JP7031541B2 - Rear body structure - Google Patents

Description

The present invention relates to a rear body structure of a vehicle.

Patent Document 1 discloses a rear vehicle body structure in which a damper support portion for supporting a damper provided in a rear suspension is provided adjacent to the inside of a rear wheel house in the vehicle width direction. In the structure of Patent Document 1, a reinforcement extending upward from the upper part of the rear wheel house and forming a closed cross section with the rear pillar is further provided.

Jikkai Sho 64-1063 Gazette

In recent years, it has become more important to improve the sense of unity (also referred to as direct feeling) of the occupant with respect to the movement of the vehicle body. Therefore, in the rear part of the vehicle body, it is desirable that the movement of the rear suspension, that is, the load input from the damper to the damper support portion is efficiently transmitted to the rear part of the vehicle body.

However, the structure of Patent Document 1 only increases the rigidity of the vehicle body in the peripheral portion of the rear pillar due to the reinforcement, and does not increase the rigidity in the peripheral portion of the damper support portion. As a result, in the structure of Patent Document 1, it is difficult to efficiently transmit the load input from the damper to the rear portion of the vehicle body via the damper support portion, and it is difficult to improve the sense of unity of the occupant with respect to the movement of the vehicle body.

An object of the present invention is to provide a rear vehicle body structure capable of improving the sense of unity of an occupant with respect to the movement of the vehicle body by efficiently transmitting the load input to the damper support portion to the rear portion of the vehicle body.

In order to solve the above problems, the present invention is characterized in that it is configured as follows.

The invention according to claim 1 of the present application is a rear body structure.
A frame member extending in the front-rear direction at the rear of the vehicle body,
A rear wheel house provided adjacent to the outside of the frame member in the vehicle width direction, and
A damper support that is provided over both the frame member and the rear wheel house or one of them and to which a damper provided for the rear suspension is attached.
A reinforcing member that reinforces the damper support portion and
It is provided at a position overlapping the damper support portion in the front-rear direction when viewed from the side of the vehicle, and is provided with a damper side side reins extending in the vertical direction along the vehicle interior side of the rear wheel house.
The reinforcing member has a rain-shaped portion that protrudes upward and is connected to the lower end portion of the damper side side reins.
The rain shape portion is formed so that the cross-sectional shape orthogonal to the extending direction is continuous with the cross-sectional shape of the damper side side reins .
The frame members are provided in pairs on both sides of the rear vehicle body in the vehicle width direction.
The rear floor extending inward in the vehicle width direction from the inner end portion of the frame member in the vehicle width direction,
A cross member provided on the upper surface of the rear floor and connecting the pair of left and right frame members in the vehicle width direction in front of the damper support portion.
With a front side reins that is provided along the vehicle interior side of the rear wheel house and extends in the vertical direction in front of the damper support portion.
Further prepare
The reinforcing member is further provided with a reinforcing member connecting portion for connecting the cross member and the front side reins .

Further, the invention according to claim 2 is the invention according to claim 1.
The damper support portion is provided with a suspension fastening portion to which the damper is fixed by fastening.
The rain-shaped portion is characterized in that it is positioned so as to overlap at least partially in the front-rear direction with respect to the suspension fastening portion when viewed from the side of the vehicle.

Further, the invention according to claim 3 is the invention according to claim 2.
The reinforcing member is characterized in that an outer vertical rib is formed so as to connect the rain-shaped portion and the suspension fastening portion in the vertical direction in a bracing manner.

With the above configuration, according to the invention of each claim of the present application, the following effects can be obtained.

First, according to the invention of claim 1, both the rain shape portion and the damper side side reins extend in the vertical direction, and since these cross-sectional shapes are configured to be continuous, the upper and lower sides of the damper support portion are formed. Improves rigidity in the direction. As a result, among the loads input from the damper to the damper support portion, the load in the vertical direction is transmitted to the damper side side reins via the rain-shaped portion, and is suitably supported by these. As a result, the load input to the damper support portion is efficiently transmitted to the rear portion of the vehicle body, so that it is easy to improve the sense of unity of the occupant with respect to the movement of the vehicle body.
Further, the cross member and the front side reins can be connected by using the reinforcing member for reinforcing the damper support portion, and the connecting portion between the frame member and the cross member can also be reinforced. That is, the rigidity of the skeleton portion of the rear vehicle body including the cross member, the front side reins, and the frame member can be improved via the reinforcing member. Further, among the loads input from the damper to the damper support portion, particularly the load in the front-rear direction is transmitted to the skeleton portion of the rear vehicle body via the reinforcing member.
Therefore, as for the load input from the damper to the damper support portion, the load in the vertical direction is suitably supported by the rain-shaped portion and the side reins on the damper side, and the load in the front-rear direction is supported by the reinforcing member connecting portion, the cross member and the front side reins. It is preferably supported. Therefore, according to the rear vehicle body structure according to this configuration, the load input from the damper is more preferably supported, so that it is easier to further improve the sense of unity of the occupant with respect to the movement of the vehicle body.

Further, according to the second aspect of the present invention, it is easy to make the rain-shaped portion function more effectively to support the load input from the damper to the suspension fastening portion.

Further, according to the third aspect of the present invention, the rigidity in the vertical direction between the suspension fastening portion and the rain-shaped portion can be improved by the outer vertical rib. As a result, the vertical load input from the damper to the suspension fastening portion is efficiently transmitted by the rain-shaped portion, so that the rain-shaped portion and the side reins on the damper side can be more effectively applied to the load. Easy to function to support.

According to the present invention, it is possible to improve the sense of unity of the occupant with respect to the movement of the vehicle body by efficiently transmitting the load input to the damper support portion to the rear portion of the vehicle body.

The perspective view which shows the rear body structure which concerns on one Embodiment of this invention. Top view of the rear body structure shown in FIG. 1. FIG. 2 is a cross-sectional view taken along the line III-III of FIG. The bottom view of the rear body structure shown in FIG. A perspective view of a main part of the rear vehicle body structure shown in FIG. 1 as viewed from the outside and below in the vehicle width direction. Front view of the rear body structure of FIG. 1. The perspective view which shows the state which attached the rear seat to the rear body structure of FIG. FIG. 2 is a cross-sectional view taken along the line VIII-VIII of FIG. FIG. 2 is a cross-sectional view taken along the line IX-IX in FIG. FIG. 2 is a cross-sectional view taken along the line XX of FIG. A perspective view showing the periphery of the reinforcing member in an exploded manner. Perspective view of the reinforcing member. Top view of the reinforcing member shown in FIG. The bottom view of the reinforcing member shown in FIG. FIG. 12 is a cross-sectional view taken along the line XV-XI of FIG. FIG. 2 is an enlarged perspective view showing the periphery of the rear side reins adapter according to the arrow A in FIG.

Hereinafter, embodiments according to the present invention will be described with reference to the accompanying drawings. It should be noted that the following description is merely an example and is not intended to limit the present invention, its application, or its use. In addition, the drawings are schematic, and the ratio of each distance is different from the actual one.

(Overall configuration of rear body structure)
Hereinafter, the overall configuration of the rear vehicle body structure V according to the embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, in front of the rear vehicle body structure V, a floor panel 1 forming the floor surface of the passenger compartment and a pair of left and right side sills 2 joined to both sides in the vehicle width direction and extending in the front-rear direction. , Are provided. The side sill 2 has a side sill inner 2a located inside in the vehicle width direction and a side sill outer 2b (see FIG. 7) located outside in the vehicle width direction, which are joined in the vehicle width direction and extend in the front-rear direction. The cross-sectional shape orthogonal to the front-rear direction is configured as a rectangular closed cross section.

With reference to FIG. 3, a rear floor panel 4 extending rearward via a kick-up portion 3 rising upward is integrally connected to the rear portion of the floor panel 1. A pair of left and right rear side frames 6 (hereinafter referred to as "frame members") extending in the front-rear direction are provided on both sides of the rear floor panel 4 in the vehicle width direction.

As will be described later, the frame member 6 is provided with a damper support portion 65 to which the damper 92 (see FIGS. 8 to 10) of the rear suspension 91 is attached from below. A reinforcing member 20 for reinforcing the damper support portion 65 is attached to the frame member 6.

The rear floor panel 4 has a rear floor front portion 4F located on the front side and a rear floor rear portion 4R located one step higher on the rear side via the step-up portion 4S. A fuel tank (not shown) is attached to the lower part of the front 4F of the rear floor, and a rear seat 90 (see FIG. 7) is attached to the upper part. The rear 4R of the rear floor mainly forms the floor surface of the luggage compartment, and is recessed downward in the middle portion in the vehicle width direction to serve as a spare tire pan for storing spare tires or a recess for storing other parts. 4a is integrally formed.

The frame member 6 extends in the front-rear direction from the kick-up portion 3 to the rear end of the rear floor panel 4, has a cross-sectional shape orthogonal to the front-rear direction formed in a rectangular closed cross section, and has a front end at the rear portion of the side sill 2. It is connected.

As shown in FIG. 2, a rear foil house 7 (hereinafter referred to as “foil house”) is adjacently provided on the outside of the frame member 6 in the vehicle width direction. With reference to FIG. 3, a rear side panel 8 (hereinafter referred to as a “side panel”) extending upward and forming a side surface portion of the rear portion of the passenger compartment is provided on the upper portion of the foil house 7.

The foil house 7 has a foil house inner 7a that bulges inward in the vehicle width direction and a foil house outer 7b (see FIG. 2) that bulges outward in the vehicle width direction with respect to the side panel 8. It is configured to be joined together with the side panel 8 in the vehicle width direction at the upper end portion. The lower end of the foil house inner 7a is joined to the frame member 6 from the outside in the vehicle width direction.

As shown in FIG. 3, the side panel 8 is formed with a panel opening 8a to which a quarter window (not shown) is attached. As shown in FIGS. 6 and 7, a rear pillar outer 9a is joined to the front side portion of the panel opening 8a of the side panel 8 from the outside in the vehicle width direction. The rear pillar outer 9a has a cross-sectional shape in the horizontal direction formed in a hat-shaped cross section that opens inward in the vehicle width direction, extends upward from the upper part of the wheel house outer 7b, and has a closed cross section extending in the vertical direction together with the side panel 8. It constitutes the rear pillar 9.

As shown in FIG. 7, on both sides of the upper part of the vehicle body, a pair of left and right roof side rails 10 extending in the front-rear direction, and a pair of left and right roof side rails 10 connected to the rear portion and extending in a downwardly inclined direction toward the rear of the vehicle. A D-pillar 11 leading to the end is provided. Each of the roof side rail 10 and the D pillar 11 has a rectangular closed cross section having a cross-sectional shape perpendicular to the extending direction.

Inside the pair of left and right roof side rails 10 in the vehicle width direction, a roof cross member 12 for connecting them in the vehicle width direction is provided. The roof cross member 12 has a closed cross section having a rectangular cross section perpendicular to the vehicle width direction.

The upper end of the rear pillar 9 is connected to the roof side rail 10. The roof cross member 12 is provided corresponding to a position where the rear pillar 9 is connected in the front-rear direction on the inner side surface of the roof side rail 10 in the vehicle width direction.

As shown in FIG. 3, a pair of front and rear front side reins 13 and rear side reins 14 (also referred to as damper side side reins) are provided on the inner side surfaces of the foil house inner 7a and the side panel 8 in the vehicle width direction. There is. The front side reins 13 are provided corresponding to the first half of the foil house inner 7a, and the rear side reins 14 are provided corresponding to the latter half of the foil house inner 7a, more specifically. Is provided at the same position as the damper support portion 65 in the front-rear direction of the vehicle.

The front side reins 13 extends upward from a substantially intermediate position in the vertical direction of the wheel house inner 7a, and the upper end thereof faces the lower half of the rear pillar 9 from the inside in the vehicle width direction. It extends to overlapping positions in the vertical direction. The rear side reins 14 extends upward from a substantially intermediate position in the vertical direction of the foil house inner 7a on the rear side of the panel opening 8a, and the upper end thereof is connected to the D pillar 11.

The front side reins 13 and the rear side reins 14 have a cross-sectional shape in the horizontal direction formed in a hat-shaped cross section that opens outward in the vehicle width direction, and have a rectangular shape extending in the vertical direction together with the wheel house inner 7a and the side panel 8. Consists of a closed cross section.

The step-up portion 4S of the rear floor panel 4 is provided with a pair of upper and lower rear cross member uppers 15 and a rear cross member lower 16 that cover the step-up portion 4S from both upper and lower sides. With reference to FIGS. 1 and 4, the pair of upper and lower rear cross member uppers 15 and the rear cross member lower 16 extend in the vehicle width direction, respectively, and the pair of left and right frame members 6 are connected in the vehicle width direction. ing.

The rear cross member upper 15 is formed in a hat-shaped cross section having a cross-sectional shape perpendicular to the vehicle width direction and opened downward, and constitutes a closed cross section extending in the vehicle width direction together with the rear floor panel 4. The rear cross member lower 16 is formed in a hat-shaped cross section having a cross-sectional shape perpendicular to the vehicle width direction and opened upward, and constitutes a rectangular closed cross section extending in the vehicle width direction together with the rear floor panel 4.

The closed cross section formed by the rear cross member upper 15 and the closed cross section formed by the rear cross member lower 16 at least partially overlap each other in a top view.

Further, a spare tire pan cloth member 17 is provided on the rear floor rear portion 4R along the lower surface of the recess 4a. With reference to FIG. 4, the spare tire pan cloth member 17 connects a pair of left and right frame members 6 in the vehicle width direction. The spare tire pan cross member 17 is formed in a hat-shaped cross section having a cross-sectional shape perpendicular to the vehicle width direction and opened upward, and constitutes a rectangular closed cross section extending in the vehicle width direction together with the rear floor rear portion 4R (recess 4a). is doing.

Hereinafter, the peripheral structure of the frame member 6 will be described in detail. Since the rear vehicle body structure V is symmetrical, the following description will be made mainly based on the configuration on the right side of the vehicle.

(Frame member)
As shown in FIGS. 2 to 4, the frame member 6 has a pair of upper and lower frame upper wall portions 61 and frame lower wall portions 62 extending in the front-rear direction, and vehicle widths of the frame upper wall portion 61 and the frame lower wall portion 62. It has a pair of frame inner wall portions 63 and a frame outer wall portion 64 in the vehicle width direction connecting the inner end portion and the outer end portion in the vertical direction, respectively.

As shown in FIG. 4, a recessed portion 65 having a substantially central portion in the vehicle width direction recessed upward is formed in an intermediate portion in the front-rear direction of the frame lower wall portion 62, specifically, at a substantially intermediate position. There is. A damper 92 (see FIGS. 8 to 10) provided in the rear suspension 91 is inserted into the recess 65 from below and is supported in the vertical direction, and is configured as a damper support portion.

The damper support portion 65 is formed in an elliptical shape that is long in the front-rear direction when viewed from the bottom surface, and a damper insertion hole 65b that penetrates in the vertical direction is formed in the central portion of the top surface 65a. Bolt insertion holes 65c and 65d penetrating in the vertical direction are formed. The frame member 6 is formed with a wide portion 6W that is wider outside in the vehicle width direction than other portions at the position P (position corresponding to the recess) where the damper support portion 65 is formed.

FIG. 8 is a cross-sectional view taken along the line VIII-VIII of FIG. 2, specifically, a cross section of the damper support portion 65 passing through the center of the damper insertion hole 65b and the pair of front and rear bolt insertion holes 65c and 65d in the front-rear direction. In the figure, the damper 92 attached here is also shown. As shown in FIG. 8, in the damper support portion 65, the frame lower wall portion 62 is recessed upward so as to abut from below on the frame upper wall portion 61.

9 is a cross-sectional view taken along the line IX-IX of FIG. 2, FIG. 10 is a cross-sectional view taken along the line XX of FIG. 2, and specifically, each is a bolt insertion hole of the damper support portion 65. It is sectional drawing in the vehicle width direction in 65c, 65d, and the damper 92 attached here is also shown. As shown in FIGS. 9 and 10, by forming the damper support portion 65 on the frame member 6, the frame member 6 is bifurcated on both sides in the vehicle width direction sandwiching the damper support portion 65.

Therefore, as shown in FIG. 4, the load path of the rear collision load that passes through the recess corresponding position P of the frame member 6 and is transmitted to the front of the vehicle at the time of the rear collision is bifurcated at the recess equivalent position P. Two load paths L1 and L2 will be configured.

Further, in the rear vehicle body structure V of the present embodiment, as described above, the frame member 6 is provided with a recessed portion 65 in order to give the frame member 6 a damper support function. Along with this, in the frame members 6 on both sides of the rear part of the vehicle body, the frame member 6, the damper support portion, and the foil house inner are separately arranged from the inside to the outside in the vehicle width direction as in the conventional case. Then, as a whole (that is, the portion extending in the front-rear direction of the vehicle), the portion is arranged at a position offset inward in the vehicle width direction.

That is, in the present embodiment, the frame member 6 has a position in which the axis 6x (see FIG. 2) along the longitudinal direction (vehicle front-rear direction) is closer to the inside in the vehicle width direction as compared with the conventional configuration described above. Due to this, the amount of offset inward in the vehicle width direction with respect to the side sill 2 is also larger than that of the conventional configuration.

The frame member 6 extends substantially parallel to the vehicle front-rear direction except for the front portion in the vehicle front-rear direction, whereas the front portion of the frame member 6 is oblique so as to be located outward in the vehicle width direction toward the front. The inclined portion 6F is formed, and the front end of the inclined portion 6F (that is, the front end of the frame member 6) is joined to the rear portion of the side sill 2.

As described above, by forming the inclined portion 6F on the front portion of the frame member 6 and connecting the front end to the side sill 2, the frame is provided with the recessed portion 65 as described above. Even in the configuration as in this embodiment in which the member 6 is arranged at a position offset inward in the vehicle width direction with respect to the side sill 2, the front end of the frame member 6 can be smoothly connected to the rear portion of the side sill 2. At the time of rear collision, the rear collision load can be efficiently transmitted from the frame member 6 to the side sill 2.

The frame lower wall portion 62 is provided with a front suspension component mounting portion 66 on the front side and a rear suspension component mounting portion 67 on the rear side with respect to the damper support portion 65. The front suspension component mounting portion 66 and the rear suspension component mounting portion 67 are bolts capable of mounting and supporting rear suspension parts such as a suspension cross member and a trailing arm (not shown) via suspension mounting bolts (not shown). It has insertion holes 66a and 67a, respectively, and is formed so as to protrude downward in a pedestal shape, respectively.

The rear cross members 15 and 16 are joined from the inside in the vehicle width direction at a position corresponding to the front suspension component mounting portion 66 in the vehicle front-rear direction among the pair of left and right frame members 6. The spare tire pan cross member 17 is joined from the inside in the vehicle width direction to a position corresponding to the rear suspension component mounting portion 67 in the front-rear direction among the pair of left and right frame members 6.

In the present embodiment, the inclined portion 6F extends from the position between the recess equivalent position P and the front suspension component mounting portion 66 (in other words, the front end position of the wide portion 6W) to the front end of the frame member 6 in the vehicle front-rear direction. Corresponds to the part.

The front portion of the inclined portion 6F overlaps the rear portion of the side sill inner 2a, that is, from the rear end of the side sill inner 2a to the rear front of the kick-up portion 3 in the vehicle front-rear direction. In this overlapping portion, the front portion of the inclined portion 6F is joined to the rear portion of the side sill inner 2a from the inside in the vehicle width direction.

The wide portion 6W formed on the frame member 6 is formed by widening outward in the vehicle width direction. As a result, the frame member 6 has a shaft core 6x (FIG. 6) toward the outside in the vehicle width direction (the side of the side sill 2 in the vehicle width direction) at the recess equivalent position P (wide portion 6W) as compared with the case where the wide portion 6W is not formed. 2) can be brought together, and the harmful effects of providing the recessed portion 65 in the frame member 6 can be corrected.

Specifically, by providing the recessed portion 65 in the frame member 6, the amount of offset of the frame member 6 inward in the vehicle width direction with respect to the side sill 2 becomes large, so that the side sill from the frame member 6 at the time of rear collision. Smooth transmission of the rear collision load to 2 is hindered, and the amount of overlap between the front portion of the frame member 6 and the rear portion of the side sill 2 in the vehicle front-rear direction becomes large, that is, the frame member and the side sill member are viewed in a plan view. It is possible to suppress the harmful effect that there is a possibility of being deformed into a Z shape.

The wide portion 6W has a frame member 6 so that the recess corresponding position P is widest outward in the vehicle width direction from a position rearward to the rear suspension component mounting portion 67 to a position closest to the rear side of the front suspension component mounting portion 66. , The frame outer wall portion 64 is formed by gently bulging outward in the vehicle width direction.

On the other hand, the frame inner wall portion 63 does not bulge inward in the vehicle width direction including the wide portion 6W, that is, the recess corresponding position P in the vehicle front-rear direction, and is from the rear end of the frame member 6 to the rear end of the inclined portion 6F. It is formed in a substantially straight line along the front-rear direction of the vehicle.

That is, the wide portion 6W is formed by inflating only the frame outer wall portion 64 of the frame member 6 so as to protrude toward the foil house inner 7a centering on the recess corresponding position P in the vehicle front-rear direction. .. The center of the recess 65 is provided at the center of the wide portion 6W in the vehicle width direction when viewed from the bottom.

As shown in FIGS. 4 and 5, the frame lower wall portion 62 is formed so that the front portion of the frame lower wall portion 62 is stepped lower toward the outside in the vehicle width direction than the rear suspension component mounting portion 67. Specifically, the frame lower wall portion 62 is located inside the recessed portion 65 in the vehicle width direction, and the lower wall portion inside portion 62A forming a part of the road path L1 and the recessed portion 65 are outside in the vehicle width direction. It has a lower wall portion outer portion 62B that detours from and extends forward and constitutes a part of the load path L2, and the lower wall portion outer portion 62B is above the lower wall portion inner portion 62A. positioned.

The lower wall portion inner portion 62A and the lower wall portion outer portion 62B are vertically connected to each other by the lower wall portion vertical wall portion 62C on the front side of the recess portion 65. The lower wall portion inner portion 62A extends forward while widening the inside of the recess portion 65 in the vehicle width direction outward in the vehicle width direction, and is formed so as to be continuous with the lower surface of the inclined portion 6F. The lower wall portion vertical wall portion 62C is continuous with the frame outer wall portion 64 at the rear portion of the inclined portion 6F. On the other hand, the lower wall portion outer side portion 62B is curved so as to bypass the recessed portion 65 from the outside in the vehicle width direction and extends forward, and at a substantially intermediate position in the front-rear direction of the inclined portion 6F, the vehicle width direction is provided with respect to the frame outer wall portion 64. It is connected from the outside.

As a result, as shown in FIG. 4, the collision load due to the rear collision is transmitted forward so as to bypass the recess 65 to the outside in the vehicle width direction in the road path L2 passing outside in the vehicle width direction. In the road path L1 passing inside in the vehicle width direction, the load path L1 is linearly transmitted forward along the longitudinal direction (vehicle front-rear direction) of the frame member 6 without bypassing the recessed portion 65.

As described above, the lower wall portion inner portion 62A constituting a part of the load path L1 is one step higher than the lower wall portion outer portion 62B forming a part of the load path L2, so that the load path L1 is the load path L2. Due to the synergistic effect of the load path L1 extending linearly in addition to the fact that the cross section is larger than that of the load path L1, the collision load due to the rear collision is more efficiently side-silled through the load path L1. It is designed to be transmitted to 2.

Further, of the frame member 6, the lower wall portion inner portion 62A forming a part of the load path L1 is curved outward in the vehicle width direction toward the inclined portion 6F, but the curved portion is curved from the outside in the vehicle width direction. The jointed lower wall portion outer portion 62B enhances the bending rigidity of the frame member 6 in the curved portion in the vehicle width direction.

As shown in FIGS. 8 to 10, in the present embodiment, the frame member 6 includes a frame upper 71 constituting the upper half of the frame upper wall portion 61 and the frame inner wall portion 63, the frame lower wall portion 62, and the frame. It has a frame lower 72 that constitutes the lower half of the inner wall portion 63 and the frame outer wall portion 64, a frame outer 73 that constitutes the frame outer wall portion 64, and a frame intermediate member 74 that constitutes the recessed portion 65.

The frame upper 71, the frame lower 72, the frame outer 73, and the frame intermediate member 74 are each integrally formed by press-molding a steel plate, or are formed by joining a plurality of members as appropriate.

The frame upper 71 has an upper surface portion 71a extending substantially horizontally in the front-rear direction, an inner surface inclined portion 71b extending downward from the inner end portion in the vehicle width direction inward in the vehicle width direction, and an upper surface portion 71a. It has an outer flange 71c extending upward from the outer end portion in the vehicle width direction. An inner flange 71d extending inward in the vehicle width direction extends to the lower end of the inner surface inclined portion 71b.

As shown in FIGS. 9 and 10, the damper 92 is attached in a posture slightly inclined outward in the vehicle width direction toward the lower side. Therefore, the flange 92a provided at the upper end of the damper 92 is slightly inclined downward toward the inside in the vehicle width direction. Therefore, as will be described later, the frame upper wall portion 61 (that is, the upper surface portion 71a of the frame upper 71) to which the damper 92 is attached via the flange 92a is also slightly inclined downward toward the inside in the vehicle width direction. ..

The frame lower 72 includes a lower surface portion 72a extending in a substantially horizontal direction, an inner surface portion 72b extending upward from the inner end portion in the vehicle width direction, and an outer surface portion 72c extending upward from the outer end portion in the vehicle width direction of the lower surface portion 72a. Have. The lower surface portion 72a is formed with an opening portion 72d that penetrates in the vertical direction at the position corresponding to the depression and is raised upward in a burring shape. An inner flange 72e extending inward in the vehicle width direction extends from the upper end of the inner surface portion 72b.

The frame outer 73 has an outer surface portion 73a extending in a substantially vertical direction in the front-rear direction, an outer surface inclined portion 73b extending in a direction inclined inward in the vehicle width direction from the upper end portion upward, and an outer surface extending upward from the upper end portion. It has a flange 73c.

The frame intermediate member 74 is formed in a cup shape with an opening at the bottom.

Explaining the joining of each member, the frame intermediate member 74 is inserted from below inside the opening 72d formed in the lower surface portion 72a of the frame lower 72, and the lower end portion of the frame intermediate member 74 stands in a burring shape. It is joined to the upper end of the raised opening 72d.

The frame upper 71 and the frame lower 72 are triple-joined with their inner flanges 71d and 72e sandwiching the outer end portion 4b of the rear floor panel 4 in the vehicle width direction at the top and bottom. In this state, the top wall portion of the frame intermediate member 74 joined to the frame lower 72 abuts on the upper surface portion 71a of the frame upper 71 from below.

Further, the frame outer 73 is joined to the upper end portion of the outer surface portion 72c of the frame lower 72 from the outside in the vehicle width direction at the lower end portion of the outer surface portion 73a. Further, the frame outer 73 and the frame upper 71 are triple-bonded with their outer flanges 73c and 71c sandwiching the lower end portion of the foil house inner 7a in the vehicle width direction.

Therefore, the frame upper wall portion 61 is mainly composed of the upper surface portion 71a of the frame upper 71. The frame lower wall portion 62 is mainly composed of a lower surface portion 72a of the frame lower 72 and a frame intermediate member 74. The frame inner wall portion 63 is mainly composed of an inner surface inclined portion 71b of the frame upper 71 and an inner surface portion 72b of the frame lower 72. The frame outer wall portion 64 is mainly composed of an outer surface portion 72c of the frame lower 72, an outer surface portion 73a of the frame outer 73, and an outer surface inclined portion 73b.

The damper insertion holes 65b and the bolt insertion holes 65c and 65d formed on the top surface 65a of the damper support portion 65 described above are formed by vertically penetrating the upper surface portion 71a of the frame upper 71 and the top wall portion of the frame intermediate member 74. Has been done.

(Reinforcing member)
As shown in FIG. 1, the reinforcing member 20 includes a reinforcing member main body portion 21 that reinforces the damper support portion 65 of the frame member 6, and a front side reins 13 and a rear cross member upper 15 in front of the damper support portion 65. It has a reinforcing member connecting portion 22 to be connected, and these are aluminum alloy members integrally formed by an aluminum die casting method.

With reference to FIG. 12, the reinforcing member main body portion 21 has a length corresponding to at least the damper support portion 65 in the vehicle front-rear direction, and the upper portion of the frame member 6 is substantially parallel to the length. A reinforcing member upper wall portion 23 extending horizontally in the front-rear direction, a reinforcing member inner wall portion 24 extending downward from the vehicle width direction inner end portion in a direction inclined inward in the vehicle width direction, and a reinforcing member upper wall portion 23. It integrally has an outer flange 25 extending upward from the outer end in the vehicle width direction.

With reference to FIGS. 8 to 10, the reinforcing member upper wall portion 23 extends in the front-rear direction substantially parallel to the frame upper wall portion 61 at a position separated upward, and is opposed to the frame upper wall portion. It has a width (length in the vehicle width direction) corresponding to the portion 61. That is, in the position of the reinforcing member upper wall portion 23 facing the wide portion 6W of the frame member 6, the inner edge portion in the vehicle width direction extends in the front-rear direction in the top view, while the outer edge portion in the vehicle width direction extends in the front-rear direction. It is formed so as to bulge outward in the vehicle width direction.

The reinforcing member upper wall portion 23 is formed with a rear flange 23a that is lowered by one step downward via the vertical wall portion 23g at the rear end portion. As shown in FIG. 8, the rear flange 23a is abutted and joined to the frame upper wall portion 61 from above.

Further, the damper insertion hole 23b communicating with the damper insertion hole 65b in the vertical direction penetrates the reinforcing member upper wall portion 23 at a position corresponding to the damper insertion hole 65b formed in the frame member 6 in this plan view. It is formed.

Furthermore, the upper wall of the frame is recessed downward at positions corresponding to the bolt insertion holes 65c and 65d formed in the frame member 6 on both front and rear sides of the damper insertion holes 23b of the reinforcing member upper wall portion 23. A front damper mounting recess 23c and a rear damper mounting recess 23d are formed so as to abut on the portion 61 to form a fastening seat surface.

At the bottoms of the front damper mounting recess 23c and the rear damper mounting recess 23d, bolt insertion holes 23e and 23f for fastening dampers communicate with the bolt insertion holes 65c and 65d formed in the frame member 6 in the vertical direction, respectively. It is formed through as follows.

As shown in FIG. 8, in order to attach the damper 92 to the damper support portion 65, first, the damper 92 is inserted through the damper support portion 65 from below, and the flange 92a provided at the upper end portion of the damper 92 is provided. Is brought into contact with the top surface 65a of the damper support portion 65 from below.

Next, the fastening bolt 93 is inserted through a pair of front and rear mounting holes 92b formed through the flange 92a of the damper 92 in the vertical direction, and the bolt insertion holes 65c and 65d formed in the frame member 6 and the reinforcing member upper wall portion. The damper 92 supports the damper by inserting the bolt insertion holes 23e and 23f formed in the 23 in order from the bottom and fastening them from above at the bottoms of the front damper mounting recess 23c and the rear damper mounting recess 23d with the fastening nut 94. It is inserted and fixed (held) in the portion 65.

Therefore, a pair of front and rear suspension fastening portions for fastening and fixing the damper 92 to the damper support portion 65 are configured at the bottom of the front side damper mounting recess 23c and the rear side damper mounting recess 23d, and are reinforced at these suspension fastening points. The member 20 is fastened together at the reinforcing member upper wall portion 23. As a result, the reinforcing member upper wall portion 23 is attached to the frame upper wall portion 61.

As shown in FIGS. 9 and 10, the reinforcing member inner wall portion 24 abuts on the inner surface inclined portion 71b of the frame upper 71 of the frame inner wall portions 63 from the inside in the vehicle width direction, and the front and rear portions at the lower end portion thereof. It is joined at multiple points spaced in the direction.

As shown in FIGS. 8 and 9, the outer flange 25 is in contact with the outer flange 71c of the frame upper 71 from the inside in the vehicle width direction, and is joined at a plurality of locations spaced apart in the front-rear direction. There is. The outer flange 25 is formed with a plurality of openings 25a between the joints to the outer flanges 71c adjacent to each other in the front-rear direction. The opening 25a is formed in a circular shape, for example, and has a triple layer of the outer flange 71c of the frame upper 71, the lower end of the wheel house inner 7a, and the outer flange 73c of the frame outer 73, avoiding the reinforcing member 20. Used as an opening to access welding jigs and tools when joining.

As shown in FIG. 12, the reinforcing member main body 21 has a rain-shaped portion that protrudes further upward than the outer flange 25 at a position that overlaps the damper support portion 65 of the frame member 6 in the front-rear direction in the vehicle side view. 30 is integrally formed. More specifically, the rain-shaped portion 30 is positioned so as to overlap at least partially in the front-rear direction with respect to the suspension fastening portion when viewed from the side of the vehicle. With reference to FIGS. 1 and 3, the rain-shaped portion 30 is connected to the lower end portion of the rear side reins 14 via the first connecting member 31.

The rain-shaped portion 30 has a horizontal cross-sectional shape formed in a U-shaped cross section that opens outward in the vehicle width direction, and has a pair of front and rear front portions 30a and rear surface portions 30b, and these inner end portions in the vehicle width direction. It has an inner surface portion 30c connected in the front-rear direction. Further, the rain-shaped portion 30 has an outer front flange 30d extending forward from the outer end portion in the vehicle width direction of the front surface portion 30a, and an outer rear flange 30e extending rearward from the outer end portion in the vehicle width direction of the rear surface portion 30b. is doing. The outer front flange 30d and the outer rear flange 30e are continuous with the outer flange 25 of the reinforcing member main body 21 at the lower end.

As shown in FIG. 1, the reinforcing member connecting portion 22 includes a connecting portion upper portion 26 extending in the vertical direction, and a connecting portion inclined portion 27 extending downward from the lower end portion toward the inside in the vehicle width direction. It integrally has a connecting portion lower portion 28 extending inward in the vehicle width direction from the inner end portion in the vehicle width direction. The upper portion 26 of the connecting portion is connected to the lower end portion of the front side reins 13 via the second connecting member 32. The lower portion 28 of the connecting portion is connected to the outer end portion of the rear cross member upper 15 in the vehicle width direction via the third connecting member 33.

The connecting portion inclined portion 27 crosses the frame member 6 from above in the vehicle width direction. With reference to FIG. 6, the connecting portion inclined portion 27 preferably has an inclination angle of about 45 degrees with respect to the vertical direction so as to connect the connecting portion upper portion 26 and the connecting portion lower portion 28 in a bracing manner. It is extended.

As shown in FIG. 12, the reinforcing member connecting portion 22 is formed in a U-shaped cross section having a cross-sectional shape orthogonal to the extending direction and opened to the outside of the vehicle, and is formed with a pair of front and rear front portions 22a and a rear surface portion 22b. It has a vehicle interior surface portion 22c that connects these vehicle interior side ends in the front-rear direction.

Specifically, the upper portion 26 of the connecting portion has a cross-sectional shape in the horizontal direction formed in a U-shaped cross section that opens outward in the vehicle width direction, and is in contact with the foil house inner 7a from the inside in the vehicle width direction. Therefore, a closed cross section extending in the vertical direction is formed between the upper portion 26 of the connecting portion and the foil house inner 7a.

With reference to FIG. 8, the connecting portion inclined portion 27 is opened in a direction in which the cross-sectional shape orthogonal to the direction inclined downward toward the inside in the vehicle width direction is inclined downward toward the outside in the vehicle width direction. It is formed in a character-shaped cross section, and is in contact with the wheel house inner 7a from the inside in the vehicle width direction and is joined to the frame member 6 from above or from the inside in the vehicle width direction. Therefore, a closed cross section extending in a downwardly inclined direction toward the inside in the vehicle width direction is formed between the connecting portion inclined portion 27 and the foil house inner 7a and the frame member 6.

The lower portion 28 of the connecting portion is formed in a U-shaped cross section having a cross-sectional shape orthogonal to the vehicle width direction and is open downward, and is in contact with the rear floor panel 4 from above. Therefore, a closed cross section extending in the vehicle width direction is formed between the lower portion 28 of the connecting portion and the rear floor panel 4.

Therefore, as shown in FIGS. 6 and 7, in the rear vehicle body structure V, the rear cross member uppers and lowers 15 and 16, the rear floor panel 4, the frame member 6, and the reinforcing member connecting portion 22 of the reinforcing member 20 are used. , 2nd and 3rd connecting members 32, 33, foil house inner 7a, front side reins 13, side panel 8, rear pillar 9, roof side rail 10, and roof cross member 12 in front view. An annular skeleton portion of the vehicle body having an annularly continuous closed cross-sectional structure is configured.

Further, as shown in FIG. 12, the reinforcing member connecting portion 22 has an outer front flange 22d extending forward from the outer end portion in the vehicle width direction of the front surface portion 22a and a rear portion 22b rearward from the outer end portion in the vehicle width direction of the rear surface portion 22b. Further has an outer rear flange 22e extending to and continuous with the outer flange 25 of the reinforcing member main body 21.

As shown in FIG. 8, a rear seat support member mounting portion 29 is formed on the upper portion of the reinforcing member connecting portion 22, and a rear seat support portion 35 projecting forward is mounted on the rear seat support member mounting portion 29. Has been done. With reference to FIG. 12, the rear seat support member mounting portion 29 extends forward from the front portion 22a over the outer front flange 22d, and has a U-shape having a cross-sectional shape orthogonal to the front-rear direction and opening outward in the vehicle width direction. It is formed in a rectangular cross section.

The rear seat support member mounting portion 29 is formed with a pair of upper and lower base joint ridge lines 29a extending in the front-rear direction for forming a U-shaped cross section at the inner end portion of the U-shaped cross section in the vehicle width direction.

The rear seat support portion 35 is formed by press forming a steel plate, and the base portion 36 whose base end portion (rear end portion) is joined to the rear seat support member mounting portion 29 and the tip end side (rear end portion) of the base portion 36 ( It has a pivot branch 37 provided on the front end side).

The base portion 36 has a cross-sectional shape orthogonal to the front-rear direction formed in a hat-shaped cross section that opens outward in the vehicle width direction, and is formed along the foil house inner 7a from the base end portion joined to the rear seat support member mounting portion 29. It extends forward and forms a closed cross section extending in the front-rear direction with the foil house inner 7a. The closed cross section by the base portion 36 is closed by an arcuate wall portion centered on the pivot portion 37 at the tip portion (front end portion).

The base portion 36 is formed at the inner end portion in the vehicle width direction with a pair of upper and lower base portion ridge lines 36a extending in the front-rear direction for forming the hat-shaped cross section.

Specifically, the base portion 36 is provided on the front side of the foil house inner 7a from the front side of the central portion in the front-rear direction, and the base end portion side is along the foil house inner 7a in the top view shown in FIG. It extends in a direction inclined outward in the vehicle width direction toward the front, and extends in the front-rear direction around the pivot portion 37. That is, the base portion 36 is formed on the rear side of the pivot portion 37 with a base portion vertical ridge line 36b extending in the vertical direction in which the extending direction in the top view switches from the direction inclined outward in the vehicle width direction toward the front to the front. The vertical ridge line 36b of the base portion increases the rigidity of the base portion 36 in the vertical direction and the front-rear direction.

In the pivot portion 37, the pivot 90c (see FIG. 7) provided on the seat back 90a of the rear seat 90 is fixed via, for example, a fastening nut, whereby the seat back 90a is fixed to the pivot 90c. It is supported so that it can be tilted in the front-back direction.

As shown in FIGS. 3 and 11, the first connecting member 31 extends in the vertical direction inside the rain-shaped portion 30 of the reinforcing member 20 and the rear side reins 14 in the vehicle width direction, and extends in the horizontal direction. The cross-sectional shape is formed in a hat-shaped cross section that opens outward in the vehicle width direction. The first connecting member 31 is joined to the rain-shaped portion 30 of the reinforcing member 20 at the lower end portion, and the lower end portion of the rear side reins 14 is sandwiched between the foil house inner 7a and the foil house inner 7a at the upper end portion 3 It is double-joined. The rain shape portion 30 and the rear side reins 14 are configured such that the cross-sectional shapes perpendicular to the vertical direction are continuous via the first connecting member 31.

In other words, the rain shape portion 30, the first connecting member 31, and the rear side reins 14 each have a pair of front and rear rain shapes located inside in the vehicle width direction for forming a hat-shaped cross section or a U-shaped cross section. It has a portion ridge line 30f, a first connecting portion ridge line 31a, and a rear side rain portion ridge line 14a, and these are configured to be substantially continuous in the vertical direction.

As shown in FIGS. 3 and 11, the second connecting member 32 extends vertically inside the connecting portion upper portion 26 of the reinforcing member connecting portion 22 and the front side reins 13 in the vehicle width direction, and is horizontal. The cross-sectional shape in the direction is formed in a hat-shaped cross section that opens outward in the vehicle width direction. The second connecting member 32 is joined to the upper portion 26 of the connecting portion at the lower end portion, and is triple-bonded to the foil house inner 7a at the upper end portion with the lower end portion of the front side reins 13 sandwiched between them. .. The upper portion 26 of the connecting portion and the front side reins 13 are configured such that the cross-sectional shapes perpendicular to the vertical direction are continuous via the second connecting member 32.

In other words, the connecting portion upper portion 26, the second connecting member 32, and the front side reins 13 are a pair of front and rear connecting portions upper portions located inside in the vehicle width direction for forming each into a hat-shaped cross section or a U-shaped cross section. It has a ridge line 26a, a second connecting portion ridge line 32a, and a front side rain portion ridge line 13a, and these are configured to be substantially continuous in the vertical direction.

As shown in FIGS. 2 and 11, the third connecting member 33 extends in the vehicle width direction under the connecting portion lower portion 28 of the reinforcing member connecting portion 22 and the rear cross member upper 15 and extends in the vehicle width direction. A cross-sectional shape orthogonal to the width direction is formed in a hat-shaped cross section that opens downward. In the third connecting member 33, the outer end portion in the vehicle width direction is joined to the lower portion 28 of the connecting portion, and the inner end portion in the vehicle width direction is joined to the outer end portion in the vehicle width direction of the rear cross member upper 15. .. The lower portion 28 of the connecting portion and the rear cross member upper 15 are configured so that the cross-sectional shape perpendicular to the vehicle width direction is continuous via the third connecting member 33.

In other words, the lower portion 28 of the connecting portion, the third connecting member 33, and the rear cross member upper 15 have a pair of front and rear lower ridges of the connecting portion located at the upper end for forming each into a hat-shaped cross section or a U-shaped cross section. It has 28a, a third connecting portion ridge line 33a, and a rear cross member ridge line 15a, and these are configured to be substantially continuous in the vehicle width direction.

Therefore, the front side reins 13 and the rear cross member upper 15 have substantially continuous ridge lines via the second and third connecting members 32 and 33 and the reinforcing member connecting portion 22, and the vehicle body is composed of these. The rigidity of the annular skeleton is increased.

As described above, the reinforcing member 20 is made of an aluminum alloy, whereas the first to third connecting members 31 to 33, the frame member 6, and the rear seat support portion 35 to be joined to the reinforcing member 20 are made by press forming a steel plate. It is a thing. For this reason, rivets (for example, self-piercing rivets, hereinafter referred to as SPR) are used for joining these members instead of spot welding.

It should be noted that the joining by the SPR requires a dedicated jig and tool, and it is preferable to carry out the joining before assembling the reinforcing member 20 to the vehicle body due to the limitation of the work space on the vehicle body. That is, after forming a sub-assy in which the frame upper 71, the first to third connecting members 31 to 33, and the rear seat support portion 35 are previously joined to the reinforcing member 20 by SPR, the sub-assy is attached to the frame upper 71, the first. It is preferable to assemble the other members of the frame member 6 and the rear vehicle body structure such as the foil house inner 7a via the third connecting members 31 to 33 and the rear seat support portion 35 by an appropriate joining means such as spot welding.

Further, as described above, as shown in FIG. 8, the reinforcing member 20 is also fastened together with the pair of front and rear suspension fastening portions in the damper support portion 65 of the damper 92, and therefore, the front side damper mounting recess 23c. The rear damper mounting recess 23d is also fixed to the frame upper wall portion 61 by fastening.

Further, as shown in FIG. 11, in the upper part of the outer front flange 22d of the reinforcing member connecting portion 22, the base portion 36 of the rear seat support portion 35 is from the outside in the vehicle width direction with respect to the outer front flange 22d. It is joined by SPR, and the second connecting member 32 is joined by SPR from the inside in the vehicle width direction adjacent to the rear side thereof.

That is, in the reinforcing member connecting portion 22, the base portion joining portion 22f for joining the base portion 36 from the outside in the vehicle width direction by SPR and the second connecting member 32 for joining by SPR from the inside in the vehicle width direction. The front rain joint portion 22 g is provided at a position close to each other side by side in the front-rear direction.

Further, the base portion joint portion 22f and the front side rain joint portion 22g are joined by SPR from different directions in the vehicle width direction. Due to the bonding method, SPR cannot polymerize and bond three or more sheets with an aluminum alloy sandwiched between them. Therefore, the bonding at the base portion bonding portion 22f and the bonding at the front rain bonding portion 22g are performed respectively. Must be done individually. In that case, in the reinforcing member 20, the base portion joint portion 22f and the front rain joint portion 22f are joined by SPR from different directions in the vehicle width direction, so that the positions of the joint portions are mutually aligned. It can be placed in close proximity and the strength of the joint can be increased.

Further, the reinforcing member 20 is formed with reinforcing ribs 41 to 46 on the vehicle interior side and the vehicle interior outer side, respectively. As shown in FIG. 12, the reinforcing member inner wall portion 24 has a plurality of inner vertical ribs 41 projecting toward the vehicle interior side (inside in the vehicle width direction) and extending in the vertical direction at intervals in the vehicle front-rear direction. It is formed.

Specifically, six inner vertical first to sixth ribs 41a to 41f are formed in this order from the front. The inner vertical second rib 41b and the inner vertical third rib 41c are formed in the front-rear direction corresponding to positions adjacent to both front and rear sides of the front damper mounting recess 23c formed in the reinforcing member upper wall portion 23. There is. The inner vertical fifth rib 41e and the inner vertical sixth rib 41f are formed in the front-rear direction corresponding to positions adjacent to both front and rear sides of the rear damper mounting recess 23d formed in the reinforcing member upper wall portion 23. ing.

With reference to FIG. 13, on the reinforcing member upper wall portion 23, an outer vertical rib 42 that projects toward the vehicle interior side (upper side) and connects to the outer flange 25 in a brace shape is provided in the vehicle front-rear direction. Multiple pieces are formed at intervals. Specifically, five outer vertical first to fifth ribs 42a to 42e are formed in order from the front, and each gradually inward in the vehicle width direction from the vicinity of the upper end portion of the outer flange 25 downward. The amount of protrusion is increased, and the lower end portion of the reinforcing member upper wall portion 23 extends to a substantially central position in the vehicle width direction.

The outer vertical first rib 42a and the outer vertical second rib 42b are formed in the front-rear direction corresponding to positions adjacent to both front and rear sides of the front damper mounting recess 23c formed in the reinforcing member upper wall portion 23. There is. The outer vertical third rib 42c and the outer vertical fourth rib 42d are formed in the front-rear direction corresponding to positions adjacent to both front and rear sides of the rear damper mounting recess 23d formed in the reinforcing member upper wall portion 23. ing. The outer vertical fifth rib 42e is formed at a position corresponding to the rear surface portion 30b of the rain-shaped portion 30 in the front-rear direction.

Further, as shown in FIG. 14, a plurality of upper wall portion lower ribs 43 projecting to the outside (lower side) of the vehicle interior are formed on the reinforcing member upper wall portion 23. Specifically, nine front and rear ribs 43a to 43i extending in the vehicle width direction and a pair of front and rear ribs 43j and 43k extending in the front-rear direction of the vehicle in order from the front. Is formed.

The second, third, fifth, sixth, and eighth ribs 43b, 43c, 43e, 43f, and 43h in the vehicle width direction are the first to third, fifth, and sixth ribs 41a to the inner vertical direction in the front-rear direction, respectively. It is formed at a position corresponding to 41c, 41e, 41f (see FIG. 13), and the inner end portion in the vehicle width direction is joined to the reinforcing member inner wall portion 24. That is, the second, third, fifth, sixth, and eighth ribs 43b, 43c, 43e, 43f, and 43h in the vehicle width direction are the first to third in the inner vertical direction via the reinforcing member inner wall portion 24, respectively. It is continuous with the upper ends of the fifth and sixth ribs 41a to 41c, 41e, 41f.

The first rib 43a in the vehicle width direction is formed at a position corresponding to the rear surface portion 22b of the reinforcing member connecting portion 22 in the front-rear direction. The ninth rib 43i in the vehicle width direction is formed at a position corresponding to the rear surface portion 30b of the rain-shaped portion 30 in the front-rear direction.

The fourth and seventh ribs 43d and 43g in the vehicle width direction are formed at positions corresponding to the center positions of the front damper mounting recess 23c and the rear damper mounting recess 23d of the reinforcing member upper wall portion 23 in the vehicle front-rear direction. The amount of protrusion is set to substantially the same position as the vertical position of the bottom of the front damper mounting recess 23c and the rear damper mounting recess 23d.

The tenth rib 43j in the front-rear direction extends in the front-rear direction of the vehicle at a position corresponding to the center position in the vehicle width direction of the front damper mounting recess 23c, and connects the first rib 43a to the third rib 43c in the vehicle width direction in the front-rear direction of the vehicle. is doing. The 11th rib 43k in the front-rear direction extends in the front-rear direction of the vehicle at a position corresponding to the center position of the rear damper mounting recess 23d in the vehicle width direction, and connects the 8th and 9th ribs 43h and 43i in the vehicle width direction in the front-rear direction of the vehicle. At the same time, the rear end portion is joined to the vertical wall portion 23g on the front side of the rear flange 23a.

The lower ribs 43 of the upper wall portion are each formed at a height such that they do not come into contact with the upper wall portion 61 of the frame in a state of being assembled to the frame member 6.

As shown in FIG. 15, from the inner vertical rib 41 formed on the reinforcing member inner wall portion 24, the vehicle width direction rib 43 formed on the reinforcing member upper wall portion 23, and the reinforcing member upper wall portion 23. The outer vertical rib 42 formed over the outer flange 25 is continuous in the vehicle width direction from the vehicle interior surface side to the vehicle interior outer surface side of the reinforcing member 20. Specifically, the ribs 41 to 43 extend the reinforcing member 20 in the vehicle width direction and the vertical direction at positions adjacent to the front and rear of the pair of front and rear suspension fastening portions (that is, the front damper mounting recess 23c and the rear damper mounting recess 23d). It is formed continuously.

Further, as shown in FIG. 12, a plurality of front-rear direction ribs 44 for connecting the reinforcing member main body portion 21 and the reinforcing member connecting portion 22 in the front-rear direction are formed. Specifically, three front-rear direction first to third ribs 44a to 44c extending in the front-rear direction are formed in order from the top.

The first rib 44a in the front-rear direction is formed so as to connect the outer flange 25 of the reinforcing member 20 and the rear surface portion 22b of the reinforcing member connecting portion 22 in a bracing manner. The second rib 44b in the front-rear direction is formed so as to connect the upper wall portion 23 of the reinforcing member and the rear surface portion 22b of the reinforcing member connecting portion 22 in a bracing manner. The third rib 44c in the front-rear direction is formed so as to connect the inner wall portion 24 of the reinforcing member and the rear surface portion 22b of the reinforcing member connecting portion 22 in a bracing manner.

The first rib 44a in the front-rear direction is close to the reinforcing member upper wall portion 23 of the outer flange 25, and more specifically, a corner formed between the outer flange 25 and the reinforcing member upper wall portion 23. It is formed in a position close to the portion. Further, the second rib 44b in the front-rear direction is close to the reinforcing member inner wall portion 24 of the reinforcing member upper wall portion 23, and more specifically, between the reinforcing member upper wall portion 23 and the reinforcing member inner wall portion 24. It is formed at a position close to the corner to be formed.

That is, the first and second ribs 44a and 44b in the front-rear direction are each provided close to the corners or corners of the reinforcing member main body 21 where the rigidity is increased, so that the support rigidity is enhanced. ing.

As shown in FIG. 12, a plurality of connecting portion ribs 45 are also formed inside the reinforcing member connecting portion 22. Specifically, the three connecting portions extending in the front-rear direction of the vehicle in order from the top, the first to third ribs 45a to 45c in the front-rear direction, and the second and third ribs 45b, 45c in the front-rear direction of the connecting portion are substantially intermediate in the vertical direction. The connecting portion cylindrical rib 45d formed at the position and the connecting portion radial first to fourth ribs 45e to 45h formed radially around the rib 45d are formed.

The first to third ribs 45a to 45c in the front-rear direction of the connecting portion are not formed over the inside of the U-shaped cross section of the reinforcing member connecting portion 22, but the corners of the U-shaped cross section are built up in a brace shape. In this plan view, it is formed in a shape cut out in an arc shape, and the thickness of the intermediate portion in the front-rear direction is relatively small. As a result, the reinforcing member connecting portion 22 effectively reinforces the cross-sectional deformation in the front-rear direction or the vehicle width direction while suppressing the weight increase.

The first to fourth ribs 45e to 45h of the connecting portion are formed from the joint portion between the second and third ribs 45b and 45c in the front-rear direction of the connecting portion and the front surface portion 22a and the rear surface portion 22b of the reinforcing member connecting portion 22, respectively. , Radially extending toward the connecting portion cylindrical rib 45d.

Further, the reinforcing member connecting portion 22 is formed with an opening 22h penetrating in the thickness direction so as to communicate with the cylindrical space formed inside the connecting portion cylindrical rib 45d. Through the opening 22h, the joining work of the member located inside the member (for example, the joining work of the foil house inner 7a and the frame member 6 as shown in FIG. 10) can be performed.

As shown in FIG. 16, the first and second ribs 45a and 45b in the front-rear direction of the connecting portion are formed so as to be continuous with a pair of upper and lower upper wall portions and lower wall portions forming the rear seat support member mounting portion 29. There is. That is, the base portion ridge line 36a of the base portion 36 of the rear seat support portion 35, the base joint portion ridge line 29a of the rear seat support member mounting portion 29, and the first and second ribs 45a and 45b in the front-rear direction of the connecting portion are continuous in the front-rear direction. It has become like.

Further, as shown in FIGS. 13 and 14, a plurality of rain portion ribs 46 are also formed inside the rain shape portion 30. Specifically, two connecting portions, the first and second ribs 46a and 46b in the front-rear direction extending in the front-rear direction of the vehicle in order from the top, and the rain portion cylindrical rib 46c formed on the lower side thereof are formed. There is.

The first and second ribs 46a and 46b in the front-rear direction of the connecting portion are not formed over the inside of the U-shaped cross section of the rain-shaped portion 30, but the corners of the U-shaped cross section are built up in a brace shape. In this plan view, it is formed in a shape cut out in an arc shape, and the thickness of the intermediate portion in the front-rear direction is relatively small. As a result, the rain-shaped portion 30 effectively reinforces the cross-sectional deformation in the front-rear direction or the vehicle width direction while suppressing the weight increase.

Further, the rain-shaped portion 30 is formed with an opening 30 g penetrating in the thickness direction so as to communicate with the cylindrical space formed inside the rain portion cylindrical rib 46c. Through the opening 30 g, it is possible to carry out the joining work of the members located inside (for example, the joining work of the foil house inner 7a and the frame member 6).

(Rear seat)
As shown in FIG. 7, the rear seat 90 is a bench seat for three people and includes a seat back 90a and a seat cushion 90b. In FIG. 7, the seat back 90a on the right side is partially transparent.

The seat back 90a is divided into three in the vehicle width direction, for example, at a ratio of 4: 2: 4, and is located between the right seat back 90aR located on the right side and the left seat back 90aL located on the left side. It is a so-called split foldable seat back having a central seat back 90aC. By selectively tilting (folding) these three seat backs 90a forward, the size of the luggage compartment can be expanded as desired.

Each seat back 90a is supported by the rear vehicle body structure V so as to be tiltable in the front-rear direction. Specifically, the right seat back 90aR is provided with a pivot 90c protruding outward in the vehicle width direction at the lower right side, and the rear seat support portion 35 provided so as to project the pivot 90c forward from the reinforcing member connecting portion 22. It is fixed to the Axis 37. Further, in the right seat back 90aR, the pivot 90c is fixed to the pivot portion provided on the rear cross member upper 15 at the lower left side. As a result, the seat back 90a is configured to be able to tilt in the front-rear direction with respect to the pivot 90c.

The left seat back 90aL is also supported by the rear vehicle body structure V, except that the left and right seat backs are different. The central seat back 90aC is supported at both the left and right lower portions so as to be tiltable in the front-rear direction by a pivotal branch (not shown) provided on the rear cross member upper 15.

The seat cushion 90b is fixed to the front 4F of the rear floor via a bracket (not shown).

According to the rear body structure V according to the above embodiment, the following effects are obtained.

(1) Since both the rain shape portion 30 and the rear side reins 14 extend in the vertical direction and their cross-sectional shapes are configured to be continuous via the first connecting member 31, the damper support portion 65 Rigidity in the vertical direction is improved. As a result, among the loads input from the damper 92 to the damper support portion 65, the load in the vertical direction is transmitted to the rear side reins 14 via the rain-shaped portion 30, and is suitably supported by these. As a result, the load input to the damper support portion 65 is efficiently transmitted to the rear portion of the vehicle body, so that it is easy to improve the sense of unity of the occupant with respect to the movement of the vehicle body.

(2) The damper support portion 65 is provided with a suspension fastening portion to which the damper 92 is fixed by fastening, and the rain-shaped portion 30 is at least partially in the front-rear direction with respect to the suspension fastening portion when viewed from the vehicle side. Since they are located so as to overlap each other, it is easy to make the rain-shaped portion 30 function so as to more effectively support the load input from the damper 92 to the suspension fastening portion.

(3) The outer vertical rib 42 can improve the rigidity in the vertical direction between the suspension fastening portion and the rain-shaped portion 30. As a result, the vertical load input from the damper 92 to the suspension fastening portion is efficiently transmitted by the rain-shaped portion 30, so that the rain-shaped portion 30 and the rear side reins 14 are further subjected to the load. Easy to function to support more effectively.

(4) As for the load input from the damper 92 to the damper support portion 65, the load in the vertical direction is suitably supported by the rain-shaped portion 30 and the rear side reins 14, and the load in the front-rear direction is the reinforcing member connecting portion 22 and the rear. It is suitably supported by the cross member upper 15 and the front side reins 13. Therefore, since the load input from the damper 92 is more preferably supported, it is easier to further improve the sense of unity of the occupant with respect to the movement of the vehicle body.

(5) Since the damper support portion 65 is provided on the frame member 6, the rear vehicle body structure related to the support of the rear suspension 91 is compared with the case where the frame member 6 and the damper support portion 65 are arranged side by side in the vehicle width direction. V can be compactly configured in the vehicle width direction.

Further, a reinforcing member 20 is attached to a portion of the frame member 6 that is bifurcated by the damper support portion 65, over the frame upper wall portion 61 and the frame inner wall portion 63. Since the reinforcing member 20 can increase the rigidity of the damper support portion 65 in the vertical direction and inside in the vehicle width direction, the vertical displacement of the damper support portion 65 due to the vertical input load from the damper 92 is suppressed. Will be done. As a result, deformation of the frame member 6 centering on the damper support portion 65 of the bifurcated portion in the vehicle width direction is suppressed.

Therefore, while the rear body structure V related to the support of the rear suspension 91 is compactly configured in the vehicle width direction, it is possible to suppress the opening deformation of the bifurcated portion of the frame member 6 in the vehicle width direction with respect to the input load from the damper 92. ..

(6) Of the damper support portion 65, the suspension fastening portion to which the load is input from the damper 92 is directly supported by the reinforcing member 20, so that the damper support portion 65 can be reinforced more effectively. As a result, the reinforcing member 20 is made to act more effectively, and the displacement of the damper support portion 65 in the vertical direction is suppressed, so that the deformation of the bifurcated portion of the frame member 6 is further suppressed.

(7) The vehicle width direction rib 43 extending in the vehicle width direction and the inner vertical rib 41 continuous thereto are orthogonal to the reinforcing member upper wall portion 23, the reinforcing member inner wall portion 24, and the space between them in the front-rear direction. Flexural rigidity in the cross section is improved. As a result, the deformation of the bifurcated portion of the frame member 6 is further suppressed.

(8) The reinforcing member 20 is formed wider in the vehicle width direction by the outer flange 25, and the bending rigidity in the cross section orthogonal to the front-rear direction of the reinforcing member 20 is improved. As a result, the deformation of the bifurcated portion of the frame member 6 is further suppressed.

(9) The outer vertical rib 42 continuous with the outer end of the vehicle width direction rib 43 further improves the bending rigidity in the cross section orthogonal to the front-rear direction between the reinforcing member upper wall portion 23 and the outer flange 25. .. As a result, the deformation of the bifurcated portion of the frame member 6 is further suppressed.

(10) It is easy for the outer vertical rib 42 and the vehicle width direction rib 43 to effectively act on the load input from the damper 92 to the suspension fastening portion, and the above load is applied via these ribs 42 and 43. It is easy to disperse from the reinforcing member upper wall portion 23 to the reinforcing member inner wall portion 24 and the outer flange 25. As a result, the deformation of the bifurcated portion of the frame member 6 is further suppressed.

(11) The rear cross member upper 15 and the front side reins 13 can be connected by using the reinforcing member 20 that reinforces the damper support portion 65, and the connecting portion between the frame member 6 and the rear cross member upper 15 can also be reinforced. .. That is, the rigidity of the skeleton portion of the rear vehicle body including the rear cross member upper 15, the front side reins 13, and the frame member 6 can be improved via the reinforcing member 20. Further, the load input from the damper 92 to the damper support portion 65 is transmitted to the skeleton portion of the rear vehicle body via the reinforcing member 20, so that the occupant's sense of unity with the movement of the vehicle body is improved.

(12) Since the reinforcing member connecting portion 22 has a cross-sectional shape perpendicular to the extending direction in a U-shaped cross section in which the outside of the vehicle is open, it is easy to increase the rigidity of the reinforcing member connecting portion 22, thereby increasing the rigidity of the reinforcing member connecting portion 22. The rear cross member upper 15 and the front side reins 13 can be firmly connected. As a result, the rigidity of the rear vehicle body can be effectively improved, so that the occupant's sense of unity with the movement of the vehicle body is further improved.

(13) The skeleton portion of the rear vehicle body, which extends from the rear cross member upper 15 to the front side reins 13 via the reinforcing member connecting portion 22, can be configured with a closed cross section. As a result, the rigidity of the rear vehicle body can be effectively improved, so that the occupant's sense of unity with the movement of the vehicle body is further improved.

(14) In the skeleton portion of the rear vehicle body from the rear cross member upper 15 to the front side reins 13 via the reinforcing member connecting portion 22, ridge lines for forming each hat-shaped cross section or U-shaped cross section are continuous. Is extending. As a result, the rigidity of the rear vehicle body can be further effectively improved, so that the occupant's sense of unity with the movement of the vehicle body is further improved.

(15) Since the connecting portion inclined portion 27 extends linearly in a direction inclined upward toward the outside in the vehicle width direction when viewed from the front of the vehicle body, the connecting portion inclined portion 27 extends from the rear cross member upper 15 via the reinforcing member connecting portion 22. It is easy to suppress the deformation of the matchbox in the vehicle width direction of the skeleton portion of the rear vehicle body leading to the front side reins 13. As a result, the rigidity of the rear vehicle body can be further effectively improved in the vehicle width direction, so that the occupant's sense of unity with the movement of the vehicle body is further improved.

(16) The load input from the damper 92 to the reinforcing member main body 21 is effectively transmitted to the reinforcing member connecting portion 22 via the front-rear rib 44. Since the front-rear direction rib 44 extends so as to be connected in the front-rear direction, the load in the front-rear direction is particularly effectively transmitted to the reinforcing member connecting portion 22 among the loads input from the damper 92.

(17) The reinforcing member main body portion 21 has a reinforcing member upper wall portion 23, a reinforcing member inner wall portion 24, and an outer flange 25, and is formed in a stepped shape, so that the rigidity is enhanced. Further, the reinforcing member connecting portion 22 is connected to each surface of the reinforcing member main body portion 21 configured in a stepped shape via each of the plurality of front-rear direction ribs 44. As a result, the connection rigidity between the reinforcing member main body portion 21 and the reinforcing member connecting portion 22 can be improved in a well-balanced manner over the extending direction of the reinforcing member connecting portion 22. As a result, the rigidity of the reinforcing member 20 is improved as a whole, so that the rigidity of the rear vehicle body can be further and effectively improved, so that the occupant's sense of unity with the movement of the vehicle body is further improved.

(18) Since the rear seat support portion 35 is provided on the skeleton portion of the rear vehicle body including the rear cross member upper 15, the front side reins 13, and the reinforcing member connecting portion 22, the rear seat 90 can be easily interlocked by the movement of the vehicle body. , The sense of unity between the rear seat 90 and the vehicle body is improved.

(19) In the reinforcing member 20, the load input from the damper 92 to the damper support portion 65 is easily transmitted to the rear seat 90 via the rear seat support portion 35, so that the rear seat 90 is easily linked to the movement of the vehicle body, and as a result, The sense of unity between the rear seats and the vehicle body is further improved.

(20) The rear seat support portion 35 has a base portion 36 provided so as to project forward from the reinforcing member connecting portion 22, and a pivot portion 37 provided on the tip end side of the base portion 36, and has a rear seat. Since the 90 is supported by the pivot portion 37 so as to be tiltable, the rear seat 90 is linked to the movement of the vehicle body even when the rear seat support portion 35 is provided in front of the skeleton portion of the rear vehicle body. be able to.

(21) Even when the rear seat support portion 35 is provided in a cantilevered state in front of the reinforcing member connecting portion 22, it extends in the vertical direction in the vicinity of the rear seat support portion 35. Since it is connected to the front side reins 13 via the base portion joint portion 22f of the reinforcing member connecting portion 22 and the front side rain joint portion 22g, it is easy to increase the vertical support rigidity of the rear seat 90 by the pivot portion 37.

(22) The first and second ribs 45a and 45b in the front-rear direction of the connecting portion are formed so as to be continuous with the pair of upper and lower upper wall portions and lower wall portions forming the rear seat support member mounting portion 29. That is, the base portion ridge line 36a of the base portion 36 of the rear seat support portion 35, the base joint portion ridge line 29a of the rear seat support member mounting portion 29, and the first and second ribs 45a and 45b in the front-rear direction of the connecting portion are continuous in the front-rear direction. It has become like. As a result, the ridgeline or rib continuously extends in the front-rear direction from the inside of the U-shaped cross section of the reinforcing member connecting portion to the rear seat support portion, so that the reinforcing member connecting portion 22 can be cantilevered forward. The rigidity of the provided rear seat support portion 35 is further improved.

In the above embodiment, the reinforcing member 20 is configured to be connected to the front side reins 13, the rear side reins 14, and the rear cross member upper 15 via the first to third connecting members 31 to 33. Not limited to. That is, the reinforcing member 20 may be configured to be directly connected to the front side reins 13, the rear side reins 14, and the rear cross member upper 15 by, for example, SPR.

Further, in the above embodiment, the case where the damper support portion 65 is provided on the frame member 6 has been described as an example, but the present invention is not limited to this. That is, it can be applied when the damper support portion 65 is provided on the foil house inner 7a or is provided over both the frame member 6 and the foil house inner 7a, and even in this case, the reinforcing member corresponds to the damper support portion 65. Then, the rain-shaped portion may be formed so as to be continuous with the cross section of the rear side reins.

It is also possible to make various modifications and modifications without departing from the spirit and scope of the invention described in the claims.

As described above, according to the rear body structure according to the present invention, while the rear body structure related to the support of the rear suspension is compactly configured in the vehicle width direction, the deformation of the frame member due to the input load from the damper is suppressed. Since it can be used, it may be suitably used in this kind of manufacturing technology field.

4 Rear floor panel 6 Frame member 6W Wide part 7 Rear wheel house 7a Wheel house inner 8 Rear side panel 9 Rear pillar 10 Roof side rail 11 D pillar 12 Roof cross member 13 Front side reins 14 Rear side reins 15 Rear cross member upper 20 Reinforcing members 21 Reinforcing member main body 22 Reinforcing member connecting part 23 Reinforcing member upper wall part 24 Reinforcing member inner wall part 25 Outer flange 41 Inner vertical rib 42 Outer vertical rib 43 Upper wall lower rib 44 Front and rear rib 45 Connecting part rib 46 Rain part Rib 65 Damper support 90 Rear seat 92 Damper

Claims (3)

A frame member extending in the front-rear direction at the rear of the vehicle body,
A rear wheel house provided adjacent to the outside of the frame member in the vehicle width direction, and
A damper support that is provided over both the frame member and the rear wheel house or one of them and to which a damper provided for the rear suspension is attached.
A reinforcing member that reinforces the damper support portion and
It is provided at a position overlapping the damper support portion in the front-rear direction when viewed from the side of the vehicle, and is provided with a damper side side reins extending in the vertical direction along the vehicle interior side of the rear wheel house.
The reinforcing member has a rain-shaped portion that protrudes upward and is connected to the lower end portion of the damper side side reins.
The rain shape portion is formed so that the cross-sectional shape orthogonal to the extending direction is continuous with the cross-sectional shape of the damper side side reins .
The frame members are provided in pairs on both sides of the rear vehicle body in the vehicle width direction.
The rear floor extending inward in the vehicle width direction from the inner end portion of the frame member in the vehicle width direction,
A cross member provided on the upper surface of the rear floor and connecting the pair of left and right frame members in the vehicle width direction in front of the damper support portion.
With a front side reins that is provided along the vehicle interior side of the rear wheel house and extends in the vertical direction in front of the damper support portion.
Further prepare
The reinforcing member is a rear vehicle body structure further having a reinforcing member connecting portion for connecting the cross member and the front side reins . The damper support portion is provided with a suspension fastening portion to which the damper is fixed by fastening.
The rain-shaped portion is located so as to overlap at least partially in the front-rear direction with respect to the suspension fastening portion when viewed from the side of the vehicle.
The rear body structure according to claim 1. The reinforcing member is formed with an outer vertical rib that connects the rain-shaped portion and the suspension fastening portion in the vertical direction in a bracing manner.
The rear body structure according to claim 2.

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