JP2023090983A - Vehicle body rear structure - Google Patents

Abstract

To efficiently disperse a vibration to be transmitted to a rear floor panel.SOLUTION: A vehicle body rear structure includes a pair of first braces 21 and 22 that are placed apart, extended in a fore-and-aft direction, and joined to a rear end panel 70 and a first rear cross member 51, and a pair of second braces 31 and 32 that are placed apart, extended in the fore-and-aft direction, and joined to the first rear cross member 51 and a second rear cross member 52. The pair of first braces 21 and 22 are interposed between the pair of second braces 31 and 32. The space between the pair of first braces 21 and 22 is smaller than a half of the space between the pair of second braces 31 and 32.SELECTED DRAWING: Figure 2

Description

The present invention relates to a vehicle body rear structure.

Some floors at the rear part of the vehicle body are provided with slopes, as disclosed in Patent Document 1, for example. By providing the slope, a load having a large dimension in the vertical direction of the vehicle can be loaded. A rear floor panel provided with such a slope is generally flat plate-shaped without unevenness such as a spare tire housing.

On the other hand, the rear floor panel is joined with a vehicle body structural member that constitutes the frame of the vehicle body. A structure that becomes a vibration source, such as a suspension structure, is attached to the vehicle body structural member. Therefore, the vibration of the structure is transmitted to the rear floor panel via the vehicle body structural member.

In Patent Document 1, a rear floor panel is provided with two support portions extending in the vehicle front-rear direction. By providing the support portion, the vibration of the rear floor panel is suppressed to some extent.

Japanese Patent No. 6081371

However, in the structure as in the above example, there is a possibility that the vibration transmitted to the rear floor panel will overreact to a single vibration mode and resonate. Therefore, there is room for improvement in suppressing the vibration of the rear floor panel in the structure in which the supporting portion is provided as in the above example.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to disperse the resonance of the vibration transmitted to the rear floor panel without overreacting to a single vibration mode. To provide a vehicle body rear structure capable of

A vehicle body rear structure according to the present invention for achieving the above object comprises a differential brace that supports a differential gearbox, and a rear differential cross member that extends in the vehicle width direction and is joined to the rear of the differential brace and joined to a rear floor panel. and a pair of braces extending rearward from the differential cross member, arranged on both sides of the differential brace in the vehicle width direction, and joined to the rear floor panel.

According to the invention, the vibrations transmitted to the rear floor panel are not overreacted to a single vibration mode, and the resonance can be distributed.

1 is a perspective view of a vehicle body rear portion structure according to the present invention, viewed from below the vehicle; FIG. FIG. 2 is a bottom view of the vehicle body rear portion structure of FIG. 1 ; FIG. 3 is a cross-sectional view taken along the line AA of FIG. 2; FIG. 3 is a bottom view showing a state in which a suspension structure and the like are attached to the vehicle body rear structure of FIG. 2 ;

An embodiment of the vehicle body rear portion structure according to the present invention will be described below with reference to the drawings (FIGS. 1 to 4). In the drawings, the direction of arrow Fr indicates the front in the longitudinal direction of the vehicle. "Front part (front end) and rear part (rear end)" in the description of the embodiment correspond to the front part and the rear part in the longitudinal direction of the vehicle. The directions of arrows L and R indicate left and right sides in the vehicle width direction. Further, "left and right" in the description of the present embodiment correspond to left and right when an occupant in the vehicle interior faces the front of the vehicle.

As shown in FIGS. 1 and 2, the rear vehicle body structure of this embodiment includes a rear floor panel 1, a rear end panel 70, a pair of rear side members 11 and 12, and three rear cross members (first rear cross member 51, a second rear cross member (rear differential cross member) 52 and a third rear cross member 53). Further, the vehicle body rear structure has a pair of first braces 21 and 22 , a pair of second braces 31 and 32 and a third brace (differential brace) 41 .

A right rear wheelhouse panel 71 and a left rear wheelhouse panel 72 are provided on both sides of the rear floor panel 1 in the vehicle width direction, and a rear suspension structure is provided below the rear floor panel 1 . Further, as shown in FIG. 4, a propeller shaft 96, a rear differential gear box 95, a drive shaft 97, and the like are arranged on the lower surface side of the rear floor panel 1. As shown in FIG.

The rear side members 11 and 12 have a right rear side member 11 and a left rear side member 12. The right rear side member 11 and the left rear side member 12 are arranged in a pair spaced apart from each other outward in the vehicle width direction. It is The right rear side member 11 and the left rear side member 12 are members that extend in the longitudinal direction of the vehicle, are formed of a metal material, and are highly rigid members that constitute the vehicle body frame. The right rear side member 11 is joined to the right side of the rear floor panel 1 in the vehicle width direction, and the left rear side member 12 is joined to the left side of the rear floor panel 1 .

The rear floor panel 1 is a plate-like member forming the floor portion of the rear portion of the vehicle body, and is made of a metal material. The rear floor panel 1 extends from the rear end of the vehicle body toward the front side of the vehicle to an intermediate portion in the front-rear direction of the vehicle body, and is joined to a center floor panel 2 which will be described later.

As shown in FIG. 3, the rear portion of the rear floor panel 1 located between the right rear side member 11 and the left rear side member 12 is inclined downward toward the vehicle rear side. Further, the right rear wheel house panel 71 and the left rear wheel house panel 72 are arranged outside the inclined portion of the rear floor panel 1 in the vehicle width direction.

As shown in FIG. 3, the inclined portion has a substantially triangular side wall 1a when viewed in the vehicle width direction. A flange projecting outward in the vehicle width direction is provided at the upper end of the triangular side wall 1a, and a right rear side member 11 and a left rear side member 12 are joined to the flange. That is, the triangular side wall 1a is spaced apart from the right rear side member 11 and the left rear side member 12 in the vehicle width direction.

The rear end panel 70 is a plate-like member that faces the rear of the vehicle, and extends upward from the rear end of the rear floor panel 1 and in the width direction of the vehicle. In this example, the lower portion of the rear end panel 70 is joined to the rear end portion of the rear floor panel 1 . A right rear wheel house panel 71 and a left rear wheel house panel 72 are joined to the lateral side of the rear end panel 70 in the vehicle width direction.

Next, the first rear cross member 51, the second rear cross member 52 and the third rear cross member 53 will be explained. The first rear cross member 51, the second rear cross member 52, and the third rear cross member 53 each extend in the vehicle width direction and are highly rigid members made of a metal material.

The first rear cross member 51, the second rear cross member 52 and the third rear cross member 53 are spaced apart in the longitudinal direction of the vehicle. In this example, a first rear cross member 51, a second rear cross member 52, and a third rear cross member 53 are arranged in this order from the vehicle rear side to the front side, and joined to the lower surface of the rear floor panel 1. ing.

The first rear cross member 51 is arranged on the vehicle front side of the rear end panel 70 with a space therebetween, and includes a first main body portion (main body) 51A, a first right extension (side member) 51B, and a first rear cross member 51A. 1 left extension (side member) 51C. The first main body portion 51A, the first right extension 51B, and the first left extension 51C each extend in the vehicle width direction, have a hat-shaped cross section opening upward, and are provided with a front flange and a rear flange. ing. The front flange 54 and the rear flange of the first body portion 51A are joined to the inclined portion of the lower surface of the rear floor panel 1 .

The first right extension 51B is joined to the right side of the first body portion 51A in the vehicle width direction, and the first left extension 51C is joined to the left side of the first body portion 51A. The first right extension 51B bridges the side wall 1a of the inclined portion of the rear floor panel 1 and the right rear side member 11, and the first left extension 51C bridges the side wall 1a and the left rear side member 12. handing over.

The second rear cross member 52 is spaced apart from the first rear cross member 51 on the front side of the vehicle, and includes a second body portion 52A, a second right extension 52B, and a second left extension 52B. It has an extension 52C. Each of the second main body portion 52A, the second right extension 52B, and the second left extension 52C extends in the vehicle width direction, has a hat-shaped cross section opening upward, and is provided with a front flange and a rear flange. ing. The front and rear flanges of the second body portion 52A, the second right extension 52B, and the second left extension 52C are joined to the lower surface of the rear floor panel 1 at a position where the inclination starts.

The third rear cross member 53 is arranged on the vehicle front side of the second rear cross member 52 with a space therebetween, and is arranged at the rear portion of the rear floor panel 1 in this example. Side portions of the third rear cross member 53 are joined to the right rear side member 11 and the left rear side member 12 . The third rear floor cross member has a hat-shaped cross-section opening upward, and although not shown in detail, is provided with a front flange and a rear flange. The front flange and rear flange are joined to the bottom surface of the rear floor panel 1 .

The rear suspension structure of this embodiment is a multi-link suspension, and as shown in FIG. 4, has a right trailing arm 81 and a left trailing arm 82 arranged on both outer sides in the vehicle width direction. The right trailing arm 81 and the left trailing arm 82 extend in the vehicle front-rear direction from the front side to the rear side of the second rear cross member 52 . The right trailing arm 81 is connected to the lower surface of the right rear side member 11 via a coil spring (not shown) or the like, and the left trailing arm 82 is connected to the lower surface of the left rear side member 12 via a coil spring or the like. ing.

As shown in FIG. 4, the right trailing arm 81 and the left trailing arm 82 are provided with spring mounting portions 81d and 82d. The spring installation portions 81d and 82d project from the vehicle width direction inside portions of the main bodies of the trailing arms 81 and 82 toward the vehicle width direction center. Installed. The spring mounting portions 81d and 82d are arranged to face the lower surfaces of the rear side members 11 and 12, respectively. As shown in FIGS. 1 and 2, spring receiving portions 11d and 12d are provided on the lower surfaces of the rear side members 11 and 12 located above the spring mounting portions 81d and 82d. The spring receiving portions 11d and 12d are arranged adjacent to the rear side of the second rear cross member 52 in the vehicle front-rear direction.

Next, a pair of first braces (first right brace 21, first left brace 22) will be described. The first right brace 21 and the first left brace 22 are members extending in the longitudinal direction of the vehicle, and are spaced apart from each other in the width direction of the vehicle. The front portions of the first right brace 21 and the first left brace 22 are joined to the first rear cross member 51 , and the rear portions thereof are joined to the rear end panel 70 .

The first right brace 21 has a hat-shaped cross section that opens upward. An outer flange 21b is provided on the outer side in the vehicle width direction of the upper portion of the first right brace 21, and an inner flange 21c is provided on the inner side in the vehicle width direction.

The outer flange 21b and the inner flange 21c positioned above the first right brace 21 are inclined along the inclined portion of the lower surface of the rear floor panel 1 . The outer flange 21b and the inner flange 21c are joined to the inclined lower surface. A lower surface 21a of the first right brace 21 extends substantially horizontally along the vehicle front-rear direction. The rear end of the first right brace 21 is joined to the lower portion of the rear end panel 70 (Fig. 3).

The front end of the lower surface 21a of the first right brace 21 is provided with a front flange 21d extending from the front end toward the vehicle front side. The front flange 21 d is joined to the lower surface 51 a of the first body portion 51 A of the first rear cross member 51 . Although not shown in detail, the front ends of the outer flange 21b and the inner flange 21c are provided with flanges extending downward from the front ends, and the flanges are joined to the rear wall of the first body portion 51A.

Like the first right brace 21, the first left brace 22 has a hat-shaped cross-sectional shape that opens upward. An inner flange 22c is provided on the inner side in the vehicle width direction.

The outer flange 22b and the inner flange 22c of the first left brace 22 are joined to the inclined portion of the lower surface of the rear floor panel 1, similarly to the first right brace 21. As shown in FIG. The lower surface 22 a of the first left brace 22 extends substantially horizontally along the vehicle front-rear direction, and the rear end of the first left brace 22 is joined to the lower portion of the rear end panel 70 .

A front flange (flange) 22d is provided at the front end of the lower surface 22a of the first left brace 22, similarly to the first right brace 21, and the front flange 22d is joined to the lower surface 51a of the first main body portion 51A. It is Also, the front end of the first left brace 22 is provided with a flange that is joined to the rear wall of the first main body portion 51A, like the first right brace 21 .

Next, a pair of second braces (a pair of braces: second right brace 31, second left brace 32) will be described. The second right brace 31 and the second left brace 32 are members extending in the longitudinal direction of the vehicle, and are spaced apart from each other in the width direction of the vehicle. The front portions of the second right brace 31 and the second left brace 32 are joined to the second rear cross member 52 , and the rear portions of the second right brace 31 and the second left brace 32 are joined to the first rear cross member 51 .

Like the first right brace 21, the second right brace 31 has a hat-shaped cross-sectional shape that opens upward. An outer flange 31b is provided on the outer side in the vehicle width direction of the upper portion of the second right brace 31, and an inner flange 31c is provided on the inner side in the vehicle width direction.

The outer flange 31b and the inner flange 31c positioned above the second right brace 31 are inclined along the inclined portion of the lower surface of the rear floor panel 1 . The outer flange 31 b and the inner flange 31 c are joined to the inclined lower surface of the rear floor panel 1 . Furthermore, the rear portion of the inner flange 31c is joined to the front flange 54 of the first main body portion 51A, and the rear portion of the outer flange 31b is joined to the front flange 55 of the first right extension 51B. Also, the rear end of the second right brace 31 may be provided with a flange that is joined to the front wall of the first body portion 51A.

Further, the front portion of the inner flange 31c of the second right brace 31 is joined to the rear flange 57 of the second body portion 52A, and the front portion of the outer flange 31b is joined to the rear flange 58 of the second right extension 52B. are spliced. A front flange 31d is formed on the front end of the lower surface 31a of the second right brace 31 and extends from the front end toward the front side of the vehicle. The front flange 31d is joined to the rear portion of the lower surface 52a of the second body portion 52A. Although detailed illustration is omitted, flanges extending downward are provided at the front ends of the outer flange 31b and the inner flange 31c, and the flanges are joined to the rear wall of the second main body portion 52A.

Like the second right brace 31, the second left brace 32 has a hat-shaped cross-sectional shape that opens upward, and is provided with an outer flange 32b and an inner flange 32c. The outer flange 32b and the inner flange 32c are joined to the inclined lower surface of the rear floor panel 1. As shown in FIG. Furthermore, the rear portion of the inner flange 32c is joined to the front flange 54 of the first main body portion 51A, and the rear portion of the outer flange 32b is joined to the front flange 56 of the first left extension 51C. Also, the rear end of the second left brace 32 may be provided with a flange that is joined to the front wall of the first body portion 51A.

Furthermore, like the second right brace 31, the front portion of the inner flange 32c of the second left brace 32 is joined to the rear flange 57 of the second body portion 52A, and the front portion of the outer flange 32b is connected to the second body portion 52A. 2 to the rear flange 59 of the left extension 52C. A front flange 32d is provided at the front end of the lower surface 32a of the second left brace 32, and the front flange 32d is joined to the rear portion of the lower surface 52a of the second body portion 52A. Furthermore, a flange (not shown) is provided at the front end of each of the outer flange 32b and the inner flange 32c, and the flange is joined to the rear wall of the second body portion 52A.

In this embodiment, the first left brace 22 and the first right brace 21 are arranged between the second right brace 31 and the second left brace 32 . In this example, the first braces 21 and 22 and the second braces 31 and 32 are arranged line-symmetrically with respect to the center of the vehicle body in the vehicle width direction. Furthermore, the vehicle width direction spacing between the first right brace 21 and the first left brace 22 is half the vehicle width direction spacing between the second right brace 31 and the second left brace 32 . It is set to be smaller than the length.

Although the rear floor panel 1 of this embodiment has an inclined surface, it does not have an uneven shape in the vertical direction of the vehicle like a spare tire housing. Therefore, the first braces 21, 22 and the second braces 31, 32 are configured linearly. As a result, the rear end panel 70, the first rear cross member 51, the first right brace 21, and the first left brace 22 form a lattice structure (frame shape) in a plan view. The rear cross member 51, the second rear cross member 52, the second right brace 31, and the second left brace 32 can constitute another lattice structure (frame shape) in plan view. Become.

By constructing the lattice structure in this manner, the drum-like vibration of the rear floor panel 1 can be suppressed. In addition, the distance between the first right brace 21 and the first left brace 22 in the vehicle width direction is the same as the distance between the second right brace 31 and the second left brace 32 in the vehicle width direction. Therefore, the vibration transmitted to the rear floor panel 1 does not react excessively to a single vibration mode, and the resonance can be dispersed. It can be improved.

Furthermore, in the event of a rear-end collision, the load transmitted from the rear bumper to the rear end panel 70 is transmitted to the right rear side member 11 and the left rear side member 12. 1 is also transmitted to the left brace 22 . The load transmitted to the first right brace 21 and the first left brace 22 is transferred via the first rear cross member 51 to the second right brace 31 and the second left brace having a large gap in the vehicle width direction. 32 and further to the second rear cross member 52 . For this reason, the load is spread over the entire cavity value, local stress concentration in the rear side members 11 and 12 is reduced, and the rear side members 11 and 12 are less likely to break, etc. It is possible to reduce the occurrence.

In addition, as shown in FIG. 3, the first right brace 21 and the first left brace 22 of the present embodiment have a substantially triangular shape when viewed in the vehicle width direction. A lower front portion of the left brace 22 is joined to the lower surface 51 a of the first rear cross member 51 . That is, in the present embodiment, the upper portions of the first right brace 21 and the first left brace 22 are inclined upward toward the front of the vehicle and become higher.

As a result, the front ends of the first right brace 21 and the first left brace 22 reduce the deformation of the first rear cross member 51, especially the load from the front-rear direction of the vehicle, which causes the front ends to collapse, thereby ensuring the rigidity of the vehicle body. , the vibration of the rear floor panel 1 can be reduced.

Furthermore, the positions of the joints between the first right brace 21 and the first left brace 22 and the first rear cross member 51 in the vehicle vertical direction are set to the second right brace 31 and the second left brace 32, It is possible to arrange them so as to be aligned with the position of the joint with the first rear cross member 51 in the vertical direction of the vehicle. As a result, the flow of load is not blocked, local stress is reduced, and installation of rear side brackets 65 and 66, which will be described later, is facilitated.

Next, the third brace 41 will be explained. The third brace 41 is a member that extends in the vehicle front-rear direction, has a hat-shaped cross section when viewed in the vehicle front-rear direction, and has a right flange 41b and a left flange 41c on both sides in the vehicle width direction. The right flange 41b and the left flange 41c are joined to the lower surface of the rear floor panel 1, and like the second braces 31 and 32, the front flange of the second rear cross member 52 and the rear flange of the third rear cross member. It is joined to the flange.

The front end of the lower surface 41a of the third brace 41 is provided with a front flange 41d formed by extending from the front end toward the vehicle front side, and the rear end is provided with a rear flange 41e similarly to the front end. ing. The rear flange 41 e is joined to the lower surface 52 a of the second body portion 52 A, and the front flange 41 d is joined to the lower surface 53 a of the third rear cross member 53 . The third brace 41 has a rear portion provided with a flange that is joined to the front wall of the second main body portion 52A, and a front portion that is provided with a flange joined to the front wall of the third rear cross member 53. is provided.

Next, the arrangement of the rear differential gearbox 95 and the like will be described. As shown in FIG. 4, the rear differential gearbox 95 is arranged between the right rear side member 11 and the left rear side member 12 in the vehicle width direction, and is arranged between the first rear cross member 51 and the first rear cross member 51 in the vehicle longitudinal direction. 2 rear cross member 52 . More specifically, the rear differential gearbox 95 is arranged between the second right brace 31 and the second left brace 32 in the vehicle width direction.

A drive shaft 97 is connected to the vehicle width direction outer portion of the rear differential gear box 95, and the drive shaft 97 is connected to the rear wheel axle via a right trailing arm 81 and a left trailing arm 82. ing. A propeller shaft 96 is connected to the front portion of the rear differential gearbox 95 .

The propeller shaft 96 is connected to a power unit (not shown) arranged in the front part of the vehicle body, and transmits power from the power unit to the rear differential gearbox 95 . The propeller shaft 96 extends in the vehicle front-rear direction and is arranged at the vehicle width direction intermediate portion on the lower surface side of the rear floor panel 1 .

The rear differential gearbox 95 is attached to the vehicle body via a front bracket 61, a right rear bracket (bracket) 65, and a left rear bracket (bracket) 66, as shown in FIG. The front bracket 61 is joined to a vehicle front-rear direction intermediate portion of the lower surface 41 a of the third brace 41 .

The right rear bracket 65 has, as shown in FIG. 2, two front joints 65a and 65b and one rear joint 65c. The two front joint portions 65a and 65b are arranged in the front portion of the right rear bracket 65 with a space therebetween in the vehicle width direction. The right rear bracket 65 is joined to the lower surface 51a of the first rear cross member 51 at two front joints 65a and 65b, and joined to the lower surface 21a of the first right brace 21 at a rear joint 65c. .

Like the right rear bracket 65, the left rear bracket 66 has two front joints and one rear joint. , and is joined to the lower surface 22a of the first left brace 22 at the rear joint portion 66c.

The brackets 61, 65, 66 of the rear differential gear box 95 are subjected to a driving rotational force from the propeller shaft 96 as well as to a pushing force and a pulling force in the longitudinal direction of the vehicle. Due to the inertial force due to the weight of the box 95, front and rear, left and right, and up and down loads act. These may not only cause deformation of the rear floor panel 1 and cause noise in the vehicle interior, but also induce deformation of the vehicle body frame.

In this embodiment, the right rear bracket 65 and the left rear bracket 66 are supported in a region where rigidity is ensured by the first rear cross member 51, the first braces 21, 22, and the second braces 31, 32. ing. At this time, as shown in FIG. 3, the lower surface 51a of the first rear cross member 51 and the front portion of the lower surface 21a of the first right brace 21 are set to have the same height, and the two front joint portions 65a, The load from the rear differential gearbox 95 can be received by joining at three points, 65b and one rear joint portion 65c. The same is true for the first left brace 22 .

Also, in this embodiment, the first rear cross member 51 is composed of three members: a first body portion 51A, a first right extension 51B, and a first left extension 51C. Also, as described above, the front portions of the first braces 21 and 22 are joined to the first main body portion 51A, and the rear portions of the second braces 31 and 32 are connected to at least one of the first extensions 51B and 51C. joined to the part.

By constructing the first rear cross member 51 with three members, it is possible to set the difference in rigidity by changing the thickness of the first main body portion 51A and the left and right extensions 51C and 51B. More freedom. For example, if the rigidity of the first main body portion 51A is made higher than that of the left and right extensions 51C and 51B, the deformation of the rear floor panel 1 is reduced by the first main body portion 51A, while the load in the event of a rear collision is reduced to the second degree. It becomes possible to distribute to the first and second braces 21, 22, 31, 32 and the first extensions 51B, 51C. Here, since the second braces 31, 32 are joined to the first extensions 51B, 51C, the load from the first braces 21, 22 at the time of rear-end collision is transferred to the first extensions 51B, 51C. Since the load is transmitted to the rear side members 11, 12 and the second braces 31, 32 via the rear side members 11, 12, it is possible to suppress uneven transmission of the load to the second braces 31, 32, thereby reducing deformation of the rear floor panel 1. can.

A center floor panel 2 is arranged on the vehicle front side of the rear floor panel 1 and on the front side of the third rear cross member 53 . A floor tunnel 3 is provided at an intermediate portion of the center floor panel 2 in the vehicle width direction, the floor tunnel 3 being open downward and extending in the vehicle front-rear direction. The third brace 41 overlaps the floor tunnel 3 when viewed from the front of the vehicle.

As described above, by providing the third brace 41, the tilting of the second rear cross member 52 in the forward direction of the vehicle is reduced, and the torsional rigidity of the vehicle body and the vibration of the floor are reduced. Also, the lattice structure composed of the first rear cross member 51, the second rear cross member 52, and the second braces 31, 32 is replaced by the first braces 21, 22 positioned in front and behind the lattice structure. and the third brace 41, the vibration suppressing effect is ensured.

Furthermore, in the flow of load transmission at the time of a rear collision, the load acting on the second rear cross member 52 passes not only through the lisa side members 11 and 12 but also through the third brace 41, and passes through the third rear cross member 53. , the center floor panel 2 joined to the third rear cross member 53, and the like. Here, the third brace 41 is joined to the third rear cross member 53 and overlaps the rear end (rear portion) of the floor tunnel 3 responsible for the basic rigidity of the floor when viewed from the front of the vehicle. , are interlocked with the floor rigidity, and the above effect can be secured.

In addition, the rear floor panel 1 of this embodiment has an inclined portion, and the upper portions of the first braces 21 and 22 and the upper portions of the second braces 31 and 32 extend along the inclination of the rear floor panel 1. ing. That is, the first braces 21, 22 and the second braces 31, 32 have a substantially triangular shape when viewed in the vehicle width direction (Fig. 3), and rigid members can be arranged without protruding downward from the bottom of the vehicle body. can.

The description of the present embodiment is an example for describing the present invention, and does not limit the invention described in the claims. Moreover, the configuration of each part of the present invention is not limited to the above-described embodiment, and various modifications are possible within the technical scope described in the claims.

For example, the first rear cross member 51 is composed of three members, that is, the first main body portion 51A, the first right extension 51B and the first left extension 51C, but the configuration is not limited to this. It may be composed of one member. The same applies to the second rear cross member 52 as well.

1 rear floor panel 2 center floor panel 3 floor tunnel 11 right rear side member 11d spring receiving portion 12 left rear side member 12d spring receiving portion 21 first right brace 21a lower surface 21b outer flange 21c inner flange 21d front flange (flange)
22 First left brace 22a Lower surface 22b Outer flange 22c Inner flange 22d Front flange (flange)
31 Second Right Brace (Brace)
31a Lower surface 31b Outer flange 31c Inner flange 31d Front flange 32 Second left brace (brace)
32a lower surface 32b outer flange 32c inner flange 32d front flange 41 third brace (differential brace)
41a Lower surface 41b Right flange 41c Left flange 41d Front flange 41e Rear flange 51 First rear cross member 51A First main body (body)
51a lower surface 51B first right extension (side member)
51C First left extension (side member)
52 Second rear cross member (rear differential cross member)
52A Second main body portion 52a Lower surface 52B Second right extension 52C Second left extension 53 Third rear cross member 53a Lower surface 54 First main body front flange 55 First right extension front flange 56 First first left extension front flange 57 second body rear flange 58 second right extension rear flange 59 second left extension rear flange 61 front bracket 65 right rear bracket (bracket)
65a Front joint 65b Front joint 65c Rear joint 66 Left rear bracket (bracket)
70 Rear end panel 71 Right rear wheel house panel 72 Left rear wheel house panel 81 Right trailing arm 81d Spring installation part 82 Left trailing arm 82d Spring installation part 95 Rear differential gear box 96 Propeller shaft 97 Drive shaft

Claims (8)

a differential brace supporting the differential gearbox;
a rear differential cross member extending in the vehicle width direction, joined to the rear portion of the differential brace, and joined to the rear floor panel;
a pair of braces extending rearward from the differential cross member, arranged on both sides of the differential brace in the vehicle width direction, and joined to the rear floor panel;
A rear body structure, characterized by comprising: a front differential cross member extending in the vehicle width direction, joined to a front portion of the differential brace, and joined to the rear floor panel;
rear side members arranged on both sides in the vehicle width direction of the lower surface side of the rear floor panel and extending in the vehicle front-rear direction;
has
2. The vehicle body rear portion structure according to claim 1, wherein vehicle width direction side portions of the front differential cross member and the rear differential cross member are joined to the rear side member. a rear cross member extending in the vehicle width direction, joined to rear portions of the pair of braces, and joined to the rear floor panel;
rear side members arranged on both sides in the vehicle width direction of the lower surface side of the rear floor panel and extending in the vehicle front-rear direction;
has
2. The vehicle body rear structure according to claim 1, wherein vehicle width direction outer portions of said rear differential cross member and said rear cross member are joined to said rear side member. 4. The vehicle body rear portion structure according to claim 3, wherein said differential gearbox is supported in the vehicle width direction by said rear cross member positioned between said pair of said braces. a rear cross member extending in the vehicle width direction, joined to rear portions of the pair of braces, and joined to the rear floor panel;
The rear cross member has a main body portion and side members arranged on outer sides of the main body portion in the vehicle width direction,
The rigidity of the main body is set higher than the rigidity of the side members on both sides,
5. The vehicle body rear portion structure according to claim 1, wherein a front portion of the brace is joined to each of the side members on both sides. The rear floor panel has a portion that slopes downward toward the rear of the vehicle,
6. The vehicle body rear portion structure according to claim 5, wherein the body portion is joined to the portion. A floor tunnel is provided on the vehicle front side of the rear floor panel,
The rear vehicle body structure according to any one of claims 1 to 6, wherein the differential brace overlaps the floor tunnel when viewed from the front of the vehicle. a front differential cross member extending in the vehicle width direction, joined to a front portion of the differential brace, and joined to the rear floor panel;
The rear vehicle body structure according to any one of claims 1 to 7, wherein the differential brace overlaps the rear portion of the floor tunnel when viewed from the front of the vehicle.

Images