초록 ▼

An airbag inflator diffusion system having a thin profile. The diffusion system includes an airbag inflator that is inserted into a sleeve. The sleeve has overlapping longitudinal edges positioned so that the sleeve tightly circumscribes the inflator. Engagement tabs are formed in one longitudinal

An airbag inflator diffusion system having a thin profile. The diffusion system includes an airbag inflator that is inserted into a sleeve. The sleeve has overlapping longitudinal edges positioned so that the sleeve tightly circumscribes the inflator. Engagement tabs are formed in one longitudinal edge of the sleeve and fold through perforations formed adjacent the other longitudinal edge. Upon activation of the inflator, the sleeve expands radially forming an exhaust passage through which exhaust gas may travel. The folded engagement tabs and their corresponding perforations limit the radial expansion of the sleeve.

대표청구항 ▼

What is claimed and desired to be secured by United States Letters Patent is: 1. An airbag inflator diffusion system, comprising: an airbag inflator having an exhaust gas exit port; a sleeve having a longitudinal axis and shaped to receive the inflator securely within the sleeve, the sleeve expandi

What is claimed and desired to be secured by United States Letters Patent is: 1. An airbag inflator diffusion system, comprising: an airbag inflator having an exhaust gas exit port; a sleeve having a longitudinal axis and shaped to receive the inflator securely within the sleeve, the sleeve expanding radially under a force of impinging exhaust gas, the sleeve comprising a structural stop to limit the radial expansion of the sleeve; and at least two crimped tabs being added to a proximal end of the sleeve and at least two crimped tabs being added to a distal end of the sleeve, wherein the crimped tabs are folded inward to hold the inflator within the sleeve during deployment, wherein when the crimped tabs are folded inwards, the tabs are substantially perpendicular to the longitudinal axis of the sleeve, and wherein when the sleeve expands radially under the force of the impinging gas, the crimped tabs moves radially outwardly away from each other. 2. The inflator diffusion system of claim 1, wherein the structural stop comprises a tab and a perforation, such that the tab is shaped to engage the perforation upon radial expansion of the sleeve to limit expansion. 3. The inflator diffusion system of claim 1, wherein the structural stop comprises a hook and a perforation, such that the hook engages the perforation upon radial expansion of the sleeve to limit expansion. 4. The inflator diffusion system of claim 1, wherein a first longitudinal edge of the sleeve overlaps a second longitudinal edge along a length of the sleeve. 5. The inflator diffusion system of claim 4, wherein the first longitudinal edge is slidably movable with respect to the second longitudinal edge under the force of impinging exhaust gas. 6. The inflator diffusion system of claim 1, wherein a perforation in the sleeve becomes exposed upon radial expansion of the sleeve. 7. The inflator diffusion system of claim 6, wherein the perforation is positioned to allow exhaust gas to flow out of the sleeve through the perforation and into an inflatable cushion. 8. The inflator diffusion system of claim 6, wherein the perforation overlays a portion of the inflator excluding the exit port. 9. The inflator diffusion system of claim 1, wherein the inflator is an elongate inflator and the sleeve extends a length of the elongate inflator. 10. The inflator diffusion system of claim 1, wherein the structural stop allows the sleeve to expand radially a predetermined amount. 11. The inflator diffusion system of claim 1, wherein the radial expansion of the sleeve forms an exhaust passage between the sleeve and the inflator. 12. The inflator diffusion system of claim 11, wherein the sleeve comprises a solid section positioned to receive direct impingement of the exhaust gas from the exit port and direct the exhaust gas through the exhaust passage. 13. The inflator diffusion system of claim 1, wherein a cross-sectional shape of the sleeve is substantially the same as a cross-sectional shape of the inflator. 14. The inflator diffusion system of claim 1. wherein the sleeve has a mounting stud extending orthogonally therefrom. 15. An airbag inflator diffuser, comprising: a sleeve having a longitudinal axis and having a first longitudinal edge that overlaps a second longitudinal edge along a length of the sleeve, the sleeve expanding radially under a force of impinging exhaust gas from an exit port of an inflator when installed within the sleeve; a structural stop to limit the radial expansion of the sleeve; and at least two crimped tabs being added to a proximal end of the sleeve and at least two crimped tabs being added to a distal end of the sleeve, wherein the crimped tabs are folded inward to hold the inflator within the sleeve during deployment, wherein when the crimped tabs are folded inwards, the tabs are substantially perpendicular to the longitudinal axis of the sleeve, and wherein when the sleeve expands radially under the force of the impinging gas, the crimped tabs move radially outwardly away from each other. 16. The diffuser of claim 15, wherein the structural stop allows the sleeve to expand radially a predetermined amount. 17. The diffuser of claim 16, wherein the structural stop comprises a tab and a perforation in the sleeve, such that the tab is shaped to engage the perforation upon radial expansion of the sleeve to limit expansion. 18. The diffuser of claim 17, wherein the perforation is adjacent the first longitudinal edge and the tab is adjacent the second longitudinal edge. 19. The diffuser of claim 18, wherein the first longitudinal edge is slidably movable with respect to the second longitudinal edge under the force of impinging exhaust gas. 20. The diffuser of claim 19, wherein the perforation becomes exposed upon radial expansion of the sleeve. 21. The diffuser of claim 20, wherein the perforation is positioned to allow exhaust gas to flow out of the sleeve through the perforation and into an inflatable cushion. 22. The diffuser of claim 21, wherein the perforation overlays a portion of the inflator excluding the exit port. 23. The diffuser of claim 22, wherein the radial expansion of the sleeve form an exhaust passage between the sleeve and the inflator. 24. The diffuser of claim 23, wherein the sleeve comprises a solid section positioned to receive direct impingement of the exhaust gas from the exit port and direct the exhaust gas through the exhaust passage. 25. The diffuser of claim 16, wherein the structural stop comprises a hook and a perforation in the sleeve, such that the hook engages the perforation upon radial expansion of the sleeve to limit the expansion. 26. The diffuser of claim 16, wherein the sleeve is shaped to extend a length of an elongate inflator. 27. The diffuser of claim 26, wherein a cross-sectional shape of the sleeve is substantially the same as a cross-sectional shape of the inflator. 28. The diffuser of claim 15, wherein the sleeve has a mounting stud extending orthogonally therefrom. 29. An airbag inflator diffusion system, comprising: an airbag inflator having an exhaust gas exit port; a sleeve having a longitudinal axis and having a first longitudinal edge that overlaps a second longitudinal edge along a length of the sleeve, the sleeve expanding radially to form an exhaust passage under a force of impinging exhaust gas from the exit port of the inflator installed within the sleeve, the sleeve having a perforation adjacent the first longitudinal edge and a tab adjacent the second longitudinal edge, such that the tab is shaped to engage the perforation upon radial expansion of the sleeve to limit expansion; and at least two crimped tabs being added to a proximal end of the sleeve and at least two crimped tabs being added to a distal end of the sleeve, wherein the crimped tabs are folded inward to hold the inflator within the sleeve during deployment, wherein when the crimped tabs are folded inwards, the tabs are substantially perpendicular to the longitudinal axis of the sleeve, and wherein when the sleeve expands radially under the force of the impinging gas, the crimped tabs move radially outwardly away from each other.