that a vehicle is approaching a geofence boundary, retract slack in a webbing associated with a seat in the vehicle by actuating a seatbelt retractor; then receive measurement data from one or more sensors associated with the seat; using the data, determine whether an occupant occupies the seat; and when no occupant occupies the seat, then transmit an instruction to stop the vehicle.

The present invention discloses a seatbelt strap sensor for automobiles. The seatbelt strap sensor could detachably fasten to a strap of a seatbelt of the automobile. The strap sensor comprises a plurality of LEDs disposed within a housing, and a pressure sensor and a bracket are disposed on the rear surface of the housing. The pressure sensor is positioned against the body of a child and configured to measure the tightness of the strap of a seatbelt. The bracket has capable to tightly hold the strap sensor to the strap of the seatbelt. The LEDs are configured to illuminate different colors for indicating the tightness of the strap based on the output of the pressure sensor. The housing having indications with letters or words and symbols corresponding to the LEDs. It helps users to determine the tightness of the strap and could be adjusted optimally.

An occupant protection device for a vehicle includes a seat, a three-point seatbelt device, and a belt airbag device. An occupant to board the vehicle is to sit on the seat. The three-point seatbelt device includes a seatbelt extendable across a front of an upper body of the occupant sitting on the seat. The belt airbag device includes a belt airbag that is provided at a shoulder belt section, which is extendable from a shoulder to a waist of the occupant, of the seatbelt, and that is configured to be deployed when a collision occurs. The belt airbag includes a belt-direction deployment section extendable and deployable along the shoulder belt section, and an intersecting-direction deployment section extendable and deployable in a direction intersecting the shoulder belt section. The sections are configured to form a single bag by being coupled to each other below a head of the occupant sitting on the seat.

An occupant protection device for a vehicle includes: a three-point seatbelt device having a seatbelt extendable across a front of an upper body of an occupant sitting on a seat; and a belt airbag device including a belt airbag that is provided at a shoulder belt section, which is extendable from a shoulder to a waist of the occupant, of the seatbelt the belt airbag being configured to be deployed when a collision occurs. The belt airbag includes a belt-direction deployment section extendable and deployable along the shoulder belt section, and an intersecting-direction deployment section extendable and deployable in a direction intersecting the shoulder belt section. The belt-direction deployment section and the intersecting-direction deployment section are configured to form a single bag by being coupled to each other below a head of the occupant sitting on the seat.