JP5357712B2 - Airbag device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the manufacturing cost by simplifying an attachment structure of an inflator. <P>SOLUTION: A storage part 53 is provided on a resin base plate 21. A fitting receiving part 55 is provided on an inner peripheral surface of a side wall part 54 of the storage part 53. A fitting part 45 having projections and recessions is provided on an outer periphery of a container part 41 of the inflator 24. A facing part 48 is provided on a flange part 47 disposed on a lower end of the inflator 24. An obstructing part 16 is disposed on a boss core metal 9 of a hub core 10 of a steering wheel body 2. When the inflator 24 is press fitted in the storage part 53, the fitting part 45 and the fitting receiving part 55 are fitted, and the inflator 24 is held by the base plate 21. When the air bag device 4 is attached to the steering wheel body 2, the obstructing part 16 faces the facing part 48. Even when the inflator 24 is moved downward, the facing part 48 is abutted to the obstructing part 16, and movement of the inflator 24 is obstructed, and the state that a gas injection port 46 is exposed in an inside of an air bag 22 can be maintained. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to an airbag device provided on a steering wheel of an automobile, for example.

  2. Description of the Related Art Conventionally, for example, with respect to a handle of an automobile, a configuration in which an airbag device is provided at a boss portion of a handle body is known.

  Such an airbag apparatus includes a metal base plate that is attached to a metal core of a handle, and a bag-like airbag, an inflator that supplies gas to the airbag, and a cover body that covers the folded airbag Etc. are attached. The inflator includes a disc-shaped main body portion provided with a gas injection port on the outer peripheral portion, and a flange portion projecting from the outer peripheral portion of the main body portion, and the main body from the lower side in a circular hole formed in the base plate. The portion is inserted and the flange portion is disposed at a position along the lower surface of the base plate. A retainer called a ring member is used for fixing the inflator. The retainer has an annular shape similar to the flange portion of the inflator, and four protruding downward from the retainer main body. With bolts. The retainer has a retainer main body portion along the top surface of the base plate, and four bolts are inserted into holes provided in the base plate and the flange portion, and nuts are screwed and tightened from below. The inflator is fixed to the base plate. Further, the airbag has a retainer bolt that penetrates through a hole provided around the gas introduction port in a state where the gas introduction port provided in the base end portion is covered from the upper side of the base plate to the main body portion of the inflator. A base end portion is sandwiched and fixed between the main body portion and the base plate. The cover body is fixed to the outer periphery of the base plate with rivets, screws, or the like. As described above, in the configuration using the retainer, although the airbag can be fixed by the retainer, an operation of screwing and tightening four nuts is necessary, and the manufacturing process becomes complicated.

  In this regard, as a configuration that facilitates easy fixing of the inflator, a configuration is known in which a housing chamber that houses a folded airbag and an inflator (gas generator) is provided in an integrally formed casing (for example, (See Patent Document 1). The casing is provided with a diffuser chamber in which the outer peripheral portion is raised and the airbag is accommodated from above, the central portion of the bottom is raised upward, and the inflator is accommodated from below. The inflator is fixed to the diffuser chamber by snap coupling, press fitting, edge deformation, or welding.

  However, the fixing of the casing by deformation or welding makes the manufacturing process complicated and makes it difficult to reduce the manufacturing cost. In particular, the deformation of the edge portion is a so-called caulking process of the flange portion, but the work is complicated and the deformation of the deformed portion occurs (spring back), so that the flange portion is in close contact with the inflator. This is not easy, and causes abnormal noise due to rattling. On the other hand, when the engagement piece is elastically engaged and fixed by inserting the inflator, it is difficult to secure the dimension (lap allowance) of the engagement piece that overlaps the bottom side that is the vehicle body side of the inflator. In order to firmly fix the inflator so that it does not move to the vehicle body in the direction opposite to the airbag even when a large force is applied when the airbag is deployed with one piece, the reaction force of the elastic deformation of the engagement piece is increased. The setting work becomes difficult, and it becomes difficult to reduce the manufacturing cost.

JP 2005-505462 A (Page 2-5, Fig. 1-2)

  As described above, when it is attempted to realize a configuration in which the inflator is easily and firmly attached to the airbag device, there is a problem that it is difficult to reduce the weight and size, or the manufacturing cost increases.

  The present invention has been made in view of such a point, and an object of the present invention is to provide an airbag device that can be easily attached with an inflator and can reduce the manufacturing cost while ensuring the function of the airbag device.

  The airbag device according to claim 1 includes a base portion and a housing portion, and is attached to a vehicle body side member, an airbag that covers the non-vehicle body side of the base body and is attached to the base body, and a container portion And an inflator for supplying gas to the airbag with a facing portion, and a blocking portion provided on the vehicle body side member, and the housing portion includes a fitting receiving portion for fitting and holding the inflator, The container portion includes a fitting portion that is fitted and held in the fitting receiving portion in a state in which the container portion is press-fitted into the housing portion along a predetermined direction, and the fitting portion is arranged along the predetermined direction. A gas injection port provided on the side opposite to the vehicle body and located on the side opposite to the vehicle body, the opposed portion facing the blocking portion, and the gap between the opposed portion and the blocking portion. The dimensions along the predetermined direction are the substrate part and the gas injection The one in which small set than a dimension along a predetermined direction between.

  The airbag device according to claim 2 is the airbag device according to claim 1, wherein the base body includes a flat plate-like substrate portion and a cylindrical fitting receiving portion protruding from the substrate portion toward the vehicle body. It is integrally formed of resin, and the fitting portion is formed by forming irregularities on the cylindrical outer peripheral portion of the container portion.

  The airbag device according to claim 3 is the airbag device according to claim 1 or 2, wherein the inflator includes a flange portion that is located on the vehicle body side of the substrate portion and projects from the outer peripheral side of the container portion. The portion is provided on the flange portion.

  The airbag device according to claim 4 is the airbag device according to any one of claims 1 to 3, wherein the vehicle body side member is a hub core of a handle attached to a steering shaft, and a blocking portion constitutes the hub core. It is provided integrally with the member.

  According to the airbag device of the first aspect, the fitting portion is fitted and held in the fitting receiving portion by press-fitting the container portion of the inflator into the accommodating portion along a predetermined direction, and the inflator can be easily attached to the base body. Can be attached to. When the airbag device operates in this state, gas is injected from the gas injection port of the inflator to the inside of the airbag, and the airbag is inflated and deployed. When a gas is supplied from the inflator and the airbag is inflated and deployed, a force that presses the inflator to the opposite side of the vehicle body is applied. Even if it tries to move to, the facing portion abuts against the blocking portion, and the amount of movement of the inflator is restricted. And since the dimension between the facing part and the blocking part is set smaller than the dimension between the substrate part and the gas injection port, even if the inflator moves to the maximum extent that the facing part contacts the blocking part The gas injection port is maintained in a state of being located on the side opposite to the vehicle body from the substrate portion, gas can be smoothly supplied from the gas injection port to the inside of the airbag, and the function of the airbag device can be ensured. Since the blocking part is provided on the member on the vehicle body side, the inflator can be attached to the base body by fitting by press-fitting, and the structure for fixing the inflator can be regulated by attaching the base body to the vehicle body side member to restrict the movement of the inflator. This simplifies and makes it possible to easily reduce the size and weight of the airbag device, facilitate the attachment work, and reduce the manufacturing cost.

  According to the airbag device of the second aspect, in addition to the effect of the first aspect, the base body is formed by integrally forming a plate-like substrate portion and a cylindrical fitting receiving portion with resin. Since the portion is configured by forming irregularities on the cylindrical outer peripheral portion of the container portion, a configuration in which the inflator can be attached to the base body by press-fitting can be easily realized, and the manufacturing cost can be reduced.

  According to the airbag device of the third aspect, in addition to the effect of the first or second aspect, the inflator can be easily and reliably held by positioning the flange portion of the inflator between the base body and the blocking portion. . By bringing the blocking portion into contact with the opposing portion provided on the flange portion, it is possible to prevent the blocking portion from coming into contact with the container portion.

  According to the airbag device of the fourth aspect, in addition to the effect of any one of the first to third aspects, since the blocking portion is integrally provided on the member constituting the hub core of the handle attached to the steering shaft, the steering wheel is steered. By attaching to the shaft, the blocking portion and the facing portion can be opposed to each other to reliably restrict the movement of the inflator, and the configuration of the airbag device and the handle provided in the handle can be simplified to reduce the manufacturing cost.

1 is a partial cross-sectional view of a state in which a handle provided with an airbag device showing an embodiment of an airbag device of the present invention is attached to a vehicle body. It is a disassembled perspective view of a part of airbag apparatus same as the above. It is a perspective view of a part of the handle constituting the airbag device. It is sectional drawing of a part of handle | steering_wheel provided with the airbag apparatus which shows other embodiment of the airbag apparatus of this invention. It is a disassembled perspective view of a part of airbag apparatus same as the above.

  Hereinafter, an embodiment of an airbag device of the present invention will be described with reference to the drawings.

  In FIG. 1, reference numeral 1 denotes a steering wheel as a steering wheel of an automobile. The steering wheel 1 includes a steering wheel main body 2 as a steering wheel main body and an airbag device 4 integrally attached to a passenger side of the steering wheel main body 2. And is mounted on the steering shaft 5 on the vehicle body side.

  The steering shaft 5 is provided so that the angle can be adjusted in a normally inclined state, and the steering wheel 1 is also provided in a normally inclined state. Hereinafter, the steering wheel main body 2 is horizontal, The axial direction is vertical, the occupant side that is the side opposite to the vehicle body, that is, the airbag device 4 side is the front side or the upper side (the direction of arrow A shown in FIG. 1), and the rear side that is the steering shaft 5 side opposite to the front side. The vehicle body side or the lower side (in the direction of arrow B shown in FIG. 1), the predetermined direction along the axis of the steering shaft 5 is the vertical direction, and the straight traveling direction in the straight traveling state of the vehicle body provided with the steering wheel 1 is a reference The directions such as the front-rear direction and the both-side direction will be described.

  And although the steering wheel main body 2 is not shown in its entirety, the rim portion as an annular grip portion, the boss portion 6 positioned inside the rim portion, and the rim portion and the boss portion 6 are connected. It is composed of a plurality of spoke parts. Further, a boss 8 fitted to the steering shaft 5 is provided on the vehicle body side of the boss portion 6, and a boss core 9 as a member is cast by casting a magnesium alloy or the like on the boss 8. Thus, the hub core 10 as a vehicle body side member is configured by being integrally formed of metal or fixed by welding a separate metal.

  And the core metal of a spoke part is integrally extended from this boss | hub metal core 9 to the radial direction, or is fixed by welding etc. metal. Further, the core metal of the rim part is integrally formed continuously with the core metal of these spoke parts, or is fixed by welding or the like. Further, a skin portion made of, for example, urethane, for example, soft foamed polyurethane, is formed on the outer peripheral portion of the core metal of the rim portion and the outer peripheral portion of the spoke core metal on the rim portion side. . Further, if necessary, a resin back cover is attached to the back side of the boss core 9 to cover the back side of the boss portion 6, and the steering wheel 1 side and the vehicle body side are electrically connected. A connecting device to be connected is arranged.

  The boss core 9 of the hub core 10 is provided with a circular boss center opening 12 that is located at the center and communicates with the upper side of the boss 8, and the side of the boss center opening 12. The boss side opening 14 is formed at the position. Further, as shown in FIGS. 1 and 3, a blocking portion 16 constituting the airbag device 4 is formed integrally with the boss core 9 toward the upper side along the outer peripheral portion of the boss central opening 12. . The blocking portion 16 is an annular rib portion surrounding the boss central opening 12, and the upper end portion serving as the tip portion forms a horizontal shape, that is, a planar shape orthogonal to a predetermined direction, and the vertical section of each portion is downward. It has a substantially trapezoidal shape in which the width dimension increases. Further, the blocking portion 16 is integrally formed with the metal boss core 9, and even when a large force is applied when the airbag device 4 is operated, in particular, a large force is applied from above, It is formed with rigidity that does not deform.

  Further, the locking means 18 is attached to the boss core 9 so as to hang over the boss side opening 14. The locking means 18 is a spring formed by bending an elastically deformable wire, and the pair of locking wire portions 19 can be deformed in a direction to open each other, that is, in a state where they are biased in a direction approaching each other. Has been placed. In addition, a nut 20 is disposed in the boss center opening 12 so as to be screwed into a screw portion 5a at the tip of the steering shaft 5 and tightened.

  The airbag device 4 is a so-called driver's seat airbag provided in the boss portion 6 of the steering wheel 1 and is made of resin as a base body as shown in FIGS. 1 and 2 in addition to the blocking portion 16 of the hub core 10. Base plate 21, bag-like airbag 22, resin-made cover body 23, and inflator 24 which is a gas supply means for supplying gas to airbag 22, and the like. An inflator 24 is attached to form a module. In addition, a horn switch mechanism that blows the horn at the time of pushing is provided integrally with the module or in a mechanism that supports the module. And in this Embodiment, the airbag apparatus 4 is utilized as an operation part of the horn switch which can be moved up and down with respect to the steering wheel main body 2. FIG.

  The airbag 22 is configured in a flat bag shape, for example, by stitching the outer peripheral portions of two base fabrics on top of each other. A rectangular airbag opening 26 is provided at the center of the lower base fabric, and an airbag attachment piece 27 is formed continuously with the airbag opening 26. The airbag mounting piece 27 is formed with a rectangular positioning hole 28 and a pair of rectangular fixing holes 29 arranged with the positioning hole 28 interposed therebetween. In addition, a folding line is formed between the fixing holes 29 to bend the base fabric of the airbag attachment piece 27. Further, if necessary, a circular gas exhaust port (not shown) is formed in the vicinity of the outer peripheral portion of the lower base fabric.

  The cover body 23 includes a substantially box-shaped cover main body 30 that is integrally formed of an elastically deformable resin and that has an open bottom surface. That is, the cover main body 30 includes a front plate portion 31 that covers the front side of the folded airbag 22 and a peripheral plate portion 32 that covers the outer peripheral side of the folded airbag 22. Further, cover body side attaching portions 33 are formed at a plurality of locations on the lower end portion of the peripheral plate portion 32. The cover body side mounting portion 33 includes a projecting portion 34 projecting, for example, in a semicircular shape from the lower edge of the peripheral plate portion 32, and a projecting portion projecting downward from the lower end portion of the projecting portion 34. One piece 35 and a fixing hole 36 located at the center of the circle formed by the projecting portion 34 are provided.

  Further, a tear line 37 is formed on the front plate portion 31 of the cover body 23 as a planned fracture portion having a substantially H-shape, for example. The tear line 37 is formed in a thin wall that is easily broken by cutting the front plate portion 31 from the back surface, that is, the lower surface side.

  The inflator 24 includes a metal container portion 41 having a disk shape, that is, a cylindrical shape having a small longitudinal dimension. The container portion 41 includes a metal cylindrical barrel portion 42, and the upper and lower portions of the barrel portion 42 are closed by a top plate portion 43 and a bottom plate portion 44. Inside the container portion 41, an internal structure such as a propellant and an igniter that ignites the propellant is accommodated. A fitting portion 45 is formed on the outer peripheral portion of the body portion 42 of the container portion 41 along a predetermined height position of the lower side portion, and a predetermined height above the fitting portion 45 is formed. A gas injection port 46 composed of a plurality of circular holes is formed along the vertical position. The fitting part 45 is formed as a knurled part by so-called knurling in which regular irregularities are formed by cutting the outer peripheral surface of the body part 42 or the like.

  Further, a flat plate-like flange portion 47 protruding from the body portion 42 to the outer peripheral side is attached to the bottom portion or the vicinity of the bottom portion of the container portion 41 of the inflator 24. The flange portion 47 has, for example, a substantially square shape, and a lower surface of a portion located on the outer peripheral side of the body portion 42 of the flange portion 47 is a facing portion 48 that is a movement restricting portion. The upper surface of the portion located on the outer peripheral side is an upper facing portion 49.

  Further, an electric wire (not shown) called a harness connected to an igniter is led out from the bottom plate portion 44 of the container portion 41, and a connector is provided at the tip of the electric wire.

  The base plate 21 is integrally formed of a resin, and includes at least a flat plate-like substrate portion 51 and a substantially cylindrical side wall that protrudes downward from the substrate portion 51 and forms an accommodating portion 53 inside. The portion 54 is integrally formed. This resin is composed of, for example, nylon 66 resin mixed with 33% by weight of glass fiber, or PPS resin added with 40% by weight of glass fiber (polyphenylene sulfide, “Lyton” (trade name) manufactured by Chevron Phillips Chemical Co., Ltd.). Has been.

  The accommodating portion 53 is located in the central portion of the substrate portion 51, and fits and accommodates the lower portion of the container portion 41 of the inflator 24, that is, a part of the container portion 41. An inner peripheral surface of the side wall portion 54 integrally protruding on the side is a fitting receiving portion 55 that is an inflator contact portion. The dimension of the fitting receiving part 55, that is, the inner diameter dimension of the side wall part 54 of the fitting receiving part 55 is the dimension of the fitting part 45, that is, the body part of the container part 41 of the inflator 24 of the fitting part 45. It is set smaller than the outer diameter of 42.

  The outer peripheral portion of the base plate portion 51 of the base plate 21 is bent downward along the outer peripheral portion so as to have a substantially U-shaped cross section, and the lower end portion of the peripheral plate portion 32 of the cover body 23 is fitted and supported. A plate portion support portion 61 is formed. Further, a cover body fixing portion 62 is formed on the peripheral plate portion support portion 61 corresponding to the cover body side mounting portion 33 of the cover body 23. The cover body fixing portion 62 includes a mounting plate portion 63 whose outer peripheral edge of the base plate 21 protrudes in a semicircular shape on the upper side, and a fixing hole 64 formed at a position facing the mounting plate portion 63. 64, and a positioning hole 65 opened in a rectangular shape at the bottom of the peripheral plate support 61.

  Further, the base plate 21 is provided with bracket portions 67 projecting downward from a plurality of locations near the outer peripheral portion of the substrate portion 51. The bracket portion 67 is formed in a plate shape having a high strength that does not deform even when the airbag 22 is deployed, and a claw-like locking portion 68 protruding outward is formed on the distal end side. Yes. That is, the lower surface of the locking portion 68 forms an inclined surface 68a, and a horizontal locking surface 68b is formed on the upper side.

  In the assembly process of the airbag device 4, first, the body portion 42 of the inflator 24 is press-fitted into the housing portion 53, that is, the side wall portion 54, from the lower side to the upper side of the base plate 21. The inflator 24 is in a predetermined position in a state where the upper facing portion 49 of the flange portion 47 of the inflator 24 is in contact with the lower end portion of the side wall portion 54. In this state, the knurled metal fitting portion 45 bites into the resin fitting receiving portion 55 so that the fitting portion 45 of the trunk portion 42 of the inflator 24 and the side wall of the accommodation portion 53 of the base plate 21 The fitting receiving portion 55 of the portion 54 is fitted, and the inflator 24 is positioned and held at a predetermined position of the accommodating portion 53 of the base plate 21. In this state, the separation dimension between the base plate 21 and the gas injection port 46 is more specifically, the separation along the vertical direction between the upper surface of the substrate portion 51 of the base plate 21 and the lower end portion of the gas injection port 46. The dimension is a predetermined dimension L1 greater than zero. In addition, the wires and connectors of the inflator 24 are drawn out downward.

  Next, the airbag 22 is folded into a predetermined shape, accommodated inside the cover main body 30, and the positioning hole 28 is inserted into the projecting piece 35, bent at a predetermined fold line, and the cover body side mounting portion 33 is inflated. The bag attaching piece 27 is aligned.

  Then, the cover body 23 is combined with the base plate 21 so that the airbag opening 26 of the folded airbag 22 covers the upper side of the inflator 24. That is, the lower end portion of the peripheral plate portion 32 of the cover body 23 is fitted into the peripheral plate portion support portion 61 of the base plate 21, and the protruding piece portion 35 is inserted into the positioning hole 65 and positioned. In this state, by inserting and crimping a rivet 71 that is a fixing tool from the outside into the fixing holes 36 and 64, the cover body side mounting portion 33 is fixed in close contact with the mounting plate portion 63, and the cover body 23 is fixed to the base plate 21. Fixed to. At the same time, the airbag 22 has an airbag mounting piece 27 around the airbag opening 26 sandwiched between the peripheral plate portion 32 of the cover body 23 and the peripheral plate portion support portion 61 of the base plate 21, A state in which the airbag mounting piece 27 of the airbag 22 is firmly attached to the base plate 21 with the rivet 71 penetrating through the fixing hole 29 and tightly sandwiched between the protruding portion 34 and the mounting plate 63. It becomes.

  Thus, the module of the airbag apparatus 4 is comprised.

  In the steering wheel body 2, the steering shaft 5 is fitted to the boss 8, and the nut 20 is fixed by tightening.

  Then, the module of the airbag device 4 is pushed into the boss portion 6 side of the steering wheel body 2 along the vertical direction of the steering shaft 5, that is, the axial direction, from above. Then, the bracket portion 67 of the base plate 21 is pushed into the boss side opening 14, and the inclined surface 68a temporarily pushes the locking means 18, and the locking means 18 is restored and deformed to be locked to the locking surface 68b. That is, the locking portion 68 of the bracket portion 67 is locked to the locking means 18, and the module of the airbag device 4 is fixed to the hub core 10 of the steering wheel body 2.

  Further, in this state, the facing portion 48 provided on the lower surface of the flange portion 47 of the inflator 24 of the airbag device 4 faces the blocking portion 16 provided on the hub core 10 of the steering wheel main body 2 in close proximity. Here, the term “facing” refers to a state of contact in a non-pressed state that is opposed to each other with a predetermined interval or is just in contact, and the vertical dimension L2 between the facing portion 48 and the blocking portion 16 is 0. In addition, it is smaller than the dimension L1 between the base plate 21 and the gas injection port 46, and is set in the range of 0 ≦ L2 <L1. Further, in the present embodiment, since the airbag device 4 is used as an operation portion of a horn switch that can move up and down with respect to the steering wheel body 2, when the horn switch stroke dimension is L3, the facing portion 48 and the blocking portion are provided. The vertical dimension L2 between 16 and 16 is larger than the dimension L3 larger than 0 and is set in the range of 0 <L3 <L2 <L1.

  And the steering wheel 1 provided with the airbag apparatus 4 is comprised in the state attached to the steering shaft 5 by performing the electrical wiring with the connector of the inflator 24, and the vehicle body side.

  Further, when the automobile collides, the airbag device 4 operates based on the control of the control device. That is, gas is rapidly supplied into the airbag 22 from the gas injection port 46 of the inflator 24, and the airbag 22 folded and stored rapidly inflates and deploys. Then, due to the inflation pressure of the airbag 22, the cover body 23 is broken along the tear line 37, the front plate portion 31 is opened like a door, and the protruding opening of the airbag 22 is formed. The airbag 22 is inflated and deployed so as to bulge to the front side and cover the entire steering wheel body 2, and restrains and protects the occupant thrown forward.

  A force is applied to the inflator 24 from the upper side due to a reaction force when the airbag 22 is deployed, and the fitting portion 45 fitted by press-fitting is disengaged from a predetermined position with respect to the fitting receiving portion 55, that is, an initial position. Even if the inflator 24 moves downward, if the inflator 24 moves downward by a predetermined dimension L2, the opposed portion 48 of the inflator 24 abuts against the blocking portion 16 of the hub core 10, and the movement is restricted. That is, when the dimension L2 is 0, the inflator 24 does not substantially move even if the fitting portion 45 is disengaged from the fitting receiving portion 55. When the dimension L2 is larger than 0, the movement amount of the inflator 24 is Limited to dimension L2. Since this dimension L2 is set smaller than the dimension L1 between the base plate 21 and the gas injection port 46, even if the inflator 24 moves while the gas is supplied from the inflator 24, the gas injection The mouth 46 is not covered with the base plate 21, so that the airbag 22 can be smoothly deployed and the function of the airbag device 4 can be secured.

  As described above, according to the present embodiment, the airbag device 4 can be easily and surely attached while securing the function of the airbag device 4, and can be reduced in size and weight, and the manufacturing cost can be reduced. In other words, the lightweight and inexpensive airbag device 4 can be provided.

  That is, in the inflator 24, the fitting portion 45 is fitted and held in the fitting receiving portion 55 by press-fitting the container portion 41 into the accommodating portion 53 along a predetermined direction, and the inflator 24 can be easily attached to the base plate 21. . Therefore, it is not necessary to use a separate member such as a retainer for mounting the inflator 24, and the mounting structure for fixing the inflator 24 can be simplified.

  When the airbag device 4 is operated, that is, when gas is supplied from the inflator 24 and the airbag 22 is inflated and deployed, a force that presses the inflator 24 downward is applied. Even if the inflator 24 moves away from the predetermined position with respect to the receiving portion 55 and the inflator 24 tries to move downward, the facing portion 48 abuts against the blocking portion 16 to regulate the movement amount of the inflator 24, that is, the inflator 24 moves beyond the predetermined amount. To stop doing. Since the dimension L2 between the facing part 48 and the blocking part 16 is set to be smaller than the dimension L1 between the substrate part 51 and the gas injection port 46, the maximum of the facing part 48 contacting the blocking part 16 Even if the inflator 24 moves to the limit, the gas injection port 46 is located above the substrate part 51 and is exposed to the inside of the airbag 22, and the gas is supplied from the gas injection port 46 to the inside of the airbag 22. It can supply smoothly and the function of the airbag apparatus 4 can be ensured.

  Further, since the blocking portion 16 is provided integrally with the boss core 9 of the hub core 10 that is a member on the vehicle body side, the inflator 24 can be attached to the base plate 21 by fitting by press fitting, and the base plate 21 is attached to the hub core 10 by fitting. The movement of the inflator 24 can be restricted by making the blocking portion 16 and the facing portion 48 face each other. Therefore, the structure for fixing the inflator 24 can be simplified, the airbag device 4 can be easily reduced in size and weight, and dedicated work such as caulking for preventing the movement of the inflator 24 becomes unnecessary. In addition, a strong fitting holding force that makes it difficult to press-fit is unnecessary, and attachment work can be facilitated. In this way, the configuration and assembly work of the airbag device 4 and the steering wheel 1 provided in the steering wheel 1 can be simplified and the manufacturing cost can be reduced.

  Further, the boss core 9 of the hub core 10 provided with the blocking portion 16 is a high-strength member constituting the steering wheel main body 2 attached to the steering shaft 5 and can reliably hold the inflator 24.

  Further, the base plate 21 is formed by integrally forming a flat substrate portion 51 and a cylindrical fitting receiving portion 55 with resin, and the fitting portion 45 of the inflator 24 is a cylindrical shape of the trunk portion 42 of the container portion 41. Since the concave and convex portions are formed on the outer peripheral portion, a configuration in which the inflator 24 can be attached to the base plate 21 by press-fitting can be easily realized, and the manufacturing cost can be reduced.

  The inflator 24 includes a flange portion 47 projecting from the outer peripheral side of the container portion 41. The flange portion 47 is disposed below the base plate portion 51 of the base plate 21, and the lower surface of the flange portion 47 is opposed to the inflator 24. The upper surface is the upper facing portion 49. Therefore, by abutting the upper facing portion 49 against the base plate 21, positioning of the inflator 24 during press-fitting can be facilitated, and the flange portion 47 is positioned between the base plate 21 and the blocking portion 16 so that the inflator 24 Can be held easily and securely. Further, by bringing the blocking portion 16 into contact with the facing portion 48 provided on the flange portion 47, the blocking portion 16 can be prevented from coming into contact with the container portion 41, and the container portion 41 can be easily protected.

  In the airbag device 4, the airbag 22 is fastened together with a rivet 71 that attaches the cover body 23 to the base plate 21, and can be sandwiched and held between the cover body 23 and the base plate 21. If it is locked to the locking means 18 by press-fitting, it can be held with one touch, which simplifies the configuration and simplifies the manufacturing process and reduces manufacturing costs. In addition, the airbag 22 is not only a portion fastened to the rivet 71, but also has a wide area of the airbag mounting piece 27 along the airbag opening 26 and the peripheral plate portion support portion 61 and the cover body 23 of the base plate 21. It is sandwiched between the lower end portion of the peripheral plate portion 32, force is not concentrated on a part of the peripheral plate portion 32, and can be reliably held with a large surface pressure and frictional resistance.

  In the above embodiment, the dimension L2 is provided between the facing portion 48 and the blocking portion 16 so that the airbag device 4 can be moved with respect to the steering wheel body 2, and the airbag device 4 is operated by a horn switch. However, the present invention is not limited to this configuration. That is, when the airbag device 4 is not used as an operation unit of a horn switch that can move up and down with respect to the steering wheel body 2, the facing portion 48 and the blocking portion 16 are always brought into contact with each other, and the dimension L2 is set to zero. You can also.

  Further, in the above embodiment, the blocking portion 16 has an annular shape, and the facing portion 48 is provided on the flange portion 47 that protrudes so as to surround the outer periphery of the container portion 41. Any shape that touches the surface may be used. For example, the blocking portion 16 can be formed by projecting into a plurality of pins, or the flat upper surface of the boss core 9 can be used as the blocking portion 16. Further, the blocking portion 16 can be formed separately from the boss core 9 and attached to the hub core 10.

  The inflator 24 can also be provided with the facing portion 48 on the bottom plate portion 44 on the bottom surface of the container portion 41 without providing the flange portion 47. Further, the inflator 24 can be configured to be press-fitted into the housing portion 53 of the base plate 21 from the upper side as well as from the lower side.

  Furthermore, the inflator 24 and the base plate 21 can be provided with a configuration in which they are elastically engaged and held. Further, the base plate 21 can take an appropriate structure with respect to the configuration for attaching the airbag 22, and the like.

  For example, as shown in FIGS. 4 and 5, the inflator 24 can be formed with an engagement receiving portion 75 and the base plate 21 can be formed with an engaging portion 76 that engages with the engagement receiving portion 75. . That is, the engagement receiving portion 75 is formed as a lower recessed portion in which the vicinity of the lower end portion of the body portion 42 is recessed in an annular shape that is continuous in the circumferential direction. Further, the engaging portion 76 is formed by notching a part of the side wall portion 54 of the base plate 21 to form an elastically deformable tongue piece, and forming a claw-like projecting portion projecting inward on the tip portion. ing. Therefore, in this configuration, when the body portion 42 of the inflator 24 is press-fitted into the housing portion 53 of the base plate 21, the fitting portion 45 and the fitting receiving portion 55 are fitted, as in the configuration shown in FIG. The joint portion 76 is engaged with the engagement receiving portion 75 so that the inflator 24 is held by the base plate 21.

  4 and 5, the airbag 22 is not held between the cover body 23 and the base plate 21 but is held on the base plate 21 by using a retainer 81 and a plurality of nuts 82. It is attached. In other words, the retainer 81 includes an annular retainer main body 83 and four bolts 84 projecting downward from the retainer main body 83. Further, the base plate 21 has a board portion 51 which is provided with four circular mounting holes 85 surrounding the opening of the housing portion 53. The airbag 22 includes a circular airbag opening 26, and circular mounting holes are provided at four locations surrounding the airbag opening 26. In this retainer 81, the retainer body 83 is inserted into the airbag 22, and the bolts 84 are pulled out of the airbag 22 from the mounting holes. Then, the retainer main body 83 is placed along the upper surface of the base plate portion 51 of the base plate 21, and the four bolts 84 are respectively inserted into the mounting holes 85 of the base plate 21, and the nuts 82 are screwed and tightened from below. The airbag 22 is fixed to the base plate 21. In this configuration, the flange portion 47 of the inflator 24 has a substantially circular planar shape, and a notch 47a that prevents interference with each bolt 84 and nut 82 is formed.

  Further, in this embodiment, the outer peripheral portion of the base plate 21 is raised upward to form a standing wall 90, and a plurality of fixing holes 91 for fixing the cover body 23 are formed in the standing wall 90. Yes. The inside of the standing wall portion 90 is an airbag storage portion in which the folded airbag 22 is stored. The peripheral plate portion 32 of the cover body 23 is fitted to the outer peripheral side of the standing wall portion 90, and the standing wall portion 90 and the peripheral plate portion 32 are connected by a rivet inserted into the fixing hole 91, so that the cover body 23 Is held by the base plate 21.

  In each of the above embodiments, the steering wheel 1 having an annular rim portion has been described. However, the present invention can be applied to a handle having various configurations such as a handle having a grip portion that is not annular. Furthermore, the airbag device 4 is not limited to the one attached to the steering wheel 1, and can be applied to an airbag device provided in an instrument panel for a passenger on the passenger seat. In the case of the airbag device 4 provided in the passenger seat, the blocking portion can be formed integrally with, for example, a lean force that is a steering member of the instrument panel.

  The present invention can be applied to, for example, an airbag device provided in a steering wheel of an automobile.

1 Steering wheel as a handle 4 Airbag device 5 Steering shaft 9 Boss cored bar as member
10 Hub core as a vehicle body member
16 Blocking part
21 Base plate as base body
22 airbag
24 inflator
41 Container
45 Mating part
46 Gas injection port
47 Flange
48 Opposite part
51 Board section
53 containment
55 Fitting receiving part L1 dimension L2 dimension

Claims (4)

A base body provided with a substrate part and a housing part and attached to the vehicle body side member;
An airbag that covers the base body side of the base body and is attached to the base body;
An inflator that includes a container part and an opposing part and supplies gas to the airbag;
A blocking portion provided in the vehicle body side member,
The accommodating portion includes a fitting receiving portion that fits and holds the inflator,
The container portion includes a fitting portion that is fitted and held in the fitting receiving portion in a state in which the container portion is press-fitted into the housing portion along a predetermined direction, and the fitting portion is arranged along the predetermined direction. A gas injection port provided on the side opposite to the vehicle body and located on the side opposite the vehicle body from the substrate portion;
The facing portion faces the blocking portion, and a dimension along the predetermined direction between the facing portion and the blocking portion is a dimension along the predetermined direction between the substrate portion and the gas injection port. An airbag device characterized by being set smaller. In the base body, a plate-shaped substrate portion and a cylindrical fitting receiving portion protruding from the substrate portion toward the vehicle body are integrally formed of resin,
The airbag device according to claim 1, wherein the fitting portion is formed by forming irregularities on a cylindrical outer peripheral portion of the container portion. The inflator is provided with a flange portion that is located on the vehicle body side of the substrate portion and protrudes on the outer peripheral side of the container portion, and the opposing portion is provided on the flange portion. Airbag device. The vehicle body side member is a handle hub core attached to the steering shaft,
The airbag device according to any one of claims 1 to 3, wherein the blocking portion is provided integrally with a member constituting the hub core.

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