JP2010195296A - Vehicle body rear structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vehicle body rear structure capable of preventing a bumper beam of a counter vehicle from running on a vehicle body rear part. <P>SOLUTION: The vehicle body rear structure 10 includes a rear frame 12 extending in the longitudinal direction of a vehicle body in a vehicle body rear part 11, a vertical reinforcing member 16 erected upwardly from a rear end 12a of the rear frame 12, and a rear pillar 13 with a forwardly tilted upper half portion 42 of the vertical reinforcing member 16 being connected thereto, which forms an opening side part of a trunk 25. The collision load F1 applied to the vehicle body rear part 11 from the rear side of the vehicle body is applied to the vertical reinforcing member 16 and transmitted to the rear frame 12. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a vehicle body rear structure in which a rear frame is extended in the longitudinal direction of a vehicle body and a rear pillar is provided above the rear frame.

Some vehicle body structures have a rear frame extending in the longitudinal direction of the vehicle body, an upper frame is provided in an arch shape above the rear frame, and the rear end of the upper frame is connected to the rear end of the rear frame. It has been.
By providing an arch-shaped upper frame, it is possible to support the bumper beam of the opponent vehicle with the upper frame when the opponent vehicle (specifically, the opponent vehicle with the bumper beam placed at a high position) collides from the rear of the vehicle body. (For example, see Patent Document 1).

European Patent Application Publication No. 1361140 (EP 1361140A2)

However, when the bumper beam of the opponent vehicle collides with the arch-shaped upper frame, the upper frame may be bent.
When the upper frame is bent, the bumper beam of the counterpart vehicle may ride on the bent upper frame (that is, the rear part of the vehicle body).

  It is an object of the present invention to provide a vehicle body rear portion structure that can prevent a bumper beam of an opponent vehicle from riding on the vehicle body rear portion.

  According to a first aspect of the present invention, there is provided a rear frame that extends in the longitudinal direction of the vehicle body at a rear portion of the vehicle body, a vertical reinforcing member that is erected upward from a rear end portion of the rear frame, and the vertical reinforcing member And a rear pillar that forms an opening side part of the trunk room, and a collision load that acts on the rear part of the vehicle body from the rear of the vehicle body is applied to the vertical reinforcing member, and the applied collision load is transmitted to the rear frame. It is characterized by that.

  According to a second aspect of the present invention, a beam folding portion is provided on the rear side of the vertical reinforcing member so as to protrude rearward of the vehicle body.

  According to a third aspect of the present invention, a rear panel is provided at the rear end of the rear frame to form a rear partition wall of the trunk room, and a rear panel stiffener is provided between the rear panel and the vertical reinforcing member to reinforce the rear panel. The beam folding part is provided inside a closed cross section formed by the rear panel and the rear panel stiffener.

  According to a fourth aspect of the present invention, a bumper beam is provided at a rear end portion of the rear frame via a bumper beam extension, and the bumper beam and the bumper beam extension can be deformed to absorb a collision load at the time of a light collision. The beam folding part is provided at a position that does not affect the deformation of the bumper beam and the bumper beam extension and above the bumper beam extension.

  According to a fifth aspect of the present invention, an upper portion of the vertical reinforcing member is provided in a closed cross section formed by the rear panel and the rear panel stiffener.

In the invention according to claim 1, the vertical reinforcing member is erected upward from the rear end of the rear frame. The collision load applied to the rear part of the vehicle body from the rear of the vehicle body is applied to the vertical reinforcing member, and the applied collision load is transmitted to the rear frame.
Therefore, when the front bumper beam of the opponent vehicle (a vehicle in which the bumper beam is positioned higher than the rear bumper beam of the rear structure of the vehicle body) collides, the collision load is applied to the vertical reinforcing member and the applied collision load is transmitted to the rear frame. I did it.

Thereby, the collision load which acted on the vertical reinforcement member can be efficiently supported by the rear frame.
In this way, by transmitting the collision load acting on the vertical reinforcing member to the rear frame, it is possible to prevent the vertical reinforcing member from being deformed by the collision load and to prevent the bumper beam of the counterpart vehicle from riding on the rear part of the vehicle body.

Here, the bumper beam of the opponent vehicle is formed in a curved shape so as to protrude toward the front of the vehicle body, and has a shape in which the central portion protrudes (swells) most forward of the vehicle body.
Therefore, the central portion of the bumper beam collides with the vehicle body rear structure, and the collision load acts as a concentrated load on the local portion of the vehicle body rear structure. For this reason, it is difficult to support the concentrated load at the local part of the vehicle body rear structure, and it is conceivable that the counterpart vehicle locally enters the vehicle body rear structure.
In particular, this tendency is remarkable when the bumper beam of the opponent vehicle collides with the rear structure of the vehicle body in an offset collision (that is, collision in a state shifted in the vehicle width direction).

Therefore, the vertical reinforcing member is erected upward from the rear end of the rear frame. Therefore, when the bumper beam of the counterpart vehicle collides with the rear structure of the vehicle body, the bumper beam of the counterpart vehicle can be bent by the vertical reinforcing member.
By bending the bumper beam, the curved bumper beam can be made substantially flat.

Therefore, when the bumper beam of the opponent vehicle collides with the vehicle body rear structure, the collision load can be applied to the vehicle body rear structure as a distributed load (that is, the load is dispersed).
In this way, by causing the collision load to be distributed and applied to the vehicle body rear structure, it is possible to prevent the opponent vehicle from entering the vehicle body rear structure.

In the invention which concerns on Claim 2, the beam folding part was provided in the vehicle body rear side of the vertical reinforcement member.
Therefore, when the bumper beam of the counterpart vehicle collides with the rear structure of the vehicle body, the curved bumper beam can be efficiently bent into a substantially flat shape at the beam folding portion.
As a result, the collision load can be distributed and acted on the rear structure of the vehicle body more satisfactorily, and the entry of the counterpart vehicle into the rear structure of the vehicle body can be further suppressed.

In the invention according to claim 3, the beam folding part is provided inside the closed cross section formed by the rear panel and the rear panel stiffener.
Thereby, the beam folding part can be provided by effectively using the internal space of the closed section.

In the invention according to claim 4, the beam folding part is provided above the bumper beam extension at a position that does not affect the deformation of the bumper beam and the bumper beam extension at the time of a light collision.
Thereby, the beam folding part can be provided by effectively using the space above the bumper beam extension.

In the invention according to claim 5, the upper part of the vertical reinforcing member is provided inside the closed cross section formed by the rear panel and the rear panel stiffener. Therefore, the upper part of the vertical reinforcing member can be provided behind the vehicle body.
Thereby, since the upper part of a vertical reinforcement member can be inclined forward toward the said rear pillar, the rigidity (especially rigidity with respect to the load which acted from the vehicle body rear) can be improved.
Therefore, the collision load applied to the vertical reinforcing member can be transmitted to the rear frame more efficiently.

In addition, by providing the upper part of the vertical reinforcing member inside the closed section, it is not necessary to provide the upper part of the vertical reinforcing member on the trunk room side.
Thus, since it is not necessary to provide the upper part of a vertical reinforcement member in the trunk room side, the space of a trunk room can be ensured large.

1 is a perspective view showing a state in which a vehicle body rear structure (Example 1) according to the present invention is viewed from the front of a vehicle body. 1 is a perspective view showing a main part of a vehicle body rear part structure relating to Embodiment 1. FIG. FIG. 3 is a sectional view taken along line 3-3 in FIG. 2. FIG. 3 is an exploded perspective view illustrating a main part of a vehicle body rear structure according to the first embodiment. It is a figure explaining the example which the other party vehicle collided with the vehicle body rear part structure which concerns on Example 1. FIG. It is a figure explaining the state before the other vehicle carries out an offset collision to the vehicle body rear part structure which concerns on Example 1. FIG. It is a figure explaining the state after the other vehicle carries out an offset collision to the vehicle body rear part structure which concerns on Example 1. FIG. It is a perspective view which shows the state which looked at the vehicle body rear part structure (Example 2) which concerns on this invention from the vehicle body front. It is a perspective view which shows the state which looked at the vehicle body rear part structure which concerns on Example 2 from the vehicle body back. FIG. 10 is a sectional view taken along line 10-10 in FIG. 8. It is a figure explaining the example which the other party vehicle collided with the vehicle body rear part structure based on Example 2. FIG. It is a figure explaining the state before the other vehicle carries out an offset collision to the vehicle body rear part structure which concerns on Example 2. FIG. It is a figure explaining the state after the other party vehicle carries out an offset collision to the vehicle body rear part structure which concerns on Example 2. FIG.

  The best mode for carrying out the present invention will be described below with reference to the accompanying drawings. Note that “front”, “rear”, “left”, and “right” indicate the direction viewed from the driver, the front side is Fr, the rear side is Rr, the left side is L, and the right side is R.

A vehicle body rear structure 10 according to the first embodiment will be described.
As shown in FIGS. 1 and 2, the vehicle body rear structure 10 includes a rear frame 12 that extends in the vehicle longitudinal direction at the vehicle body rear portion 11, a rear pillar 13 that is provided above the rear frame 12, and a rear frame. 12, rear panel 14 provided at rear end 12 a and rear end 13 a of rear pillar 13, rear panel stiffener 15 that reinforces rear panel 14, rear panel stiffener 15, and standing on rear end 12 a of rear frame 12. The vertical reinforcing member 16 is provided.

Further, as shown in FIG. 3, the vehicle body rear structure 10 includes a bumper beam extension 21 provided on the rear end portion 12a of the rear frame 12 via a rear panel 14, and left and right bumper beam extensions 21 (left bumper beam extension 21). Only a rear bumper beam (bumper beam) 22 spanning the rear end portion 21a.
The rear bumper beam 22 and the bumper beam extension 21 can be suitably deformed during a light collision and can absorb the collision load well.

  The rear frame 12 is a member that extends in the longitudinal direction of the vehicle body along the inner wall of the rear wheel arch 24 (see FIG. 2) and forms a skeleton of the vehicle body rear structure 10.

The rear pillar 13 is an aggregate that is provided above the rear frame 12 and whose rear end portion 13 a is bent in an inclined manner toward the rear end portion 12 a of the rear frame 12 to form an opening side portion of the trunk room 25.
The rear end 13a of the rear pillar 13 is formed in a state of being inclined forward toward the front of the vehicle body by being bent in an inclined manner.

  The rear panel 14 is a member that forms a rear partition wall of the trunk room 25 by providing a lower side portion 14 a at the rear end portion 12 a of the rear frame 12 and an upper side portion 14 b at the rear end portion 13 a of the rear pillar 13.

The rear panel stiffener 15 is disposed between the rear panel 14 and the vertical reinforcing member 16 (specifically, a front vertical reinforcing member 31 described later), and is provided on the rear panel 14 from the vehicle body front side (trunk room 25 side) as shown in FIG. It has been.
By providing the rear panel stiffener 15 on the rear panel 14, the rear panel 14 can be reinforced by the rear panel stiffener 15.
The rear panel stiffener 15 includes a stiffener wall 28 that faces the trunk room 25.

In the stiffener wall portion 28, the lower half portion 28 a of the stiffener is raised vertically, and the upper half portion 28 b of the stiffener is inclined forward to the rear end portion 13 a of the rear pillar 13.
The upper end 28c of the stiffener upper half 28b is joined to the rear end 13a of the rear pillar 13.

The vertical reinforcing member 16 is provided on the rear panel stiffener 15 and is erected on the rear end portion 12 a of the rear frame 12.
The vertical reinforcing member 16 includes a front vertical reinforcing member 31 provided on the inner surface 15b (the surface on the trunk room 25 side) of the rear panel stiffener 15 and an outer surface 15a of the rear panel stiffener 15 (a closed cross section formed by the rear panel 14 and the rear panel stiffener 15). And a rear vertical reinforcing member 32 provided on a surface in the portion 34.

As shown in FIG. 4, the front vertical reinforcing member 31 extends downward from the inner surface 15b of the rear panel stiffener 15 (specifically, the inner surface of the lower half portion 28a of the stiffener) toward the rear end portion 12a of the rear frame 12. The inclined front wall portion 36, the inner side wall portion 37 bent from the inner side of the inclined front wall portion 36 toward the rear of the vehicle body, and the outer side edge of the inclined front wall portion 36 bent toward the rear of the vehicle body. And an outer wall 38 (see FIG. 3).
The front vertical reinforcing member 31 is formed in a substantially U-shaped cross section by an inclined front wall portion 36, an inner wall portion 37 and an outer wall portion 38.

The inclined front wall portion 36 extends with a downward slope toward the front of the vehicle body by joining the upper side portion 36a to the inner surface 15b of the rear panel stiffener 15 and joining the lower side portion 36b to the rear end portion 12a of the rear frame 12. Has been.
Here, as shown in FIG. 3, a substantially right triangle is formed by the inclined front wall portion 36, the stiffener lower half portion 28 a, and the rear end portion 12 a of the rear frame 12.

  As shown in FIG. 4, the inner side wall portion 37 is formed in a substantially triangular shape, the vertical side portion 37 a is joined to the inner surface 15 b of the rear panel stiffener 15, and the horizontal side portion 37 b is joined to the inner flange 12 b of the rear frame 12. ing.

  The outer side wall portion 38 is a symmetrical portion with the inner side wall portion 37, is formed in a substantially triangular shape (see also FIG. 3), the vertical side portion 38a is joined to the inner surface 15b of the rear panel stiffener 15, and the horizontal side portion ( (Not shown) is joined to the outer flange 12c of the rear frame 12.

  By providing the front vertical reinforcing member 31 on the rear panel stiffener 15 and standing on the rear end 12 a of the rear frame 12, it is possible to transmit the collision load acting on the rear body 11 from the rear of the vehicle body to the rear frame 12.

The rear vertical reinforcing member 32 is disposed in an internal space (inside) 35 (that is, the rear side of the vehicle body of the front vertical reinforcing member 31) of the closed cross section 34 formed by the rear panel 14 and the rear panel stiffener 15, and protrudes rearward of the vehicle body ( It is a box-shaped (boat bottom-shaped) member formed to swell.
The rear vertical reinforcing member 32 includes a vertically lower half portion 41 provided vertically and a forward inclined upper half portion (upper portion of the vertical reinforcing member) 42 inclined forward.

By providing the rear vertical reinforcing member 32 in the internal space 35, the rear vertical reinforcing member 32 can be provided at the rear of the vehicle body. Therefore, the forward inclined upper half 42 can be inclined forward toward the rear pillar 13.
Further, by providing the rear vertical reinforcing member 32 in the internal space 35, the rear vertical reinforcing member 32 can be provided by effectively using the internal space 35 of the closed cross section 34.

  The rear vertical reinforcing member 32 includes a bottom wall portion 44 formed in a substantially rectangular shape, an inner wall portion 45 bent from the inner side of the bottom wall portion 44 toward the front of the vehicle body, and an outer side of the bottom wall portion 44. The outer wall portion 46 is bent toward the front of the vehicle body, the upper wall portion 47 is bent toward the front of the vehicle body from the upper side of the bottom wall portion 44, and is bent toward the front of the vehicle body from the lower side of the bottom wall portion 44. And a lower wall portion 48.

  Further, the rear vertical reinforcing member 32 includes an inner joint portion 45a bent toward the vehicle body center side from the edge of the inner wall portion 45, and an outer joint portion 46a bent toward the vehicle body outside from the edge of the outer wall portion 46. And an upper joint portion 47a bent upward from the edge of the upper wall portion 47 and a lower joint portion 48a bent downward from the edge of the lower wall portion 48.

The inner joint portion 45a has a lower half portion provided vertically along the stiffener lower half portion 28a and an upper half portion provided forwardly inclined along the stiffener upper half portion 28b.
Further, the outer joint portion 46a has a lower half portion provided vertically along the stiffener lower half portion 28a and an upper half portion provided forwardly inclined along the stiffener upper half portion 28b.

The lower half of the inner joint 45a, the lower half of the outer joint 46a, and the lower joint 48a are joined to the stiffener lower half 28a, respectively.
The upper half of the inner joint 45a, the upper half of the outer joint 46a, and the upper joint 47a are joined to the stiffener upper half 28b.

That is, in the vertical rear reinforcing member 32, the vertical lower half 41 is joined to the rear surface of the stiffener lower half 28a, and the forward inclined upper half 42 is joined to the rear surface of the stiffener upper half 28b.
In this state, the rear vertical reinforcing member 32 is provided in the internal space 35 between the rear panel 14 and the rear panel stiffener 15.

  Further, the rear vertical reinforcing member 32 has a forward inclined upper half 42 protruding upward from the upper end 31a of the front vertical reinforcing member 31, and joined (connected) to the rear end 13a of the rear pillar 13 via the stiffener upper half 28b. )

As described above, by tilting the forward inclined upper half 42 toward the rear pillar 13, the rigidity of the rear vertical reinforcing member 32 (particularly, the rigidity against the load applied from the rear of the vehicle body) can be increased.
Thereby, the collision load which acted on the back vertical reinforcement member 32 (namely, vertical reinforcement member 16) can be efficiently transmitted to the rear frame 12.

Further, the rear vertical reinforcing member 32 serves as a beam folding portion that bends the front bumper beam 56 (see FIG. 6) of the counterpart vehicle 55.
Therefore, when the front bumper beam 56 of the opponent vehicle 55 collides with the rear body structure 10 by an offset collision (that is, collides in a state shifted in the vehicle width direction), the curved front bumper beam 56 is replaced with the rear vertical reinforcing member 32. Can be efficiently folded into a substantially flat shape.

In addition, by providing the rear vertical reinforcing member 32 in the internal space 35 of the closed cross section 34, it is not necessary to provide the rear vertical reinforcing member 32 on the trunk room 25 (see FIG. 3) side.
Thus, since it is not necessary to provide the rear vertical reinforcing member 32 on the trunk room 25 side, a large space in the trunk room 25 can be secured.

Next, an example in which the opponent vehicle 55 collides with the vehicle body rear portion 11 of the vehicle body rear structure 10 will be described with reference to FIGS.
First, an example in which a collision load is supported by the rear frame 12 will be described with reference to FIG.
As shown in FIG. 5A, the vertical reinforcing member 16 (that is, the front vertical reinforcing member 31 and the rear vertical reinforcing member 32) is erected upward from the rear end portion 12a of the rear frame 12.

Here, the front bumper beam 56 of the counterpart vehicle 55 is disposed at a position higher than the rear bumper beam 22 of the vehicle body rear structure 10.
That is, the front bumper beam 56 of the opponent vehicle 55 is disposed at a position facing the vertical reinforcing member 16.
The front bumper beam 56 of the opponent vehicle 55 collides with the vertical reinforcing member 16 as indicated by an arrow A.

  As shown in FIG. 5B, the collision load F1 acts on the vertical reinforcing member 16, and the applied collision load F1 passes through the vertical reinforcing member 16 (particularly, the front vertical reinforcing member 31) as the load F2 on the rear frame 12. I can tell you.

Thereby, the collision load F <b> 1 acting on the vertical reinforcing member 16 can be efficiently supported by the rear frame 12.
Thus, by transmitting the collision load F1 applied to the vertical reinforcing member 16 to the rear frame 12 as the load F2, it is possible to prevent the vertical reinforcing member 16 from being deformed by the collision load F1.
Therefore, the front bumper beam 56 of the opponent vehicle 55 can be prevented from riding on the vehicle body rear portion 11 of the vehicle body rear structure 10.

Next, an example in which the front bumper beam 56 of the opponent vehicle collides with the vehicle body rear portion 11 of the vehicle body rear structure 10 will be described with reference to FIGS.
As shown in FIG. 6A, the vertical reinforcing member 16 (that is, the front vertical reinforcing member 31 and the rear vertical reinforcing member 32) is erected upward from the rear end portion 12a of the rear frame 12.

Here, the front bumper beam 56 of the opponent vehicle 55 is disposed at a position higher than the rear bumper beam 22 of the vehicle body rear structure 10.
That is, the front bumper beam 56 of the opponent vehicle 55 is disposed at a position facing the vertical reinforcing member 16.

As shown in FIG. 6B, the front bumper beam 56 of the opponent vehicle 55 collides with an offset as indicated by an arrow B in a state where the front bumper beam 56 is shifted to the left side with respect to the vehicle body rear portion 11.
The substantially central portion 56 a of the curved front bumper beam 56 collides with the vertical reinforcing member 16.

  As shown in FIG. 7A, when the substantially central portion 56a of the curved front bumper beam 56 collides with the vertical reinforcing member 16, the substantially central portion 56a of the front bumper beam 56 is moved to the vertical reinforcing member 16 (in particular, The rear vertical reinforcing member 32) can be bent.

By bending the substantially central portion 56a of the curved front bumper beam 56, the curved front bumper beam 56 can be made substantially flat (straight).
Therefore, when the front bumper beam 56 of the opponent vehicle 55 collides with the vehicle body rear structure 10, the collision load F3 can be distributed and applied to the vehicle body rear portion 11 as a distributed load.

  As shown in FIG. 7 (b), by causing the collision load F3 to be dispersed and applied to the rear part 11 of the vehicle body, the intrusion of the opponent vehicle 55 into the rear part 11 of the vehicle body can be further suppressed.

A vehicle body rear structure 60 according to the second embodiment will be described.
As shown in FIGS. 8 to 9, the vehicle body rear structure 60 includes a vertical reinforcing member 61, an upper beam folding part (beam folding part) 62, and a lower beam folding part (beam folding part) 63. The configuration is the same as that of the vehicle body rear structure 10 of the first embodiment.

As shown in FIG. 8, the vertical reinforcing member 61 is extended from the inner surface 15b of the rear panel stiffener 15 (specifically, the inner surface of the upper half portion 28b of the stiffener) toward the rear end 12a of the rear frame 12. A wall portion 65, an inner wall portion 66 bent from the inner side of the front wall portion 65 toward the rear of the vehicle body, an outer wall portion 67 bent from the outer side of the front wall portion 65 toward the rear of the vehicle body, And a pair of upper wall portions 68 bent toward the rear of the vehicle body from the upper side of the wall portion 65.
The vertical reinforcing member 61 is formed of a front wall portion 65, an inner wall portion 66 and an outer wall portion 67 in a substantially U-shaped cross section.

The front wall portion 65 has an upper half portion 65a formed in a vertical shape, and a lower half portion 65b formed in a downward slope toward the front of the vehicle body.
The lower joint portion 65c of the lower half portion 65b is joined to the rear end portion 12a of the rear frame 12.

The inner wall portion 66 has an inner joint portion 66 a joined to the inner surface 15 b of the rear panel stiffener 15 and the inner flange 12 b of the rear frame 12.
The outer side wall portion 67 has an outer joint portion 67 a joined to the inner surface 15 b of the rear panel stiffener 15 and the outer flange 12 c of the rear frame 12.
In the pair of upper wall portions 68, an upper joint portion 68 a is joined to the inner surface 15 b of the rear panel stiffener 15.

  By providing the vertical reinforcing member 61 on the rear panel stiffener 15 and standing on the rear end portion 12 a of the rear frame 12, it is possible to transmit the collision load acting on the rear body portion 11 from the rear of the vehicle body to the rear frame 12.

  As shown in FIGS. 9 and 10, the upper beam folding part 62 is a similar member of the rear vertical reinforcing member 32 provided in the first embodiment, and is an internal space of the closed cross-sectional part 34 formed by the rear panel 14 and the rear panel stiffener 15. 35 (that is, the rear side of the vertical reinforcing member 61), and a box-shaped member formed so as to protrude (bulge) rearward of the vehicle body.

The upper beam folding part 62 includes a vertically lower half part 71 provided vertically and a forwardly inclined upper half part (upper part of the upper beam folding part 62) 72 inclined forward.
By providing the upper beam folding part 62 in the internal space 35, the upper beam folding part 62 can be provided at the rear of the vehicle body. Therefore, the forward tilting upper half 72 can be tilted forward toward the rear pillar 13.
Further, by providing the upper beam folding part 62 in the internal space 35, the upper beam folding part 62 can be provided by effectively using the internal space 35 of the closed section 34.

In the upper beam folding part 62, the vertical lower half 71 is joined to the rear surface of the stiffener lower half 28a, and the forward inclined upper half 72 is the stiffener upper half 28b, similarly to the rear vertical reinforcing member 32 of the first embodiment. It is joined to the rear surface.
In this state, the upper beam folding part 62 is provided in the internal space 35 between the rear panel 14 and the rear panel stiffener 15.

  Further, the upper beam folding portion 62 has a forward inclined upper half portion 72 provided at substantially the same height as the upper end portion of the vertical reinforcing member 61, and is connected to the rear end portion 13 a of the rear pillar 13 via the stiffener upper half portion 28 b. It is joined (connected).

As described above, by tilting the upper beam folding part 62 forward toward the rear pillar 13, the rigidity of the upper beam folding part 62 (particularly, rigidity against a load applied from the rear of the vehicle body) can be increased.
Thereby, the collision load acting on the upper beam folding part 62 can be efficiently transmitted to the rear frame 12.

Further, the upper beam folding part 62 serves as a member that bends the front bumper beam 56 (see FIG. 11) of the opponent vehicle 55.
Therefore, when the front bumper beam 56 of the counterpart vehicle 55 collides with the rear structure 60 of the vehicle body, the curved front bumper beam 56 can be efficiently bent into a substantially flat shape by the upper beam folding portion 62.

In addition, by providing the upper beam folding part 62 in the internal space 35 of the closed cross section 34, it is not necessary to provide the upper beam folding part 62 on the trunk room 25 (see FIG. 10) side.
Thus, since it is not necessary to provide the upper beam folding part 62 on the trunk room 25 side, a large space in the trunk room 25 can be secured.

  The lower beam folding part 63 is formed smaller than the upper beam folding part 62, and is a lower space 74 of the closed cross section 34 formed by the rear panel 14 and the rear panel stiffener 15 (that is, the vehicle body rear side of the vertical reinforcing member 61). It is a box-shaped member that is arranged at the rear and is formed so as to protrude (expand) rearward of the vehicle body.

The lower beam folding part 63 has a joint part 64 joined to the rear surface of the lower side part 14 a of the rear panel 14.
The rear panel 14 has a lower side portion 14a formed in a stepped shape toward the front of the vehicle body. A lower beam folding portion 63 is provided at the stepped portion 76 of the rear panel 14 and above the bumper beam extension 21.

Therefore, the lower beam folding part 63 can be disposed at a position that does not affect the deformation of the rear bumper beam 22 and the bumper beam extension 21 when a light collision is caused from the rear to the vehicle body rear part 11.
Thereby, the lower beam folding part 63 can be provided by effectively using the space above the bumper beam extension 21.

The lower beam folding part 63 serves as a member that bends the front bumper beam 56 (see FIG. 11) of the opponent vehicle 55.
Therefore, when the front bumper beam 56 of the counterpart vehicle 55 collides with the rear body structure 60 in an offset manner, the curved front bumper beam 56 can be efficiently bent into a substantially flat shape by the lower beam folding portion 63.

Next, an example in which the opponent vehicle 55 collides with the vehicle body rear portion 11 of the vehicle body rear structure 60 will be described with reference to FIGS.
First, an example in which a collision load is supported by the rear frame 12 will be described with reference to FIG.
As shown in FIG. 11A, a vertical reinforcing member 61 is erected upward from the rear end portion 12a of the rear frame 12, and upper and lower beam folding portions 62 and 63 are provided at the rear of the vertical reinforcing member 61 in the vehicle body. It was.

Here, the front bumper beam 56 of the opponent vehicle 55 is disposed at a position higher than the rear bumper beam 22 of the vehicle body rear structure 60.
That is, the front bumper beam 56 of the opponent vehicle 55 is disposed at a position facing the vertical reinforcing member 61 and the upper and lower beam folding portions 62 and 63.
The front bumper beam 56 of the opponent vehicle 55 collides with the upper and lower beam folding parts 62 and 63 as indicated by an arrow C.

  As shown in FIG. 11B, the collision load F4 acts on the vertical reinforcing member 61 through the upper and lower beam folding parts 62 and 63. The applied collision load F4 can be transmitted as the load F5 to the rear frame 12 through the vertical reinforcing member 61.

As a result, the collision load F4 acting on the vertical reinforcing member 61 can be efficiently supported by the rear frame 12.
Thus, by transmitting the collision load F4 applied to the vertical reinforcing member 61 to the rear frame 12 as the load F5, the vertical reinforcing member 61 can be prevented from being deformed by the collision load F4.
Therefore, the front bumper beam 56 of the opponent vehicle 55 can be prevented from riding on the vehicle body rear portion 11 of the vehicle body rear portion structure 60.

Next, an example in which the front bumper beam 56 of the opponent vehicle collides with the rear body 11 of the rear body structure 60 will be described with reference to FIGS.
As shown in FIG. 12A, a vertical reinforcing member 61 is erected upward from the rear end portion 12a of the rear frame 12, and upper and lower beam folding portions 62 and 63 are provided at the rear of the vertical reinforcing member 61 in the vehicle body. It was.

Here, the front bumper beam 56 of the opponent vehicle 55 is disposed at a position higher than the rear bumper beam 22 of the vehicle body rear structure 60.
That is, the front bumper beam 56 of the opponent vehicle 55 is disposed at a position facing the vertical reinforcing member 61 and the upper and lower beam folding portions 62 and 63.

As shown in FIG. 12B, the front bumper beam 56 of the opponent vehicle 55 collides with an offset as indicated by an arrow D in a state where the front bumper beam 56 is shifted to the left with respect to the vehicle body rear portion 11.
A substantially central portion 56 a of the curved front bumper beam 56 collides with the upper and lower beam folding portions 62 and 63.

  As shown in FIG. 13 (a), the substantially central portion 56a of the curved front bumper beam 56 collides with the upper and lower beam folding portions 62 and 63, so that the substantially central portion 56a of the front bumper beam 56 is moved to the upper and lower beams. The folding parts 62 and 63 can be bent.

By bending the substantially central portion 56a of the curved front bumper beam 56, the curved front bumper beam 56 can be made substantially flat (straight).
Therefore, when the front bumper beam 56 of the counterpart vehicle 55 collides with the vehicle body rear structure 60, the collision load F6 can be distributed and applied to the vehicle body rear portion 11 as a distributed load.

  As shown in FIG. 13 (b), by causing the collision load F6 to be dispersed and acted on the vehicle body rear portion 11 in an appropriate manner, it is possible to further effectively prevent the opponent vehicle 55 from entering the vehicle body rear portion 11.

The vehicle body rear structure 10 according to the present invention is not limited to the first and second embodiments described above, and can be changed or improved as appropriate.
For example, in the second embodiment, the example in which the substantially central portion 56a of the front bumper beam 56 is bent by the upper and lower beam folding portions 62 and 63 has been described, but the upper beam folding portion 62 and the lower beam folding portion are not limited thereto. It is also possible to bend the substantially central portion 56 a of the front bumper beam 56 at any one of the beam folding portions 63.

  In addition, the rear frame 12, the rear pillar 13, the rear panel 14, the rear panel stiffener 15, the vertical reinforcing members 16, 61, the bumper beam extension 21, the rear bumper beam 22, the trunk room 25, the closed cross-section portion 34, the inside shown in the first and second embodiments. The shapes of the space 35, the forward tilting upper half 42, the upper beam folding part 62, the lower beam folding part 63, and the like are not limited to those illustrated, and can be changed as appropriate.

  The present invention is suitable for application to an automobile having a rear body structure in which a rear frame extends in the longitudinal direction of the vehicle body and a rear pillar is provided above the rear frame.

  DESCRIPTION OF SYMBOLS 10 ... Vehicle body rear part structure, 11 ... Vehicle body rear part, 12 ... Rear frame, 12a ... Rear frame rear end part, 13 ... Rear pillar, 14 ... Rear panel, 15 ... Rear panel stiffener, 16, 61 ... Vertical reinforcement member, 21 ... Bumper beam Extension, 22 ... Rear bumper beam (bumper beam), 25 ... Trunk room, 34 ... Closed section, 35 ... Internal space (inside), 42 ... Forward tilted upper half (upper part of vertical reinforcing member), 62 ... Upper beam folding part ( Beam folding part), 63 ... Lower beam folding part (beam folding part), F1, F3, F4, F6 ... Collision load.

Claims (5)

A rear frame extending toward the longitudinal direction of the vehicle body at the rear of the vehicle body;
A vertical reinforcing member erected upward from the rear end of the rear frame;
The upper part of the vertical reinforcing member is connected, and the rear pillar that forms the opening side part of the trunk room,
With
A rear structure of a vehicle body, wherein a collision load applied to a rear part of the vehicle body from the rear of the vehicle body is applied to the vertical reinforcing member, and the applied collision load is transmitted to the rear frame.   2. The vehicle body rear structure according to claim 1, wherein a beam folding portion is provided on the vehicle body rear side of the vertical reinforcing member so as to protrude rearward of the vehicle body. A rear panel provided at the rear end of the rear frame to form a rear partition wall of the trunk room;
In order to reinforce the rear panel, a rear panel stiffener is provided between the rear panel and the vertical reinforcing member,
The vehicle body rear part structure according to claim 2, wherein the beam folding part is provided inside a closed cross section formed by the rear panel and the rear panel stiffener. A bumper beam is provided via a bumper beam extension at the rear end of the rear frame,
The bumper beam and the bumper beam extension can be deformed to absorb a collision load during a light collision,
4. The beam folding portion is provided at a position that does not affect the deformation of the bumper beam and the bumper beam extension at the time of the light collision and above the bumper beam extension. Car body rear structure.   The vehicle body rear structure according to claim 2, wherein an upper portion of the vertical reinforcing member is provided in a closed cross section formed by the rear panel and the rear panel stiffener.

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