JP5470209B2 - Airbag device - Google Patents

Description

  The present invention relates to an airbag device.

  The airbag device includes an airbag bag body (hereinafter referred to as an airbag) formed by joining outer peripheral portions of a first base fabric and a second base fabric, and is a gas supplied from an inflator at the time of a vehicle collision. The airbag is deployed in the passenger compartment to restrain the occupant. In such an airbag device, development of a technology capable of suppressing a fluctuation in internal pressure in an inflating process toward the occupant direction and obtaining a stable buffer effect is being promoted.

As such a technique, a break joint part that breaks in the middle of deployment of the airbag is provided in the airbag in advance, and the volume is gradually increased while suppressing an increase in the internal pressure of the airbag due to the break of the break joint part. The structure which goes is known (for example, refer patent document 1).
In addition, a configuration in which a vent hole for gas discharge is provided in the airbag in order to prevent the internal pressure of the airbag from excessively rising is also known.

Here, Patent Document 2 discloses a configuration in which a vent hole cover that closes the vent hole is provided, and an end portion of the vent hole cover is joined to the airbag by a fracture joint portion. According to this configuration, the vent hole cover is released from the fracture joint by breaking the fracture joint when the airbag is deployed. Then, the vent hole is opened by the vent hole cover being pushed out of the vent hole due to the increase in the internal pressure of the airbag.
Patent Document 3 describes a configuration in which a guide member that covers the vent hole cover is provided, and the movement of the vent hole cover is guided by the guide member when the fracture joint portion is broken.

JP 2005-170206 A JP 2007-302224 A JP 2010-69974 A

  By the way, since the kinetic energy which the passenger | crew has at the time of a collision changes with a passenger | crew's seating position, a physique, etc., this also changes the ideal energy absorption amount in an airbag. That is, for a small occupant seated close to the airbag, the energy absorption amount of the airbag may be less than when a large occupant seated far from the airbag collides with the airbag. desirable. Therefore, in recent years, it has been desired to develop a technique for exhibiting a more ideal energy absorption amount corresponding to various occupants having different seating positions and physiques.

  Here, in order to achieve the ideal energy absorption amount according to the timing of the collision with the airbag due to differences in the seating position and physique of the occupant, the vent hole is opened at the desired timing and the internal pressure of the airbag is increased. It is possible to suppress the rise. At this time, in the configurations of Patent Documents 2 and 3 described above, the vent hole cover may be opened unless the fracture joint portion is broken because the vent hole cover is joined to the airbag by the fracture joint portion. could not.

  Therefore, the present invention has been made in view of such circumstances, and provides an airbag device that can restrain an occupant with an ideal amount of energy absorption according to the contact timing.

In order to solve the above-mentioned problem, the invention described in claim 1 is a first base cloth (for example, the first base cloth 36 in the embodiment) disposed on the steering (for example, the steering wheel 12 in the embodiment) side. And an airbag bag body (for example, an airbag in the embodiment) formed by joining outer peripheral portions of the second base fabric (for example, the second base fabric 37 in the embodiment) disposed on the passenger side. 32) is an airbag device (for example, the airbag device 13 in the embodiment), and the first base fabric and the second base fabric have a first sewing portion (for example, an implementation) for sewing the outer peripheral portions together. A sewing portion 38) in the form, and a second sewing portion (for example, the sewing portion 39 in the embodiment) that can be sewed at the inner side of the first sewing portion and can be broken when the airbag bag body is inflated, Is arranged, wherein the first base fabric, an inflator (e.g., an inflator 31 in the embodiment) an inflator opening which is connected to (e.g., opening 36a in the embodiment) and, provided on the side of the inflator opening vent A hole (for example, the vent hole 36b in the embodiment) is formed, and has a closing portion (for example, the closing portion 53 in the embodiment) that can close the vent hole, and inside the airbag bag body. A vent hole cover (for example, vent hole cover 50 in the embodiment) sewed on the first base fabric and the second base fabric is provided, and the first base fabric has the closed portion of the vent hole cover interposed therebetween. A guide member (for example, the guide portion in the embodiment) that covers the blocking portion and guides the movement of the blocking portion. 61) is provided, and the blocking portion is partly located on the opposite side of the inflator opening side of the first base fabric from the inflator opening side and inside the second sewing portion. The joint member is sewn together with the guide member, so that it is fixed to the first base fabric and moved in the guide member by the collision of the occupant with the second base fabric. open be characterized by Rukoto.

  According to a second aspect of the present invention, the vent hole cover is sewn in the center portion of the first base fabric and the second base fabric, and the deployment width regulation for regulating the deployment width when the airbag bag body is deployed. A base fabric (for example, the base portions 51 and 52 and the restriction portions 54 and 55 in the embodiment) is provided, and moves with a decrease in the deployment width due to the collision of the occupant with the second base fabric, so that the vent hole is It is characterized by opening.

The invention described in claim 3 is characterized in that a through hole (for example, the through hole 61a in the embodiment) is formed in the guide member at a position overlapping the vent hole.

In the invention described in claim 4, wherein the vent hole cover, said a developed width regulating base fabric that restricts the developed width at deployment of the air bag body, the vent hole and can be closed for the closing part (e.g., implemented The expansion width regulating base fabric includes a first base portion (for example, the first base portion 51 in the embodiment) sewn on the first base fabric, and the second base portion. A second base portion sewn on the cloth (for example, the second base portion 52 in the embodiment), and the first restriction portion (for example, the first restriction in the embodiment) that connects the first base portion and the second base portion. Portion 54) and a second restricting portion (for example, the second restricting portion 55 in the embodiment) that connects the second base fabric and the closing portion.

According to the first aspect of the present invention, since the vent hole cover is sewn to the first base fabric and the second base fabric, when the airbag bag body is deployed, the deployment width of the airbag bag body ( The width in the vehicle longitudinal direction) is regulated. In this state, when the occupant collides with the airbag bag body from the second base fabric side and the shape of the airbag bag body changes, the deployment width of the airbag bag body decreases. Then, due to the increase in the internal pressure of the airbag bag body due to the collision, the vent hole cover closing the vent hole is pushed outward from the vent hole, and the airbag bag body is opened. Thereby, the gas in an airbag bag body is discharged | emitted from a vent hole, and the raise of the internal pressure of an airbag bag body can be prevented. That is, when the occupant collides with the second base fabric, the vent hole is opened to relieve the internal pressure of the airbag bag body. Therefore, the occupant can be restrained with an ideal energy absorption amount according to the contact time of the occupant.
In addition , the vent hole cover can be prevented from being exhausted during the deployment of the airbag bag body and before the passenger collides with the airbag bag body, and the vent hole cover can be smoothly vented when the internal pressure increases due to the collision. Can guide you.
Furthermore , by partially sewing the vent hole cover together with the first base fabric together with the guide member, it is possible to reliably prevent displacement of the vent hole cover while allowing movement of the vent hole cover when the internal pressure increases. .

  According to the invention described in claim 2, when the occupant collides with the airbag bag body, the regulation by the deployment width regulation base fabric is released, and the deployment width of the airbag bag body is reduced. This quickly opens the vent hole. Therefore, the internal pressure of the airbag bag body can be relieved in response to a load input to the airbag bag body at the time of collision.

According to the invention described in claim 3 , by forming the through hole so as to overlap the vent hole in the guide member, the internal pressure of the airbag bag body acts on the vent hole cover through the through hole. Thereby, the vent hole can be quickly opened when the internal pressure of the airbag bag body is increased due to the collision.

According to the invention described in claim 4 , when the occupant collides with the airbag bag body from the second base fabric side and the shape of the airbag bag body changes, the regulating portion of the vent hole cover that regulates the deployment width Is loosened between the first base fabric and the second base fabric, thereby reducing the deployment width of the airbag bag. At this time, due to the increase in the internal pressure of the airbag bag body due to the collision, the closed portion is pushed outward from the vent hole. And the 2nd control part connected with the obstruction | occlusion part moves toward a vent hole so that it may be pulled by the movement of an obstruction | occlusion part. As a result, the closed portion jumps out from the vent hole and the vent hole is opened. That is, when the occupant collides with the second base fabric, the airbag bag body is opened to relieve the internal pressure of the airbag bag body, so that the occupant can be restrained with an ideal energy absorption amount according to the contact timing of the occupant. .

It is a perspective view which shows the vehicle interior of the vehicle provided with the airbag apparatus which concerns on embodiment of this invention. It is sectional drawing which follows the AA line of FIG. It is a disassembled perspective view of the airbag in one Example of the airbag apparatus which concerns on this invention. It is the top view which looked at the airbag from the front. It is sectional drawing which follows the BB line of FIG. It is a top view around a vent hole. It is sectional drawing which shows the time of expansion | deployment of an airbag. It is sectional drawing of the airbag corresponded in FIG. 7, and is operation | movement explanatory drawing at the time of a collision.

(Airbag device)
Next, embodiments of the present invention will be described with reference to the drawings. Note that the airbag device described below is an aspect of an airbag device stored in a handle for a vehicle driver, and the front-rear and left-right directions in the following description are directions in the vehicle unless otherwise specified. Same as Moreover, in the figure, the arrow UP indicates the upper side in the vertical direction of the vehicle.

FIG. 1 is a perspective view showing the interior of a vehicle equipped with an airbag device.
As shown in FIG. 1, an airbag device 13 is accommodated in a steering wheel 12 disposed in front of a driver seat 11.

2 is a cross-sectional view taken along line AA in FIG.
As shown in FIG. 2, the steering wheel 12 has a boss portion 16 fixed to the rear end of the steering shaft 14 by a nut 15, and a cup-shaped front cover 17 is fixed to the boss portion 16. A rear cover 19 is fixed to the periphery of the front cover 17 by a plurality of bolts 18 so as to close the front cover 17. A plurality of spoke portions 20 extending radially are attached to the outer peripheral surface of the front cover 17, and a steering wheel main body 21 is supported by the spoke portions 20.

A retainer 22 is fastened together with a bolt 18 on the inner peripheral surface of the rear cover 19, and the airbag device 13 is supported on the retainer 22. The front cover 17 and the rear cover 19 constitute an airbag cover that houses the airbag device 13.
A tear line 19a is formed on the inner surface of the rear cover 19 to promote breakage. When the rear cover 19 is viewed from the front, the tear line 19a is formed in a substantially H-shape, and the rear cover 19 is broken along the tear line 19a so as to be divided into an upper side and a lower side in FIG. Become.

  The airbag device 13 is configured by sewing an inflator 31 filled with a propellant that generates high-pressure gas by combustion, and base fabrics 36 and 37, which will be described later, and is inflated by introduction of high-pressure gas generated from the inflator 31. (Airbag bag body) 32 and a fixing ring 33 for fixing the base of the airbag 32 are provided. The flange 31 a of the inflator 31 and the fixing ring 33 are superposed on the front surface and the rear surface of the retainer 22, and are fastened and fixed with a plurality of bolts 34 and nuts 35. The base portion of the airbag 32 is fixed between the rear surface of the retainer 22 and the front surface of the fixing ring 33.

(Airbag)
3 is an exploded perspective view of the airbag, and FIG. 4 is a plan view of the airbag as viewed from the front. FIG. 5 is a sectional view taken along line BB in FIG.
As shown in FIGS. 3 to 5, the circular airbag 32 includes a first base fabric 36 disposed on the front side (the steering wheel 12 side) and a second base fabric 37 disposed on the front side (occupant side). The outer peripheral portions of the first base fabric 36 and the second base fabric 37 are integrally sewn by a sewing portion 38. Further, the overlapped first and second base fabrics 36 and 37 are sewn by a plurality of spiral sewing portions 39 inside the sewing portion 38. In the present embodiment, the number of spiral sewing portions 39 is three, but may be two or four or more. Further, the outer peripheral sewing portion 38 is firmly sewn with a thick thread so as not to be broken when the airbag 32 is inflated. However, the spiral three sewing portions 39 inside thereof can be broken when the airbag 32 is inflated. It is fragilely sewn with fine thread.
The radially inner end 39a of the spiral sewing part 39 is directed to the center of the airbag 32, and stress is concentrated on the radially inner end 39a when the airbag 32 is deployed to promote the breakage of the sewing part 39. ing.

The first base fabric 36 is a seat positioned on the front side of the vehicle so as to face the steering wheel 12 when the airbag 32 is deployed, and includes a circular opening (inflator opening) 36a surrounding the inflator 31 and a circular vent hole. 36b and a plurality of through holes (not shown) that are formed around the opening 36a and through which the plurality of bolts 34 are respectively inserted.
The opening 36a is disposed at the center of the first base fabric 36, and the tip of the inflator 31 is inserted into the airbag 32 (see FIG. 5). And after inserting the front-end | tip of the inflator 31 in the airbag 32, as mentioned above, the fixing ring 33 and the retainer with the first base fabric 36 sandwiched between the rear surface of the fixing ring 33 and the front surface of the retainer 22. 22 is tightened with a plurality of bolts 34. Therefore, the gas generated by the inflator 31 is supplied into the airbag 32 through the opening 36 a at the center of the first base fabric 36.

  The vent hole 36b is for adjusting the internal pressure of the airbag 32 when the airbag 32 is deployed, and is a circular through hole for releasing a part of the gas introduced into the airbag 32 to the outside. . The vent hole 36b is disposed adjacent to the upper side of the opening 36a and is eccentric from the center of the first base fabric 36.

  Here, the airbag 32 is provided with a vent hole cover 50 for controlling its internal pressure. The vent hole cover 50 is a member that can close the vent hole 36b and is movable so as to open the vent hole 36b when a passenger collides with the airbag 32. The vent hole cover 50 is formed by forming the same material as the first base cloth 36 and the second base cloth 37 into a U shape. Specifically, the vent hole cover 50 includes a first base part (deployment width regulating base cloth) 51 sewn at the center part of the first base cloth 36 and a second base part sewn at the center part of the second base cloth 37. A base part (expansion width restricting base fabric) 52; a closing part 53 capable of closing the vent hole 36b; a first restricting part (deployment width restricting base cloth) 54 connecting the base parts 51 and 52; A second restricting portion (deployment width restricting base fabric) 55 that connects the base portion 52 and the closing portion 53 to each other is integrally formed.

  The first base portion 51 is an annular member surrounding the periphery of the opening 36a, and has a through hole 51a formed with an inner diameter equivalent to that of the opening 36a. The first base portion 51 is sewn to the first base cloth 36 by a sewing portion 56 with the through hole 51a and the opening 36a being overlapped. In addition, a plurality of through holes (not shown) formed corresponding to the through holes (not shown) of the first base fabric 36 are formed around the through holes 51a. The first base portion 51 is sandwiched between the rear surface of the fixing ring 33 and the front surface of the retainer 22 together with the first base fabric 36, and is fastened to the retainer 22 together with the first base fabric 36 by bolts 34. Thereby, the opening 36a periphery can be reinforced.

  The second base portion 52 is a circular member formed with substantially the same diameter as the first base portion 51, and the outer peripheral portion is a central portion (a position facing the first base portion 51) in the second base cloth 37. It is sewn by the sewing part 57.

  The blocking portion 53 is a rectangular member that is formed so as to cover the vent hole 50 from the rear side and whose longitudinal direction is the vertical direction, and is shared with the first base fabric 36 together with a guide member 61 described later on the rear surface side. Sewn. The guide member 61 is a rectangular member that is formed to be larger than the vent hole 36 b and is made of the same material as the base cloths 36 and 37 and the vent hole cover 50. The guide member 61 has a through hole 61a at a position overlapping the vent hole 36b in the front-rear direction.

FIG. 6 is a plan view around the vent hole.
As shown in FIG. 6, the closing portion 53 and the guide member 61 are stitched together with the first base fabric 36 by the sewing portion 58. The sewing part 58 has a U-shape surrounding the upper part of the guide member 61 and the left and right peripheral parts, and the closing part 53 is sewn to the first base fabric 36 by an upper sewing part 58a. That is, the closing portion 53 is arranged inside the left and right sewing portions 58b, and only one end side (upper end side) in the longitudinal direction is sewn to the first base cloth 36 by the upper sewing portion 58a. Accordingly, the closing portion 53 is movable along the extending direction (vertical direction) of the left and right sewing portions 58b in the guide path 62 surrounded by the first base cloth 36, the guide member 61, and the left and right sewing portions 58b. It is configured.

  Returning to FIGS. 3 to 5, the first restricting portion 54 is a band-shaped member that integrally connects parts of the first base portion 51 and the second base portion 52 in the circumferential direction. It is stored in a folded state. The length of the first restricting portion 54 is formed to be equal to a desired deployment width H (length in the front-rear direction of the vehicle) when the airbag 32 is deployed. In other words, the first restricting portion 54 connects the first base cloth 36 and the second base cloth 37 via the base portions 51 and 52, and restricts the deployment of the airbag 32 beyond the deployment width H. is there.

  The second restricting portion 55 is a band-like member having a width equivalent to that of the first restricting portion 54, and one end of the second restricting portion 55 is opposite to the connection portion of the first restricting portion 54 in the second base portion 52 (in the circumferential direction). The other end side is connected to the other end side in the longitudinal direction (lower end side) of the closing portion 53. Further, the length of the second restricting portion 55 is formed to be equal to that of the first restricting portion 54, and restricts the deployment of the airbag 32 beyond the deploying width H together with the first restricting portion 54.

(Function)
Next, the operation of the above-described airbag device will be described.
In the airbag device 13 of the present embodiment, the inflator 31 is ignited when a gravitational acceleration of a predetermined value or more is detected at the time of a vehicle collision, and the folded airbag 32 starts to inflate with the gas generated from the inflator 31. When the airbag 32 is inflated, the rear cover 19 is broken at the tear line 19a by receiving this pressure, and the airbag 32 is deployed into the vehicle compartment from the opening formed there.

FIG. 7 is a cross-sectional view showing the airbag when deployed.
As shown in FIG. 7, when the airbag 32 is inflated, three spiral sewing parts 39 integrally join the first base fabric 36 and the second base fabric 37, so that the airbag 32 is inflated at a stretch. First, a small-capacity airbag 32 is formed early (first deployed state A in FIG. 7). At this time, since the first base cloth 36 and the second base cloth 37 are connected to each other by the vent hole cover 50, the deployment width H of the airbag 32 is equal to the length of the restriction portions 54 and 55 of the vent hole cover 50. become. That is, the airbag 32 is deployed in a flat shape in the front-rear direction.

  Thereafter, as the internal pressure of the airbag 32 increases, the three sewing portions 39 break from the radially inner side to the outer side, so that the airbag 32 gradually increases in volume while maintaining an appropriate internal pressure (in FIG. 7). In the second unfolded state B and the third unfolded state C), the base fabrics 36 and 37 are finally joined only by the sewing portion 38 (final unfolded state D in FIG. 7). However, in this case as well, the first base fabric 36 and the second base fabric 37 are connected by the vent hole cover 50, so that the first base fabric 36 and the second base fabric 37 are deployed outward in the radial direction while maintaining the development width H.

  When the airbag 32 is deployed, the vent hole 36b is closed by the closing portion 53 of the vent hole cover 50 and gas leakage is suppressed, so that the internal pressure of the airbag 32 is quickly raised and the internal pressure is increased. Can be held appropriately. After the airbag 32 reaches the final deployed state D, the internal pressure of the airbag 32 is maintained until a collision with the occupant J occurs.

FIG. 8 is a cross-sectional view of the airbag corresponding to FIG. 7, and an operation explanatory diagram at the time of collision.
Here, as shown in FIG. 8, when the occupant J collides with the airbag 32 in the final deployed state D of the airbag 32, the airbag 32 is deformed due to the collision, so that the airbag 32 is deployed at the center of the airbag 32. The width H decreases. At this time, the restricting portions 54 and 55 of the vent hole cover 50 restricting the development width H are loosened in the front-rear direction between the first base cloth 36 and the second base cloth 37 (the restriction by the restricting portions 54 and 55 is released). ) Further, due to the increase in the internal pressure of the airbag 32 due to the collision, the closing portion 53 is pushed forward (outward) through the through hole 61a of the guide member 61. At this time, the second restricting portion 55 connected to the closing portion 53 moves upward in the guide path 62 (between the first base cloth 36 and the guide member 61) so as to be pulled by the movement of the closing portion 53. Moving. As a result, the blocking portion 53 jumps out from the vent hole 36b toward the outside, and the vent hole 36b is opened.

  As a result, excess gas in the airbag 32 is discharged from the vent hole 36b, and an excessive increase in the internal pressure of the airbag 32 can be prevented. At this time, since the closing portion 53 and the second restricting portion 55 move in the guide path 62 toward the vent hole 36b, the closing portion 53 and the second restricting portion 55 are prevented from being displaced and closed when a load is input. The portion 53 can be smoothly guided to the vent hole 36b. Moreover, since the vent hole 36b is provided in the 1st base fabric 36, the gas discharged | emitted from the vent hole 36b does not hit the passenger | crew J directly, and does not give the passenger | crew J discomfort.

  By the way, a small passenger seated at a position close to the airbag device 13 collides with the airbag 32 earlier than a large passenger seated at a position far from the airbag device 13.

  Here, when the occupant J collides with the airbag 32 before the airbag 32 reaches the final deployed state D (for example, the first deployed state A), the airbag 32 is deformed by the collision, so that the airbag 32 is deformed. The developing width H decreases at the center portion of. At this time, similarly to the collision in the final deployed state D described above, the closing portion 53 jumps out from the vent hole 36b and the vent hole 36b is opened. That is, in the airbag 32 of this embodiment, when the occupant J contacts the airbag 32 and is deformed regardless of the deployed state, the closing portion 53 is pushed out from the vent hole 36b to the outside. The hole 36b is opened. As a result, excess gas in the airbag 32 is discharged from the vent hole 36b, and an excessive increase in the internal pressure of the airbag 32 can be prevented.

As described above, in the present embodiment, the vent hole cover 50 is sewn to the first base cloth 36 and the second base cloth 37 so as to regulate the deployment width H of the airbag 32 and the second base cloth 37 of the occupant. The vent hole 36b is opened by the collision.
According to this configuration, the shape of the airbag 32 changes due to the collision of the occupant, and the deployment width H of the airbag 32 decreases, so that the closing portion 53 that closes the vent hole 36b is removed from the vent hole 36b. The air bag 32 is pushed out. Thereby, the gas in the airbag 32 is discharged | emitted from the vent hole 36b, and the raise of the internal pressure of the airbag 32 can be prevented. That is, when the occupant collides with the second base cloth 37, the airbag 32 is opened and the internal pressure of the airbag 32 can be relieved, so that the occupant can be restrained with an ideal energy absorption amount according to the contact timing of the occupant.

  At this time, since the closing portion 53 of the vent hole cover 50 is connected to the second restricting portion 55, the vent hole 36b is quickly opened when the deployment width H of the airbag 32 decreases. Thereby, the internal pressure of the airbag 32 can be relieved in response to the load input to the airbag 32 promptly.

Further, since one end side of the closing portion 53 in the vent hole cover 50 is sewn together with the first base fabric 36 together with the guide member 61, the movement of the closing portion 53 when the internal pressure rises is allowed, It is possible to prevent displacement of the closing portion 53, the vent hole 36b, and the guide member 61 during the deployment and before the occupant collides with the airbag 32. Therefore, exhaust due to unintended displacement of the blocking portion 53 can be prevented.
Further, by forming the through hole 61a in the guide member 61 so as to overlap the vent hole 36b, the internal pressure of the airbag 32 acts on the closing portion 53 through the through hole 61a. Accordingly, the vent hole 36b can be quickly opened when the internal pressure of the airbag 32 increases.
In addition, the vent hole cover 50 according to the present embodiment includes the base portions 51 and 52, the closing portion 53, and the restricting portions 54 and 55, which are integrally formed. Processes can be reduced.

As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, the concrete structure is not restricted to this embodiment, The design change etc. of the range which does not deviate from the summary of this invention are included.
For example, the shape of the vent hole cover 50 is not limited to the above-described embodiment, and the design can be appropriately changed as long as the closing portion 53 is closed while the deployment width H of the airbag 32 is restricted. .
In the above-described embodiment, the aspect of the airbag device stored in the handle has been described. However, the present invention can also be applied to an airbag device other than the handle retractable type.

DESCRIPTION OF SYMBOLS 12 ... Steering wheel (steering) 13 ... Air bag apparatus 31 ... Inflator 32 ... Air bag (airbag bag body) 36 ... 1st base fabric 36a ... Opening (inflator opening) 36b ... Vent hole 37 ... 2nd base fabric 50 ... Vent hole cover 51 ... 1st base part (deployment width regulation base fabric) 52 ... 2nd base part (deployment width regulation base fabric) 53 ... Closure part (deployment width regulation base fabric) 54 ... 1st regulation part (deployment width regulation) 55) 2nd regulation part (deployment width regulation base fabric) 61 ... Guide member 61a ... Through-hole

Claims (4)

An airbag device including an airbag bag body configured by joining outer peripheral portions of a first base fabric disposed on a steering side and a second base fabric disposed on an occupant side,
The first base fabric and the second base fabric are sewn between a first sewing portion that sews the outer peripheral portions and inner portions of the first sewing portion, and can be broken when the airbag bag body is inflated. A second sewing portion is disposed,
In the first base fabric, an inflator opening connected to the inflator, and a vent hole provided on a side of the inflator opening are formed,
A vent hole cover sewn to the first base cloth and the second base cloth inside the airbag bag body, and having a closing portion capable of closing the vent hole;
The first base fabric is provided with a guide member for covering the closing portion with the closing portion of the vent hole cover interposed therebetween and guiding the movement of the closing portion,
The closing portion is a portion of the first base fabric that is located on the opposite side of the inflator opening side with respect to the vent hole and on the inner side of the second sewing portion. by being sewn and said is fixed to the first base fabric, by moving the guide member by collision to the second base fabric of the occupant, characterized that you open the vent hole An airbag device.   The vent hole cover is provided with a deployment width regulating base fabric that is sewn in a central portion of the first base fabric and the second base fabric and regulates a deployment width when the airbag bag body is deployed, The airbag apparatus according to claim 1, wherein the vent hole is opened as the deployment width decreases due to a collision with the second base fabric. The airbag device according to claim 1 or 2 , wherein a through hole is formed in the guide member at a position overlapping the vent hole. The vent hole cover is provided with a developed width regulating base fabric that restricts the developed width at deployment of the air bag body, and a said closed portion that can close the vent hole,
The spread width regulating base fabric includes a first base portion sewn on the first base fabric, a second base portion sewn on the second base fabric, the first base portion, and the second base portion. a first regulating portion for coupling, according to any one of claims 1 to 3, characterized in that it comprises a and a second regulating portion for connecting said second base fabric and said closure portion Airbag device.

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