A curtain airbag for a vehicle may include a curtain airbag cushion, a first folding portion formed from an indoor side to a window side of the curtain airbag cushion, at a predetermined distance rearward from a front end of the curtain airbag cushion, a second folding portion formed from the indoor side to the window side of the cushion airbag at a predetermined distance rearward from the first folding portion, a panel tether connecting the first folding portion and the second folding portion to each other on the window side of the curtain airbag cushion, the panel tether being shorter than a length of the window side of the curtain airbag cushion between the first folding portion and the second folding portion, and a protruding portion protruding inward between the first folding portion and the second folding portion of the curtain airbag cushion by tension of the panel tether.

Provided is an airbag which further reduces the degree of injury to a vehicle occupant while also exhibiting sufficient occupant protection performance using less output from the inflator, by both preventing airbag internal pressure from rising excessively when making contact with the occupant and increasing the speed of deployment in an occupant-protection area. This hollow-weave airbag has an opening in a main chamber that inflates for the purpose of occupant protection, a structure wherein a first yarn extending separatingly from a first fabric layer of the opening to a non-inflating portion is caught on a float yarn extending on the inside of a second fabric layer and subsequently caught on a float yarn extending on the inside of the first fabric layer, this structure being repeated at least once and forming a pair with another structure wherein a second yarn extending separatingly from the second fabric layer of the opening to the non-inflating portion is caught on the float yarn extending on the inside of the first fabric layer and subsequently caught on the float yarn extending on the inside of the second fabric layer, this structure being repeated at least once.

A vehicle includes a frame. The vehicle is an open-frame vehicle. The frame includes an A-pillar, a B-pillar, and a roof siderail. The roof siderail extends between the A-pillar and the B-pillar. An A-pillar trim member is coupled to the A-pillar and includes a first portion and a second portion. The first portion defines an aperture that receives the second portion. A B-pillar trim member is coupled to the B-pillar. A roof siderail trim member is coupled to the roof siderail and extends between the A-pillar trim member and the B-pillar trim member. An inflatable member is positioned between the frame and at least two of the A-pillar trim member, the B-pillar trim member, and the roof siderail trim member when the inflatable member is in a deflated state. An inflated state of the inflatable member separates the second portion of the A-pillar trim member from the aperture of the A-pillar trim member.

A vehicle includes a frame. The vehicle is an open-frame vehicle. The frame includes an A-pillar, a B-pillar, and a roof siderail. The roof siderail extends between the A-pillar and the B-pillar. An A-pillar trim member is coupled to the A-pillar and includes a first portion and a second portion. The first portion defines an aperture that receives the second portion. A B-pillar trim member is coupled to the B-pillar. A roof siderail trim member is coupled to the roof siderail and extends between the A-pillar trim member and the B-pillar trim member. An inflatable member is positioned between the frame and at least two of the A-pillar trim member, the B-pillar trim member, and the roof siderail trim member when the inflatable member is in a deflated state. An inflated state of the inflatable member separates the second portion of the A-pillar trim member from the aperture of the A-pillar trim member.

A life protection device system is proposed. More particularly, the life protection device system includes: a shock absorbing device provided with a shock absorbing part, a shock absorber, and an airbag that are mounted on a moving object so as to absorb impact to protect the life of passengers in a crash or collision of the moving object; a measuring device detecting the shock applied to the moving object; a controller generating a preset driving control signal according to the detected shock of the measuring device; and an artificial intelligence part notifying of an occurrence of a disaster and asking for help from a designated disaster center in response to the driving control signal of the controller, wherein the impact on the passengers is minimized even when the moving object such as a drone, autonomous aircraft, and autonomous vehicle crashes or collides, or falls into a river or sea.

A configuration of the airbag module according to the present invention is an airbag module including an airbag cushion that is folded or wound, an inflator equipped in the airbag cushion, and a case-shaped housing where the airbag cushion is stowed. Herein, the housing includes four side walls, the upper part thereof being open; one side wall of the four side walls and two side walls positioned and connected on both sides thereof; and two extendable walls and at the opening above the four side walls that are in a folded state prior to expansion and deployment of the airbag cushion and open up when the airbag cushion expands and deploys.

A configuration of the airbag module according to the present invention is an airbag module including an airbag cushion that is folded or wound, an inflator equipped in the airbag cushion, and a case-shaped housing where the airbag cushion is stowed. Herein, the housing includes four side walls, the upper part thereof being open; one side wall of the four side walls and two side walls positioned and connected on both sides thereof; and two extendable walls and at the opening above the four side walls that are in a folded state prior to expansion and deployment of the airbag cushion and open up when the airbag cushion expands and deploys.

An acceleration sensor for a vehicle includes a micro-electro-mechanical (MEMS) high-G sensing element and low-G sensing element provided in a single MEMS housing in one embodiment. In another embodiment, the high-G sensor and the low-G sensor are integrated as a single MEMS low/high-G sensing element and in another embodiment, the high-G and low-G sensing elements are provided in separate MEMS housings disposed in the same acceleration sensor housing. An application specific integrated circuit (ASIC) processes signals from the high-G/low-G sensing element(s). A collision determination system for an autonomous vehicle processes the high-G/low-G signals to actuate airbags and/or to provide collision information to a remote system.

An acceleration sensor for a vehicle includes a micro-electro-mechanical (MEMS) high-G sensing element and low-G sensing element provided in a single MEMS housing in one embodiment. In another embodiment, the high-G sensor and the low-G sensor are integrated as a single MEMS low/high-G sensing element and in another embodiment, the high-G and low-G sensing elements are provided in separate MEMS housings disposed in the same acceleration sensor housing. An application specific integrated circuit (ASIC) processes signals from the high-G/low-G sensing element(s). A collision determination system for an autonomous vehicle processes the high-G/low-G signals to actuate airbags and/or to provide collision information to a remote system.

A proactive, prophylactic vehicle fluid capture system that embodies an inflatable air-diaper disposed under the engine. The inflatable air-diaper is deployed upon an indication of a sufficient crash event, wherein the deployed inflatable air-diaper catches the above-mentioned vehicular fluid prior to contact with the surrounding ground, thereby lessening the negative environmental impact and clean-up time resulting from the crash event. The inflatable air-diaper may deploy with peripheral sidewalls to facilitate the retention of the hazardous fluid on the inflatable air-diaper. The inflatable air-diaper is made of material adapted to absorb these hazardous vehicular fluids.