JP5653969B2 - Suspension device - Google Patents

Description

  The present invention relates to a suspension device that supports a rear wheel of an automobile, and more particularly, to a suspension device that includes a swing arm made of a plate material.

  In a rear suspension device for an automobile, a swing arm (trailing arm) that extends in the front-rear direction of the vehicle body, is supported by the vehicle body at the front end so as to be swingable (turnable), and has an axle support portion at the rear end, and a vehicle First and second extending in the width direction and supported to be swingable (turnable) by the vehicle body at the inner end of the vehicle and supported to be swingable (turnable) by the swing arm at the outer end of the vehicle. A suspension device having a lower arm and an upper arm (link member), and a compression coil spring and a damper (shock absorber) interposed between the swing arm and the vehicle body are known. There exists what formed the swing arm of such a suspension apparatus from the press-formed steel plate (for example, patent document 1). In the swing arm according to Patent Document 1, a plurality of press-formed steel plates are joined to each other by welding to form a closed cross-sectional structure to increase rigidity. In addition, a cylindrical collar is interposed in the internal space of the closed cross-sectional structure of the swing arm, bolts are inserted through the panels and the collar, and the members are fastened together.

JP 2002-187416 A

  Since the suspension device needs to support the wheels at a predetermined toe angle and camber angle, the swing arm has rigidity against torsion in the camber angle direction and torsion in the toe angle direction (that is, camber rigidity and toe rigidity). Required. In the swing arm according to Patent Document 1, a collar is interposed between the inner panel and the outer panel, but the collar only extends parallel to the axis of the axle, and the camber rigidity and toe rigidity are sufficient. It's hard to say.

  The present invention has been made in view of the above background, and an object of the present invention is to increase the rigidity of a swing arm in a suspension device including a swing arm made of a plate material.

In order to solve the above problems, the present invention includes an axle support portion (14, 25) that extends in the front-rear direction, is swingably supported by the vehicle body at the front end portion, and supports the axle at the rear end portion. A swing arm (3), an upper link member (4) for connecting the upper support part (29) provided at the upper part of the swing arm and the vehicle body, and a lower support part (provided at the lower part of the swing arm) 17) and a suspension device (1) having a lower link member (5) for connecting the vehicle body, wherein the swing arm is disposed outside the inner panel (11) and the inner panel in the vehicle width direction. An outer panel (12) coupled to the inner panel so as to form an inner space (38) through which the axle axis (A) passes between the inner panel and the inner panel; width Wherein a plurality of spacers abutting the inner panel and the outer panel (40, 41) in countercurrent, the spacer, between the front of the axis of the axle, and the previous SL on the support portion and the lower support portion A first spacer (40) disposed and extending substantially parallel to a virtual line (C) connecting the upper support portion and the lower support portion, and disposed rearward of the axis of the axle, the axis of the axle And a second spacer (41) connected to the first spacer by a front / rear extending portion (91) extending in the front / rear direction through the upper side or the lower side . The spacer includes a pair of cylindrical portions arranged in parallel to each other, and an extending portion that couples the pair of cylindrical portions in the radial direction, and each of the cylindrical portions is connected to the inner panel and the outer panel. Bolts are inserted, and the extending portion is disposed between the upper support portion and the lower support portion, and extends substantially parallel to an imaginary line connecting the upper support portion and the lower support portion. . In the invention described above, one of the tube portions may be disposed above the axis of the axle, and the other one of the tube portions may be disposed below the axis of the axle.

According to this configuration, the camber rigidity of the swing arm is increased by the extending portion of the spacer. Moreover, the rigidity of the swing arm can be increased by providing a plurality of spacers as reinforcing members. In addition, the toe rigidity of the swing arm is increased by the front / rear extending portion in which the spacer extends in the front / rear direction.

  In the above invention, in the cross section viewed from above, the inner panel and the outer panel are coupled to each other in front of the spacer, and the triangular closed cross-section structure (85) is formed by the spacer, the inner panel, and the outer panel. May be formed.

  According to this configuration, the toe rigidity of the swing arm is enhanced by the closed cross-sectional structure that is triangular when viewed from above.

  In the above invention, at least one of the inner panel and the outer panel is a part that defines the internal space and is a through hole in a part that is positioned forward of the spacer. It is characterized by having.

  According to this configuration, the inner panel or the outer panel is formed by the notch portion so that the rigidity of the inner panel, the outer panel, and the spacer is different between the inner panel, the outer panel, and the spacer. It is possible to prevent stress concentration from occurring at the joint.

  According to the above configuration, the rigidity of the swing arm can be increased in the suspension device including the swing arm made of a plate material.

A perspective view of a rear suspension according to an embodiment The side view which looked at the rear suspension which concerns on embodiment from the vehicle inside The exploded perspective view of the swing arm concerning an embodiment The side view which expanded the swing arm which concerns on embodiment and was seen from the vehicle outer side VV sectional view of FIG. VI-VI sectional view of FIG. The side view which expanded the swing arm which concerns on some deformation | transformation embodiment, and was seen from the vehicle outer side

  Hereinafter, an embodiment in which the present invention is applied to a rear suspension of an automobile will be described in detail with reference to the drawings. The suspension 1 according to the present embodiment is a double wishbone type rear suspension that is an independent suspension type, and supports the left rear wheel 2. In the following description, as shown in FIG. 1, the front-rear, left-right, and up-down directions are defined with reference to the vehicle.

  As shown in FIG. 1, the suspension 1 includes a swing arm (trailing arm) 3, an upper arm (upper link member) 4, a first lower arm (first lower link member) 5, and a second lower arm (second lower arm). A link member 6, a spring 7, and a damper 8. The swing arm 3 is provided with a hub support member (axle support member) 10 (see FIG. 5) that rotatably supports the hub 9 coupled to the wheel 2.

  As shown in FIGS. 1 to 3, the swing arm 3 is a member extending in the front-rear direction, and is formed by connecting an inner panel 11 and an outer panel 12 that are press-formed steel plates to each other. The inner panel 11 extends substantially in the front-rear direction while the main surface faces in the left-right direction and has a width in the up-down direction. The inner panel 11 has an arm part 13 having a certain width in the up-down direction and extending in the front-rear direction, and an axle support part 14 continuous with the rear end of the arm part 13. As shown in FIG. 6, the arm portion 13 is inclined with respect to the front-rear direction so as to go rearward (leftward) toward the rear, and the axle support portion 14 extends in the front-rear direction. In the inner panel 11, the axle support portion 14 is wider in the vertical direction than the arm portion 13. The inner panel 11 is formed in a convex shape so that an intermediate portion in the vertical direction of the arm portion 13 and the axle support portion 14 bulges to the outside of the vehicle, and has increased rigidity. Further, in the arm portion 13, a protrusion that protrudes further toward the vehicle interior and extends in the front-rear direction is formed at an intermediate portion in the vertical direction, and rigidity is increased.

  The rear edge of the inner panel 11 is bent at a substantially right angle toward the vehicle inner side (right side) to form an inner side rear edge wall 15 whose surface faces in the front-rear direction. An inner side second lower arm support portion 17 provided with a support hole 16 penetrating in the thickness direction (front and rear) is formed at the lower end portion of the inner side rear edge wall 15. An inner side damper support that supports the damper 8 is provided with a support hole 18 penetrating in the thickness direction (front and rear) in a portion of the inner side rear edge wall 15 positioned above the inner side second lower arm support portion 17. A portion 19 is formed.

  An upper notch 20 cut downward is formed at the upper edge of the rear end of the inner panel 11. Further, a lower notch 21 cut upward is formed at the lower edge of the rear end portion of the inner panel 11. The edges of the upper notch portion 20 and the lower notch portion 21 are bent up toward the vehicle interior to increase the rigidity.

  A bush fitting hole 22 that is a circular hole penetrating in the thickness direction (left-right direction) is formed in the front end portion of the inner panel 11. A boss that protrudes toward the inside of the vehicle is formed at the periphery of the bush fitting hole 22, and the bush fitting hole 22 has a predetermined axial length. A bush 23 is fitted in the bush fitting hole 22. The bush 23 has an outer cylinder and an inner cylinder arranged concentrically, and an elastic body that is a cylindrical rubber interposed between the outer cylinder and the inner cylinder, and the outer cylinder is a bush fitting hole 22. Is fitted. A shaft 24 is inserted through the inner cylinder. The shaft 24 is supported by a bracket coupled to the vehicle body (rear frame). Thus, the inner panel 11 is supported so as to be swingable with respect to the vehicle body via the bush 23.

  As shown in FIG. 3, the outer panel 12 is a member joined to the vehicle outer side of the inner panel 11, and includes a central wall 25 having a surface facing substantially in the left-right direction, and an inner side from the upper and lower edges of the central wall 25 An upper edge wall 26 and a lower edge wall 27 that extend (to the right), and an inclined wall 28 that is inclined forward and inward from the front edge of the central wall 25. An upper arm support portion 29 for supporting one end of the upper arm 4 is formed on the upper edge wall 26. The upper arm support portion 29 has a pair of wall portions facing each other in the front-rear direction and having a substantially U-shaped cross section as viewed from the top and bottom. Each of the pair of wall portions of the upper arm support portion 29 is formed with a support hole 31 that penetrates in the thickness direction (front and rear) and is coaxial with each other. The upper edge wall 26 has an upper joint flange 33 bent and raised substantially at a right angle at an inner edge including the upper arm support portion 29.

  A first lower arm support portion 35 for supporting one end of the first lower arm 5 is formed on the lower edge wall 27. The first lower arm support portion 35 has a pair of wall portions that face each other in the front-rear direction and are opposed to each other. Each of the pair of wall portions of the first lower arm support portion 35 is formed with a support hole 36 that penetrates in the thickness direction (front and rear) and is coaxial with each other. The first lower arm support portion 35 is provided below the upper arm support portion 29. The lower edge wall 27 has a lower joint flange 37 bent and raised substantially at a right angle at an inner edge portion including the first lower arm support portion 35.

  The outer panel 12 is joined to the inner panel 11 by being welded to the vehicle outer surface of the axle support portion 14 of the inner panel 11 at the front edges of the upper joint flange 33, the lower joint flange 37, and the inclined wall 28. In a state where the inner panel 11 and the outer panel 12 are coupled to each other, the axle support portion 14 of the inner panel 11 and the central wall 25 of the outer panel 12 each extend in parallel in the front-rear direction, and an internal space therebetween. 38 is defined. Although details will be described later, a pair of spacers 40 and 41 are interposed between the axle support portion 14 and the central wall 25.

  The rear end portion of the central wall 25 of the outer panel 12 extends rearward from the rear edge of the axle support portion 14. The rear edge of the central wall 25 of the outer panel 12 is bent at a substantially right angle toward the vehicle inner side (right side) to form an outer side rear edge wall 42 whose surface faces in the front-rear direction. The outer side rear edge wall 42 is disposed at a predetermined distance behind the inner side rear edge wall 15, and the outer side rear edge wall 42 and the inner side rear edge wall 15 are disposed substantially parallel to each other.

  A lower end portion of the outer side rear edge wall 42 and a portion facing the inner side second lower arm support portion 17 penetrates in the thickness direction and is coaxial with the support hole 16 of the inner side second lower arm support portion 17. A support hole 45 is provided, and an outer side second lower arm support portion 44 is formed. A portion of the outer side rear edge wall 42 located above the outer side second lower arm support portion 44 and facing the inner side damper support portion 19 penetrates in the thickness direction, and the inner side damper support portion. A support hole 47 that is coaxial with the 19 support holes 18 is provided, and an outer side damper support portion 46 that supports the damper 8 is formed.

  As shown in FIG. 2, the upper arm support portion 29 of the outer panel 12 is disposed at a position corresponding to the upper cutout portion 20 of the inner panel 11, and a pair of wall portions constituting the upper arm support portion 29 are arranged at the upper cutout at the side end portions. It is welded to the edge of the part 20. As a result, the end of the upper arm 4 can pass through the upper notch 20 and enter the upper arm support 29. The first lower arm support portion 35 of the outer panel 12 is disposed at a position corresponding to the lower notch portion 21 of the inner panel 11, and a pair of wall portions constituting the first lower arm support portion 35 are lower notch portions at the side end portions. It is welded to the edge of 21. An end portion of the upper arm 4 can pass through the lower notch portion 21 and enter the first lower arm support portion 35.

  As shown in FIGS. 3 and 4, the central portion of the central wall 25 of the outer panel 12 is a circular hole centering on the axis A of the axle (hub 9) of the wheel 2, and a hub insertion hole that penetrates in the thickness direction. 51 is formed. Further, a rear axle insertion hole 52 penetrating in the thickness direction is formed in a portion of the inner panel 11 facing the hub insertion hole 51 and through which the axis A passes. The rear axle insertion hole 52 is smaller than the hub insertion hole 51 and has a substantially triangular shape.

  The central wall 25 of the outer panel 12 has a first hole 54, a second hole 55, a third hole 56, and a fourth hole 57, which are circular holes penetrating in the thickness direction, around the hub insertion hole 51, that is, around the axis A. Is formed. The first hole 54 is formed in a portion located in front of the hub insertion hole 51 and above the axis A, and the second hole 55 is a portion located in front of the hub insertion hole 51 and below the axis A. The third hole 56 is formed in a portion located behind the hub insertion hole 51 and above the axis A, and the fourth hole 57 is located behind the hub insertion hole 51 and below the axis A. It is formed in the part located in. The first to fourth holes 54 to 57 have the same diameter.

  As shown in FIG. 4, the first hole 54 and the second hole 55 are disposed between the upper arm support portion 29 and the first lower arm support portion 35. The imaginary line B connecting the centers of the first hole 54 and the second hole 55 is substantially parallel to the imaginary line C connecting the centers of the upper arm support part 29 and the first lower arm support part 35, and extends substantially vertically. Exist. The third hole 56 is disposed behind the fourth hole 57 and the imaginary line D connecting the centers of the third hole 56 and the fourth hole 57 is inclined backward with respect to the imaginary line C. ing. In the present embodiment, the distance between the centers of the first hole 54 and the second hole 55 and the distance between the centers of the third hole 56 and the fourth hole 57 are set to be equal. Therefore, since the virtual line D is inclined backward with respect to the virtual line C, the center distance L1 between the first hole 54 and the third hole 56 is changed to the center distance L2 between the second hole 55 and the fourth hole 57. Longer than. The inclined wall 28 of the outer panel 12 is formed with a first cutout portion 58 and a second cutout portion 59 that penetrate in the thickness direction. The 1st notch part 58 and the 2nd notch part 59 are formed in the long hole long at the front and back.

  As shown in FIG. 3, the inner panel 11 has a fifth hole 61 at a position corresponding to the first hole 54 in the vehicle width direction, a sixth hole 62, a third hole at a position corresponding to the second hole 55 in the vehicle width direction. A seventh hole 63 is provided at a position corresponding to the hole 56 in the vehicle width direction, and an eighth hole 64 is provided at a position corresponding to the fourth hole 57 in the vehicle width direction. Each of the fifth to eighth holes 61 to 64 is a circular hole penetrating in the thickness direction, and has the same diameter as the first hole 54. A third notch 65 penetrating in the thickness direction is formed in front of the sixth hole 62 of the axle support portion 14 of the inner panel 11. The 3rd notch part 65 is formed in the long hole long in the front-back direction.

  As shown in FIG. 3, each of the pair of spacers 40 and 41 has a pair of cylindrical portions 71 and 72 having both ends of the inner hole opened. The cylindrical portions 71 and 72 have a predetermined thickness in the radial direction, and have planar end surfaces orthogonal to the axis at both ends in the axial direction. The pair of cylindrical portions 71 and 72 are arranged such that their axis lines are parallel to each other and their end faces are arranged on the same plane, and extend linearly in the radial direction of the cylindrical portions 71 and 72. They are connected by an extension part (beam part) 73. In the present embodiment, the extending portion 73 is formed shorter than the cylindrical portions 71 and 72 in the axial direction of the cylindrical portion 71 and is not continuous with the end surfaces of the cylindrical portions 71 and 72. In another embodiment, the extending portion 73 may form an end surface that is flush with the end surfaces of the cylindrical portions 71 and 72.

  The first spacer 40 is arranged so that one cylindrical portion 71 is coaxial with the first hole 54 and the fifth hole 61, and the other cylindrical portion 72 is coaxial with the second hole 55 and the sixth hole 62. The extending portion 73 is disposed along the virtual line B. The second spacer 41 is arranged so that one cylindrical portion 71 is coaxial with the third hole 56 and the seventh hole 63, and the other cylindrical portion 72 is coaxial with the fourth hole 57 and the eighth hole 64. The extending portion 73 is disposed along the virtual line D. As shown in FIG. 6, the end surfaces of the cylindrical portions 71 and 72 in the axial direction are in contact with the vehicle outer surface of the axle support portion 14 or the vehicle inner surface of the central wall 25.

  As shown in FIG. 5, the drum brake 75 and the hub support member 10 are attached to the vehicle outer surface of the central wall 25 of the outer panel 12. The drum brake 75 has a disc shape and has a back plate 76 in which an annular peripheral wall is erected along the peripheral edge thereof. The back plate 76 is arranged so as to be coaxial with the axis A and so that the peripheral wall protrudes to the outside of the vehicle, and penetrates through the portion corresponding to the hub insertion hole 51 and the first to fourth holes 54 to 57 in the thickness direction. have. A known brake shoe 77 and a wheel cylinder (not shown) for driving the brake shoe 77 are supported inside the back plate 76 (portion facing the vehicle exterior).

  The hub support member 10 has a cylindrical shape with both ends opened, and is disposed coaxially with the axis A. The hub support member 10 has four coupling pieces 79 protruding radially on the outer peripheral surface. Each coupling piece 79 has a female screw hole 81 extending to a position corresponding to one of the first hole to the fourth hole 54 to 57 when viewed from the vehicle width direction and coaxial with the first hole 54 to the fourth hole 57. doing.

  The back plate 76 and the hub support member 10 are attached to the inner panel 11 and the outer panel 12 from the inner side of the inner panel 11 to the fifth to eighth holes 61 to 64 of the inner panel 11 and the cylindrical portions 71 of the spacers 40 and 41. , 72, the first to fourth holes 54 to 57 of the outer panel 12, and the holes of the back plate 76 are inserted into the bolts 83 and screwed into the female screw holes 81 of the hub support member 10. Thus, the inner panel 11, the spacers 40 and 41, the outer panel 12 and the back plate 76 are sandwiched and fastened between the head of the bolt 83 and the coupling piece 79 of the hub support member 10.

  The hub 9 is supported inside the hub support member 10 so as to be rotatable around the axis A through a bearing (not shown). Bolts are fastened to the hub 9 so that the drum (not shown) of the drum brake 75 and the wheel 2 rotate together. The drum has a disk centered on the axis A and an annular peripheral wall standing on the periphery of the disk, and is disposed at a position where the brake shoe can contact the inner peripheral surface of the peripheral wall.

  The inner end of the hub 9 protrudes into an internal space 38 defined between the inner panel 11 and the outer panel 12 through the hub insertion hole 51 of the outer panel 12. The inner end portion of the hub 9 is freely connected to the outer end portion of the rear axle (not shown) that passes through the rear axle insertion hole 52 of the inner panel 11 and extends into the inner space 38, for example, a barfield joint or the like. It is connected via a joint. As a result, the hub 9 and the wheel 2 rotate by receiving a driving force from the rear axle.

  As shown in FIGS. 1 and 2, the upper arm support portion 29 supports an end portion on the vehicle outer side of the upper arm 4 that extends substantially in the vehicle width direction and passes through the upper notch portion 20. Specifically, a support shaft (not shown) is inserted into a support hole 31 formed in a pair of wall portions of the upper arm support portion 29, and the vehicle outer end portion of the upper arm 4 is pivotally supported by the support shaft via a bush. ing. The inner end of the upper arm 4 is pivotally supported by the vehicle body.

  As shown in FIGS. 1 and 2, the first lower arm support portion 35 supports an end portion on the vehicle outer side of the first lower arm 5 that extends substantially in the vehicle width direction and passes through the lower notch portion 21. . Specifically, a support shaft (not shown) is inserted into a support hole 36 formed in a pair of wall portions of the first lower arm support portion 35, and the vehicle outer side end portion of the first lower arm 5 is inserted into the support shaft via a bush. Is pivotally supported. The vehicle inner end portion of the first lower arm 5 is pivotally supported by the vehicle body.

  As shown in FIGS. 1 and 2, the second lower arm 6 is a member extending substantially in the vehicle width direction, the middle portion in the vehicle width direction is widened in the front-rear direction, and the seat portion on the lower end side of the spring 7 is formed. It is composed. The inner side second lower arm support portion 17 and the outer side second lower arm support portion 44 support the vehicle outer end portion of the second lower arm 6 in cooperation with each other. Specifically, a support shaft (not shown) is inserted into the support hole 16 of the inner side second lower arm support portion 17 and the support hole 45 of the outer side second lower arm support portion 44, and the support shaft (not shown) is inserted into the support shaft via a bush. The outer end of the lower arm 6 is pivotally supported. The inner end of the second lower arm 6 is pivotally supported by the vehicle body. A part of the vehicle body is disposed above the second lower arm 6, and a spring 7, which is a compression coil spring between the vehicle body and the second lower arm 6, is interposed, and the second lower arm 6 is biased downward with respect to the vehicle body. Has been.

  As shown in FIGS. 1 and 2, the inner side damper support portion 19 and the outer side damper support portion 46 cooperate to support the lower end portion of the damper 8. Specifically, a support shaft (not shown) is inserted into the support hole 18 of the inner side damper support portion 19 and the support hole 47 of the outer side damper support portion 46, and the lower end portion of the damper 8 is inserted into this support shaft via a bush. Is pivotally supported. The damper 8 may be a known de-carbon type shock absorber or the like, and its upper end is supported by the vehicle body.

  In the suspension 1 configured as described above, since the swing arm 3 is formed from the press-formed steel plate of the inner panel 11 and the outer panel 12, the weight can be reduced as compared with the case where it is formed by casting. A pair of spacers 40 and 41 are interposed between the inner panel 11 and the outer panel 12 to form an internal space 38 that forms a closed cross section between the inner panel 11 and the outer panel 12. Is three-dimensionally formed and has increased rigidity. Since the spacers 40 and 41 are arranged so that the cylindrical portions 71 and 72 contacting the inner panel 11 and the outer panel 12 surround the axis A of the wheel 2, the support rigidity of the swing arm 3 with respect to the hub 9 and the wheel 2 is increased. Has been enhanced.

  In particular, as shown in FIG. 4, one spacer 40 is disposed between the upper arm support portion 29 and the first lower arm support portion 35, and the extending portion 73 connects the upper arm support portion 29 and the first lower arm support portion 35. Since it extends substantially parallel to the connecting virtual line C, the rigidity (camber rigidity) of the swing arm 3 against twisting in the camber angle direction is enhanced. Further, as shown in FIG. 6, by welding the inner panel 11 and the front edge of the inclined wall 28 of the outer panel 12, one spacer 40, the inner panel 11, The inclined wall 28 forms a closed sectional structure 85 having a triangular shape as viewed from above. The closed cross-section structure 85 enhances the rigidity (torque rigidity) of the swing arm 3 against twisting in the toe angle direction.

  Further, the first notch portion 58 and the second notch portion 59 are provided in the inclined wall 28 of the outer panel 12, and the third notch portion 65 is provided in the axle support portion 14 of the inner panel 11, so that the outer panel 12 and the inner panel 11 are intentionally provided. The part with low rigidity was introduced. Therefore, even when there is a difference in rigidity among the members of the outer panel 12, the inner panel 11, and the spacers 40 and 41, the stress is distributed around the first notch 58, the second notch 59, and the third notch 65. In addition, the concentration of stress on the joint portion of each member can be reduced.

  FIG. 7 shows a partially modified embodiment obtained by modifying a part of the embodiment described above. As shown in FIG. 7, in the partially modified embodiment, the spacers 40 and 41 are connected to each other by a bridge 91. The bridge 91 extends in the front-rear direction above the axis A, is coupled to the first cylindrical portion 71 of the first spacer 40 at the front end, and is connected to the first cylindrical portion 71 of the second spacer 41 at the rear end. Is bound to. That is, the spacers 40 and 41 and the bridge 91 are integrally formed and have a U-shape that opens downward in a side view. In the present embodiment, the bridge 91 is formed such that an intermediate portion in the front-rear direction is thin in the vertical direction so as not to overlap with the hub insertion hole 51 in a side view. Thus, by providing the bridge 91 that connects the spacers 40 and 41 back and forth, the rigidity of the swing arm 3 against torsion in the toe angle direction can be increased.

  Instead of the bridge 91 that connects the cylindrical portions 71 and 71, a bridge 92 that extends in the front-rear direction below the axis A and connects the pair of cylindrical portions 72 and 72 (two points in FIG. 7). May be provided). Further, both the bridge 91 and the bridge 92 may be provided.

  Although the description of the specific embodiment is finished as described above, the present invention is not limited to the above embodiment and can be widely modified. For example, in this embodiment, the inner panel 11 is configured as a member extending in the front and rear direction including the arm portion 13 and the outer panel 12 is coupled to the rear portion of the inner panel 11. However, the outer panel 12 includes the arm portion 13. Alternatively, a member extending in the front-rear direction may be used, and the axle support portion 14 of the inner panel 11 may be coupled to the rear portion of the inner side surface of the outer panel 12. Further, when the vehicle is a front wheel drive vehicle and there is no rear axle, the hub insertion hole 51 and the rear axle insertion hole 52 may be omitted. Further, the upper arm support portion 29 and the first lower arm support portion 35 may be formed on the inner panel 11 instead of the outer panel 12. In addition, the spacers 40 and 41 may contact the inner panel 11 and the outer panel 12 not only at the end surfaces of the cylindrical portions 71 and 72 but also at the extending portion 73. The spacers 40 and 41 may be provided not only in two but also three or more.

  DESCRIPTION OF SYMBOLS 1 ... Suspension, 2 ... Wheel, 3 ... Swing arm, 4 ... Upper arm (upper link member), 5 ... 1st lower arm (lower link member), 6 ... 2nd lower arm (lower link member), 7 ... Spring, 8 ... Damper, 9 ... Hub, 10 ... Hub support member, 11 ... Inner panel, 12 ... Outer panel, 13 ... Arm part, 14 ... Axle support part, 15 ... Inner side rear edge wall, 17 ... Inner side second lower arm support part, DESCRIPTION OF SYMBOLS 19 ... Inner side damper support part, 20 ... Upper notch part, 21 ... Lower notch part, 25 ... Center wall, 26 ... Upper edge wall, 27 ... Lower edge wall, 28 ... Inclined wall, 29 ... Upper arm support part, 35 ... First lower arm support section, 38 ... inner space, 40 ... first spacer, 41 ... second spacer, 42 ... outer side rear edge wall, 44 ... outer side second lower arm support section, 46 ... outer side damper support section , 58 ... DESCRIPTION OF SYMBOLS 1 notch part, 59 ... 2nd notch part, 65 ... 3rd notch part, 71 ... Cylindrical part, 72 ... Cylindrical part, 73 ... Extension part, 83 ... Bolt, 91 ... Bridge (front-rear extension part), A ... Wheel Axis, BD ... Virtual line

Claims (5)

A swing arm that extends in the front-rear direction, is swingably supported by the vehicle body at the front end portion, and has an axle support portion that supports the axle at the rear end portion; and an upper support portion provided on an upper portion of the swing arm; A suspension device having an upper link member for connecting to the vehicle body, a lower support member provided at a lower portion of the swing arm, and a lower link member for connecting the vehicle body;
The swing arm is disposed outside the inner panel in the vehicle width direction of the inner panel, and is coupled to the inner panel so as to form an internal space through which the axis of the axle passes between the inner panel and the inner panel. An outer panel, and a plurality of spacers disposed in the inner space and in contact with the inner panel and the outer panel in the vehicle width direction,
The spacer is forward of the axis of the axle, and is disposed between the lower support portion and the front SL on the support portion, a first extending substantially parallel to the imaginary line connecting the said upper support portion and the lower support portion And a second spacer that is disposed rearward of the axle axis and is connected to the first spacer by a longitudinally extending portion that passes above or below the axle axis and extends in the front-rear direction. suspension device characterized in that it comprises and. In the cross section viewed from above, the inner panel and the outer panel are coupled to each other in front of the spacer, and a triangular closed cross-sectional structure is formed by the spacer, the inner panel, and the outer panel. The suspension device according to claim 1 . Wherein at least one of the inner panel and the outer panel, according to claim 1 or claims characterized in that it has a cutout portion is a through hole in a portion located further forward than the spacer a portion defining said internal space Item 3. The suspension device according to Item 2 . The spacer includes a pair of cylindrical portions arranged in parallel to each other, and an extending portion that couples the pair of cylindrical portions in the radial direction, and each of the cylindrical portions includes a bolt along with the inner panel and the outer panel. The suspension device according to any one of claims 1 to 3, wherein the suspension device is inserted. The one of the said cylinder parts is arrange | positioned upwards from the axis line of the said axle, The other one of the said cylinder parts is arrange | positioned below the axis line of the said axle shaft, The Claim 1 characterized by the above-mentioned. Suspension device.

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