JP3489320B2 - Vehicle suspension - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle suspension, and more particularly to controlling a vehicle attitude by utilizing a longitudinal force input to an axle housing that rotatably supports wheels during acceleration and deceleration. It was done like this.

[0002]

2. Description of the Related Art As a conventional vehicle suspension,
For example, there is one disclosed in Japanese Utility Model Laid-Open No. 64-32208, and in the conventional vehicle suspension disclosed in this publication, the upper and lower portions of an axle housing that rotatably supports wheels are respectively provided. It is supported on the vehicle body side via suspension links. The elastic center determined by the vehicle front-rear direction supporting rigidity between the upper portion of the axle housing and the vehicle body-side member and the vehicle front-rear direction supporting rigidity between the lower portion of the axle housing and the vehicle body-side member is the wheel center ( It was supposed to be located below the axis of rotation of the wheels. However, the vehicle attitude has not been controlled by positively utilizing the rotation of the axle housing during acceleration / deceleration.

On the other hand, in a conventional conventional vehicle suspension, for example, the wheel center moves along a desired locus in a side view of the vehicle in order to suppress the depression of the rear side of the vehicle body during acceleration. The design was done. In other words, in order to prevent the rear wheels from sinking during acceleration, the entire suspension is designed so that the wheel center moves upward during acceleration, based on the idea of so-called anti-scut geometry. On the contrary,
In order to improve the feeling of acceleration of the vehicle, there is also a design requirement to actively promote the sinking of the rear side of the vehicle body during acceleration. In response to such a requirement, the wheel center moves downward during acceleration. I was trying to design the entire suspension.

[0004]

However, in the prior art that controls the depression of the vehicle body at the time of acceleration as described above and controls such as acceleration by only adjusting the locus of the wheel center, due to the arrangement constraint of the suspension link. If the desired wheel center trajectory cannot be secured and the posture control of the vehicle cannot be performed properly, the posture during acceleration cannot be kept flat, or a sufficient sense of acceleration cannot be obtained. Had challenges. In other words, the degree of freedom in design was low in the prior art that controls the vehicle attitude by directly reflecting the desired vertical displacement of the vehicle body during acceleration or the like on the trajectory of the wheel center.

The present invention has been made by paying attention to the unsolved problems of the prior art as described above, and it is possible to control the attitude of the vehicle at the time of acceleration / deceleration even when the suspension link layout constraint is large. The purpose of the present invention is to provide a vehicle suspension.

[0006]

In order to achieve the above-mentioned object, a vehicle suspension according to a first aspect of the present invention comprises an axle housing for rotatably supporting a vehicle rear wheel , which is a drive wheel, and a vehicle body side member. The elastic center of the axle housing for input in the vehicle front-rear direction, which is determined by the support rigidity in the vehicle front-rear direction between the upper and lower sides, is located above the wheel center , and the spring and the seat supporting body are supported.
The ax of at least one of the shock absorbers
Connection point to the housing or the spring and
At least one of the shock absorbers has been combined
Connect the suspension link to the axle housing.
The connection point is on the vehicle rear side of the wheel center, and
A vehicle between the upper part of the axle housing and a member on the vehicle body side.
Support rigidity in both front and rear directions is provided in the axle housing.
When both forward forces are input, it becomes higher and
When a rearward force is input to the vehicle housing
Was set to be low .

[0007] To achieve the above object, vehicle suspension is the invention according to claim 2, the vehicle front and rear between the axle Pillow grayed and the vehicle body-side member for rotatably supporting the vehicle rear wheel which is a driving wheel The elastic center of the axle housing for input in the vehicle front-rear direction, which is determined by the supporting rigidity in the direction, is located above the wheel center, and at least one of a spring and a shock absorber supporting the vehicle body is connected to the axle housing. Alternatively, the connection point of the suspension link to which at least one of the spring and the shock absorber is coupled to the axle housing is on the vehicle rear side with respect to the wheel center, and the axle housing is further provided.
Support in the vehicle longitudinal direction between the lower part of the wing and the body side member
The rigidity is adjusted so that the vehicle front force is applied to the axle housing.
When the force is applied, it becomes lower and the axle housing
Increased when a vehicle rearward force is input
I did .

[0008] To achieve the above object, vehicle suspension is the invention according to claim 3, the vehicle front and rear between the axle Pillow grayed and the vehicle body-side member for rotatably supporting the vehicle rear wheel which is a driving wheel The elastic center of the axle housing for input in the vehicle front-rear direction, which is determined by the supporting rigidity in the direction, is below the wheel center, and at least one of a spring and a shock absorber supporting the vehicle body is connected to the axle housing. Or a connection point of the suspension link, to which at least one of the spring and the shock absorber is coupled, to the axle housing is set to the vehicle front side with respect to the wheel center, and the axle housing is further provided.
Support in the vehicle longitudinal direction between the upper part of the wing and the body side member
The rigidity is adjusted so that the vehicle front force is applied to the axle housing.
When the force is applied, it becomes lower and the axle housing
Increased when a vehicle rearward force is input
I did .

[0009] To achieve the above object, vehicle suspension invention is according to claim 4, vehicle front and rear between the axle Pillow grayed and the vehicle body-side member for rotatably supporting the vehicle rear wheel which is a driving wheel The elastic center of the axle housing for input in the vehicle front-rear direction, which is determined by the supporting rigidity in the direction, is below the wheel center, and at least one of a spring and a shock absorber supporting the vehicle body is connected to the axle housing. Or a connection point of the suspension link, to which at least one of the spring and the shock absorber is coupled, to the axle housing is set to the vehicle front side with respect to the wheel center, and the axle housing is further provided.
Support in the vehicle longitudinal direction between the lower part of the wing and the body side member
The rigidity is adjusted so that the vehicle front force is applied to the axle housing.
It will be higher when forced,
Lower when vehicle rearward force is input
I did .

[0010] To achieve the above object, vehicle suspension invention is according to claim 5, the vehicle longitudinal direction between the axle Pillow grayed and the vehicle body-side member for rotatably supporting the vehicle wheel is a drive wheel of the elastic center with respect to the vehicle longitudinal direction of the input of the axle housing which is determined by the supporting rigidity, while the upper side of the wheel center, point of connection to at least one of the axle housing of the spring and shock absorber for supporting the vehicle body or A connection point of the suspension link, to which at least one of the spring and the shock absorber is coupled, to the axle housing is set to a vehicle front side with respect to a wheel center, and the axle housing is further provided.
Support in the vehicle longitudinal direction between the upper part of the wing and the body side member
The rigidity is adjusted so that the vehicle front force is applied to the axle housing.
It will be higher when forced,
Lower when vehicle rearward force is input
I did .

In order to achieve the above object , a vehicle suspension according to a sixth aspect of the invention is a vehicle that has drive wheels.
Axle housing and vehicle body that rotatably support both front wheels
Determined by the supporting rigidity in the vehicle front-rear direction between the side members
For input in the vehicle longitudinal direction of the axle housing
Even if the elastic center is above the wheel center,
A spring and a shock absorber for supporting the vehicle body
To at least one of the axle housings
Connection point or the spring and shock absorber
Suspension suspension to which at least one of the
Link the axle to the axle housing with
The vehicle front side with respect to the center, and further, the vehicle front-rear direction supporting rigidity between the lower portion of the axle housing and the vehicle body side member becomes lower when a vehicle forward force is input to the axle housing. It is set to be higher when a rearward force of the vehicle is input to the housing. In order to achieve the above object, the invention according to claim 7
The vehicle suspension, which is the
Axle housing and body side member that rotatably support the vehicle
Between the vehicle and the
Elasticity of the vehicle housing against input in the vehicle longitudinal direction
Keep your mind below the wheel center and
Of the springs and shock absorbers that support the
Connection point of at least one of the axle housings
Of the above-mentioned springs and shock absorbers,
In front of a suspension link with at least one connected
Note that the connection point to the axle housing is
The rear side of the vehicle and the axle housing
The support rigidity in the vehicle front-rear direction between the upper part and the vehicle body side member,
Vehicle forward force is input to the axle housing
If it goes low, behind the vehicle in the axle housing
When the force of the direction is input, it becomes higher. Up
In order to achieve the above object, a vehicle according to claim 8 of the invention.
The dual-purpose suspension rotates the front wheels of the vehicle, which are the driving wheels.
Between the currently supported axle housing and the body side member
The axle shaft is determined by the supporting rigidity in the vehicle front-rear direction.
The elastic center for the input of the housing in the vehicle front-back direction is
To together When below the Irusenta, to support the vehicle body
At least one of the springs and shock absorbers
The connection point or front of one of the axle housings
At least one of the spring and shock absorber
The ax of the suspension link where one side is connected
The connection point to the vehicle housing rather than the wheel center
The rear side, and the lower part of the axle housing and the vehicle
The support rigidity in the vehicle front-rear direction between the body-side member and
If a vehicle forward force is input to the through housing,
The vehicle rearward force on the axle housing
It becomes low when is input.

According to a ninth aspect of the invention, in the vehicle suspension according to the first or fifth aspect of the invention, the vehicle front-rear supporting rigidity between the lower portion of the axle housing and the vehicle body side member is It is set to be low when a vehicle frontward force is input to the axle housing, and is high when a vehicle rearward force is input to the axle housing.

[0013]

Further, the invention according to claim 10 is the vehicle suspension according to claim 3 or 7 , wherein the supporting rigidity in the vehicle longitudinal direction between the lower portion of the axle housing and the vehicle body side member is: It becomes high when a vehicle forward force is input to the axle housing,
The force is set to be low when a backward force of the vehicle is input to the axle housing.

That is, according to the present invention, when a force (driving force, engine braking force) in the vehicle front-rear direction is input to the axle housing during acceleration or deceleration, and the axle housing attempts to move forward or backward of the vehicle. , The input point of the force in the front-rear direction is the wheel center, whereas the elastic center of the axle housing for input in the vehicle front-rear direction is above or below the wheel center, so rotational displacement occurs in the axle housing. Try to. The elastic center of the axle housing for input in the vehicle front-rear direction is determined by the supporting rigidity in the front-rear direction between the axle housing and the vehicle body-side member (vehicle body or suspension member). When the axle housing supported by the side member via the suspension link is to be displaced in the front-rear direction, the displacement force in the front-rear direction can be moved in parallel in the front-rear direction without tilting the axle housing. It is an input point. That is, the support rigidity in the vehicle front-rear direction between the upper portion of the axle housing and the vehicle body side member is _KU ,
When the vehicle front-rear direction supporting rigidity between the lower portion of the axle housing and the vehicle body side member is set to K _L , the support between the suspension link connecting point A at the upper portion of the axle housing and the suspension link connecting point B at the lower portion of the axle housing is supported. inverse ratio of stiffness KU and KL: internally dividing the point at (K _L K _U) (i.e., a line connecting the coupling points a and B, K _L a coupling point a side: a point obtained by internally dividing a ratio of K _U) Is the elastic center of the axle housing for input in the vehicle front-rear direction.

When a rotational displacement occurs in the axle housing, the rotational displacement is converted into a vertical force and transmitted to the vehicle body side member, so that the vehicle body side member attempts to raise or lower it. A force is generated which controls the vehicle attitude. In order to convert the rotational displacement of the axle housing into a vertical force and transmit it to the vehicle body side member, for example, between the axle housing and the vehicle body side member,
Alternatively, a suspension link connected to the axle housing and a spring or a shock absorber interposed between the vehicle body side members can be used. That is, those springs or shock absorbers are connected to the axle housing at the vehicle front side or the vehicle rear side of the wheel center, or the suspension links to which the springs or shock absorbers are connected are connected to the vehicle front side of the wheel center or the vehicle rear side. When coupled to the axle housing at the side position, the spring or the shock absorber expands or contracts due to the rotational displacement of the axle housing, and the vertical force generated by the expansion or contraction is transmitted to the vehicle body side member.

[0017] The invention according to claim 1, 2, there is applied to the axle housing which supports the vehicle rear wheels as driving wheels rotatably, yet acceleration feeling conducive sinking of the vehicle body rear portion during acceleration Is intended to improve. In other words, the driving force of the engine is input to the drive wheels via the axles, etc., so that the axle housing that rotatably supports the drive wheels is driven by the force that attempts to move the axle housing to the front of the vehicle. It is input as an input point. Then, since the elastic center of the axle housing for the input in the vehicle front-rear direction is located above the wheel center, the axle housing is rotated such that the front portion of the vehicle rises and the rear portion of the vehicle descends. Displacement will occur. As a result, at least one of the spring and the shock absorber has its lower spring connection point displaced downward, so that a downward force is input to the vehicle body member via the spring or the shock absorber. , Sinking at the rear of the car body is promoted.

The inventions according to claims 3 and 4 are also claimed.
1, as in the 2 to such a present invention, there is applied to the axle housing for rotatably supporting a vehicle rear wheel as driving wheel, moreover acceleration feeling conducive sinking of the vehicle body rear portion can be improved during acceleration It was done like this. That is , in the inventions according to Claims 3 and 4 , unlike the inventions according to Claims 1 and 2, since the elastic center of the axle housing with respect to the input in the vehicle front-rear direction is located below the wheel center, The axle housing causes a rotational displacement such that the vehicle frontward portion that is input during acceleration causes the vehicle front side portion to descend and the vehicle rear side portion to rise, but the spring or the unsprung side of the shock absorber is generated. Since the connection point of is on the vehicle front side of the wheel center,
Again, the connection point on the lower side of the spring of the spring or the shock absorber is displaced downward, and a downward force is input to the vehicle body side member, which promotes the depression of the rear portion of the vehicle body.

Meanwhile, the invention of claim 5 and 6, there is applied to the axle housing for supporting a vehicle wheel as a driving wheel rotatably, yet is conducive to lifting of the front vehicle body during acceleration acceleration The feeling is improved. That is, in the invention according to 請 Motomeko 5,6, since the elastic center and above the wheel center with respect to the input in the vehicle longitudinal direction of the axle housing, axle housing, by the vehicle forward force inputted during acceleration, the Rotational displacement occurs such that the front part of the vehicle rises and the rear part of the vehicle descends.However, since the connecting point on the lower side of the spring of the spring or shock absorber is on the vehicle front side of the wheel center, the spring or The connection point on the lower side of the spring of the shock absorber is displaced to the upper side, and an upward force is input to the vehicle body side member to promote lifting of the front portion of the vehicle body.

The inventions according to claims 7 and 8 are also claimed.
Similar to the invention according to 5,6, there is applied to the axle housing for rotatably supporting the vehicle wheel as a driving wheel, yet so that acceleration feeling is conducive to lifting of the vehicle body front portion is increased during acceleration It is the one. That is ,
In the invention according to 請 Motomeko 7,8, unlike the invention according to claim 5 and 6, since the lower side of the elastic center wheel center with respect to the vehicle longitudinal direction of the input of the axle housing, axle housing, during acceleration The input forward force of the vehicle causes a rotational displacement such that the vehicle front part is lowered and the vehicle rear part is raised, but the connection point on the unsprung side of the spring or shock absorber is connected to the wheel center. Since it is located on the rear side of the vehicle, the connection point on the lower side of the spring of the spring or the shock absorber is displaced upward, and an upward force is input to the vehicle body side member to promote lifting of the front portion of the vehicle body.

Further, according to the first and fifth aspects of the invention, when a forward force of the vehicle is input to the axle housing, such as during acceleration, the vehicle between the upper portion of the axle housing and the vehicle body side member. Since the support rigidity in the front-back direction is high,
The elastic center is relatively far from the wheel center, but when a rearward force of the vehicle is input to the axle housing, such as when the engine is being braked, the elastic rigidity of the elastic center accelerates because the supporting rigidity in the vehicle front-rear direction is low. It comes closer to the wheel center than in the case of time. For this reason,
Since the rotational displacement of the axle housing is large during acceleration and small during engine braking, the vehicle attitude control force during acceleration is large, and the vehicle attitude control force during engine braking is small.

Also, in the inventions according to claims 2, 6, and 9 , when a forward force of the vehicle is input to the axle housing as during acceleration, a portion between the lower portion of the axle housing and the vehicle body side member is provided. Since the support rigidity of the vehicle in the vehicle front-rear direction is low, the elastic center is located relatively far from the wheel center.However, when a rearward force of the vehicle is input to the axle housing such as during engine braking, Since the support rigidity is high, the elastic center comes closer to the wheel center as compared with the case of acceleration. For this reason,
Since the rotational displacement of the axle housing is large during acceleration and small during engine braking, the vehicle attitude control force during acceleration is large, and the vehicle attitude control force during engine braking is small.

On the other hand, according to the third and seventh aspects of the invention, when a vehicle forward force is input to the axle housing as during acceleration, the vehicle front-rear direction between the upper portion of the axle housing and the vehicle body side member is increased. Since the support rigidity is low, the elastic center is relatively far from the wheel center, but when a rearward force is input to the axle housing, such as during engine braking, the support rigidity in the vehicle front-rear direction is high. , The elastic center comes closer to the wheel center as compared with the case of acceleration. Therefore, the rotational displacement of the axle housing is large during acceleration and small during engine braking, so the control force for the vehicle attitude during acceleration is large and the control force for the vehicle attitude during engine braking is small.

Further, in the invention according to claims 4 , 8 and 10 , when a vehicle forward force is input to the axle housing as during acceleration, the front and rear of the vehicle between the lower portion of the axle housing and the vehicle body side member. Since the directional support rigidity is high,
The elastic center is relatively far from the wheel center,
When a vehicle rearward force is input to the axle housing as during engine braking, the elastic center comes closer to the wheel center as compared with the case of acceleration because the supporting rigidity in the vehicle longitudinal direction is low. Therefore, the rotational displacement of the axle housing is large during acceleration and small during engine braking, so the control force for the vehicle attitude during acceleration is large and the control force for the vehicle attitude during engine braking is small.

[0025]

According to the present invention, a rotational displacement is positively generated in the axle housing during acceleration / deceleration, and the rotational displacement is converted into a vertical force and transmitted to a member on the vehicle body side. Since the vehicle attitude is controlled, there is an effect that the degree of freedom in design is increased, and the vehicle attitude during acceleration / deceleration can be easily controlled even when the suspension link layout constraint is large.

Further, since the lifting of the sinking or vehicle front portion of the vehicle body rear portion at the time of acceleration is promoted, there is also an effect that it is possible to improve the acceleration feeling.

Furthermore, while capable of improving the acceleration feeling, there is also an effect that the vehicle leaning forward when the engine brake or the like does not become excessive.

[0028]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. 1 to 4 are views showing a first embodiment of the present invention. FIG. 1 is a perspective view showing a left side structure of a vehicle suspension according to the present invention, and FIG. 2 is a view of the same vehicle suspension. It is a side view. The configuration on the right side of the vehicle suspension is the same as the configuration on the left side, except that it is symmetrical, and therefore its illustration and description are omitted.

First, the structure will be described. The vehicle suspension according to the present embodiment is a rear suspension for a rear-wheel drive vehicle and has an axle housing 2 for rotatably supporting an axle 1 extending in the vehicle lateral direction. A wheel (rear wheel of the vehicle) W as a drive wheel and a disk rotor are integrally fixed in the rotational direction to a portion of the axle 1 that protrudes outward from the axle housing 2 in the lateral direction of the vehicle. A wheel is rotatably supported by the wheel 2. The axle 1 has a constant velocity universal joint 1A,
Driving force is transmitted from a final reduction gear device (not shown) via 1B and the like.

On the other hand, below the vehicle body of the vehicle, lateral members 3A, 3B extending laterally of the vehicle so as to sandwich a final reduction gear (not shown) from the front-rear direction, and these lateral members 3A, 3B.
A suspension member 3 is disposed as a vehicle body side member composed of a vertical member 3C (one vertical member is not shown) extending in the vehicle front-rear direction so as to connect both end portions of the vertical member 3C. Elastic bushes 4A, 4
It is connected to the vehicle body via B. Elastic bush 4A,
As 4B, a double-cylindrical elastic bush having elastic rubber interposed between the inner cylinder and the outer cylinder can be applied. The other vertical member (not shown) is also connected to the vehicle body in the same configuration as the vertical member 3C.

Then, the above-mentioned axle housing 2
However, the suspension member 3 is connected via a plurality of links.
Supported by. Specifically, the axle housing 2
The rear end side of the radius rod 5 extending substantially in the front-rear direction of the vehicle is swingably connected to the front lower part of the vehicle via, for example, a double cylindrical elastic bush 5A, and the front end side of the radius rod 5 is similarly double cylinder type. It is swingably connected to the front end of the vertical member 3C via the elastic bush 5B. In this case, the swing axes of the elastic bushes 5A and 5B are parallel to each other, and are directed from the diagonally left front to the diagonally right rear in a substantially horizontal plane.

At the lower part of the front side of the axle housing 2, the outer end side of the lateral link 6 on the front side of the vehicle, which extends substantially in the lateral direction of the vehicle, is positioned below the rear end of the radius rod 5, for example, a double cylinder. Of the vertical link 3C is swingably connected via a flexible elastic bush 6A, and the inner end side of the lateral link 6 is also slightly forward of the central portion of the vertical member 3C via a double cylindrical elastic bush 6B. It is swingably connected to the side. In this case, the elastic bushes 6A, 6B
The swing axes of are parallel to each other and are oriented substantially in the vehicle front-rear direction.

On the other hand, the lower portion of the rear side of the axle housing 2 is integrally formed with an arm portion 2A which projects rearward from the vehicle, and the rear portion of the vehicle which extends substantially in the lateral direction of the vehicle is attached to the arm portion 2A. The outer end side of the lateral link 7 is swingably connected via, for example, a double cylindrical elastic bush 7A, and the inner end side of the lateral link 7 is also laterally connected via a double cylindrical elastic bush 7B. It is swingably connected to the rear surface of the end of the member 3B. In this case, the swing shafts of the elastic bushes 7A and 7B are parallel to each other and are oriented substantially in the vehicle front-rear direction.

On the other hand, on the front side of the upper portion of the axle housing 2, there is integrally formed an arm portion (not shown) projecting upward therefrom, and the outer end side of the upper arm 8 extending substantially in the lateral direction of the vehicle is ball-shaped on the arm portion. A joint 8A (omitted in FIG. 1, only shown in FIG. 2) is swingably and swivelly connected. The upper arm 8 is curved toward the vehicle front side so as to avoid buffering with a shock absorber described later, and the inner end side is bifurcated in the vehicle front-rear direction, and the branched inner end portions are elastic bushes. 8B,
It is swingably connected to the vertical member 3C via 8C. In this case, the swing shafts of the elastic bushes 8B and 8C are on the same straight line and are oriented substantially in the vehicle front-rear direction.

As described above, the lower portion of the axle housing 2 is supported by the suspension member 3 via the radius rod 5 and the two lateral links 6 and 7, and the upper portion thereof is supported by the suspension member 3 via the upper arm 8. ing.

The portion of the lateral link 7 on the rear side of the vehicle which is not covered by the suspension member 3 is widened in the vehicle front-rear direction, and the coil spring 10 is arranged on the widened portion. The coil spring 10 extends in a substantially vertical direction, and its upper end is fixed to a vehicle body (not shown), so that the vehicle body load is supported by the lateral link 7 via the coil spring 10. Incidentally, the vehicle load applied to the lateral link 7 is supported on the road surface via the elastic bush 7A, the arm 2A, the axle housing 2 and the wheels.

On the inner surface of the upper portion of the axle housing 2, there is integrally formed an arm portion 2B extending obliquely upward and inward of the vehicle. The upper end portion of this arm portion 2B is the lower end of the cylinder 11A of the shock absorber 11. The sides are connected via an elastic bush 12. The shock absorber 11 extends upward while slightly tilting toward the rear inside of the vehicle, and has a pair of elastic bodies 14A that sandwich the vehicle body 13 from above and below at the upper end of the piston rod 11B that coaxially protrudes from the upper end of the cylinder 11A. , 14B are provided. That is, the upper end of the shock absorber 11 is elastically connected to the vehicle body 13 via the elastic bodies 14A and 14B. Further, below the elastic pair 14B, the bump rubber 15 made of a rubber-like elastic body is interposed via the bracket 11a.
Are arranged coaxially.

Here, the axle housing 2 is a member that rotatably supports the wheels W, and the wheel center WC, which is the rotation center of the wheels W, is located substantially at the center of the axle housing 2, as shown in FIG. Like And
With this wheel center WC as a reference, the connection point on the axle housing 2 side of the lateral link 7 as a suspension link to which the coil spring 10 is coupled is
It is located on the vehicle rear side of the wheel center WC.

Further, the support rigidity K _{U in} the vehicle front-rear direction between the upper portion of the axle housing 2 and the vertical member 3C is determined mainly by the rigidity of the ball joints 8A and the elastic bushes 8B, 8C provided at both ends of the upper arm 8. , support rigidity K _L in the vehicle longitudinal direction between the lower and the longitudinal member 3C of the axle housing 2, elastic bushes 5A provided mainly at both ends of the radius rod 5, 5B
However, in the present embodiment, the support rigidity K _U is set to be larger than the support rigidity K _L , so that FIG.
As shown in FIG. 3, the elastic center C of the axle housing 2 with respect to the input in the vehicle front-rear direction is positioned above the wheel center WC. In FIG. 3, A is a connecting point of the upper arm 8 on the axle housing 2 side, and B is a connecting point of the radius rod 5 on the axle housing 2 side.

[0040] That is, elastic center C is a straight line connecting the coupling point A and B, since a point obtained by internally dividing a reverse ratio of the support stiffness K _U and K _L, the ratio of their support rigidity K _U and K _L By setting it appropriately, it is possible to set it at an arbitrary position relatively freely.

Next, the operation of this embodiment will be described. That is, the driving force generated by the engine during vehicle acceleration is transmitted to the wheels W as a rotational force via the final reduction gear unit, the axle 1, etc., and the rotational force of the wheels W causes the vehicle to travel forward F _D
Is input to the axle housing 2. Then, the driving force F _D is transmitted from there to the suspension member 3 via the upper arm 8 and the radius rod 5, whereby the entire vehicle moves forward.

Since the driving force F _D is input from the wheel W to the axle housing 2 via the axle 1,
The input point to the axle housing 2 is the wheel center WC as shown in FIG. 4, but since the wheel center WC is located below the elastic center C of the axle housing 2, the support rigidity K _L side is By flexing more than the supporting rigidity K _U side, the axle housing 2 is rotationally displaced as shown by an arrow D in FIG. In other words, the axle housing 2 during acceleration, while moving in front of the vehicle by the drive force F _D, is to rotationally displaced by moment action by the distance between the driving force F _D and the wheel center WC and elastic center C.

In this way, during acceleration, the axle housing 2 is rotationally displaced in the direction in which the front portion in the vehicle direction is lifted, so that the axle housing 2 is connected to a portion on the vehicle rear side of the wheel center WC. The lateral link 7 moves downward as indicated by arrow E.

Then, the lower end of the coil spring 10 supported by the lateral link 7 also moves downward, so that the vehicle body 1 passes through the coil spring 10.
A downward force is input to 3, which promotes the sinking of the rear part of the vehicle body. As a result, the rear part of the vehicle body largely sinks, so that the driver can feel a sufficient sense of acceleration.

That is, in a normal vehicle, the posture of the rear part of the vehicle body is controlled by the load movement to the rear side of the vehicle at the time of acceleration and, for example, the anti-scut force obtained by the suspension geometry. In that case, so to speak, the third attitude control force can be obtained. For this reason, the degree of freedom in design is dramatically increased. For example, even when a desired trajectory cannot be given to the wheel center WC due to restrictions on the layout of the vehicle, for example, the rear portion of the vehicle body may be depressed during acceleration. It helps to improve the feeling of acceleration.

FIGS. 5 to 8 are views showing a second embodiment of the present invention. Since the overall configuration is the same as that of the first embodiment, its illustration and description will be omitted. Further, the same members and the like as those in the first embodiment are designated by the same reference numerals, and the duplicated description thereof will be omitted.

That is, in the present embodiment, as shown in FIG. 5 which is a plan view of the upper arm 8, elastic bushes 8B and 8C for connecting the upper arm 8 to the suspension member are provided on the front side of the vehicle. The stopper members 20A and 20B made of a rubber-like elastic body are provided. These stopper members 20A and 20B are rectangular parallelepiped members fixed to the suspension member side,
The surface of the elastic bushes 8B and 8C facing the vehicle rear side is in contact with the surface of the elastic bushes 8B and 8C facing the vehicle front side. However, the elastic bushes 8A and 8C and the stopper members 20A and 20C are in a non-bonded state.

With this structure, the relationship between the force in the vehicle front-rear direction (vertical axis) input to the axle housing and the relative displacement in the vehicle front-rear direction between the upper portion of the axle housing and the suspension member (horizontal axis) is shown. , As shown in FIG. That is, FIG. 6 shows the characteristic of the support rigidity K _{U in} the vehicle front-rear direction between the upper portion of the axle housing and the suspension member, but when a forward force is input to the axle housing (during acceleration), the upper arm 8
Elastic bushing 8B
And 8C come into contact with the stopper members 20A and 20B, and the supporting rigidity K _{U has} a magnitude that combines the rigidity of both.
The supporting rigidity K _U becomes high (hard). On the other hand, when a backward force is input to the axle housing (during engine braking), the upper arm 8 also tries to move rearward of the vehicle, so that the elastic bushes 8B and 8C are separated from the stopper members 20A and 20B. Since the supporting rigidity K _U is determined by the rigidity of the elastic bushes 8B and 8C, the supporting rigidity K _U becomes low (soft).

Then, as shown in FIG. 7, when the driving force F _D during vehicle acceleration is input to the axle housing, the axle housing tries to move forward of the vehicle, and as a result, the stopper members 20A and 20B become effective. Support rigidity K
_{Since U} becomes relatively high, the elastic center C determined by the relatively large supporting rigidity K _U and the relatively small supporting rigidity K _L is above the wheel center WC and is the same as in the first embodiment. It will be located relatively far from the WC. Therefore, by the same operation as that of the first embodiment, the vehicle body 1 is passed through the coil spring 10.
A downward force is input to 3, which promotes the sinking of the rear part of the vehicle body, improving the feeling of acceleration.

On the other hand, as shown in FIG. 8, during engine braking, the engine braking force F _B (that is, the negative driving force) opposite to the driving force F _D is input to the axle housing, so As a result of the housing moving toward the rear of the vehicle, the stopper members 20A and 20B
Becomes invalid, the supporting rigidity K _U becomes relatively low, the difference between the supporting rigidity K _U and K _L becomes small, and the elastic center C approaches the wheel center WC.

Then, even if the engine braking force F _B is input to the axle housing, the rotational displacement of the axle housing does not occur or is extremely small. Therefore, the vertical displacement of the lateral link 7 becomes almost zero, and No vertical force is input.

That is, according to the present embodiment, while the same operational effect as that of the first embodiment is exhibited at the time of acceleration, at the time of engine braking, the reverse operation is effected by the action opposite to that of the first embodiment. In addition, it is possible to prevent the rear part of the vehicle body from being lifted up, and it is possible to suppress changes in the posture during engine braking, which improves the sense of security.

[0053] Rather, the support rigidity K _U during acceleration, by appropriately selecting the supporting rigidity K _U and supporting rigidity K _L during engine braking, so that the elastic center C is positioned at the position as shown in FIG. 7 at the time of acceleration If the elastic center C is positioned slightly below the wheel center WC during engine braking, the feeling of acceleration during acceleration is improved, and a force in the direction of depression is input to the rear part of the vehicle body during engine braking. The force in the sinking direction can offset or reduce the force in the direction that lifts the rear part of the vehicle body due to the load movement to the front of the vehicle during engine braking, and the vehicle attitude during engine braking can be kept flatter. become able to.

9 to 11 are views showing a third embodiment of the present invention. Since the overall configuration is the same as that of the first embodiment, its illustration and description will be omitted.
Further, the same members and the like as those in the first embodiment are designated by the same reference numerals, and the duplicated description thereof will be omitted.

That is, in this embodiment, the elastic bush 5A of the radius rod 5 is the outer cylinder 5a and the outer cylinder 5a.
A double cylinder type elastic bushing composed of an inner cylinder 5b coaxially inserted in a and an elastic body 5c interposed between the outer cylinder 5a and the inner cylinder 5b is adopted. And the inner cylinder 5b is fixed to the axle housing side.

A slit 5d extending in a substantially arc shape is formed in a portion of the elastic body 5c on the vehicle rear side of the inner cylinder 5b, and a portion of the elastic body 5c on the vehicle front side of the inner cylinder 5b is formed. A hollow curled portion 5e is formed. It should be noted that when no load is applied to the elastic bush 5A from the outside, the slit 5d is closed and the cut portion 5e is opened.

With such a structure, the relationship between the vehicle longitudinal force (vertical axis) input to the axle housing and the vehicle longitudinal relative displacement between the lower portion of the axle housing and the suspension member (horizontal axis) is shown. , As shown in FIG. That is, FIG. 10 shows the support rigidity K in the vehicle front-rear direction between the lower portion of the axle housing and the suspension member.
_Although it shows the characteristic of _L , when a forward force is input to the axle housing (during acceleration), the inner cylinder 5b of the elastic bush 5A tries to move to the front of the vehicle,
Since the elastic body 5c is deformed in the opening direction of the slit 5d,
The rigidity of the elastic body 5c remains relatively low as determined by the size of the currant portion 5e and the like, and the supporting rigidity K _L becomes low (soft). On the other hand, when backward force is input to the axle housing (when the engine is braking)
In addition, since the inner cylinder 5b tends to move toward the rear of the vehicle, the elastic body 5c is deformed in the direction in which the slit 5d is closed and pressed, so that the rigidity of the elastic body 5c becomes high and the support rigidity K _U becomes high ( It becomes hard).

Then, at the time of acceleration, similarly to the case described with reference to FIG. 7 in the second embodiment, the supporting rigidity K _{U is obtained.}
Is high and the supporting rigidity K _L is low, the elastic center C is located above the wheel center WC and relatively distant from the wheel center WC. Therefore, due to the same operation as that of the first embodiment, a downward force is input to the vehicle body 13 through the coil spring 10, the depression of the rear portion of the vehicle body is promoted, and the feeling of acceleration is improved.

[0059] In contrast, as shown in FIG. 11, at the time of engine braking, since the engine braking force F _B is inputted to the axle housing, as a result of the axle housing tends to move toward the rear of the vehicle, rigidity of the support rigidity K _L Becomes higher, the difference between the supporting rigidity K _U and K _L becomes smaller, and the elastic center C approaches the wheel center WC. Then, even if the engine braking force F _B is input to the axle housing, the rotational displacement of the axle housing does not occur or is extremely small, so that the vertical displacement of the lateral link 7 becomes substantially zero, and the vertical displacement of the vehicle body 13 in the vertical direction. No force is input.

That is, even in the present embodiment, similar to the second embodiment, the same operational effect as in the first embodiment is exhibited at the time of acceleration, while the above-mentioned effect is obtained at the time of engine braking. It is possible to prevent the rear portion of the vehicle body from being lifted up by the action reverse to that of the first embodiment, and it is possible to suppress the posture change during engine braking and to improve the sense of security.

Even with the structure of the present embodiment, if the elastic center C is located slightly below the wheel center WC during engine braking, the sunk that is input to the rear part of the vehicle body during engine braking will occur. By the force in the inward direction, it is possible to cancel or reduce the force in the direction of raising the rear part of the vehicle body due to the load movement to the front of the vehicle at the time of engine braking, and it becomes possible to keep the vehicle attitude at the time of engine braking more flat. .

12 and 13 are diagrams showing a fourth embodiment of the present invention. Since the overall configuration is the same as that of the first embodiment, its illustration and description will be omitted. Further, the same members and the like as those in the first embodiment are designated by the same reference numerals, and the duplicated description thereof will be omitted.

That is, this embodiment has substantially the same structure as that of the second embodiment, except that the front-back force is not input to the axle housing, as shown in FIG. As described above, the elastic bush 8B of the upper arm 8 is
And 8C and a predetermined clearance are formed between the stopper members 20A and 20B, and when a certain amount of vehicle forward force is input to the axle housing, the elastic bushes 8B and 8C come into contact with the stopper members 20A and 20B. That is the point.

With such a structure, the supporting rigidity K
_As shown in FIG. 13, _U has a low supporting rigidity K _U (soft) as in the second embodiment when a rearward vehicle force is input to the axle housing, but the vehicle has Even if a forward force is input, the supporting rigidity K is maintained until the elastic bushes 8B and 8C of the upper arm 8 and the stopper members 20A and 20B come into contact with each other.
_U becomes low, and after they come into contact, the supporting rigidity K _U becomes high (hard).

Therefore, as in the case of the second embodiment, the posture change during engine braking can be suppressed to improve the sense of security, and the supporting rigidity can be maintained even at the time of acceleration when the acceleration is small and the acceleration is small. Since K _U remains low, no force that positively sinks the rear part of the vehicle body is generated, but the support rigidity K _U becomes high at the time of sudden acceleration with a large depression of the accelerator, and the same operation as in the first embodiment described above. As a result, a force that positively sinks the rear part of the vehicle body is generated, and the feeling of acceleration can be improved.

That is, in the case of the fourth embodiment,
The vehicle attitude control using the rotational displacement of the axle housing can be performed more finely. In addition,
In the above embodiments, at as but the elastic center C during acceleration is to be located above the wheel center WC, for example, it is smaller than the supporting rigidity K _U during acceleration support rigidity K _L, The elastic center C may be located below the wheel center WC. However, in that case, the axle housing 2 is rotationally displaced in the direction opposite to that described with reference to FIG. 4 in the first embodiment, so that the rear portion of the vehicle body is depressed during acceleration. Must connect the lower end of the coil spring 10 or the end of the lateral link 7 supporting the coil spring 10 to the axle housing 2 on the front side of the wheel center WC. Even in this case, as the second embodiment and the third embodiment, the size of the support rigidity K _U and K _L between time of acceleration and engine braking so as to change the engine You may make it suppress the sinking of the rear part of the vehicle body at the time of braking.

In each of the above embodiments, the present invention is
Although the case where the present invention is applied to the suspension on the rear wheel side of the vehicle as the drive wheel has been described, the present invention is not limited to this and may be applied to the suspension on the front wheel of the vehicle as the drive wheel, or a four-wheel drive vehicle. In this case, it may be applied to both front and rear suspensions as driving wheels.

However, the suspension of the front wheels of the vehicle as the driving wheels
The present invention is applied to the application to improve the feeling of acceleration.
Then, contrary to the above-mentioned embodiments, the vehicle body is lifted up.
There is a need. Therefore, the elastic center C during acceleration is set to the wheel center.
Coil WC
Supports the lower end of the pulling 10 or the coil spring 10.
Connect the end of the lateral link 7 to the wheel center WC.
It is necessary to connect to the axle housing 2 on the front side
However, the elastic center C during acceleration is lower than the wheel center WC.
The coil spring 10 below
Suspension supporting end or coil spring 10
Align the end of the link with the rear side of the wheel center WC.
It must be connected to the axle housing 2. And drive
The present invention is applied to a suspension of a front wheel of a vehicle as a driving wheel.
Even if it is done, the form of the second embodiment or the third embodiment
Support rigidity during acceleration and engine braking
K _UAnd K_LThe size of the engine
Suppress the lifting of the front part of the car body during rake and make the car body more
You may make it flat.

Further, in each of the above-mentioned embodiments, the present invention is applied to the suspension of the drive wheels, but the present invention is not limited to this, and is applied to the suspension of the vehicle rear wheels and the vehicle front wheels as the driven wheels. You may. However, since the driven wheels rotate following the movement of the axle in the vehicle front-rear direction, the driving force F _D and engine braking force F _B input to the axle housing that rotatably supports the driven wheels.
Is in the opposite direction to that of the drive wheels, so its driving force F _D
And the engine braking force F _B causes the axle housing to be rotationally displaced, and the rotational displacement is caused by coil spring
When converting to vertical force via the and transmitting to the vehicle body,
The direction of the vertical force is opposite to that in the case of the drive wheel suspension. Therefore, the position of the elastic center C with respect to the wheel center WC, the lower end of the coil spring 10 or the connecting position of the end of the suspension link supporting the coil spring 10 to the axle housing is set so that a vertical force in a desired direction is generated. It is necessary to set it appropriately.

Further, in each of the above-mentioned embodiments, in order to improve the feeling of acceleration, the rear part of the vehicle body is depressed at the time of acceleration. However, for example, it is desired to make the vehicle body flat during both acceleration and engine braking. In order to meet such a requirement, a force may be generated to lift the rear part of the vehicle body during acceleration, and a force may be generated to sink the rear part of the vehicle body during engine braking. For example, in the case of the configuration of the first embodiment described above, the position of the elastic center C is located below the wheel center WC, or the coil spring 10 is placed in the wheel center WC.
If it is connected to the axle housing 2 on the front side, a force in the direction of raising the rear part of the vehicle body is generated during acceleration, and a force in the direction of sinking the rear part of the vehicle body is generated during engine braking.

In each of the above-described embodiments, the rotational displacement of the axle housing 2 is converted into a vertical force by using the coil spring 10 and transmitted to the vehicle body 13 side, but the present invention is not limited to this. However, the shock absorber 11 can be used by appropriately selecting the connecting position of the shock absorber 11 on the lower side of the spring. In some cases, both the coil spring 10 and the shock absorber 11 are used. May be.

In each of the above embodiments, the coil spring 10 is connected to the axle housing 2 via the lateral link 7, but the coil spring 10 may be directly connected to the axle housing 2. .

Further, although the second and third embodiments are described separately, these second and third embodiments
By combining both the embodiment and the third embodiment, the position of the elastic center C may be moved up and down during acceleration and during engine braking.

[Brief description of drawings]

FIG. 1 is a perspective view of a vehicle suspension according to a first embodiment.

FIG. 2 is a side view of the vehicle suspension according to the first embodiment.

FIG. 3 is an explanatory diagram of a relationship between support rigidity K _U , K _L and elastic center C.

FIG. 4 is an explanatory diagram of an operation of the first embodiment.

FIG. 5 is a plan view of an upper arm showing a second embodiment.

FIG. 6 is a characteristic diagram of a support rigidity K _U in the second embodiment.

FIG. 7 is an explanatory diagram of an operation during acceleration according to the second embodiment.

FIG. 8 is an explanatory diagram of an operation during engine braking according to the second embodiment.

FIG. 9 is an enlarged view showing a main part of the third embodiment.

FIG. 10 is a characteristic diagram of a support rigidity K _L in the second embodiment.

FIG. 11 is an explanatory diagram of an operation during engine braking according to the third embodiment.

FIG. 12 is a plan view of an upper arm showing a fourth embodiment.

FIG. 13 is a characteristic diagram of the support rigidity K _{U according to} the fourth embodiment.

[Explanation of symbols]

1 Axle 2 Axle housing 3 Suspension member (vehicle side member) 5 Radius rod 6 Lateral link 7 Lateral link (Suspension link) 8 Upper arm 10 Coil spring 11 Shock absorber 13 Vehicle body 20A, 20B Stopper member C Elastic center W Wheel WC Wheel center

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-2-306805 (JP, A) JP-A-3-99914 (JP, A) JP-A-64-70207 (JP, A) JP-B 3- 56922 (JP, B2) Actual public 7-37928 (JP, Y2) Actual public 5-25928 (JP, Y2) (58) Fields investigated (Int.Cl. ⁷ , DB name) B60G 3/18-3 / 28 B60G 7/02

Claims (10)

(57) [Claims] 1. An elastic center for an input in the vehicle front-rear direction of the axle housing, which is determined by a supporting rigidity in a vehicle front-rear direction between an axle housing that rotatably supports a vehicle rear wheel that is a drive wheel and a vehicle body side member, A spring that supports the vehicle body and is located above the wheel center.
And / or shock absorber
Connection point to the axle housing or the splice
And / or shock absorber
Said axle housing of combined suspension links
The connection point to the rear of the vehicle from the wheel center.
In addition, the upper part of the axle housing and the side part of the vehicle body
The support rigidity in the vehicle front-rear direction between the
It is not high when the vehicle-forward force is input to the housing.
The vehicle rearward force is input to the axle housing.
A suspension for a vehicle, which is characterized in that it is lowered when subjected to . 2. A method vehicles elastic center with respect to the vehicle longitudinal direction of the input of the axle housing which is determined by the support rigidity in the longitudinal direction between the axle Pillow grayed and the vehicle body-side member for rotatably supporting the vehicle rear wheel is a drive wheel , Above the wheel center and at the connecting point of at least one of a spring and a shock absorber supporting the vehicle body to the axle housing or a suspension link to which at least one of the spring and the shock absorber is coupled. The connection point to the axle housing is on the vehicle rear side of the wheel center , and the lower portion of the axle housing and the vehicle body side portion
The support rigidity in the vehicle front-rear direction between the
If the vehicle's forward force is input to the housing, it should be low.
The vehicle rearward force is input to the axle housing.
A suspension for a vehicle, which is characterized in that it is set to be higher when subjected to . The 3. A vehicle elastic center with respect to the vehicle longitudinal direction of the input of the axle housing which is determined by the support rigidity in the longitudinal direction between the axle Pillow grayed and the vehicle body-side member for rotatably supporting the vehicle rear wheel is a drive wheel , Below the wheel center and at a connection point of at least one of a spring and a shock absorber supporting the vehicle body to the axle housing or a suspension link to which at least one of the spring and the shock absorber is coupled. The connecting point to the axle housing is on the vehicle front side of the wheel center , and the upper portion of the axle housing and the vehicle body side portion
The support rigidity in the vehicle front-rear direction between the
If the vehicle's forward force is input to the housing, it should be low.
The vehicle rearward force is input to the axle housing.
A suspension for a vehicle, which is characterized in that it is set to be higher when subjected to . 4. A vehicle elastic center with respect to the vehicle longitudinal direction of the input of the axle housing which is determined by the support rigidity in the longitudinal direction between the axle Pillow grayed and the vehicle body-side member for rotatably supporting the vehicle rear wheel is a drive wheel , Below the wheel center and at a connection point of at least one of a spring and a shock absorber supporting the vehicle body to the axle housing or a suspension link to which at least one of the spring and the shock absorber is coupled. The connecting point to the axle housing is on the vehicle front side of the wheel center , and the lower portion of the axle housing and the vehicle body side portion
The support rigidity in the vehicle front-rear direction between the
It is not high when the vehicle-forward force is input to the housing.
The vehicle rearward force is input to the axle housing.
A suspension for a vehicle, which is characterized in that it is lowered when subjected to . 5. A vehicle elastic center with respect to the vehicle longitudinal direction of the input of the axle housing which is determined by the support rigidity in the longitudinal direction between the axle Pillow grayed and the vehicle body-side member for rotatably supporting the vehicle wheel is a driving wheel, with the upper side of the wheel center, the axle of the suspension link at least one of which is coupled to the at least one coupling point or the spring and shock absorber to the axle housing of the spring and shock absorber for supporting the vehicle body The connecting point to the housing is located on the vehicle front side with respect to the wheel center , and further, the upper portion of the axle housing and the vehicle body side portion.
The support rigidity in the vehicle front-rear direction between the
It is not high when the vehicle-forward force is input to the housing.
The vehicle rearward force is input to the axle housing.
A suspension for a vehicle, which is characterized in that it is lowered when subjected to . 6. A vehicle front wheel, which is a drive wheel, is rotatably supported.
Front and rear of vehicle between axle housing and body side member
Axle housing determined by directional support stiffness
The elastic center of the vehicle
The upper part of the vehicle
And / or shock absorber
Connection point to the axle housing or the splice
And / or shock absorber
Said axle housing of combined suspension links
Connection point to the front of the vehicle rather than the wheel center.
In addition, the support rigidity in the vehicle front-rear direction between the lower portion of the axle housing and the vehicle body side member is reduced when a vehicle forward force is input to the axle housing, and the axle is lowered. A vehicle suspension characterized in that when a rearward-directed force is input to the housing, the force is increased . 7. A vehicle front wheel which is a driving wheel is rotatably supported.
Front and rear of vehicle between axle housing and body side member
Axle housing determined by directional support stiffness
The elastic center of the vehicle
The lower side of the engine and the sprue that supports the vehicle body.
And / or shock absorber
Connection point to the axle housing or the splice
And / or shock absorber
Said axle housing of combined suspension links
The connection point to the rear of the vehicle from the wheel center.
In addition, the support rigidity in the vehicle front-rear direction between the upper portion of the axle housing and the vehicle body side member becomes low when a vehicle frontward force is input to the axle housing, and the vehicle rearward orientation is reduced in the axle housing. A vehicle suspension characterized in that it becomes higher when force is input. 8. A vehicle front wheel, which is a driving wheel, is rotatably supported.
Front and rear of vehicle between axle housing and body side member
Axle housing determined by directional support stiffness
The elastic center of the vehicle
The lower side of the engine and the sprue that supports the vehicle body.
And / or shock absorber
Connection point to the axle housing or the splice
And / or shock absorber
Said axle housing of combined suspension links
The connection point to the rear of the vehicle from the wheel center.
And, further, the vehicle support rigidity in the longitudinal direction between the lower and the vehicle body-side member of the axle housing, Ri high rather Do <br/> if the vehicle forward force is inputted to the axle housing, wherein A vehicle suspension characterized in that it is lowered when a rearward force is input to the axle housing. <br /> 9. A support rigidity in a vehicle front-rear direction between a lower portion of the axle housing and a vehicle body-side member is lowered when a vehicle forward force is input to the axle housing, and the axle is lowered. The vehicle suspension according to claim 1 or 5 , wherein the force is increased when a backward force of the vehicle is input to the housing. 10. A lower portion of the axle housing and a vehicle body side
The support rigidity in the vehicle front-rear direction between the member and
High when vehicle forward force is input to the housing
The vehicle rearward force is applied to the axle housing.
Claim 3 or claim so as to be lowered when forced
Item 7. The vehicle suspension according to item 7.