JP6194802B2 - Mounting structure of pedestrian protection airbag device for vehicles with hood - Google Patents

Description

  The present invention relates to a mounting structure for a pedestrian protection airbag device for a hooded vehicle.

  Patent Document 1 below discloses an invention relating to a seal structure of a vehicle hood airbag device. In this seal structure for a vehicle hood airbag device, an airbag module is disposed inside the hood. Thus, when the vehicle collides with a pedestrian, the airbag door provided in the hood is deployed, and the hood airbag is inflated and deployed along the rear end of the hood and the left and right front pillars.

  Patent Document 2 listed below discloses an invention relating to a pedestrian airbag apparatus. In this pedestrian airbag device, the airbag module is disposed on the lower surface side of the rear end portion of the hood. As a result, when the vehicle collides with a pedestrian, the cover provided at the rear end of the hood is pressed and deployed by the hood airbag, and the rear end of the hood is pushed up, and in that state toward the windshield glass The hood airbag is inflated and deployed.

JP 2007-196801 A Japanese Patent Laid-Open No. 2005-178487

  However, in the case of the prior art described in Patent Document 1, since the airbag door is provided on the design surface of the hood, the degree of freedom in design of the hood is limited.

  On the other hand, in the case of the prior art described in Patent Document 2, since the hood airbag is inflated and deployed from the rear end portion of the hood toward the windshield glass, the prior art described in Patent Document 1 is used. In comparison, the design freedom of the hood is ensured. However, in the prior art described in Patent Document 2, when the hood airbag is deployed, the hood is pressed toward the front side of the vehicle in response to the deployment reaction force of the hood airbag. Concentrate. As a result, the behavior of the hood when the hood airbag is deployed may not be stable, and as a result, the deployment behavior of the hood airbag may not be stable.

  In consideration of the above facts, the present invention can provide a mounting structure for a pedestrian protection airbag device for a hooded vehicle that can stabilize the deployment behavior of the hood airbag while ensuring the freedom of design of the hood. Is the purpose.

The mounting structure of the pedestrian protection airbag device for a hooded vehicle according to the first aspect of the present invention is disposed on the lower side of the rear end portion of the hood whose rear end portion can be raised to the vehicle upper side. An inflator that ejects gas when activated, and is stored in a folded state on the lower side of the rear end of the hood, and the rear end of the hood and the windshield are supplied with gas from the inflator A pedestrian protection airbag that is inflated and deployed from between the glass and the rear upper surface of the vehicle; a hood hinge mounting portion that is provided below the rear end of the hood and to which the hood hinge is attached; and the rear end of the hood A support wall that is provided on a lower side of the portion and that supports the deployment reaction force of the pedestrian protection airbag on the vehicle front side of the inflator. And it has a base portion that transmits to the hood hinge attachment portion the deployment reaction forces through the section member, wherein the base portion is coupled to the hood hinge attachment portion via the coupling member as the member Yes.

The mounting structure of the pedestrian protection airbag device for a hooded vehicle according to the second aspect of the present invention is disposed on the lower side of the rear end portion of the hood whose rear end portion can be raised to the vehicle upper side. An inflator that ejects gas when activated, and is stored in a folded state on the lower side of the rear end of the hood, and the rear end of the hood and the windshield are supplied with gas from the inflator A pedestrian protection airbag that is inflated and deployed from between the glass and the rear upper surface of the vehicle; a hood hinge mounting portion that is provided below the rear end of the hood and to which the hood hinge is attached; and the rear end of the hood A support wall that is provided on a lower side of the portion and that supports the deployment reaction force of the pedestrian protection airbag on the vehicle front side of the inflator. And having a base portion for transmitting the deployment reaction forces directly to prior SL hood hinge attachment portion, the base portion, the hood along the rear portion of the hood inner panel constituting the inner member of the hood A first bulging portion that is integrally formed with the inner panel and bulges downward in the vehicle, and extends in the vehicle front-rear direction along each of the vehicle width direction both ends of the hood inner panel and integrally with the hood inner panel. The first bulging portion and the second bulging portion are integrally formed, including a second bulging portion that is formed and connected to the first bulging portion and bulges downward in the vehicle. The hood hinge mounting portion is provided integrally with the second bulge portion, and the second bulge portion extends from the boundary portion with the first bulge portion to the vehicle rear side. And forward extending from the boundary portion to the vehicle front side It is configured to include a left portion, a.

The mounting structure of the hooded vehicle pedestrian protection airbag device according to the present invention as set forth in claim 3 is the invention according to claim 2 , wherein the width of the rear bulge portion is larger than the width of the front bulge portion. The length of the front bulge portion in the vehicle front-rear direction is set to be longer than the length of the rear bulge portion in the vehicle front-rear direction, and the hood hinge mounting portion is Provided in the department.

  According to the first aspect of the present invention, when the inflator disposed on the lower side of the rear end of the hood is operated, gas is ejected from the inflator. This gas is supplied into a pedestrian protection airbag stored in a folded state on the lower side of the rear end of the hood. On the other hand, the rear end of the hood rises to the vehicle upper side, and an opening for inflating and deploying the pedestrian protection airbag is formed. For this reason, the pedestrian protection airbag is inflated and deployed from the rear end of the hood and the windshield glass toward the rear upper surface of the vehicle. Thus, in this invention, in order to deploy a pedestrian protection airbag, it is not necessary to provide an airbag door etc. in a hood.

  By the way, the hood is attached to the hood hinge at the hood hinge attachment portion, and the vehicle body and the hood are connected by the hood hinge. For this reason, when the inflator is activated and the pedestrian protection airbag is inflated and deployed, the deployment reaction force at that time acts on the inflator, and the hood receives the deployment reaction force and is pressed toward the front side of the vehicle. As a result, it is conceivable that stress concentrates on the periphery of the hood hinge mounting portion in the hood.

Here, in this invention, the base part is provided in the downward side of the rear-end part of the food | hood, and the inflator is being fixed to the said base part. A support wall is provided on the vehicle front side of the inflator in the base portion, and the deployment reaction force of the pedestrian protection airbag is supported by the support wall, and the deployment reaction force is directly or via a member. Is transmitted from the base portion to the hood hinge mounting portion. For this reason, the deployment reaction force when the pedestrian protection airbag is inflated and deployed can be transmitted from the base portion to the hood hinge. As a result, it is possible to transmit the deployment reaction force when the pedestrian protection airbag is inflated and deployed to the vehicle body via the hood hinge, thereby suppressing the concentration of stress on the periphery of the hood hinge mounting portion in the hood. be able to.
Moreover, in this invention, the base part is connected with the hood hinge attachment part via the connection member. For this reason, even if the shape of the base portion and the positional relationship between the base portion and the hood hinge attachment portion are changed according to the shape of the hood, the base portion and the hood hinge attachment portion are changed by changing the shape of the connecting member. Can be connected.

  According to the second aspect of the present invention, the rear end portion of the hood is reinforced by the first bulge portion, and both end portions of the hood in the vehicle width direction are reinforced by the second bulge portion. Further, the hood hinge mounting portion is provided integrally with the second bulge portion. Therefore, the base portion can integrally reinforce the rear end portion of the hood and both end portions in the vehicle width direction, thereby improving the rigidity of the entire hood.

As described above, the mounting structure of the pedestrian protection airbag device for a hooded vehicle according to the first aspect of the present invention stabilizes the deployment behavior of the hood airbag while ensuring the freedom of design design of the hood. It has an excellent effect of being able to be made.
In addition, the present invention has an excellent effect that the deployment reaction force when the pedestrian protection airbag is inflated and deployed can be transmitted to the hood hinge while ensuring the design freedom of the hood.

  The mounting structure of the pedestrian protection airbag device for a hooded vehicle according to the second aspect of the present invention distributes the deployment reaction force when the pedestrian protection airbag is inflated and deployed to the entire hood, and the deployment reaction force It has an excellent effect that it can be transmitted to the hood hinge.

It is the bottom view which looked at the hood concerning a 1st embodiment from the vehicles lower part side. It is a principal part expansion perspective view which fractures | ruptures and shows the principal part of the pedestrian protection airbag apparatus of a non-operation state concerning 1st Embodiment. (A) is a longitudinal cross-sectional view which shows the non-operation state of a pedestrian protection airbag apparatus, (B) is a longitudinal cross-sectional view which shows the operation state of a pedestrian protection airbag apparatus. It is a perspective view which shows the state which the pedestrian protection airbag apparatus act | operated and the pedestrian protection airbag inflate-deployed in relation to a motor vehicle. (A) is the bottom view which looked at the hood which concerns on 2nd Embodiment from the vehicle downward side, (B) is an expanded longitudinal cross-sectional view of the hood along the XX line of (A).

[First Embodiment]
A first embodiment of a vehicle pedestrian protection airbag device to which the mounting structure of a hooded vehicle pedestrian protection airbag device according to the present invention is applied will be described below with reference to FIGS. Note that an arrow FR appropriately shown in each figure indicates the vehicle front side, and an arrow UP indicates the vehicle upper side. Furthermore, the arrow IN indicates the inner side in the vehicle width direction.

  As shown in FIGS. 3 and 4, a hood 14 is provided on the upper surface side of an engine room (power unit chamber) 12 that houses a power unit 11 of a vehicle (automobile) 10. The front end of the hood 14 is normally locked to the vehicle body 15 by a hood lock (not shown).

  On the other hand, as shown in FIG. 1, a hood hinge mounting portion 76 described later is provided on both sides in the vehicle width direction of the rear end portion 16 of the hood 14, and the hood hinge 24 is attached to the hood hinge mounting portion 76. Is attached. More specifically, the hood hinge 24 includes a hinge base (not shown) fixed to the vehicle body 15 and one end fixed to the hood hinge mounting portion 76 and the other end pin-connected to the hinge base. And a hinge arm 25 that is swingable.

  Returning to FIG. 4 and continuing the description, pop-up devices 18 that raise the rear end portion 16 of the hood 14 at the time of a collision with a pedestrian are disposed on both sides of the rear end portion of the hood 14 in the vehicle width direction. Thereby, the rear end portion 16 of the hood 14 can be raised to the vehicle upper side. In FIG. 4, the pop-up device 18 is schematically illustrated by a rod-shaped member that rises when the gas generating means is operated. However, the rear end portion 16 of the hood 14 may be popped up by a link mechanism. However, various configurations can be adopted.

  2 and 3A, the hood 14 is disposed outside the vehicle and forms a design surface of the hood 14, and the hood outer panel 20 is disposed on the engine room 12 side. And a hood inner panel 22 for reinforcing the structure. As will be described later, the hood inner panel 22 is formed with a bulging portion 70 as a base portion. The bulging portion 70 has a vehicle pedestrian protection airbag device (hereinafter simply referred to as “air”). 28) is also attached.

  The airbag device 28 includes a module case 30 formed in a long and substantially box shape with the vehicle width direction as a longitudinal direction, and a hood airbag stored in a folded state in the module case 30, that is, pedestrian protection. An air bag (hereinafter also simply referred to as “air bag”) 32, an inflator 34 that injects gas at the time of collision with a pedestrian and supplies the air bag 32, and an inflator 34 for fixing the inflator 34 to the hood 14 to be described later. And an inflator mounting bracket 36.

  The module case 30 includes an upper mounting wall 30A, a front wall portion 30B that is bent upward from the rear end portion of the upper mounting wall 30A and is erected toward the vehicle rear upper side, and an upper end portion of the front wall portion 30B. The upper wall portion 30C extending from the rear side to the vehicle rear side, the rear wall portion 30D bent from the rear end portion of the upper wall portion 30C to the vehicle lower side, and the lower end portion of the rear wall portion 30D extending to the vehicle front side. The lower wall portion 30E that is taken out, the lower mounting wall 30F that extends from the lower wall portion 30E to the vehicle front side as it is and is disposed on the lower side of the upper mounting wall 30A, and left and right side wall portions (not shown) It is configured to include. The upper wall portion 30 </ b> C is disposed along the general wall 22 </ b> A of the hood inner panel 22. The rear wall portion 30D is disposed substantially parallel to the front wall portion 30B, and the lower wall portion 30E is disposed substantially parallel to the upper wall portion 30C.

  In addition, a V-shaped groove is formed on the inner side of the case at the upper corner of the module case 30 (the corner where the upper wall 30C and the rear wall 30D are connected), thereby forming a thin wall. A tiered portion 38 is formed. The tier portion 38 has lower strength and rigidity than the general portion of each wall.

  As shown in FIGS. 2 to 4, the airbag 32 is formed in a bag shape by sewing the outer peripheral portions of two base fabrics as an example. In a state where the airbag 32 is inflated and deployed, the bag main body portion 40 extending in the vehicle width direction along the rear end portion 16 of the hood 14, the bag main body portion 40 and the pair of left and right front pillars 42 are connected. And a pair of bag side portions 44 covering the front surface. Further, the bag main body 40 is formed in a cylindrical shape from between the bag base portion 40A that expands in the vehicle width direction along the lower surface of the rear end portion 16 of the hood 14, and between the rear end portion 16 of the hood 14 and the windshield glass 46. The bag cylindrical portion 40B is inflated and deployed to cover the front surface of the lower end portion 46A of the windshield glass 46. The airbag 32 having the above configuration is stored in the module case 30 in a state of being folded by bellows folding or roll folding.

  Inside the airbag 32 described above, a pair of left and right inflators 34 are disposed, and the inflator 34 is made of metal and is formed in a cylindrical shape with both axial ends closed. A squib (ignition device) (not shown) is disposed at the axial center of one end of the inflator 34 in the axial direction. The inflator 34 is filled with a gas generating agent that generates a large amount of gas by combustion, and is generated when the coolant and the gas generating agent for cooling the generated high-temperature gas are combusted. A filter or the like for removing debris is accommodated. The inflator 34 is a type of inflator that uses a gas generating agent, but an inflator in which high-pressure gas is sealed may be used. A plurality of gas ejection holes are formed in the peripheral wall portion of the inflator 34.

  The inflator 34 is connected to a controller (airbag ECU) (not shown) disposed at the center of the vehicle body floor. The controller is connected to a collision detection sensor (not shown) or a pre-crash sensor (not shown) disposed on a front bumper (not shown) arranged at the front end of the vehicle (automobile) 10 with the vehicle width direction as a longitudinal direction. Yes. As the collision detection sensor, for example, a long pressure chamber or pressure tube disposed along the front bumper on the back surface side of the front bumper, and a pressure sensor for detecting a change in internal pressure of the pressure chamber or pressure tube What was comprised by this is applicable. Further, a so-called optical fiber system in which a long optical fiber sensor is arranged along the front bumper may be applied. On the other hand, as a pre-crash sensor, for example, a sensor that predicts a collision with a collision object such as a pedestrian using a millimeter wave radar provided in a radiator grill or a stereo camera mounted in a vehicle interior is applicable. is there.

  Here, in the present embodiment, the pedestrian protection airbag device for a hooded vehicle configured to include the inflator mounting bracket 36 and the bulging portion 70 as a “base portion” formed on the hood inner panel 22. The airbag device 28 is fixed by the mounting structure. Hereinafter, the mounting structure of the pedestrian protection airbag device for a hooded vehicle centering on the bulging part 70 which is the main part of the present invention will be described in detail.

  First, the inflator mounting bracket 36 that fixes the inflator 34 to the bulging portion 70 will be described. As shown in FIG. 2, the inflator mounting bracket 36 is manufactured by press-molding a strip-shaped metal plate that is elongated in the vehicle longitudinal direction. Structurally, the inflator mounting bracket 36 includes a first fixing portion 48 fixed to the bulging portion 70 and a second fixing portion 50 to which the inflator 34 is fixed as main elements.

  The first fixing portion 48 is formed in a rectangular flat plate shape, and is sandwiched between the upper mounting wall 30A and the lower mounting wall 30F of the airbag 32. Moreover, the 2nd fixing | fixed part 50 is formed in the substantially 1/4 cylinder shape, and the inflator 34 is being fixed to the upper surface of this 2nd fixing | fixed part 50 by welding. In the state where the airbag device 28 is assembled, the inflator 34 is in contact with the front wall portion 30B and the upper wall portion 30C of the module case 30.

  On the other hand, as shown in FIGS. 1 and 2, the bulging portion 70 includes a first bulging portion 72 integrally formed along the rear end portion of the hood inner panel 22 and the vehicle width of the hood inner panel 22. And a second bulging portion 74 integrally formed along both ends in the direction, and is formed in an H shape in plan view.

  More specifically, the first bulging portion 72 includes a bottom wall 72A facing the vehicle lower side and a rear end wall 72B as a “support wall” facing the module case 30, and extends along the vehicle width direction. While extending, it swells to the vehicle lower side and forms a closed cross section with the hood outer panel 20. Accordingly, the rear end portion 16 of the hood 14 is reinforced by the first bulging portion 72, in other words, the first bulging portion 72 functions as a reinforcing member. The first bulging portion 72 is formed at a position offset to the vehicle lower side of the rear end portion 16 of the hood 14, more specifically to the vehicle front side from directly below the rear end portion 16 of the hood 14. . The bottom wall 72A and the rear end wall 72B of the first bulge portion 72 are in contact with the upper mounting wall 30A of the module case 30 against the bottom wall 72A, while the front wall portion 30B of the module case 30 is against the rear end wall 72B. The shape is set so that can be brought into contact with each other.

  Similarly to the first bulge 72, the second bulge 74 bulges downward in the vehicle, forms a closed cross section with the hood outer panel 20, and extends along the vehicle front-rear direction. It is formed integrally (connected) with the bulging portion 72. Thereby, both the vehicle width direction both ends of the hood 14 are reinforced by the 2nd bulging part 74, and the 2nd bulging part 74 functions as a reinforcement member in other words. The width of the second bulge portion 74 on the vehicle rear side with respect to the boundary portion with the first bulge portion 72 (hereinafter referred to as “rear bulge portion 74A”) is greater on the vehicle front side than the boundary portion. (Hereinafter referred to as “front bulge portion 74B”). Further, the length of the front bulge portion 74B in the vehicle front-rear direction is set to be longer than the length of the rear bulge portion 74A in the vehicle front-rear direction. Note that the four corners at the boundary between the first bulging portion 72 and the second bulging portion are all formed in a smooth curved surface.

  In the bulging portion 70 formed as described above, the storage space 26 is formed on the vehicle rear side of the first bulging portion 72 in the hood inner panel 22 by the first bulging portion 72 and the rear bulging portion 74A. Yes. An air bag device 28 is disposed in the storage space 26. On the other hand, as shown in FIG. 2, a bolt insertion hole 54 is formed in the first fixing portion 48 of the inflator mounting bracket 36. Correspondingly, bolt insertion holes 56, 58 are formed on the upper mounting wall 30 </ b> A and the lower mounting wall 30 </ b> F of the module case 30 coaxially with the bolt insertion hole 54 of the first fixing portion 48. Then, the mounting bolts 60 are inserted into the bolt insertion holes 56, 54, 58 in this order from the lower side of the vehicle, and screwed into the weld nut 62 provided on the upper surface of the bottom wall 72 A of the first bulge portion 72. Yes. Thereby, the inflator mounting bracket 36 and the module case 30 are fastened together with the bottom wall 72 </ b> A of the first bulging portion 72, and as a result, the airbag device 28 is fixed to the hood 14.

  Further, in the state where the airbag device 28 is assembled to the first bulging portion 72, the upper mounting wall 30A of the module case 30 is on the bottom wall 72A, and the front wall portion 30B of the module case 30 is on the rear end wall 72B. It is contacted in a surface contact state. Further, since the airbag device 28 is disposed on the vehicle rear side of the first bulging portion 72, the airbag device 28 is retracted between the airbag device 28 and the power unit 11, as shown in FIG. A space (energy absorption space) 78 is secured.

  On the other hand, as shown in FIG. 1, the rear bulge portion 74A of the second bulge portion 74 is provided with a hood hinge attachment portion 76 integrally with the rear bulge portion 74A. The hood hinge mounting portion 76 includes a weld nut (not shown) provided on the upper surface of the bottom wall 74 </ b> C of the second bulge portion 74. Correspondingly, a bolt insertion hole (not shown) is formed at one end of the hinge arm 25. The mounting bolt 80 is inserted into the bolt insertion hole from the lower side of the vehicle and screwed into the weld nut of the hood hinge mounting portion 76, so that the hinge arm 25 is mounted on the hood hinge mounting portion 76. Accordingly, the hood 14 is attached to the hood hinge 24, and the vehicle body 15 and the hood 14 are connected by the hood hinge 24. In the present embodiment, as an example, the vertical cross-sectional shapes of the first bulge portion 72 and the second bulge portion 74 are widened toward the vehicle upper side, and are trapezoidal with the vehicle upper side open. Yes. In addition, the longitudinal cross-sectional shapes of the first bulging portion 72 and the second bulging portion 74 may be set to an arc shape or the like as long as the airbag device 28 and the hood hinge 24 can be attached. .

(Operation and effect of this embodiment)
Next, the operation and effect of this embodiment will be described.

  In a state before colliding with a pedestrian, as shown in FIGS. 2 and 3A, the pop-up device 18 and the airbag device 28 are maintained in an inoperative state. That is, the rear end portion 16 of the hood 14 is not popped up, and the airbag 32 is stored in a folded state in the module case 30.

  If it collides with a pedestrian from this state, it will detect that it collided with the pedestrian by the collision detection sensor not shown provided in the front bumper. The same applies when a collision with a pedestrian is predicted using a pre-crash sensor or a stereo camera. As a result, as shown in FIG. 3B, the pop-up device 18 is first actuated by a controller (not shown), and the rear end portion 16 of the hood 14 is raised (popped up) to a predetermined height above the vehicle. . As a result, an opening for inflating and deploying the airbag 32 is formed.

  Further, when the rising amount of the rear end portion 16 of the hood 14 reaches a predetermined amount, the inflator 34 of the airbag device 28 is operated by a controller (not shown). For this reason, gas is ejected from the gas ejection holes of the inflator 34, and the gas is supplied into the folded airbag 32. As a result, the airbag 32 starts to expand in the module case 30 and the tensile load applied to the tier portion 38 of the module case 30 increases. When the tensile load applied to the tier portion 38 reaches a predetermined value, as shown in FIG. 3B, the tier portion 38 breaks, and the rear wall portion 30D and the lower wall portion 30E of the module case 30 are located below the vehicle. Expanded to the side. Thus, the airbag 32 is inflated and deployed from the rear end portion 16 of the hood 14 and the windshield glass 46 toward the vehicle rear upper surface. When the airbag 32 is inflated and deployed, as shown in FIGS. 3B and 4, the bag cylindrical portion 40 </ b> B of the bag main body portion 40 is cylindrical in the vehicle width direction along the rear end portion 16 of the hood 14. The pair of left and right bag side portions 44 are inflated and deployed so as to cover the front surface of the front pillar 42. Thus, in this embodiment, in order to deploy the airbag 32, it is not necessary to provide an airbag door or the like on the hood 14.

  By the way, the hood 14 is attached to the hood hinge 24 by the hood hinge attaching portion 76, and the vehicle body 15 and the hood 14 are connected by the hood hinge 24. For this reason, when the inflator 34 is operated and the airbag 32 is inflated and deployed, the deployment reaction force at that time acts on the inflator 34, and the hood 14 receives the deployment reaction force and is pressed toward the front side of the vehicle. As a result, it is conceivable that stress concentrates on the periphery of the hood hinge mounting portion 76 in the hood 14.

  Here, in the present embodiment, a first bulging portion 72 as a base portion constituting the bulging portion 70 is provided on the vehicle lower side of the rear end portion 16 of the hood 14. The inflator 34 is fixed to. A rear end wall 72B of the first bulge portion 72 is provided on the vehicle front side of the inflator 34 in the first bulge portion 72, and the deployment reaction force of the airbag 32 is supported by the rear end wall 72B. At the same time, the unfolding reaction force is directly transmitted from the bulging portion 70 to the hood hinge mounting portion 76.

  More specifically, the deployment reaction force acting on the inflator 34 when the airbag 32 is deployed is first transmitted to the front wall portion 30B of the module case 30 that is in contact with the inflator 34. The front wall portion 30B is in contact with the rear end wall 72B of the first bulging portion 72, and the deployment reaction force of the airbag 32 is transmitted to the first bulging portion 72 via the front wall portion 30B. Is done. Since the first bulge portion 72 forms a closed cross section with the hood outer panel 20 as described above, the first bulge portion 72 has sufficient rigidity against a force acting in the vehicle front-rear direction. Accordingly, the deployment reaction force of the airbag 32 is received by the rear end wall 72B of the first bulging portion 72. The deployment reaction force of the airbag 32 received by the rear end wall 72 </ b> B is transmitted to the second bulging portion 74 formed by being connected to the first bulging portion 72. It is transmitted to the provided hood hinge mounting portion 76. For this reason, the deployment reaction force when the airbag 32 is inflated and deployed can be transmitted from the bulging portion 70 to the hood hinge 24.

  Thus, in this embodiment, the airbag 32 can be deployed without providing the hood 14 with an airbag door or the like. Further, the deployment reaction force when the airbag 32 is inflated and deployed can be transmitted to the vehicle body 15 via the hood hinge 24, thereby suppressing the concentration of stress on the periphery of the hood hinge mounting portion 76 in the hood 14. can do. As a result, according to the present embodiment, the deployment behavior of the airbag 32 can be stabilized while ensuring the degree of freedom in design design of the hood 14.

  In the present embodiment, the rear end portion 16 of the hood 14 is reinforced by the first bulge portion 72, and both end portions in the vehicle width direction of the hood 14 are reinforced by the second bulge portion 74. Further, the hood hinge attachment portion 76 is provided integrally with the second bulge portion 74. For this reason, the bulging portion 70 can integrally reinforce the rear end portion 16 of the hood 14 and both end portions in the vehicle width direction, thereby improving the rigidity of the hood 14 as a whole. As a result, according to the present embodiment, the deployment reaction force when the airbag 32 is inflated and deployed can be distributed to the entire hood 14 and the deployment reaction force can be transmitted to the hood hinge 24.

  Further, in the present embodiment, the inflator 34 that is a heavy object in the airbag device 28 is fixed to the bulging portion 70 having high rigidity. For this reason, the attachment state of the inflator 34 and the module case 30 can be stabilized. As a result, according to the present embodiment, the behavior of the module case 30 and the hood 14 can be stabilized when the vehicle is running or when the airbag 32 is deployed.

  In addition, in this embodiment, the bulging portion 70 is formed integrally with the hood inner panel 22. For this reason, the hood 14 can be reinforced without increasing the number of parts. As a result, according to the present embodiment, the rigidity of the hood 14 against the deployment reaction force of the airbag 32 can be increased without increasing the mass and cost. Further, it is not necessary to reinforce the rear end portion 16 of the hood 14 in order to receive the reaction force of the deployment, or even if it is reinforced, the degree of reinforcement is reduced. Just go up. As a result, according to the present embodiment, the pedestrian protection performance on the upper surface of the hood 14 can be maintained well.

  In addition, in the present embodiment, the airbag device 28 is disposed on the vehicle rear side of the first bulging portion 72 in the hood inner panel 22. For this reason, the space below the vehicle of the hood 14 can be used effectively, and the retreat space 78 can be secured between the airbag device 28 and the power unit 11. As a result, according to this embodiment, the pedestrian protection performance when the airbag device 28 is in the non-operating state can be favorably maintained.

[Second Embodiment]
Hereinafter, 2nd Embodiment of the mounting structure of the pedestrian protection airbag apparatus for hooded vehicles which concerns on this invention is described. Note that the same components as those in the first embodiment described above are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 5, in the second embodiment, the hood inner panel 90 and the base member 92 as a base part are configured as separate parts and a connection plate 94 as a connection member is provided. There is a feature.

  More specifically, as shown in FIG. 5A, the hood inner panel 90 in the present embodiment is configured by a flat panel material arranged along the hood outer panel 20, and the hood inner A base member 92 is disposed on the panel 90.

  The base member 92 extends along the rear end of the hood inner panel 90 and has a box shape that is gently curved so as to be convex toward the front side of the vehicle in plan view. The trapezoidal shape is widened toward the upper side of the vehicle and opened on the upper side of the vehicle. Similar to the first bulging portion 72 in the first embodiment, the base member 92 is on the vehicle lower side of the rear end portion 16 of the hood 14, more specifically, directly below the rear end portion 16 of the hood 14. It is arranged at a position offset to the front side of the vehicle. The base member 92 includes a bottom wall 92A facing the vehicle lower side and a rear end wall 92B as a support wall facing the module case 30. The bottom wall 92A and the rear end wall 92B can abut the front wall portion 30B of the module case 30 on the rear end wall 92B while abutting the upper mounting wall 30A of the module case 30 on the bottom wall 92A. The shape is set as follows. In the present embodiment, as an example, the base member 92 is made of an aluminum alloy, and functions as a reinforcing member in the same manner as the first bulging portion 72 in the first embodiment. Further, the base member 92 may be made of a steel plate or the like, or may be made of a resin block as long as the base member 92 has sufficient rigidity against the reaction force of the airbag 32.

  Further, a total of four attachment portions 92C are provided on both sides of the base member 92 in the vehicle width direction, one in the vehicle front-rear direction, and as shown in FIG. Bolt insertion holes 96 are formed. Correspondingly, a weld nut 98 is provided on the upper surface of the hood inner panel 90. The base member 92 is fixed to the hood inner panel 90 by the mounting bolt 100 being inserted into the bolt insertion hole 96 from below the vehicle and screwed into the weld nut 98. Further, a weld nut (not shown) is provided on the upper surface of the bottom wall 92A of the base member 92, and the airbag device 28 is fixed to the base member 92 by mounting bolts 60 as in the first embodiment. . When the airbag device 28 is assembled to the base member 92, the upper mounting wall 30A of the module case 30 is in surface contact with the bottom wall 92A, and the front wall portion 30B of the module case 30 is in surface contact with the rear end wall 92B. It is in contact with.

  On the other hand, the connection plate 94 is made of a high-strength and high-rigidity member. Structurally, the lower wall portion 94A disposed in surface contact with the bottom wall 92A of the base member 92, and the lower wall portion 94A are bent from the outer end in the vehicle width direction and extended to the vehicle upper side. The bent portion 94B and an upper wall portion 94C extending from the upper end of the bent portion 94B to the vehicle front side are configured. Two bolt insertion holes (not shown) are formed in the lower wall portion 94A of the connecting plate 94 at a predetermined interval in the vehicle width direction. Correspondingly, weld nuts (not shown) are provided on both sides of the upper surface of the bottom wall 92A of the base member 92 in the vehicle width direction. The attachment bolt 102 is inserted into the bolt insertion hole of the lower wall portion 94A from the lower side of the vehicle and screwed into the weld nut of the bottom wall 92A, whereby the connection plate 94 is fixed to the base member 92.

  Further, two bolt insertion holes (not shown) are formed in the upper wall portion 94C of the connecting plate 94 with a predetermined interval in the vehicle front-rear direction. These bolt insertion holes correspond to the weld nuts of the hood hinge mounting portions 76 provided on both sides of the hood inner panel 90 in the vehicle width direction in this embodiment. Further, the upper wall portion 94C of the connecting plate 94 is disposed in surface contact with the hood hinge mounting portion 76 (hood inner panel 90), and one end portion of the hinge arm 25 is disposed on the vehicle lower side of the upper wall portion 94C. Has been. Then, in a state where the insertion holes of the hinge arm 25 and the upper wall portion 94C are coaxially arranged, the mounting bolt 104 is inserted into the insertion hole of the hinge arm 25 and the upper wall portion 94C from the lower side of the vehicle, and the hood hinge attachment portion Screwed onto 76 weld nuts. Thereby, the hinge arm 25 and the connecting plate 94 are fastened together with the hood hinge mounting portion 76. That is, in the present embodiment, the base member 92 and the hood hinge mounting portion 76 are connected via the connecting plate 94. In addition, since the connection plate 94 is composed of a high-strength and high-rigidity member, it also functions as a reinforcing member.

(Operation and effect of this embodiment)
Next, the operation and effect of this embodiment will be described.

  In the present embodiment, the base member 92 is fixed to the hood inner panel 90, and the inflator 34 is fixed to the base member 92. Further, a rear end wall 92B is provided on the vehicle front side of the inflator 34 in the base member 92, and the deployment reaction force of the airbag 32 can be received by the rear end wall 92B. Then, the deployment reaction force of the airbag 32 received by the rear end wall 92 </ b> B is transmitted to the hood hinge mounting portion 76 via the connection plate 94. For this reason, the deployment reaction force when the airbag 32 is inflated and deployed can be transmitted from the base member 92 to the hood hinge 24. Therefore, also in this embodiment, the same operations and effects as those of the first embodiment described above can be obtained except for the operations and effects obtained by integrally forming the bulging portion 70 on the hood inner panel 22.

  In the present embodiment, the base member 92 is connected to the hood hinge mounting portion 76 via the connecting plate 94. Therefore, even if the shape of the base member 92 and the positional relationship between the base member 92 and the hood hinge mounting portion 76 are changed according to the shape of the hood 14, the base member 92 is changed by changing the shape of the connecting plate 94. And the hood hinge mounting portion 76 can be connected. As a result, according to the present embodiment, the deployment reaction force when the airbag 32 is inflated and deployed can be transmitted to the hood hinge 24 while securing the design freedom of the hood 14.

  Further, in the present embodiment, the base member 92 is configured as a separate part from the hood inner panel 90. Therefore, the airbag device 28 can be mounted on the hood 14 without significantly changing the design of the hood inner panel 90. As a result, according to the present embodiment, the time required for the design change of the hood 14 associated with the application of the airbag device 28 can be reduced.

[Supplementary explanation of the above embodiment]
In the above-described embodiment, a diffuser for rectifying the gas ejected from the gas ejection hole of the inflator 34 may be provided around the inflator 34. As an example, the diffuser is formed in a cylindrical shape, and may be integrated with the inflator 34 by caulking an axial intermediate portion to the axial line side. In this case, the inflator mounting bracket 36 may be fixed to the outer periphery of the diffuser. Further, when the diffuser is set on the outer peripheral portion of the inflator 34, the inflator 34 and the diffuser correspond to the “inflator” in the present invention.

  In the above-described embodiment, the inflator 34 is formed in a straight cylindrical shape, but is not limited thereto, and may be a straight cylindrical shape, or may be a straight square cylindrical shape or the like.

10 Vehicle (Automobile)
DESCRIPTION OF SYMBOLS 14 Hood 16 Rear end part 22 Hood inner panel 24 Hood hinge 28 Vehicle pedestrian protection airbag apparatus 32 Pedestrian protection airbag 34 Inflator 46 Windshield glass 70 A bulging part (base part)
72 1st bulging part (base part)
72B Rear end wall (support wall)
74 Second bulge part (base part)
74A rear bulge
74B front bulging portion 76 Hood hinge mounting portion 90 Hood inner panel 92 Base member (base portion)
92B Rear end wall (support wall)
94 Connection plate (connection member)

Claims (3)

An inflator that is disposed on the lower side of the rear end portion of the hood, the rear end portion of which is capable of rising to the vehicle upper side, and ejects gas by operating;
The hood is stored in a folded state below the rear end of the hood, and is inflated and deployed from between the rear end of the hood and the windshield glass toward the rear upper surface of the vehicle by supplying gas from the inflator. A pedestrian protection airbag,
A hood hinge mounting portion provided on a lower side of the rear end portion of the hood, to which a hood hinge is mounted;
Provided on the lower side of the rear end of the hood, the inflator is fixed, and a support wall capable of supporting the deployment reaction force of the pedestrian protection airbag is provided on the vehicle front side of the inflator and the deployment reaction a base portion that transmits to the hood hinge attachment portion a force through the section member,
Have
The base portion is connected to the hood hinge mounting portion via a connecting member as the member.
Mounting structure of pedestrian protection airbag device for hooded vehicles. An inflator that is disposed on the lower side of the rear end portion of the hood, the rear end portion of which is capable of rising to the vehicle upper side, and ejects gas by operating;
The hood is stored in a folded state below the rear end of the hood, and is inflated and deployed from between the rear end of the hood and the windshield glass toward the rear upper surface of the vehicle by supplying gas from the inflator. A pedestrian protection airbag,
A hood hinge mounting portion provided on a lower side of the rear end portion of the hood, to which a hood hinge is mounted;
Provided on the lower side of the rear end of the hood, the inflator is fixed, and a support wall capable of supporting the deployment reaction force of the pedestrian protection airbag is provided on the vehicle front side of the inflator and the deployment reaction a base portion for transmitting a force directly to prior SL hood hinge attachment portion,
Have
The base portion is formed integrally with the hood inner panel along the rear end portion of the hood inner panel constituting the inner member of the hood, and bulges toward the vehicle lower side, and the hood inner panel A second bulging portion that extends in the vehicle longitudinal direction along each of both ends in the vehicle width direction, is formed integrally with the hood inner panel, is connected to the first bulging portion, and bulges downward on the vehicle; , And the first bulging portion and the second bulging portion are integrally formed,
The hood hinge attachment portion is provided integrally with the second bulge portion,
The second bulging portion includes a rear bulging portion extending from the boundary portion with the first bulging portion to the vehicle rear side, and a front bulging portion extending from the boundary portion to the vehicle front side. ing,
Mounting structure of pedestrian protection airbag device for hooded vehicles. The width of the rear bulge portion is set larger than the width of the front bulge portion,
The length of the front bulge portion in the vehicle front-rear direction is set to be longer than the length of the rear bulge portion in the vehicle front-rear direction,
The hood hinge mounting portion is provided on the rear bulge portion,
The mounting structure of the pedestrian protection airbag apparatus for vehicles with a hood of Claim 2.

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