JP2016064741A - Rack guide, and rack-pinion type steering device provided with rack guide - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rack guide which supports a rack bar that is engaged with a pinion pivoted on a gear case through a rack tooth so as to be movable in an axial direction and achieves prevention of worn-out of the rack guide and can smoothly support the rack bar, and a rack-pinion type steering device provided with the rack guide without increase in manufacturing cost.SOLUTION: A rack guide includes a sliding plate piece 61 contacting with a rack bar 3 and a rack guide body 62 having a mounting surface 62a formed thereon. Tongue piece portions 61b are formed on both side ends in a direction orthogonal to a movement direction of the rack bar 3 in the sliding plate piece 61, projection portions 62c are formed on both side ends in a direction orthogonal to the movement direction of the mounting surface 62a in the rack guide body 62, and the tongue piece portions 61b and the projection portions 62c are engaged with each other.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a technology of a rack guide and a rack and pinion type steering apparatus including the rack guide.

Generally, a rack and pinion type steering device includes a gear case, a pinion that is pivotally supported by the gear case, a rack bar that is formed with rack teeth that mesh with the pinion, and the rack bar that can slide within the gear case. And a coil spring that urges the rack guide to be pressed against the rack bar.
Conventionally, the rack guide is formed of an Fe-based sintered metal or a synthetic resin.
Here, the rack guide made of Fe-based sintered metal has sufficient mechanical strength against the impact load received from the rack bar, but because the sliding friction resistance is large, the efficiency of the entire steering device is reduced, There was a possibility that it became a factor of operability deterioration.
On the other hand, since the rack guide made of synthetic resin has low sliding friction resistance, the overall efficiency of the steering device can be improved, but the mechanical strength against the impact load received from the rack bar is inferior. In addition, the durability of the steering device as a whole may be affected.

Therefore, as means for solving these problems, for example, in “Patent Document 1”, a rack guide body formed of a metal member such as an Fe-based sintered metal or an aluminum alloy, and a surface is covered with a synthetic resin layer In addition, there is disclosed a technique relating to a rack guide constituted by a sliding plate piece fixed to the rack guide body.
More specifically, the rack guide is composed of a rack guide body having a hole in the center and a sliding plate piece having a protrusion in the center, and slides with respect to the hole of the rack guide body. The sliding plate piece is fixed to the rack guide body by press-fitting the protrusion of the moving plate piece.

In the rack guide having the above-described configuration in the “Patent Document 1”, for example, when the mounting posture of the sliding plate piece with respect to the rack guide body is slightly inclined compared to a predetermined posture, It is substantially possible to press-fit and fit the protrusions of the sliding plate pieces into the holes.
Therefore, it is doubtful whether the mounting posture of the sliding plate piece with respect to the rack guide body is always a predetermined posture, the rack bar hits against the rack guide piece, and the rack guide (especially the sliding plate piece) is worn out. There was a possibility to become a factor to encourage.

Further, in the rack guide in the above-mentioned “Patent Document 1”, since the protruding portion of the sliding plate piece is mainly formed by press drawing, the protruding side of the protruding portion of the sliding plate piece (rack guide main body). A concave portion corresponding to the protrusion is formed in the plane opposite to the side), that is, in the center of the sliding support surface that directly contacts the rack bar when the rack bar is supported.
Therefore, the pressure receiving area of the sliding support surface is reduced by the cross-sectional integral of the recess, and the stress applied to the sliding support surface when the rack bar is supported by the rack guide is increased. The sliding plate piece) is a factor that promotes wear and tear.

  Furthermore, in the rack guide described in “Patent Document 1”, when the protruding portion of the sliding plate piece is formed by such press drawing, the manufacturing process becomes complicated, which causes an increase in manufacturing cost.

  Therefore, as means for solving such a problem, for example, in “Patent Document 2”, a tongue-shaped restricting portion is formed at both ends of the rack bar in the moving direction, and these restricting portions are interposed. A rack guide having a sliding plate piece fixed to a rack guide main body is disclosed.

JP 2006-321351 A JP 2009-132304 A

According to the rack guide described in “Patent Document 2”, it is possible to mount the sliding plate piece on the rack guide body only when the mounting posture of the sliding plate piece with respect to the rack guide body is a predetermined posture. Therefore, the mounting posture of the sliding plate piece with respect to the rack guide body can always be maintained in a predetermined posture. Therefore, the rack bar can be prevented from coming into contact with the rack guide, and wear of the rack guide (especially the sliding plate piece) is not promoted.
Further, according to the rack guide described in “Patent Document 2”, a protrusion by press drawing is formed in the center of the sliding plate piece, or a hole corresponding to the protrusion is formed in the rack guide body. There is no need to do. Therefore, since the concave portion corresponding to the protruding portion is not formed at the center of the sliding support surface of the sliding plate piece as described above, the pressure receiving area of the sliding support surface is the cross-sectional integral of the concave portion. As a result, the stress applied to the sliding support surface at the time of supporting the rack bar is increased, and the wear of the rack guide (especially the sliding plate piece) is not promoted.

  However, in the rack guide in “Patent Document 2”, the shape of the restricting portion of the sliding plate piece and the engaging groove portion of the rack guide body corresponding to the restricting portion is complicated, and high manufacturing accuracy is required. For this reason, the manufacturing process becomes complicated, which further increases the manufacturing cost.

  The present invention has been made in view of the present problems described above, and supports a rack bar meshed with a pinion pivotally supported by a gear case via rack teeth so as to be movable in the axial direction. A rack and pinion type steering apparatus including a rack guide and the rack guide, which can prevent the rack guide from being worn and can smoothly support a rack bar, and a rack and pinion type steering apparatus including the rack guide Is to be provided without an increase in manufacturing cost.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  In other words, the rack guide according to claim 1 of the present invention is a rack guide that supports a rack bar that meshes with a pinion that is pivotally supported by a gear case via rack teeth so as to be movable in the axial direction. A sliding plate piece formed in a concave shape that slidably comes into contact with a convex surface on the opposite side to the side on which the rack teeth are formed in the bar, and a mounting surface comprising a shape corresponding to the sliding plate piece A rack guide body formed at one end of the sliding plate piece, wherein the sliding plate piece has tongue pieces formed at both side ends in a direction orthogonal to the moving direction of the rack bar. In the surface, protrusions are formed at both end portions in the direction orthogonal to the moving direction of the rack bar, and the sliding plate piece is mounted on the rack guide body through the mounting surface, Tongue Preliminary the protrusion portion is characterized in that mutually fit together.

As described above, in the rack guide of the present invention, the tongue piece portions respectively formed on the both side end portions of the sliding plate piece and the protruding portions respectively formed on the both side end portions of the mounting surface of the rack guide body. Since the sliding plate pieces are firmly fixed to the rack guide main body by being fitted to each other, the rack plate only when the mounting posture of the sliding plate pieces to the rack guide main body is a predetermined posture. The sliding plate piece can be mounted on the guide body, and the mounting posture of the sliding plate piece with respect to the rack guide body can always be maintained in a predetermined posture.
Therefore, it is possible to prevent the rack bar from coming into contact with the rack guide, and it is possible to prevent the rack guide (more specifically, the sliding plate piece) from being worn out.
Further, in the rack guide of the present invention, as in the conventional rack guide, a protrusion by press drawing is formed in the center of the sliding plate piece, and a hole corresponding to the protrusion is formed in the rack guide body. Since there is no need to form, a concave portion corresponding to the protruding portion is not formed at the center of the sliding support surface of the sliding plate piece as described above. By reducing the area by the cross-sectional integral of the recess, the stress applied to the sliding support surface when supporting the rack bar increases, and wear of the rack guide (more specifically, the sliding plate piece) is reduced. There is nothing to encourage.
Furthermore, in the rack guide of the present invention, it is not necessary to perform press drawing processing having a complicated manufacturing process when forming protrusions on the sliding plate piece, and the sliding plate piece is formed by a simple press punching process. Therefore, the manufacturing cost of the rack guide as a whole can be reduced.

  Further, in the rack guide according to claim 2 of the present invention, a pair of tongue pieces are formed at the both side ends of the sliding plate piece so as to be separated from each other in the moving direction, The protruding portions are respectively formed in the central portion in the moving direction at the both side end portions of the mounting surface, and the protruding pieces are sandwiched between the tongue pieces so that the tongue pieces and the protruding portions are sandwiched between the protruding pieces. The raising portions are characterized by being fitted to each other.

  As described above, according to the rack guide of the present invention, from the pair of tongue pieces provided at both side ends of the sliding plate piece and the protruding portions provided at both side ends of the mounting surface of the rack guide body. With a simple configuration, they can be fitted to each other.

  Further, in the rack guide according to claim 3 of the present invention, the tongue piece portions are respectively formed in the center portion in the moving direction at the both side end portions of the sliding plate piece, and the mounting surface of the rack guide body is provided. A pair of the protruding portions are formed on the both side end portions in the moving direction so as to be separated from each other in the moving direction, and the tongue piece portion and the protruding portion are sandwiched by the pair of protruding portions. The raising portions are characterized by being fitted to each other.

  As described above, according to the rack guide of the present invention, the tongue piece portion provided at the both end portions of the sliding plate piece and the pair of protruding portions provided at the both end portions on the mounting surface of the rack guide main body. With a simple configuration, they can be fitted to each other.

  On the other hand, a rack and pinion steering device according to a fourth aspect of the present invention includes the rack guide according to any one of the first to third aspects.

  As described above, the rack and pinion type steering device of the present invention includes the rack guide of the present invention described above, thereby preventing the rack guide from being worn without increasing the manufacturing cost as a whole device. It can be supported smoothly.

  As effects of the present invention, the following effects can be obtained.

  That is, according to the rack guide and the rack and pinion type steering apparatus including the rack guide according to the present invention, the rack guide can be prevented from being worn and the rack bar can be smoothly supported without increasing the manufacturing cost. .

The cross-sectional side view which showed the whole structure of the rack and pinion type steering apparatus provided with the rack guide which concerns on one Embodiment of this invention. It is the figure which showed the structure of the rack guide, Comprising: (a) is the top view, (b) is the side view. It is the figure which showed the structure of the rack guide which concerns on another embodiment of this invention, Comprising: (a) is the top view, (b) is the partial cross section side view seen from the direction of arrow B of Fig.3 (a) . The cross-sectional side view which showed the whole structure of the rack and pinion type steering device provided with the conventional rack guide.

  Next, embodiments of the invention will be described.

[Rack and pinion steering device 1]
First, an overall configuration of a rack and pinion steering device 1 (hereinafter simply referred to as “steering device 1”) including a rack guide 6 embodying the present invention will be described with reference to FIG.
In the following description, for convenience, the vertical direction in FIG. 1 is described as the vertical direction of the steering device 1.
In FIG. 1, the direction of the arrow A is defined as the front of the steering device 1.

The steering device 1 in the present embodiment is a device for converting, for example, a rotation operation of a pinion 2 rotated by a steering wheel (not shown) into a straight movement operation of the rack bar 3.
The steering device 1 is provided with a gear case 4, and one end of the pinion 2 is inserted into the gear case 4, for example, toward the front (in the direction of arrow A in FIG. 1).

Here, a pinion tooth 2 a is formed at one end of the pinion 2.
In the gear case 4, one end of the pinion 2 is pivotally supported via a pair of bearings 5 and 5 arranged with the pinion teeth 2 a interposed therebetween.

  The other end of the pinion 2 extends in the axial direction outside the gear case 4 and is connected to a steering wheel (not shown).

A rack bar 3 that meshes with the pinion 2 is disposed inside the gear case 4.
Rack teeth 3a are formed on the outer peripheral surface of the central portion in the axial direction of the rack bar 3, and the back surface (the surface opposite to the side on which the rack teeth 3a are formed) with respect to the rack teeth 3a has a predetermined curvature. It is a convex surface 3b having a circular arc shape in a sectional view having a radius.

  The rack bar 3 is disposed below the pinion teeth 2a so as to extend in a direction orthogonal to the pinion 2 (for example, in the left-right direction in the present embodiment), and the pinion teeth 2a are connected to the rack bars 3a via the rack teeth 3a. Meshed.

  Both end portions of the rack bar 3 protrude from the inside of the gear case 4 toward the outside, and the rack bar 3 can slide in the axial direction (left-right direction) via a bearing member (not shown). Supported by

A hollow housing portion 4 a extending in a cylindrical shape is integrally formed on the lower surface of the gear case 4.
The housing portion 4a is formed at a position such that the rack bar 3 is sandwiched between the housing 4a and the pinion 2, and the rack bar 3 slides on the inner peripheral portion (space portion surrounded by the inner peripheral surface). A rack guide 6 that is supported is slidably disposed in the extending direction of the housing portion 4a (in the present embodiment, the vertical direction).

  And the rack guide 6 is urged | biased by the rack bar 3 side by the compression coil spring 8 as an elastic member arrange | positioned between the cover members 7 which obstruct | occlude the lower end of the housing part 4a.

  In the steering apparatus 1 having the above-described configuration, when the pinion 2 is rotated around the axis via a steering wheel (not shown), the rotational driving force applied to the pinion 2 is the pinion teeth. 2a and rack teeth 3a are transmitted in this order, and converted into a propulsive force in the axial direction of the rack bar 3.

[Rack guide 6]
Next, the configuration of the rack guide 6 will be described in detail with reference to FIGS. 1, 2, and 4.
In the following description, for the sake of convenience, the vertical direction in FIG. 2B is defined as the vertical direction of the rack guide 6, and the vertical direction in FIG. 4 is defined as the vertical direction of the conventional rack and pinion steering device 101. Describe.
2A, 2B, and 4, the direction of arrow A is defined as the front of the rack guide 6 or the conventional rack and pinion steering device 101.

As shown in FIG. 1, the rack guide 6 supports the rack bar 3 engaged with the pinion 2 so as to be slidable in the axial direction of the rack bar 3 while pressing the rack bar 3 toward the pinion 2 side. Is.
The rack guide 6 includes a sliding plate piece 61 that comes into contact with the convex surface 3b of the rack bar 3, a rack guide main body 62 on which the sliding plate piece 61 is mounted, and the like.

The sliding plate piece 61 has a main body portion 61a having a concave surface shape having an arc shape substantially the same as the convex surface 3b of the rack bar 3, and a moving direction of the rack bar 3 in the main body portion 61a (in the present embodiment, the left-right direction). It is comprised by a pair of tongue piece part 61b * 61b etc. which are each provided in the both-sides edge part of the orthogonal direction (in this embodiment, the front-back direction).
Specifically, as shown in FIG. 2A, the pair of tongue pieces 61 b and 61 b are arranged in the moving direction (left-right direction) of the rack bar 3 at each end on the front and rear sides of the sliding plate piece 61. It is spaced apart and is formed to protrude horizontally toward the front or rear.

On the other hand, as shown in FIG. 2 (b), the rack guide main body 62 is constituted by a cylindrical metal member made of, for example, an Fe-based sintered metal or an aluminum alloy, and one end thereof (in the present embodiment, At the upper end), a mounting surface 62a having a concave shape having a circular arc shape in cross section corresponding to the main body portion 61a of the sliding plate piece 61 is formed, and at the other end (the lower end in the present embodiment). Is formed with a cylindrical hollow portion 62b capable of holding the compression coil spring 8 (see FIG. 1).
Further, as shown in FIG. 2A, at the upper end portion of the rack guide main body 62, convex portions are protruded at both end portions in the orthogonal direction (front-rear direction) with respect to the moving direction (left-right direction) of the rack bar 3 on the mounting surface 62a. The raising parts 62c are each formed in the center of the moving direction (left-right direction).

  The width dimension in the left-right direction of each protrusion 62c (dimension Wa in FIG. 2A) is the distance between the pair of tongue pieces 61b and 61b (dimension Wb in FIG. 2A). Are set to be approximately the same (Wa = Wb).

At the upper end of the rack guide main body 62, the sliding plate piece 61 is fitted to the rack guide main body 62 via the mounting surface 62a while the protruding portions 62c are fitted by the pair of tongue pieces 61b and 61b. Installed.
In other words, in a state where the sliding plate piece 61 is mounted on the rack guide main body 62 via the mounting surface 62a, the tongue piece portion 61b and the protruding portion 62c are fitted to each other.
As a result, the sliding plate piece 61 is firmly held at the upper end of the rack guide body 62.

  As shown in FIG. 1, the rack guide 6 having such a configuration has a housing portion 4 a and a gear portion 4 with the concave surface side of the main portion 61 a of the sliding plate piece 61 facing the rack bar 3 side. It is arranged on the same axis. Further, the other end portion of the compression coil spring 8 whose one end portion is fixed by the lid member 7 is held via a cylindrical hollow portion 62 b of the rack guide main body 62.

Thus, the rack guide 6 contacts the convex surface 3b of the rack bar 3 through the main body portion 61a of the sliding plate piece 61, and the inner peripheral portion of the housing portion 4a through the outer peripheral surface 62d of the rack guide body 62. It is arranged to be slidable in the axial direction (in this embodiment, the vertical direction). That is, the rack guide 6 is slidably disposed on the inner peripheral portion of the housing portion 4a in the direction of approaching and separating from the rack bar 3 via the outer peripheral surface 62d.
At this time, the rack guide 6 is always urged toward the rack bar 3 by the compression coil spring 8.

As described above, in the rack guide 6 of the present embodiment, the rack guide body 62 (more specifically, the pair of tongue pieces 61b and 61b formed at the both ends in the front-rear direction of the sliding plate piece 61, respectively. Specifically, the projecting portions 62c (see FIG. 2) formed at both end portions in the front-rear direction of the mounting surface 62a) are fitted, so that the sliding plate piece 61 is firmly attached to the rack guide body 62. It is configured to be fixed to.
Therefore, the sliding plate piece 61 can be attached to the rack guide main body 62 only when the mounting posture of the sliding plate piece 61 with respect to the rack guide main body 62 is a predetermined posture. The mounting posture of the moving plate piece 61 can always be maintained in a predetermined posture.
Therefore, it is possible to prevent the rack bar 3 from coming into contact with the rack guide 6, and the sliding plate piece 61 in the rack guide 6 will not be worn out.

Further, in the rack guide 6 of the present embodiment, as shown in FIG. 4, the protruding portion 161 a by the press drawing process as the rack guide 106 provided in the conventional rack and pinion type steering device 101 is provided with the sliding plate piece 161. It is not necessary to form in the center of the rack guide body 162, or to form a hole 162a corresponding to the projection 161a in the rack guide main body 162.
Accordingly, as in the conventional rack guide 106, the concave portion 161b corresponding to the protruding portion 161a is formed at the center of the concave surface side of the sliding plate piece 161, so that the pressure receiving area of the sliding plate piece 161 is reduced by the concave portion. In this embodiment, the rack guide 6 (especially the sliding plate) is reduced because the stress applied to the sliding plate piece 161 when the rack bar 103 is supported is not increased. The wear of the piece 61) is not promoted.

  Furthermore, in the rack guide 6 of the present embodiment, unlike the conventional rack guide 106, there is no need to perform press drawing processing having a complicated manufacturing process for forming the protruding portion 161a on the sliding plate piece 161. Since the sliding plate piece 61 can be formed by a simple press punching process, the manufacturing cost of the rack guide 6 can be reduced as a whole.

  In FIG. 1, the arrangement position of the rack guide 6 is not limited to the present embodiment, and the rack bar 3 can be supported while being pressed toward the pinion 2 via the sliding plate piece 61. As long as it is provided in any direction along the axial direction of the rack bar 3.

[Rack guide 206 (another embodiment)]
Next, the configuration of the rack guide 206 according to another embodiment of the present invention will be described in detail with reference to FIGS. 3 and 4.
In the following description, for convenience, the vertical direction in FIG. 3B is described as the vertical direction of the rack guide 206.
3A and 3B, the direction of arrow A is defined as the front of the rack guide 206.

The rack guide 206 in another embodiment has substantially the same configuration as the rack guide 6 described above. On the other hand, in the configuration of the tongue piece portion 261b of the sliding plate piece 261 and the protruding portion 262c of the rack guide body 262, the rack guide 6 and different.
Therefore, in the following description, differences from the rack guide 6 will be mainly described, and descriptions of configurations equivalent to the rack guide 6 will be omitted.

  The rack guide 206 includes a sliding plate piece 261 that comes into contact with the convex surface 203b of the rack bar 203, a rack guide body 262 on which the sliding plate piece 261 is mounted, and the like.

The sliding plate piece 261 has a main body portion 261a having a concave shape having an arc shape substantially the same as the convex surface 203b of the rack bar 203, and a direction orthogonal to the moving direction (left-right direction) of the rack bar 203 in the main body portion 261a. ) On both side end portions of the tongue piece portion 261b provided at the center in the moving direction (left-right direction).
Specifically, as shown in FIG. 3A, the tongue piece portion 261b is formed to protrude in the horizontal direction toward the front or the rear at each of the front and rear ends of the sliding plate piece 261.

On the other hand, as shown in FIG. 3 (b), the rack guide main body 262 is constituted by a columnar metal member made of, for example, an Fe-based sintered metal or an aluminum alloy, and at one end (upper end) thereof, A mounting surface 262a having a concave shape in an arc shape in cross section corresponding to the main portion 261a of the sliding plate piece 261 is formed.
Further, as shown in FIG. 3A, at the upper end portion of the rack guide main body 262, a pair of end portions on both sides of the mounting surface 262a in the orthogonal direction (front-rear direction) with respect to the moving direction (left-right direction) of the rack bar 203 are provided. The protruding portions 262c and 262c are formed apart from each other in the movement direction (left-right direction) of the rack bar 3.

  Note that the separation dimension (the dimension Wc in FIG. 3A) of the pair of protruding portions 262c and 262c is substantially the same as the width dimension of the tongue piece 261b (the dimension Wd in FIG. 3A). (Wc = Wd).

At the upper end of the rack guide body 262, the sliding plate piece 261 is fitted to the rack guide body 262 via the mounting surface 262a while the tongue pieces 261b are fitted by the pair of protruding portions 262c and 262c. Installed.
In other words, in a state where the sliding plate piece 261 is attached to the rack guide main body 262 via the attachment surface 262a, the tongue piece portion 261b and the protruding portion 262c are fitted to each other.
Thereby, the sliding plate piece 261 is firmly held at the upper end of the rack guide body 262.

As described above, in the rack guide 206 according to another embodiment, a pair of protruding portions 262c, which are respectively formed at both end portions in the front-rear direction of the rack guide main body 262 (more specifically, the mounting surface 262a). The sliding plate piece 261 is firmly fixed to the rack guide main body 262 by fitting the tongue piece portions 261b respectively formed at both end portions in the front-rear direction of the sliding plate piece 261 by the 262c. It has become.
Therefore, the sliding plate piece 261 can be attached to the rack guide main body 262 only when the mounting posture of the sliding plate piece 261 with respect to the rack guide main body 262 is a predetermined posture. The mounting posture of the moving plate piece 261 can always be maintained in a predetermined posture.
Accordingly, it is possible to prevent the rack bar 203 from coming into contact with the rack guide 206 and to prevent the sliding plate piece 261 from being worn out in the rack guide 206.

Moreover, in the rack guide 206 of another embodiment, as shown in FIG. 4, the protrusion 161a by press drawing like the rack guide 106 with which the conventional rack and pinion type steering apparatus 101 is provided is a sliding plate piece 161. It is not necessary to form in the center of the rack guide body 162, or to form a hole 162a corresponding to the projection 161a in the rack guide main body 162.
Accordingly, as in the conventional rack guide 106, the concave portion 161b corresponding to the protruding portion 161a is formed at the center of the concave surface side of the sliding plate piece 161, so that the pressure receiving area of the sliding plate piece 161 is reduced by the concave portion. In this embodiment, the rack guide 206 (especially the sliding plate) is reduced because the stress applied to the sliding plate piece 161 when supporting the rack bar 103 is not increased. The wear of the piece 261) is not promoted.

  Furthermore, in the rack guide 206 according to another embodiment, unlike the conventional rack guide 106, there is no need to perform press drawing which has a complicated manufacturing process for forming the protrusion 161a on the sliding plate piece 161. Since the sliding plate piece 261 can be formed by a simple press punching process, the manufacturing cost of the rack guide 206 as a whole can be reduced.

DESCRIPTION OF SYMBOLS 1 Rack pinion type steering device 2 Pinion 3 Rack bar 3a Rack tooth 3b Convex surface 4 Gear case 6 Rack guide 61 Sliding plate piece 61b Tongue piece part 62 Rack guide main body 62a Mounting surface 62c Protrusion part 203 Rack bar 203b Convex surface 206 Rack guide 261 Sliding plate piece 261b Tongue piece 262 Rack guide body 262a Mounting surface 262c Protrusion

Claims (4)

A rack guide that supports a rack bar that meshes with a pinion pivotally supported by a gear case via rack teeth, and is movable in the axial direction.
A sliding plate piece formed in a concave shape that slidably contacts the convex surface on the opposite side to the side on which the rack teeth are formed in the rack bar;
A rack guide main body having a mounting surface formed at one end thereof in a shape conforming to the sliding plate piece;
With
In the sliding plate piece,
Tongue pieces are formed at both ends in the direction perpendicular to the direction of movement of the rack bar,
In the mounting surface of the rack guide body,
Protrusions are formed at both end portions in the direction perpendicular to the direction of movement of the rack bar,
In the state where the sliding plate piece is mounted on the rack guide body through the mounting surface,
The tongue piece and the raised portion are fitted to each other;
A rack guide characterized by that. At the both ends of the sliding plate piece,
A pair of tongue pieces are formed apart from each other in the moving direction,
In the both end portions of the mounting surface of the rack guide body,
The protruding portions are respectively formed in the central portion of the moving direction;
By sandwiching the protruding portion by a pair of tongue pieces,
The tongue piece and the raised portion are fitted to each other;
The rack guide according to claim 1, wherein: At the both ends of the sliding plate piece,
The tongue pieces are respectively formed at the center in the moving direction;
In the both end portions of the mounting surface of the rack guide body,
A pair of the protruding portions are formed apart from each other in the moving direction,
By sandwiching the tongue piece part by a pair of protruding parts,
The tongue piece and the raised portion are fitted to each other;
The rack guide according to claim 1, wherein: A rack guide according to any one of claims 1 to 3 is provided.
A rack-and-pinion type steering device characterized by that.

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