JP3529521B2 - Steering gear - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rack and pinion type steering device, and more particularly to a mechanism for fixing a dust boot to a casing.

[0002]

2. Description of the Related Art In a conventional example shown in FIG. 9, a rod 2 is slidably incorporated in a casing 1. A rack is formed at a position (not shown) of the rod 2, and a pinion linked to the handle is engaged with the rack. Therefore, when a handle (not shown) is turned, the rotational force is converted into a moving force in the axial direction of the rod 2 via the pinion and the rack. At both ends of the rod 2, ball joints 3
The wheels (not shown) are linked to each other via. That is,
The cylindrical member 4 is fixed to the end of the rod 2, and the cylindrical member 4
The ball receiving groove 5 is formed in the. A ball member 7 is provided on the arm member 6 with which the wheels are linked, and the ball member 7 is fitted into the ball receiving groove 5.

Dust boots 8 formed of resin, rubber or the like are provided at both ends of the rod 2 as described above in order to prevent water and dust from entering. Dust boots 8
As shown in FIG. 9, is a tubular shape and has a bellows shape that is expandable and contractible in the axial direction. The dust boot 8 is provided from the side of the arm member 6 in the state where no wheels are provided yet, and the cylindrical member 4 and the ball member 7 are positioned therein. The opening 9 on the wheel side of the dust boot 8 is fixed to the arm member 6 by the clamp member 10. On the other hand, the opening 11 of the dust boot 8 on the casing 1 side is fixed to the end of the casing 1 as follows. At the end of the casing 1, a clamp portion 12 having a slightly larger outer diameter is provided.
Is formed, and the annular fixing groove 13 is formed therein. Further, the inner diameter of the opening 11 on the casing 1 side of the dust boot 8 is made slightly smaller than the outer diameter of the fixing groove 13.
Then, the opening 11 is covered with the fixing groove 13, and the band member 14 made of resin is sufficiently tightened.

In this prior art example, the dust boot 8 formed of resin, rubber or the like is brought into close contact with the fixing groove 13 to exert a sealing function. That is, the fixed groove 13 on the casting surface is machined to eliminate the unevenness and smooth the surface. Then, the smooth surface is covered with the opening 11 of the dust boot 8 and the band member 14
The sealing function is secured by tightening and tightening with. Even in this case, when the band member 14 is tightened, the dust boot 8 may be wrinkled. Therefore, it is necessary to apply a sealant between the smoothed fixing groove 13 and the inner peripheral surface of the opening 11. There is. The conventional example shown in FIG.
The wire member 1 made of iron, not the resin band member 14
5 is an example in which the opening 11 portion of the dust boot 8 is tightened. Further, the conventional example shown in FIG. 11 is an example in which the opening 11 portion of the dust boot 8 is tightened by the iron band member 16 instead of the resin band member 14. And
Since the conventional example shown in FIGS. 10 and 11 is exactly the same as the above-described conventional example in other configurations, detailed description thereof will be omitted.

[0005]

In the above conventional example, the dust boot 8 is fixed to the end portion of the casing 1 by tightening the resin band member 14, the iron wire member 15, the iron band member 16 and the like. . Therefore, the number of parts is increased by that much, and the cost is increased. Further, in order to secure the sealing function, the outer peripheral surface of the fixed groove 13 must be smoothed by machining. Therefore, the processing man-hours increase correspondingly and the cost increases. Furthermore, when the opening 11 is tightened with the band members 14 and 16 and the wire member 15, the dust boot 8 may be wrinkled. Therefore, the sealing agent has to be applied between the fixed groove 13 and the inner peripheral surface of the opening 11, resulting in a large number of assembling steps and cost. The present invention is to provide a steering device that can easily fix the dust boot to the casing while sufficiently ensuring the sealing function and can reduce the cost.

[0006]

SUMMARY OF THE INVENTION According to the present invention, a rod that is axially movable in association with a handle, a cylindrical casing in which the rod is slidably incorporated, and a wheel that links both ends of the rod with wheels. The steering device has a mechanism and has a structure in which a dust boot is fixed to an end portion of the casing to prevent intrusion of moisture and dust. The first invention includes a dust boot having an opening, and the opposing surface provided on the respective openings and the casing of the dust boot, cable
The annular groove formed on the opposing surface of the sing, the seal member assembled in the annular groove , and the outer peripheral surface of the casing or the inner peripheral surface of the opening of the dust boot are arranged at a predetermined interval and inclined at a certain lead angle. A plurality of locking parts that form a surface, a fitting groove formed in the middle of the inclined surface of these locking parts, and the outer peripheral surface of the casing or the inner peripheral surface of the opening of the dust boot are arranged at a predetermined interval. Multiple protrusions
And an elastic shrink provided on the inner peripheral surface of the dust boot.
With a diameter portion, the end portion of the casing is inserted into the opening of the dust boot, when the dust boot and the casing are relatively rotated, the convex portion moves along the inclined surface of the locking portion,
Moreover, when the facing surfaces are close to each other and the dust boot and the casing are further rotated relative to each other, a part of the convex portion is fitted into the fitting groove, and the reduced diameter portion formed on the facing surface on the dust boot side. Is characterized in that the seal member is pressed against the elastic force.

In the first invention, when the end of the casing is inserted into the opening of the dust boot and the dust boot and the casing are relatively rotated, the convex portion moves along the inclined surface of the locking portion, At the same time, the facing surfaces approach each other. Then, when these are rotated further relative to each other, part of the protrusion is fitted into the fitting groove, and the diameter of the dust boot is reduced.
Due to the elastic force, the portion comes into pressure contact with the seal member. When the dust boot is assembled to the casing in this manner, the convex portion is fitted into the fitting groove, so that the relative rotation between the dust boot and the casing is restricted. Also,
When the reduced diameter portion comes into contact with the facing surface, a force acts on the casing in a direction away from the dust boot due to the elastic force of the reduced diameter portion . Then, this force acts in a direction in which the convex portion and the fitting groove are in contact with each other, so that the axial movement of the dust boot is also restricted. In this way, the dust boot can be easily fixed to the casing only by rotating the dust boot and the casing relative to each other. Moreover, when the dust boot is assembled to the casing in this manner, the sealing member is pressed against the facing surface on the dust boot side, and thus the sealing function is also exhibited.

A second invention is the locking of the first invention.
The fitting groove formed at the
It is characterized in that the opposite end has a shape opposite to the end on the entry direction side of the protrusion . In the second invention, the configuration is as described above.
Therefore, the convex part can be securely stopped in the fitting groove.
It A third invention is the first or second invention,
It is characterized in that the engaging portion and the convex portion are arranged at equal intervals on the outer peripheral surface of the casing or the inner peripheral surface of the opening of the dust boot. In the third invention, since the locking portion and the convex portion are arranged at equal intervals on the circumference, for example, when the dust boot and the casing are relatively rotated, they act on the locking portion and the convex portion. You can even out the force. Therefore, it is possible to prevent the axes of the dust boot and the casing from being displaced when the relative rotation is performed.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION A first embodiment of the present invention shown in FIGS. 1 to 5 has a structure of an opening 11 of a dust boot 8 and a structure of a clamp portion 12 of a casing 1 as compared with the above-mentioned conventional example. This is a modified example. Since other configurations are exactly the same as the conventional example, detailed description thereof will be omitted. As shown in FIG. 1, a clamp portion 12 is formed at the end of the casing 1. And the annular groove 1 at the forefront
7 is formed, and an O-ring 18 is attached thereto as a seal member. Further, on the outer peripheral surface of the clamp portion 12, as shown in FIG. 1, three convex portions 1 arranged at equal intervals are provided.
9 (only two protrusions 19 are shown in FIG. 1) are integrally formed. Here, as shown in FIG. 2, the protrusions 19 are formed by forming a right-angled triangle 20 having a certain angle θ into the clamp portion 1.
2 has a shape wound around the outer peripheral surface. At this time, the base 21 of the right-angled triangle 20 is wound along the circumference a at a predetermined distance from the outermost end of the clamp portion 12. Therefore, the inclined surface 22 having the lead angle θ is formed in the shape of a helix in the manner of a right-hand screw on each of the convex portions 19.

On the other hand, the resin dust boot 8 has a cylindrical shape as in the conventional example, and has a bellows shape which is axially expandable and contractible. Then, as shown in FIG. 3, the dust boots 8 are arranged at equal intervals on the inner peripheral surface of the opening 11.
The two locking portions 23 are integrally formed. These locking parts 2
3 also has a shape in which a right-angled triangle having an angle θ is wound around the inner peripheral surface of the opening 11. And at this time,
The bottom side 23a of the right triangle is wound around the outermost end of the opening 11. Therefore, these locking portions 2
3, the inclined surface 24 having the lead angle θ is formed in a spiral winding shape. In addition, the locking portion 23 is opened 11
Although they are arranged at equal intervals on the inner peripheral surface of the, as shown in FIG. 4, between a certain locking portion 23 and the adjacent locking portion 23.
The distance X of is larger than the length x of the base 21 of the convex portion 19.

Further, at the end of each inclined surface 24,
The fitting groove 25 is formed. The fitting groove 25 has a shape that matches the corner portion 26 of the convex portion 19. That is, the fitting groove 2 formed in the locking portion 23
5 is a convex portion of the engaging portion 23 on the side of the convex approaching direction.
The shape of the portion 19 is opposite to that of the end portion on the entry direction side. In the opening 11 of the dust boot 8 thus formed, a reduced diameter portion 27 having an elastic force is formed at a position recessed from the outermost end portion of the inner peripheral surface thereof by a predetermined length h. This reduced diameter portion 27
As will be described later, is for pressing and sealing the O-ring 18 when the dust boot 8 and the casing 1 are assembled. Further, on the inner peripheral surface of the opening 11, a seal pressing portion 28 is formed in an annular shape at the root portion of the reduced diameter portion 27 on the opening 11 side. This seal holder 2
As will be described later, reference numeral 8 is for sealing the O-ring 18 when the dust boot 8 and the casing 1 are assembled. If the outer diameter of the clamp portion 12 is R and the thickness of the convex portion 19 provided on the clamp portion 12 is r, the inner diameter of the opening 11 is R + r, and the locking portion is
The thickness of 23 is r, which is the same as the thickness of the convex portion 19. further,
The thickness of the seal pressing portion 28 is also the same r as the thickness of the locking portion 23, that is, the thickness of the convex portion 19.

Next, similarly to the conventional example for explaining the operation of the first embodiment, the dust boot 8 is provided from the arm member 6 side in the state where the wheel is not provided yet, and the cylindrical member 4 and the balls are provided therein. Position the member 7. Then, the clamp portion 12 of the casing 1 is inserted into the opening 11 of the dust boot 8 so that the bottom surface 21 of the convex portion 19 is exposed between the locking portion 23 and the locking portion 23 adjacent thereto. From this state, when the dust boot 8 and the casing 1 are relatively rotated, that is, when the dust boot 8 is rotated clockwise with respect to the casing 1, the inclined surface 22 of the convex portion 19 becomes the inclined surface 24 of the locking portion 23. Along the way, it slides like a screw (see Fig. 4 (a)). At the same time, the dust boot 8 also moves in the axial direction according to the lead angle θ, so that the side surface of the reduced diameter portion 27 approaches the end surface of the casing 1. Since the locking portion 23 and the convex portion 19 are arranged at equal intervals on the circumference, the forces acting on the locking portion 23 and the convex portion 19 can be made uniform when they are relatively rotated. Therefore, the axes of the dust boot 8 and the casing 1 will not be displaced.

When the dust boot 8 and the casing 1 are rotated relative to each other by a predetermined angle, the corner portion 26 of the convex portion 19 is rotated.
However, it is located just before the fitting groove 25 (see FIG. 4).
(See (b)). Further, the lead angle θ and the lengths a and h are set, and at this time, the side surface of the reduced diameter portion 27 is the casing 1
The end surface of the O ring is pressed against the O ring 18. In this state, the side surface of the reduced diameter portion 27 is already in contact with the end surface of the casing 1, so that the relative rotation between the dust boot 8 and the casing 1 is hindered. However, since the diameter-reduced portion 27 has an elastic force, if the components are strongly rotated relative to each other, the diameter-reduced portion 27 is greatly deformed for a moment, and eventually the corner portion 26 of the convex portion 19 fits into the fitting groove 25. (See FIG. 4C). Then, with the convex portion 19 fitted in the fitting groove 25, the O-ring 18
Is sealed by the seal groove 17, the seal pressing portion 28, and the side surface of the reduced diameter portion 27, and is kept in pressure contact by the elastic force of the reduced diameter portion 27.

In this way, when the dust boot 8 is attached to the casing 1, the convex portion 19 fits into the fitting groove 25, so that the relative rotation between the dust boot 8 and the casing 1 is restricted. Moreover, since the side surface of the reduced diameter portion 27 pushes the end surface of the casing 1 by the elastic force, the force f acts on the casing 1 in the direction away from the dust boot 8. Then, this force f is generated between the convex portion 19 and the locking portion 23.
Since the dust boot 8 acts in the direction of the arrow shown in FIG. 4C, the axial movement of the dust boot 8 is also restricted. That is, by rotating the dust boot 8 and the casing 1 relative to each other and fitting the corner portion 26 of the convex portion 19 into the fitting groove 25, the dust boot 8 can be fixed to the casing 1.

According to the first embodiment described above, the dust boot 8 can be easily fixed to the casing 1 only by relatively rotating the dust boot 8 and the casing 1. Therefore, the band members 14 and 16 and the wire member 15 of the conventional example are not required, and the cost can be reduced.
Moreover, when the dust boot 8 is assembled to the casing 1, the side surface of the reduced diameter portion 27 is pressed against the O-ring 18 at the same time and the O-ring 18 is sealed, so that the sealing function is exerted. Therefore, even if the clamp portion 12 has a cast surface, it is possible to prevent water and dust from entering. Furthermore, unlike the conventional example, since the band members 14, 16 and the wire member 15 are not used, the dust boot 8 is not wrinkled and the sealing function can be sufficiently maintained without applying the sealing agent. .

The second embodiment shown in FIG. 6 is an example in which a rubber dust boot 8 is used. Here, the dust boot 8 is used.
At the time of molding, the metal ring 29 is inserted into the opening 11 portion. The metal ring 29 reinforces, for example, the reduced diameter portion 27 to increase its rigidity. The third embodiment shown in FIGS. 7 and 8 is an example in which cylindrical portions 30 as convex portions are arranged on the outer peripheral surface of the clamp portion 12 at equal intervals. The shape of the fitting groove 25 of the locking portion 23 is also semicircular so as to match the cylindrical portion 30. The other configurations, operations, and effects are almost the same as those of the first embodiment, and detailed description thereof will be omitted. However, in this third embodiment, when the dust boot 8 and the casing 1 are relatively rotated, the cylindrical portion 30 moves on the inclined surface 24 of the locking portion 23 while making point contact, so that the dust boot 8 and the casing 1 are There may be rattling. In the first to third embodiments described above, the ball joint 3 constitutes a linkage mechanism that links the wheels to the rod 2. Further, the facing surfaces provided in the openings 11 of the casing 1 and the dust boot 8 are respectively the end surface of the casing 1 and the reduced diameter portion 2.
It is assumed that 7 side surfaces are configured.

[0017]

According to the first invention, the dust boot can be fixed to the casing only by rotating the dust boot and the casing relative to each other. Therefore, the cost can be reduced without using a band member or a wire member. In addition, when the reduced diameter part comes into contact with the facing surface,
Due to the elastic force of the dia.
The force acts in the direction away from the
Since they act in the direction of abutting each other with the groove ,
The sealing function can be fully exerted. Therefore, the casing may be a cast surface, and the machining for smoothing the outer peripheral surface of the casing is not required, and the cost can be reduced. Further, since no band member or wire member is used, the dust boot does not wrinkle. Therefore, the sealing function can be sufficiently maintained without applying the sealing agent. According to the second aspect of the invention, the locking portion has a shape.
The fitting groove made is the end of the engaging part on the protruding direction
Since the projection has a shape opposite to the end on the intrusion direction side,
They fit together perfectly. According to the third invention, when the dust boot is assembled to the casing , it is possible to prevent the axes of the dust boot from being displaced. Therefore, the dust boot can be firmly fixed to the casing. Moreover, since the seal member is pressed uniformly, the sealing function can be sufficiently exerted.

[Brief description of drawings]

FIG. 1 is a perspective view showing a casing of a steering system according to a first embodiment.

FIG. 2 is an imaginary view for explaining a convex portion formed on a casing.

FIG. 3 is a perspective view showing a dust boot in the steering system of the first embodiment.

FIG. 4 is a plan view showing a process of assembling the dust boot to the casing. FIG. 4A shows a state where the convex portion is moving along the inclined surface of the locking portion, and FIG. The corner of the convex portion is located immediately in front of the fitting groove, and FIG. (C) shows the corner of the protruding portion fitted in the fitting groove.

FIG. 5 is a cross-sectional view showing a state in which the dust boot is fixed to the casing in the steering system of the first embodiment.

FIG. 6 is a diagram showing an example in which a metal ring is inserted into an opening portion of a rubber dust boot to reinforce the steering apparatus of the second embodiment.

FIG. 7 is a perspective view showing a casing in a steering system according to a third embodiment.

FIG. 8 is a plan view showing a process of assembling the dust boot and the casing in the steering system according to the third embodiment.

FIG. 9 is a cross-sectional view showing a state where a dust boot is fixed to a casing in a steering device of a conventional example.

FIG. 10 is a cross-sectional view showing a state where a dust boot is fixed to a casing in a steering device of a conventional example.

FIG. 11 is a cross-sectional view showing a state where a dust boot is fixed to a casing in a steering device of a conventional example.

[Explanation of symbols]

1 casing 2 rod 8 dust boots 12 Clamp part 17 Seal groove 18 O-ring 19 convex 22 Inclined (convex) 23 Locking part 24 Inclined surface (of locking part) 25 Fitting groove 26 Corner 27 Reduced diameter part 30 Cylindrical part (as convex part)

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References Actual flat 2-60771 (JP, U) Actual open 61-193047 (JP, U) Actual open 49-128993 (JP, U) (58) Survey Field (Int.Cl. ⁷ , DB name) B62D 3/00-3/12 F16B ⁷ /00-7/22 F16J 3/00-3/06

Claims (3)

(57) [Claims] 1. An end of a casing comprising: a rod that moves in an axial direction in association with a handle; a cylindrical casing in which the rod is slidably incorporated; and a linkage mechanism that links wheels to both ends of the rod. Fix the dust boots on the part,
In steering apparatus has a structure for preventing the intrusion of moisture and dust, and dust boot having an opening, and the opposing surface provided on the respective openings and the casing of the dust boot, Keshi
An annular groove formed on the opposite surface of the ring, a seal member assembled in the annular groove, are arranged at predetermined intervals on either the inner peripheral surface of the outer peripheral surface or dust boot of the opening of the casing, inclined at a certain lead angle A plurality of locking parts that form a surface, a fitting groove formed in the middle of the inclined surface of these locking parts, and the outer peripheral surface of the casing or the inner peripheral surface of the opening of the dust boot are arranged at a predetermined interval. Multiple protrusions
And an elastic shrink provided on the inner peripheral surface of the dust boot.
With a diameter portion, the end portion of the casing is inserted into the opening of the dust boot, when the dust boot and the casing are relatively rotated, the convex portion moves along the inclined surface of the locking portion,
Moreover, when the facing surfaces are close to each other and the dust boot and the casing are further rotated relative to each other, a part of the convex portion is fitted into the fitting groove, and the reduced diameter portion formed on the facing surface on the dust boot side. The steering device is characterized in that the seal member is brought into pressure contact with the elastic force. 2. The engaging groove formed in the engaging portion is the engaging portion.
At the end of the convex part in the entry direction and the end of the convex part in the entry direction
The steering device according to claim 1, wherein the steering device has an opposite shape . 3. The locking portion and the convex portion are arranged at equal intervals on the outer peripheral surface of the casing or the inner peripheral surface of the opening of the dust boot, respectively.
The steering device described.