JP6767450B2 - Body front structure - Google Patents

Description

The present invention relates to a vehicle body front structure including a front subframe.

As a vehicle body front structure of a four-wheeled vehicle, a structure having a pair of left and right front side frames extending in the front-rear direction and a front subframe attached to the lower side of the front side frame is known (for example, Patent Document 1). The front subframe has a pair of left and right vertical members extending forward and backward, and a cross member extending left and right and connected to the left and right vertical members. The left and right vertical members are attached to the corresponding front subframes at the front and rear, respectively. At the center of the vertical member in the longitudinal direction, a bending promoting portion that becomes a starting point of deformation when a load of a forward collision is applied is formed. The vertical member absorbs the collision load by deforming from the bending promoting portion as a starting point.

Japanese Unexamined Patent Publication No. 2005-271810

If the rigidity of the subframe is low, the subframe is likely to be deformed by the lateral force input from the lower arm of the suspension, and the riding comfort and running performance are deteriorated. When the bending promoting portion is provided in the vertical member, the rigidity of the vertical member is lowered, so that the riding comfort and the like may be further deteriorated.

In view of the above background, it is an object of the present invention to improve the rigidity against the lateral force input from the lower arm in the vehicle body front structure provided with the front subframe.

In order to solve the above problems, one aspect of the present invention is a front subframe (6) attached to the front portion of the vehicle (2) and a suspension (30) oscillatingly supported by the front subframe. The front subframe has a pair of left and right lower arms (31), a pair of left and right vertical members (23) extending forward and backward, and a cross member (24) extending left and right and connected to the left and right vertical members. And at least one of the vertical member and the cross member, and having at least one lower arm support portion (36) for swingably supporting the lower arm, and each of the vertical members has the cross. A front lower arm support portion which has a deformation promoting portion (53) having a lower rigidity than other portions of the vertical member on the front side of the joint portion with the member and is arranged on the frontmost side of the lower arm support portions. Provided is a vehicle body front structure characterized in that the rear end is arranged behind the front end of the cross member and the front end of the front lower arm support is arranged behind the front end of the cross member. ..

According to this configuration, in the vertical member provided with the deformation promoting portion, the front lower arm support portion is arranged at the portion where the rigidity is increased by the cross member, so that the front subframe is deformed by the lateral force applied from the lower arm. It can be difficult. As a result, riding comfort and running performance can be improved. Further, since the front lower arm support portion is provided at a portion that overlaps the cross member in the left-right direction, the front subframe can be made more difficult to be deformed by the lateral force applied from the lower arm.

In the above aspect, the front lower arm support portion may be coupled to the vertical member and the cross member.

According to this configuration, the rigidity of the front lower arm support portion is improved by the cross member, and the lower arm can be reliably supported. Further, in the vertical member, the difference in rigidity between the deformation promoting portion and the portion provided with the cross member behind the deformation promoting portion and the front lower arm support portion becomes large, so that the vertical member is surely in the deformation promoting portion at the time of a forward collision. It can be transformed.

In the above aspect, the front lower arm support portion may be connected to the left and right outer surfaces and the upper surface of the vertical member and the upper surface of the cross member.

According to this configuration, the lateral force applied from the lower arm to the front lower arm support portion can be transmitted to the cross member.

In the above embodiment, the vehicle has a pair of left and right front side frames (4) extending forward and backward, and the front lower arm support portion extends upward from the vertical member and is attached to the front side frame. It is good to have.

According to this configuration, the lateral force applied from the lower arm to the front lower arm support portion can be transmitted to the front side frame.

In the above aspect, the front lower arm support portion may have a connecting portion (36D) extending outward and upward from the cross member toward the front side frame.

According to this configuration, the load can be efficiently transmitted from the cross member to the front side frame.

In the above aspect, the cross member is provided with a collar (47) that penetrates the cross member up and down and is coupled to the upper surface and the lower surface of the cross member, and the collar is provided with a steering gear box (40). Is attached, and the inner end of the inclined portion in the left-right direction may be arranged on the side of the upper end of the collar.

According to this configuration, since the end portion of the inclined portion is provided at the portion of the cross member whose rigidity is improved by the collar, the load can be efficiently transmitted from the cross member to the front side frame.

In the above aspect, the steering gear box may extend to the left and right and may be coupled to the upper surface of the cross member at a plurality of positions in the left and right directions.

According to this configuration, the rigidity of the cross member can be improved by the steering gear box. This makes it difficult for the front subframe to be deformed with respect to the lateral force input from the lower arm to the front subframe.

In the above aspect, the deformation promoting portion may be a recess recessed downward on the upper surface of the vertical member.

According to this configuration, a deformation promoting portion capable of reliably bending the vertical member downward can be formed with a simple configuration.

In the above aspect, the left and right outer edges of the vertical member may be curved so that the central portion in the front-rear direction is recessed inward in the left-right direction.

According to this configuration, a large space for steering the front wheels can be secured on the left and right outer sides of the subframe, and the steering angle of the front wheels can be increased.

In the above aspect, the front side frame has a front mounting portion (28) to which a portion of the vertical member on the front side of the deformation promoting portion is mounted, and is on the front side of the front side frame from the front mounting portion. It is preferable that the shock absorbing structure (12) is provided.

According to this configuration, since the front collision load can be absorbed by the impact absorbing structure, it is possible to suppress the deformation of the deformation promoting portion when the collision load is small. This makes it possible to avoid replacement of the front subframe.

According to the above configuration, in the vehicle body front structure provided with the front subframe, the rigidity against the lateral force input from the lower arm can be improved.

Bottom view of the vehicle body structure according to the embodiment Bottom view of the vehicle body structure with the front subframe and rear subframe omitted Side view of the front part of the car body structure Bottom view of the front part of the car body structure Perspective view of front subframe Left side view of front subframe Cross-sectional view showing the fastening structure between the rear end portion and the rear end support portion of the front vertical member of the front subframe. Floor plan showing the front subframe

Hereinafter, the vehicle body structure according to the present invention will be described. 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 the vehicle. Left-right inward (inside in the vehicle width direction) means a direction approaching the center of the vehicle in the left-right direction, and left-right outside (outside in the vehicle width direction) means a direction away from the center of the vehicle in the left-right direction. Unless otherwise specified, the frames, panels, and various members that make up the vehicle body structure are made of steel.

As shown in FIGS. 1 and 2, the vehicle body structure 1 includes a pair of left and right side sills 3 extending forward and backward on the lower left and right side portions of both side portions of the vehicle 2, and a front portion of the vehicle 2 extending forward and backward at the rear end. It has a pair of left and right front side frames 4 connected to the front ends of the corresponding left and right side sills 3, and a front subframe 6 attached to the lower side of the left and right front side frames 4 to support the front wheels 5.

A front floor panel 7 whose surface faces up and down is hung on the upper side of the left and right side sills 3. As shown in FIG. 3, a pair of left and right front pillars 8 are provided at the front ends of the left and right side sills 3. Each front pillar 8 extends vertically and is coupled to the front end of the side sill 3 at the lower end. As shown in FIGS. 1 and 2, a dash panel 9 whose surface faces the front and rear is provided between the left and right front pillars 8. The dash panel 9 is connected to the left and right front pillars 8 at the left and right side edges, and is connected to the front edge of the front floor panel 7 at the lower edge.

As shown in FIGS. 1 to 4, the left and right front side frames 4 have a front side frame front portion 4A extending inward and upward from the left and right side sills 3 in the front-rear direction and rear of each front side frame front portion 4A. The front side frame intermediate portion 4B extending rearward and downward from the end and the front side frame inclined portion 4C 4C extending rearwardly and laterally outward from the rear end of each front side frame intermediate portion 4B and coupled to the front end of the corresponding side sill 3. Outrigger) and.

The front side frame intermediate portion 4B has a hat-shaped cross section that opens upward, is coupled to the front surface of the lower portion of the dash panel 9, and forms a closed cross section structure in cooperation with the dash panel 9. The front side frame inclined portion 4C has a hat-shaped cross section that opens upward, is coupled to the lower surface of the front floor panel 7, and forms a closed cross section structure in cooperation with the front floor panel 7. The front-rear width of the front side frame inclined portion 4C gradually increases toward the left-right outer side, and is connected to the inner side surface of the side sill 3 in the left-right direction at the left-right outer end.

As shown in FIG. 3, bulkheads 11 are provided at the front ends of the left and right front side frame front portions 4A. The bulkhead 11 includes a pair of left and right bulkhead side members 11A extending vertically, a bulkhead upper member 11B extending left and right to connect the upper ends of the left and right bulkhead side members 11A, and left and right bulkheads extending left and right. It has a bulkhead lower member 11C that connects the lower ends of the side members 11A, and is formed in a quadrangular frame shape. The front end of the front side frame front portion 4A is coupled to the vertical intermediate portion of the rear surface of the bulkhead side member 11A.

The left and right bulkhead side members 11A are coupled with front bumper beams 13 extending to the left and right via a pair of left and right front crash boxes 12 as shock absorbers. Each front crash box 12 is formed in a tubular shape extending in the front-rear direction, is coupled to the intermediate portion of the bulkhead side member 11A in the vertical direction at the rear end, and is coupled to the rear side surface of the front bumper beam 13 at the front end. 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 deforms before the front side frame 4 and the like when a load at the time of a front collision is applied. Absorbs shock.

A front upper member 15 that extends forward and then extends forward and downward is provided on the upper portion of each front pillar 8. The left and right front upper members 15 are arranged outside and above 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 connecting member 16 extending to the left and right. A front damper housing 17 is provided between the front side frame front portion 4A corresponding to the left and right sides and the front upper member 15. The front damper housing 17 extends upward from the rear portion of the front side frame front portion 4A to the vertical wall portion 17A and extends outward from the upper end of the vertical wall portion 17A to the left and right outer ends, and is coupled to the front upper member 15 at the left and right outer ends. It has a wall portion 17B.

As shown in FIG. 4, the left and right front side frame intermediate portions 4B are each provided with lateral extension portions 4D extending inward to the left and right. The left and right inner ends of the left and right lateral extension portions 4D face each other with a gap in the left and right direction. The left and right outer ends of the left and right lateral extension portions 4D are connected to the inner side surface of the front side frame intermediate portion 4B. The lateral extension portion 4D has a hat-shaped cross section that opens upward, and forms a closed cross-section structure in cooperation with the floor panel. The lateral extension portion 4D constitutes a part of the front side frame 4.

As shown in FIGS. 4 and 7, guide members 19 are provided at the left and right inner ends of the left and right lateral extension portions 4D. The guide member 19 extends rearward from the lower surface of the left and right inner ends of the lateral extension portion 4D. The guide member 19 has an inclined surface 19A inclined downward toward the rear in the lower front portion thereof. The lateral extension portion 4D and the guide member 19 form 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 to which the rear end of the front subframe 6 is fastened.

As shown in FIGS. 4 and 5, the front subframe 6 has a pair of left and right front vertical members 23 extending forward and backward, and a front cross member 24 extending left and right and connected to each of the front vertical members 23. The left and right front vertical members 23 are inclined inward to the left and right so that they are closer to each other toward the rear. Further, the left and right outer edges of the front vertical member 23 are curved so that the central portion in the front-rear direction is recessed inward in the left-right direction.

The left and right ends of the front cross member 24 are connected to an intermediate portion of the front vertical member 23 in the front-rear direction. The left and right ends of the front cross member 24 are connected slightly forward of the center of the front vertical member 23 in the front-rear direction. The front vertical member 23 and the front cross member 24 each have a cross section having a closed cross section 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 trailing edge of the front cross member 24 is inclined rearward toward the left and right outward at the left and right ends. That is, the front-rear width of the front cross member 24 gradually increases toward the left and right outwards.

Behind the front cross member 24, a brace 26 extending left and right and connecting the left and right front vertical members 23 is provided. The brace 26 has an X-shape in a plan view and extends from the central portion to the front left, the front right, the rear left, and the rear right. It is connected to the left and right ends of the front cross member 24 at the left and right ends on the front side, and is connected to the left and right front vertical members 23 at the left and right ends on the rear side. The brace 26 is preferably formed of a steel plate whose surface faces up and down.

As shown in FIG. 4, the front end of each front vertical member 23 is arranged so as to be offset downward and left and right inward of the corresponding front side frame front portion 4A on the left and right. More specifically, in a plan view, the left and right outer portions of the front end of the front vertical member 23 are arranged at positions that overlap with the left and right inner portions of the front end of the front side frame front portion 4A. The front vertical member 23 has a front end mounting portion 23A attached to the front side frame 4 at the front end portion. The front end mounting portion 23A is provided on the left and right outer portions of the front end of the front vertical member 23. The front end mounting portion 23A of each front vertical member 23 and the front end of the front side frame front portion 4A corresponding to each other on the left and right are connected to each other by a front connecting member 28 extending vertically. Specifically, the front vertical member 23 is fastened to the lower end of the front connecting member by a bolt penetrating from below. The front connecting member 28 constitutes a front end support portion that supports the front end of the front subframe 6. In the present embodiment, the front end mounting portion 23A is indirectly attached to the front side frame front portion 4A via the front connecting member 28. In another embodiment, the front end mounting portion 23A may be indirectly mounted to the front side frame front portion 4A via the front connecting member 28.

The rear ends of each front vertical member 23 are arranged below the corresponding lateral extension portions 4D on the left and right sides. That is, the rear ends of the front vertical member 23 are arranged inward on the left and right sides of the corresponding front side frame intermediate portion 4B on the left and right sides. As shown in FIG. 7, a collar 29A penetrating vertically is provided at the rear end of the front vertical member 23. The rear end of the front vertical member 23 is fastened to the lower surface of the lateral extension portion 4D by a bolt 29B that penetrates the collar 29A from below and is screwed into the nut 29C coupled to the lateral extension portion 4D. The rear end of the front vertical member 23 protrudes rearward from the lateral extension portion 4D, and the trailing edge extends to the left and right. Further, the vertical width (vertical thickness) of the rear end of the front vertical member 23 gradually decreases toward the rear.

The rear end of the front vertical member 23 faces the inclined surface 19A of the guide member 19 with a gap in the front-rear direction. Further, in a plan view, the rear end of the front vertical member 23 is arranged at a position overlapping with the inclined surface 19A of the guide member 19.

As shown in FIG. 4, the lower surface of the rear end of the front vertical member 23 is connected to the lower surface of the front side frame intermediate portion 4B by a plate piece-shaped connecting member 27. When a predetermined load is applied, the connecting member 27 is deformed to release the connection between the front vertical member 23 and the front side frame intermediate portion 4B.

As shown in FIGS. 1 and 8, the front subframe 6 and the left and right front side frames 4 are provided with a pair of left and right front suspensions 30. The front suspension 30 includes a pair of left and right lower arms 31 swayably supported by the left and right front vertical members 23, a pair of left and right front knuckles 32 supported by each of the lower arms 31, and an upper portion of each front knuckle 32. And a front shock absorber 33 for connecting the upper wall portion 17B of the front damper housing 17 corresponding to the left and right sides.

The lower arm 31 is a so-called A arm, and has an arm rear portion 31A extending outward from the rear end and inclined forward, an arm bending portion 31B curved from the front end of the arm rear portion 31A to the left and right outward, and an arm bending portion. It has an arm front portion 31C extending outward from the left and right outer ends of 31B and supporting the front knuckle 32 at the tip. The arm front portion 31C is formed to be wider than each of the arm rear portion 31A and the arm bending portion 31B. Front shaft support portions 31D projecting inward to the left and right are provided on the left and right inner surfaces of the arm curved portion 31B. The front shaft branch 31D has an axis extending back and forth. At the rear end of the rear portion 31A of the arm, a rear shaft support portion 31E having an axial line extending vertically is provided.

As shown in FIG. 4, each of the left and right front vertical members 23 has a front lower arm support 36 that supports the front shaft support 31D of the lower arm 31, and a rear lower arm support 51 that supports the rear shaft support 31E of the lower arm 31. And are provided.

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

As shown in FIG. 5, the front lower arm support portion 36 extends to the left and right above the front vertical member 23, and is coupled to the front vertical member 23 and the front cross member 24, and the base portion 36A and the front vertical member. It has a front support wall 36B and a rear support wall 36C which are connected to 23 and project outward from the left and right outer surfaces of the front vertical member 23.

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

The left and right outer ends of the base portion 36A are coupled to the lower surface of the front side frame front portion 4A via the bracket 39. The bracket 39 has an upper plate portion fastened to the lower surface of the front side frame front portion 4A by bolts extending vertically, and a vertical plate portion hanging from the left and right inner ends of the upper plate portion. The vertical plate portion of the bracket 39 is in contact with the left and right outer end faces 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 to the left and right.

The upper portion of the base portion 36A forms an uphill connecting portion 36D from the left and right inner ends to the left and right outer ends. That is, the connecting portion 36D is inclined and extends 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-shaped members whose surfaces face forward and backward, and are welded to the left and right outer sides of the front vertical member 23 at their left and right inner edges. The rear support wall 36C is arranged with a gap behind the front support wall 36B. The upper portions of the left and right inner edges of the front support wall 36B extend above the front vertical member 23 and are welded to the front surface of the base portion 36A. The upper portions of the left and right inner edges of the rear support wall 36C extend above the front vertical member 23 and are welded to the rear surface of the base portion 36A. The lower portions of the left and right inner edges of the front support wall 36B and the rear support wall 36C extend below the front vertical member 23 and are welded to the lower surface of the front vertical member 23.

As shown in FIG. 8, the front axle support 31D of the lower arm 31 is arranged between the front support wall 36B and the rear support wall 36C. A rubber bush (not shown) is attached to the front shaft support 31D of the lower arm 31, and a support shaft (not shown) extending forward and backward through the rubber bush is provided on 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 supports the front shaft support portion 31D of the lower arm 31 so as to be swingable. The front lower arm support portion 36 is welded to the front vertical 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, the front support wall 36B forming the front end of the front lower arm support portion 36 is arranged in front of the rear ends of the left and right ends of the front cross member 24, and is behind the front lower arm support portion 36. The rear support wall 36C forming the end is preferably arranged behind the front end of the front cross member 24. That is, it is preferable that the front lower arm support portion 36 has an overlap with the front cross member 24 in the left-right direction. In the present embodiment, the front support wall 36B (front end of the front lower arm support 36) is arranged behind the front end of the front cross member 24, and the rear support wall 36C (rear front end of the front lower arm support 36) is the front cross member. It is arranged in front of the rear end of 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 tubular rack housing 41 extending to the left and right. Inside the rack housing 41, a rack shaft 42 is provided so as to be slidable to the left and right with respect to the rack housing 41. The left and right ends of the rack shaft 42 project left and right from the rack housing 41, and are connected to the left and right front knuckles 32 via a tie rod 43. The rack shaft 42 and the tie rod 43 are connected by, for example, a joint portion 44 which is a ball joint. The left and right joint portions 44 are arranged inside the boots 45 attached to the left and right ends of the rack housing 41, respectively.

The front cross member 24 is provided at four locations: the left and right ends of the front portion of the front cross member 24, and the left and right inner ends of the base portion 36A of the rear left and right front lower arm support portions 36. A collar 47 is provided which penetrates vertically and is welded to the upper wall and the lower wall of the front cross member 24. The two collars 47 on the rear side are arranged inward on the left and right with respect to the two collars 47 on the front side.

The left and right ends on the front side of the rack housing 41 are fastened to the left and right front collars 47 provided on the front cross member 24 with bolts. The rear portion of the rack housing 41 is bolted to one of the left and right rear collars 47 provided on the front cross member 24. The shape of the rack housing 41 differs depending on the left and right positions of the steering shaft. Depending on the shape of the rack housing 41, the rear collar 47 for fastening the rack housing 41 is selected. In this way, the rack housing 41 is fastened to the front cross member 24 at three places.

The front ends of the left and right front lower arm support portions 36 are arranged behind the front ends of the front cross member 24. The left and right inner ends of the connecting portion 36D of the base portion 36A are arranged on the left and right outer sides (sideways) of the upper end of the collar.

The rear lower arm support portion 51 is provided between the front lower arm support portion 36 and the rear end portion fastened to the lateral extension portion 4D in the front vertical member 23. The rear lower arm support portion 51 is provided at the rear side of the opening 51A formed on the left and right outer surfaces of the front vertical member 23 and the opening 51A, and extends vertically and is connected to the upper wall and the lower wall of the front vertical member 23. It has a support shaft (not shown). A rubber bush (not shown) through which a support shaft is inserted is attached to the rear shaft branch 31E of the lower arm 31. The rear axle branch 31E of the lower arm 31 is displaced with respect to the rear lower arm support 51 due to the deformation of the rubber bush. The lower arm 31 is swingably supported by the front subframe 6 by the front lower arm support portion 36 and the rear lower arm support portion 51.

As shown in FIG. 4, in the bottom view (plan view), the left rear lower arm support portion 51 is arranged on an extension line extending the left rear end portion of the brace 26. Further, in a plan view, the right rear lower arm support portion 51 is arranged on an extension line extending the right rear end portion of the brace 26. The rear lower arm support portion 51 is arranged inward in the left-right direction with respect to the front lower arm support portion 36. Further, the left and right rear lower arm support portions 51 are arranged on the left and right inward sides of the left and right joint portions 44.

The front lower arm support portion 36 is arranged behind the steering gear box 40. The arm front portion 31C may be slightly inclined rearward toward the left and right outwards, and the joint portion 44 at the neutral position O1 may be arranged on an extension line obtained by extrapolating the arm front portion 31C in the longitudinal direction.

As shown in FIGS. 5 and 6, each of the front vertical members 23 has a deformation promoting portion 53 having a lower rigidity than the other parts of the front vertical member 23 on the front side of the joint portion with the front cross member 24. .. The deformation promoting portion 53 is a recess recessed downward in the upper surface of the front vertical member 23. The deformation promoting portion 53 extends from the left and right inner side surfaces of the front vertical member 23 to the left and right outer surfaces. When a collision load is applied to the front vertical member 23 from the front and back, the front vertical member 23 first deforms at the deformation promoting portion 53 and bends downward starting from the deformation promoting portion 53.

Reinforcing plates 54 are coupled along the upper surface to the front side of the deformation promoting portion 53 on the upper surface of each front vertical member 23. 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, and has a laterally extending portion extending to the left and right and left and right ends extending rearward from both left and right ends of the laterally extending portion, and the left and right ends are left and right via a connecting member. It is coupled to the lower end of the front shock absorber 33. The front stabilizer support portion 56 has a support hole (not shown) through which the laterally extending portion of the stabilizer passes. A rubber bush for supporting the laterally extending portion of the stabilizer is installed in the support hole. The front stabilizer support portion 56 is fastened to the upper surface of the front vertical member 23 by a plurality of bolts. In the front vertical member 23, the portion provided with the reinforcing plate 54 and the front stabilizer support portion 56 has higher rigidity than the other portions.

The effects of the above-described embodiments will be described below. In the front subframe 6 according to the present embodiment, since the front lower arm support portion 36 is arranged in the portion where the rigidity is increased by the front cross member 24, the front vertical member 23 has the deformation promoting portion 53, or the front Even in a mode in which the vertical member 23 has a curved shape in order to widen the steering space of the front wheels 5, the front subframe 6 is less likely to be deformed by the lateral force applied from the lower arm 31. As a result, riding comfort and running performance can be improved. Further, the front vertical member 23 can be curved inward to the left and right, and a large space for steering the front wheel 5 can be secured on the left and right outside of the front subframe 6, and the steering angle of the front wheel 5 can be adjusted. Can be made larger.

By providing the front lower arm support portion 36 at a portion that overlaps the front cross member 24 in the left-right direction, the front subframe 6 can be made more difficult to be deformed by a lateral force applied from the lower arm 31.

By connecting the front lower arm support portion 36 to the front vertical member 23 and the front cross member 24, the rigidity of the front lower arm support portion 36 is further improved. As a result, the front subframe 6 can reliably support the lower arm 31. Further, in the front vertical member 23, the rigidity difference between the deformation promoting portion 53 and the portion provided with the front cross member 24 and the front lower arm supporting portion 36 behind the deformation promoting portion 53 becomes large, so that the front vertical member 23 has a large rigidity difference. The deformation promoting portion 53 can be reliably deformed at the time of a forward collision.

Since the front lower arm support portion 36 is coupled to the front side frame 4, 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 connecting portion 36D can efficiently transmit the load from the front vertical member 23 and the front cross member 24 to the front side frame 4. Since the end portion of the connecting portion 36D is provided at the portion of the front cross member 24 whose rigidity is improved 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 improved by the steering gear box 40.

The brace 26 improves the rigidity of the front subframe 6. Similarly, the front stabilizer 55 improves the rigidity of the front subframe 6. As a result, the front subframe 6 can be made difficult to be deformed by the lateral force applied from the lower arm 31.

At the time of a forward collision, the front crash box 12 first deforms to absorb the load, so that it is possible to suppress the deformation of the deformation promoting portion 53 when the collision load is small. As a result, replacement of the front subframe 6 can be avoided.

Although the description of the specific embodiment is completed above, the present invention can be widely modified without being limited to the above embodiment.

1: Body structure 3: Side sill 4: Front side frame 6: Front subframe 23: Front vertical member 24: Front cross member 26: Brace 31: Lower arm 36: Front lower arm support 40: Steering gear box 44: Joint 51: Rear lower arm support 53: Deformation promotion 55: Front stabilizer 56: Front stabilizer support

Claims (10)

The front subframe attached to the front of the vehicle and
It has a pair of left and right lower arms of the suspension that are swingably supported by the front subframe.
The front sub-frame, a pair of left and right vertical members extending in the longitudinal, cross member attached to the longitudinal members of the left and right extending to the right and left, provided on the longitudinal member and the Kurosumen bar, swingable lower arm Has at least one lower arm support for supporting the
Each of the vertical members has a deformation promoting portion having a lower rigidity than the other portions of the vertical member on the front side of the joint portion with the cross member.
Reinforcing plates are coupled along the upper surface on the upper surface of each of the vertical members in front of the deformation promoting portion, and each of the reinforcing plates is provided with a stabilizer support portion that rotatably supports the stabilizer. ,
The rear end of the front lower arm support portion arranged on the frontmost side of the lower arm support portion is arranged behind the front end of the cross member, and the front end of the front lower arm support portion is from the rear end of the cross member. The front structure of the car body is characterized by being placed in front of the car. The vehicle body front structure according to claim 1, wherein the front lower arm support portion is coupled to the vertical member and the cross member. The vehicle body front structure according to claim 2, wherein the front lower arm support portion is coupled to the left and right outer surfaces and the upper surface of the vertical member and the upper surface of the cross member. It has a pair of left and right front side frames that extend the front of the vehicle back and forth.
The vehicle body front structure according to claim 2 or 3, wherein the front lower arm support portion extends from the vertical member and is attached to the front side frame. The vehicle body front structure according to claim 4, wherein the front lower arm support portion has a connecting portion extending outward and upward from the cross member toward the front side frame. The cross member is provided with a collar that penetrates the cross member up and down and is coupled to the upper surface and the lower surface of the cross member.
A steering gear box is attached to the collar.
The vehicle body front structure according to claim 5, wherein the inner end of the connecting portion in the left-right direction is arranged on the side of the upper end of the collar. The vehicle body front structure according to claim 6, wherein the steering gear box extends to the left and right and is coupled to the upper surface of the cross member at a plurality of positions in the left and right directions. The vehicle body front structure according to any one of claims 1 to 7, wherein the deformation promoting portion is a recess recessed downward in the upper surface of the vertical member. The vehicle body front structure according to any one of claims 1 to 8, wherein the left and right outer edges of the vertical member are curved so that the central portion in the front-rear direction is recessed inward in the left-right direction. .. The front side frame has a front mounting portion to which a portion of the vertical member on the front side of the deformation promoting portion is mounted.
The vehicle body front structure according to any one of claims 4 to 7, wherein a shock absorbing structure is provided on the front side of the front side frame from the front mounting portion.

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