JP5675493B2 - Airbag device - Google Patents

Description

  The present invention relates to an airbag device that inflates and deploys an airbag in a vehicle and protects an occupant with the airbag.

  Airbag devices are used to protect passengers in the event of a vehicle emergency or collision. The airbag device inflates and deploys the airbag with the gas generated by the inflator. The occupant is received and protected by the airbag. 2. Description of the Related Art Conventionally, an airbag in which an inflator is disposed in a rectifying cloth and gas is rectified with the rectifying cloth is known (see Patent Document 1).

  In the conventional airbag, the rectifying cloth is inserted into the connection port portion of the airbag and assembled in the inflating portion of the airbag. The rectifying cloth is a diffuser formed in a V shape. When the airbag is deployed, the rectifying cloth releases gas in two directions from the two gas discharge portions in the inflatable portion. However, the gas discharge part may move violently with the momentum of gas. As a result, the gas discharge direction may fluctuate, which may hinder stable gas discharge into the inflatable portion. Further, when the movement of the gas discharge part becomes large, the airbag may be damaged. Therefore, it is necessary to suppress the movement of the gas discharge part from the viewpoint of preventing the airbag from being damaged.

JP 2009-55977 A

  The present invention has been made in view of such conventional problems, and an object of the present invention is to stably release gas from the diffuser into the inflatable portion of the airbag when the airbag is deployed. Another object is to prevent the airbag from being damaged by the diffuser.

The present invention, by overlapping opposing base fabrics joined at the outer junction, the airbag forming the expansion part for expanding the gas between the base fabric, an inflator for generating gas in the air bag, the inflator is arranged to surround the gas ejection portion the airbag apparatus provided with a diffuser which releases the gas in the expansion portion, the airbag together with the diffuser are arranged inside the insertion portion inflator is inserted a diffuser, together with the inflator is inserted is disposed in the insertion portion of the airbag, a gas flow path which branches are arranged from the insertion portion to an expanded portion, the gas flow path which branches are arranged in the expansion portion a plurality of gas discharge portion connected, protruding from each edge of the plurality of gas discharge portion, have a, a joining piece which is joined to the base fabric at the outer joint portion of the air bag, Airbus When joining the base fabric, the joint piece is placed at the position of the outer edge joint and joined to the base fabric at the outer edge joint. The insertion part of the airbag is not joined to the part where the diffuser gas flows. The portion located in the insertion portion of the diffuser is an airbag device formed with a width narrower than the width inside the insertion portion .

  According to the present invention, gas can be stably released from the diffuser into the inflatable portion of the airbag when the airbag is deployed. Further, the airbag can be prevented from being damaged by the diffuser.

It is a figure which shows the airbag apparatus of this embodiment. It is a front view which shows the expand | deployed airbag. It is a figure which shows the diffuser before and behind formation. It is a front view which shows the airbag before formation. It is a figure which shows the insertion part of a diffuser and an airbag. It is a figure which shows the diffuser assembled | attached to the airbag. It is an enlarged view which shows the junction part vicinity of FIG. It is sectional drawing of a diffuser and an insertion part. It is a figure which shows the airbag after the assembly | attachment of an inflator. It is a figure which shows the inflator assembled | attached to an airbag. It is a figure which shows the inflator assembled | attached to an airbag. It is a front view which shows the inflated airbag. It is an enlarged view which shows the junction part of an insertion part and a diffuser. It is a figure which shows the diffuser of other embodiment. It is a figure which shows the diffuser of other embodiment. It is a figure which shows the diffuser of other embodiment.

An embodiment of an airbag device of the present invention will be described with reference to the drawings.
In the present embodiment, a curtain airbag device (hereinafter simply referred to as an airbag device) that deploys an airbag in a curtain shape in a vehicle will be described as an example. The airbag device is mounted in a vehicle and receives and protects an occupant with an airbag that is inflated and deployed.

FIG. 1 is a view showing an airbag apparatus according to the present embodiment. In FIG. 1, the airbag apparatus 1 mounted in the vehicle 90 is shown as viewed from the passenger compartment. Further, the side wall 91 and the airbag device 1 of the vehicle 90 are schematically shown as viewed from the width direction of the vehicle 90 with the rear side of the vehicle 90 omitted. The airbag device 1 is shown through the inner surface of the vehicle 90.
In the present invention, the front and rear in the vehicle 90 are simply referred to as front and rear, and the front-rear direction in the vehicle 90 is simply referred to as front-rear direction. In addition, the upper and lower portions in the vehicle 90 are simply referred to as upper and lower portions, and the vertical direction in the vehicle 90 is simply referred to as the vertical direction.

  As shown, the vehicle 90 has an upper roof rail 92, a front front pillar (A pillar) 93, a center pillar (B pillar) 94, and a rear rear pillar (C pillar) (see FIG. Not shown). The vehicle 90 includes a front door 95, a rear door 96, and window portions 97 and 98 provided in the doors 95 and 96.

  The airbag device 1 includes an airbag (curtain airbag) 10 and a tubular inflator 2. The airbag device 1 is disposed inside a trim and a head lining (not shown) attached to the vehicle body. The airbag 10 is folded and attached to the vehicle 90 so as to be inflated and deployed. In addition, the airbag 10 is folded along an elongated shape and disposed along the upper portion of the side wall 91. The airbag 10 is attached to the roof rail 92 along the front-rear direction, and is disposed from the rear pillar to the front pillar 93. The folded airbag 10 is fixed to the vehicle body by fixing means (not shown). The front portion 11 of the airbag 10 is attached to the front pillar 93.

  The inflator 2 is a cylinder type gas generator. The inflator 2 is inserted into the airbag 10 and generates gas in the airbag 10. The inflator 2 is disposed above the center pillar 94 and attached to the roof rail 92. The inflator 2 is fixed to the vehicle body by fixing means (not shown). The inflator 2 generates gas and supplies gas to the airbag 10 at the time of vehicle emergency or impact detection. With this gas, the airbag 10 is inflated and deployed in a curtain shape from the upper part of the side wall 91 downward.

FIG. 2 is a front view showing the deployed airbag 10.
As shown in the figure, the airbag 10 is a rectangular bag, and is manufactured, for example, from a base fabric made of a cloth coated with a resin. Here, the airbag 10 includes a front base fabric (front panel) 12 on the passenger side and a back base fabric (back panel) 13 on the side wall 91 side. The airbag 10 includes a connecting belt 20, a plurality (six in FIG. 2) of fixed fabrics 21 to 26, a cylindrical insertion portion 40, and a diffuser 50. Inflator 2 (not shown in FIG. 2) is inserted into insertion portion 40.

  The front end of the airbag 10 is connected to the front pillar 93 by the connecting belt 20. The plurality of fixed fabrics 21 to 26 have a rectangular shape and are integrally formed on an upper edge (referred to as an upper edge) of the airbag 10. The connecting belt 20 and the fixing cloths 21 to 26 are fixed to the front pillar 93 and the roof rail 92 by fixing means (not shown) made of bolts or the like.

  The front base fabric 12 and the back base fabric 13 are formed in the same shape, overlapped, and joined along the outer edge joint portion 15. The outer edge joint portion 15 divides the airbag 10 and forms an inflatable portion 30 between the base fabrics 12 and 13. The inflating part 30 is inflated by the gas generated by the inflator 2. The outer edge joint portion 15 defines the outer edge shape of the inflating portion 30. The base fabrics 12 and 13 are joined by sewing at an outer edge joint portion 15. The base fabrics 12 and 13 are sewn one or more times along the outer edge joint portion 15 and joined in an airtight manner.

  In the airbag 10, a front inflating portion 31, a rear inflating portion 32, and a connected inflating portion 33 are formed by the outer edge joint portion 15. The inflating parts 31 to 33 each have a rectangular shape and constitute the inflating part 30 of the airbag 10 as a whole. The front inflating part 31 is formed to be the longest in the front-rear direction in the inflating parts 31 to 33, and is disposed forward in the airbag 10. The front inflating portion 31 inflates at the side of the window 97 of the front door 95 and the center pillar 94, and mainly receives the front seat occupant.

  The rear inflating portion 32 is formed shorter in the front-rear direction than the front inflating portion 31 and is disposed rearward in the airbag 10. The rear inflating part 32 inflates above the rear door 96 and mainly receives the rear seat occupant. The connected expansion part 33 is formed narrower in the vertical direction than the other expansion parts 31 and 32. The connecting inflating portion 33 is provided between the front inflating portion 31 and the rear inflating portion 32 at the upper edge of the airbag 10 and connects the inflating portions 31 and 32. Between the three inflating parts 31 to 33, a non-inflating part 34 is formed upward from the lower edge (referred to as the lower edge) of the airbag 10. The non-expanding part 34 is provided outside the expanding part 30.

  The airbag 10 has first to fourth internal joint portions 16 to 19 in the inflatable portion 30. The base fabrics 12 and 13 are joined by sewing at a plurality of internal joint portions 16 to 19. The distal ends of the internal joint portions 16 to 19 are joined in an annular shape (annular portions 16A to 19A) in the expansion portion 30. The plurality of internal joint portions 16 to 19 are arranged apart from each other in the front-rear direction, and form a gas circulation portion and an air chamber in the expansion portion 30. The first and second internal joint portions 16 and 17 form first and second air chambers 35 and 36 in the front expansion portion 31. The fourth internal joint portion 19 forms a third air chamber 37 in the rear expansion portion 32.

  The insertion part 40 is an opening (gas supply part) for supplying gas into the airbag 10. The insertion portion 40 is formed in the middle of the airbag 10 in the front-rear direction and opens at the rear end of the front inflating portion 31. The base fabrics 12 and 13 protrude obliquely upward from the upper edge of the airbag 10 at the insertion portion 40. The edges of the base fabrics 12 and 13 are joined continuously from the outer edge joint 15 except for the insertion port 41 at the tip. Thereby, the insertion part 40 is formed in the cylinder shape which both ends opened, and is provided in the upper edge of the airbag 10 integrally.

  The insertion portion 40 protrudes linearly from the inflating portion 30 and is inclined at a predetermined angle α with respect to the longitudinal direction of the airbag 10. The angle α is an angle between the direction in which the insertion portion 40 extends and the longitudinal direction of the airbag 10 in a state where the airbag 10 is expanded on a plane. Here, the angle α of the insertion portion 40 is set to an angle of 30 degrees to 60 degrees. The inside of the insertion portion 40 is connected to the outside of the airbag 10 through an insertion port 41 at one end, and is connected to the inside of the inflating portion 30 at the other end. The inflator 2 is inserted into the insertion portion 40 from the insertion port 41 and disposed in the airbag 10. However, a part of the diffuser 50 is disposed in the insertion portion 40 in advance. That is, the diffuser 50 is disposed inside the insertion portion 40 and the inflator 2 is inserted. The inflator 2 is disposed in the diffuser 50. The diffuser 50 is disposed from the insertion portion 40 to the inflating portion 30 in the airbag 10.

FIG. 3 shows the diffuser 50 before and after formation. FIG. 3A is a development view of the diffuser 50 before formation. FIG. 3B is a front view of the diffuser 50 after formation.
The diffuser 50 is a rectifying member that rectifies the gas generated by the inflator 2 and is composed of a cylindrical member branched into a plurality. The diffuser 50 is made of a flexible member or a deformable member. In the present embodiment, the diffuser 50 includes a deformable base fabric 51. The diffuser 50 is formed by joining the folded base fabric 51 by sewing.

  As shown in the drawing, the base fabric 51 for the diffuser 50 includes a rectangular central portion 51A, a pair of inclined wing-like portions 51B, and joining pieces 52A and 52B. The pair of wing-like parts 51B are integrally formed on the side edge of the central part 51A and project in the opposite direction from the central part 51A. The base fabric 51 is folded back at a predetermined folding line L. At that time, the base fabric 51 is folded back at the center line in the width direction (vertical direction in FIG. 3).

  The base fabrics 51C and 51D on both sides of the fold line L are overlapped with their edges aligned. The wing-like portion 51B is formed longer on one base cloth 51C than on the other base cloth 51D. Each of the joining pieces 52A and 52B is a tab formed in a rectangular shape. The joining pieces 52A and 52B are provided at both ends in the longitudinal direction of the base fabrics 51C and 51D. Further, the joining pieces 52A and 52B protrude from the edges of the base fabrics 51C and 51D on both sides of the fold line L. When the base fabrics 51C and 51D are overlapped, the joining pieces 52A and 52B overlap each other.

  After overlapping the base fabrics 51C and 51D, the base fabrics 51C and 51D are joined at two joint portions 51E and 51F (see FIG. 3B) along the edge. The joint portions 51E and 51F close the space between the base fabrics 51C and 51D. The diffuser 50 is formed in a cylindrical shape by joining the overlapped base fabrics 51. A gas flow path 53 is formed in the diffuser 50 by the joining. Further, the diffuser 50 includes a housing portion 54 of the inflator 2, a plurality (two in FIG. 3) of gas discharge portions 55A and 55B, gas discharge ports 56A and 56B, and outer pieces 57 and 58.

  The accommodating part 54 is formed in a cylindrical shape by joining a pair of wing-like parts 51B. An insertion port 54 </ b> A for the inflator 2 is provided at one end of the housing portion 54. The inflator 2 is inserted into the diffuser 50 (accommodating portion 54) from the insertion port 54A. The accommodating portion 54 accommodates the distal end portion of the inflator 2. The gas flow path 53 is an internal space of the diffuser 50 and is formed from the accommodating portion 54 to the gas discharge portions 55A and 55B. The inflator 2 is inserted into the gas flow path 53 in the housing portion 54. The gas flow path 53 branches in the diffuser 50 and is connected to a plurality of gas discharge portions 55A and 55B.

  The first and second gas discharge portions 55A and 55B are provided at both ends of the folded center portion 51A. The accommodating part 54 and the gas flow path 53 are located between the two gas discharge parts 55A and 55B. The gas flow path 53 branches into two toward the two gas discharge portions 55A and 55B, and guides the gas to the gas discharge portions 55A and 55B. The gas discharge ports 56A and 56B are openings provided in the diffuser 50, and are located at end portions of the gas discharge portions 55A and 55B. The gas discharge ports 56 </ b> A and 56 </ b> B are open at the ends in the front-rear direction of the diffuser 50 in the reverse direction. The joining pieces 52A and 52B are integrally formed at the end portions of the gas discharge portions 55A and 55B in a state where two rectangular pieces overlap each other. The joining pieces 52A and 52B protrude in the same direction at the ends of the gas discharge portions 55A and 55B.

  When the inflator 2 generates gas in the housing portion 54, the gas is guided to the gas discharge portions 55 </ b> A and 55 </ b> B through the gas flow path 53. The gas is discharged from the gas discharge ports 56A and 56B of the gas discharge portions 55A and 55B through the gas flow path 53. The gas discharge portions 55A and 55B discharge the gas in the diffuser 50 into the airbag 10. The gas is discharged from a plurality of gas discharge portions 55A and 55B in different predetermined directions (in the reverse direction here).

  The outer pieces 57 and 58 are tongue-like members (tongue portions) provided at the end of the diffuser 50, and project outward from the diffuser 50. When the diffuser 50 is disposed in the airbag 10, the outer pieces 57 and 58 are not disposed inside the insertion portion 40 but are disposed outside the insertion portion 40 and the airbag 10. The outer pieces 57 and 58 have a rectangular shape and are integrally formed at the distal end portion of the accommodating portion 54. The first outer piece 57 is provided on one base cloth 51 </ b> C and is formed to have the same width as the accommodating portion 54. The second outer piece 58 is provided on the other base cloth 51 </ b> D and is formed smaller than the first outer piece 57. The second outer piece 58 is opposed to the first outer piece 57 at a position inside the first outer piece 57.

Next, a procedure for forming the airbag 10 will be described.
FIG. 4 is a front view showing the airbag 10 before formation.
First, as illustrated, the base fabrics 12 and 13 for the airbag 10 are overlapped. The diffuser 50 is sandwiched between the base fabrics 12 and 13 and arranged at a predetermined position (see FIG. 2). Next, the opposing base fabrics 12 and 13 are joined at the outer edge joint portion 15 to form the inflatable portion 30 between the base fabrics 12 and 13. In addition, the base fabrics 12 and 13 are joined at the internal joining portions 16 to 19, and the connecting belt 20 is attached to the airbag 10. The diffuser 50 is assembled to the airbag 10 along with the joining at the outer edge joining portion 15. Hereinafter, the assembly of the diffuser 50 will be described in detail.

FIG. 5 is a diagram showing the diffuser 50 and the insertion portion 40 of the airbag 10. FIG. 5A shows the diffuser 50 before assembly and the airbag 10 before joining. FIG. 5B is a cross-sectional view of the insertion portion 40 as viewed in the direction of arrows XX in FIG. 5A.
As shown in the figure, the insertion portion 40 has projecting pieces 42 and 43 formed in the same manner as the outer pieces 57 and 58 of the diffuser 50. The projecting pieces 42 and 43 are tongue-like members provided at the end of the insertion portion 40, and project outward from the insertion portion 40. The projecting pieces 42 and 43 have a rectangular shape and are integrally formed at the end of the insertion portion 40. The first projecting piece 42 is provided on the back base fabric 13 of the airbag 10 and is formed to have the same width as the insertion portion 40. The second projecting piece 43 is provided on the front base fabric 12 and is smaller than the first projecting piece 42. The second projecting piece 43 is opposed to the first projecting piece 42 at a position in the first projecting piece 42.

  The insertion portion 40 and the diffuser 50 have two connection holes 44 and 59, respectively. The insertion portion 40 and the diffuser 50 are connected to the inflator 2 through connecting holes 44 and 59 as will be described later. The connection holes 44 and 59 are formed in a circular shape in the protruding piece 42 of the insertion portion 40 and the outer piece 57 of the diffuser 50. The two connection holes 59 of the diffuser 50 are arranged along the longitudinal direction of the housing portion 54. The two connection holes 44 of the insertion portion 40 are arranged at the same interval as the two connection holes 59 of the diffuser 50. The diffuser 50 is disposed between the base fabrics 12 and 13 so that the positions of the connecting holes 59 and 44 are aligned.

FIG. 6 is a view showing the diffuser 50 assembled to the airbag 10. 6A and 6C are front views of the airbag 10 and the diffuser 50. FIG. 6B is a cross-sectional view of the airbag 10 and the diffuser 50 as viewed in the direction of arrows YY in FIG. 6A.
Before joining the base fabrics 12 and 13, as shown in FIGS. 6A and 6B, the diffuser 50 is disposed in advance at a predetermined position between the base fabrics 12 and 13. The accommodating portion 54 of the diffuser 50 is disposed at the position of the insertion portion 40. The end of the diffuser 50 is aligned with the end of the insertion portion 40. The gas discharge portions 55 </ b> A and 55 </ b> B of the diffuser 50 are disposed at the position of the expansion portion 30. Thereafter, the base fabrics 12 and 13 are joined at the outer edge joint portion 15.

  The base fabrics 12 and 13 are joined along the edge of the diffuser 50. Thereby, the accommodating part 54 is arrange | positioned in the insertion part 40 of the airbag 10. FIG. The gas discharge portions 55 </ b> A and 55 </ b> B and the gas discharge ports 56 </ b> A and 56 </ b> B are disposed in the inflating portion 30 of the airbag 10. The gas flow path 53 is disposed from the insertion part 40 to the expansion part 30. The connection holes 59 and 44 are disposed so as to pass through the diffuser 50 and the insertion portion 40. The projecting pieces 42 and 43 of the insertion portion 40 overlap the outer pieces 57 and 58 of the diffuser 50, respectively.

  The outer edge joint portion 15 of the airbag 10 is provided outside the diffuser 50 so as not to overlap the diffuser 50. However, only the joining pieces 52 </ b> A and 52 </ b> B of the diffuser 50 are arranged at the position of the outer edge joining portion 15. When joining the base fabrics 12 and 13 of the airbag 10, the joining pieces 52 </ b> A and 52 </ b> B are joined to the airbag 10 (the base fabrics 12 and 13) at the outer edge joining portion 15. The joining pieces 52 </ b> A and 52 </ b> B are joined together with the base fabrics 12 and 13 between the base fabrics 12 and 13. That is, the joining pieces 52 </ b> A and 52 </ b> B are sewn to the base fabrics 12 and 13 at the outer edge joint portion 15 simultaneously with the sewing of the base fabrics 12 and 13.

  The joining pieces 52A and 52B are provided at end portions of the gas discharge portions 55A and 55B. The joining pieces 52 </ b> A and 52 </ b> B are joined to the airbag 10 to connect the gas discharge portions 55 </ b> A and 55 </ b> B to the airbag 10. The gas discharge portions 55A and 55B are fastened to the airbag 10 by the joining pieces 52A and 52B, and are integrated with the airbag 10. In that case, the edge part of gas discharge | release part 55A, 55B is attached to the airbag 10 by joining piece 52A, 52B.

  Next, the diffuser 50 and the insertion portion 40 are joined by the outer pieces 57 and 58 and the projecting pieces 42 and 43 as shown in FIG. 6C. The outer pieces 57, 58 and the projecting pieces 42, 43 are joined by sewing at the joint portions 45, 46. Thereby, the diffuser 50 is assembled to the airbag 10. The diffuser 50 is joined to the airbag 10 only by the joining pieces 52A and 52B and the outer pieces 57 and 58. In the diffuser 50, portions other than the joining pieces 52A and 52B and the outer pieces 57 and 58 are not joined to the airbag 10. The accommodating part 54 is formed in the width H2 narrower than the width H1 inside the insertion part 40 so that a gap may be formed between the insertion part 40 and the diffuser 50.

  The diffuser 50 and the insertion portion 40 are integrated around the insertion port 41 by joining at the joint portions 45 and 46. As a result, the diffuser 50 is joined to the insertion portion 40 at the insertion port 41 provided in the insertion portion 40. Moreover, the diffuser 50 and the insertion part 40 are integrated and reinforced. The diffuser 50 and the insertion portion 40 receive external force jointly without receiving external force alone. As a result, the diffuser 50 and the insertion portion 40 have high strength against external force and are difficult to break. Thus, the joining parts 45 and 46 are reinforcing parts (reinforcement sewing) that reinforce the diffuser 50 and the insertion part 40.

FIG. 7 is an enlarged view showing the vicinity of the joint portions 45 and 46. FIG. 8 is a cross-sectional view of the diffuser 50 and the insertion portion 40. 8A to 8D show cross-sectional views taken along line Z1-Z1 to Z4-Z4 in FIG. 7, respectively.
As shown in FIG. 7, the outer pieces 57 and 58 of the diffuser 50 and the projecting pieces 42 and 43 of the insertion portion 40 are sewn together at the joint portions 45 and 46. The diffuser 50 and the insertion portion 40 are joined at a portion (joint portion 45) between the two connecting holes 59.

  The first outer piece 57 and the projecting piece 42 are stitched along the width direction of the accommodating portion 54 at the joint portion 45 located in the center (see FIG. 8A). The second outer piece 58 and the projecting piece 43 are stitched along the width direction of the accommodating portion 54 at the joint portion 46 located in the center (see FIG. 8B). Inside the insertion portion 40 (see FIG. 8C), the diffuser 50 is arranged in the insertion portion 40 without being joined to the insertion portion 40. The inflator 2 is inserted into the accommodating portion 54 (gas flow path 53) from the insertion port 54A (see FIG. 8D) of the diffuser 50 and assembled to the airbag 10.

FIG. 9 is a view showing the airbag 10 after the inflator 2 is assembled.
The diffuser 50 is arrange | positioned in the position away from the lower 3rd internal junction part 18 like illustration. The diffuser 50 is partially joined to the airbag 10 without coming into contact with the third internal joint 18. The inflator 2 is inserted into the diffuser 50 and assembled to the diffuser 50 and the airbag 10.

10 and 11 are diagrams showing the inflator 2 assembled to the airbag 10. 10 and 11, the inflator 2 and the insertion portion 40 are shown in an enlarged manner.
As shown in FIG. 10A, the inflator 2 includes a plurality of gas ejection ports 2A and two connecting members 2B. 2 A of jet nozzles are arrange | positioned at the one end part of the longitudinal direction of the inflator 2 at the outer periphery of the inflator 2 whole. The inflator 2 ejects gas radially from the plurality of ejection ports 2A. The two connecting members 2 </ b> B are arranged apart from each other in the longitudinal direction of the inflator 2 and are fixed to the inflator 2. The connecting member 2 </ b> B is a bolt and projects to the side of the inflator 2. For example, the connecting member 2B is integrally fixed to the inflator 2 by welding. The connection holes 44 and 59 described above are formed at the same interval as the connection member 2B.

  When the inflator 2 is inserted, the insertion port 54A of the diffuser 50 is widened by the protruding pieces 42 and 43 and the outer pieces 57 and 58, as shown in FIG. 10B. At that time, holding the protruding pieces 42 and 43 and the outer pieces 57 and 58, the insertion port 54A is widened. Alternatively, the protrusions 42 and 43 and the outer pieces 57 and 58 are pushed to widen the insertion port 54A. That is, the protrusions 42 and 43 and the outer pieces 57 and 58 are moved to open the insertion port 54A. The inflator 2 is inserted into the diffuser 50 through the opened insertion port 54 </ b> A and disposed in the diffuser 50. Further, as shown in FIG. 11A, the inflator 2 is inserted into the housing portion 54 so that at least the jet outlet 2 </ b> A is located in the housing portion 54. Accordingly, a predetermined range including the tip portion of the inflator 2 is arranged in the diffuser 50 (accommodating portion 54).

  Next, as shown in FIG. 11B, the diffuser 50 and the insertion portion 40 are wound around the inflator 2. At that time, the joined projecting piece 42 and outer piece 57 are wound around the outer periphery of the inflator 2. At the same time, the connecting member 2 </ b> B of the inflator 2 is inserted into the connecting holes 44 and 59 that penetrate the diffuser 50 and the insertion portion 40. The connecting member 2 </ b> B connects the inflator 2 to the diffuser 50 and the insertion portion 40.

  Subsequently, the inflator 2 is wrapped with the projecting piece 42 and the outer piece 57, and the band 3 is disposed on the outer periphery of the insertion portion 40 as shown in FIG. 11C. The insertion portion 40 and the diffuser 50 are fastened by the band 3 and are fixed to the inflator 2 in an airtight manner. Thereby, the inflator 2 is assembled to the diffuser 50 and the insertion portion 40. The diffuser 50 surrounds a gas ejection part (gas generation part) of the inflator 2 provided with the ejection port 2A. Thereafter, the airbag device 1 is mounted on the vehicle 90. The airbag apparatus 1 operates the inflator 2 when receiving the operation signal to inflate and deploy the airbag 10.

FIG. 12 is a front view showing the airbag 10 inflated and deployed. In FIG. 12, the gas flow in the airbag 10 is indicated by arrows.
As shown, the inflator 2 is attached to the vehicle body along the front-rear direction. Along with this, the insertion portion 40 and the diffuser 50 are bent. The inflator 2 generates gas in the diffuser 50 and supplies the gas into the airbag 10. By the supplied gas, the inflating portion 30 is inflated, and the airbag 10 is deployed in a curtain shape while eliminating the folded shape.

  The diffuser 50 is disposed in the airbag 10 so as to surround the inflator 2 and starts to inflate first. Further, the diffuser 50 discharges the gas generated by the inflator 2 from the gas discharge portions 55 </ b> A and 55 </ b> B in the expansion portion 30. The diffuser 50 flows the gas out to the expansion unit 30 and continuously supplies the gas to the expansion unit 30. At that time, the gas discharge portions 55A and 55B discharge the gas from the gas discharge ports 56A and 56B in a predetermined direction in the expansion portion 30. The diffuser 50 distributes the gas in a plurality of directions in the expansion unit 30 by the plurality of gas discharge units 55A and 55B.

  The gas generated by the inflator 2 branches through the diffuser 50 and is distributed in the front-rear direction. The gas is supplied to the front expansion part 31 and is supplied to the rear expansion part 32 through the connection expansion part 33. As a result, the airbag 10 (see FIG. 1) is inflated and deployed so as to cover the side wall 91 and closes the windows 97 and 98. The airbag 10 receives the front and rear occupants and protects the occupant's head.

  As described above, in the present embodiment, the joining pieces 52A and 52B are provided in the gas discharge portions 55A and 55B of the diffuser 50 and joined to the airbag 10. Thereby, while being able to connect gas discharge parts 55A and 55B to air bag 10, gas discharge parts 55A and 55B and air bag 10 can be united. When gas is discharged from the gas discharge portions 55A and 55B, the movement of the gas discharge portions 55A and 55B can be suppressed. The positions of the gas discharge portions 55A and 55B can also be maintained at predetermined positions in the expansion portion 30. Since it is possible to prevent the gas discharge portions 55A and 55B from moving violently, fluctuations in the gas discharge direction can be reduced. As a result, gas can be stably discharged from the diffuser 50 into the inflatable portion 30 when the airbag 10 is deployed. Further, the airbag 10 can be prevented from being damaged by the diffuser 50.

  Since the joining pieces 52A and 52B are joined to the base fabrics 12 and 13 by the outer edge joining portion 15, the base fabrics 12 and 13 and the joining pieces 52A and 52B can be joined simultaneously. Further, since the labor and man-hour required for joining the joining pieces 52A and 52B can be reduced, the working efficiency can be improved. Since it is possible to prevent the joining pieces 52A and 52B from being forgotten to be joined, the joining pieces 52A and 52B can be reliably joined to the airbag 10.

  The diffuser 50 has gas discharge ports 56A and 56B located at end portions of the gas discharge portions 55A and 55B. The joining pieces 52A and 52B are provided at the end portions of the gas discharge portions 55A and 55B, and the end portions of the gas discharge portions 55A and 55B are attached to the airbag 10. Thereby, the movement of gas discharge part 55A, 55B can be suppressed in the part of gas discharge port 56A, 56B which is the easiest to move. Moreover, since the intense movement of the gas discharge portions 55A and 55B can be effectively prevented, the effect of stabilizing the gas release is enhanced. Damage to the airbag 10 can also be prevented more reliably. Even if the joining pieces 52A and 52B are made small, sufficient effects can be obtained. By reducing the joining pieces 52A and 52B, the joining range of the joining pieces 52A and 52B can be reduced. Therefore, the working efficiency at the time of joining can be improved. Moreover, since the usage-amount of a base fabric can be reduced, the cost of the airbag 10 can be reduced.

  Since the diffuser 50 is joined to the insertion portion 40 through the insertion port 41, the inflator 2 is not inserted between the diffuser 50 and the insertion portion 40, but is reliably inserted into the diffuser 50. As a result, erroneous insertion of the inflator 2 can be prevented. Moreover, since the gap between the diffuser 50 and the insertion portion 40 can be prevented, the inflator 2 can be easily inserted into the diffuser 50. With the joining, the diffuser 50 and the insertion portion 40 can be reinforced as described above. It is possible to prevent the diffuser 50 and the insertion portion 40 from being displaced due to the gas pressure.

  The inflator 2 can be easily inserted into the diffuser 50 by the protruding pieces 42 and 43 of the insertion portion 40 and the outer pieces 57 and 58 of the diffuser 50. Therefore, the work efficiency of insertion becomes high. By joining the projecting pieces 42 and 43 and the outer pieces 57 and 58 together, the insertion portion 40 and the diffuser 50 can be easily joined. Since the projecting piece 42 and the outer piece 57 are not bulky and can be easily wound around the inflator 2, the winding work is also facilitated. Further, the projecting piece 42 and the outer piece 57 can be wound around the inflator 2 in a compact manner.

  The inflator 2 is connected to the diffuser 50 and the insertion portion 40 by the connecting member 2 </ b> B and the connecting holes 44 and 59. Therefore, the change of the position of the inflator 2, the diffuser 50, and the insertion part 40 can be suppressed. Further, when the airbag 10 is deployed, the diffuser 50 and the insertion portion 40 are hooked on the connecting member 2 </ b> B, so that the inflator 2 can be prevented from coming off from the diffuser 50 and the insertion portion 40. That is, the diffuser 50 and the insertion portion 40 are not detached from the inflator 2. When the connection holes 44 and 59 are formed in the projecting piece 42 and the outer piece 57, the connection member 2B can be easily inserted into the connection holes 44 and 59.

  By joining the diffuser 50 and the insertion portion 40 at the joint portion 45, the vicinity of the connection holes 44 and 59 can be reinforced. As a result, the diffuser 50 and the insertion portion 40 are not easily broken in the vicinity of the connection holes 44 and 59. The inflator 2 is maintained in a state of being connected to the diffuser 50 and the insertion portion 40 by the connecting member 2 </ b> B and the connecting holes 44 and 59. Therefore, the inflator 2 can be more reliably prevented from coming off from the diffuser 50 and the insertion portion 40.

  Since the diffuser 50 is formed of a flexible member or a deformable member, the diffuser 50 can be easily deformed. As a result, the diffuser 50 can be easily folded and bent, and the airbag 10 can be easily attached to the vehicle body. Even when the diffuser 50 located in the insertion portion 40 is deformed or bent, the diffuser 50 located in the expansion portion 30 is hardly affected by deformation or bending in the insertion portion 40. As a result, since the positions of the gas discharge portions 55A and 55B are maintained in the expansion portion 30, gas can be reliably discharged from the gas discharge portions 55A and 55B into the expansion portion 30. The gas discharge portions 55A and 55B can also distribute the gas accurately in a predetermined direction in the expansion portion 30.

  Regardless of the shape and configuration of the airbag 10, the gas can be released or distributed in the inflatable portion 30 only by the diffuser 50. Even when the gas is ejected radially from the inflator 2, the gas can be rectified and guided while flowing through the gas flow path 53 of the diffuser 50, so that the gas can be appropriately supplied to the expansion portion 30. The diffuser 50 can be easily manufactured by joining the overlapped base fabrics 51 to form the diffuser 50.

  Since the insertion portion 40 is not joined to the portion of the diffuser 50 through which the gas flows, the insertion portion 40 is hardly affected by the movement of the diffuser 50 or the pressure. Therefore, damage to the insertion portion 40 can be prevented. In addition, it is preferable to form the part (accommodating part 54) located in the insertion part 40 of the diffuser 50 in the width H2 narrower than the width H1 inside the insertion part 40 (refer FIG. 6C). In this way, by making the diffuser 50 smaller (thinner) than the insertion portion 40, a gap is provided between the diffuser 50 and the insertion portion 40. The gap prevents the heat of the inflator 2 from being transmitted to the insertion portion 40. Further, the movement and pressure of the diffuser 50 are further suppressed from being transmitted to the insertion portion 40. As a result, the effect of protecting the insertion portion 40 is enhanced.

  The diffuser 50 may be made of the same material as the base fabrics 12 and 13 of the airbag 10 or may be made of a material different from the base fabrics 12 and 13. In the present embodiment, the diffuser 50 includes a base fabric 51 having higher heat resistance than the base fabrics 12 and 13 of the airbag 10. For example, the base fabric 51 of the diffuser 50 is made thicker than the base fabrics 12 and 13 of the airbag 10. Further, the amount of silicone coated on the base fabric 51 is set to be larger than the amount of silicone coated on the base fabrics 12 and 13. Thereby, the heat resistance of the diffuser 50 is made high and the airbag 10 is protected from the gas and heat which the inflator 2 generate | occur | produces.

  One or three or more connecting members 2B may be provided in the inflator 2. In this case, one or three or more connection holes 44 and 59 are formed in accordance with the number of connection members 2B. When two or more connecting members 2B are provided in the inflator 2, only a part of the connecting members 2B located on the tip side of the inflator 2 may be inserted into the connecting holes 44 and 59. The connecting member 2 </ b> B located on the rear end side of the inflator 2 is disposed outside the diffuser 50 and the insertion portion 40 without being inserted into the connecting holes 44 and 59.

Next, other embodiments of the joint portions 45 and 46 will be described.
FIG. 13 is an enlarged view showing a joint portion between the insertion portion 40 and the diffuser 50.
Here, as shown in FIG. 13A, the insertion portion 40 and the diffuser 50 do not have the second protruding piece 43 and the outer piece 58 but have the first protruding piece 42 and the outer piece 57. The first projecting piece 42 and the outer piece 57 are stitched along the width direction of the housing portion 54 at the joint portion 60 located at the center. Further, the insertion portion 40 and the diffuser 50 are stitched along the width direction of the housing portion 54 at the joint portion 61 located at the portion of the insertion ports 41 and 54A. In this case, since the insertion portion 40 and the diffuser 50 can be made smaller by the amount of the second projecting piece 43 and the outer piece 58, the yield can be improved.

  As shown in FIG. 13B, the insertion portion 40 and the diffuser 50 may be sewn together at a joint portion 62 that obliquely crosses between the two connection holes 59. Even if the inflator 2 is inserted between the projecting piece 42 and the outer piece 57 in the joint portion 62, the joint portion 62 is positioned between the inflator 2 and one of the connecting holes 44 and 59. Therefore, one connecting member 2B of the inflator 2 cannot be inserted into the connecting holes 44 and 59. As a result, the erroneous insertion of the inflator 2 can be reliably detected.

  The insertion part 40 and the diffuser 50 may be sewn together at a rectangular joint part 63 as shown in FIG. 13C. The joint portion 63 is a sewing portion that surrounds the connection holes 44 and 59. The joint 63 is provided around the connection holes 44 and 59 at a position away from the connection holes 44 and 59 by a predetermined distance (here, 10 mm). Both end portions of the joint portion 63 are formed in an arc shape. Since the joint 63 can reinforce the periphery of the connection holes 44 and 59, the strength of the connection holes 44 and 59 can be increased. As a result, the insertion portion 40 and the diffuser 50 are not easily broken around the connection holes 44 and 59. It is possible to more reliably prevent the inflator 2 from coming out of the diffuser 50 and the insertion portion 40. Even when the inflator 2 is inserted between the projecting piece 42 and the outer piece 57, both connecting members 2 </ b> B of the inflator 2 cannot be inserted into the connecting holes 44 and 59. Therefore, the erroneous insertion of the inflator 2 can be reliably detected.

  The insertion portion 40 and the diffuser 50 may be sewn together at a joint portion 64 along the edge of the outer piece 57 as shown in FIG. 13D. The joint portion 64 is a rectangular sewing portion that surrounds the connection holes 44 and 59. The entire outer piece 57 is joined to the protruding piece 42 by the joining portion 64. Since the inflator 2 cannot be inserted between the projecting piece 42 and the outer piece 57 by the joint portion 64, erroneous insertion of the inflator 2 can be prevented. In each embodiment shown in FIG. 13, the second protrusion 43 and the outer piece 58 may be provided on the insertion portion 40 and the diffuser 50, and the second protrusion 43 and the outer piece 58 may be joined.

  In addition, the several gas discharge port 56 (refer FIG. 6) of the diffuser 50 may be formed in the same magnitude | size, and may be formed in a different magnitude | size. The accommodating portion 54 of the diffuser 50 may be formed with the same width H2 as the width H1 of the insertion portion 40. The diffuser 50 may be formed by sewing the base fabric 51 or may be formed by jacquard weaving. One or three or more gas discharge portions 55 and gas discharge ports 56 may be provided in the diffuser 50. When the diffuser 50 includes a plurality of gas discharge portions 55 that distribute gas within the expansion portion 30, the joining piece 52 may be provided on all of the plurality of gas discharge portions 55 or a part thereof. Good.

14 to 16 show diffusers 70 to 72 according to other embodiments. In FIGS. 14-16, the diffusers 70-72 are shown corresponding to FIG.
The diffusers 70 to 72 are basically configured in the same manner as the above-described diffuser 50 (see FIG. 3). Below, only the parts different from the diffuser 50 are demonstrated about the diffusers 70-72.

As shown in FIG. 14, in the diffuser 70, the joining piece 52A is provided only in the first gas discharge part 55A. The second gas discharge portion 55B does not have the joining piece 52B and is formed shorter than the first gas discharge portion 55A.
As shown in FIG. 15, in the diffuser 71, the joining piece 52B is provided only in the second gas discharge portion 55B. The first gas discharge part 55A does not have the joining piece 52A and is formed shorter than the second gas discharge part 55B.
Thus, depending on the shape of the gas discharge part 55 and the degree of movement, the joining piece 52 may be provided only in a part of the gas discharge parts 55.

  In the diffuser 50 shown in FIG. 3, the joining pieces 52 </ b> A and 52 </ b> B are provided on the base fabrics 51 </ b> C and 51 </ b> D on both sides of the folding line L. On the other hand, as shown in FIG. 16, in the diffuser 72, the joining pieces 52A and 52B are provided only on one base cloth 51C. That is, the joining pieces 52A and 52B may be one member or a plurality of stacked members.

  DESCRIPTION OF SYMBOLS 1 ... Airbag apparatus, 2 ... Inflator, 2A ... Spout, 2B ... Connecting member, 3 ... Band, 10 ... Airbag, 11 ... Front part, 12. .. Front base fabric, 13 ... Back base fabric, 15 ... Outer edge joint, 16-19 ... Internal joint, 20 ... Connection belt, 21-26 ... Fixed fabric, 30 ..Expansion part, 31 ... front expansion part, 32 ... rear expansion part, 33 ... connected expansion part, 34 ... non-expansion part, 35-37 ... air chamber, 40 ... Insertion part 41 ... Insertion opening 42, 43 ... Projection piece 44 ... Connection hole 45, 46 ... Joint part 50 ... Diffuser 51 ... Base fabric 52 ..Joint piece, 53... Gas flow path, 54... Housing portion, 54 A .. insertion port, 55. -Outer piece, 59 ... Connection hole, 60-64 ... Joint part, 70-72 ... Diffuser, 90 ... Vehicle, 91 ... Side wall, 92 ... Roof rail, 93 ... Front pillar, 94 ... center pillar, 95 ... front door, 96 ... rear door, 97, 98 ... window.

Claims (1)

An air bag in which an inflating part that inflates with gas is formed between the base cloths and is inflated by gas, an inflator that generates gas in the air bag, and a gas ejection part of the inflator the airbag apparatus provided with a diffuser which releases in enclosing disposed expanded portion of the gas, and
The airbag has an insertion portion in which the inflator is inserted, and the diffuser is disposed inside,
The diffuser is arranged in the insertion portion of the airbag and the inflator is inserted therein, and a plurality of gas flow paths arranged from the insertion portion to the inflating portion and a plurality of gas passages arranged in the inflating portion and connected to the diverging gas flow passage a gas discharge portion, protrude respectively from the edge of the plurality of gas discharge portion, have a, a joining piece which is joined to the base fabric at the outer joint portion of the air bag, when joining the base fabric of the air bag, joining Only the piece is placed at the position of the outer edge joint and joined to the base fabric at the outer edge joint,
The insertion part of the airbag is not joined to the part where the gas of the diffuser flows,
The airbag apparatus in which the part located in the insertion part of a diffuser was formed in the width | variety narrower than the width | variety inside an insertion part .

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