JP5217963B2 - Front suspension device - Google Patents

Description

  The present invention relates to a so-called double joint type front suspension device that is used in a vehicle such as an automobile and in which an axle carrier that supports a wheel is joint-connected by two lower links.

As a conventional double joint type front suspension device, there is an axle carrier that rotatably supports a wheel, and an upper link that pivotably connects an upper portion of the axle carrier above the axle to the vehicle body side. And a lower arm to which the lower part below the axle of the axle carrier is pivotably connected to the vehicle body side and the lower end of the strut is connected to the front suspension device (for example, (See Patent Document 1).

However, in the conventional front suspension system, by adjusting the direction of the rubber bush used for the mounting part of the lower arm body, high lateral rigidity against the lateral force during vehicle turning and desirable king pin shaft However, it was not possible to make both of them compatible at a high level only by adjusting the rubber bush.
An object of the present invention is to provide a front suspension device that can achieve both high lateral rigidity with respect to lateral force, compliance steer during turning of the vehicle, and reduction in changes in the front-rear direction of the king pin shaft as viewed from the side of the vehicle. Is to provide.

In the front suspension device of the present invention, the lower part of the axle carrier and the vehicle body are connected by the first lower link and the second lower link disposed on the rear side in the vehicle front-rear direction with respect to the first lower link. Therefore, the connection of the outer end of the second lower link in the vehicle width direction to the axle carrier is positioned so as to overlap the axle in the longitudinal direction of the vehicle, and the axis of the second lower link becomes the center axis of rotation of the wheel. The connecting position for connecting to the axle carrier of the first lower link so that the angle formed toward the rear side of the vehicle is smaller than the angle formed by the axis of the first lower link with respect to the wheel rotation center axis. the higher than the connecting position of the axle carrier of the second lower link, and a lower position than the axis of rotation of the wheel, accession one link of the first lower link and the second lower link A coupling position for coupling to the Le carrier, is positioned inside in the vehicle width direction than the connecting position of the other link connecting to the axle carrier of the first lower link and the second lower link suspension King of The pin axis is located at an upper joint point determined by the upper arm, a lower intersection on the axis of the second lower link, and a height between the lower intersection and the upper joint point. These three points are determined so as to pass through an intermediate intersection on the axis of the first lower arm .

  In the front suspension device of the present invention, it is possible to reduce changes in the front-rear direction of the king pin shaft while ensuring both high lateral rigidity with respect to lateral force and compliance steer during vehicle turning.

  The front suspension apparatus of the present invention will be described below with reference to the drawings.

1 to 4 show a front suspension apparatus according to a first embodiment of the present invention.
FIG. 1 is a perspective view showing the arrangement of a front suspension apparatus according to a first embodiment and a steering system connected thereto. FIG. 2 shows a front suspension apparatus on the left side of the vehicle among the left and right front suspension apparatuses according to the first embodiment. FIG. 3 is a side view of the front suspension device of the first embodiment when viewed from the side, and FIG. 4 is a front view of the front suspension device of the first embodiment when viewed from the front.

  As shown in FIG. 1, the front suspension device 1 of the first embodiment is provided symmetrically on the left and right of the front portion of the vehicle. In FIG. 1, the stabilizer of the suspension device 1 is omitted for easy understanding. Although the detailed structure of these left and right front suspension devices will be described later, the axle carrier 10 which is one of these components is connected to the steering system 2 and can steer the left and right wheels 9. In other words, the steering system 2 engages a rack 6 extending in the vehicle width direction with a pinion 5 provided below a steering shaft 4 that is driven to rotate by a steering wheel 3 that is steered by a driver. It is possible to move left and right in the vehicle width direction according to the steering of the wheel 3. Rack ends 7 are provided at both ends of the rack 6, and ball joints 8 attached to the ends are connected to the knuckle arm portions 10 d of the axle carrier 10.

  On the other hand, as shown in FIGS. 2 to 4, the front suspension apparatus 1 includes an axle carrier 10 that rotatably supports the wheel 9, and a V-shaped upper / lower connecting the vehicle body 11 side and the axle carrier 10. An arm 12, a front lower link 13 connecting the vehicle body 11 and the axle carrier 10, a rear lower link 14 connecting the vehicle body 11 and the axle carrier 10, and a vehicle body 12 and a rear lower. A link 14, a strut 15 that connects the vehicle body 12 and the rear lower link 14, and a stabilizer 24 that connects the rear lower link 14 of the left and right suspension devices 1 are provided. Here, the front lower link 13 and the rear lower link 14 correspond to the first lower link and the second lower link of the present invention, respectively.

  The axle carrier 10 is also referred to as a knuckle arm, and a main body portion 10a that rotatably supports the axle 20 of the wheel 9 via a bearing (not shown), an upper portion 10b extending upward therefrom, and a lower portion from the main body portion 10a. And an extended lower portion 10c.

  As shown in FIGS. 2 to 4, the upper portion 10 b of the axle carrier 10 is bent from the middle so as to form a portion above the wheel 9, and the upper end portion of the axle carrier 10 extends outwardly in the vehicle width direction. Is extended toward a position on the vehicle rear side with respect to the rotation center axis O. As a result, the upper end portion of the upper portion 10b is positioned on the upper surface of the wheel 9 and at a position behind the rotation center axis O of the wheel 1 in the neutral position in the non-steered state. In addition, by bringing the upper portion 10b of the axle carrier 10 above the wheel 9 in this way, the king pin inclination angle in the vehicle front view can be reduced to improve the ground contact property of the tire. Shorten the distance between the pin axis K and the center point in the width direction of the wheel 9 to reduce the moment around the king pin axis, and increase the caster angle without increasing the caster trail, improving maneuverability and stability can do.

  On the other hand, the lower portion 10 c of the axle carrier 10 includes a rear side connecting portion 10 f for connecting the rear lower link 14 directly below the axle 20, the rear side connecting portion 10 f and the rotation center axis O of the wheel 9. A front-side connecting portion 10e for connecting the front-rear link 13 at a position in front of the rear-side connecting portion 10f at a height between the front-side link 13 and a front-side and lower-side from the front-rear link 13 A knuckle arm portion 10d connected to the rack end 7 of the steering system 2 is integrally formed at the side position. Accordingly, the lower portion 10c is connected to the front rear link 13, the rear lower link 14, and the rack end 7, respectively.

  The upper arm 12 is formed in a V shape and extends in the vehicle width direction, and an outer end portion 12a in the vehicle width direction, which is the tip of the upper arm 12, can swing on the upper end portion of the axle carrier 10 via a ball joint 17. The vehicle body 11 is swingable with respect to the vehicle body 11 in a state where the vehicle body 11 is separated in the vehicle front-rear direction as two parts of the vehicle-side front inner end portion 12b and the vehicle-side rear inner end portion 12c. Install.

  That is, the vehicle-side front inner end portion 12b and the vehicle-side rear inner end portion 12c of the upper arm 12 are positioned at the vehicle front position from the rotation center axis O of the wheel 9 in the vehicle top view. Further, the vehicle-side rear inner end portion 12c is connected to the vehicle body side 11 through the cylindrical bushes 16a and 16b so as to be swingable from the rotation center axis O of the wheel 9 to the vehicle rearward position. The cylindrical bushes 16a and 16b are arranged such that their central axes extend in the vehicle front-rear direction. Further, as shown in FIGS. 3 and 4, the swing center lines of the vehicle-side front inner end portion 12b and the vehicle-side rear inner end portion 12c are on the same line as shown in FIGS. It is tilted in the vehicle front-rear direction so as to be obliquely downward at a position higher than 10.

    Further, when the vehicle is on a horizontal road plane G, the vehicle-side front inner end portion 12b and the vehicle-side rear inner end portion 12c can swing on the vehicle body 11 at a position lower than the vehicle width direction outer end portion 12a. Connect to Accordingly, in this case, the height of the upper arm 12 from the ground increases as it goes outward in the vehicle body width direction.

On the other hand, the rear end connecting portion 10f of the lower portion 10c of the axle carrier 10 swings the outer end portion 14a in the vehicle width direction of the rear lower link 14 via the ball joint 19 at a position directly below the axle 20. Connect movably. Further, the front side connecting part 10e of the lower part 10c of the axle carrier 10 has a vehicle that is below the wheel rotation center axis O, above the rear side connecting part 10f, and slightly ahead of the rear side connecting part 10f. The outer end 13a in the vehicle width direction of the front lower link 13 is slidably connected via a ball joint 18 at a position on the inner side in the width direction.

Here, the rigidity of the lower portion 10c of the axle carrier 10 is different between the front side connecting portion 10e and the rear side connecting portion 10f. That is, as shown in FIG. 6, the rear side connecting portion 10f for fixing the ball joint 19 for connecting the rear lower link 14 is a gap for housing the ball portion of the ball joint 19 and the rear lower link 14. The portion 102 is set larger than the gap portion 101 of the front side connecting portion e that fixes the ball joint 18 that connects the front lower link 13. Thereby, the support rigidity of the rear side connection part 10f is made smaller than the support rigidity of the front side connection part 10e.

On the other hand, the front lower link 13 and the rear lower link 14 are connected to the vehicle body 11 as follows.
As described above, the front lower link 13 is connected to the front side connecting portion 10e of the axle carrier 10 through the ball joint 18 so as to be swingable from the vehicle width direction outer end portion 13a to the vehicle body 11 obliquely forward and inward. The vehicle width direction inner end portion 13b is connected to the vehicle body 11 through a cylindrical rubber bush 21 so as to be swingable at a position ahead of the rotation center O of the wheel 9.

The front lower link 13 is attached to the vehicle body 11 while being inclined with respect to the longitudinal direction of the vehicle body 11. The cylindrical portion provided at the inner end portion 13b in the width direction of the front lower link 13 is the front lower link. -Provided in an oblique direction with respect to the axis M direction of the link 13 and oriented in the vehicle front-rear direction so that the center line of the rubber bush 21 inserted into the cylindrical portion is parallel to the longitudinal direction of the vehicle body. The rubber bush 21 is set to be relatively hard in the radial direction as compared with the rubber bush at the inner end portion in the width direction of a conventional front lower link (tension rod, etc.).
Here, the axis M means a straight line passing through the center points of the width direction outer end portion 13 a and the width direction inner end portion 13 b of the front lower link 13. Similarly, the axis N means a straight line passing through the center points of the width direction outer end portion 14a and the width direction inner end portion 14b of the rear lower link 14.

  As described above, the rear lower link 14 is obliquely rearward inward from the vehicle width direction outer end portion 14a slidably connected via the ball joint 19 of the rear side connection portion 10f of the axle carrier 10. The inner end portion 14b in the vehicle width direction is connected to the vehicle body 11 through a cylindrical rubber bush 22 so as to be swingable slightly behind the rotation center O of the wheel 9. Since the cylindrical portion of the inner end portion 14b in the vehicle width direction is provided so as to be orthogonal to the axis N of the rear lower link 14, the center line of the rubber bush 22 is inclined with respect to the longitudinal direction of the vehicle body. However, since the angle of the axis N of the rear lower link 14 with respect to the rotation center axis O of the wheel 9 is set to be small as will be described later, the inclination angle of the center line of the rubber bush 22 with respect to the vehicle longitudinal direction is small. Nearly parallel.

  The vehicle width direction inner end portion 13 b of the front lower link 13 is connected to the vehicle body 11 at a position higher than the vehicle width direction inner end portion 14 b of the rear lower link 14. Further, in the vehicle side view, the vehicle width direction outer end portion 13a of the front lower link 13 is set to a position higher than the vehicle width direction inner end portion 14b connected to the axle carrier 10 of the rear lower link 14. To do.

  Further, as schematically shown in FIG. 5, the angle θf formed between the rotation center axis O of the wheel 9 and the axis M of the front lower link 13 in the vehicle top view is determined by the rotation center axis O of the wheel 9 and the rear axis. The angle θr formed by the axis N of the lower link 14 is set to be considerably larger. Accordingly, the front lower link 13 is longer than the rear lower link 14. The angle θr formed by the rotation center axis O of the wheel 9 and the axis N of the rear lower link 14 is larger than 0 degrees so that the inner end portion 14b of the rear lower link 14 is in the vehicle width direction. The angle θr is considerably small, for example, about 10 °, although it is positioned on the rear side of the direction outer end portion 14a. On the other hand, the angle θf is set to about 50 °.

  The knuckle arm portion 10d of the axle carrier 10 has a height position in front of the main body portion 10a and the front side connecting portion 10e and between the front side connecting portion 10e and the rear side connecting portion 10f in a side view of the vehicle. Thus, it is provided integrally with the main body portion 10a below the front lower link 14 so that the rack end 7 crosses the lower portion of the front lower link 14 in the vehicle width direction. The ball joint 8 that connects the tie rod 7 and the axle carrier 10 in the knuckle arm portion 10d so as to be swingable has a strong connection rigidity.

  Here, in the front suspension device 1, a straight line passing through the ball joint 17 that connects the tip portion 12 a of the upper arm 12 and the tip portion of the upper portion 10 b of the axle carrier 10 extends vertically. A straight line that intersects the axis M of the front lower arm 13 and the axis N of the rear lower arm 14 which are separated and non-parallel is the king pin axis K. Therefore, this king pin axis K is not determined by connecting two points of the upper side joint and the intersection of the two lower link axes (virtual instantaneous center point) as in the case of the conventional suspension device. The upper joint point of the ball joint 17, the intersection K1 between the king pin axis K and the axis M of the front lower arm 13, the king pin axis K and the axis N of the rear lower arm 14, This is determined three-dimensionally by the three points of the intersection K2. That is, the intersection K1 is located behind and above the intersection 2.

  The king pin axis K is inclined so that the trail or scrub radius, which is the distance between the intersection on the road surface G and the center position of the tire of the wheel 9, does not become excessive. In practice, after determining the king and pin axis K, the joint points / intersections and the directions of the arms and links are determined.

The strut 15 with a built-in shock absorber has its lower end jointed to the axle carrier 10 side portion of the rear lower arm 14 and the upper end of the axle carrier 10 in the vehicle side view shown in FIG. The upper end portion 10b of the upper arm 12 connected to the upper end portion 12b of the upper arm 12 is positioned in front of the upper end portion 12a, and the upper end portion is inclined inwardly of the lower end portion in the front view shown in FIG. Connected to the vehicle body 11. A coil spring 23 is provided above the strut 15 to press the rear lower arm 14 toward the ground.
Further, the rear lower links 14 of the left and right suspension devices 1 are connected by a stabilizer 24. The middle portion of the stabilizer 24 is supported on the vehicle body 11 side.

The front suspension device configured as described above operates as follows.
1 to 4 show a state where the wheel 9 is on a horizontal plane road surface G in a state where the wheel 9 is not steered.

  When an upward or downward force is applied to the wheel 9 when passing through a road surface protrusion or a depression on the road surface or while the vehicle is turning, the upper arm 12, the front lower arm 13, and the rear lower arm 14 move up and down. The vertical movement of the wheel 9 with respect to the vehicle body 11 is allowed. In this case, at the same time, the coil spring 24 expands and contracts, and the shock absorber inside the strut 15 generates a damping force according to the expansion and contraction speed.

  When overcoming the projection on the road surface while traveling, the wheel 9 is in a freely rotating state, so that no force in the rotational direction acts on the center of rotation of the wheel 9, but only a longitudinal force and a vertical force act. As a result, when these forces act on the upper arm 12, the front lower arm 13, and the rear lower arm 14, they swing upward and the vehicle inner front inner end portion 12 b of the upper arm 12. The rubber bushing of the vehicle-side rear inner end portion 12c, the rubber bushing 16a of the front lower arm 13 in the vehicle width direction inner end portion 13b, and the inner end portion 14b of the rear lower arm 14 in the vehicle width direction. Since the rubber bush 16b is oriented in the longitudinal direction or substantially in the longitudinal direction of the vehicle, the joint point on the upper side (position of the ball joint 17), the intersection K1 by the front lower arm 13 on the lower side, and the rear lower -The intersection K2 by the arm 14 will also move backward substantially the same amount.

  Therefore, the king pin axis K is also moved substantially in parallel while maintaining a slight inclination to the rear and inward in the vehicle width direction. Therefore, changes in the scrub radius, trail, etc. can be kept very small, and excellent maneuverability and stability can be ensured.

  In this case, since the front inner end portion 12b in the vehicle width direction of the upper arm 12 is set at a position higher than the rear inner end portion 12c in the vehicle width direction, the wheel 9 having a great influence on the riding comfort performance such as riding over the road surface protrusions. The rotation center trajectory angle can be increased, and riding performance is improved. It also improves anti-dive performance.

  Further, since the rubber bush 16a of the front lower arm 13 and the rubber bush 16b of the rear lower arm 14 are both oriented in the longitudinal direction of the vehicle or substantially in the longitudinal direction, the longitudinal direction of the vehicle of the rubber bushes 16a and 16b. If the rigidity in the direction is weakened, the input of road noise from the road surface can be reduced.

  On the other hand, when the vehicle turns, a cornering force acts on the ground contact surface of the tire. That is, a lateral force acts on the wheel 9 and acts on the upper arm 12, the front lower arm 13, and the rear lower arm 14 via the axle carrier 10. At this time, the rear lower arm 14 is directly below the axle 20 and the angle θr that the axis N forms rearward with respect to the rotation center axis O of the wheel 9 is set small. Will receive here.

  In this case, since the rubber bushing 22 of the inner end portion 14b in the vehicle width direction of the rear lower arm 14 is set to be relatively hard in the radial direction, the amount of bending thereof is small. That is, it is possible to secure excellent maneuverability and stability by increasing the rigidity against the lateral force. On the other hand, since the rigidity of the rear side connecting portion 10f of the axle carrier 10 that supports the rear lower arm 14 is weakened, the shocking lateral force can be absorbed here and the direct impact force enters the vehicle body 11. It is preventing. Further, since the connection of the rear lower arm 14 to the vehicle body 11 side is set behind the rotation center axis O of the wheel 9, the lateral force compliance can be increased.

  A small portion of the lateral force is also input to the front lower arm 13, but the axis M of the front lower arm 13 is greatly inclined forward with respect to the rotation center axis O of the wheel 9, so the direction of the axis M External force acts in the vehicle width direction. Since the cylindrical portion of the inner end portion 13b in the vehicle width direction of the front lower arm 13 and the central axis direction of the rubber bush 21 are oriented in the longitudinal direction of the vehicle, the rubber Since the bush 21 is slightly in the vehicle width direction and soft in the vehicle front-rear direction, it is deformed forward.

As a result, the axis N of the axis M and the rear lower arm 14 of the front lower arm 13 is moved inwardly in the vehicle width direction, these axes M, also the intersection of the N and king pin axis K car Moves inward in the width direction and forward of the vehicle. At this time, since the coupling rigidity between the rack end 7 of the steering system 2 by the ball joint 8 and the knuckle arm portion 10d of the axle carrier 10 is set high, the axle carrier 10 has the coupling portion as a center of rotation. Will move. Accordingly, the front inner wheel 9 that rebounds in this manner faces the toe-in direction.

  At this time, a tension acts on the upper arm 12 toward the outer side in the vehicle width direction, contrary to the case of the lower arms 13 and 14. Therefore, the connection point (corresponding to the position of the ball joint 17) between the upper arm 12 and the axle carrier 10 is determined by the rubber bushes 16a and 16c in the vehicle body width inner portions 12b and 12c before and after the upper arm 12. Because it bends in the radial direction, it tries to move outward in the vehicle width direction. However, when the upper arm 12 swings in the rebound direction, the length in the width direction is shortened and offset, and the amount of displacement in the width direction is small.

Therefore, the axis N of the axis M and the rear lower arm 14 of the front lower arm 13 by the lower end of the link 13 and 14, while moving inwardly in the vehicle width direction and forward front inner ring becomes rebound state , Since the crossing points K1 and K2 move above the king pin axis K, the king pin axis K formed at the connecting point at the tip 12a of the upper arm 12 Reduces the amount of change in the front-rear direction when viewed from the side of the vehicle.

As described above, in the suspension device 1 of the first embodiment, the following effects can be obtained.
That is, in the suspension device 1 according to the first embodiment, the lower portion 10c of the axle carrier 10 and the vehicle body 11 are connected by the front lower link 13 and the rear lower link 14, but the rear The connection of the outer end portion 14 a in the vehicle width direction of the lower link 14 to the axle carrier 10 is a position directly below the axle 20, and the axis N of the rear lower link 14 is formed with respect to the rotation center axis O of the wheel 9. The angle θr is made considerably small, and the angle θf formed by the axis M of the front lower link 13 with respect to the rotation center axis O of the wheel 9 is made considerably larger than the angle θr. Can be received by the rear lower link 14 arranged so that the axis N is close to the perpendicular direction to the front suspension. It is possible to increase the lateral stiffness of location 1.

  In addition, since the outer end portion 14a in the vehicle width direction of the rear lower link 14 is located behind the vehicle center line O in a top view of the vehicle, when a lateral force is input to the tire contact point, the compliance steer for the lateral force is applied. Can be made large. Further, it is possible to reduce road noise input from the road surface from the rear lower link 14 to the vehicle body 11. The remaining lateral force is also received by the front lower link 13, but the rubber bush 21 is deformed by being inserted into the cylindrical portion of the vehicle width direction inner end portion 13b and having a central axis parallel to the vehicle longitudinal direction. Since the directional rigidity is increased, the lateral rigidity of the front lower link 13 is also increased.

Further, due to the arrangement relationship between the front lower link 13 and the rear lower link 14, the rigidity in the radial direction of the rubber bushes 21 and 22 used for these vehicle body side connecting portions is set high in order to increase the lateral rigidity. However, it becomes possible to turn the cornering force generated during turning of the vehicle in the toe-in direction due to the movement of the front lower link 13 and the rear lower link 14 due to the deformation in the longitudinal direction of the vehicle. , You can get the desired compliance steer.
Therefore, in the front suspension device 1 of the first embodiment, it is possible to obtain a desired compliance steer when the lateral force is applied and to achieve both of them.

  Further, the axis M of the links 13 and 14 is determined by the arrangement of the front lower link 13 and the rear lower link 14 where the angle θf> the angle θr, and the connection to the axle carrier 10 with a difference in the vertical direction. The three-dimensional intersection with the N king pin axis K makes it possible to suppress a change in the front-rear direction of the king pin axis K as viewed from the side of the vehicle.

  Since the connecting position for connecting the front lower link 13 to the axle carrier 10 is located on the inner side in the vehicle width direction than the connecting position for connecting the rear lower link 14 to the axle carrier 10, The change of the king pin axis can be reduced.

  Since the cylindrical portion of the inner end portion 13b in the vehicle width direction of the front lower link 13 and the central axis of the rubber bush 21 inserted therein are made parallel along the longitudinal direction of the vehicle, the radial direction that opposes the lateral force The rigidity in the axial direction can be made softer while keeping the rigidity high, and the longitudinal rigidity of the suspension device 1 with respect to the input from the wheel 9 can be set small. Therefore, riding comfort performance can be improved when the road surface protrusion is over the road.

  In addition, since the connecting point of the upper arm 12 to the axle carrier 10 (position of the ball joint 17) is positioned behind the rotational center axis of the wheel 9, the caster angle can be increased and the road surface can be increased. The input to the vehicle body 11 can be made smaller than the disturbance input.

In the vehicle side view, the connecting point of the front lower link 13 to the axle carrier 10 is above the connecting point of the rear lower link 14 to the axle carrier 10 and the vehicle body of the rear lower link 14 since it arranged so that above the connecting point to the 11 side, and the rear-side connecting portion 10f of the lower portion 10c of the axle carrier 10 rear lower link 14 a significant effect on road noise performance is linked It becomes possible and benzalkonium be separated and knuckle arm portion 10d of the steering system 2 is connected is, can be coupled to the axle carrier 10 in an optimal stiffness, respectively.

  Since the length of the front lower link 13 is set longer than the length of the rear lower link 14 so that the angle θf> the angle θr, the front inner ring is It can be a toe-in.

  Since the front inner end portion 12b in the vehicle width direction of the upper arm 12 is set at a position higher than the inner end portion 12c in the vehicle width direction, the wheel 9 has a great influence on the riding comfort performance as in the case of riding over the road surface protrusion. It is possible to increase the trajectory angle of the rotation center. Further, the anti-dive performance can be improved.

Next, a suspension device according to a second embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 7, in the suspension device of the second embodiment, the front lower link 13 is swingably connected to a lower portion of the axle carrier 10 just below the axle 20 by a ball joint 18. To do. On the other hand, the rear lower link 14 is also connected to a lower portion of the axle carrier 10 just below the axle 20 so as to be swingable by a ball joint 19. The connection position of the rear lower link 14 to the axle carrier 10 is at a position on the inner side in the vehicle width direction than the connection position of the front lower link 13 to the axle carrier 10 and the former is lower than the latter. Provide. The arrangement relationship in the vehicle top view is shown as a diagram in FIG. Since the other configuration is the same as the configuration of the first embodiment, the same numbers are assigned to the same parts and portions, and the description thereof is omitted.

  Even in the suspension device of the second embodiment configured as described above, the same operations and effects as those of the first embodiment can be obtained.

The present invention is not limited to the embodiments described above, and it is needless to say that various other modifications can be made within the scope of the present invention.
For example, the upper arm 12, the front lower link 13, and the rear lower link 14 may be a pipe-shaped link or a press-formed plate-shaped arm. Further, these links may be attached to the vehicle body 11 via a gusset or the like.

  In addition, the cylindrical portion of the vehicle width direction inner end portion 13b of the front lower link 13 and the central axis of the rubber bush 21 inserted therein are made parallel along the longitudinal direction of the vehicle, but must be strictly parallel. Even if the central axis of the rubber bush 21 is made as close to the parallel as possible and tilted somewhat with respect to the longitudinal direction of the vehicle, the front inner ring is directed to the toe-in direction by compliance steer while the vehicle is turning. I just need it.

In the first embodiment, the connection position of the front lower link 13 to the axle carrier 10 is set inward in the vehicle width direction from the connection position of the rear lower link 14 to the axle carrier 10 and the vehicle 9 is rotated. Although provided in front of the central axis O, it may be provided on the rotational central axis O of the vehicle 9.
Similarly, in the second embodiment, the connecting position of the front lower link 13 to the axle carrier 10 is outside the connecting position of the rear lower link 14 to the axle carrier 10 in the vehicle width direction, and the vehicle. 9 is provided on the rotation center axis O of the vehicle 9, but is not necessarily provided on the rotation center axis O of the vehicle 9.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing a positional relationship between a front suspension device according to a first embodiment of the present invention and a steering system connected thereto, as viewed from the front side of a vehicle. FIG. 3 is a plan view of the left-side front suspension device of the left and right front suspension devices of the first embodiment when viewed from above. FIG. 3 is a side view of the front suspension device on the left side of the vehicle according to the first embodiment when viewed from the left side of the vehicle. 1 is a front view of a front suspension device on a left side of a vehicle according to a first embodiment as viewed from the front side of the vehicle. FIG. 3 is a plan view illustrating the positional relationship between the front lower link and the rear lower link in the front suspension device on the left side of the vehicle according to the first embodiment as a diagram when viewed from the top of the vehicle. FIG. 3 is a cross-sectional view of a portion where the front lower link and the rear lower link are connected to the axle carrier in the front suspension device on the left side of the vehicle according to the first embodiment. It is the top view which looked at the front suspension apparatus of the vehicle left side among the vehicle left and right front suspension apparatuses of Example 2 of this invention from upper direction. FIG. 6 is a plan view illustrating a positional relationship between a front lower link and a rear lower link in a front suspension device on the left side of a vehicle according to a second embodiment as a diagram as viewed from above the vehicle.

Explanation of symbols

K King pin axis K1 Intersection of front lower link axis and king pin axis K2 Intersection of rear lower link axis and king pin axis M Front lower link axis N Rear lower Link axis O Wheel center axis 1 Front suspension device 2 Steering system 9 Wheel 10 Axle carrier 10a Main body part 10b Upper part 10c Lower part 10d Knuckle arm part 10e Rear side connecting part 10e Front side connecting part 12f Rear side Connecting portion 11 Car body 12 Upper arm 12a Vehicle width direction outer end portion 12b Vehicle side front inner end portion 12c Vehicle side rear inner end portion 13 Front lower link (first lower link)
13a Vehicle width direction outer end portion 13b Vehicle width direction inner end portion 14 Rear lower link (second lower link)
14a Vehicle width direction outer end portion 14b Vehicle width direction inner end portion 16a, 16b Rubber bush (bush)
17, 18, 19 Ball joint 20 Axle 21, 22 Rubber bush (bush)

Claims (6)

An axle carrier having an axle for rotatably supporting the wheels;
A plurality of links extending from the vehicle body side in the vehicle body width direction and connected to the axle carrier, and a suspension device comprising:
The plurality of links are:
An upper arm that swingably connects an upper part of the axle carrier above the axle to the vehicle body;
A vehicle width direction outer end portion on a lower portion below the axle of the axle carrier, and a vehicle width direction inner end portion on the vehicle body side in the vehicle front-rear direction front side with respect to the vehicle width direction outer end portion, A first lower link coupled in a swingable manner;
On the rear side in the vehicle longitudinal direction with respect to the first lower link, an outer end portion in the vehicle width direction is provided at a lower portion below the axle of the axle carrier, and the outer end portion in the vehicle width direction. A second lower link in which a vehicle width direction inner end portion is slidably connected to the vehicle body side on the rear side in the vehicle width front-rear direction;
With
The connection of the outer end portion of the second lower link in the vehicle width direction to the axle carrier is a position overlapping the axle in the vehicle front-rear direction,
An angle formed by an axis connecting the outer end portion in the vehicle width direction and the inner end portion in the vehicle width direction of the second lower link to the vehicle rear side with respect to the rotation center axis of the wheel is defined as the first lower link. An axis connecting the outer end portion in the vehicle width direction and the inner end portion in the vehicle width direction is smaller than an angle formed toward the vehicle front side with respect to the rotation center axis of the wheel,
A connection position of the first lower link connected to the axle carrier is higher than a connection position of the second lower link to the axle carrier and lower than a rotation center axis of the wheel;
A connection position for connecting one of the first lower link and the second lower link to the axle carrier is defined as the other link of the first lower link and the second lower link. Is located on the inner side in the vehicle width direction than the connecting position for connecting to the axle carrier ,
The king pin axis of the suspension is an upper joint point determined by the upper arm, a lower intersection point on the axis of the second lower link, and a height between the lower intersection point and the upper joint point. Determined at these three points through the intermediate intersection on the axis of the first lower arm, located at
A front suspension device characterized by that. The front suspension apparatus according to claim 1,
A front suspension apparatus, wherein a cylindrical portion of the inner end portion of the first lower link in the vehicle width direction and a central axis of a bush inserted therein are made parallel along the vehicle longitudinal direction. The front suspension apparatus according to claim 1 or 2,
A front suspension device, wherein a connection point of the upper arm to the axle carrier is disposed at a position rearward of the center axis of rotation of the wheel as viewed from above the vehicle. The front suspension device according to any one of claims 1 to 3,
The connection point between the vehicle arm direction front inner end portion of the upper arm and the vehicle body side is disposed at a position higher than the connection point between the vehicle width direction rear inner end portion of the upper arm and the vehicle body side. A front suspension device characterized by that. The front suspension device according to any one of claims 1 to 4,
In the vehicle side view, the connection point of the first lower link to the axle carrier is higher than the connection point of the second lower link to the axle carrier, and the second lower link. The front suspension device is arranged at a position higher than the connection point to the vehicle body side. The front suspension device according to any one of claims 1 to 4,
A lower part of the axle carrier has a lower supporting rigidity of a connecting part with the second lower link than a supporting rigidity of a connecting part with the first lower link. .

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