CN110949514A - Vehicle body rear structure - Google Patents

Abstract

The invention provides a vehicle body rear structure, which increases the impact absorption amount when the rear part of the vehicle body rear structure is collided. A vehicle body rear structure (1) is provided with: left and right side members (3), left and right rear side frames (71), a rear sub frame (72), and a rear shock absorber support (112), the rear side frame having: a rear frame front part (71A) which extends obliquely rearward and laterally inward from the rear end of the side member; and a rear side frame rear part (71C) extending rearward from the rear end of the rear side frame front part via a rear side frame bent part (71B), the rear subframe having a rear subframe side member (91) having: a side member front part (91A) extending rearward and obliquely to the left and right inner sides; and a side member rear portion (91C) extending rearward from the rear end of the side member front portion via a side member bent portion (91B), the rear side frame bent portion and the side member bent portion being disposed at positions overlapping the rear absorber stay in the left-right direction.

Description

Vehicle body rear structure

Technical Field

The present invention relates to a vehicle body rear structure having a rear sub-frame.

Background

As a vehicle body rear structure of a four-wheeled vehicle, a structure having a pair of left and right rear side frames extending in the front-rear direction and a sub frame attached to the lower side of the rear side frames is known (for example, patent document 1). The auxiliary frame has the following functions: supports the engine and the generator, and disperses or absorbs the collision load at the time of a rear collision of the vehicle.

Documents of the prior art

Patent document 1: japanese patent laid-open publication No. 2011-143871

In the vehicle body rear structure according to patent document 1, front portions of left and right rear side frames are bent toward the rear and left and right inside in order to avoid interference with rear wheels. Further, the front portions of the pair of left and right side members of the subframe are also bent toward the rear, left and right inner sides, as in the case of the rear side frame. In such a rear vehicle body structure, stress is concentrated on the bent portions of the rear side frames and the side members with respect to a load from behind, and the rear vehicle body structure is likely to be deformed, and the amount of impact absorption may be insufficient.

Disclosure of Invention

In view of the above background, an object of the present invention is to increase the amount of impact absorption at the time of a rear collision in a vehicle body rear structure.

In order to solve the above problem, one aspect of the present invention is a vehicle body rear structure 1 including: a pair of left and right side members 3 extending in the front-rear direction at the side portions of the vehicle 2; a pair of left and right rear side frames 71 extending forward and backward at the rear of the vehicle; a rear sub-frame 72 attached to the left and right rear side frames; and a rear absorber support 112 provided to each of the rear side frames, the rear side frames having: a rear side frame front portion 71A extending obliquely rearward and laterally inward from a rear end of the side member; and a rear side frame rear portion 71C extending rearward from a rear end of the rear side frame front portion via a rear side frame bent portion 71B, the rear subframe including: a pair of left and right rear sub-frame longitudinal members 91 extending forward and rearward; and rear subframe cross members 92, 93 extending left and right to be combined with the left and right rear subframe longitudinal members, the rear subframe longitudinal members having: a side member front portion 91A extending rearward and obliquely inward from left to right; and a side member rear portion 91C extending rearward from a rear end of the side member front portion via a side member bent portion 91B, the rear side frame bent portion and the side member bent portion being disposed at positions overlapping the rear cushion receiver in the left-right direction.

According to this structure, the rear side frame bent portion is reinforced by the rear absorber stay, and the rigidity of the rear side frame in the front-rear direction can be improved. Further, since the rigidity of the rear side frame is improved, the rigidity of the rear sub frame attached to the rear side frame is improved. A load input from the rear of the vehicle body is transmitted to the side portions of the vehicle body through the rear side frames and the rear sub frame side members. The load applied to the rear side frame is transmitted to the side portion of the vehicle body via the absorber stay. This can suppress the load from being applied to the drive source such as an electric motor supported by the rear subframe.

In addition to the above-described aspect, the present invention may further include: a vehicle body cross member 77 extending left and right and coupled to the left and right rear side frame front portions; and a pair of left and right load transmission members 80 extending forward and inward from the rear frame bent portions and coupled to the cross member.

According to this structure, the load applied to the rear side frame can be transmitted to the cross member via the load transmission member. That is, the load applied to the rear side frame can be dispersed to the left and right outer sides and the left and right inner sides.

In the above aspect, the load transmission member may have a lateral width that increases as the load transmission member moves forward, and the lateral edge portions of the load transmission member may be coupled to the rear frame front portion.

According to this structure, the load applied to the rear side frame is dispersed over a wide range of the cross member by the load transmission member.

In addition to the above, the load transmission member may have a floor 78 provided above the left and right rear side frames, and the load transmission member may form a closed cross-sectional structure in cooperation with the front portion of the rear side frame and the floor.

With this configuration, the load transmission member can enhance the rigidity of the rear side frame front portion and the floor. This makes it possible to transmit the load applied to the rear side frame due to the front collision to the cross member.

In addition to the above aspect, the load transmission member may include: a bottom wall portion 80A that forms a triangular shape in plan view, and that is joined to the bottom surface of the cross member at a first side edge and to the bottom surface of the rear frame front portion at a second side edge; and a vertical wall portion 80B extending vertically from the third side edge of the bottom wall portion and coupled to the lower surface of the floor panel at the upper edge.

According to this structure, the load transmission member, the rear side frame front portion, and the floor panel can form a closed cross-sectional structure.

In addition to the above, a partition wall 81 coupled to the load transmission member and the rear side frame may be provided inside the closed cross section of the closed cross-sectional structure. Further, the partition wall extends left and right, and is coupled to the rear side frame at an outer edge in the left-right direction, and is coupled to the load transmission member at an inner edge and a lower edge in the left-right direction. Further, a sleeve 85B may be provided, which extends upward from the load transmission member inside the closed cross-sectional structure. Further, the cannula may be coupled to the septum wall.

With these configurations, the rigidity of the load transmission member, the rear side frame front portion, and the floor can be improved.

In addition to the above, the rear sub frame side member may be attached to the bushing.

According to this structure, can promote the installation intensity of the front end of back sub vehicle frame longeron.

Effects of the invention

According to the above configuration, in the vehicle body rear structure, the shock absorption amount at the time of a rear collision can be increased.

Drawings

Fig. 1 is a bottom view of a vehicle body structure according to an embodiment.

Fig. 2 is a bottom view of the vehicle body structure with the front subframe and the rear subframe omitted.

FIG. 3 is a side view of a front portion of the vehicle body structure.

Fig. 4 is a bottom view of the front portion of the vehicle body structure.

FIG. 5 is a perspective view of the front subframe.

FIG. 6 is a left side view of the front subframe.

Fig. 7 is a cross-sectional view showing a fastening structure of the rear end portion and the rear end support portion of the front side member of the front subframe.

Fig. 8 is a plan view showing the front subframe.

Fig. 9 is a perspective view showing a connection structure of the rear side frame, the body cross member, and the load transmission member, with the rear floor omitted.

Fig. 10 is a sectional view showing a connection structure of the rear side frame, the vehicle body cross member, and the load transmission member.

Fig. 11 is a perspective view of the rear subframe.

FIG. 12 is a top view of the rear subframe.

Fig. 13 is a sectional view taken along line XIII-XIII in fig. 12.

Fig. 14 is a rear view (view viewed along arrow XIV in fig. 12) showing the rear left end of the rear subframe.

Fig. 15 is a perspective view of the rear left end of the rear subframe as viewed from below.

Fig. 16 is a sectional view taken along line XVI-XVI in fig. 12.

Fig. 17 is a sectional view taken along line XVII-XVII in fig. 12.

Fig. 18 is a left side view of the rear portion of the vehicle body structure (the left side wall of the rear side frame is omitted for illustration).

Fig. 19 is a perspective view showing the left end of the rear portion of the vehicle body structure.

Fig. 20 is a cross-sectional view of an impact absorbing structure.

Fig. 21 is an explanatory diagram showing the arrangement of the electric motor with respect to the rear portion of the vehicle body structure.

Description of the reference symbols

1: a vehicle body structure;

3: a side beam;

4: a front side frame;

6: a front subframe;

23: a front longitudinal beam;

24: a front cross member;

26: a support member;

31: a lower arm;

36: a front lower arm supporting portion;

40: a steering gear box;

44: a joint portion;

51: a rear lower arm support portion;

53: a deformation promoting portion;

55: a front stabilizer;

56: a front stabilizer support;

71: a rear side frame;

72: a rear subframe;

75: an electric motor;

77: a vehicle body cross member;

78: a rear floor;

80: a load transmission member;

81: a partition wall;

91: a rear stringer;

92: a first rear cross member;

93: a second rear cross member;

93C: a second extension;

93L: a protrusion;

130: an impact absorbing structure;

131: a first shock absorber;

132: a second impact absorber;

140: a battery.

Detailed Description

The vehicle body structure of the present invention will be explained below. In the following description, the front-rear direction, the left-right direction (vehicle width direction), and the up-down direction are defined with reference to a vehicle. The right and left inner sides (inner sides in the vehicle width direction) are directions toward the center of the vehicle in the right and left direction, and the right and left outer sides (outer sides in the vehicle width direction) are directions away from the center of the vehicle in the right and left direction. The frame or panel, various components that make up the vehicle body structure, unless otherwise specified, are formed of steel.

As shown in fig. 1 and 2, the vehicle body structure 1 includes: a pair of left and right side members 3 extending in the front-rear direction at the left and right side portions of the lower portion of the both side portions of the vehicle 2; a pair of left and right front side frames 4 extending in the front-rear direction of the vehicle 2 and coupled at the rear ends thereof to the front ends of the corresponding left and right side members 3; and a front sub-frame 6 mounted on the lower side of the left and right front side frames 4 for supporting the front wheels 5.

A front floor 7 facing upward and downward is provided above the left and right side members 3. As shown in fig. 3, a pair of left and right front pillars 8 are provided at front ends of the left and right side members 3. Each front pillar 8 extends vertically and is joined at a lower end to a front end of the side member 3. As shown in fig. 1 and 2, a shroud 9 facing forward and backward is provided between the left and right front pillars 8. The shroud 9 is coupled to the left and right front pillars 8 at left and right side edges, and is coupled to the front edge of the front floor 7 at a lower edge.

As shown in fig. 1 to 4, the left and right front side frames 4 include: a front side frame front portion 4A extending forward and backward at a position on the left and right inner sides and above the left and right side members 3; a front side frame intermediate portion 4B extending rearward and downward from a rear end of each front side frame front portion 4A; and a front side frame inclined portion 4C (outrigger) extending rearward and laterally outward from a rear end of each front side frame intermediate portion 4B and coupled to a front end of the corresponding side member 3.

The front side frame intermediate portion 4B has a hat-shaped cross section that opens upward, and the front side frame intermediate portion 4B is joined to the front surface of the lower portion of the apron 9 to form a closed cross-sectional structure in cooperation with the apron 9. The front side frame inclined portion 4C has a hat-shaped cross section that opens upward, and is joined to the lower surface of the front floor 7 to form a closed cross-sectional structure in cooperation with the front floor 7. The front side frame inclined portion 4C has a front-rear width that increases toward the left and right outer sides, and is coupled to the left-right inner side surfaces of the side members 3 at the left and right outer ends.

As shown in fig. 3, a bulkhead 11 is provided at the front end of the left and right front side frame front portions 4A. The separator 11 has: a pair of left and right partition side members 11A extending vertically; a partition upper member 11B extending in the left-right direction and connecting upper ends of the left and right partition side members 11A to each other; and a lower bulkhead beam 11C extending in the left-right direction and connecting the lower ends of the left and right side bulkhead beams 11A, the bulkhead 11 being formed in a quadrangular frame shape. The front end of front side frame front portion 4A is coupled to a vertically intermediate portion of the rear surface of bulkhead side member 11A.

The front bumper beam 13 extending to the left and right is coupled to the left and right bulkhead side members 11A via a pair of left and right front crush boxes 12 as shock absorbers. Each front crash box 12 is formed in a tubular shape extending forward and rearward, and is coupled at a rear end to a middle portion in the vertical direction of the bulkhead side member 11A, and is coupled at a front end to a rear side surface of the front bumper beam 13. The front crash box 12 has lower rigidity in the front-rear direction than the front side frame 4, the front bumper beam 13, and the bulkhead 11, and when a load at the time of a front collision is applied, the front crash box 12 deforms earlier than the front side frame 4 and the like to absorb an impact.

A front upper beam 15 extending forward and then extending forward and downward is provided at an upper portion of each front pillar 8. The left and right front upper rails 15 are arranged laterally outward and upward with respect to the left and right front side frame front portions 4A. The front end of each front upper member 15 is coupled to the front end of the corresponding front side frame front portion 4A via a coupling member 16 extending in the left-right direction. A front absorber case 17 is provided between the front side frame front portion 4A and the front upper frame 15 corresponding to the left and right. The front absorber housing 17 has: a vertical wall portion 17A extending upward from the rear portion of the front frame front portion 4A; and an upper wall portion 17B extending laterally outward from the upper end of the vertical wall portion 17A and joined to the front upper member 15 at the lateral outer ends.

As shown in fig. 4, the left and right front side frame intermediate portions 4B are provided with lateral extension portions 4D extending leftward and rightward, respectively. The left and right inner ends of the left and right lateral extensions 4D face each other with a gap therebetween in the left-right direction. The left and right outer ends of the left and right lateral extensions 4D are joined to the inner side surfaces of the front side frame intermediate portions 4B. The lateral extension 4D has a hat-shaped cross section that opens upward, and forms a closed cross-sectional structure in cooperation with the floor. The lateral extension 4D constitutes a part of the front side frame 4.

As shown in fig. 4 and 7, guide members 19 are provided at the left and right inner ends of the left and right lateral extensions 4D. The guide members 19 extend rearward from lower surfaces of left and right inner ends of the lateral extension portion 4D. The guide member 19 has an inclined surface 19A inclined downward rearward at its lower front portion. The lateral extension portion 4D and the guide member 19 constitute a rear end support portion 21 that supports the rear end of the front subframe 6. The lateral extension portion 4D functions as a fastening seat for fastening the rear end of the front subframe 6.

As shown in fig. 4 and 5, the front subframe 6 includes a pair of left and right front side members 23 extending in the front-rear direction, and a front cross member 24 extending in the left-right direction and coupled to each front side member 23. The left and right front side members 23 are inclined rearward and leftward and rightward so as to approach each other at a distance rearward. Further, the left and right outer edges of the front side member 23 are curved so that the central portions in the front-rear direction are recessed inward in the left and right.

The left and right ends of the front cross member 24 are coupled to the middle portion of the front side member 23 in the front-rear direction. The left and right ends of the front cross member 24 are coupled to the front side frames 23 at positions slightly forward of the center in the front-rear direction. The front side member 23 and the front cross member 24 each have a cross section of a closed cross-sectional structure. The front edge (front end) of the front cross member 24 is formed linearly in the left-right direction. The front edge of the front cross member 24 is formed linearly in the left-right direction. The rear edge of the front cross member 24 is inclined rearward toward the left and right outer sides at the left and right ends. That is, the front cross member 24 has a front-rear width that increases toward the left and right outer sides.

A support member 26 extending left and right and connecting the left and right front side members 23 is provided behind the front cross member 24. The support member 26 is formed in an X shape in plan view, and extends from a central portion to the left front, right front, left rear, and right rear. The left and right ends of the front cross member 24 are joined to the left and right ends of the front side member, and the left and right ends of the rear side member are joined to the left and right front side members 23. The support member 26 is preferably formed of a steel plate facing downward.

As shown in fig. 4, the front end of each front side member 23 is disposed below and offset to the left and right inside of the front side frame front portion 4A corresponding to the left and right. Specifically, in a plan view, the left and right outer portions of the front end of the front side frame 23 are disposed at positions overlapping the left and right inner portions of the front end of the front side frame front 4A. The front side member 23 has a front end mounting portion 23A at a front end portion thereof to be mounted to the front side frame 4. The front end attachment portions 23A are provided at the left and right outer portions of the front end of the front side member 23. The front end attachment portion 23A of each front side frame 23 and the front end of the front side frame front portion 4A corresponding to the left and right are coupled to each other by a front link member 28 extending vertically. Specifically, the front side frame 23 is fastened to the lower end of the front connecting member by a bolt inserted from below. The front connecting member 28 constitutes a front end supporting portion that supports the front end of the front subframe 6. In the present embodiment, the front end attachment portion 23A is indirectly attached to the front side frame front portion 4A via the front connection member 28. In another embodiment, the front attachment member 23A may be indirectly attached to the front side frame front portion 4A via the front connection member 28.

The rear end of each front side member 23 is disposed below the corresponding left and right lateral extension portion 4D. That is, the rear end of the front side member 23 is disposed on the left and right inner sides of the front side frame intermediate portion 4B corresponding to the left and right. As shown in fig. 7, a vertically penetrating sleeve 29A is provided at the rear end of the front side member 23. The rear end of the front side member 23 is fastened to the lower surface of the lateral extension 4D by a bolt 29B, and the bolt 29B is inserted through a sleeve 29A from below and screwed to a nut 29C coupled to the lateral extension 4D. The rear end of the front side member 23 projects rearward from the lateral extension portion 4D, and the rear edge thereof extends to the left and right. The vertical width (vertical thickness) of the rear end of the front side member 23 gradually decreases toward the rear.

The rear end of the front side member 23 faces the inclined surface 19A of the guide member 19 with a gap therebetween in the front-rear direction. In addition, the rear end of the front side member 23 is disposed at a position overlapping the inclined surface 19A of the guide member 19 in a plan view.

As shown in fig. 4, the lower surface of the rear end of the front side member 23 is connected to the lower surface of the front side frame intermediate portion 4B by a plate-like connecting member 27. The connecting member 27 deforms when a predetermined load is applied, and releases the connection between the front side frame 23 and the front side frame intermediate portion 4B.

As shown in fig. 1 and 8, a pair of left and right front suspensions 30 are provided on the front subframe 6 and the left and right front side frames 4. The front suspension 30 has: a pair of left and right lower arms 31 swingably supported by the left and right front side members 23; a pair of right and left front knuckles 32 supported by the respective lower arms 31; and a front damper 33 connecting an upper portion of each front knuckle 32 and the upper wall portion 17B of the front damper housing 17 corresponding to the left and right.

The lower arm 31 is a so-called a-arm having: an arm rear portion 31A extending obliquely from the rear end to the left and right outer sides and forward; an arm bent portion 31B bent outward in the right and left direction from the front end of the arm rear portion 31A, and an arm front portion 31C extending outward in the right and left direction from the right and left outer ends of the arm bent portion 31B and supporting the front knuckle 32 at the tip end. The arm front portion 31C is formed to have a width wider than each of the arm rear portion 31A and the arm bent portion 31B. Front axle support portions 31D protruding inward in the right and left direction are provided on the right and left inner surfaces of the arm bent portion 31B. The axis of the front axle support 31D extends forward and rearward. A rear shaft support 31E extending in the vertical direction is provided at the rear end of the arm rear portion 31A.

As shown in fig. 4, each of the left and right front side members 23 is provided with a front lower arm support portion 36 that supports the front axle support portion 31D of the lower arm 31, and a rear lower arm support portion 51 that supports the rear axle support portion 31E of the lower arm 31.

The front lower arm support portion 36 is disposed at a position overlapping the front cross member 24 in the left-right direction, and the front lower arm support portion 36 is coupled to the front side member 23 and the front cross member 24.

As shown in fig. 5, the front lower arm support portion 36 includes: a base portion 36A extending right and left on the upper side of the front side member 23 and coupled to the front side member 23 and the front cross member 24; and a front support wall 36B and a rear support wall 36C that are coupled to the base 36A and the front side member 23 and protrude from the left and right outer side surfaces of the front side member 23 to the left and right outer sides.

The base portion 36A is formed in a hollow shape by combining the front member and the rear member with each other, and is coupled to the upper surface and the left and right inner side surfaces of the front side member 23 and the upper wall of the front cross member 24. The left and right inner ends of the base portion 36A extend through the upper wall of the hollow front cross member 24 toward the inside of the front cross member 24. The base portion 36A extends upward and laterally outward from the upper surface of the front side member 23 to form left and right outer end portions. The left and right outer ends of the front side member 23 are positioned on the left and right outer sides of the left and right outer side surfaces of the front side member 23.

The right and left outer ends of the base portion 36A are coupled to the lower surface of the front side frame front 4A via brackets 39. The bracket 39 has: an upper plate portion fastened to the lower surface of the front side frame front portion 4A by vertically extending bolts; and vertical plate parts hanging from the left and right inner ends of the upper plate part. The vertical plate portion of the bracket 39 abuts left and right outer end surfaces of the left and right outer ends of the base portion 36A, and is fastened to the left and right outer ends of the base portion 36A by bolts extending in the left and right directions.

The upper portion of the base portion 36A forms an inclined portion 36D (connecting portion) of an upward slope (upward gradient) from left and right inner end portions to left and right outer end portions. That is, the inclined portion 36D extends obliquely from the front cross member 24 to the front side frame front portion 4A.

The front support wall 36B and the rear support wall 36C are plate-like members facing front and rear, and are welded to left and right outer sides of the front side member 23 at left and right inner edges thereof. The rear support wall 36C is disposed with a gap in the rear with respect to the front support wall 36B. Upper portions of left and right inner edges of the front support wall 36B extend to an upper side of the front side member 23 and are welded to a front surface of the base 36A. Upper portions of left and right inner edges of the rear support wall 36C extend to an upper side of the front side member 23 and are welded to a rear surface of the base 36A. Lower portions of left and right inner edges of the front support wall 36B and the rear support wall 36C extend to a lower side of the front side member 23, and are welded to a lower surface of the front side member 23.

As shown in fig. 8, front axle support portion 31D of lower arm 31 is disposed between front support wall 36B and rear support wall 36C. A rubber bush (not shown) is attached to the front shaft support portion 31D of the lower arm 31, and a support shaft (not shown) extending in the front-rear direction through the rubber bush is provided to the front support wall 36B and the rear support wall 36C.

As described above, the front lower arm support portion 36 has the base portion 36A, the front support wall 36B, and the rear support wall 36C, and the front lower arm support portion 36 swingably supports the front shaft support portion 31D of the lower arm 31. The front lower arm support portion 36 is welded to the front side member 23 and the front cross member 24, and is fastened to the front side frame front portion 4A via a bracket 39.

As shown in fig. 4, in a plan view, it is preferable that front support wall 36B constituting the front end of front lower arm support 36 is disposed forward of the rear ends of the left and right end portions of front cross member 24, and rear support wall 36C constituting the rear end of front lower arm support 36 is disposed rearward of the front end of front cross member 24. That is, the front lower arm support portion 36 preferably has an overlap with the front cross member 24 in the left-right direction. In the present embodiment, the front support wall 36B (the front end of the front lower arm support portion 36) is disposed rearward of the front end of the front cross member 24, and the rear support wall 36C (the rear end of the front lower arm support portion 36) is disposed forward of the rear end of the front cross member 24.

As shown in fig. 8, a steering gear box 40 is provided on the upper surface of the front cross member 24. The steering gear box 40 has a rack housing 41 having a cylindrical portion extending in the right and left direction. A rack shaft 42 is provided inside the rack housing 41 so as to be slidable in the left and right directions with respect to the rack housing 41. The rack shaft 42 has left and right end portions projecting left and right from the rack housing 41, respectively, and is connected to the left and right front knuckles 32 via tie rods 43. The rack shaft 42 is connected to a tie rod 43, for example, by means of a ball joint 44. The left and right joint portions 44 are disposed inside shields 45 attached to the left and right ends of the rack housing 41, respectively.

Sleeves 47 vertically penetrating the front cross member 24 and welded to the upper wall and the lower wall of the front cross member 24 are provided at four locations, namely, left and right end portions of the front cross member 24 at the front portion and left and right inner end portions of the base portion 36A of the left and right front lower arm support portions 36 at the rear portion. The two rear side sleeves 47 are disposed on the left and right inner sides with respect to the two front side sleeves 47.

The left and right ends of the front side of the rack housing 41 are fastened to bushings 47 provided on the left and right front sides of the front cross member 24 by bolts. The rear portion of the rack housing 41 is fastened by bolts to one of bushings 47 provided on the left and right rear sides of the front cross member 24. The shape of the rack housing 41 differs depending on the left-right position of the steering shaft. The bushing 47 fastening the rear side of the rack housing 41 is selected according to the shape of the rack housing 41. Thus, the rack housing 41 is fastened to the front cross member 24 at three places.

The front edges (front ends) of the left and right front lower arm support portions 36 are disposed rearward of the front edge (front end) of the front cross member 24. The right and left inner ends of the inclined portion 36D of the base portion 36A are disposed on the right and left outer sides (lateral sides) of the upper end of the sleeve.

The front side member 23 is provided with a rear lower arm support portion 51 between the front lower arm support portion 36 and the rear end portion fastened to the lateral extension portion 4D. The rear lower arm support 51 includes: openings 51A formed in the left and right outer side surfaces of the front side member 23; and a support shaft (not shown) provided on the rear side of the opening 51A, extending vertically, and coupled to the upper wall and the lower wall of the front side member 23. A rubber bush (not shown) into which the support shaft is inserted is attached to the rear shaft support portion 31E of the lower arm 31. The rear shaft support portion 31E of the lower arm 31 is displaced with respect to the rear lower arm support portion 51 by deformation of the rubber bush. The lower arm 31 is swingably supported by the front subframe 6 via the front lower arm support portion 36 and the rear lower arm support portion 51.

As shown in fig. 4, the left rear lower arm supporting portion 51 is disposed on an extension line extending a left rear end of the support member 26 in a bottom view (in a top view). In addition, the right rear lower arm supporting portion 51 is disposed on an extension line extending a right rear end portion of the support member 26 in a plan view. The rear lower arm support portion 51 is disposed at a position more inward in the left-right direction than the front lower arm support portion 36. The left and right rear lower arm support portions 51 are disposed on the left and right inner sides of the left and right joint portions 44.

The front lower arm support portion 36 is disposed rearward of the steering gear box 40. The arm front portion 31C may be inclined slightly rearward outward in the left-right direction, or the joint portion 44 at the neutral position O1 may be disposed on an extension line extending the arm front portion 31C in the longitudinal direction.

As shown in fig. 5 and 6, each of the front side frames 23 has a deformation promoting portion 53 having lower rigidity than the other portions of the front side frame 23 at a position on the front side of the joint portion with the front cross member 24. The deformation promoting portion 53 is a concave portion recessed downward from the upper surface of the front side member 23. The deformation promoting portions 53 extend from the left and right inner side surfaces of the front side member 23 to the left and right outer side surfaces. When a collision load is applied to the front side member 23 from the front and rear, the front side member 23 is deformed first at the deformation promoting portion 53, and buckles downward from the deformation promoting portion 53 as a starting point.

A reinforcing plate 54 is joined to the upper surface of each front side member 23 along the upper surface thereof at a position forward of the deformation promoting portion 53. Each reinforcing plate 54 is provided with a front stabilizer support portion 56 that rotatably supports the front stabilizer 55. The front stabilizer 55 is a rod-shaped member having a laterally extending portion extending in the left-right direction and left-right end portions extending rearward from both left and right ends of the laterally extending portion, and the front stabilizer 55 is coupled at the end portions to the lower surfaces of the left and right front dampers 33 via a coupling member. The front stabilizer support portion 56 has a support hole (not shown) through which the lateral extension portion of the stabilizer passes. A rubber bush for supporting the lateral extension of the stabilizer is fitted in the supporting hole. The front stabilizer support portion 56 is fastened to the upper surface of the front side member 23 by a plurality of bolts. The front side member 23 has a higher rigidity at the portion where the reinforcing plate 54 and the front stabilizer support portion 56 are provided than at other portions.

As shown in fig. 1 and 2, the vehicle body structure 1 includes, as a rear structure, a pair of left and right rear side frames 71 extending rearward from rear ends of left and right side members, and a rear sub frame 72 provided below the left and right rear side frames 71. The rear subframe 72 supports a rear wheel 74 via a rear suspension 73, and supports an electric motor 75 as a driving source for driving the rear wheel 74. In other embodiments, the drive source may be an internal combustion engine.

As shown in fig. 2, each rear side frame 71 includes: a rear side frame front portion 71A (kick-up portion) extending obliquely upward and leftward and inward from the rear end of the side member 3; and a rear side frame rear portion 71C extending rearward from a rear end of the rear side frame front portion 71A via the rear side frame bent portion 71B. The rear side frame 71 has a cross section having a rectangular closed cross section including a lower wall, inner walls disposed on the left and right inner sides, outer walls disposed on the left and right outer sides, and an upper wall.

The left and right rear side frame front portions 71A are coupled to each other by left and right extending vehicle body cross members 77. The left and right end portions of the vehicle body cross member 77 are coupled to the left and right inner surfaces of the front side of the rear frame front portion 71A. A rear floor 78 is provided above the left and right rear side frames 71 and the vehicle body cross member 77. The vehicle body cross member 77 has a hat-shaped cross section that opens upward, and forms a closed cross-sectional structure in cooperation with the rear floor 78. A pair of left and right floor beams 79 extending forward along the lower surface of the rear floor 78 are provided at the intermediate portion in the left-right direction of the vehicle body cross member 77. The floor beam 79 is formed to be lower in height than the vehicle body cross member 77.

As shown in fig. 2 and 9, a pair of left and right load transmission members 80 are provided on the left and right inner sides of the left and right rear side frame front portions 71A and on the rear side of the vehicle body cross member 77. The load transmission member 80 is disposed at a corner formed by the rear frame front portion 71A and the vehicle body cross member 77. As shown in fig. 9 and 10, the load transmission member 80 includes: upward and downward facing bottom wall portion 80A; a vertical wall portion 80B extending upward from the left and right inner edges of the bottom wall portion 80A; and a flange portion 80C extending leftward and rightward from the upper edge of the vertical wall portion 80B.

The bottom wall portion 80A has: a leading edge extending left and right; and an inner edge and an outer edge inclined from both left and right ends of the front edge in a direction rearward and approaching each other, respectively, to form a triangle. That is, the bottom wall portion 80A of the load transmission member 80 increases in lateral width toward the front. Specifically, bottom wall portion 80A is formed in an isosceles triangle shape in which the lengths of the inner edge and the outer edge are substantially equal. The front edge of the bottom wall portion 80A extends along the lower surface of the cross member 77, and is welded to the lower surface of the cross member 77 at a plurality of locations. The outer edge of the bottom wall portion 80A extends along the lower surface of the lower wall of the rear side frame front portion 71A, and is welded to the lower wall of the rear side frame front portion 71A at a plurality of locations. The flange portion 80C is welded to the lower surface of the rear floor 78 at a plurality of locations. The vertical wall portion 80B and the flange portion 80C extend forward and laterally inward from the rear end of the rear frame front portion 71A to the rear surface of the cross member 77. The load transmission member 80 forms a closed cross-sectional structure in cooperation with the rear side frame front portion 71A, the body cross member 77, and the rear floor 78.

At least one partition wall 81 is provided inside the closed cross-sectional structure formed by the load transmission member 80, the rear side frame front portion 71A, the vehicle body cross member 77, and the rear floor 78. Each partition wall 81 extends in the front-rear direction and in the left-right direction, is welded to the vertical wall portion 80B of the load transmission member 80 at the left-right inner ends, and is welded to the inner wall of the rear side frame front portion 71A at the left-right outer ends. The lower end of partition wall 81 is welded to bottom wall 80A of load transmission member 80. The left and right inner ends, left and right outer ends, and lower ends of the partition wall 81 are preferably bent to form flanges. In addition, in other embodiments, the upper end of the partition wall 81 may be welded to the lower surface of the rear floor 78.

As shown in fig. 2, a pair of left and right first to fourth body-side mounting portions 83 to 86 for mounting the rear subframe 72 are provided at the rear portion of the vehicle body structure 1. The left and right first vehicle body side mounting portions 83 are provided at the front end portions of the left and right corresponding rear side frame front portions 71A. The first vehicle-body-side mounting portion 83 is formed by a through-hole formed in the lower wall of the rear frame front portion 71A and a bushing provided on the upper surface side of the lower wall of the rear frame front portion 71A so as to face the through-hole. The sleeve preferably extends vertically inside the rear side frame front portion 71A and is welded to the lower wall of the rear side frame front portion 71A. Further, the sleeve may be welded to a partition wall provided inside the rear side frame front portion 71A. An internal thread is formed inside the sleeve.

As shown in fig. 2, 9, and 13, left and right second body-side mounting portions 84 are provided at left and right end portions of the vehicle body cross member 77. The left and right second vehicle-body side mounting portions 84 are disposed on the left and right inner sides of the left and right first vehicle-body side mounting portions 83. The second vehicle-side mounting portion 84 is formed by a through-hole formed in the lower wall of the vehicle body cross member 77 and a bushing 84A provided on the upper surface side of the lower wall of the vehicle body cross member 77 so as to face the through-hole. The sleeve 84A preferably extends vertically inside the cross member 77 and is welded to the lower wall of the cross member 77. Further, the sleeve 84A may be welded to a partition wall provided inside the vehicle body cross member 77. An internal thread is formed inside the sleeve.

As shown in fig. 9 and 10, the left and right third vehicle body-side mounting portions 85 are provided on the left and right corresponding load transmission members 80. The third vehicle-body side mounting portions 85 on the left and right in the left-right direction are disposed at the same positions as the second vehicle-body side mounting portions 84 on the left and right. The third vehicle-body side mounting portion 85 includes a through hole 85A vertically penetrating the bottom wall portion 80A of each load transmission member 80, and a bushing 85B provided on the upper surface of the bottom wall portion 80A at a position facing the through hole 85A. Sleeve 85B extends vertically, and is welded at its lower end to the upper surface of bottom wall 80A and at its side surface to partition wall 81. The partition wall 81 preferably has a recess 81A formed therein for accommodating the side portion of the sleeve 85B. The sleeve 85B may have a rim portion 85C at its lower end, contacting the bottom wall portion 80A at the rim portion 85C. A female screw is formed on the inner peripheral surface of the sleeve 85B.

As shown in fig. 2 and 17, the left and right fourth vehicle body-side mounting portions 86 are provided at the rear ends of the left and right corresponding rear side frame rear portions 71C. The left and right fourth body-side mounting portions 86 are disposed on the left and right inner sides of the left and right first body-side mounting portions 83 and on the left and right outer sides of the left and right second body-side mounting portions 84. The fourth vehicle-body-side mounting portion 86 is formed by a through-hole 86A formed in the lower wall of the rear side frame 71 and a bushing 86B provided on the upper surface side of the lower wall of the rear side frame rear portion 71C so as to face the through-hole 86A. The sleeve 86B preferably extends vertically inside the rear side frame rear portion 71C and is welded to the lower wall of the rear side frame rear portion 71C. Further, the sleeve 86B may be welded to a partition wall 86C provided inside the rear side frame rear portion 71C. A female screw is formed inside the sleeve 86B.

As shown in fig. 17 and 18, rear ends of the left and right rear side frame rear portions 71C are joined to rear plates 88 extending left and right and facing front and rear. The rear plate 88 is joined to the rear edge of the rear floor 78.

The rear subframe 72 includes a pair of left and right rear side members 91 extending in the front-rear direction, and a first rear cross member 92 and a second rear cross member 93 extending in the left-right direction and coupled to the respective rear side members 91. The first rear cross member 92 is disposed forward of the second rear cross member 93.

The left and right rear side members 91, the first rear cross member 92, and the second rear cross member 93 are formed by combining an upper member (e.g., 94A) having a channel-shaped cross section that opens downward and a lower member (94B) having a channel-shaped cross section that opens upward, respectively, and have a hollow structure (see fig. 16). As shown in fig. 11, the first rear cross member 92 has a pair of left and right first side member insertion holes 92A penetrating in the front-rear direction. The second rear cross member 93 has a pair of right and left second side member insertion holes 93A penetrating in the front-rear direction. The left and right rear side members 91 extend in the front-rear direction through the first side member insertion holes 92A and the second side member insertion holes 93A corresponding in the left and right, and are welded to the first rear cross member 92 and the second rear cross member 93 at the first side member insertion holes 92A and the second side member insertion holes 93A. A portion of the first rear cross member 92 that is coupled to the left and right rear side members 91, that is, a portion around the first side member insertion hole 92A is referred to as a first side member coupling portion 92B. In addition, a portion of the second rear cross member 93 to which the left and right rear side members 91 are coupled, that is, a portion around the second side member insertion hole 93A is referred to as a second side member coupling portion 93B.

As shown in fig. 11 and 12, the rear side member 91 includes: a rear side member front part 91A extending obliquely rearward and laterally inward; and a rear side member rear portion 91C extending rearward from a rear end of the rear side member front portion 91A via the rear side member bent portion 91B. The rear side member 91 is joined to a first side member joining portion 92B of the first rear cross member 92 at a rear side member buckling portion 91B. The rear side member rear portion 91C extends from the first side member joint portion 92B of the first rear cross member 92 to the second side member joint portion 93B of the second rear cross member 93. A rear side member front end portion 91D extending laterally outward is provided at the front end of the rear side member front portion 91A.

(first rear sub-frame side mounting part 101)

First rear sub-frame side mounting portions 101 are formed at the left and right outer ends of the rear side member front end portion 91D. The first rear sub-frame side mounting portion 101 has a boss 101A vertically penetrating the rear side member front end portion 91D. The sleeve 101A is welded to the upper and lower walls of the rear side member front end portion 91D. The first rear sub-frame side mounting portion 101 is disposed below the first vehicle body side mounting portion 83, and is fastened to the first vehicle body side mounting portion 83 by a bolt.

A second rear sub-frame side mounting portion 102 is formed at the rear side member front portion 91A. The second rear sub-frame side mounting portion 102 has a boss 102A vertically penetrating the rear side member front portion 91A. The sleeve 102A is welded to the upper and lower walls of the rear side member front portion 91A. The second rear sub-frame side mounting portion 102 is disposed below the second body side mounting portion 84, and is fastened to the second body side mounting portion 84 by bolts.

The first rear cross member 92 has first extending portions 92C extending laterally outward and upward from the first side member coupling portions 92B (rear side members 91) at left and right end portions. A third rear sub-frame side mounting portion 103 is formed at the tip (left and right outer ends) of each first extension portion 92C. The third rear sub-frame side mounting portion 103 has a sleeve 103A vertically penetrating the tip end of the first extension portion 92C. The sleeve 103A is welded to the upper and lower walls of the first extension 92C. The third rear sub-frame side mounting portion 103 is disposed below the third vehicle body side mounting portion 85, and is fastened to the third vehicle body side mounting portion 85 by bolts.

The second rear cross member 93 has second extending portions 93C extending laterally outward and upward from the second side member coupling portions 93B (rear side members 91) at left and right end portions. A fourth rear sub-frame side mounting portion 104 is formed at a distal end (left and right outer ends) of each second extension portion 93C. The fourth rear sub-frame side mounting portion 104 has a sleeve 104A vertically penetrating the distal end of the second extension portion 93C. The sleeve 104A is welded to the upper and lower walls of the second extension 93C. The fourth rear sub-frame side mounting portion 104 is disposed below the fourth vehicle body side mounting portion 86, and is fastened to the fourth vehicle body side mounting portion 86 by a bolt. The rear side member 91 has a rear end attachment portion 91E attached to the rear side frame 71 at the rear end portion. The rear end mounting portion 91E is indirectly mounted to the rear side frame rear portion 71C via the second extension portion 93C of the second rear cross member 93. In another embodiment, the rear end mounting portion 91E may be directly mounted to the rear side frame rear portion 71C.

The vertical width of each of the first extended portion 92C and the second extended portion 93C gradually decreases toward the left and right outer sides. That is, the first extension portion 92C and the second extension portion 93C are tapered toward the distal ends.

As shown in fig. 14 and 15, the second rear cross member 93 has: an upper surface central portion 93D extending upward and rightward and leftward; a pair of left and right upper surface inclined portions 93F extending laterally outward and upward from both left and right ends of the upper surface central portion 93D via the upper surface bent portions 93E, respectively; a lower surface central portion 93G extending downward and left and right; and a pair of left and right lower surface inclined portions 93J extending laterally outward and upward from the left and right ends of the lower surface central portion 93G via the lower surface bent portions 93H. The left and right outer ends of the upper surface inclined portion 93F and the lower surface inclined portion 93J reach the fourth rear sub-frame side mounting portion 104. The upper surface central portion 93D, the upper surface inflection portion 93E, and the upper surface inclined portion 93F are formed in the upper member 94A constituting the second rear cross member 93, and the lower surface central portion 93G, the lower surface inflection portion 93H, and the lower surface inclined portion 93J are formed in the lower member 94B constituting the second rear cross member 93.

The left and right upper curved portions 93E are disposed on the left and right inner sides of the left and right second side member coupling portions 93B, and the left and right lower curved portions 93H are disposed on the left and right outer sides of the left and right second side member coupling portions 93B. Thereby, the vertical width of the second rear cross member 93 is maximized at the second side member joint portion 93B. The upper surface inflection portion 93E has a smaller angle with respect to the horizontal plane than the lower surface inflection portion 93H. The lower surface inclined portion 93J has a bead 93K extending from the lower surface bent portion 93H toward the fourth rear sub-frame side mounting portion 104.

As shown in fig. 1, the rear side member 91 is disposed inside and below the rear side frame 71. The rear side member front portion 91A and the rear side frame front portion 71A are arranged parallel to each other, and the rear side member rear portion 91C and the rear side frame rear portion 71C are arranged parallel to each other in a plan view. The rear side frame bent portion 71B and the rear side frame bent portion 91B are disposed at the same front-rear position.

A rear absorber support 112 for supporting the upper end of the rear absorber 111 is provided at each rear side frame 71. The rear absorber mount 112 may constitute a part of a side panel 113, the side panel 113 constituting a rear side wall of the vehicle 2. The rear side frame bent portion 71B and the rear side member bent portion 91B are disposed at positions overlapping the rear absorber stay 112 in the left-right direction. In other words, the rear side frame bent portion 71B and the rear side member bent portion 91B are disposed rearward of the front end of the rear damper mount 112 and forward of the rear end of the rear damper mount 112.

The left and right rear side members 91 are provided with a first suspension arm supporting portion 115, a second suspension arm supporting portion 116, and a third suspension arm supporting portion 117 from the front side. The first suspension arm supporting portion 115 is provided at the boundary between the rear side member front end portion 91D and the rear side member front portion 91A, and the second suspension arm supporting portion 116 and the third suspension arm supporting portion 117 are provided at the rear side member rear portion 91C. Inner ends of the first to third suspension arms 121 to 123 are rotatably supported by the first to third suspension arm support portions 115 to 117 via rubber bushes, respectively. In the case of illustrating the third suspension arm 123, as shown in fig. 16, a rubber bush 123A is provided at the inner end of the third suspension arm 123, and the rubber bush 123A is axially supported by a support shaft 117A provided in the third suspension arm support portion 117. A rear knuckle 124 that rotatably supports the rear wheel 74 is supported by the outer ends of the first to third suspension arms 121 to 123. The upper portion of the rear knuckle 124 is connected to the rear absorber mount 112 via the rear absorber 111.

As shown in fig. 1, the lower portions of the left and right rear shock absorbers 111 are connected to each other by a rear stabilizer 126. The rear stabilizer 126 is a rod-shaped member having a laterally extending portion extending in the left-right direction and left-right end portions extending rearward from both left and right ends of the laterally extending portion, and is coupled to the lower ends of the left and right rear shock absorbers 111 at the end portions via a coupling member. A rear stabilizer support portion 127 that rotatably supports a laterally extending portion of the rear stabilizer 126 is provided on a lower surface of the left and right rear side member front portions 91A.

As shown in fig. 18 and 19, a pair of left and right impact absorbing structures 130 extending rearward are provided at the rear ends of the left and right rear side frames 71 via the rear plate 88. The shock absorbing structure 130 is provided with a first shock absorber 131 and a second shock absorber 132 that extend rearward from the rear surface of the rear plate 88, respectively. The second shock absorber 132 has higher strength (rigidity) in the front-rear direction than the first shock absorber 131. The second shock absorber 132 is shorter in front-rear than the first shock absorber 131, and the rear end of the second shock absorber 132 is located forward of the rear end of the first shock absorber 131.

As shown in fig. 19 and 20, the first shock absorber 131 is a crash box in which two steel plates are formed into a cylindrical shape, and the axis extends forward and backward. The left-right width of the middle portion in the vertical direction of the first shock absorber 131 is formed narrower than the left-right width of the upper portion and the left-right width of the lower portion. It is preferable that the first shock absorber 131 is formed with a plurality of grooves and ridges extending in the left-right direction or the up-down direction. The rear ends of the left and right first shock absorbers 131 are coupled to a left and right extending rear bumper beam 133. The rear ends of the left and right first shock absorbers 131 are coupled to a left and right extending rear bumper beam 133.

The second shock absorber 132 is disposed inside the first shock absorber 131 formed in a cylindrical shape. In the present embodiment, the second shock absorber is two steel plates, and is welded to the inner surfaces of the left and right side portions of the first shock absorber 131. The second shock absorber 132 has irregularities, and forms a closed cross-sectional structure in cooperation with the first shock absorber 131. The second shock absorber 132 is formed of a material having higher strength (rigidity) than the first shock absorber 131.

As shown in fig. 12 and 18, the second rear cross member 93 has a projecting portion 93L projecting rearward at a central portion in the left-right direction. The rear plate 88 has a recess 88A recessed upward in the center of the lower edge, and the projection 93L projects rearward of the rear plate 88 through the recess 88A. The rear end of the projection 93L is located rearward of the rear end of the rear side frame 71 and the rear plate 88, and forward of the rear end of the impact absorbing structure 130. Specifically, the rear end of the protrusion 93L is located rearward of the rear end of the second shock absorber 132 and forward of the rear end of the first shock absorber 131. The rear edge of the second rear cross member 93 is inclined forward and laterally outward from the protruding portion 93L toward the fourth rear sub-frame side mounting portions 104 on the left and right sides.

As shown in fig. 21, an electric motor 75 as a driving source is attached to the upper side of the rear subframe 72. The electric motor 75 is supported by two mounts 135 provided to the first rear cross member 92 and one mount 135 provided to the second rear cross member 93. The mount 135 is fastened to the first and second rear cross members 92, 93, and has a base portion 135A that supports a rubber bush, and an arm portion 135B that is supported by the base portion via the rubber bush and fastened to the electric motor 75.

The electric motor 75 is supported by the rear subframe 72 so that its rotation shaft extends in the right and left directions. The driving force of the electric motor 75 is transmitted to the rear wheel 74 via the transmission mechanism. The electric motor 75 is disposed such that the center of gravity G thereof is located rearward of the rotation axis O of the rear wheel 74. That is, the electric motor 75 is disposed at the rear end portion of the vehicle 2.

The rear end of the projection 93L is located rearward of the rear end of the electric motor 75. The upper end of the shock absorbing structure 130 (first shock absorber 131) is disposed at a position higher than the lower end of the electric motor 75, and the lower end of the shock absorbing structure 130 (first shock absorber 131) is disposed at a position lower than the upper end of the electric motor 75. That is, the shock absorbing structure 130 is disposed at a position overlapping the electric motor 75 when viewed from the front-rear direction. With the above arrangement, the load at the time of a rear collision is applied not directly to the electric motor 75 but to at least one of the second rear cross member 93 and the impact absorbing structure 130.

As shown in fig. 1, a battery 140 is disposed below the front floor panel 7 and the rear floor panel 78. The battery 140 is disposed in a region surrounded by the left and right side members 3, the front subframe 6, and the rear subframe 72 in a plan view (in a bottom view). The battery 140 may be disposed in a region surrounded by the left and right side sills 3, the left and right front side frame inclined portions 4C, the left and right lateral extension portions 4D, and the vehicle body cross member 77.

The battery 140 includes a plurality of battery cells connected to each other and a battery case that houses the plurality of battery cells. The battery box constituting the housing of the battery 140 is supported by a plurality of battery support beams 143 that are spanned between the left and right side members 3.

The effects of the above embodiment will be described below. In the vehicle body structure 1 of the embodiment, the load at the time of a front collision is transmitted to the left and right side sills 3 via the left and right front side frames 4, and is suppressed from being transmitted to the battery 140. Further, the front subframe 6 attached to the front side frame 4 absorbs the load of the front collision, and can suppress the load from being transmitted to the battery 140. The load of the rear collision is transmitted to the left and right side members 3 via the left and right rear side frames 71, and is restrained from being transmitted to the battery 140. Further, the rear sub frame 72 attached to the rear side frame 71 absorbs the load of the rear collision, and can suppress the load from being transmitted to the battery 140. Since the battery 140 is disposed in a relatively large area surrounded by the left and right side members 3, the front subframe 6, and the rear subframe 72, the battery 140 can be increased in size.

When the front subframe 6 not equipped with the electric motor 75 receives a collision load, the front subframe is detached from the rear end support portion 21 and moves downward, and therefore, the load transmission from the front subframe 6 to the battery 140 can be suppressed. The guide member 19 abuts the rear end of the front subframe 6 at the inclined surface 19A, and the front subframe 6 can be reliably moved downward.

The load transmission member 80 distributes a load applied from behind to the rear side frame 71 at the time of a rear collision to the side member 3 and the body cross member 77, and can suppress deformation of the rear side frame 71. Thus, the rear side frame 71 can resist the load at the time of a rear collision, and the electric motor 75 mounted on the rear sub frame 72 can be appropriately protected. The load transmission member 80 forms a closed cross-sectional structure by cooperating with the rear side frames 71 and the rear floor 78, whereby the rigidity is improved. Further, the load transmission member 80 has increased rigidity due to the partition wall 81 and the sleeve 85B. Since the second body-side mounting portion 84 is provided in the load transmission member 80 having relatively high rigidity, the rear subframe 72 can be supported with good stability. Since the lateral width of the load transmission member 80 increases as the vehicle moves forward, the load applied to the rear side frame 71 can be dispersed over a wide range of the cross member 77 by the load transmission member 80.

The lateral load input from the first to third suspension arms 121 to 123 to the rear side member 91 is transmitted to the load transmission member 80 and the rear side frame 71 through the first and second side member coupling portions 92B, 93B, the first and second extension portions 92C, 93C, and the third and fourth rear sub-frame side mounting portions 103, 104 in this order. This can improve the rigidity of the rear side frame 72 against a lateral load from the suspension arm.

The vertical width of the second rear cross member 93 is maximized at the second side member coupling portion 93B, and therefore the rear side member 91 can be reliably supported. This allows the rear side member 91 to sufficiently resist a relatively large lateral force at the initial stage of input. Since the vertical width of the second extended portion 93C gradually decreases toward the left and right outer sides, stress concentration on the second extended portion 93C can be suppressed. By setting the buckling of the upper surface buckling portion 93E to be gentle with respect to the buckling of the lower surface buckling portion 93H, the lateral force applied from the rear side member 91 to the second rear cross member 93 can be efficiently transmitted to the rear side frame 71.

Since the left and right front side members 23 of the front subframe 6 are inclined in the direction approaching each other in the rear direction, the load at the time of a frontal collision applied to the front subframe 6 can be transmitted to the vehicle interior side inclined with respect to the left and right front side frames 4, and the load can be dispersed.

When a load at the time of a frontal collision is applied to the front side member 23, the front side member 23 buckles downward at the deformation promoting portion 53. As a result, stress is applied to the rear end support portion 21 and the bolt 29B, the fastening structure between the rear end of the front side member 23 and the rear end support portion 21 is broken, and the front subframe 6 can be smoothly detached from the rear end support portion 21. Since the reinforcing plate 54, the front stabilizer support portion 56, the front cross member 24, and the front lower arm support portion 36 are provided in front of and behind the deformation promoting portion 53, the rigidity of the deformation promoting portion 53 is relatively low. This makes it easy for stress to concentrate on the deformation promoting portion 53 and for the deformation promoting portion 53 to serve as a starting point of deformation.

Since the rear side frame bent portion 71B is disposed on the side of the rear shock absorber mount 112, the rear side frame bent portion 71B is reinforced by the rear shock absorber mount 112, and the rear side frame bent portion 71B is less likely to be bent by a load at the time of a rear collision.

Since the rear end of the impact absorbing structure 130 protrudes rearward from the rear end (the protruding portion 93L) of the rear subframe 72, the rear subframe 72 receives the load at the protruding portion 93L after the impact absorbing structure 130 absorbs the load. Therefore, when the collision load is relatively small, the load is absorbed by the deformation of the impact absorbing structure 130, and is difficult to be transmitted to the rear subframe 72. Therefore, deformation of the rear subframe 72 is suppressed. On the other hand, when the collision load is large, the load is transmitted from the protruding portion to the rear sub frame 72, and the load applied to the rear side frame 71 can be dispersed.

When the collision load is relatively small, the load is absorbed by the first shock absorber 131, and when the collision load is large, the load is absorbed by the second shock absorber 132. Since the shock absorbing structure 130 is disposed rearward of the electric motor 75, the load at the time of a rear collision is absorbed by the shock absorbing structure 130 and then applied to the electric motor 75.

Since the protruding portion 93L of the second rear cross member 93 constituting the rear end of the rear subframe 72 is located rearward of the rear end of the electric motor 75, a load of a rear collision is more likely to be applied to the rear subframe 72 than the electric motor 75. Since the electric motor 75 is disposed at the rear portion of the rear subframe 72, a space can be secured in front of the electric motor 75. A high voltage device such as a converter can be arranged in the space. Further, the space can be used as a movement space (escape space) of the electric motor 75 at the time of a rear collision, and collision of the battery 140 with the electric motor 75 can be suppressed. By providing the recess 88A at the lower edge of the rear plate 88, the protruding portion 93L of the rear subframe 72 can protrude rearward of the rear plate 88 without interfering with the rear plate 88.

By disposing the rear end of the protruding portion 93L rearward of the rear end of the rear side frame 71, the electric motor 75 can be disposed further rearward of the vehicle body structure 1, and a space can be secured forward of the electric motor 75. Further, the load applied to the rear side frame 71 due to the rear collision can be transmitted from the protruding portion 93L to the rear subframe 72, and the load applied to the rear subframe 71 can be dispersed.

Since the second rear cross member 93 is inclined forward and laterally outward from the protruding portion 93L toward the left and right fourth rear sub-frame side mounting portions 104, a load applied from behind to the center portion of the second rear cross member 93 can be efficiently transmitted to the left and right rear side frames 71.

Since the protruding portion 93L of the rear side frame 71 is located forward of the rear end of the impact absorbing structure 130 and rearward of the front end, the second rear cross member 93 receives the load at the protruding portion 93L after the impact absorbing structure 130 absorbs the load. Therefore, a relatively small collision load is absorbed by the impact absorbing structure 130 and is difficult to be transmitted to the rear sub frame 72. Therefore, deformation of the rear subframe 72 is suppressed. On the other hand, when the collision load is large, the load is transmitted from the protruding portion 93L to the rear sub frame 72, and the load applied to the rear side frame 71 can be dispersed.

Since the front subframe 6 according to the present embodiment has the front lower arm support portion 36 disposed in the portion where the rigidity is improved by the front cross member 24, the front subframe 6 is less likely to deform in response to the lateral force applied from the lower arm 31 even in the case where the front side member 23 has the deformation promoting portion 53 or the case where the front side member 23 has a shape curved to expand the steering space of the front wheel 5. This can improve the ride quality and the traveling performance. Further, the front side frame 23 can be bent to the left and right inner sides, and a space for steering the front wheel 5 can be secured large on the left and right outer sides of the front subframe 6, and the steering angle of the front wheel 5 can be set large.

The front lower arm support portion 36 is provided in a portion that overlaps the front cross member 24 in the left-right direction, and thus the front subframe 6 can be made more resistant to deformation against lateral forces applied from the lower arm 31.

The front lower arm support portion 36 is coupled to the front side member 23 and the front cross member 24, whereby the rigidity of the front lower arm support portion 36 is further improved. This enables the front subframe 6 to reliably support the lower arm 31. Further, in the front side member 23, the difference in rigidity between the deformation promoting portion 53 and the portion behind the deformation promoting portion 53 where the front cross member 24 and the front lower arm supporting portion 36 are provided is increased, and therefore, the front side member 23 can be reliably deformed at the deformation promoting portion 53 at the time of a front collision.

The front lower arm support portion 36 is coupled to the front side frame 4, and therefore, the rigidity of the front lower arm support portion 36 is improved. Further, the lateral force applied from the lower arm 31 to the front lower arm support portion 36 can be transmitted to the front side frame 4. Further, the load can be efficiently transmitted from the front side member 23 and the front cross member 24 to the front side frame 4 through the inclined portion 36D. Since the end of the inclined portion 36D is provided at the portion of the front cross member 24 where rigidity is enhanced by the collar 47, the load can be efficiently transmitted from the front cross member 24 to the front side frame 4. Further, the rigidity of the front cross member 24 can be enhanced by the steering gear box 40.

The support members 26 increase the rigidity of the front sub-frame 6. Likewise, the front stabilizer 55 raises the rigidity of the front sub frame 6. This makes it possible to make the front subframe 6 less likely to deform in response to a lateral force applied from the lower arm 31.

In the event of a frontal collision, the front crush box 12 is first deformed to absorb the load, and therefore, the deformation promoting portion 53 can be suppressed from being deformed when the collision load is small. This can avoid replacement of the front subframe 6.

While the description of the specific embodiments has been completed, the present invention is not limited to the above embodiments, and can be widely modified.

Claims (10)

1. A vehicle body rear structure characterized by comprising:

a pair of left and right side members extending in front and rear directions on side portions of the vehicle;

a pair of left and right rear side frames extending forward and rearward at a rear portion of the vehicle;

a rear sub-frame mounted to the left and right rear side frames; and

a rear shock absorber support provided to each of the rear side frames,

the rear side frame has: a rear frame front portion extending obliquely rearward and laterally inward from a rear end of the side member; and a rear side frame rear portion extending rearward from a rear end of the rear side frame front portion via a rear side frame bent portion,

the rear subframe has: a pair of left and right rear subframe stringers extending fore and aft; and a rear sub frame cross member extending left and right to be combined with the left and right rear sub frame longitudinal members,

the rear subframe longitudinal beam has: a side member front part extending rearward and obliquely inward of the left and right sides; and a side member rear portion extending rearward from a rear end of the side member front portion via a side member bent portion,

the rear side frame bent portion and the side member bent portion are disposed at positions overlapping the rear absorber stay in the left-right direction.

2. The vehicle body rear structure according to claim 1,

the vehicle body rear structure has:

a vehicle body cross member extending in the left-right direction and coupled to the front portions of the left and right rear side frames; and

and a pair of left and right load transmission members extending forward and inward from the rear frame bent portions and coupled to the cross member.

3. The vehicle body rear structure according to claim 2,

the load transmission member has a width that increases as it approaches the front,

the load transmission member has left and right outer edges joined to the rear frame front portion.

4. The vehicle body rear structure according to claim 2,

the vehicle body rear structure has a floor panel provided on an upper side of the left and right rear side frames,

the load transmission member forms a closed-section structure in cooperation with the rear side frame front portion and the floor panel.

5. The vehicle body rear structure according to claim 4,

the load transmission member includes: a bottom wall portion that forms a triangular shape in plan view, and that is joined to the bottom surface of the cross member at a first side edge and to the bottom surface of the front portion of the rear side frame at a second side edge; and a vertical wall portion extending upward from a third side edge of the bottom wall portion, and coupled to the lower surface of the floor panel at an upper edge.

6. The vehicle body rear structure according to claim 4,

a partition wall coupled to the load transmission member and the rear side frame is provided inside the closed cross-sectional structure.

7. The vehicle body rear structure according to claim 6,

the partition wall extends in the right and left direction, is coupled to the rear side frame at the outer edge in the right and left direction, and is coupled to the load transmission member at the inner edge and the lower edge in the right and left direction.

8. The vehicle body rear structure according to claim 6,

the vehicle body rear structure has a sleeve extending upward from the load transmission member inside the closed cross section of the closed cross section structure.

9. The vehicle body rear structure according to claim 8,

the sleeve is coupled to the septum wall.

10. The vehicle body rear structure according to claim 8 or 9,

the rear subframe rail is mounted to the bushing.

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