KR100440007B1 - A drive shaft of differential gear - Google Patents

Abstract

The present invention absorbs and attenuates the axial force generated at the differential gear side joint during the driving of the vehicle, in particular during the turning drive, and prevents the axial force from moving to the wheel side, thereby improving the quietness and ride comfort of the vehicle. Provide the shaft. The drive shaft includes a first body having a differential gear side joint on one side, a body separated by a second body having a wheel side joint on one side, and a first body and a second body to interconnect the first body and the second body. It is fixedly arranged at the other end and consists of axial force damping device for absorbing and attenuating axial force generated in the differential gear side joint. The damping device includes a first mount fixed to the other end of the first body, a second mount fixed to the other end of the second body, and a damping member to which the first mount and the second mount are fixed to both sides and connected to each other. And fastening means for fastening the first mount, the second mount, and the damping member integrally.

Description

A drive shaft of differential gear

The present invention relates to a drive shaft for a longitudinal deceleration differential of an automobile, and more particularly, to prevent the axial force generated from the differential gear side joint from being transmitted to the wheel side, thereby preventing lateral fluctuation of the vehicle and improving riding comfort. A drive shaft of a longitudinal deceleration differential device.

In general, most automobiles, such as passenger cars, are equipped with a longitudinal deceleration differential, which receives the rotational power from the transmission through a propeller shaft and converts it to a right angle or a substantially right angle as well as increase torque. Final deceleration is being done for. In addition, the longitudinal deceleration differential device serves to generate a rotation difference of the left and right wheels according to the turning or road surface conditions while the vehicle is driving, and for this purpose, it is installed in the axle housing together with the longitudinal reduction gear.

On the other hand, as shown in Figure 1, the drive shaft (3) is connected to both sides to the differential gear (2) built in the axle housing (1), and the wheel (4) at the end of each drive shaft (3) ) Is connected, and as a result, the wheel is driven by the decelerated rotational power. The drive shaft 3 is connected to the differential gear 2 via a joint 4 such as a treeport joint, as shown in FIG. 2, and at its opposite end the wheel 4 via a joint 5 such as a ball joint. Is connected to the axle.

However, when the longitudinal deceleration differential device and the drive shaft having such a configuration are driven, some problems are caused because the axial force generated in the differential gear side joint is transmitted without attenuation to the wheel side joint. In other words, the joint such as the tripod joint on the side of the differential device increases the axial force in the axial direction as the driving force and the joint angle become larger, thereby generating resonance along with the lateral natural frequency of the vehicle during low acceleration of the vehicle. It causes vibration and swing in the left and right directions, thereby causing a deterioration of ride comfort and instability.

On the other hand, in order to solve this problem, a method of adopting a shredderless joint structure capable of preventing or preventing the tripod joint recently has been proposed, but in this case, the frictional force component of the axial force is reduced or reduced. Although there is a limit to the reduction of the component of the axial force due to the fundamental driving force, there is also a problem that when the operating angle is large or the input torque is large, the lateral vibration is similarly brought down and the riding comfort and noise prevention performance is deteriorated.

Therefore, the present invention has been invented to solve the above-mentioned problems, and an object of the present invention is to provide a drive shaft of a longitudinal reduction differential device capable of absorbing and attenuating vibration generated during driving of a vehicle to improve ride comfort and noise prevention performance. To provide.

Another object of the present invention is to provide a drive shaft of a longitudinally decelerating differential device which can prevent the axial force generated in the differential gear side joint from being transmitted to the wheel side joint.

Still another object of the present invention is to reduce all components of the axial force generated on the differential gear side, to prevent the generation of noise due to the rotational play, and to reduce the noise generated from the transmission itself. To provide a drive shaft.

1 is a perspective view schematically showing an installation state of a drive shaft of a longitudinal reduction gear of a typical vehicle.

2 is a front view showing the drive shaft of FIG.

Figure 3 is a perspective view showing the drive shaft of the longitudinal reduction differential according to the present invention.

Figure 4 is an exploded perspective view of the axial force damping device installed in the drive shaft according to the present invention.

5 is a cross-sectional view taken along the line VV of FIG. 3V.

♣ Explanation of symbols for the main parts of the drawing ♣

10: main body 12, 14: joint

16: first body 18: second body

20: damping device 22: first mount

24, 34: insert 26, 36: flange

28,38: fixing hole 30,40: fixing part

42: damping member 44: through hole

50: bolt 52: nut

Such objects include: a drive shaft of a longitudinal deceleration vehicle of an automobile, comprising: a main body separated into a first body having a differential gear side joint at one side, and a second body having a wheel side joint at one side; And a axial force damping device which is fixedly disposed at the other end of each body to interconnect the first body and the second body and absorbs and attenuates the axial force generated at the differential gear side joint. Can be achieved by a drive shaft.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, referring to FIGS. 3 and 4, the drive shaft of the longitudinal reduction differential device according to the present invention has a main body 10 having a circular cross section. Basically, one side of the main body 10 is provided with a differential gear side joint 12 connected to, for example, a differential gear not shown. In addition, the other side of the main body 10 is provided with a wheel side joint 14 connected to a wheel (not shown). Of course, each of these joints are composed of a tripod joint or a ball joint, such a joint scheme is well known, and thus detailed description thereof is omitted here.

In particular, the main body 10 is cut at an appropriate position and separated into a first body 16 and a second body 18. As such, the reason why the main body 10 is separated into two parts is to integrate the vibration damping device described later in detail into the main body. Of course, the cutting position of the body 10 is preferably a position that can most effectively absorb and attenuate the axial force generated in the differential gear side joint.

The main body 10 is provided with an axial force damping device 20 for absorbing and damping the axial force generated at the differential gear side joint of the drive shaft. The axial force damping device 20 includes a first mount 22 fixed to an end of the first body 16 of the body 10.

The first mount 22 actually includes an insert 24 which is extrapolated to the end of the first body 16. A flange 26 is integrally formed around the insertion portion 24, and the flanges 26 are formed to extend outward from each other at the same angle and interval, and a plurality of branch fixing portions 30 in which fixing holes 28 are formed, respectively. Is preferably provided. In addition, each fixing portion 30 is integrally formed with a supporting portion 30a in which a hole communicating with each fixing hole is formed. Each support portion 30a serves to be supported on one side of the axial force absorbing member to be described later in detail. In this embodiment, the number of the fixing part 30 is set to three, but may be set to two, three or more depending on the size of the drive shaft.

Correspondingly, the second mount 32 is fixed to the end of the second body 18 of the main body 10. The second mount 32 actually comprises an insert 34 which is extrapolated to the end of the second body 18. A flange 36 is integrally formed around the insertion part 34, and the flange 36 extends outward from each other at the same angle and interval, and each of the plurality of branch fixing parts 40 in which the fixing holes 38 are formed. Is preferably provided. In addition, each fixing portion 40 is integrally formed with a supporting portion 40a in which a hole communicating with each fixing hole is formed. Each support portion 40a serves to be supported on one side of the axial force damping member which will be described later in detail. Of course, it will be apparent that the number of fixing parts 40 of the second mount 32 should be equal to the number of the first mounts 22.

Each of the mounts 22, 32 described above is fixed to both sides of the damping member 42, which can actually absorb and damp the axial force. The damping member 42 is preferably formed of rubber or a compound of rubber and nylon so as to absorb and damp the components of the axial force easily and effectively. In addition, a through hole 44 is formed at the center of the damping member 42. In addition, it is preferable that a plurality of through holes 46 are formed at a predetermined interval around the through holes 44 to correspond more accurately to the sum of the fixing holes formed in each mount. Each through hole 46 is preferably a bushing 48 is inserted for a firm and stable insertion of the bolt described below.

On the other hand, fixing means such as a plurality of bolts 50 and nuts 52 are used to fix each mount 22, 32 to the damping member 42.

Hereinafter, the assembly method of the drive shaft of the present invention configured as described above and its operation mode will be described in detail.

First, the operator presses or welds the cutout of the first body 16 of the two bodies in which the proper position of the main body 10 of the drive shaft is cut into the insertion portion 24 of the first mount 22. In the same way, the cutout of the second body 18 is pressed or welded into the insert 34 of the second mount 32.

Thereafter, each fixing hole 28 formed in the first mount 22 and each fixing hole 38 formed in the second mount 32 are formed in each through hole 46 formed in the damping member 42. It is preferred to be inserted to match. More specifically, in this embodiment, each of the three fixing holes 28 formed in the first mount 22 and the three fixing holes 38 formed in the second mount 32 do not coincide, that is, Each through hole 46 of the damping member 42 is arranged such that only one through hole of each of the fixing holes 28 and 38 of the two mounts 22 and 32 communicates therewith.

In this state, the operator bolts the nut 52 in a state in which the bolts 50 are respectively inserted into respective communication holes communicating with the through hole 46 on the damping member 42 and one of the fixing holes of the two mounts. By fastening to 50, installation of the axial force damping device 20 with respect to the main body 10 is completed.

In the state where the damping device 20 is mounted on the main body 10 of the drive shaft, the axial force and axial vibration generated in the differential gear side joint 12 while the vehicle is traveling, in particular during the turning of the vehicle, are relative to the joint. It is absorbed and attenuated by the axial force damping device 20 located close by. That is, the axial force generated in the joint is transmitted to the damping member 42 through the first mount 22 of the damping device 20, and is absorbed and damped by the damping member 42.

In this way, components in all directions of the axial force generated in the differential gear side joint 12 are absorbed and attenuated by the damping device 20, and the axial force is prevented from being transmitted to the wheel side joint 14 and the wheels to drive the vehicle. In particular, the vehicle is prevented from oscillating or vibrating in the lateral direction during turning. Accordingly, the driver and the passenger can be provided with a stable ride and quietness.

As a result, according to the drive shaft of the longitudinal reduction differential apparatus according to the present invention, there is an effect of absorbing and attenuating the axial force generated in the differential gear side joint during the driving of the vehicle, in particular during the turning drive.

In addition, it is possible to prevent the axial force generated at the differential gear side from moving to the wheel side, to absorb and reduce all components of the axial force, to prevent the generation of noise due to the rotational play, and to prevent the noise generated at the transmission itself. Riding comfort and noise prevention performance is improved.

While a preferred embodiment according to the present invention has been described above, it will be understood by those skilled in the art that various modifications and changes can be made without departing from the scope of the appended claims.

Claims (6)

(Correct) A drive shaft of a longitudinal deceleration vehicle of an automobile, comprising: a main body separated into a first body having a differential gear side joint on one side and a second body having a wheel side joint on one side, and the first body and the second body; The first mount is fixed to the other end of each of the bodies so as to interconnect the bodies and is fixed to the other end of the first body to absorb and attenuate the axial force generated in the differential gear side joint. A second mount fixed to the other end of the body, the damping member is fixed to both sides of the first mount and the second mount is connected to each other, the fastening for fastening the first mount, the second mount and the damping member integrally A drive shaft of a longitudinal reduction gearbox comprising an axial force damping device constituted by means, The first mount of the axial force damping device is inserted into the center formed to be extrapolated to the end of the first body, a flange integrally formed around the insertion portion, and formed and fixed at regular intervals around the flange Integrally comprising a plurality of fixing portions through which the ball is drilled; The second mount of the axial force damping device is inserted into the center formed to be extrapolated to the end of the first body, a flange integrally formed around the insertion portion, and formed and fixed at regular intervals around the flange Integrally comprising a plurality of fixings through which the ball is drilled; A through hole is formed in the center of the damping member of the axial force damping device, and a plurality of through holes are formed in the periphery of the through hole, alternately communicating with the fixing holes formed in the respective mounts, and through which the fastening means passes; The fastening means of the axial force damping device drive shaft of the longitudinal reduction differential device, characterized in that it comprises a bolt and a nut. (delete) (delete) (delete) (delete) (delete)