초록 ▼

The present invention provides a system and method for distributing inflation gases within an airbag cushion. Such a cushion may have one or more protection zones configured to inflate to protect vehicle occupants. An inflation channel maybe enclosed by one or more of the protection zones, and may b

The present invention provides a system and method for distributing inflation gases within an airbag cushion. Such a cushion may have one or more protection zones configured to inflate to protect vehicle occupants. An inflation channel maybe enclosed by one or more of the protection zones, and may be attached to a mounting surface within a protection zone. The inflation channel may be connected to an inflator, and may have a plurality of holes along its length, sized or spaced apart in a manner selected to provide a comparatively even flow rate of inflation gas to all parts of the cushion during inflation. Additionally, the inflation channel may have a gas outlet extension along which the holes are disposed; the gas outlet extension may have a tapered shape configured to collapse under external pressure to prevent backflow of inflation gases into the inflation channel. The inflation channel may be easily manufactured in a number of ways, including extrusion of a polymeric workpiece with a slit along its length. The slit may be intermittently closed to form the gas outlet extension with the holes, without the need for punching or drilling.

대표청구항 ▼

1. A cushion for an inflatable curtain module for protecting an occupant of a vehicle from lateral impact, the cushion comprising:a first membrane having an interior portion and an outer edge, the interior portion having a mounting surface extending longitudinally along the interior portion;a second

1. A cushion for an inflatable curtain module for protecting an occupant of a vehicle from lateral impact, the cushion comprising:a first membrane having an interior portion and an outer edge, the interior portion having a mounting surface extending longitudinally along the interior portion;a second membrane having an interior portion and an outer edge, the outer edges of the first and second membranes being attachable to form at least one inflatable protection zone between the interior portions of the first and second membranes; andan inflation channel configured to receive pressurized gas from a source of pressurized gas, the inflation channel having a plurality of holes formed therein to permit pressurized gas to escape from the inflation channel into the protection zone, wherein the inflation channel is configured to be attached to the mounting surface such that the protection zone encloses at least a portion of a length of the inflation channel in a longitudinal direction, the inflation channel comprising a conduit configured to direct a flow of pressurized gas along a length of the conduit, a gas outlet extension affixed to the conduit and extending along at least a portion of the length of the conduit, the gas outlet extension having a plurality of holes, wherein the gas outlet extension is configured to receive pressurized gas from the conduit and to disperse the pressurized gas within the cushion via the holes, and wherein the gas outlet extension has a tapered shape selected to substantially prevent pressurized gas from re-entering the conduit through the holes. 2. The cushion of claim 1, wherein the first and second membranes are attached together via a first attachment mechanism, and wherein the first membrane and the inflation channel are attached together via a second attachment mechanism. 3. The cushion of claim 2, wherein the first attachment mechanism is mechanical fastening, sewing, weaving, chemical bonding, adhesive bonding, thermal welding, sonic welding, or electromagnetic welding, and wherein the second attachment mechanism is a type different from the first attachment mechanism. 4. The cushion of claim 2, wherein the inflation channel is constructed substantially of a urethane-based material, and wherein the first membrane comprises a urethane-based coating on the mounting surface of the first membrane, and wherein the second attachment mechanism comprises RF welding the inflation channel to the mounting surface. 5. The cushion of claim 2, wherein the inflation channel is constructed substantially of a fabric, the inflation channel further comprising a urethane-coated portion, and wherein the first membrane comprises a urethane-based coating on the mounting surface of the first membrane, and wherein the second attachment mechanism comprises RF welding the urethane-coated portion of the inflation channel to the mounting surface. 6. The cushion of claim 2, wherein the second attachment mechanism comprises sewing. 7. The cushion of claim 1, wherein the holes comprise a plurality of sizes selected to provide a substantially uniform mass flow rate of pressurized gas flowing into the protection zone along the length of the protection zone when the source of pressurized gas is activated. 8. The cushion of claim 1, wherein the holes are spaced apart by a plurality of displacements selected to provide a substantially uniform mass flow rate of pressurized gas flowing into the protection zone along the length of the protection zone when the source of pressurized gas is activated. 9. A cushion as in claim 1 wherein the gas outlet extension forms a substantially pointed interior in communication with the holes. 10. The cushion of claim 1, wherein the inflation channel comprises two attachment surfaces along the length of the inflation channel, the attachment surfaces being attached together via a third attachment mechanism applied exclusive of the holes. 11. A cushion as in claim 1 wherein the gas outlet extension is collapsible. 12. A method of manufacturing a cushion for an inflatable curtain module for protecting an occupant of a vehicle from lateral impact, the method comprising:providing a first membrane having an interior portion and an outer edge, the interior portion having a mounting surface extending longitudinally along the interior portion;providing a second membrane having an interior portion and an outer edge;providing an inflation channel configured to receive pressurized gas from a source of pressurized gas, the inflation channel having a plurality of holes along a length of the inflation channel in a longitudinal direction to permit escape of the pressurized gas;attaching the inflation channel to the mounting surface; andattaching the outer edge of the first membrane to the outer edge of the second membrane to form at least one inflatable protection zone between the interior portions of the first and second membranes, the protection zone enclosing at least a portion of the length of the inflation channel, wherein the cushion is further constructed such that the inflatable channel is not attached to the second membrane. 13. The method of claim 12, wherein attaching the outer edge of the first membrane to the outer edge of the second membrane comprises applying a first attachment mechanism to the outer edges, and wherein attaching the inflation channel to the mounting surface comprises applying a second attachment mechanism to the mounting surface and the inflation channel. 14. The method of claim 13, wherein the first attachment mechanism is selected from the group consisting of mechanical fastening, sewing, weaving, chemical bonding, adhesive bonding, thermal welding, sonic welding, and electromagnetic welding, and wherein the second attachment mechanism is a type different from the first attachment mechanism. 15. The method of claim 12, wherein the inflation channel is constructed substantially of a urethane-based material, the first membrane comprising a urethane-based coating on the mounting surface, and wherein attaching the inflation channel to the mounting surface comprises RF welding the inflation channel to the mounting surface. 16. The method of claim 12, wherein the inflation channel is constructed substantially of a fabric, the fabric having a urethane-coated portion, the first membrane comprising a urethane-based coating on the mounting surface, and wherein attaching the inflation channel to the mounting surface comprises RF welding the urethane-coated portion of the inflation channel to the mounting surface. 17. The method of claim 12, wherein attaching the inflation channel to the mounting portion comprises sewing the inflation channel to the mounting portion. 18. A method of manufacturing a cushion for an inflatable curtain module for protecting an occupant of a vehicle from lateral impact, the method comprising:providing a first membrane having an interior portion and an outer edge, the interior portion having a mounting surface extending longitudinally along the interior portion;providing a second membrane having an interior portion and an outer edge;providing an inflation channel configured to receive pressurized gas from a source of pressurized gas, the inflation channel having a plurality of holes along a length of the inflation channel in a longitudinal direction to permit escape of the pressurized gas;attaching the inflation channel to the mounting surface; andattaching the outer edge of the first membrane to the outer edge of the second membrane to form at least one inflatable protection zone between the interior portions of the first and second membranes, the protection zone enclosing at least a portion of the length of the inflation channel, wherein the inflation channel comprises a conduit configured to direct a flow of pressurized gas along a length of the conduit, a gas outlet extension affixed to the conduit and extending along at least a portion of the length of the conduit, the gas outlet extension having a plurality of holes, wherein the gas outlet extension is configured to receive pressurized gas from the conduit and to disperse the pressurized gas within the cushion via the holes, and wherein the gas outlet extension has a tapered shape selected to substantially prevent pressurized gas from re-entering the conduit through the holes. 19. The method of claim 18, wherein attaching the outer edge of the first membrane to the outer edge of the second membrane comprises applying a first attachment mechanism to the outer edges, and wherein attaching the inflation channel to the mounting surface comprises applying a second attachment mechanism to the mounting surface and the inflation channel. 20. The method of claim 19, wherein the first attachment mechanism is mechanical fastening, sewing, weaving, chemical bonding, adhesive bonding, thermal welding, sonic welding, or electromagnetic welding, and wherein the second attachment mechanism is a type different from the first attachment mechanism. 21. The method of claim 18, wherein the inflation channel is constructed substantially of a urethane-based material, the first membrane comprising a urethane-based coating on the mounting surface, and wherein attaching the inflation channel to the mounting surface comprises RF welding the inflation channel to the mounting surface. 22. The method of claim 18, wherein the inflation channel is constructed substantially of a fabric, the fabric having a urethane-coated portion, the first membrane comprising a urethane-based coating on the mounting surface, and wherein attaching the inflation channel to the mounting surface comprises RF welding the urethane-coated portion of the inflation channel to the mounting surface. 23. The method of claim 18, wherein attaching the inflation channel to the mounting portion comprises sewing the inflation channel to the mounting portion. 24. A cushion for an inflatable curtain module for protecting an occupant of a vehicle from lateral impact, the cushion comprising:a first membrane having an interior portion and an outer edge, the interior portion having a mounting surface extending longitudinally along the interior portion;a second membrane having an interior portion and an outer edge, the outer edges of the first and second membranes being attachable to form at least one inflatable protection zone between the interior portions of the first and second membranes; andan inflation channel to receive pressurized gas from a source of pressurized gas, the inflation channel having a plurality of holes formed therein to permit pressurized gas to escape from the inflation channel into the protection zone, wherein the inflation channel is attached to the mounting surface such that the protection zone encloses at least a portion of a length of the inflation channel in a longitudinal direction, the cushion being further configured such that the inflation channel is not attached to the second membrane. 25. The cushion of claim 24, wherein the first and second membranes are attached together via a first attachment mechanism, and wherein the first membrane and the inflation channel are attached together via a second attachment mechanism. 26. The cushion of claim 25, wherein the first attachment mechanism is mechanical fastening, sewing, weaving, chemical bonding, adhesive bonding, thermal welding, sonic welding, or electromagnetic welding, and wherein the second attachment mechanism is a type different from the first attachment mechanism. 27. The cushion of claim 25, wherein the inflation channel is constructed substantially of a urethane-based material, and wherein the first membrane comprises a urethane-based coating on the mounting surface of the first membrane, and wherein the second attachment mechanism comprises RF welding the inflation channel to the mounting surface. 28. The cushion of claim 25, wherein the inflation channel is constructed substantially of a fabric, the inflation channel further comp rising a urethane-coated portion, and wherein the first membrane comprises a urethane-based coating on the mounting surface of the first membrane, and wherein the second attachment mechanism comprises RF welding the urethane-coated portion of the inflation channel to the mounting surface. 29. The cushion of claim 25, wherein the second attachment mechanism comprises sewing. 30. The cushion of claim 24, wherein the holes comprise a plurality of sizes selected to provide a substantially uniform mass flow rate of pressurized gas flowing into the protection zone along the length of the protection zone when the source of pressurized gas is activated. 31. The cushion of claim 24, wherein the holes are spaced apart by a plurality of displacements selected to provide a substantially uniform mass flow rate of pressurized gas flowing into the protection zone along the length of the protection zone when the source of pressurized gas is activated. 32. The cushion of claim 24, wherein the inflation channel comprises:a conduit configured to direct a flow of pressurized gas along a length of the conduit;a gas outlet extension affixed to the conduit and extending along at least a portion of the length of the conduit, the gas outlet extension having a plurality of holes, wherein the gas outlet extension is configured to receive pressurized gas from the conduit and to disperse the pressurized gas within the cushion via the holes; andwherein the gas outlet has a tapered shape selected to substantially prevent pressurized gas from re-entering the conduit through the holes. 33. The cushion of claim 24, wherein the inflation channel comprises two attachment surfaces along the length of the inflation channel, the attachment surfaces being attached together via a third attachment mechanism applied exclusive of the holes. 34. A cushion for an inflatable curtain module for protecting an occupant of a vehicle from lateral impact, the cushion comprising:a first membrane having an interior portion and an outer edge, the interior portion having a mounting surface extending longitudinally along the interior portion;a second membrane having an interior portion and an outer edge, the outer edges of the first and second membranes being attachable to form two or more inflatable protection zones between the interior portions of the first and second membranes; andan inflation channel to receive pressurized gas from a source of pressurized gas, the inflation channel having a plurality of holes formed therein to permit pressurized gas to escape from the inflation channel into the protection zone, wherein the inflation channel is attached to the mounting surface such that at least one of the protection zones encloses at least a portion of a length of the inflation channel in a longitudinal direction, the cushion further comprising a connection zone to permit communication of inflation gases between the protection zones, the cushion being further configured such that the inflation channel is not attached to the second membrane. 35. A cushion as in claim 34 wherein the connection zone is configured to attach the protection zones. 36. A cushion as in claim 34 wherein the connection zone is not configured to provide impact protection. 37. A cushion as in claim 34 wherein the connection zone includes a transfer port. 38. A cushion as in claim 37 wherein the connection zone permits communication of inflation gases between the protection zones through the transfer port. 39. A cushion as in claim 37 wherein the transfer port is in communication with one or more connection chambers. 40. A cushion as in claim 34 wherein the connection zone includes flexible portions. 41. A cushion as in claim 40 wherein the connection chambers are connected together and connected to the protection zones through the flexible portions.