JP2019019952A - Slide bearing - Google Patents

Abstract

To provide a slide bearing which can reduce the generation of noise caused by the backlash of a shaft member while suppressing torque generated by slide movement sliding with the shaft member.SOLUTION: A rack bush 1 is accommodated in a cylindrical housing 2 with its movement in an axis O-direction regulated, is attached to a back face (the face on the opposite side of a rack gear 40) 41 side of a rack bar 4, and supports a load applied to the rack bar 4 while permitting the movement of the rack bar 4 in the axis O-direction. The rack bush comprises: a cylindrical bush main body 10 having a clearance between the rack bar 4 and itself; a through slit 120 formed through both end faces of the bush main body 10 along an axial direction at the rack gear 40 side of the rack bar 4; and a pair of support faces 11 for supporting the rack bar 4 in contact with the rack bar 4 so as to sandwich the rack bar from a vertical direction (the width direction of the through slit 102) V.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a sliding bearing that supports a load applied to a shaft member, and more particularly to a sliding bearing suitable for a rack bush used in a rack and pinion type steering mechanism.

  The rack-and-pinion type steering mechanism is a linear movement of the rack gear that rotates the pinion gear by meshing with the pinion gear formed at the tip of the shaft that rotates in conjunction with the steering wheel and the rack gear formed on the rack bar. Convert to Thereby, the direction of the tire connected to the tie rod interlocked with the rack bar is changed.

  Patent Document 1 discloses a rack and pinion type steering mechanism including a rack bush. In this steering mechanism, the rack bush is mounted on the back side of the rack gear surface of the rack bar and supports the rack bar when a load is applied while allowing the rack bar to move linearly. Moreover, the rack bush has a through slit that penetrates both end surfaces formed along the axial direction on the rack gear side of the rack bar. Therefore, the rack bush is easily reduced in diameter as compared with a cylindrical bush without the through slit. The assembly work of the rack bush to the housing that houses the rack bush together with the rack bar becomes easy and smooth.

JP 2013-79024 A

  In the rack bush described in Patent Document 1, the inner peripheral surface is in contact with the outer peripheral surface of the rack bar over the entire periphery. For this reason, torque is generated by sliding between the rack bar and the rack bush, which affects the steering operation. In order to reduce this influence, it is preferable to have a clearance with respect to the entire circumference of the rack bar so as not to contact the rack bar.

  However, in the rack-and-pinion type steering mechanism, when the rotational motion of the pinion gear is converted into the linear motion of the rack gear, the rack gear is dragged in the vertical direction by the pinion gear, and the rack bar is rattled in the vertical direction. For this reason, in a rack bush having a clearance with respect to the entire circumference of the rack bar, abnormal noise may be generated by abutting the rack bar due to rattling in the vertical direction of the rack bar.

  This problem is not limited to the rack bush used in the rack and pinion type steering mechanism. In the sliding bearing that supports the load applied to the shaft member, when the clearance is provided with respect to the entire circumference of the shaft member, this occurs due to rattling of the shaft member.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a sliding bearing capable of reducing the generation of noise due to rattling of the shaft member while suppressing torque due to sliding with the shaft member. It is to provide.

  In order to solve the above-described problem, in the present invention, a through-hole slit is formed in a cylindrical bearing body into which a shaft member is inserted so as to penetrate both end surfaces of the bearing body along the axial direction. A pair of support surfaces that contact and support the shaft member so as to sandwich the shaft member are provided radially inward from the inner peripheral surface of the bearing body.

For example, the present invention
A sliding bearing for supporting a shaft member,
A cylindrical bearing body into which the shaft member is inserted;
A through slit penetrating both axial end surfaces of the bearing body;
A pair of support surfaces that are formed radially inward from the inner peripheral surface of the bearing body and support the shaft member so as to be sandwiched from the width direction of the through slit.

  In the present invention, the shaft member is supported by the pair of support surfaces so as to be sandwiched from the width direction of the through slit, so that the shaft member is prevented from rattling in the width direction of the through slit, and the shaft member due to this backlash is prevented. The contact can be prevented, and thereby the generation of abnormal noise can be prevented. Further, since the pair of support surfaces are formed radially inward from the inner peripheral surface of the bearing body, the contact with the shaft member inserted into the bearing body can be made only to the support surface. Torque due to sliding between the member and the sliding bearing can be suppressed. Therefore, according to this invention, generation | occurrence | production of the noise by the shakiness of a shaft member can be reduced, suppressing the torque by sliding with a shaft member.

FIG. 1 is a partial top sectional view of a rack and pinion type steering mechanism in which a rack bush 1 according to an embodiment of the present invention is used. FIG. 2 is a side sectional view of the rack and pinion type steering mechanism shown in FIG. FIGS. 3A, 3B, 3C, and 3D are a front view, a top view, a left side view, and a right side view of the rack bush 1, respectively. 4 (A) and 4 (B) are an AA sectional view and a BB sectional view of the rack bush 1 shown in FIG. 3 (C).

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a partial top sectional view of a rack and pinion type steering mechanism in which a rack bush 1 according to an embodiment of the present invention is used. 2 is a side sectional view of the rack-and-pinion type steering mechanism shown in FIG.

  As shown in the figure, the rack-and-pinion type steering mechanism includes a pinion gear 30 formed at the tip of the shaft 3 that rotates in conjunction with a steering wheel (not shown), and a rack gear 40 formed on the rack bar 4. By the meshing, the rotational motion R of the pinion gear 30 is converted into a linear motion L in the direction of the axis O of the rack gear 40 (perpendicular and horizontal to the vehicle traveling direction G). Thereby, the direction of the tire (not shown) connected to the tie rod (not shown) interlocked with the rack bar 4 is changed.

  Here, the rack bush 1 is housed in a cylindrical housing 2 in a state in which movement in the axis O direction is restricted, and is mounted on the rear surface (surface opposite to the rack gear 40) 41 side of the rack bar 4. Thus, the load applied to the rack bar 4 is supported while allowing the rack bar 4 to move in the axis O direction.

  FIGS. 3A, 3B, 3C, and 3D are a front view, a top view, a left side view, and a right side view of the rack bush 1, respectively. 4 (A) and 4 (B) are an AA sectional view and a BB sectional view of the rack bush 1 shown in FIG. 3 (C).

  The rack bush 1 is formed of a synthetic resin having good sliding characteristics such as polyacetal resin, polyamide resin, polyethylene resin, and the like, as shown in the figure, a cylindrical bush body 10 and a pair of support portions 13 each having a support surface 11. And.

  The bush main body 10 has a pair of slits 101 provided for each support portion 13, a through slit 102, and a flange 103.

  The pair of slits 101 is formed along the axis O direction from one end face 104 a to the other end face 104 b in the vertical direction V (the width direction of the through slit 102) V of the bush body 10. In addition, the corresponding support surface 11 of the support portion 13 is arranged inward in the radial direction.

  The through slit 102 passes through both end faces 104a and 104b of the bush main body 10 along the axis O direction on the rack gear 40 side of the rack bar 4 (see FIG. 2). It can be expanded and contracted in the direction. The width H1 of the through slit 102 is larger than the width H2 of the rack gear 40 of the rack bar 4 (see FIG. 2). This prevents the edge 1020 of the through slit 102 from coming into contact with the gear surface of the rack gear 40.

  The flange 103 is formed on the outer peripheral surface 105 of the bush main body 10 on the other end surface 104 b side of the bush main body 10, and is inserted into the annular groove 21 formed in the circumferential direction on the inner peripheral surface 20 of the housing 2. Thereby, the movement of the rack bush 1 accommodated in the housing 2 in the direction of the axis O is regulated (see FIG. 1).

  The flange 103 is formed with a protrusion 106 for alignment. By inserting the protrusion 106 into a guide groove 22 formed in the axis O direction on the inner peripheral surface 20 of the housing 2, the through slit 102 is formed. Is positioned on the rack gear 40 side of the rack bar 4 and the rack bush 1 is correctly positioned so that the width direction thereof coincides with the vertical direction V (see FIG. 1).

  The bush main body 10 has an inner peripheral surface 109 disposed on the back surface 41 side of the rack bar 4, a first inner diameter portion 107 having an inner diameter r 1 larger than the outer diameter r 3 of the rack bar 4, and a first inner diameter portion 107. The second inner diameter portion 108 is arranged on the rack gear 40 side of the rack bar 4 and has an inner diameter r2 larger than the inner diameter r1 of the first inner diameter portion 107. Thereby, the inner peripheral surface 109 of the bush main body 10 has a clearance with respect to the rack bar 4 over the entire periphery. Further, by setting the inner diameter r2 of the second inner diameter portion 108 to be larger than the inner diameter r1 of the first inner diameter portion 107, the bush main body 10 is mounted on the rack bar 4 by the back and forth of the rack bush 1 (vehicle traveling direction G). The possibility of contact with the rack gear 40 is reduced (see FIG. 2).

  The pair of support portions 13 are in contact with and supported by the support surfaces 11 so as to sandwich the rack bar 4 from the vertical direction V (see FIG. 2). As described above, the support portions 13 are arranged in the corresponding slits 101 with the support surface 11 facing radially inward, and are connected to the bushing body 10 by the arms 12 extending in the axis O direction. The arm 12 and the support portion 13 are disposed on the inner side (axis O side) of the bush body 10 than the outer peripheral surface 105 of the bush body 10. For this reason, when the rack bush 1 is accommodated in the housing 2, a gap g is formed between the outer peripheral surface 14 of the arm 12 and the outer peripheral surface 15 of the support portion 13 and the inner peripheral surface 20 of the housing 2 (see FIG. 2). Thus, the support surface 11 can move in the vertical direction V and the circumferential direction C while contacting the rack bar 4.

  Each of the pair of support portions 13 has the support surface 11 arranged on a circle 110 set so as to be squeezed with respect to the rack bar 4, thereby reliably contacting the rack bar 4. Has been. Furthermore, each of the pair of support portions 13 has the support surface 11 disposed on the rack gear 40 side of the rack bar 4 with respect to the vertical line D including the axis O and parallel to the width direction of the through slit 102. Thereby, the backlash of the rack bush 1 before and after (vehicle traveling direction G) is suppressed, and the possibility that the bush body 10 contacts the rack gear 40 of the rack bar 4 is reduced (see FIG. 2).

  The embodiment of the present invention has been described above.

  In the present embodiment, since the rack bush 1 is mounted on the rack bar 4 so that the width direction of the through slit 102 coincides with the vertical direction V of the rack bar 4, the rack bush 1 supports the pair of support portions 13. The rack bar 4 is contacted and supported by the surface 11 so as to be sandwiched from the vertical direction V. For this reason, the backlash of the rack bar 4 in the vertical direction V can be suppressed to prevent the backlash from coming into contact with the rack bar 4, thereby preventing the generation of abnormal noise. Further, since the inner diameter (the inner diameter r1 of the first inner diameter portion 107 and the inner diameter r2 of the second inner diameter portion 108) having a clearance with respect to the rack bar 4 is used and only the support surface 11 is in contact with the rack bar 4, the rack bar The torque caused by sliding between the rack bush 1 and the rack bush 1 can be reduced to reduce the influence on the steering operation. Therefore, it is possible to reduce the occurrence of abnormal noise while suppressing the influence on the steering operation.

  In the present embodiment, the support portion 13 has the support surface 11 disposed in the corresponding slit 101 inward in the radial direction, and is connected to the bushing body 10 by the arm 12 extending in the axis O direction. Yes. The support surface 11 can move in the vertical direction V and the circumferential direction C while abutting the rack bar 4 by elastic deformation in the width direction of the through slit 102 of the arm 12 and the circumferential direction of the bush body 10. The pair of support surfaces 11 can be reliably brought into contact with the rack bar 4.

  Further, in the present embodiment, since the through slit 102 penetrating the both end faces 104a and 104b of the bush main body 10 is provided along the axis O direction on the rack gear 40 side of the rack bar 4, the through slit 102 allows the bush The main body 10 can be expanded and contracted in the radial direction, and can be easily attached to the housing 2.

  Further, in the present embodiment, the pair of support surfaces 11 that support the rack bar 4 from the vertical direction V are provided on the rack bar 4 with respect to the vertical line D including the axis O and parallel to the width direction of the through slit 102. Since it is arranged on the rack gear 40 side, backlash of the rack bush 1 before and after (vehicle traveling direction G) can be suppressed, and the possibility that the bush body 10 contacts the rack gear 40 of the rack bar 4 can be reduced. Therefore, the occurrence of abnormal noise can be further reduced.

  Further, in the present embodiment, the bush main body 10 includes the first inner diameter portion 107 disposed on the back surface 41 side of the rack bar 4 with the inner diameter r2 of the second inner diameter portion 108 disposed on the rack gear 40 side of the rack bar 4. Since the inner diameter r1 of the rack bush 1 is larger than the inner diameter r1, the possibility of the bush body 10 coming into contact with the rack gear 40 of the rack bar 4 can be reduced due to the back and forth of the rack bush 1 (vehicle traveling direction G). The generation of abnormal noise can be further reduced.

  In addition, this invention is not limited to said embodiment, Many deformation | transformation are possible within the range of the summary.

  For example, in the above-described embodiment, the support surface 11 is disposed radially inward in the corresponding slit 101 and connected to the bushing body 10 by the arm 12 extending in the axis O direction. However, the present invention is not limited to this. The support surface 11 may be connected to the bushing body 10 by any method as long as it can move in the vertical direction V while contacting the rack bar 4. For example, an elastic body such as rubber or thermoplastic elastomer is interposed between the support surface 11 and the inner peripheral surface 109 of the bush body 10, so that the support surface 11 is brought into contact with the rack bar 4 in the vertical direction V. It may be movable. Alternatively, a gap is provided between the support portion 13 and the inner peripheral surface 20 of the housing 2 so that the support portion 13 can move within the gap, thereby causing the support surface 11 to contact the rack bar 4 in the vertical direction. It may be movable to V.

  Further, the present invention is not limited to a rack bush used in a rack and pinion type steering mechanism. The present invention can be widely applied to a sliding bearing that supports a shaft member.

1: rack bush, 2: housing, 3: shaft, 4: rack bar, 10: bushing body, 11: support surface, 12: arm, 13: support portion, 14: outer peripheral surface of arm 12, 15: support portion 13 20: Inner peripheral surface of the housing 2, 21: An annular groove 21 of the housing 2, 22: Guide groove of the housing 2, 30: Pinion gear, 40: Rack gear, 101: Slit, 102: Through slit, 103: 104a, 104b: end surface of the bush body 10, 105: outer peripheral surface of the bush body 10, 106: protrusion of the flange 103, 107: first inner diameter portion of the bush body 10, 108: second inner diameter portion of the bush body 10 109: Inner peripheral surface of the bush body 10 1020: Edge of the through slit 102

Claims (12)

A sliding bearing for supporting a shaft member,
A cylindrical bearing body into which the shaft member is inserted;
A through slit penetrating both axial end surfaces of the bearing body;
A pair of support surfaces that are formed radially inward from the inner peripheral surface of the bearing body and support the shaft member so as to sandwich the shaft member from the width direction of the through slit. . The sliding bearing according to claim 1,
The sliding bearing is characterized in that the support surface is movable while contacting the shaft member. A sliding bearing according to claim 1 or 2,
The bearing body is
A pair of slits provided corresponding to each of the pair of support surfaces, and formed in the axial direction from one end surface to the other end surface;
An arm that is provided corresponding to each of the pair of support surfaces and is elastically deformable,
The support surface is
A sliding bearing, wherein the sliding bearing is disposed in the corresponding slit and connected to the bearing body by the corresponding arm. The sliding bearing according to claim 3,
The arm is
A sliding bearing, wherein the sliding bearing is arranged inside the bearing body relative to an outer peripheral surface of the bearing body. The sliding bearing according to claim 3,
The sliding bearing is
It is accommodated in a cylindrical housing with axial movement restricted.
The arm is
A slide bearing having a gap in a radial direction with respect to an inner peripheral surface of the housing. The sliding bearing according to claim 1 or 2,
Each further comprising a pair of support portions formed with the support surfaces;
The pair of support portions is
A sliding bearing, wherein the sliding bearing is arranged inside the bearing body relative to an outer peripheral surface of the bearing body. The sliding bearing according to claim 1 or 2,
Each further comprising a pair of support portions formed with the support surfaces;
The sliding bearing is
It is accommodated in a cylindrical housing with axial movement restricted.
The pair of support portions is
A slide bearing having a gap in a radial direction with respect to an inner peripheral surface of the housing. A sliding bearing according to any one of claims 1 to 7,
The pair of support surfaces is
A plain bearing comprising an axial center and arranged on the through slit side with respect to a straight line parallel to the width direction of the through slit. A sliding bearing according to any one of claims 1 to 8,
The shaft member is
It is a rack bar of a rack and pinion type steering mechanism,
The sliding bearing is
The sliding bearing, wherein the through slit is attached to the rack bar so as to penetrate the both end surfaces of the bushing body along the axial direction on the rack gear side of the rack bar. The sliding bearing according to claim 9, wherein
The pair of support surfaces is
A sliding bearing characterized in that it is arranged on the rack gear side of the rack bar with respect to a straight line including an axis and parallel to the width direction of the through slit. A sliding bearing according to claim 9 or 10,
The bearing body is
A first inner diameter portion disposed on the back side opposite to the rack gear of the rack bar;
A slide bearing comprising: a second inner diameter portion which is arranged on the rack gear side of the rack bar from the first inner diameter portion and is larger in diameter than the first inner diameter portion. A sliding bearing according to any one of claims 9 to 11,
The width of the through slit is
A slide bearing characterized by being larger than the width of the rack gear of the rack bar.

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