A heat-resistance increasing fabric sheet for an airbag is used in an airbag that is deployed and inflated by inflation gas discharged from a gas outlet portion of an inflator. The heat-resistance increasing fabric sheet is configured to increase the heat resistance of a member subjected to an increase in heat resistance. The heat-resistance increasing fabric sheet includes a base fabric sheet, a heat-resistant layer, and a top coat layer. The base fabric sheet is made of cotton fibers and arranged between the member subjected to an increase in heat resistance and the gas outlet portion. The heat-resistant layer is made of aluminum foil laminated on a surface of the base fabric sheet that faces the gas outlet portion. The top coat layer is made of a plastic film laminated on a surface of the heat-resistant layer that faces the gas outlet portion.

Coupling spots are properly protected upon reception of gas pressure. A seam is possessed as a partition that partitions the interior of an airbag, and the seam is a coupling spot along which a frontal-side base fabric and a backside base fabric are coupled to each other. First and second reinforcing fabrics are provided on inner sides of the frontal-side base fabric and the backside base fabric, and the first and second reinforcing fabrics have remaining margins that are oriented toward the gas supply side in the downward direction rather than toward the seam, and each of the remaining margins functions as a shield wall against a flow of gas toward the seam.

An airbag module for protecting an occupant of a vehicle. The module includes an airbag and an inflator for providing inflation gas for the airbag. A diffuser is positioned in the airbag and configured to direct the flow of inflation gas into the airbag. The diffuser includes a main panel and a deflector panel connected together. The diffuser is configured to provide for first and second flow paths for inflation gas to exit diffuser and flow into the cushion. The main panel is folded along a fold line to create two folded portions and the deflector panel is located within the connected folded portions. The deflector panel is located in the first flow path and extends beyond the folded portions of the main panel. The extending portion of the deflector panel forces the inflation gas to change direction.

Disclosed is an inflation gas deflector for an automotive airbag assembly. The inflation gas deflector includes at least one layer of inorganic platelets or a multiple layer composite of at least one support layer and at least one inorganic platelet layer carried by the support layer. Also disclosed is an airbag cushion incorporating the inflation gas deflector and an automotive airbag assembly including the inflatable airbag cushion, the inflation gas deflector, and an inflator.

An airbag cushion having a main airbag cushion panel that includes a pair of major body fabric portions continuously formed together with a pair of inner valve fabric portions extending therebetween. The pair of inner valve fabric portions are foldable to form an inner valve for at least in part containing an inflation gas supplying inflator device. The pair of major body fabric portions are joinable together at a peripheral joint portion to at least in part form an airbag cushion body. The airbag cushion body has or forms an interior to receive inflation gas and is deployable on a side of an occupant seated in a vehicle seat. Also provided are corresponding or associated methods of or for manufacturing a side airbag cushion.

An airbag of an airbag device includes a connection port to be joined with an inflator and a flexible reinforcing sheet disposed inside the connection port. The reinforcing sheet includes a first cover region and a second cover region each of which wraps the leading end of the inflator and has an opening for providing gas communication with a main body of the airbag. The first cover region has a double-folded configuration that is doubled on a crease which crosses an axial direction of the inflator while the second cover region has a double-folded configuration that is doubled on a crease extending in parallel to the axial direction of the inflator. The first cover region and second cover region are arranged in such an overlapped fashion that the crease of the first cover region continues to the crease of the second cover region.

A side airbag device including an airbag (2); an inflator (3); and an inner tube (4) formed of a fabric and covering discharge holes (3a) of the inflator (3). The inner tube (4) protrudes toward a center of the airbag (2) in a deployed state and a first end (4b) is closed in the direction of gas discharge, and second ends (4c) that are in a vehicle height direction of the airbag (2) in the deployed state are open. The inner tube (4) is folded back at a folded-back portion (4d) inside the airbag (2) when the airbag (2) is folded in a case where the side airbag device is installed in a vehicle seat back.