JP2011025916A - Inflator structure of airbag for vehicle, airbag module and airbag structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inflator structure of an airbag for a vehicle, sufficient in a narrow space for an airbag arranging part offered to install an inflator, capable of attaining compactness, and capable of reducing installation manhours. <P>SOLUTION: This airbag for the vehicle has an installation bracket 6 installed in and fixed to a mount part 4 arranged in a boss part 2 of a steering wheel 1, and a housing 7 arranged on the installation bracket by internally storing the airbag 8 and the disk-shaped inflator 9 installed in the airbag. In the inflator, an installation bolt 10 is directly joined in arrangement to be stored in the external shape contour of the inflator to an installation surface 9a facing the installation bracket via the housing, and the installation bolt is fastened to the installation bracket by penetrating through the housing. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  INDUSTRIAL APPLICABILITY The present invention provides an inflator structure for an air bag for a vehicle, in which an air bag installation portion used for mounting an inflator suffices in a narrow space, can achieve downsizing, and can reduce mounting man-hours, and an air bag The present invention relates to a module and an airbag structure.

  In addition, the present invention can assemble a vehicle airbag by eliminating a retainer with a bolt, and can reduce the weight and securely and firmly fix the airbag to the airbag installation portion. The present invention relates to an inflator structure, an air bag module, and an air bag structure of a vehicle air bag that can achieve simplification of the air bag structure, increase in productivity, and cost reduction, and contribute to ecology and resource saving.

  As a structure for attaching an airbag to a vehicle, for example, Patent Literature 1 and Patent Literature 2 are known. The “steering device” of Patent Document 1 is a steering device mounted on a vehicle, in which a disk-shaped inflator is attached to a retainer, and the retainer is attached and fixed on a mandrel.

  The “airbag device” of Patent Document 2 is an airbag device in which an airbag module having an airbag main body and an inflator is attached to reinforcement via a fixture, and the fixture includes the airbag module. A storage case, a bracket having legs for supporting and fixing the airbag module and the storage case, and a protruding member protruding from the bottom of the storage case. Further, the leg portion of the bracket has an inclined portion, and the protruding member presses the inclined portion of the leg portion when the housing case receives an impact and deforms the bracket. It is comprised so that a deformation | transformation may be assisted.

JP 2005-313713 A JP 2008-110737 A

  Conventionally, generally, a disk-shaped inflator is attached to a metal core of a steering wheel using a retainer that accommodates an airbag or a separate bracket as disclosed in Patent Document 1. A mounting space for mounting the inflator is set on the retainer and the bracket, and mounting means such as mounting bolts for mounting on the steering wheel are arranged around the mounting space. Accordingly, there is a problem that the retainer and the bracket itself become larger than the outer dimensions of the inflator, and the core metal portion of the steering wheel to which these are attached must be set in a wide space.

  Further, regarding the mounting man-hours, it is necessary to attach the inflator to the retainer or the like and then attach the retainer or the like to the core metal, which is complicated.

  The problem is not limited to the airbag module installed on the steering wheel, but is the same for airbag devices installed in other locations such as a passenger seat airbag device.

  In Patent Document 2, the inflator has a mounting flange. The flange is coupled to the retainer, the airbag body, the housing case for housing the airbag, and the bracket with a nut using a bolt of a frame-like retainer housed in the airbag body. A fixing portion is provided in the reinforcement which is a vehicle side fixing portion, and an inflator, an airbag main body, and the like are fixed to the fixing portion via a bracket.

  In the inflator, an upper hemisphere portion surrounded by the retainer is accommodated inside the airbag body, and a lower hemisphere portion protrudes from the opening portion of the airbag body and the accommodation case and is exposed to the outside.

  The inflator generates inflator gas by rapid combustion of explosives. The inflator generates an impact by a rapid combustion action. Therefore, the inflator needs to be firmly supported and fixed to the reinforcement. In order to firmly support and fix the inflator with the reinforcement, the retainer bolt passed through the flange of the inflator has secured the connection with the reinforcement side. For this reason, in the structure of patent document 2, the retainer with a volt | bolt was essential. Since a retainer with a bolt is necessary, there is a problem that the weight increases.

  The airbag body has a large opening through which the lower hemisphere of the inflator is exposed. The retainer presses the flange of the inflator and the periphery of the opening of the airbag body toward the housing case to reinforce the opening. However, the retainer is such that the outer peripheral edge of the opening is pressed in an annular shape, the pressing area is small, and the periphery of the opening of the airbag body cannot be sufficiently reinforced. Further, since the retainer has a frame shape surrounding the inflator, its strength is insufficient, and the retainer is easily deformed by an impact caused by a rapid combustion action in the inflator and an inflation pressure of the airbag body.

  In short, the reinforcement around the opening by the retainer is not sufficient because the area for pressing the airbag body is small and easily deforms. For this reason, in order to reinforce the reinforcement around the opening of the airbag body, it is necessary to firmly reinforce the periphery of the opening with the airbag body itself, for example, by laminating and sewing a large number of pieces of cloth around the opening. It was. This reinforcement complicates the structure of the airbag body, which takes time to manufacture the airbag body and increases the cost of the product.

  INDUSTRIAL APPLICABILITY The present invention provides an inflator structure for an air bag for a vehicle, in which an air bag installation portion used for mounting an inflator suffices in a narrow space, can achieve downsizing, and can reduce mounting man-hours, and an air bag An object is to provide a module and an airbag structure.

  In addition, the present invention can assemble a vehicle airbag by eliminating a retainer with a bolt, and can reduce the weight and fix the airbag cushion to the vehicle side fixing portion in a sound and strong manner. A vehicle airbag inflator structure, an airbag module, and an airbag structure that can achieve simplification of the structure of the airbag cushion, improvement of productivity, and cost reduction, and contribute to ecology and resource saving. For the purpose.

  An inflator structure for a vehicle airbag according to the present invention includes an attachment bracket that is attached and fixed to an airbag installation portion of a vehicle, an airbag and a disk-shaped inflator attached to the airbag, and the attachment bracket. A vehicle air bag having a housing mounted thereon, wherein the inflator is mounted on a mounting surface facing the mounting bracket via the housing, and the mounting bolt is disposed within an outer contour of the inflator. Are directly joined, and the mounting bolt penetrates the housing and is fastened to the mounting bracket.

  A vehicle airbag module according to the present invention is a vehicle airbag module that includes an airbag and a disk-shaped inflator that is accommodated in the airbag and that expands and inflates the airbag. A mounting surface facing a mounting bracket that is mounted and fixed to the airbag installation portion of the vehicle, and is directly joined to the mounting surface so as to fit within the outer contour of the inflator, and the airbag is mounted together with the inflator. A mounting bolt that can be fastened to the bracket is provided.

  It is preferable to provide an ignition device connection terminal adjacent to the mounting bolt on the mounting surface of the inflator.

  Two mounting bolts are provided, and the mounting position of each mounting bolt is set such that a straight line connecting the positions of the center lines of the mounting bolts passes through the center position of the inflator on the mounting surface of the inflator. It is desirable.

  It is preferable that a straight line connecting the positions of the center lines of the mounting bolts is set in the left-right direction of the vehicle.

  Three or more mounting bolts are provided, and the mounting position of each mounting bolt is drawn on the mounting surface of the inflator by connecting the positions of the center lines of the mounting bolts in the circumferential direction along the outer contour of the inflator. It is desirable that the square barycentric position is set so as to coincide with the center position of the inflator.

  In the mounting surface of the inflator, it is preferable that the number of installations on the front side of the vehicle does not fall below the number of installations on the rear side of the vehicle.

  A vehicle airbag structure according to the present invention is a vehicle airbag structure in which the vehicle airbag module is installed in an airbag installation part of a vehicle, and the airbag installation part is fixed so as to face each other. And a slope portion, and at least the slope portion is inclined toward the fixing portion to form a mount region that gradually narrows between the fixing portion and the vehicle airbag module. A mounting portion facing the fixing portion is formed on the mounting bracket fastened with a mounting bolt, and a sliding portion that is slidably engaged with the slope portion and a fixing portion that faces the fixing portion are formed, and the mounting portion of the mounting bracket is connected to the airbag installation portion. The fixing portion is coupled to the fixing portion by a fastening member that pulls the attachment portion toward the fixing portion through the slide portion by a fastening action.

  And a cover that is attached to the vehicle and covers the airbag installation portion, and a housing that houses the airbag and is installed on the mounting bracket. The housing has an opening toward the cover. An opening edge is formed, the opening edge of the housing and the cover are connected by a connecting bracket, and the housing has a flexibility that can be deformed according to the dimension between the mounting bracket and the cover. It is preferable to have.

  In the present invention, the air bag installation portion used for attaching the inflator is sufficient in a narrow space, so that compactness can be achieved and the number of attachment steps can be reduced.

  In the present invention, the retainer with the bolt can be eliminated to assemble the vehicle airbag, the weight can be reduced, and the airbag cushion can be securely and firmly fixed to the vehicle side fixing portion. The structure of the airbag cushion can be simplified, the productivity can be improved, and the cost can be reduced, contributing to ecology and resource saving.

It is a disassembled perspective view which shows suitable one Embodiment of this invention. It is the structure of FIG. 1, Comprising: It is a sectional side view which shows the condition before attaching and fixing a mounting bracket. It is the structure of FIG. 1, Comprising: It is a sectional side view which shows the condition after attaching and fixing a mounting bracket. It is a perspective view which shows the mounting state of the mount part applied to the structure of FIG. 1, and a mounting bracket. FIG. 2 is a partial cross-sectional view showing the structure of FIG. 1 and an attachment structure between a cover and a bush. It is a bottom view which shows the attachment surface of the inflator main body in the structure of FIG. It is a sectional side view which shows the structure around the inflator applied to the structure of FIG. It is explanatory drawing explaining the joining state of the inflator main body and attachment bolt of FIG. It is explanatory drawing explaining the modification of the structure shown in FIG. It is explanatory drawing explaining the modification of the installation state of an inflator.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. As shown in FIGS. 1 and 2, the present embodiment will be described taking an example in which the present embodiment is applied to a steering wheel 1. The metal core of the steering wheel 1 that is a component of the vehicle is formed mainly of a metal material. The steering wheel 1 has a boss 2 at the center. The boss 2 is connected to the steering shaft.

  The steering wheel 1 is usually provided with a cover 3 made of synthetic resin or the like that serves as a horn button. The cover 3 is arranged in the rim 1a of the steering wheel 1 so as to cover the boss portion 2 in an arrangement continuous with the design surface 1c of the spoke 1b (see FIG. 5). The outer shape of the cover 3 is formed so as to be continuous with the outer shape of the design surface 1c of the rim 1a and the spoke 1b.

  A mount portion 4 is formed on the boss portion 2, and a metal plate-like mounting bracket 6 is attached and fixed to the mount portion 4. In this embodiment, the mount part 4 is provided in the boss | hub part 2 of the steering wheel 1, and the airbag installation part is comprised. The mounting structure of the mounting bracket 6 to the mount portion 4 will be described in detail later.

  The mounting bracket 6 is provided with a housing 7 on the upper surface facing the cover 3 side. The housing 7 is formed with an opening edge portion 7a that opens toward the cover 3, whereby the housing 7 is formed in a container shape. Inside the housing 7, a folded airbag 8 and an inflator 9 attached to the airbag 8 are accommodated.

  As shown in FIGS. 7 and 8, the inflator 9 includes an inflator body 9 a and a mounting bolt 10. The inflator body 9a that ejects the inflator gas is formed in a disk shape having a circular or polygonal planar outer contour and a low height. A plurality of gas ejection holes 24 are formed laterally along the circumferential direction on the peripheral side surface of the inflator body 9a.

  The inside of the inflator body 9a is filled with explosives that are rapidly burned when inflator gas is generated. As is well known, the outer shell of the inflator body 9a is formed with a considerable strength that is not destroyed or scattered by the pressure of the explosive combustion action or the pressure of the inflator gas generated thereby. That is, the outer shell of the inflator body 9a is formed as a pressure vessel (pressure vessel) from a thick metal material.

  The inflator main body 9a provided with the pressure vessel is accommodated inside the airbag 8 that is expanded and inflated with inflator gas. The airbag 8 is made of a fabric and formed in a bag shape as is well known in the art. The inflator body 9a is built in the bag-like airbag 8.

  The inflator body 9a has a mounting surface (bottom surface) 9b formed as a flat surface. The mounting surface 9b of the inflator body 9a faces the mounting bracket 6 that is mounted and fixed to the airbag installation portion via the airbag 8 and the housing 7. The mounting bolt 10 is directly joined to the mounting surface 9b of the inflator body 9a directly by welding or the like. One end of the mounting bolt 10 is joined to the mounting surface 9b of the inflator body 9a, and protrudes downward from the mounting surface 9b so as to be fastened to the mounting bracket 6. The mounting bolt 10 is provided in an arrangement that fits within the planar outer contour of the inflator body 9a. In the illustrated example, two mounting bolts 10 are provided side by side, but the number of mounting bolts 10 is not limited to two.

  When there are two mounting bolts 10, the center line BC in the bolt axial direction of each mounting bolt 10 is directed to the mounting surface 9b of the inflator body 9a. On the attachment surface 9b of the inflator body 9a, a straight line L connecting the positions where the center lines BC of the two attachment bolts 10 intersect the attachment surface 9b (hereinafter referred to as “intersection position”) is the attachment surface 9b of the inflator body 9a. The joint position of the mounting bolt 10 is set so as to pass through the center C. The straight line L connecting the intersection points is set in the left-right direction of the vehicle (vehicle width direction) in the case of a passenger seat airbag, and in the front-rear direction of the vehicle (length of the vehicle) in the case of a driver seat airbag. Is set to the vertical direction).

  As shown in FIG. 6, an ignition device connection terminal 23 for connecting a harness 12 for inputting an ignition signal to the inflator 9 is provided on the mounting surface 9 b of the inflator body 9 a so as to be adjacent to the mounting bolt 10. In the illustrated example, the connection terminal 23 is disposed between the two mounting bolts 10. Thus, when there are a plurality of mounting bolts 10, the connection terminal 23 is provided at a position surrounded by the mounting bolts 10. Specifically, the connection terminal 23 is disposed at the center of the mounting surface 9b, and the mounting bolt 10 is disposed on the outer peripheral side of the mounting surface 9b surrounding the center.

  By setting the mounting bolt 10 position on the outer peripheral edge side of the mounting surface 9b, the inflator main body 9a is stably fixed to the mounting bracket 6, and the connection terminal 23 is installed at the center of the mounting surface 9b, so that the harness Twelve connection work locations are integrated, and the connection terminals 23 are arranged in a space-saving manner.

  Further, the center of the attachment surface 9b of the inflator body 9a is set to coincide with the vicinity of the center of the boss portion 2. Thereby, the inflator main body 9a which generate | occur | produces inflator gas can be appropriately supported by a steering shaft via the boss | hub part 2, and the operation stability of the airbag 8 is improved.

  As shown in FIG. 7, two bolt insertion holes 8 a are formed in the airbag 8 so that the two attachment bolts 10 joined to the inflator main body 9 a housed in the airbag 8 protrude outward from the airbag 8. These bolt insertion holes 8 a are formed with a hole diameter slightly larger than the outer diameter of the mounting bolt 10 so that the mounting bolt 10 can be inserted. The airbag 8 is provided with a reinforcing structure that reinforces the bolt insertion hole 8a that is the only missing portion.

  As the reinforcing structure, for example, one to several reinforcing cloths 25 having bolt through holes 25a through which the mounting bolts 10 are passed, the bolt through holes 25a around the bolt through holes 8a of the airbag 8, and the bolt through holes 8a. In accordance with the above, it is joined by sewing or the like. The reinforcing cloth 25 may be used as one set for each mounting bolt 10, or two sets may be used. Alternatively, the reinforcing cloth 25 may be formed with a large external dimension extending over both of the two mounting bolts 10 and used as one set. Good.

  The airbag 8 incorporating the inflator main body 9a is accommodated in the housing 7 as described above. The flat bottom surface 7c of the housing 7 is formed with a bolt hole 7b of the mounting bolt 10 protruding from the airbag 8, and the mounting bolt 10 is passed through the bolt hole 7b. At this time, the attachment surface 9 b of the inflator body 9 a is pressed against the bottom surface 7 c of the housing 7 through the airbag 8.

  The housing 7 is installed on the mounting bracket 6. Bolt holes 6a (see FIGS. 1 and 4) through which the mounting bolts 10 are inserted are formed in the mounting bracket 6, and the mounting bolts 10 are inserted through the bolt holes 6a. A nut 11 is screwed into the mounting bolt 10 inserted through the bolt hole 6a. By screwing the nut 11 into the mounting bolt 10, the housing 7 is fastened and fixed to the mounting bracket 6, and the airbag 8 accommodated in the housing 7 is fastened and fixed together with the inflator body 9 a inside.

  The inflator body 9 a may be fixed to the housing 7 by fastening the mounting bolt 10 to the housing 7 with the nut 11. In this case, the housing 7 is separately joined to the mounting bracket 6.

  In any case, the inflator body 9 a is fixed to the mounting bracket 6 or the housing 7 by the fastening action of the mounting bolt 10. Due to the tension T generated in the mounting bolt 10 by this fastening action, the mounting surface 9b of the inflator body 9a presses and fixes the airbag 8 to the mounting bracket 6 or the bottom surface 7c of the housing 7.

  A plurality of holes 13 are formed in the opening edge portion 7 a of the housing 7 along the circumferential direction for attachment to the cover 3. A plurality of locking holes 14 are formed in the cover 3 according to the positions of the holes 13 of the housing 7. Between the cover 3 and the housing 7, a metal connection bracket 15 is provided to connect the housing 7 to the cover 3. In the present embodiment, the connection bracket 15 is formed in a ring shape along the opening edge portion 7 a of the housing 7.

  A plurality of hooks 15 a are formed in the connection bracket 15 in accordance with the positions of the locking holes 14 and the holes 13. Each hook 15 a of the connection bracket 15 is inserted into each hole 13 of the opening edge 7 a of the housing 7, and each hook 15 a inserted through each hole 13 is locked to each locking hole 14 of the cover 3. Thus, the opening edge 7 a of the housing 7 is connected to the cover 3 via the connection bracket 15.

  The housing 7 is configured to have flexibility that can be deformed in accordance with the dimension between the mounting bracket 6 and the connecting bracket 15, and the dimension between the mounting bracket 6 and the cover 3. For example, the housing 7 is provided with flexibility as follows.

  First, the housing 7 is made of, for example, a cloth woven from synthetic fibers, etc., and at least the height dimension from the mounting bracket 6 to the cover 3 is more flexible and flexible than that dimension. It is set to the given dimension. Secondly, the housing 7 can be extended and contracted between the mounting bracket 6 and the cover 3, and the height dimension extending from the mounting bracket 6 to the cover 3 is more flexible and flexible. A bellows portion is formed. In this case, the housing 7 may be formed of a thin metal material or a synthetic resin material in addition to the cloth. Thirdly, the housing 7 is formed of an elastic material having elasticity. Fourth, the housing 7 is formed of a spreadable material. In any of these, the housing 7 absorbs the variation in dimensions between the mounting bracket 6 and the cover 3.

  The mounting structure of the mounting bracket 6 to the mounting portion 4 will be described. As shown in FIGS. 2 to 4, the mounting portions 4 face each other and face the mounting bracket 6 and the cover 3 from the boss portion 2 side. The fixing portion 4a and the slope portion 4b that are formed by being raised are integrally formed. In the present embodiment, one fixing portion 4a is arranged at the position of the 6 o'clock direction on the steering wheel 1, and two slope portions are parallel to each other at the position of the 3 o'clock direction and the 9 o'clock direction. 4b is arranged. The slope portion 4b and the fixing portion 4a are formed in a narrow plate shape. Each slope part 4b is provided via the vertical wall part 4d with respect to the baseplate part 4c.

  These slope portions 4b are formed above the boss portion 2 so as to be inclined toward the fixing portion 4a in order to form a mount region M gradually narrowing from the cover 3 side toward the boss portion 2 side. The fixing portion 4a is also formed above the boss portion 2 so as to be inclined toward the slope portion 4b in order to form a mount region M that gradually narrows from the cover 3 side toward the boss portion 2 side. Therefore, on the boss portion 2 of the steering wheel 1, a mount portion 4 forms a U-shaped or V-shaped mounting region M that narrows downward as viewed from the 3 o'clock or 9 o'clock direction. Is done.

  In the present embodiment, the mount portion 4 is configured by integrally forming one fixing portion 4a and two slope portions 4b formed in a plate shape on the bottom plate portion 4c. However, it goes without saying that the mount portion 4 may be formed in the shape of a mortar having the fixing portion 4a and the slope portion 4b as “surfaces”.

  The mounting bracket 6 includes a slide portion 6b that is slidably engaged with the slope portion 4b of the mount portion 4, a mounting portion 6c that faces the fixing portion 4a, and a connecting portion 6d that connects the mounting portion 6c and the slide portion 6b. Is integrally formed. The lower surface of the slide portion 6b facing the slope portion 4b is formed along the slope of the slope portion 4b so as to be slidable with respect to the upper surface of the slope portion 4b. Further, the mounting portion 6c facing the fixing portion 4a of the mount portion 4 is formed along the inclination of the fixing portion 4a so as to be in close contact with the fixing portion 4a. Accordingly, the mounting bracket 6 is also formed in a U shape or a V shape along the form of the mount portion 4 when viewed from the 3 o'clock direction or the 9 o'clock direction.

  In the present embodiment, the slide portion 6b is formed with a grip portion 16 that grips the slope portion 4b in order to slidably engage the slide portion 6b with the slope portion 4b. The grip portion 16 is formed by integrally forming a U-shaped piece surrounding the slope portion 4b on the lower surface of the slide portion 6b that slides on the slope portion 4b. The means for slidably engaging the slide portion 6b with the slope portion 4b is not limited to the grip portion 16, and a dovetail slide groove formed along the slide direction on each of the slope portion 4b and the slide portion 6b and the slide. It may be a slide ridge that engages with the groove.

  Fastening members are provided on the attachment portion 6c of the attachment bracket 6 and the fixing portion 4a of the mount portion 4 to connect them. In the present embodiment, the fastening member is constituted by a bolt 17 inserted through the attachment portion 6c and the fixing portion 4a. A bolt insertion hole is formed in the attachment portion 6c, and a slot 18 is formed in the fixing portion 4a along the inclination direction of the slope portion 4b in order to insert the bolt 17 in an adjustable manner. A nut 19 is fastened from the lower surface side of the fixing portion 4a to the bolt insertion hole of the attachment portion 6c and the fixing portion 4a and the bolt 17 inserted into the slot 18, thereby connecting the fixing portion 4a and the attachment portion 6c.

  When fastening with the bolt 17, this fastening action causes the entire mounting bracket 6 to slide relative to the slope portion 4b via the slide portion 6b, and the mounting portion 6c is pulled toward the fixing portion 4a. By this pulling action, the slide portion 6b is deeply engaged with the slope portion 4b, and the attachment portion 6c is coupled to the fixing portion 4a by the bolt 17, whereby the attachment bracket 6 is firmly attached and fixed to the mount portion 4. Is done.

  The mounting bracket 6 is supported at three points on the mount portion 4 by one fixing portion 4a and two slope portions 4b and is stably fixed. Further, the mounting bracket 6 and the mount portion 4 are fixed only by the fastening operation of the single bolt 17. In the present embodiment, the bolt 17 is exemplified as the fastening member. However, any type of fastening member may be used as long as the mounting bracket 6 can be pulled and coupled to the mount portion 4.

  As described above, the cover 3 is attached to the mount portion 4 by the mounting bracket 6 via the housing 7 and the connection bracket 15, and can be pressed by the steering wheel 1 via an elastic member as shown in FIG. 5. Floating supported. In this embodiment, the coil spring 21 is illustrated as an elastic member.

  A bush 20 is provided in the vicinity of each spoke 1 b of the steering wheel 1. For example, the bush 20 is provided at three locations in the circumferential direction of the steering wheel 1. The coil spring 21 is provided between the bush 20 and the cover 3. A rod-shaped locking piece 22 projects from the cover 3 in accordance with the position of the bush 20. The locking piece 22 is movably penetrated through the hollow through hole 21a in the center of the coil spring 21. The locking piece 22 is moved downward by the pressing operation of the cover 3 and is moved upward by the restoring operation by the elastic force of the coil spring 21. A claw portion 22 a is formed at the lower end of each locking piece 22.

  The bush 20 is formed in a hollow box shape that opens toward the locking piece 22 in order to allow movement of the locking piece 22. The bush 20 is formed with an engaging portion 20a that can be inserted into the locking piece 22 during assembly and that engages with the claw portion 22a of the locking piece 22 in order to prevent the locking piece 22 from being detached during use. The The engaging portion 20a engages with a claw portion 22a that moves upward by the elastic force of the coil spring 21 to lock the cover 3 to the steering wheel 1, thereby positioning the restoring position of the cover 3 with respect to the steering wheel 1. Is done. Further, the bush 20 is engaged with the locking pieces 22 of the cover 3 at three locations along the circumferential direction of the steering wheel 1, thereby positioning the cover 3 with respect to the rim 1 a. Of course, the locking piece 22 and the bush 20 may be provided at three or more locations.

  In relation to the present embodiment described above, instead of individually attaching the components to the steering wheel 1, an airbag module in which various components are assembled in advance may be configured. For example, the airbag module is configured by attaching at least the airbag 8 and the inflator 9 to the mount portion 4, the mounting bracket 6, the housing 7, the connection bracket 15, the cover 3, the bush 20, and the coil spring 21 in advance. The airbag module is attached and fixed to the mount portion 4 via the housing 7 and the attachment bracket 6, and the cover 3 and the like are attached to the airbag module via the connection bracket 15. The airbag module may be configured by attaching the cover 3 via the housing 7 and / or the attachment bracket 6 and the connection bracket 15 in advance.

  The operation of this embodiment will be described below. An example of the assembly procedure will be described. The airbag 8 and the inflator 9 are accommodated in the housing 7 to constitute an airbag module, and the housing 7 is attached to the mounting bracket 6 by using the mounting bolt 10 of the inflator body 9a. Can be fixed.

  First, the structure of the inflator 9 can be obtained by directly and integrally joining the mounting bolt 10 to the mounting surface 9b of the inflator body 9a.

  The assembly of the airbag module will be described. First, the inflator body 9a is accommodated in the airbag 8 in which the reinforcing cloth 25 is joined to the periphery of the bolt insertion hole 8a, and the mounting bolt 10 is moved from the bolt insertion hole 8a to the outside of the airbag 8. To protrude. Next, the airbag 8 is accommodated in the housing 7 so that the mounting surface 9b of the inflator body 9a is pressed against the bottom surface 7c of the housing 7, and the mounting bolt 10 is protruded from the bolt hole 7b. Thereby, an airbag module is constituted.

  When the housing 7 is installed on the mounting bracket 6, the nut 11 is screwed onto the mounting bolt 10, and the mounting bolt 10 is fastened to the mounting bracket 6, a tension T is generated on the mounting bolt 10. By this tension T, the mounting surface 9b of the inflator body 9a is pulled toward the mounting bracket 6 and the housing 7, and the airbag 8 can be pressed and fixed to the mounting bracket 6 or the like.

  Next, the airbag module in which the mounting bracket 6 is fastened with the mounting bolt 10 is inserted into the mount region M in the steering wheel 1. At this time, the harness 12 is connected to the connection terminal 23.

  When the airbag module is inserted, the slide portion 6b having the grip portion 16 is slidably engaged with the slope portion 4b, and the mounting portion 6c of the mounting bracket 6 is fixed to the fixing portion 4a of the mount portion 4 using the slide portion 6b. To approach. When the fixing portion 4 a and the attachment portion 6 c are brought close to each other, the bolt 17 is inserted through the bolt insertion hole and the slot 18 and tightened with the nut 19.

  In this fastening stage, the slide part 6b engages with the slope part 4b more deeply by the fastening action of the nut 19. The movement of the position of the bolt 17 due to the movement of the slide portion 6 b is allowed by the slot 18. When the fastening of the nut 19 to the bolt 17 is completed, the airbag module is attached and fixed to the boss portion 2 of the steering wheel 1 via the mount portion 4.

  Next, the bush 20 is disposed on the steering wheel 1. At the same time, the hook 15a of the connection bracket 15 is inserted into the hole 13 of the opening edge 7a in the housing 7 of the airbag module. Thereafter, the hook 15 a is locked in the locking hole 14 of the cover 3. Thereby, the cover 3 is attached to the mount portion 4 via the housing 7.

  The coil spring 21 is inserted into the locking piece 22 of the cover 3, the inserted coil spring 21 is disposed on the bush 20, and the cover 3 is pressed toward the bush 20. By this pressing, the claw portion 22 a of the locking piece 22 is engaged with the engaging portion 20 a of the bush 20. As a result, the cover 3 is attached to the steering wheel 1 while being positioned with respect to the restoring position and the rim 1a. When the cover 3 is pressed, the flexible housing 7 allows the cover 3 to move.

  The above assembling procedure is an example, and the cover 3 may be attached to the housing 7 via the connecting bracket 15 at the stage of producing the airbag module, or each component may be attached to the cover 3 from the boss portion 2 side. You may make it attach in order toward the side.

  In the present embodiment described above, the mounting bolt 10 is directly joined to the mounting surface 9b of the inflator body 9a facing the mounting bracket 6 through the housing 7 so as to fit within the outer contour of the inflator body 9a. Since the mounting bolt 10 is passed through the housing 7 and can be fastened to the mounting bracket 6, the inflator 9 is fixed as compared with the case of mounting and fixing with a retainer or bracket that becomes large as in the background art. The boss portion 2 on the side is sufficient in a narrow space, and the mounting portion can be made compact. Moreover, since the inflator 9 can be directly attached to the mounting bracket 6, the man-hour for attaching the inflator 9 can be reduced.

  Since the mounting bolt 10 is directly and integrally joined to the mounting surface 9b of the disc-shaped inflator body 9a whose outer shell is formed of a pressure vessel, the retainer with the bolt can be eliminated and a vehicle airbag can be assembled. , Can reduce the weight. Further, the entire inflator body 9a having the mounting bolt 10 is accommodated in the airbag 8, and the airbag 8 can be fastened to the mounting bracket 6 together with the inflator body 9a by the mounting bolt 10. It can be securely and firmly fixed to the mounting bracket 6 that is fixedly attached to the bag installation portion, the reinforcing structure of the airbag 8 can be simplified, productivity can be improved and cost can be reduced, and ecology and resource saving can be achieved. Can contribute.

  When the airbag 8 is deployed and inflated, that is, when inflator gas is generated by rapid combustion of explosives inside the inflator main body 9a, the pressure vessel of the inflator main body 9a is strong against the pressure by the combustion action and the inflator gas pressure. Functions as a pressure vessel. The inflator body 9a composed of a rigid pressure vessel, the mounting bolt 10 directly and integrally joined to the inflator body 9a, the mounting bracket 6 fastened to the mounting bolt 10 and the airbag installation portion Unlike the mounting structure using a retainer with a bolt that is easily deformed as described above, the structure is highly integrated and rigid. Therefore, it is possible to ensure high strength against the pressure accompanying rapid combustion and the inflation pressure of the airbag 8 that is inflated and deployed. Resist.

  Specifically, the mounting bolts 10 are joined to the mounting surface 9b of the inflator main body 9a and are arranged at a clearly narrower interval than the bolt interval of the retainer with bolts, so that the attachment strength to the airbag installation portion is increased. be able to. Since the mounting surface 9b of the inflator main body 9a is pressed against the mounting bracket 6 side, the pressing area of the inflator main body 9a to the airbag installation portion can be expanded as compared with the case where the annular retainer is pressed.

  In addition, since the mounting position of the mounting bolt 10 is set so that the straight line L connecting the center line (intersection position) BC of the mounting bolt 10 passes through the center C of the mounting surface 9b of the inflator body 9a, The mounting bolts 10 can be evenly arranged with good balance with respect to the mounting surface 9b. With this arrangement, pressure and gas pressure due to rapid combustion can be evenly distributed and transmitted to the mounting bracket 6 and the airbag installation portion, and the disk-shaped inflator body 9a tilts when the gas is ejected. A situation can be prevented and the airbag 8 can be appropriately inflated and inflated.

  In the case of a passenger seat airbag, since the straight line L is set in the left-right direction of the vehicle, the deployment and inflation direction of the airbag 8 can be reliably directed toward the rear of the vehicle, and the operational stability of the airbag 8 can be improved.

  In the case of a driver's seat airbag, since the straight line L is set in the longitudinal direction of the vehicle, the deployment and inflation direction of the airbag 8 can be reliably directed to the driver, and the operational stability of the airbag 8 can be improved.

  In this way, the inflator body 9a having a rigid pressure-resistant container is not easily deformed by connecting the inflator body 9a and the airbag installation portion with the mounting bolt 10 directly and integrally joined to the inflator body 9a. In addition, the mounting strength can be increased, the pressing area can be expanded, the distortion and deformation around the installation location of the inflator body 9a can be suppressed, and the pressure, gas pressure, and expansion pressure associated with the combustion action can be reduced. It can be received reliably and sufficiently.

  At the same time, the area for pressing the airbag 8 into the airbag installation part or the housing 7 can be expanded. Since the airbag 8 can be pressed and fixed to the airbag installation portion or the like over a wide range by the mounting surface 9b of the inflator body 9a, reinforcement of the airbag 8 can be reduced.

  Furthermore, since the defect | deletion part of the airbag 8 is about the bolt insertion hole 8a, unlike the case where the opening part which exposes the lower hemisphere part of an inflator is provided like the background art, the intensity | strength of the airbag 8 itself can also be strengthened. Since the strength of the airbag 8 can be increased in this way, sufficient reinforcement can be secured around the bolt insertion hole 8a by stacking one to several reinforcing cloths 25.

  As described above, the deployment and inflation performance of the airbag 8 can be appropriately ensured, and appropriate occupant protection performance can be ensured. Furthermore, since the retainer with a bolt can be abolished, weight reduction can be achieved.

  Since the ignition device connection terminal 23 is provided adjacent to the attachment bolt 10 on the attachment surface 9b of the inflator body 9a, the connection work locations of the harness 12 to the connection terminal 23 can be integrated, and the connection terminal 23 can be omitted. Can be arranged in space. By setting the position of the mounting bolt 10 to the outer peripheral edge side of the mounting surface 9b with respect to the position of the connecting terminal 23, the inflator body 9a can be stably fixed to the mounting bracket 6 and the connecting terminal is connected to the central portion of the mounting surface 9b. By installing 23, it is possible to consolidate connection work locations and save space.

  Since the center of the mounting surface 9b of the inflator body 9a is set to coincide with the center of the boss part 2, the inflator 9 that generates inflator gas can be appropriately supported by the steering shaft via the boss part 2. The operational stability of the airbag 8 can be improved.

  Since the housing 7 having flexibility that can be deformed in accordance with the dimension between the mounting bracket 6 and the cover 3 is provided, the boss portion 2 and the mount portion 4 of the steering wheel 1 constituting the airbag installation portion are connected to the cover 3. The housing 7 can absorb the dimensional tolerance and assembly tolerance of each part.

  In other words, the flexible housing 7 makes it possible to make the attachment to the boss portion 2 and the support of the cover 3 to the steering wheel 1 independent, and the dimensional tolerance of parts on the boss portion 2 side relative to the housing 7 In addition, it is possible to prevent the assembly tolerance from affecting the cover 3 side, and the dimensional tolerance and assembly tolerance of the parts closer to the cover 3 than the housing 7 from affecting the boss portion 2 side.

  As a result, the mounting and fixing to the boss portion 2 can be ensured, and at the same time, the installation position of the cover 3 that hides the airbag 8 can be accurately aligned with the steering wheel 1. Therefore, for example, the design surface 1c position of the rim 1a and the spoke 1b of the steering wheel 1 and the installation position of the cover 3 can be aligned in series, and the appearance design can be improved. Further, the flexible housing 7 increases the flexibility of the mounting operation of the cover 3, and can improve the mounting operation between the locking piece 22 of the cover 3, the bush 20, and the coil spring 21.

  Further, the mounting bracket 6 can be attached to the mount portion 4 by sliding movement using traction obtained by the fastening action of the bolt 17 and the nut 19, and a large number of bolts and nuts can be used as in the background art. Compared to locking the locking wire to the hook part, the workability can be improved while the work for assembling the steering wheel 1 is a downward work, and the assembly tolerance is generated at the bolt fastening portion of the fixing part 4a and the mounting part 6c. As a result, the reliability of the assembly work can be improved.

  When the mounting bracket 6 is attached to the mount portion 4 by sliding the slide portion 6b along the slope of the slope portion 4b, the flexible housing 7 moves the mounting bracket 6 downward from the cover 3 side toward the boss portion 2 side. It can be tolerated, can be fitted to the assembling work by the slide operation, and can be attached appropriately and reliably.

  Since the mount portion 4 forms a mount region M that gradually narrows from the cover 3 side toward the boss portion 2 side, including the fixing portion 4a, at least by the slope portion 4b. 4 can be guided toward the center of the steering wheel 1, and even the small-diameter steering wheel 1 can perform the work accurately and quickly, and can automate the assembly work. can do.

  Since the slot 18 is formed in the fixing portion 4a of the mount portion 4, the position of the bolt 17 can be adjusted by adapting to the procedure of sliding the slide portion 6b to the slope portion 4b, and the mounting bracket 6 is mounted on the mount portion 4 Can be mounted and fixed accurately.

  Since the grip portion 16 that grips and engages the slope portion 4a is formed on the slide portion 6b, the slide movement of the slide portion 6b relative to the slope portion 4a can be stabilized.

  Since the fixing bracket 6 is supported at three points by the one fixing portion 4a and the two slope portions 4b, the airbag 8 that expands and inflates and the inflator 9 that explodes and ejects the inflator gas can be reliably supported. . Since the mount portion 4 and the mounting bracket 6 are fastened by the single bolt 17, the fastening work location can be made one place, and the assembly work can be simplified.

  The cover 3 is formed with the locking hole 14, the housing 7 is formed with the hole 13, and the connecting bracket 15 is formed with the hook 15 a that is inserted into the hole 13 and locked into the locking hole 14. The housing 7 can be connected to the cover 3 with extremely simple and good workability, and the assembling work can be simplified.

  By assembling at least the airbag 8 and the inflator 9 to form an airbag module, assembly workability can be simplified.

  By constructing the airbag module by further incorporating the cover 3, the connecting bracket 15, the housing 7, and / or the mounting bracket 6, the assembly workability can be further simplified.

  In the present embodiment, the structure of the driver airbag device has been described with the boss portion 2 and the mount portion 4 of the steering wheel 1 as the airbag installation portion. However, instead of this form, for example, a passenger seat airbag device, a rear seat airbag device, a curtain airbag device, a seat having a steering support member or the like as an airbag installation portion and a lid of an instrument panel as a cover. Of course, it can be applied to the structure of any airbag device such as an airbag device incorporated in a back or seat cushion.

  FIG. 9 shows a modification of the above embodiment. This modification is a case where three or more mounting bolts 10 are provided on the mounting surface 9b of the inflator body 9a. As in the above embodiment, the center line BC in the bolt axial direction of each mounting bolt 10 is directed to the mounting surface 9b of the inflator body 9a.

  In this modification, the mounting surface 9b of the inflator body 9a is drawn by connecting the intersections of a plurality of mounting bolts 10 in the circumferential direction along the outer contour of the mounting surface 9b, in the illustrated example, in the circumferential direction. The mounting position of the mounting bolt 10 is set so that the center of gravity G of the polygon Q to be aligned matches the center position C of the mounting surface 9b of the inflator body 9a.

  Thereby, even if it is a case where the number of attachment bolts 10 is three or more, the attachment bolt 10 can be arrange | positioned with sufficient balance with respect to the attachment surface 9b of the inflator main body 9a. Therefore, the airbag 8 can be appropriately deployed and inflated as in the above embodiment.

  When the number of the mounting bolts 10 is three or more, as shown in the inside of the instrument panel H in FIG. 10, the mounting bolts 10 are arranged on the mounting surface 9 b of the inflator body 9 a on the vehicle front side. It is preferable that the number of installations does not fall below the number of installations on the vehicle rear side. In this way, the inflator body 9a can be firmly fixed toward the rear of the vehicle, the deployment and inflation direction of the airbag 8 can be reliably directed toward the rear of the vehicle, and the operational stability of the airbag 8 can be improved. Can be improved.

  The embodiments and modifications described above are preferable examples of the present invention, and other embodiments can be implemented or performed by various methods. In particular, the present invention is not limited to the detailed shape, size, configuration, and the like of the components shown in the accompanying drawings unless otherwise stated in the present specification. For example, the attachment surface 9b (joint location) of the inflator body 9a to which the attachment bolt 10 is joined is not limited to a flat surface but may be a spherical surface or a curved surface. In addition, expressions and terms used in the present specification are for the purpose of explanation, and are not limited thereto unless otherwise specified.

DESCRIPTION OF SYMBOLS 1 Steering wheel 2 Boss part 3 Cover 4 Mount part 4a Fixing part 4b Slope part 6 Mounting bracket 6b Slide part of mounting bracket 6c Mounting part of mounting bracket 7 Housing 7a Opening edge part of housing 8 Air bag 9 Inflator 9b Inflator mounting surface 10 mounting bolt 15 connecting bracket 17 bolt 23 connection terminal for ignition device M mount area

Claims (9)

A vehicle airbag having a mounting bracket that is fixedly attached to an airbag installation portion of a vehicle, a housing that houses an airbag and a disk-shaped inflator attached to the airbag, and is installed on the mounting bracket. Because
A mounting bolt is directly joined to the inflator on the mounting surface facing the mounting bracket via the housing in an arrangement that fits within the outer contour of the inflator.
An inflator structure for a vehicle airbag, wherein the mounting bolt penetrates the housing and is fastened to the mounting bracket. A vehicle airbag module comprising an airbag and a disk-shaped inflator accommodated in the airbag and deploying and inflating the airbag,
The inflator is directly joined to the mounting surface facing a mounting bracket that is mounted and fixed to the airbag installation portion of the vehicle, and is disposed within the outer contour of the inflator, and the airbag together with the inflator. And a mounting bolt that can be fastened to the mounting bracket.   The vehicle airbag module according to claim 2, wherein an ignition device connection terminal is provided adjacent to the mounting bolt on the mounting surface of the inflator.   Two mounting bolts are provided, and the mounting position of each mounting bolt is set such that a straight line connecting the positions of the center lines of the mounting bolts passes through the center position of the inflator on the mounting surface of the inflator. The vehicle airbag module according to claim 2 or 3.   The vehicle airbag module according to claim 4, wherein a straight line connecting positions of center lines of the mounting bolts is set in a left-right direction of the vehicle.   Three or more mounting bolts are provided, and the mounting position of each mounting bolt is drawn on the mounting surface of the inflator by connecting the positions of the center lines of the mounting bolts in the circumferential direction along the outer contour of the inflator. The vehicle airbag module according to claim 2 or 3, wherein the center of gravity of the square is set so as to coincide with the center of the inflator.   The vehicle airbag module according to claim 6, wherein the number of installations on the front side of the vehicle is less than the number of installations on the rear side of the vehicle on the mounting surface of the inflator. A vehicle airbag structure in which the vehicle airbag module according to any one of claims 2 to 7 is installed in an airbag installation part of a vehicle,
In the airbag installation part, facing each other, forming a fixing part and a slope part,
At least the slope portion is formed so as to be inclined toward the fixing portion, and a mount region gradually narrowing between the fixing portion and the fixing portion is formed.
The mounting bracket that fastens the vehicle airbag module with the mounting bolt is formed with a sliding portion that is slidably engaged with the slope portion and a mounting portion that faces the fixing portion,
The mounting portion of the mounting bracket is coupled to the fixing portion of the airbag installation portion by a fastening member that pulls the mounting portion toward the fixing portion through the slide portion by a fastening action. Airbag structure for vehicles. And a cover that is attached to the vehicle and covers the airbag installation portion; a housing that houses the airbag and is installed on the attachment bracket;
The housing has an opening edge that opens toward the cover,
The opening edge of the housing and the cover are connected by a connection bracket,
The vehicle airbag structure according to claim 8, wherein the housing has a flexibility that can be deformed in accordance with a dimension between the mounting bracket and the cover.

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