JP2004232788A - Power transmission device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power transmission device using a rack supporting bushing not requiring the processing accuracy or installing accuracy to any significant degree, capable of putting the rack supporting bushing in the optimum position with respect to a rack shaft. <P>SOLUTION: The power transmission device is structured so that the rack shaft 2 is installed in a rack housing 1 and a pinion 3 is meshed with a rack 2a formed on the rack shaft and further includes a rack hold-down mechanism for keeping the rack meshing with the pinion properly and also a rack supporting bushing 6 for supporting the rack shaft installed at the end of the rack housing, wherein the rack supporting bushing 6 is furnished with an adjusting screw mechanism which intersects perpendicularly to the axial direction of the rack shaft, is movable in the direction of the rack meshing with the pinion, and adjusts the position of the rack supporting bushing. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a rack and pinion type power transmission device.
[0002]
[Prior art]
As a rack and pinion type power transmission device, for example, there is one shown in FIG. In this power transmission device, a rack shaft 2 is incorporated in a rack housing 1 installed so as to extend in the left-right direction of the vehicle body, and is slidably supported in the axial direction. Joints 4 are connected to both ends of the rack shaft 2, and a shaft of a power transmission system such as a tie rod is connected through the joint 4 to transmit the motion of the rack shaft 2 to wheels.
On the other hand, the pinion 3 is linked to a steering wheel (not shown) and meshes the pinion 3 with a rack 2 a formed on the rack shaft 2.
That is, with the rotation of the pinion 3 in accordance with the steering of the steering wheel, the rack shaft 2 moves in the axial direction, and the movement is transmitted to the shaft of the power transmission system, and the wheels are steered.
[0003]
In such an apparatus, various problems occur unless the position of the rack shaft 2 with respect to the pinion 3 is maintained properly.
For example, if the rack 2a escapes with respect to the pinion 3 and does not engage with the pinion 3, a problem occurs in that the rotation of the pinion side is not transmitted to the rack shaft. Conversely, when the pressing force is too strong. However, power transmission may not be performed smoothly.
Therefore, a rack holding mechanism (not shown) for appropriately pressing the rack shaft 2 against the pinion 3 is provided, and a rack supporting bush 5 for supporting the rack shaft 2 is provided on the inner periphery of the end of the rack housing 1. I have.
[0004]
The rack holding mechanism presses the rack shaft 2 in the direction of the pinion 3 to prevent the tooth surfaces from separating at the meshing portion between the pinion 3 and the rack 2a, thereby preventing backlash and harmful rattling noise. are doing.
The rack support bush 5 is a resin or metal cylinder, and slidably supports the rack shaft 2 on its inner wall. Further, the rack supporting bush 5 has a flange portion 5 a formed on the outer periphery, and this is fitted into an annular groove 1 a formed on the inner wall of the rack housing 1 and attached.
Alternatively, a bearing may be provided in the rack housing 1 instead of the bush 5 to support the rack shaft (see Patent Document 1).
Further, the rack shaft 2 is tilted or warped when a large load is input from the wheel side to the rack shaft 2 side, so that the power transmission efficiency is not reduced. The same rack support bush 5 is also provided at the end of the rack housing 1.
[0005]
[Patent Document 1]
Japanese Utility Model Application Laid-Open No. 61-1270075 (page 3, lines 15 to 20)
[0006]
[Problems to be solved by the invention]
In the case of the device shown in FIG. 4, the positions of the rack support bush 5 and the rack shaft 2 are uniquely determined, whereas the rack holding mechanism engages the rack 2a and the pinion 3 with proper backlash. To compensate. Therefore, even if the rack 2 a meshes with the pinion 3 with an appropriate backlash, the axis of the rack shaft 2 does not always match the axis of the rack support bush 5.
The mismatch between the axis of the rack shaft 2 and the axis of the rack support bush 5 causes the sliding resistance of the rack shaft 2 to increase or the rack shaft 2 to be tilted due to insufficient support of the rack shaft 2. It also causes. In both cases, smooth steering is hindered.
[0007]
Thus, the position of the rack support bush 5 that determines the position of the rack 2a with respect to the pinion 3 is an important factor for smooth steering. However, it is impossible to adjust the position of the rack support bush 5 relative to the rack shaft 2 after attaching the rack support bush 5 to the rack housing 1. Therefore, the positional accuracy of the rack support bush 5 and the rack shaft 2 depends on the processing accuracy of the rack support bush 5 and the outer peripheral surface of the rack shaft 2.
In other words, the rack shaft 2 is supported while maintaining an appropriate position with respect to the pinion 3, and the sliding resistance of the rack shaft 2 is not excessively increased. The processing accuracy of the rack support bush 5 and the like must be improved. Furthermore, it had to be assembled with high precision, which made processing and assembly extremely difficult and increased the cost.
An object of the present invention is to provide a rack support bush that does not require much processing precision or assembly precision, thereby supporting a rack shaft without increasing sliding resistance and preventing rattling noise caused by inappropriate support. It is to provide a power transmission device.
[0008]
[Means for Solving the Problems]
The first invention incorporates a rack shaft into a rack housing, and engages a pinion with a rack provided on the rack shaft, and includes a rack holding mechanism to appropriately maintain engagement between the rack and the pinion, and In a power transmission device provided with a rack supporting bush for supporting a rack shaft at an end of the rack housing, the rack supporting bush is in a direction orthogonal to the axial direction of the rack shaft, and the rack and the pinion engage with each other. The present invention is characterized in that an adjusting screw mechanism for adjusting the position of the rack supporting bush is provided while being movable in the direction.
[0009]
The second invention is based on the first invention and includes a guide ring for incorporating the rack support bush on the inner periphery of the rack housing, and the moving force of the adjusting screw mechanism penetrates the guide ring to reach the rack support bush. The guide ring is characterized in that an inner periphery of the guide ring is provided with a moving surface and a moving space on which a rack supporting bush can move in accordance with a moving direction of the adjusting screw mechanism.
The third invention is based on the second invention, wherein the inner shape of the guide ring is made elliptical, the minor diameter of the guide ring is made substantially coincident with the outer diameter of the rack support bush, and the major diameter of the guide ring is changed to the length of the rack support bush. The feature is that it is larger than the outer diameter.
[0010]
The fourth invention is based on the second invention, wherein the inner shape of the guide ring is circular, the outer shape of the rack support bush is elliptical, and the major axis of the outer shape of the rack support bush is substantially equal to the inner diameter of the guide ring. There is a characteristic in the point that it is done.
The fifth invention is based on the first to fourth inventions and is characterized in that a pedestal is interposed between the adjusting screw mechanism and the rack support bush.
The sixth invention is based on the fifth invention, and is characterized in that a curved surface is brought into contact with the pedestal on the side opposite to the rack supporting bush.
The seventh invention is characterized by the fact that the rack supporting bush is formed of an oil-containing resin or an oil-containing metal on the premise of the above inventions.
The oil-impregnated metal is a metal obtained by impregnating a material having a void, such as a sinterable metal or a casting, with a lubricating oil.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
1 to 3 show an embodiment of the present invention.
In the rack and pinion type power transmission device shown in FIG. 1, a pinion 3 is engaged with a rack 2 a of a rack shaft 2 slidably incorporated in a rack housing 1. A joint 4 is connected to both ends of the rack shaft 2, and the rack shaft 2 and a shaft of a power transmission system linked to wheels are connected via the joint 4.
Further, a large-diameter portion 1b is formed at an end of the rack housing 1, and a rack support bush 6 is incorporated therein, so that the rack shaft 2 is supported by the rack support bush 6. The axial position of the rack support bush 6 and the like is fixed by press-fitting the ring member 12 into the opening side of the large-diameter portion 1b into which the rack support bush 6 and a guide ring 7 described later are incorporated. ing.
[0012]
The rack support bush 6 is made of an oil-containing resin or an oil-containing metal, and is a cylindrical component. However, the rack support bush 6 is not limited to the oil-containing material. It is also possible to use a non-oil impregnated resin or metal, but in the case of an oil impregnated resin or an oil impregnated metal such as a sintered metal or a casting, as in this embodiment, the lubricating oil should be contained in the rack support bush 6. Thus, the rack shaft 2 can slide more smoothly.
[0013]
Further, a guide ring 7 is interposed between the rack support bush 6 and the large diameter portion 1b of the rack housing 1. The guide ring 7 is a cylinder whose outer periphery is an arc contacting the large diameter portion 1b and whose inner diameter is elliptical. The minor axis of the ellipse, that is, the lateral direction in FIG. 2 is substantially equal to the outer diameter of the rack support bush 6. That is, the rack support bush 6 is sandwiched between the guide ring 7 short diameter sides, and the rack support bush 6 is movable in the major diameter direction of the guide ring 7.
[0014]
However, the inner shape of the guide ring 7 is not a mathematically strict ellipse, but has a moving surface on which the rack supporting bush 6 slides and moves in the major axis direction. That is, the moving surface of the present invention is provided near the minor axis of the guide ring 7, and the moving space of the present invention is provided on both sides in the major axis direction.
Further, the inner shape of the guide ring 7 does not need to be elliptical. In short, the inner shape of the guide ring 7 may be any shape as long as the rack support bush 6 can move only in the vertical direction in FIGS. Absent. However, it is expected that the inner shape of the guide ring 7 and the outer shape of the rack support bush 6 are easier to form in a circle or an ellipse than in an irregular shape.
[0015]
The guide ring 7 has a circular opening on a side surface, and the opening is positioned below in FIG. 2, and a disk-shaped pedestal 8 faces the opening. This pedestal is made of iron.
On the other hand, a cylindrical portion 1c that is orthogonal to the axis of the rack housing 1 and protrudes in a direction opposite to the rack 2a is formed in the large diameter portion 1b of the rack housing 1. A screw portion 1d is formed on the opening end side of the cylindrical portion 1c.
A ball holder 9 is incorporated in the cylindrical portion 1c, and a ball 10 is fitted in a hole formed on the upper surface thereof.
[0016]
Further, an adjusting screw 11 having a screw portion 11a is fastened to the screw portion 1d of the cylindrical portion 1c. The adjustment screw 11 closes the opening of the cylindrical portion 1 c, presses the ball holder 9 toward the rack shaft 2, and presses the ball 10 against the pedestal 8.
When the tightening amount of the adjusting screw 11 is increased, the ball 10 presses the pedestal 8, and the pedestal 8 further moves the rack supporting bush 6 upward in the drawing.
Then, for the reason explained in the conventional example, the axis of the rack support bush 6 is made to coincide with the axis of the rack shaft 2 determined by the pinion 3 and the rack support bush 6 at the other end (not shown) of the rack housing 1. Next, the position of the rack support bush 6 is adjusted and fixed via the adjustment screw 11.
[0017]
That is, the position of the rack support bush 6 is adjusted in accordance with the amount of tightening of the adjusting screw 11, and an optimum backlash is provided between the rack 2 a and the pinion 3 to optimize the rack shaft 2. The position, that is, an appropriate distance between the rack shaft 2 and the rack support member 6 can be realized. This adjusting screw 11 is the adjusting screw mechanism of the present invention.
Then, the position of the rack support bush 6 with respect to the rack shaft 2 can be adjusted by the adjusting screw 11 after assembling the components. Therefore, even if the rack housing 1 and the rack support bush 6 are not so precisely dimensioned or mounted, the optimal contact can be adjusted, and smooth power transmission can be achieved.
Also, when the position of the rack support bush 6 changes with time, an appropriate backlash between the rack 2a and the pinion 3 or an appropriate support state of the rack support bush 6 with respect to the rack shaft 2 is lost. The above-mentioned change can be dealt with by readjustment without performing the above.
[0018]
Although the pedestal 8 is provided in this embodiment, the pedestal 8 is not essential. The ball 10 may directly contact the rack support bush 6 without using the pedestal 8, or the adjustment screw 11 directly contacts the rack support bush 6 omitting the ball holder 9. It does not matter.
However, in this embodiment, the pedestal 8 is provided because when the pressing force of the ball 10 is concentrated at one point, the rack supporting bush 6 made of an oil-containing metal such as an oil-containing resin or sintered metal is used. This is to prevent damage. An oil-containing resin or an oil-containing metal such as a sintered metal has a lower strength than a metal block having no oil-impregnated voids, and thus may be broken when pressed directly with an iron ball.
[0019]
When the iron base 8 is used as in this embodiment, even if the ball 10 is made of iron, the base 8 does not break due to the pressing force of the ball 10, and the rack support bush 6 does not have any surface pressure. There is no worry about breaking.
Further, since the pedestal 8 is in point contact with the surface of the ball 10, the pedestal 8 can be inclined with respect to the moving direction of the adjusting screw 11 on the surface of the ball 10. If the rack shaft 2 is attached to the rack housing 1 at an angle from the beginning due to a component processing error or an assembly error, the pedestal 8 tilts on the surface of the ball 10, The inclination of the rack shaft 2 can be adjusted. In this manner, the inclination of the rack shaft 2 is absorbed by the inclination of the pedestal 8, and the position of the rack support bush 6 can be adjusted to an appropriate position.
[0020]
The member for pressing the pedestal 8 is not limited to a ball. If the pedestal 8 contacts the pedestal 8 at a point, such as a hemisphere or a projection, the pedestal 8 can be tilted in accordance with the tilt of the rack shaft 2. However, if the rack shaft 2 can be assembled so as not to be inclined with respect to the rack housing 1, a ball or the like is unnecessary.
[0021]
The second embodiment shown in FIG. 3 is different from the first embodiment in that the rack support bush 6 'has a slit formed in a portion located on the side of the rack 2a. This is the same as the embodiment. Therefore, the same components as those of the first embodiment are denoted by the same reference numerals as those of the first embodiment. A cross-sectional view in the direction of the rack shaft 2 is omitted because it is the same as FIG.
Since the rack supporting bush 6 'of the second embodiment is provided with a slit, the diameter can be reduced by the amount of the slit, incorporated into the rack housing 1, assembled, and then expanded. Therefore, the guide ring 7 and the ring member 12 can be formed integrally with the rack housing 1, whereby the number of parts can be reduced.
[0022]
However, in practice, when the rack support bush 6 'is made movable in the radial direction, the guide ring 7 can be separated from the rack housing 1 even if the number of parts is increased as compared with processing the rack housing 1 into a predetermined shape. It is easier to process this.
In the second embodiment as well, the effect of being able to adjust the position of the rack support bush 6 'is the same as in the first embodiment.
In the first and second embodiments, the rack support bushes 6, 6 'of the present invention are provided at one end of the rack housing 1. However, the rack support bushes 6.6' are connected to the rack housing 1. 1 may be provided at both ends.
[0023]
【The invention's effect】
According to the first to seventh inventions, it is possible to adjust the positional relationship among the pinion, the rack support bush, and the rack shaft after the rack shaft is assembled to the rack support bush. Therefore, the rack shaft can be supported at an appropriate position without increasing the processing accuracy and the assembling accuracy of the individual components. Therefore, smooth power transmission can be achieved without rattling of the meshing portion between the pinion and the rack or rattling of the rack shaft or excessive increase in resistance.
[0024]
According to the second to fourth aspects of the invention, in order to support the rack support bush so that the position of the rack support bush can be adjusted, the guide including the moving surface on the inner periphery of the rack housing on which the rack support bush can move and the moving space. Since the ring is provided, it is not necessary to process the inner shape of the rack housing into a shape that allows the movement thereof while holding the rack support bush.
The inner diameter of the rack housing may be a circle, and the dimensions may not be so precise. Even when forming a dimensioned ellipse or other internal shape, machining the guide ring is easier than machining in the rack housing.
According to the third and fourth inventions, the processing of the inner shape of the guide ring and the outer shape of the rack supporting bush can be easily performed.
[0025]
According to the fifth aspect, by interposing the pedestal, even when a protrusion is provided between the adjusting screw mechanism and the rack support bush, pressure does not concentrate on one point of the rack support bush. Therefore, a low-strength oil-containing resin or sintered metal can be used as the rack supporting bush, and the movement of the rack shaft can be more smoothly moved by the lubricating oil.
[0026]
In the sixth aspect, since the projecting surface is interposed between the adjustment screw mechanism and the pedestal, the pedestal can rotate around a point on the curved surface. Thus, even if there is a shift between the rack shaft and the rack housing, the shift can be absorbed. Therefore, the processing accuracy of the rack shaft and the rack housing and the assembling accuracy do not need to be significantly increased.
According to the seventh aspect, lubricating oil is contained in the rack support bush, so that the rack shaft can slide more smoothly.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a power transmission device according to a first embodiment.
FIG. 2 is a sectional view taken along line II-II of FIG.
FIG. 3 is a sectional view of a second embodiment.
FIG. 4 is a sectional view of a conventional power transmission device.
[Explanation of symbols]
Reference Signs List 1 rack housing 1d screw part 2 rack shaft 2a rack 3 pinion 6, 6 'rack support bush 7 guide ring 8 pedestal 10 ball 11 adjustment screw 11a screw part

Claims (7)

The rack shaft is incorporated into the rack housing, and the rack provided on the rack shaft is engaged with a pinion, and a rack holding mechanism is provided for properly maintaining the engagement between the rack and the pinion. In a power transmission device provided with a rack supporting bush for supporting a rack shaft, the rack supporting bush is movable in a direction orthogonal to the axial direction of the rack shaft and in a direction in which the rack and the pinion engage. A power transmission device having an adjusting screw mechanism for adjusting the position of the rack support bush. A guide ring incorporating a rack support bush is provided on the inner periphery of the rack housing, and the moving force of the adjusting screw mechanism is configured to penetrate through the guide ring to reach the rack support bush. The power transmission device according to claim 1, further comprising a moving surface and a moving space on which the rack supporting bush can move in accordance with a moving direction of the screw mechanism. 3. The power transmission device according to claim 2, wherein the inner shape of the guide ring is made elliptical, the minor diameter of the guide ring is made substantially equal to the outer diameter of the rack support bush, and the major diameter is larger than the outer diameter of the rack support bush. . 3. The power transmission device according to claim 2, wherein the inner shape of the guide ring is circular, the outer shape of the rack support bush is elliptical, and the major axis of the outer shape of the rack support bush is substantially equal to the inner diameter of the guide ring. The power transmission device according to claim 1, wherein a pedestal is interposed between the adjustment screw mechanism and the rack support bush. The power transmission device according to claim 5, wherein the pedestal has a protruding surface in contact with the side opposite to the rack supporting bush. The power transmission device according to any one of claims 1 to 6, wherein the rack supporting bush is formed of an oil-containing resin or an oil-containing metal.

Images