JP5227925B2 - Air bag body - Google Patents

Description

  The present invention relates to an airbag bag body that regulates gas outflow by covering a vent hole with a vent hole cover.

In the airbag bag body, when the gas introduced from the inflator expands the airbag bag body, the vent hole provided in the airbag bag body is covered with a vent hole cover to regulate gas emission from the vent hole. There is something.
Here, the vent hole cover is supported by a cover guide member in the vicinity of the vent hole so as not to be displaced with respect to the vent hole (see, for example, Patent Document 1).

According to the airbag bag body of Patent Document 1, it is possible to regulate the release of gas with the vent hole cover until the airbag bag body is deployed in a shape that can restrain the occupant.
When the airbag bag body is deployed to a shape that can restrain the occupant, the sewing thread that has stopped the vent hole cover is broken.

When the sewing thread breaks, the holding of the vent hole cover by the sewing thread is released, and the vent hole cover is pushed out of the airbag bag body from the vent hole.
Therefore, a gap is formed between the vent hole cover and the vent hole, and gas is released to the outside through the formed gap.
By releasing the gas from the formed gap to the outside, the internal pressure of the airbag bag body can be adjusted.

  In such an airbag bag body, a device that can stabilize the behavior of the vent hole cover and smoothly realize the outflow of gas from the vent hole is desired.

Japanese Patent Laid-Open No. 2005-199987

  The present invention has a function of preventing the gas from flowing out at the beginning of the inflation of the airbag bag body, quickly stabilizing the shape, and allowing the outflow of gas from the vent hole of the airbag bag body as necessary. It is an object of the present invention to provide an airbag bag body having a highly reliable structure in which the vent hole cover can respond smoothly when the function of the vent hole cover is added to the vent hole.

  The invention according to claim 1 is an airbag bag body configured to be inflatable by gas of an inflator and provided with a vent hole for preventing an increase in internal pressure. The vent hole covers the vent hole on the airbag bag body. A cover and a guide member that regulates the movement of the vent hole cover; the guide member is connected to the base fabric of the airbag bag body by stitching; and stress that suppresses concentration of stress on the stitched end of the guide member A concentration suppressing part is formed.

Furthermore, the invention according to claim 1 is characterized in that the stress concentration suppressing portion is formed of a stitched portion formed in an arc shape.

Furthermore, the invention according to claim 1 is provided with a reinforcing member that is formed in substantially the same shape as the guide member and reinforces the vent hole in the airbag bag body, and the stress concentration suppressing portion is a region where the guide member and the reinforcing member overlap each other. It is provided in.

The present invention has the following effects.
The invention according to claim 1 is an airbag bag body configured to be inflatable by inflator gas and provided with a vent hole for preventing an increase in internal pressure, wherein the vent hole cover covers the vent hole on the airbag bag body. And a guide member for restricting the movement of the vent hole cover.
Since the guide member is connected to the base fabric of the airbag bag body by stitching and the stress concentration suppressing portion that suppresses the concentration of stress on the suture end of the guide member is formed, the guide member is the base fabric of the airbag bag body. Can be prevented from peeling off.

Furthermore, in the invention according to claim 1 , since the stress concentration suppressing portion is formed by a stitched portion formed in an arc shape, interference between the guide member and the vent hole cover can be prevented, and smooth movement of the vent hole cover can be achieved. Can be realized.

Furthermore, in the invention according to claim 1 , the airbag bag body is provided with a reinforcing member that is formed in substantially the same shape as the guide member and reinforces the vent hole, and the stress concentration suppressing portion is a region where the guide member and the reinforcing member overlap each other. Therefore, further reinforcement of the vent hole portion can be strengthened, and stress relaxation of the vent hole portion can be achieved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a vehicle equipped with a vehicle airbag device that employs an airbag bag body according to a first embodiment of the present invention. It is the figure which looked at the airbag bag body of Example 1 concerning the present invention from the vehicles front. FIG. 3 is a sectional view taken along line 3-3 in FIG. 2. It is a disassembled perspective view of the airbag apparatus which employ | adopted the airbag bag body shown in FIG. FIG. 3 is a detailed view of a breaking suture portion shown in FIG. 2. FIG. 6 is a sectional view taken along line 6-6 of FIG. It is a principal part enlarged view of the airbag bag body shown in FIG. It is an enlarged view of the stress concentration suppression part of the airbag bag body shown in FIG. FIG. 3 is a comparative study diagram of the airbag bag body shown in FIG. 2. It is a disassembled perspective view of the airbag apparatus which employ | adopted the airbag bag body of Example 2 which concerns on this invention. It is the principal part enlarged view which looked at the airbag bag body shown by FIG. 10 from the vehicle front.

  Embodiments of the present invention will be described below with reference to the accompanying drawings. "Front", "Rear", "Left", "Right", "Up", "Down" follow the direction seen from the driver, Fr is front, Rr is rear, Le is left, Ri is right Indicates.

  As shown in FIG. 1, the vehicle 10 has a vehicle airbag device 13 (hereinafter referred to as “airbag device 13”) stored on a steering wheel 12 disposed in front of a driver's seat 11. It is. The airbag device 13 introduces gas into an airbag bag body from an inflator (not shown) when collision energy is applied to the vehicle 10 and deploys the gas to the front side of the driver (hereinafter referred to as “occupant”). Is to be restrained and protected. Hereinafter, the airbag device 13 will be described in detail.

  As shown in FIGS. 2 and 3, the airbag device 13 includes an inflator 20 (see FIGS. 3 and 4) indicated by an imaginary line and a retainer 22 (see FIGS. 3 and 4) arranged integrally with the steering wheel 12. ), A fixing ring 23, and an airbag bag body 30. When the inflator 20 receives an ignition signal due to the collision energy acting on the vehicle 10, the inflator 20 ignites a gas generating agent (not shown) so as to ignite a high-pressure gas for bag expansion (hereinafter simply referred to as "gas"). Is generated and supplied to the airbag bag body 30. The inflator 20 has a mounting flange 21. The retainer 22 is a member that holds the airbag bag body 30 in a folded state and supports the inflator 20, and is provided on the steering wheel 12 (see FIG. 1). A bolt 24 (see FIG. 4) formed integrally with a fixing ring 23 disposed in the airbag bag body 30 is inserted into a through-hole formed in the mounting flange 21, and the retainer 22 is attached by the fixing ring 23 and the flange 21. The inflator 20 is fixed to the steering wheel 12 by fastening with a nut in a sandwiched state.

  As shown in FIGS. 2 to 4, the airbag bag body 30 includes a first base cloth 31 and a second base cloth 41 each having a circular shape. The first base fabric 31 is a front seat positioned so as to face the steering wheel 12 when the airbag bag body 30 is deployed. The second base fabric 41 is a rear seat positioned so as to face the occupant when the airbag bag 30 is deployed. By overlapping the first and second base fabrics 31 and 41 and joining the outer peripheral portions 42 to each other (sewing integrally with the outer peripheral stitching portion 43), the airbag bag body 30 having a circular shape in front view is configured. Is done.

The first base fabric 31 is formed with one inflator insertion hole 32, a plurality of bolt holes 33, and one vent hole 34.
The inflator insertion hole 32 is a circular through hole that is disposed at the center CP of the first base fabric 31 and surrounds the inserted inflator 20. The gas generated by the inflator 20 is supplied to the inside of the airbag bag body 30. Hereinafter, the center CP of the first base fabric 31 is appropriately rephrased as “the center CP of the inflator insertion hole 32”.

  The plurality of bolt holes 33 are arranged around the inflator insertion hole 32. By overlapping the first base fabric 31 and the fixing ring 23 on the mounting flange 21 of the inflator 20 and screwing the bolt 24 (see FIG. 4) inserted into the bolt hole 33 to the mounting flange 21, the airbag bag body 30. Is attached to a retainer 22 on the steering wheel 12.

  The vent hole 34 is a circular through hole for releasing a part of gas to the outside when the airbag bag body 30 is inflated, and is a position offset by a predetermined distance from the center CP of the inflator insertion hole 32. It is arranged at HP (hole center HP). By releasing a part of the gas, it is possible to prevent the gas pressure (bag internal pressure) in the airbag bag body 30 from becoming excessive.

  As shown in FIGS. 2 and 3, the overlapped first and second base fabrics 31, 41 are a plurality of stitches, for example, three stitches, which are generally continuous in the circumferential direction from the central portion toward the outer peripheral portion. It is stitched by 51, 52, 53. These suture portions 51 to 53 are configured to be separated by sequentially breaking the suture from the central portion toward the outer peripheral portion due to the bag internal pressure when the airbag bag body 30 is inflated. Hereinafter, the separable stitching portions 51 to 53 are referred to as “breaking stitching portions 51 to 53”. Hereinafter, the breaking suture portions 51 to 53 will be described in detail.

  FIG. 5 shows a cross section in a state in which the first and second base fabrics 31 and 41 are stitched together by the breaking stitching portions 51 to 53. As shown in FIGS. 2 and 5, the three breaking suture portions 51 to 53 are portions that are spirally stitched from the stitching start point 54 near the center CP of the inflator insertion hole 32 to the stitching end point 55 of the outer peripheral portion 42. It is. Thus, the stitching start point 54 located at the radially inner end is directed to the center CP of the airbag bag body 30 (the center CP of the inflator insertion hole 32). For this reason, stress can be concentrated on the sewing start point 54 by the bag internal pressure.

  All of these three breaking suture portions 51 to 53 have the same configuration, and the length from the stitching start point 54 to the stitching end point 55 is the same, and they are arranged with a phase shift of 120 °. In the three breaking suture portions 51 to 53, the distances from the center CP of the inflator insertion hole 32 to the stitching start point 54 are all the same, and the distances from the center CP to the stitching end point 55 are all the same.

  Here, in FIG. 2, it is assumed that the azimuth in which the hole center HP is located is 0 ° with respect to the center CP of the inflator insertion hole 32, and the angle increases clockwise in the figure. The straight line SL1 extending from the center CP of the inflator insertion hole 32 through the center of the hole center HP to the azimuth of 0 ° is referred to as a reference line SL1. A straight line orthogonal to the reference line SL1 on the surface of the first base fabric 31 is referred to as an orthogonal reference line SL2.

  The first breaking suture portion 51 has a azimuth 0 ° as a stitching start point 54, and is slightly stitched outward in the radial direction while slightly extending outward from the stitching start point 54, and then stitched in a circular arc shape. It is sewn in a spiral shape by an angle of 120 °, and an azimuth of 120 ° is a stitching end point 55. The stitching start point 54 is located radially outward from the vent hole 34. The stitching end point 55 is formed before reaching the outer peripheral edge of the base fabric 31, 41, thereby allowing gas to flow between the end point and the outer peripheral edge.

  Similarly, the second breaking suture part 52 is stitched in a spiral shape by 240 ° in the counterclockwise direction along the outer periphery of the first breaking suture part 51 with the azimuth 120 ° as the stitching start point 54. The azimuth 240 ° is the stitching end point 55. The third breaking suture portion 53 has a direction 240 ° as a sewing start point 54, and is sutured in a spiral shape by 240 ° counterclockwise along the outer periphery of the second breakage suture portion 52. ° is the stitching end point 55. The breaking suture portions 51, 52, 53 are spaced apart from each other with a predetermined interval in the radial direction. This interval gradually decreases as the stitching start point 54 advances to the stitching end point 55.

  As described above, each of the breaking suture portions 51 to 53 is configured to be separated by sequentially breaking the suture thread 56 from the central portion toward the outer peripheral portion. As shown in FIG. 6, the suture thread 56 is composed of a first thread 56a and a second thread 56b. The first yarn 56a is not weakly colored so as to be broken by a bag internal pressure of a predetermined level or more, for example, tensile strength (force required for pulling and breaking, breaking load) of 20N to 60N is not applied. Made of filament yarn. On the other hand, the second thread 56b is a thread that guides the first thread 56a in the stitching direction of the breaking suture portions 51, 52, and 53, and is not broken by the bag internal pressure when the airbag bag body 30 is inflated. In addition, the tensile strength is set larger than that of the first yarn 56a.

  For this reason, the 1st thread | yarn 56a is fractured | ruptured by the tension | tensile_strength which acts on a 1st thread | yarn based on the bag internal pressure more than predetermined. Moreover, the first thread 56a is guided in the stitching direction by the second thread 56b. For this reason, the breaking strength of the first thread 56a is kept substantially constant at any location in each of the breaking suture portions 51 to 53. Accordingly, the first yarn 56a is appropriately and sequentially broken from the central portion toward the outer peripheral portion of the first and second base fabrics 31 and 41. The airbag bag body 30 can be inflated more smoothly with good timing by the gas supplied from the inflator 20. For this reason, the change of the bag internal pressure can be controlled more appropriately. And the internal pressure characteristic of the airbag bag body 30 after starting supply of gas from the inflator 20 to the airbag bag body 30 can be made still more exact.

  The filament yarn constituting the first yarn 56a is a yarn composed of filaments (continuous continuous fibers) and has no or almost no twist. Since there is no twist, there is little variation in breaking load in the length direction of the yarn. Accordingly, the first yarn 56a is accurately and sequentially broken from the central portion toward the outer peripheral portion of the first and second base fabrics 31 and 41 by a bag internal pressure of a predetermined level or more.

As shown in FIGS. 2 to 4, the airbag bag body 30 includes a vent hole cover 60, a cover guide member 70, and first, second, and third reinforcing sheets 81, 82, and 83. Each of the reinforcing sheets 81 to 83 has a through-hole having substantially the same diameter as the inflator insertion hole 32.
The first reinforcing sheet 81 is superimposed on the surface of the first base cloth 31 (the face facing the mounting flange 21), and further, the second reinforcing sheet 82, the vent hole cover 60, The cover guide member 70 and the third reinforcing sheet 83 are overlapped in this order, and all these members are integrally stitched around the inflator insertion hole 32.

  The first and third reinforcing sheets 81 and 83 are annular (hollow circular) members, and reinforce the periphery of the inflator insertion hole 32 in the first base cloth 31. The second reinforcing sheet 82 is an elongated member, and reinforces the periphery of the inflator insertion hole 32 and the periphery of the vent hole 34 in the first base cloth 31. The mounting flange 21 is overlapped with the first base fabric 31 via the first reinforcing sheet 81. The fixing ring 23 is overlaid on the first base fabric 31 via the third reinforcing sheet 83.

  The first and second base fabrics 31 and 41, the vent hole cover 60, the cover guide member 70, and the first, second, and third reinforcing sheets 81, 82, and 83 are all made of the same material and the same thickness ( Flexible panel). This cloth has mutually different friction characteristics (friction resistance) on the front surface (one surface) and the back surface (the other surface). For example, the friction characteristics are different between the front and back surfaces by applying a silicon coating only to one side of the cloth. The first base cloth 31, the second base cloth 41, the vent hole cover 60, and the cover guide member 70 are arranged so that the front and back surfaces of the first base cloth 31, the second base cloth 41, and the cover guide member 70 face each other alternately.

  For example, the friction resistance of the first base fabric 31 is smaller on the front surface (surface facing the mounting flange 21) than on the back surface. The vent hole cover 60 has a surface with a small frictional resistance facing a back surface (a surface with a large frictional resistance) of the first base fabric 31. The cover guide member 70 has a surface with a small frictional resistance facing a back surface (a surface with a high frictional resistance) of the vent hole cover 60. The surface of the second base fabric 41 having a small frictional resistance faces the back surface (a surface having a high frictional resistance) of the cover guide member 70.

  In FIG. 7, the state which saw through the 1st base fabric 31 shown with an imaginary line is represented. As shown in FIGS. 2 to 4 and 7, the vent hole cover 60 is a member that closes the vent hole 34 in a normal state until a bag pressure of a predetermined level or more is applied to the airbag bag body 30. The vent hole cover 60 is formed in a substantially T-shape when viewed from the front, and includes an annular base 61, a vertical belt-like extension portion 62, and a horizontal belt-like orthogonal portion 63. The vent hole cover 60 is symmetrical with respect to the reference line SL1.

  More specifically, the base 61 of the vent hole cover 60 is an annular portion located at the center CP of the inflator insertion hole 32, and has a through hole having substantially the same diameter as the inflator insertion hole 32. The base 61 is integrally stitched to the first base cloth 31 around the inflator insertion hole 32.

  The extended portion 62 of the vent hole cover 60 is a vertical strip portion having a predetermined width extending along the reference line SL1 from the base portion 61 to the vent hole 34 along the back surface of the first base fabric 31.

  The orthogonal portion 63 of the vent hole cover 60 is a horizontal band-shaped portion having a predetermined width extending from the tip portion of the extending portion 62 to the left and right with respect to the reference line SL1 along the back surface of the first base fabric 31. is there. That is, it extends in a direction orthogonal to the extending part 62. In FIG. 7, the upper edge of the orthogonal part 63 is formed substantially parallel to the orthogonal reference line SL2. Further, the lower edge of the orthogonal part 63 is formed in a slightly tapered shape that protrudes toward the center CP side of the inflator insertion hole 32.

  More specifically, the orthogonal part 63 includes a pair of left and right belt-like parts 64 and 64 extending in directions away from the reference line SL1. The front end portions 64a and 64a of the left and right belt-like portions 64 and 64, that is, both end portions of the orthogonal portion 63 are stitched to the first and second base fabrics 31 and 41 by the respective breaking stitching portions 51 to 53. .

  The intersection of the vertical belt-like extension part 62 and the horizontal belt-like orthogonal part 63 is located at the hole center HP. The distance from the corner portion (the T-shaped corner portion of the vent hole cover 60) between the edge of the extension portion 62 and the edge of the orthogonal portion 63 to the edge of the vent hole 34 is larger than the other portions of the vent hole cover 60. It is set small.

  The cover guide member 70 is a member that guides the position of the orthogonal portion 63 of the vent hole cover 60 so as not to shift when the orthogonal portion 63 moves in the direction of the reference line SL1. The cover guide member 70 is formed in a substantially T-shape when viewed from the front, and includes an annular base 71 and a lateral belt-shaped guide 72. This cover guide member 70 is symmetrical with respect to the reference line SL1.

  More specifically, the base 71 of the cover guide member 70 is an annular portion located at the center CP of the inflator insertion hole 32, and has a through hole having substantially the same diameter as the inflator insertion hole 32. The base 71 is integrally stitched to the first base cloth 31 around the inflator insertion hole 32. By extending the base 71 to the vicinity of the inflator 20, the relative position between the inflator 20 and the cover guide member 70 can be easily adjusted, and the manufacturing accuracy can be improved.

  The guide portion 72 is a horizontal band-shaped portion having a predetermined width extending from the outer peripheral portion of the base portion 71 along the back surface of the first base fabric 31 both to the left and right with respect to the reference line SL1. The guide portion 72 is superimposed on the first base cloth 31 from above the orthogonal portion 63 of the vent hole cover 60, and is guided by the first, second, and third stitching portions 73 to 75 for guide. Only the base fabric 31 is sewn together. The movement (sliding) of the orthogonal part 63 of the vent hole cover 60 is guided and the moving direction of the orthogonal part 63 is regulated by the three guide sewing parts 73 to 75 (guide sewing parts 73 to 75). The The left and right tips 72a, 72a of the guide portion 72 are opened without being sewn and extended to the vicinity of the breaking suture portions 51 to 53.

  As shown in FIG. 7, the first guide stitching portion 73 is a stitched portion from the vicinity of the left tip 72 a to the vicinity of the right tip 72 a along the upper edge of the guide portion 72. The first guide stitching portion 73 is stitched substantially parallel to the upper edge of the guide portion 72.

  The second guide stitching portion 74 is sewn from the vicinity of the left end 72a of the guide portion 72 to the vicinity of the edge of the extending portion 62 of the vent hole cover 60 along the left lower edge of the guide portion 72. Part. The second guide stitching portion 74 is stitched to the lower edge of the left side of the guide portion 72 so that the extending portion 62 side is slightly closer to the inflator insertion hole 32.

  The third guide stitching portion 75 is stitched from the vicinity of the right tip 72a of the guide portion 72 to the vicinity of the edge of the extension portion 62 of the vent hole cover 60 along the right lower edge of the guide portion 72. Part. The third guide stitching portion 75 is stitched to the lower edge of the right side of the guide portion 72 so that the extending portion 62 side is slightly inclined toward the inflator insertion hole 32.

  As shown in FIGS. 8A and 8B, the guide stitching portions 73 to 75 have stress concentration suppressing portions 76 and 76 at stitched ends on both sides, respectively. As shown in FIGS. 7 and 8 (a) and 8 (b), the stress concentration suppressing portions 76 and 76 on both sides further guide the suture portions 73 to 75 away from the vent hole cover 60 at each suture end. This is a looped portion (sewn portion). In the present embodiment, the stress concentration suppressing portions 76 and 76 are formed in a substantially oval shape in a front view that is elongated in the direction along the respective guide stitching portions 73 to 75. For this reason, each stitching end exhibits an arc shape.

  If the guide stitching portion 73 is described as an example, the stress concentration suppressing portion 76 is sewn in a semicircular arc shape in a direction away from the vent hole cover 60 from the main stitching portion 73a of the guide stitching portion 73. An arc portion 76a, a first straight portion 76b that is sewn linearly from the first arc portion 76a, and a second that is sewn in a semicircular arc shape toward the direction approaching the vent hole cover 60 from the first straight portion 76b. It comprises an arc portion 76c and a second straight portion 76d which is sewn linearly from the second arc portion 76c and along the main stitching portion 73a.

  The stress concentration suppressing portion 76 formed in the guide suturing portions 74 and 75 also has the same stitching configuration as the stress concentration suppressing portion 76 of the guide suturing portion 73, and the guide suturing portions 74 and 75 are each a main stitching portion 74a. , 75a.

  9A, an airbag bag body 300 of a comparative example is shown. The airbag bag body 300 is provided with a vent hole cover 301 that covers the vent hole 309, and a cover guide that guides the vent hole cover 301. A member 302 is provided, and the cover guide member 302 is stitched to a base fabric (not shown) of the airbag bag body 300 by first to third guide stitching portions 303 to 305.

  Since the first to third guide stitching portions 303 to 305 are formed in a straight line, when the vent hole cover 301 moves relative to the cover guide member 302 due to gas from an inflator (not shown), for example, Shear stress acts on the stitching end portion 306 of the first guide stitching portion 303 and the stitching end portions 307 and 307 of the third guide stitching portion 305, and the cover guide member 302 is peeled from the base fabric of the airbag bag body 300. There is a fear. Further, the stitching end portion 306 of the first guide stitching portion 303 and the stitching end portions 307 and 307 of the third guide stitching portion 305 are in contact with the cover guide member 302 in a manner similar to point contact. The force that the vent hole cover 301 bites into the guide member 302 may act, and the smooth movement of the vent hole cover 301 may be hindered.

  9B, in the airbag bag body 30 of the embodiment, as shown in FIGS. 2 and 3, the vent bag 34 is configured so as to be inflatable by the gas of the inflator 20, and prevents an increase in internal pressure. The airbag bag body 30 includes a vent hole cover 60 that covers the vent hole 34 and a cover guide member (guide member) 70 that regulates or guides the movement of the vent hole cover 60. With.

  In the airbag bag body 30, the cover guide member 70 is connected to the first base fabric 31 of the airbag bag body 30 by stitching, and a plurality of stresses that suppress concentration of stress on the stitched end of the cover guide member 70 are suppressed. Since the concentration suppressing portion 76 is formed, it is possible to prevent the cover guide member 70 from peeling from the first base cloth 31 of the airbag bag body 30.

  Further, since the stress concentration suppressing portion 76 is formed in an arc shape in the airbag body 30, the interference between the cover guide member 70 and the vent hole cover 60 can be prevented, and the vent hole cover 60 can be smoothly moved. Can be realized.

  As shown in FIG. 7, when the airbag bag 30 is viewed from the front, the stress concentration suppressing portions 76 and 76 are in the following relationship with respect to the guide stitching portions 73 to 75. That is, the stress concentration suppressing portions 76 and 76 of the first guide stitching portion 73 are formed on the first guide stitching portion 73. The stress concentration suppressing portions 76 and 76 of the second and third guide stitching portions 74 and 75 are formed below the second and third guide stitching portions 74 and 75.

  As described above, the stress concentration suppressing portions 76 and 76 are provided at the respective suture ends of the guide stitching portions 73 to 75. When the vent hole cover 60 moves between the first and second guide stitching portions 73 and 74, or when the vent hole cover 60 moves between the first and third guide stitching portions 73 and 75, the vent hole The edge of the cover 60 moves while rubbing the stress concentration suppressing portions 76 and 76. Since these stress concentration suppressing portions 76 and 76 are formed in an arc shape, the stress is suppressed from concentrating on this portion. For this reason, there is no fear that each stitching end in the guide stitching portions 73 to 75 is rubbed against the vent hole cover 60 and peeled off. Further, the vent hole cover 60 and the cover guide member (guide member) 70 do not interfere with each other. Therefore, the vent hole cover 60 can move smoothly.

  The length from the reference line SL1 to the distal end 72a of the guide portion 72 is set shorter than the length from the reference line SL1 to the distal end portion 64a of the strip-like portion 64. However, the length from the reference line SL1 to the distal end 72a of the guide portion 72 is set to be longer than the length from the distal end 72a to the distal end portion 64a of the strip-shaped portion 64. Therefore, it is assumed that the breaking stitches 51 to 53 break and the tip 64a is unconstrained, and the band 64 is folded back to the back side of the guide part 72 while the band 64 moves to the reference line SL1 side. However, the vent hole 34 is not blocked by the tip 64a.

  Furthermore, the left and right tips 72a, 72a of the guide portion 72 are formed in an inclined shape that is inclined with respect to the reference line SL1 (inclined with respect to the orthogonal portion 63 of the vent hole cover 60). Therefore, even when the belt-like portion 64 of the vent hole cover 60 is moved to the reference line SL1 side, even if the belt-like portion 64 is folded back to the back side of the guide portion 72, the belt-like portion 64 is folded obliquely along the inclined tip 72a. become. For this reason, the folded state of the band-like portion 64 can be solved very easily. The belt-like portion 64 can move smoothly in the guide portion 72.

  Furthermore, the guide part 72 has an opening 77 located at the hole center HP. That is, the guide portion 72 has an opening 77 at a portion corresponding to the vent hole 34. The opening 77 is a circular hole that is substantially the same type as the vent hole 34.

Next, the operation of the airbag device 13 will be described.
When collision energy of a predetermined level or more acts on the vehicle 10 (see FIG. 1), the inflator 20 shown in FIG. 3 receives the ignition signal and ignites the gas generating agent, thereby generating gas, and the airbag bag body. 30. The airbag bag body 30 housed in a folded state on the steering wheel 12 (see FIG. 1) starts to inflate with gas. In the process of inflating the airbag bag body 30, a cover (not shown) attached to the steering wheel 12 is broken from the tear line to form an opening for the airbag bag body 30 to expand and deploy. As a result, the airbag bag body 30 starts to be deployed in the vehicle interior.

  As shown in FIGS. 2 and 3, the airbag bag body 30 has the first and second base fabrics 31 and 41 integrally stitched together by three breaking suture portions 51 to 53. For this reason, the inflation volume of the airbag body 30 is regulated at the initial stage of deployment, and the membrane pressure distribution quickly reaches a uniform membrane pressure distribution within the regulated volume between the center and the breaking suture portions 51 to 53. At this time, when the occupant is present at a position close to the steering wheel 12 and starts to contact, the rupture of the breaking suture portions 51 to 53 progresses with the increase of the internal pressure, thereby suppressing the amount of increase in the internal pressure and softly occupant. Can be restrained.

  Even when there is no contact with the occupant, the three breaking suture portions 51 to 53 move from the stitching start point 54 to the stitching end point according to the increase in the bag internal pressure in the airbag bag body 30 due to gas inflow from the inflator 20. It is sequentially broken toward 55. For this reason, the airbag body 30 gradually expands its volume while maintaining an appropriate bag internal pressure, and is deployed so as to have a predetermined shape.

  By the way, as shown in FIG. 7, the distal end portions 64 a and 64 a of the left and right belt-like portions 64 and 64 in the vent hole cover 60 are formed by first and second base fabrics 31 and 41 by the breaking suture portions 51 to 53. Is sewn to. For this reason, the front end portions 64 a and 64 a are restrained by the first and second base fabrics 31 and 41 until the breaking portions 51 to 53 are broken. Since the vent hole 34 is closed by the vent hole cover 60, the gas in the airbag bag body 30 is prevented from escaping to the outside. As a result, the gas pressure in the airbag bag body 30 rises quickly, and the gas pressure is appropriately maintained. The gas pressure in the airbag bag body 30 acts on the central portion of the orthogonal portion 63 of the vent hole cover 60 through the opening 77 of the cover guide member 70.

  Thereafter, when all of the breaking suture portions 51 to 53 are broken at the end of deployment of the airbag body 30, the restraints of the end portions 64a and 64a of the belt-like portions 64 and 64 are released. The central part of the orthogonal part 63 of the vent hole cover 60 is pushed out from the vent hole 34. As it is pushed out, the left and right belt-like parts 64, 64 are guided by the guide part 72 (guided by the guide stitching parts 73 to 75) and move toward the vent hole 34. As a result, the vent hole 34 is opened. Thus, even after the relaxation of the pressure increase by each breaking suture portion is completed, the excess gas in the airbag bag body 30 is discharged from the vent hole 34, so that the airbag bag body 30 has a maximum shape. After that, excessive increase in the bag internal pressure of the airbag bag body 30 is prevented.

  10 and 11 show an airbag device 113 that employs the airbag bag body 130 of the second embodiment. The same parts as those used in the airbag device 13 and the airbag bag body 30 shown in FIGS. 1 to 9 are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 10, the airbag device 113 includes an inflator 20, a retainer 22 disposed integrally with the steering wheel 12 (see FIG. 1), a fixing ring 23, and an airbag bag body 130. . The inflator 20 has a mounting flange 21.

  The airbag bag body 130 includes a first base cloth 31 and a second base cloth 41 each having a circular shape. Further, the airbag bag body 130 includes a vent hole cover 60, a cover guide member 70, and first, second, and third reinforcing sheets 81, 140, and 83.

  The second reinforcing sheet 140 is a reinforcing member that reinforces the inflator insertion hole 32 and reinforces the vent hole 34. Further, it is also a member that guides so that the orthogonal portion 63 of the vent hole cover 60 does not shift when it moves in the direction of the reference line SL1. That is, it is formed in substantially the same shape as the cover guide member (guide member) 70.

  Similar to the cover guide member 70, the second reinforcing sheet (reinforcing member) 140 is formed in a substantially T-shape when viewed from the front, and includes an annular base portion 141 and a lateral belt-shaped guide portion 142. The second reinforcing sheet 140 is symmetrical with respect to the reference line SL1.

The second reinforcing sheet (reinforcing member) 140 is stitched together with the guide portion 142 to the first base cloth 31.
Specifically, in the second reinforcing sheet 140, the guide portions 141 and 142 extend from the outer peripheral portion of the base portion 141 to the left and right with respect to the reference line SL1 along the back surface of the first base fabric 31. The guide portions 141 and 142 are horizontal band-shaped portions having a predetermined width. The second reinforcing sheet 140 is superimposed on the first base cloth 31 from above the orthogonal part 63 of the vent hole cover 60, and is guided by the first, second, and third stitching parts 143 to 145. The cover guide member 70 and the first base fabric 31 are integrally stitched together. The movement (sliding) of the orthogonal part 63 of the vent hole cover 60 is guided and the movement direction of the orthogonal part 63 is regulated by the three guide sewing parts 143 to 145 (guide sewing parts 143 to 145). The The left and right ends 142a, 142a of the second reinforcing sheet 140 are opened without being sewn and extended to the vicinity of the breaking suture portions 51-53.

Further, the second reinforcing sheet (reinforcing member) 140 has an opening 147 located at the hole center HP. That is, the second reinforcing sheet 140 has an opening 147 at a portion corresponding to the vent hole 34. The opening 147 is a circular hole that is substantially the same type as the vent hole 34.
The second reinforcing sheet 140 has a through hole having substantially the same diameter as the inflator insertion hole 32 and a plurality of bolt holes having substantially the same diameter as the bolt hole 33.

The second reinforcing sheet 140 is made of the same material and the same thickness as the first and second base cloths 31 and 41, the vent hole cover 60, the cover guide member 70, and the first and third reinforcing sheets 81 and 83. (Panel having flexibility). This cloth has mutually different friction characteristics (friction resistance) on the front surface (one surface) and the back surface (the other surface). For example, the friction characteristics are different between the front and back surfaces by applying a silicon coating only to one side of the cloth. The first base cloth 31, the second base cloth 41, the vent hole cover 60, and the cover guide member 70 are arranged so that the front and back surfaces of the first base cloth 31, the second base cloth 41, and the cover guide member 70 face each other alternately.
The front and back of the second reinforcing sheet 140 are arranged in the same direction as the first base fabric 31.

  As shown in FIG. 11, the guide suture portions 143 to 145 have stress concentration suppressing portions 146 and 146 at the suture ends on both sides, respectively. The stress concentration suppressing portions 146 and 146 on both sides are portions (sewed) where the guide stitching portions 143 to 145 are stitched in a curved shape (R shape) in a direction away from the belt-like portions 64 and 64 of the vent hole cover 60 at each stitching end. Part). Further, the stress concentration suppressing portions 146 and 146 are provided in a region where the guide member 70 and the reinforcing member 140 overlap.

  In the airbag bag body 130, the stress concentration suppressing portion 146 is formed of a stitched portion formed in a curved shape in a direction away from the belt-like portion 64 of the vent hole cover 60, so that the vent hole cover 60 is not caught from the vent hole 34. It can be discharged smoothly. Further, since the stress concentration suppressing portion 146 is a stitched portion formed in a curved shape in a direction away from the belt-like portion 64 of the vent hole cover 60, mass production equipment is not limited, and mass production is possible even with general sewing equipment. .

  The airbag bag body 130 includes a reinforcing member 140 that is formed in substantially the same shape as the guide member 70 and reinforces the vent hole 34, and a stress concentration suppressing portion 146 is provided in a region where the guide member 70 and the reinforcing member 140 overlap. Therefore, further reinforcement of the vent hole 34 portion can be strengthened, and stress relaxation of the vent hole 34 portion can be achieved.

  In the airbag bag according to the present invention, as shown in FIGS. 8A and 8B, the stress concentration suppressing portion 76 includes a first arc portion 76a, a first straight portion 76b, and a second arc. Although it is formed in an oval shape composed of the portion 76c and the second straight portion 76d, the present invention is not limited to this, and it may include sewing where the sewing end portion including an ellipse, an arc, or a curve is rounded. Good.

  In the airbag bag body 130 according to the second embodiment of the present invention, as illustrated in FIG. 10, the second reinforcing sheet (reinforcing member) 140 is formed in substantially the same shape as the cover guide member (guide member) 70. However, the present invention is not limited to this, and the third reinforcing sheet 83 may have substantially the same shape as the cover guide member 70. Further, both the second and third reinforcing sheets 140 and 83 may be the same as the cover guide member 70. The substantially same shape may be used.

  The present invention is suitable for application to an automobile including an airbag bag body that regulates gas outflow by covering a vent hole with a vent hole cover.

  DESCRIPTION OF SYMBOLS 13,113 ... Vehicle airbag apparatus, 20 ... Inflator, 30, 130 ... Air bag body, 31, 41 ... 1st, 2nd base fabric, 34 ... Vent hole, 60 ... Vent hole cover, 70 ... Guide Member (cover guide member), 76, 146 ... Stress concentration suppressing portion, 140 ... Reinforcing member (second reinforcing sheet).

Claims (1)

An airbag bag body configured to be inflatable by inflator gas and having a vent hole for preventing an increase in internal pressure,
The airbag body includes a vent hole cover that covers the vent hole, a guide member that restricts the movement of the vent hole cover, and a reinforcing member that is formed in substantially the same shape as the guide member and reinforces the vent hole. Prepared,
The guide member is connected to the base fabric of the airbag bag body by stitching, and a stress concentration suppressing portion that suppresses stress concentration on the stitching end of the guide member is formed ,
The stress concentration suppressing portion includes a stitched portion formed in an arc shape, and is provided in a region where the guide member and the reinforcing member overlap each other .

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