JP6164184B2 - Automotive hood structure - Google Patents

Description

  The present invention relates to a bonnet structure of an automobile, and more specifically, a rear part of a bonnet having a bonnet outer panel and a bonnet inner panel is pivotally supported by a vehicle body via a hinge, and a lock part engaged with the vehicle body side is provided at the front part of the bonnet The present invention relates to an automobile bonnet structure.

Generally, a bonnet of an automobile includes a bonnet outer panel and a bonnet inner panel, and the bonnet is pivotally supported on the vehicle body via a hinge so as to cover the upper part of the engine room so as to be opened and closed.
The bonnet described above requires at least the following requirements. That is, the bonnet is securely supported by the vehicle body so that it does not bend or vibrate due to traveling vibration or wind pressure of the traveling wind, and the rear end of the bonnet is hinged at the time of vehicle collision (front collision) That is, the vehicle does not move backward through the vehicle and can absorb the impact energy when the vehicle collides with a collision object such as a pedestrian.

  Therefore, when the hinge support rigidity of the bonnet is increased, the cushioning performance at the time of collision with the collision object decreases, or the bonnet retraction increases due to an increase in load input to the hinge shaft of the bonnet hinge at the time of frontal collision of the vehicle. There is a concern to do. Furthermore, when the structure which reinforces a bonnet hinge is employ | adopted, the weight and cost of the said bonnet hinge will increase.

  By the way, in patent document 1 and patent document 2, the structure which provides a weak part in a bonnet inner panel for the purpose of the rear end of a bonnet not moving backward via a hinge at the time of a vehicle collision (front collision). Is disclosed.

  That is, in Patent Document 1, an intermediate fragile portion is formed in the bonnet to bend and deform the bonnet upward at a substantially intermediate position in the front-rear direction between the striker and the hinge when an impact load from the front of the vehicle is input. In addition, a rear fragile portion is formed between the intermediate fragile portion and the hinge to bend and deform the bonnet downward.

  In the conventional structure disclosed in Patent Document 1, the bonnet is fold-folded at the rear fragile portion at the time of a vehicle collision, and the bonnet is fold-folded at the middle fragile portion. On the other hand, there is an advantage that it is possible to prevent the rearward movement of the bonnet. On the other hand, the fragile portions are disadvantageous in terms of the hinge support rigidity of the bonnet.

  Patent Document 2 discloses a configuration in which fragile portions are provided in both portions of the bonnet inner panel immediately before the hinge reinforcement and in the vicinity of the striker mounting portion.

  However, the conventional structure disclosed in Patent Document 2 is disadvantageous in terms of hinge support rigidity of the bonnet due to the provision of the above-described weakened portion, and promotes deformation of the bonnet by the weakened portion below the hood-side hinge bracket. In addition, there is a problem that a space is indispensable for the purpose, and in addition, there is a problem that the upper part of the hinge is disadvantageous as a buffer for a collision object.

JP 2009-35088 A JP 2008-238919 A

  SUMMARY OF THE INVENTION An object of the present invention is to provide an automobile bonnet structure capable of ensuring both the hinge support rigidity of the bonnet and preventing the rear part of the bonnet from retreating at the time of a vehicle front collision.

In the bonnet structure of an automobile according to the present invention, a rear part of a bonnet having a bonnet outer panel and a bonnet inner panel is pivotally supported via a hinge on a vehicle body spaced apart so as to be able to contact at the time of a front collision. A bonnet structure of an automobile provided with a lock portion that engages with a side, wherein the bonnet inner panel extends in the vehicle width direction along the rear end of the bonnet and projects toward the bonnet outer panel side. A side ridge, a central ridge having a shape that protrudes toward the bonnet outer panel, and has a rear surface that is inclined forward and upward from the lower edge at a position in front of the rear ridge, and the rear ridge A concave groove formed in the vehicle width direction formed by the center and the central raised portion, and deformed downward with an input load greater than the proof strength in the vehicle longitudinal direction And a reinforcing portion that, while being placed in the vehicle width direction outer side of the rear-side ridges, and the hinge reinforcement which extends to the groove front edge of the reinforcing portion, the lock portion and the reinforcing portion of the hood inner panel A mountain fold starting point that promotes upward bending provided in a portion between, the mountain fold starting point that is recessed upward from the lower surface of the bonnet inner panel, and the above that extends upward from the recessed shape portion The hinge reinforcement is formed of a side surface of a central raised portion, and the reinforcing portion is formed of a concave shape portion recessed downward from the upper surface of the bonnet inner panel and a vertical wall extending downward from the concave shape portion. However, it is arranged so that the front end is located in front of or behind the lower edge of the inclined rear surface in the central bulge portion, and is above the hinge reinforcement. And the upper surface of the central raised portion extending in the longitudinal direction of the vehicle, in the side surface of the central elevated portion, in which prior to impact load transmission path is formed for the reinforcing portion.

According to the above configuration, the reinforcement portion (rigidity changing point) and the hinge reinforcement front end (rigidity changing point) are aligned in the vehicle width direction, thereby improving the bending rigidity and hinge support rigidity of the rear bonnet at the normal time. be able to.
In addition, by aligning the reinforcement part as the rigidity change point and the hinge reinforcement front end in the vehicle width direction, stress concentrates on the rigidity change point at the time of the front collision, and the reinforcement part and the hinge reinforcement front end face downward. Deformation (down-folding, trough-folding) can be made into a bending mode in which the hinge is pressed against the vehicle body to promote the downward bending deformation and to distribute the load.
In short, it is possible to achieve both of securing the hinge support rigidity of the bonnet and preventing the rearward movement of the bonnet rear part at the time of a vehicle front collision.

In addition, the present invention is characterized in that a hinge reinforcement is provided which is disposed on the outer side in the vehicle width direction of the rear raised portion and extends to the front edge of the groove of the reinforcing portion.

  According to the above configuration, the hinge reinforcement can reinforce the opening deformation of the concave groove, and the weight and rigidity can be increased, and the concave groove is strongly bent to promote the deformation at the time of frontal collision of the vehicle. Is pressed against the vehicle body, so that the front impact load can be distributed.

Further, the present invention is characterized in that the hinge reinforcement is arranged such that a front end thereof is located in front of or at the rear of the lower edge of the inclined rear surface in the central raised portion and at the same or rearward position of the upper edge.

  According to the above configuration, the lower edge of the central raised portion can be reinforced with the hinge reinforcement described above, and light weight and high rigidity can be achieved. In addition, the rigidity at the normal time can be controlled at the front end position of the hinge reinforcement.

Further, according to the present invention, a front impact load transmission path to the reinforcing portion is formed by an upper surface of the central raised portion extending in the vehicle longitudinal direction above the hinge reinforcement and a side surface of the central raised portion. It is characterized by that.

  According to the above configuration, since the front collision load transmission path exists above the hinge reinforcement, the load can be reliably transmitted to the rear in the initial stage of the collision, and the hinge reinforcement and the front collision load transmission path By securing the amount of offset in the vertical direction between the two, the downward bending deformation can be more reliably promoted.

Furthermore the present invention, the outward bending starting point, and the recess-shaped portion recessed upward from a lower surface the hood inner panel, is formed in the side surface of the central elevated portion extending upwardly from the depressions shaped portion, the reinforcement portion characterized and the hood inner panel from the top surface concave portion recessed downward, that is formed in the vertical wall from the concave shaped portion Ru extends downward.

According to the said structure, the increase in the load absorption amount by a deformation | transformation can be aimed at by a mountain fold starting point and a reinforcement part. Further, the front impact load urged by the hinge reinforcement can be distributed to the vehicle body from the hinge reinforcement that is bent downward and deformed, thereby further preventing the rear of the bonnet from retreating. In addition, the normal rigidity can be ensured by the vertical wall of the reinforcing portion .

  According to the present invention, there is an effect that both the securing of the hinge support rigidity of the bonnet and the prevention of the rearward movement of the rear part of the bonnet at the time of the vehicle front collision can be achieved.

Front perspective view of an automobile equipped with the bonnet structure of the present invention A perspective view showing the hood structure of an automobile with the hood outer panel removed. Side view of FIG. Sectional view showing the bonnet structure vertically cut at the center in the vehicle width direction (A) is an enlarged sectional view of the front part of FIG. 4, (b) is an enlarged sectional view of the rear part of FIG. Top view of bonnet inner panel Side view showing hinge reinforcement mounting structure to bonnet inner panel Front enlarged plan view of the bonnet inner panel with the stiffener removed from the state of FIG. FIG. 8 is a perspective view. (A)-(d) is a schematic side view which shows in order the deformation | transformation state of a bonnet at the time of a vehicle front collision.

  The rear part of the bonnet having a bonnet outer panel and a bonnet inner panel is pivotally supported on the vehicle body via a hinge for the purpose of ensuring the hinge support rigidity of the bonnet and preventing the rear part of the bonnet from retreating at the time of a frontal collision of the vehicle. In a hood structure of an automobile in which a lock portion that engages with the vehicle body is provided at the front portion of the bonnet, upward bending is promoted to a portion between the lock portion of the bonnet inner panel and the hinge reinforcement. A mountain fold starting point is provided, and a reinforcing portion that extends in the vehicle width direction and deforms downward with an input load greater than the proof strength in the vehicle front-rear direction and a hinge reinforcement front end are provided at the rear of the mountain fold starting point. Realized by the configuration of being arranged in the width direction.

An embodiment of the present invention will be described in detail with reference to the drawings.
The drawing shows a hood structure of an automobile, and FIG. 1 is a front perspective view of the automobile provided with the hood structure. In FIG. 1, a hood 10 is provided that covers the engine room 1 so as to be openable and closable.
The front of the engine room 1 is covered with a front bumper 2, and the left and right sides of the engine room 1 are covered with left and right front fenders 3 and 3.

Behind the bonnet 10 is a front window member that extends obliquely rearward and upward from a cowl portion 4 at the top of a dash lower panel 12 (see FIG. 2) that partitions the engine room 1 and the vehicle compartment in the front-rear direction of the vehicle. A front window glass 5 is provided, and both left and right ends of the front window glass 5 are supported by a front pillar 6, and the upper end of the front window glass 5 is bonded and fixed to the lower surface of the front end of the roof panel 7. It is supported by a front header that extends in the vehicle width direction.
In FIG. 1, 8 is a front door provided with a side window glass 8a, and 9 is a front wheel.

  2 is a perspective view showing the hood structure of the automobile with the bonnet outer panel removed, FIG. 3 is a side view of FIG. 2, and FIG. 4 is a cross-sectional view showing the hood structure vertically cut at the center in the vehicle width direction. 5 (a) is an enlarged sectional view of the front part of the bonnet of FIG. 4, FIG. 5 (b) is an enlarged sectional view of the rear part of the hood of FIG. 4, FIG. 6 is a plan view of the bonnet inner panel, and FIG. FIG. 8 is a front enlarged plan view of the bonnet inner panel shown with the stiffener removed from the state of FIG. 6, and FIG. 9 is a perspective view of FIG.

As shown in FIGS. 2, 3 and 4, a dash lower panel 12 for partitioning the engine room 1 and the vehicle compartment 11 in the vehicle front-rear direction is provided, and a cowl panel is provided above the dash lower panel 12 as shown in FIG. The cowl front panel 14 is joined and fixed so as to extend forward from the lower front end of the cowl panel 13, and the cowl front reinforcement 15 is joined and fixed to the front lower part of the cowl front panel 14. Thus, the cowl portion 4 having an open cowl structure is formed.
A closed section 16 extending in the vehicle width direction is formed between the above-described cowl front panel 14 and the cowl front reinforcement 15, thereby improving the cowl rigidity.
As shown in FIG. 4, a cowl grill 17 is provided above the cowl part 4, while a cowl grill front 18 is provided in front of the cowl part 4.

As shown in FIG. 3, the above-described bonnet 10 is attached to an upper bent portion 19a of the cowl side panel 19 located at the base of an apron reinforcement (not shown) via a bonnet hinge 20 so as to be opened and closed. It has been.
As shown in FIG. 7, the bonnet hinge 20 described above includes a body-side hinge bracket 22 that is fixed to the upper-end bent portion 19 a of the cowl side panel 19 using an attachment member 21 such as a bolt or a nut, and the body side A hood-side hinge bracket 24 connected to the hinge bracket 22 via a hinge pin 23 is provided, and the hood-side hinge bracket 24 is connected and fixed to the lower surfaces of both the left and right sides of the rear end portion of the bonnet 10 described above.

  As shown in FIG. 4, the bonnet 10 described above has a bonnet outer panel 25 made of iron plate and a bonnet inner panel 26 made of aluminum or aluminum alloy, and the rear part of the bonnet 10 has a bonnet hinge 20 (FIG. 3). (See FIG. 7).

  As shown in a plan view of the bonnet inner panel 26 with the bonnet outer panel 25 removed in FIG. 6, the bonnet inner panel 26 includes a front side portion 26F, left and right side portions 26L and 26R, and a rear side portion 26B. And edge portions of the side portions 26F, 26L, 26R, and 26B are integrally fixed to corresponding portions of the bonnet outer panel 25 by hemming.

  As shown in FIG. 6, a lateral groove 27 that is recessed along the front side portion 26F and extends in the vehicle width direction, and a side groove that is recessed along the left side portion 26L and extends in the vehicle front-rear direction. 28 and a side groove 29 that is recessed along the right side portion 26R described above and extends in the vehicle front-rear direction form a U-shaped frame-like groove 30 that is open on the rear side in plan view.

As shown in FIGS. 2, 3, 4, and 6, the middle of the bonnet inner panel 26 that is surrounded on three sides by the grooves (that is, the frame-shaped grooves 30) of the lateral grooves 27 and the left and right side grooves 28 and 29. The part is provided with a central raised portion 31 having a shape protruding upward toward the bonnet outer panel 25 in a front view of the vehicle.
In addition, a rear raised portion 32 extending in the vehicle width direction is provided along the rear side portion 26B of the bonnet inner panel 26 so as to be located behind the above-described central raised portion 31.

The central raised portion 31 and the rear raised portion 32 located behind the central raised portion 31 are provided side by side in the front-rear direction, and a concave groove shape as a reinforcing portion is formed between the raised portions 31 and 32. A deep drawing groove 33 is formed extending in the vehicle width direction.
The above-described deep drawing groove 33 is formed into a deep groove shape by a plurality of press processes.

Here, as shown in FIG. 5B and FIG. 7, the rear raised portion 32 described above includes a front wall 32 a that slopes in a front-rear and rear-high shape, and a side wall 32 b, and the rear raised portion. A convex portion 32c is provided on the front edge of the upper surface of the portion 32 so as to be spaced forward from the rear end of the bonnet and extend in the vehicle width direction to support the bonnet outer panel 25. By the convex portion 32c, the above-described deep drawing groove In addition to the structure in which the groove depth of 33 is further deepened, and a structure in which a convex portion is provided at the rear edge of the rear raised portion 32, the hinge support rigidity is improved and the tension rigidity of the rear portion of the bonnet outer panel 25 is improved. ing.
Further, at least one ridge line X1 extending in the vehicle width direction is formed by the shape of the convex portion 32c as shown in FIG. 5B.

  As shown in FIGS. 2, 6, and 7, the left and right hinge reinforcements extend from the side of the side wall 32 b of the rear raised portion 32 to the rear end of the central raised portion 31 through the side of the deep drawing groove 33. Ment 40, 40 is attached.

  As shown in FIGS. 6 and 7, the hinge reinforcement 40 is formed in a concave shape in a front view to improve the rigidity of the hinge reinforcement 40 itself, and as shown in FIG. Both the front and rear portions of the hinge reinforcement 40 are coupled to the bonnet inner panel 26 using rivets 41 and 41, and the intermediate portions in the front and rear direction of the hinge reinforcement 40 include mounting members 42 and 42 such as bolts and nuts. The bonnet inner panel 26 and the hood-side hinge bracket 24 are fastened together.

  In this way, the hinge reinforcement 40 is extended from the side of the rear raised portion 32 to the rear end of the central raised portion 31 through the side of the deep drawing groove 33, whereby the left and right hinge reinforcements 40, The deep drawing groove 33 spanning the vehicle width direction between the 40 increases the vertical bending rigidity of the central portion of the bonnet 10 in the vehicle width direction, and the hinge reinforcement 40 causes the mouth opening deformation of the deep drawing groove 33 and the rear part of the bonnet 10. In order to prevent the vertical bending deformation, the rigidity is improved.

That is, in the bonnet 10 having the central raised portion 31, the hinge support rigidity at the rear of the bonnet 10 is increased to prevent the bonnet 10 from being bent or vibrated due to traveling vibration or wind pressure of the traveling wind. It is.
As shown in FIGS. 4 and 5B, the deep drawing groove 33 is formed with a sub-groove 33a that is one step deeper and extends in the vehicle width direction at the front of the groove. By the formation, a plurality of ridge lines X2, X3, and X4 along the sub-groove 33a are formed.

As shown in FIGS. 2 and 6, the deep drawing groove 33 described above is curved such that a center part in the vehicle width direction protrudes forward of the vehicle in plan view, and includes a curved center part 33c (including a sub groove 33a). The curved central portion of the deep drawing groove 33 is located in front of the vehicle from the front end of the hinge reinforcement 40 described above.
Due to the curved structure of the deep drawing groove 33, the hinge support rigidity is improved to the front part from the front end of the hinge reinforcement 40, and further, the rigidity of the deep drawing groove 33 against opening deformation is improved by the curved structure. It is comprised as follows.

As shown in FIGS. 2 and 6, the left and right side grooves 28 and 29 in the frame-shaped groove 30 extend in the front-rear direction along the left and right side portions 26 </ b> L and 26 </ b> R at the left and right sides of the bonnet inner panel 26. These left and right side grooves 28 and 29 are formed so as to be recessed below the above-described deep drawing groove 33, and as shown in FIG. The hinge reinforcement 40 described above is fixed at a position below the bottom of the groove.
The deep drawing groove 33 and the rear raised portion 32 are reinforced by the left and right side grooves 28 and 29 described above, and the hinge reinforcement 40 is fixed at a position below the deep drawing groove 33. The crush space for impactor buffering (that is, for collision object buffering) above the hinge reinforcement 40 is configured to be expanded.

  By the way, the above-mentioned central raised portion 31 absorbs impact energy at the time of collision with a collision object, and as shown in FIG. 2, in this embodiment, the upper portion of the central raised portion 31 is formed in an uneven shape. Yes.

  That is, the central raised portion 31 is located on the upper front side and extends in the vehicle width direction, on the rear side of the convex portion 31a, on the rear side of the convex portion 31b, and on the further rear side of the convex portion 31b. A convex portion 31c extending in the vehicle width direction, a convex portion 31d located on the upper rear side of the central raised portion 31 and extending in the vehicle width direction, between the convex portions 31a and 31b, between the convex portions 31b and 31c, and a convex portion Concave portions 31e, 31f, and 31g extending in the vehicle width direction between 31c and 31d are provided.

  2 and 6, the central raised portion 31 includes an inclined front surface 31h extending obliquely forward and downward from the convex portion 31a, an inclined rear surface 31i extending obliquely rearward and downward from the convex portion 31d, and a central raised portion. Left and right inclined side surfaces 31j and 31k extending obliquely downward and outward from the upper left and right of the upper portion 31 are provided.

On the other hand, as shown in FIGS. 4, 5 (a), 8, and 9, the striker reinforcement 50 is located at a position corresponding to the lateral groove 27 at the center of the bonnet inner panel 26 in the front vehicle width direction. The striker 51 is attached so as to sandwich the striker reinforcement 50 and the bonnet inner panel 26.
The striker 51 is provided so as to protrude downward from the front vehicle width direction center of the bonnet inner panel 26, and the striker 51 is configured to be engageable with a latch on the vehicle body side.

As shown in FIGS. 4 and 5A, the striker 51 is attached between the inclined front surface 31h of the central raised portion 31 and the front end portion (front side portion 26F) of the bonnet inner panel 26. A stiffener 60 as a reinforcing member is installed so as to be spaced upward from the portion.
Then, the above-described deep drawing groove 33, frame-shaped groove 30 and stiffener 60 ensure the hood rigidity at the normal time, while the central raised portion 31, the rear raised portion 32 and the stiffener 60 generally have an inertial mass. Concentrate on the upper part of the bonnet 10 (on the bonnet outer panel 25 side), while increasing the vertical crash stroke to ensure a reaction force characteristic that keeps the reaction force high at the beginning of the collision and low at the later stage. doing.

  As shown in FIGS. 2 and 6, a plurality of front and rear openings 61 and 62 are formed in the above-described stiffener 60, and the back opening 61 and the front opening 62 are curved in the front-rear direction. A horizontal bead 63 extending in the vehicle width direction is formed, and vertical beads 64 and 64 that are curved outward in the vehicle width direction and extend in the front-rear direction are formed at both left and right portions of the horizontal bead 63, and are reinforced. The bead itself is configured to be a starting point for preventing the shock absorbing stroke of the colliding object from being reduced.

As shown in an enlarged view of the bonnet inner panel 26 in FIGS. 8 and 9, substantially circular ridgelines X5 and X6 are formed at the upper and lower portions of the central raised portion 31 described above.
The left and right corner portions on the front side of the central raised portion 31 are provided with a pair of slits 43 and 43 for cutting the upper and lower ridge lines X5 and X6 and a columnar portion 44 positioned between the pair of slits 43 and 43. ing. The slit 43 and the pair of slits 43 extend obliquely in the vertical direction along the corner portion of the central raised portion 31, and the pair of slits 43 and 43 increase deformation resistance when the collision object absorbs collision energy. In addition to preventing bottoming, the columnar portion 44 is configured to ensure normal rigidity and to improve the initial reaction force during impact object buffering.
Of the frame-shaped grooves 30 described above, the lateral grooves 27 extending in the vehicle width direction are one step deeper than the lateral grooves 27 and extend in the vehicle width direction, as shown in FIGS. An extending auxiliary groove 27a is formed in a recessed manner. Further, ridgelines X7 and X8 extending in the vehicle width direction are formed at both front and rear portions of the sub groove 27a.

  As shown in FIGS. 6, 8, and 9, a pair of openings 45, 45 are formed on the left and right of the inclined front surface 31 h of the central raised portion 31. Furthermore, as shown in the figure, a plurality of openings 46 for reducing the weight are formed in the recess 31e and the recess 31g of the central raised portion 31.

In addition, as shown in FIG. 6, the bonnet inner panel 26 is formed on the top deck surface of each of the convex portions 31 a, 31 b, 31 c, 31 d of the central raised portion 31 and the convex portion 32 c of the rear raised portion 32. Is attached to the bonnet outer panel 25 by an adhesive 47 (indicated by a small-diameter white circle in FIG. 6).
For convenience of illustration, the filler 47 is not shown in FIGS. 2, 3 and 7 to 9.

  By the way, as shown in FIGS. 3 and 6, the portion between the striker reinforcement 50 constituting the lock portion of the bonnet inner panel 26 and the hinge reinforcement 40 described above is located in the bonnet 10 at the time of a vehicle front collision. A mountain fold starting point 52 that promotes upward bending (mountain fold deformation) is provided.

  In this embodiment, the above-described mountain fold starting point 52 extends downward from the lower surface of the bonnet inner panel 26, specifically, a recessed portion 53 recessed upward from the bottom wall portions of the side grooves 28 and 29, and the recessed portion 53. It is formed by the inclined side surfaces 31j and 31k of the central raised portion 31 as the first vertical wall.

  By providing the above-described mountain fold starting points 52 and 52, as shown in FIG. 6, a mountain fold line L3 that connects the left and right mountain fold starting points 52 and 52 in the vehicle width direction is formed.

  As shown in FIG. 3 and FIG. 6, it is deformed downward at an area behind the above-described mountain folding starting points 52, 52 with an input load exceeding the proof strength in the vehicle front-rear direction (valley folding deformation). A deep drawing groove 33 as a reinforcing portion and a front end of the hinge reinforcement 40 are provided side by side in the vehicle width direction.

  Both the deep drawing groove 33 and the front end of the hinge reinforcement 40 act as a stiffness change point. The deep drawing groove 33 and the front end of the hinge reinforcement 40 are aligned in the vehicle width direction, so that the normal time The rear bonnet 10 is configured to improve the bending rigidity and hinge support rigidity.

Further, since the deep drawing groove 33 as the rigidity changing point and the front end of the hinge reinforcement 40 are arranged in the vehicle width direction, stress concentrates on the rigidity changing point at the time of the front collision, and the deep drawing groove 33 and the hinge reinforcement 40 The front end of the ment 40 is deformed downward (down-fold deformation, valley-fold deformation), and the bonnet hinge 20 (specifically, the bonnet-side hinge bracket 24) is placed in a bending mode that presses against the vehicle body to promote the downward bend deformation and load. It is configured to achieve dispersion.
That is, the configuration is such that both the securing of the hinge support rigidity of the bonnet 10 and the prevention of the backward movement of the rear part of the bonnet 10 at the time of a vehicle front collision are achieved.

  As shown in FIGS. 2, 3 and 7, the deep drawing groove 33 as a reinforcing portion is formed as a concave groove, and as shown in FIG. 7, the front end of the hinge reinforcement 40 is the deep drawing groove. 33 (that is, a concave groove) extends forward of the vehicle up to the front edge.

  Further, the hinge reinforcement 40 reinforces the opening deformation of the concave groove (deep drawing groove 33) to increase the weight and rigidity, and the deep drawing groove 33 is strongly bent and deformed at the time of a vehicle front collision. And the bonnet hinge 20 is pressed against the vehicle body to disperse the front impact load.

  As shown in FIGS. 6 and 7, the front end of the hinge reinforcement 40 described above is in front of the lower edge of the inclined rear surface 31 i of the central raised portion 31, and is the same as or behind the upper edge of the inclined rear surface 31 i. It is provided so that it may be located in.

  As a result, the lower edge of the central raised portion 31 is reinforced with the hinge reinforcement 40 described above to achieve light weight and high rigidity, and the normal rigidity can be controlled at the front end position of the hinge reinforcement 40. It is configured.

  As shown in FIG. 3 and FIG. 6, the front impact load transmission path Z (specifically, the upper surface of the central raised portion 31 is inclined with respect to the deep drawing groove 33 as the reinforcing portion above the hinge reinforcement 40. Side surfaces 31j and 31k) extend in the vehicle front-rear direction.

As a result, the front collision load transmission path Z (the upper surface of the central raised portion 31 and the inclined side surfaces 31j, 31k) exists above the hinge reinforcement 40, so that the load can be reliably transmitted to the rear in the initial stage of the collision. By ensuring the amount of offset in the vertical direction between the hinge reinforcement 40 and the front collision load transmission path Z, the downward bending deformation is more reliably promoted.
By providing the deep drawing groove 33 and the front end of the hinge reinforcement 40 side by side in the vehicle width direction behind the front collision load transmission path Z (the upper surface of the central raised portion 31 and the inclined side surfaces 31j, 31k), As shown in FIG. 6, a valley fold line L4 is formed that connects the front ends of the left and right hinge reinforcements 40, 40 in the vehicle width direction.

  As shown in FIGS. 3 and 6, the deep drawing groove 33 as the above-described reinforcing portion includes a concave shape portion that is recessed downward from the upper surface of the bonnet inner panel 26 and a second vertical wall that extends downward from the concave shape portion. 33b (specifically, a vertical wall between the bottom of the deep drawing groove 33 and the left and right side grooves 28 and 29 shown in FIG. 6), and the second vertical wall 33b ensures rigidity during normal operation. It is comprised so that it may aim.

  Further, as shown in FIG. 3, there is provided a mountain fold starting point 52 composed of the above-described recessed portion 53 and the inclined side surfaces 31j and 31k of the central raised portion 31 which is the first vertical wall. By providing the deep drawing groove 33 formed by the above-mentioned concave shape portion and the second vertical wall 33b in the rear portion, the load absorption amount due to deformation at the mountain fold starting point 52 and the reinforcing portion (the deep drawing groove 33). In addition, the front impact load urged by the hinge reinforcement 40 is distributed to the vehicle body from the hinge reinforcement 40 that is bent downward and deformed to suppress the backward movement of the bonnet 10. It is composed.

  Incidentally, as shown in a plan view in FIG. 6, the bonnet inner panel 26 has left and right openings 45 in the inclined front surface 31 h of the central raised portion 31 in addition to the above-described mountain fold line L 3 and valley fold line L 4. , 45 and the slits 43, 43 in the vehicle width direction, a valley fold line L1 (a line that deforms at the time of a collision with a collision object), and left and right columnar portions 44 formed at the front corner portion of the central raised portion 31, 44 is connected to the upper part from the lower part to the upper part, and a pre-mountain fold line L2 (front mountain fold starting point part) that connects the upper parts of the left and right columnar parts 44, 44 in the vehicle width direction along the rear surface of the convex part 31a. , Is formed.

(A)-(d) of FIG. 10 is a schematic side view which shows the deformation | transformation state of the bonnet 10 at the time of the vehicle front collision in order of the deformation | transformation.
As shown in FIG. 10 (a), at the time of frontal collision of the vehicle, stress is first concentrated on the pre-mountain fold line L2 (the front mountain fold starting point), and the front collision load transmission path Z (the upper surface of the central ridge 31). And the load is transmitted to the rear via the inclined side surfaces 31j and 31k).

  Next, as shown in FIG. 10 (b), the pre-mountain folding line L2 is bent, the bonnet 10 is bent and deformed, and the rigidity changes due to the load transmitted rearward from the above-described front collision load transmission path Z. Stress concentrates on the point (the deep drawing groove 33 and the front end of the hinge reinforcement 40), and the deep drawing groove 33 starts to bend and deform.

  Next, as shown in FIG. 10C, the bonnet side hinge bracket 24 of the bonnet hinge 20 interferes with the vehicle body due to the progress of the valley deformation of the deep drawing groove 33, while the stress is dispersed. The stress that has lost its place due to the interference between the side hinge bracket 24 and the vehicle body concentrates at the mountain break starting point 52.

Next, as shown in FIG. 10 (d), the central raised portion 31 is bent and deformed by the above-described mountain fold starting point 52, and the load is absorbed, whereby the amount of transmission of the front impact load to the rear of the bonnet 10 is achieved. Since the deep drawing groove 33 is further bent and deformed, the amount of transmission of the front impact load to the rear of the bonnet 10 is further reduced, so that the backward load to the hinge pin 23 is reduced and the rear part of the bonnet 10 is reduced. Prevents the vehicle from moving backwards. For this reason, the bonnet 10 is deformed into a tri-fold state in front of the hinge pin 23.
In FIG. 10, α indicates the position of the striker 51 at the normal time (before the front collision). In FIG. 3, reference numeral 48 denotes a cowl seal. Furthermore, in the figure, arrow F indicates the front of the vehicle, and arrow R indicates the rear of the vehicle.

  As described above, the bonnet structure of the automobile of the above embodiment is such that the rear portion of the bonnet 10 having the bonnet outer panel 25 and the bonnet inner panel 26 is pivotally supported on the vehicle body via the hinge (see the bonnet hinge 20). The bonnet structure of the automobile is provided with a lock portion (see striker reinforcement 50) that engages the vehicle body side, and the lock portion (striker reinforcement 50) of the bonnet inner panel 26 and the hinge reinforcement A mountain fold starting point 52 that promotes upward bending is provided at a position between the ment 40 and an input that extends in the vehicle width direction and exceeds the proof strength in the vehicle front-rear direction at a position behind the mountain fold starting point 52. Reinforcing part that deforms downward with load (see deep drawing groove 33) and hinge reinforcement 40 And the end is what was arranged in the vehicle width direction (see FIGS. 3, 4 and 6).

According to this configuration, the deep drawing groove 33 (rigidity changing point) as the reinforcing portion and the hinge reinforcement 40 front end (rigidity changing point) are arranged in the vehicle width direction, so that the bending rigidity of the rear portion of the bonnet 10 at the normal time is obtained. And hinge support rigidity can be improved.
Further, since the reinforcing portion (deep drawing groove 33) as the rigidity changing point and the front end of the hinge reinforcement 40 are aligned in the vehicle width direction, stress concentrates on the rigidity changing point at the time of the front collision, and the reinforcing portion (depth The throttle groove 33) and the front end of the hinge reinforcement 40 are deformed downward (down-fold deformation, valley-fold deformation), and the bending mode in which the bonnet hinge 20 is pressed against the vehicle body is set to promote the downward bending deformation and to distribute the load. Can be planned.
In short, it is possible to achieve both the securing of the hinge support rigidity of the bonnet 10 and the prevention of the rearward movement of the rear part of the bonnet 10 at the time of a vehicle front collision.

  In an embodiment of the present invention, the reinforcing portion (see the deep drawing groove 33) is formed by a concave groove, and the hinge reinforcement 40 extends to the front edge of the concave groove (the deep drawing groove 33). Yes (see FIG. 7).

  According to this configuration, the hinge reinforcement 40 can reinforce the opening deformation of the concave groove (see the deep-drawn groove 33), and the weight and rigidity can be increased, and the concave groove ( The deep-drawing groove 33) strongly promotes downward deformation and the bonnet hinge 20 is pressed against the vehicle body, so that the front impact load can be dispersed.

  In one embodiment of the present invention, the bonnet inner panel 26 is provided with a central raised portion 31 having an inclined rear surface 31i inclined forward and upward with respect to the lower surface, and is higher in front than the lower edge of the inclined rear surface 31i. The front end of the hinge reinforcement 40 is provided on the same side as or behind the edge (see FIGS. 6 and 7).

  According to this configuration, the lower edge of the central raised portion 31 can be reinforced with the hinge reinforcement 40 described above, and lightweight and high rigidity can be achieved. Further, the rigidity at the normal time can be controlled at the front end position of the hinge reinforcement 40.

In an embodiment of the present invention, a front impact load transmission path Z is extended in the vehicle front-rear direction above the hinge reinforcement 40 with respect to the reinforcing portion (deep drawing groove 33) ( (See FIGS. 3 and 7).
In this embodiment, the above-described front collision load transmission path Z is formed by the upper surface of the central raised portion 31 and the side surfaces 31j and 31k.

  According to this configuration, since the front collision load transmission path Z exists above the hinge reinforcement 40, the load can be reliably transmitted to the rear in the initial stage of the collision, and the hinge reinforcement 40 and the front collision load can be transmitted. By securing the amount of offset in the vertical direction with respect to the transmission path Z, the downward bending deformation can be more reliably promoted.

  In one embodiment of the present invention, the mountain fold starting point 52 includes a recessed portion 53 that is recessed upward from the lower surface of the bonnet inner panel 26, and a first vertical wall (central raised portion) that extends upward from the recessed portion 53. 31 (see the inclined side surfaces 31j and 31k), and the reinforcing portion (deep drawing groove 33) is a recessed portion recessed downward from the upper surface of the bonnet inner panel 26, and a second extending downward from the recessed portion. And the vertical wall 33b (see FIGS. 3 and 6).

  According to this configuration, it is possible to increase the load absorption amount due to deformation at the mountain fold starting point 52 and the reinforcing portion (deep drawing groove 33). Further, the front impact load urged by the hinge reinforcement 40 can be distributed to the vehicle body from the hinge reinforcement 40 which is bent downward and deformed, thereby further preventing the rear portion of the bonnet 10 from retreating. In addition, the above-described second vertical wall 33b can ensure normal rigidity.

In the correspondence between the configuration of the present invention and the above-described embodiment,
The hinge of the present invention corresponds to the bonnet hinge 20 of the embodiment,
Similarly,
The lock portion corresponds to the striker reinforcement 50 engaged with the vehicle body side via the striker 51,
The reinforcing part and the concave groove correspond to the deep drawing groove 33,
The first vertical wall corresponds to the inclined side surfaces 31j, 31k of the central raised portion 31,
The present invention is not limited to the configuration of the above-described embodiment.

  As described above, according to the present invention, the rear portion of the bonnet having the bonnet outer panel and the bonnet inner panel is pivotally supported on the vehicle body via the hinge, and the lock portion that engages the vehicle body side is provided at the front portion of the bonnet. It is useful for the hood structure of automobiles.

10 ... Bonnet 20 ... Bonnet hinge (hinge)
25 ... Bonnet outer panel 26 ... Bonnet inner panel 31 ... Central raised part 31i ... Inclined rear surface 31j, 31k ... Inclined side surface (first vertical wall)
33 ... Deep drawing groove (reinforcing part, concave groove)
33b ... 2nd vertical wall 40 ... Hinge reinforcement 50 ... Strike reinforcement (lock part)
52 ... Mountain break starting point 53 ... Recessed portion Z ... Front impact load transmission path

Claims (1)

The rear part of the bonnet having a bonnet outer panel and a bonnet inner panel is pivotally supported via a hinge on a vehicle body that is spaced at the time of a front collision ,
A bonnet structure of an automobile provided with a lock portion that engages with the vehicle body side at the front of the bonnet,
The bonnet inner panel
A rear raised portion that extends in the vehicle width direction along the bonnet rear end and protrudes toward the bonnet outer panel side,
A central raised portion having a shape that protrudes toward the bonnet outer panel side, having an inclined rear surface that is inclined forward and upward from the lower edge at a position in front of the rear raised portion,
A concave portion formed in the vehicle-width direction formed by the rear bulge portion and the central bulge portion;
A hinge reinforcement that is disposed outside the rear raised portion in the vehicle width direction and extends to the front edge of the recessed groove of the reinforcing portion;
Provided with a mountain fold starting point that promotes upward bending provided in a portion between the lock portion of the bonnet inner panel and the reinforcing portion ,
The mountain break starting point
It is formed by a recessed portion that is recessed upward from the lower surface of the bonnet inner panel, and a side surface of the central raised portion that extends upward from the recessed portion.
The reinforcing part is
The bonnet inner panel is formed by a concave portion recessed downward from the upper surface of the bonnet inner panel, and a vertical wall extending downward from the concave shape portion,
The hinge reinforcement is
It is arranged so that its front end is located in front of or behind the lower edge of the inclined rear surface of the central raised portion, equivalent to or behind the upper edge,
A front impact load transmission path for the reinforcing portion is formed by the upper surface of the central raised portion extending in the vehicle longitudinal direction above the hinge reinforcement and the side surface of the central raised portion. > Automobile bonnet structure.

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