CN215970994U - Toe-in self-adjusting torsion beam rear axle - Google Patents

Abstract

The utility model provides a toe-in self-torsion beam rear axle which comprises a rear axle welding assembly, a wheel support mounting plate, a front bushing, a rear bushing and a ball pin, wherein the wheel support mounting plate is fixed at the end part of the rear axle welding assembly, the front bushing and the rear bushing are respectively pressed into the left side part and the right side part of the wheel support, the ball pin is pressed into the upper part of the wheel support, and the wheel support is integrally assembled with the wheel support mounting plate through the front bushing, the rear bushing and the ball pin. The utility model can greatly improve the vehicle operation stability, improve the steering response and the riding comfort of the rear suspension and ensure that the hardness of the front suspension and the rear suspension are better balanced by improving the rear axle. The toe-in self-adjusting torsion beam rear axle can improve the comfort and improve the operation stability.

Description

Toe-in self-adjusting torsion beam rear axle

Technical Field

The utility model relates to the field of automobiles, in particular to a toe-in self-adjusting torsion beam rear axle.

Background

In the field of automobiles, a torsion beam rear axle is widely applied to rear suspensions of small and medium-sized cars due to simple structure, low cost and small occupied space.

However, the torsion beam rear axle is mounted on the vehicle body only through the bush of the front point of the longitudinal arm, and the hub bearing and the rear axle are assembled through the wheel bracket and are in hard connection. When the rear wheel receives lateral force, the whole rear axle rotates around the front point of the longitudinal arm, and the lateral force received by the rear wheel is opposite to the steering of the rear axle when the rear wheel steers, so that the vehicle tends to oversteer.

Meanwhile, in order to avoid the tire, the connection point of the trailing arm and the vehicle body is closer to the inner side relative to the wheel. Therefore, when braking or receiving a longitudinal force, the wheel tends to be unstable due to the trailing arm deformation in a state of usually being flared (toe-in angle is reduced).

In view of this, the utility model people of this application have designed a toe-in selftwist beam rear axle to overcome above-mentioned technical problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects that vehicles have oversteering tendency and the like when a torsion beam rear axle is steered in the prior art, and provides a toe-in self-adjusting torsion beam rear axle.

The utility model solves the technical problems through the following technical scheme:

the utility model provides a toe-in auto-twist beam rear axle, its characterized in that, toe-in auto-twist beam rear axle includes rear axle welding assembly, wheel support mounting panel, preceding bush, back bush and ball round pin, wheel support mounting panel is fixed the tip of rear axle welding assembly, preceding bush with the back bush is impressed respectively the left and right sides portion of wheel support, the ball round pin is impressed the upper portion of wheel support, the wheel support passes through preceding bush the back bush with the ball round pin with wheel support mounting panel assembles as an organic wholely.

According to one embodiment of the utility model, the rear axle welding assembly comprises a cross beam and two trailing arms, wherein the trailing arms are respectively welded at two ends of the cross beam;

the wheel support is assembled with the hub bearing or the drum brake through a fixing piece.

According to one embodiment of the present invention, the front bushing, the rear bushing, and the ball pin are assembled with the wheel carrier mounting plate by fixing members.

According to one embodiment of the utility model, the left and right sides of the lower part of the wheel support mounting plate are respectively provided with a first connecting part and a second connecting part, the front bushing is connected with the first connecting part through a bolt and a nut, and the rear bushing is connected with the second connecting part through a bolt and a nut.

According to one embodiment of the present invention, the left and right sides of the upper end portion of the wheel carrier mounting plate are respectively provided with outwardly projecting mounting surfaces, and the ball pin is mounted between the mounting surfaces by bolts and nuts.

According to one embodiment of the utility model, the other end of the trailing arm is provided with a body bushing.

According to one embodiment of the utility model, the toe-in self-twist beam rear axle projects to an XZ plane, and in the X direction, the central point of the ball pin is 47.1-67.1mm away from the wheel center point of the automobile tire, the central point of the front bushing is 62.1-82.1mm away from the wheel center point of the automobile tire, and the central point of the rear bushing is 22.9-42.9mm away from the wheel center point of the automobile tire.

According to one embodiment of the utility model, the toe-in self-twist beam rear axle projects to an XZ plane, and in the Z direction, the central point of the ball pin is 55.5-65.5mm away from the wheel center point of the automobile tire, the central point of the front bushing is 74.5-94.5mm away from the wheel center point of the automobile tire, and the central point of the rear bushing is 69.5-89.5mm away from the wheel center point of the automobile tire.

According to one embodiment of the utility model, the toe-in self-twist beam rear axle projects to an XY plane, and in a Y direction, the central point of the ball pin is 80-100mm away from the wheel center point of the automobile tire, the central point of the front bushing is 52-72mm away from the wheel center point of the automobile tire, and the central point of the rear bushing is 49-69mm away from the wheel center point of the automobile tire.

According to one embodiment of the utility model, the radial rigidity of the front bushing and the rear bushing is 12000-18000N/mm, and the axial rigidity is 500-1000N/mm.

The positive progress effects of the utility model are as follows:

according to the toe-in self-adjusting torsion beam rear axle, the rear axle is improved, so that the vehicle operation stability can be greatly improved, the steering response and the riding comfort of the rear suspension are improved, and the hardness of the front suspension and the rear suspension are better balanced. The toe-in self-adjusting torsion beam rear axle can improve the comfort and improve the operation stability.

Drawings

The above and other features, properties and advantages of the present invention will become more apparent from the following description of the embodiments with reference to the accompanying drawings in which like reference numerals denote like features throughout the several views, wherein:

fig. 1 is a front view of a toe-in autotwist beam rear axle of the present invention.

Fig. 2 is a schematic structural view of a toe-in auto-twist beam rear axle according to the present invention.

Fig. 3 is a schematic diagram of the use of the toe-in autotwist beam rear axle of the present invention.

Fig. 4 is a schematic view of the toe-in autotwist beam rear axle of the present invention projected onto the XZ plane.

Fig. 5 is a schematic view of the toe-in autotwist beam rear axle projected onto the XY plane in accordance with the present invention.

[ reference numerals ]

Rear axle welding assembly 10

Wheel support 20

Wheel carrier mounting plate 30

Front bushing 40

Rear bushing 50

Ball pin 60

Cross member 11

Trailing arm 12

First connecting portion 31

Second connecting part 32

Mounting surface 33

Vehicle body bushing 70

At ground point A

Intersection point B

Instantaneous center of velocity C

Center of wheel point D

Wheel 80

Center point 61 of ball pin

Center point 41 of the front bushing

Center point 51 of the rear bushing

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

Embodiments of the present invention will now be described in detail with reference to the accompanying drawings. Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.

Further, although the terms used in the present invention are selected from publicly known and used terms, some of the terms mentioned in the description of the present invention may be selected by the applicant at his or her discretion, the detailed meanings of which are described in relevant parts of the description herein.

Furthermore, it is required that the present invention is understood, not simply by the actual terms used but by the meaning of each term lying within.

Fig. 1 is a front view of a toe-in autotwist beam rear axle of the present invention. Fig. 2 is a schematic structural view of a toe-in auto-twist beam rear axle according to the present invention. Fig. 3 is a schematic diagram of the use of the toe-in autotwist beam rear axle of the present invention. Fig. 4 is a schematic view of the toe-in autotwist beam rear axle of the present invention projected onto the XZ plane. Fig. 5 is a schematic view of the toe-in autotwist beam rear axle projected onto the XY plane in accordance with the present invention.

As shown in fig. 1 to 5, the utility model discloses a toe-in twist beam rear axle, which comprises a rear axle welding assembly 10, a wheel bracket 20, a wheel bracket mounting plate 30, a front bushing 40, a rear bushing 50 and a ball pin 60, wherein the wheel bracket mounting plate 30 is fixed at the end part of the rear axle welding assembly 10, the front bushing 40 and the rear bushing 50 are respectively pressed into the left side part and the right side part of the wheel bracket 20, the ball pin 60 is pressed into the upper part of the wheel bracket 20, and the wheel bracket 20 is integrally assembled with the wheel bracket mounting plate 30 through the front bushing 40, the rear bushing 50 and the ball pin 60.

Preferably, the rear axle welding assembly 10 includes a cross beam 11 and two trailing arms 12, and the trailing arms 12 are welded to both ends of the cross beam 11, respectively. The wheel carrier 20 is assembled with a hub bearing or a drum brake by fixing members. The fixing member may preferably be a bolt.

Further, the front bushing 40, the rear bushing 50, and the ball pin 60 are assembled with the wheel carrier mounting plate 30 by fixing members. The left and right sides of the lower portion of the wheel carrier mounting plate 30 are respectively provided with a first connecting portion 31 and a second connecting portion 32, the front bushing 40 is connected to the first connecting portion 31 by bolts and nuts, and the rear bushing 50 is connected to the second connecting portion 32 by bolts and nuts.

Mounting surfaces 33 protruding outward are provided on the left and right sides of the upper end portion of the wheel carrier mounting plate 30, respectively, and the ball pin 60 is mounted between the mounting surfaces 33 by bolts and nuts.

Further, a vehicle body bushing 70 is provided at the other end portion of the trailing arm 12 for connection to a vehicle body.

The toe-in self-adjusting torsion beam rear axle generates a virtual kingpin axis through the deformation of the front bushing and the structure, and a rear wheel in an automobile tire rotates slightly around the virtual kingpin axis when being stressed. The virtual kingpin axis of a conventional twist beam rear suspension intersects the ground at a point B generally forward of the wheel 80 and inboard of the center plane of the wheel 80, and when the vehicle is turning, the moment developed about the instantaneous axis tends to oversteer the vehicle. When the vehicle brakes, the rear wheel receives backward braking force at the grounding point, and the moment is formed around the instantaneous king pin axis, so that the toe-in of the rear wheel is expanded, and the braking stability of the vehicle is reduced.

Preferably, the hard point is projected to an XZ plane (namely the toe-in twist beam rear axle is projected to the XZ plane) by adjusting the hard point arrangement and changing the virtual kingpin axis, and in the X direction, the central point 61 of the ball pin 60 is 47.1-67.1mm away from the wheel center point D of the automobile tire, the central point 41 of the front bush 40 is 62.1-82.1mm away from the wheel center point D of the automobile tire, and the central point 51 of the rear bush 50 is 22.9-42.9mm away from the wheel center point D of the automobile tire.

The projection of the toe-in self-twist beam rear axle to the XZ plane is that in the Z direction, the central point 61 of the ball pin 60 is 55.5-65.5mm away from the wheel center point D of the automobile tire, the central point 41 of the front bush 40 is 74.5-94.5mm away from the wheel center point D of the automobile tire, and the central point 51 of the rear bush 50 is 69.5-89.5mm away from the wheel center point D of the automobile tire.

The toe-in self-twist beam rear axle projects to an XY plane, in the Y direction, the distance from the central point 61 of the ball pin 60 to the wheel center point D of the automobile tire is 80-100mm, the distance from the central point 41 of the front bushing 40 to the wheel center point D of the automobile tire is 52-72mm, and the distance from the central point 51 of the rear bushing 50 to the wheel center point D of the automobile tire is 49-69 mm.

As shown in fig. 3, the toe-in self-torsion beam rear axle according to the present invention changes the virtual kingpin axis by adjusting the hard point arrangement so that the intersection points B of the virtual kingpin axis and the ground are on the rear side and the outer side of the wheel, and the upper ball pin provides all rotational degrees of freedom to restrict all degrees of freedom of movement, so that the virtual kingpin axis must pass through the upper ball pin, and the rotation below the wheel bracket is generated by the deformation of the bushing. According to the instant center theorem, the virtual kingpin axis passes through the speed instant center C at two points of the lower bushing, and the rear axle can simultaneously change the defects of over-steering of the original rear axle and outward expansion of wheel braking, so that the operation stability is greatly improved.

According to the structural description, the toe-in self-torsion beam rear axle is characterized in that a wheel support mounting plate and a longitudinal arm are connected through welding, two bushings and a ball pin are respectively pressed into a wheel support from the left side and the right side, the wheel support mounting plate is assembled through bolts and nuts, and the wheel support is assembled with a hub bearing or a drum brake through bolts.

The toe-in self-torsion beam rear axle has the following advantages:

the wheel support is connected with the rear axle welding assembly through the bushing and the ball pin, road surface load is transferred, the filtering portion jolts, the NVH characteristic of the rear axle is improved, and the comfort of a vehicle is improved.

And secondly, the front bushing of the rear axle of the torsion beam and the structure deform to generate a virtual kingpin axis, and the rear wheel rotates slightly around the virtual kingpin axis when stressed. The intersection of the virtual kingpin axis of a conventional twist beam rear suspension with the ground is generally forward of the wheel and inboard of the wheel center plane, and when the vehicle turns, the moment about the instantaneous axis creates a tendency for the vehicle to oversteer. When the vehicle brakes, the rear wheel receives a moment formed by a backward braking force at the grounding point A around the instantaneous king pin axis, so that the toe-in of the rear wheel is expanded, and the braking stability of the vehicle is reduced.

And thirdly, for the front beam self-adjusting torsion beam rear axle, the lateral stiffness is generally required to be large to ensure the response of a rear suspension except for the requirement of reasonable deformation of a positioning angle, and the longitudinal stiffness is required to be small to ensure the longitudinal flexibility.

Therefore, the radial rigidity of the bushing is enough (for example 12000-18000N/mm), the axial rigidity is small (for example 500-1000N/mm)) to resist the lateral force along the y direction of the whole vehicle as much as possible, and the deformation direction is the axial rigidity.

In conclusion, the front-toe self-torsion beam rear axle can greatly improve the vehicle operation stability, improve the steering response and the riding comfort of the rear suspension and ensure that the hardness of the front suspension and the rear suspension are better balanced by improving the rear axle. The toe-in self-adjusting torsion beam rear axle can improve the comfort and improve the operation stability.

While specific embodiments of the utility model have been described above, it will be appreciated by those skilled in the art that these are by way of example only, and that the scope of the utility model is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and scope of the utility model, and these changes and modifications are within the scope of the utility model.

Claims (10)

1. The utility model provides a toe-in self-modulation torsion beam rear axle, its characterized in that, toe-in self-modulation torsion beam rear axle includes rear axle welding assembly, wheel support mounting panel, preceding bush, back bush and ball round pin, wheel support mounting panel is fixed the tip of rear axle welding assembly, preceding bush with the back bush is impressed respectively the left and right sides portion of wheel support, the ball round pin is impressed the upper portion of wheel support, the wheel support passes through preceding bush the back bush with the ball round pin with wheel support mounting panel assembles as an organic wholely.

2. The toe twist beam rear axle according to claim 1, wherein the rear axle welding assembly comprises a cross beam and two trailing arms, the trailing arms being welded to two ends of the cross beam, respectively;

the wheel support is assembled with the hub bearing or the drum brake through a fixing piece.

3. The toe twist beam rear axle according to claim 1, wherein the front bushing, the rear bushing and the ball pin are assembled with the wheel bracket mounting plate by a fixing member.

4. The toe-in twist beam rear axle according to claim 3, wherein a first connecting portion and a second connecting portion are respectively provided on the left and right sides of the lower portion of the wheel bracket mounting plate, the front bushing is connected to the first connecting portion through a bolt and a nut, and the rear bushing is connected to the second connecting portion through a bolt and a nut.

5. The toe-in twist beam rear axle according to claim 3, wherein the left and right sides of the upper end portion of the wheel bracket mounting plate are respectively provided with outwardly projecting mounting surfaces, and the ball pin is mounted between the mounting surfaces through a bolt and a nut.

6. The toe twist beam rear axle according to claim 2, wherein the other end portion of the trailing arm is provided with a body bushing.

7. The toe twist beam rear axle according to claim 1, wherein the toe twist beam rear axle projects to an XZ plane, and in the X direction, the center point of the ball pin is 47.1-67.1mm from the wheel center point of the automobile tire, the center point of the front bushing is 62.1-82.1mm from the wheel center point of the automobile tire, and the center point of the rear bushing is 22.9-42.9mm from the wheel center point of the automobile tire.

8. The toe twist beam rear axle according to claim 1, wherein the toe twist beam rear axle projects to an XZ plane, and in the Z direction, the center point of the ball pin is 55.5-65.5mm from the wheel center point of the automobile tire, the center point of the front bushing is 74.5-94.5mm from the wheel center point of the automobile tire, and the center point of the rear bushing is 69.5-89.5mm from the wheel center point of the automobile tire.

9. The toe twist beam rear axle according to claim 1, wherein the toe twist beam rear axle projects to an XY plane, and in a Y direction, a center point of the ball pin is 80-100mm from a wheel center point of an automobile tire, a center point of the front bushing is 52-72mm from the wheel center point of the automobile tire, and a center point of the rear bushing is 49-69mm from the wheel center point of the automobile tire.

10. The toe twist beam rear axle according to claim 1, wherein the radial stiffness of the front bushing and the rear bushing is 12000-18000N/mm and the axial stiffness is 500-1000N/mm.

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