JP2019163030A - Steering device - Google Patents

Abstract

An object of the present invention is to provide a steering device capable of reducing a difference in operation load of an operation member due to a position of a column jacket after tilt adjustment. A lock mechanism locks a position of a column jacket with respect to an upper fixing bracket after tilt adjustment. The lock mechanism 19 includes an insertion shaft 40, an operation member 41, a first pressing member 43, and a second pressing member 44. The insertion shaft 40 is inserted into the long slot for tilt 25 of the first outer plate 22 and the second outer plate 23. The first pressing member 43 presses the first outer plate 22 against the first inner plate 26 by pressing the first outer plate 22. The second pressing member 44 presses the first inner plate 26 against the first outer plate by pressing the second inner plate 27 through the long slot 25 for tilt of the second outer plate 23. The drive mechanism 60 moves the second pressing member 44 so that the first pressing member 43 and the second pressing member 44 approach each other in the insertion axis direction J with the rotation of the operation member 41. [Selection diagram] FIG.

Description

  The present invention relates to a steering device.

  The steering device described in Patent Document 1 below is provided with a lock mechanism for locking the position of the steering column after tilt adjustment. The lock mechanism includes an operation lever and a support shaft. The support shaft is inserted into a tilt long hole formed in each of the pair of side plates of the vehicle body side bracket and a telescopic long hole formed in each of the pair of side plates of the column side bracket.

JP 2013-001243 A

  At the time of tilt adjustment, the support shaft moves in the tilt direction with respect to the vehicle body side bracket together with the steering column and the column side bracket. When the operating lever is operated after the tilt adjustment, the operating force of the operating lever is converted into the axial force of the support shaft, and the pair of side plates of the vehicle body side bracket receives the axial force and bends so as to approach each other. As the pair of side plates of the vehicle body side bracket is bent, the pair of side plates of the column side bracket is sandwiched by the pair of side plates of the vehicle body side bracket. Thereby, the position of the steering column after the tilt adjustment is locked.

  The position at which the axial force of the support shaft acts on the pair of side plates of the vehicle body side bracket varies depending on the position of the steering column after tilt adjustment. Since the pair of side plates of the vehicle body side bracket extends downward from the plate portion fixed to the vehicle body in the tilt direction, each of the pair of side plates of the vehicle body side bracket bends about the upper end in the tilt direction. Therefore, the pair of side plates of the vehicle body side bracket is less likely to bend as the position of receiving the axial force of the support shaft is closer to the upper end in the tilt direction, and is more likely to bend as the position of receiving the axial force of the support shaft is closer to the lower end of the tilt direction. Therefore, the operation load of the operation lever required to bend the pair of side plates of the vehicle body side bracket varies according to the position of the steering column after the tilt adjustment.

  The present invention has been made under such a background, and an object thereof is to provide a steering device that can reduce a difference in operation load of an operation member depending on a position of a column jacket after tilt adjustment.

  The invention according to claim 1 is a steering device (1; 1P; 1Q; 1R) capable of tilt adjustment, and a steering shaft (3) having a steering member (2) connected to one end thereof, and an insertion hole (25). ) Formed with a first side plate (22) and a second side plate (23), a fixed bracket (17) fixed to the vehicle body (13), and the steering shaft rotatably supported, A column jacket (4) disposed between the side plate and the second side plate and moving with respect to the fixed bracket during tilt adjustment, and a lock mechanism (19 for locking the position of the column jacket with respect to the fixed bracket after tilt adjustment) 19P), and the lock mechanism is inserted through the insertion hole of the first outer plate and the insertion hole of the second outer plate, and the insertion shaft. An operation member (41) supported and rotatable, a first pressing member (43; 43P) that presses the first side plate against the column jacket by pressing the first side plate, and the second side plate A second pressing member (44) for pressing the column jacket against the first side plate by pressing the column jacket through the insertion hole; and the first pressing member and the second pressing member as the operation member rotates. Is a steering device including a drive mechanism (60; 60P) that moves at least one of the first pressing member and the second pressing member so as to approach each other in the axial direction (J) of the insertion shaft.

  According to a second aspect of the present invention, the second pressing member has a facing portion (52) facing the outer side surface (23b) of the second side plate, the locking mechanism is configured so that the second pressing member is the second pressing member. The steering apparatus according to claim 1, further comprising an elastic member (46) that elastically deforms between the facing portion of the second pressing member and the outer side surface of the second side plate when the column jacket is pressed. is there.

According to a third aspect of the present invention, the drive mechanism (60) is provided on at least one of the first cam (61) that rotates integrally with the operation member, the first pressing member, and the second pressing member. The steering apparatus according to claim 1, further comprising a second cam (62) engaged with the first cam.
According to a fourth aspect of the present invention, the drive mechanism (60P) includes a male screw portion (40c) provided at one end of a shaft portion (40a) of a bolt as the insertion shaft and a nut ( 45), and with the rotation of the operation member, the head (40b) provided at the other end of the shaft portion and the nut are brought closer to each other, whereby the first pressing member and the second pressing member The steering apparatus according to any one of claims 1 to 3, wherein the members are moved closer to each other in the axial direction.

  In addition, in the above, the numbers in parentheses represent reference numerals of corresponding components in the embodiments described later, but the scope of the claims is not limited by these reference numerals.

  According to the first aspect of the present invention, the drive mechanism brings the first pressing member and the second pressing member closer to each other in the axial direction according to the rotation operation of the operating member. As a result, the first side plate of the fixed bracket is pressed by the first pressing member and pressed against the column jacket. Further, the second pressing member presses the column jacket without passing through the second side plate of the fixed bracket. As a result, the column jacket is pressed against the first side plate. When the column jacket and the first side plate are pressed against each other, the friction generated between the column jacket and the first side plate restricts the movement of the column jacket relative to the fixed bracket. That is, the position of the column jacket with respect to the fixed bracket is locked.

In this way, the position of the column jacket relative to the fixed bracket can be locked without holding the column jacket between the first side plate and the second side plate of the fixed bracket. Therefore, the difference in operation load of the operation member due to the position of the column jacket after tilt adjustment can be reduced.
According to the invention described in claim 2, the elastic member is elastically deformed between the opposing portion of the second pressing member and the second side plate when the second pressing member presses the column jacket. Therefore, the gap between the second side plate and the opposing portion of the second pressing member can be filled with the elastic member while reliably maintaining the pressing of the column jacket by the second pressing member. Therefore, it is possible to improve the support rigidity while achieving a reduction in the difference in operation load of the operation member depending on the position of the column jacket after tilt adjustment.

According to the third aspect of the present invention, the first pressing member and the second pressing member can be brought close to each other by a drive mechanism having a simple configuration of engagement between the first cam and the second cam.
According to the fourth aspect of the present invention, the drive mechanism is constituted by the male screw portion of the bolt and the nut. Therefore, the first pressing member and the second pressing member can be brought close to each other using a simple configuration of engagement between the bolt and the nut.

FIG. 1 is a schematic diagram illustrating a schematic configuration of a steering apparatus according to a first embodiment of the present invention. FIG. 2 is a cross-sectional view of the steering device in the vicinity of the lock mechanism, and is a diagram showing a unlocked state of the steering device. FIG. 3 is a cross-sectional view of the steering device in the vicinity of the lock mechanism, and shows a locked state of the steering device. FIG. 4 is a cross-sectional view of the steering device in the vicinity of the lock mechanism according to the second embodiment of the present invention, and shows the unlocked state of the steering device. FIG. 5 is a cross-sectional view of the steering device around the lock mechanism according to the second embodiment, and shows a locked state of the steering device. FIG. 6 is a cross-sectional view for explaining a modified example of the steering device according to the second embodiment. FIG. 7 is a perspective view of a steering apparatus according to the third embodiment of the present invention. FIG. 8 is a cross-sectional view of the steering device in the vicinity of the lock mechanism according to the third embodiment, and shows the unlocked state of the steering device. FIG. 9 is a cross-sectional view of the steering device around the lock mechanism according to the third embodiment, and shows a locked state of the steering device. FIG. 10 is a cross-sectional view of the steering device around the lock mechanism according to the fourth embodiment of the present invention, and shows the unlocked state of the steering device. FIG. 11 is a cross-sectional view of the steering device around the lock mechanism according to the fourth embodiment, and shows a locked state of the steering device. FIG. 12 is a cross-sectional view for explaining a modified example of the steering device according to the fourth embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
<First Embodiment>
FIG. 1 is a schematic diagram showing a schematic configuration of a steering apparatus 1 according to an embodiment of the present invention. With reference to FIG. 1, the steering device 1 includes a steering shaft 3, a column jacket 4, an intermediate shaft 5, and a steering mechanism 6. The steering shaft 3 extends substantially in the vertical direction of the vehicle. A steering member 2 such as a steering wheel is connected to one end (the upper end in the axial direction) of the steering shaft 3. The steering device 1 steers steered wheels (not shown) in conjunction with the steering of the steering member 2. The steering mechanism 6 is, for example, a rack and pinion mechanism, but is not limited thereto.

  Hereinafter, a direction in which the central axis A1 of the steering shaft 3 extends is referred to as a column axial direction X. The steering shaft 3 has a cylindrical upper shaft 3U and a lower shaft 3L extending in the column axial direction X. The upper shaft 3U and the lower shaft 3L are fitted so as to be relatively movable by, for example, spline fitting or serration fitting. The steering member 2 is coupled to the upper end in the axial direction of the upper shaft 3U.

  The steering device 1 further includes a lower fixed bracket 14, a tilt center shaft 15, and a lower movable bracket 16. The lower fixing bracket 14 is fixed to the vehicle body 13. The tilt center axis 15 is supported by the lower fixing bracket 14. The lower movable bracket 16 is fixed to the outer periphery of the lower end in the axial direction of the column jacket 4, and is supported by the lower fixing bracket 14 so as to be rotatable around the tilt center axis 15.

The column jacket 4 includes a lower jacket 8 supported by a lower fixing bracket 14 so as to be rotatable around a tilt center axis 15, and an upper jacket 7 slidably fitted to the lower jacket 8. The column axial direction X is also the axial direction of the upper jacket 7 and the axial direction of the lower jacket 8.
The steering shaft 3 is inserted into the column jacket 4. The upper shaft 3U is rotatably supported by the upper jacket 7 via a bearing 9. The lower shaft 3 </ b> L is rotatably supported by the lower jacket 8 via the bearing 10. When the upper shaft 3U moves in the column axial direction X with respect to the lower shaft 3L, the upper jacket 7 moves in the column axial direction X with respect to the lower jacket 8. The column jacket 4 can extend and contract in the column axial direction X together with the steering shaft 3.

By extending and retracting the steering shaft 3 and the column jacket 4 in the column axial direction X, the position of the steering member 2 can be adjusted in the longitudinal direction of the vehicle. Thus, the steering device 1 has a telescopic adjustment function.
The lower jacket 8 rotates in the tilt direction T together with the steering shaft 3 with the center axis (tilt center TC) of the tilt center shaft 15 provided near the lower end in the axial direction of the steering shaft 3 as a fulcrum. The tilt direction T is a direction that intersects the column axis direction X. By rotating the steering shaft 3 and the column jacket 4 about the tilt center TC, the position of the steering member 2 can be adjusted in the vertical direction of the vehicle. Thus, the steering device 1 has a tilt adjustment function.

  The steering device 1 further includes an upper fixing bracket 17 and a lock mechanism 19. The upper fixing bracket 17 is fixed to the vehicle body 13. The column jacket 4 further includes an upper movable bracket 18 fixed to the upper jacket 7 by welding or the like. The upper movable bracket 18 moves integrally with the upper jacket 7 at the time of tilt adjustment. The lock mechanism 19 is a mechanism for locking the position of the column jacket 4 after tilt adjustment. The state of the steering device 1 when the position of the column jacket 4 is locked by the lock mechanism 19 is referred to as “locked state”. The state of the steering device 1 when the position of the column jacket 4 is unlocked by the lock mechanism 19 is referred to as “unlocked state”.

2 and 3 are sectional views of the periphery of the lock mechanism 19. FIG. 2 is a diagram illustrating the unlocked state of the steering device 1, and FIG. 3 is a diagram illustrating the locked state of the steering device 1.
As shown in FIG. 2, the upper fixing bracket 17 includes a mounting plate 21, a first outer plate 22 (first side plate), a second outer plate 23 (second side plate), and a connecting plate 24.

  The attachment plate 21 is attached to the vehicle body 13. Each of the first outer plate 22 and the second outer plate 23 extends downward in the tilt direction T from the lower surface of the mounting plate 21. The first outer plate 22 and the second outer plate 23 face each other with an interval therebetween. The connecting plate 24 connects the upper end of the first outer plate 22 in the tilt direction T and the upper end of the second outer plate 23 in the tilt direction T. The first outer plate 22, the second outer plate 23, and the connecting plate 24 are integrally formed. Each of the first outer plate 22 and the second outer plate 23 is formed with a long tilt hole 25 extending in the tilt direction T.

The upper movable bracket 18 includes a first inner plate 26, a second inner plate 27 and a connecting plate 28. The first inner plate 26, the second inner plate 27, and the connecting plate 28 are integrally formed. The upper movable bracket 18 is disposed between the first outer plate 22 and the second outer plate 23.
Each of the first inner plate 26 and the second inner plate 27 extends downward in the tilt direction T from the outer peripheral surface of the upper jacket 7 of the column jacket 4. The upper ends of the first inner plate 26 and the second inner plate 27 in the tilt direction T are connected to the outer peripheral surface of the upper jacket 7 of the column jacket 4 by welding or the like. The connecting plate 28 connects the lower end of the first inner plate 26 in the tilt direction T and the lower end of the second inner plate 27 in the tilt direction T.

The first inner plate 26 has a plate shape along the inner surface 22 a of the first outer plate 22. The second inner plate 27 has a plate shape along the inner side surface 23 a of the second outer plate 23. A telescopic elongated hole 29 extending in the column axial direction X is formed in each of the first inner plate 26 and the second inner plate 27.
The lock mechanism 19 includes an insertion shaft 40, an operation member 41, a fixed cam member 42, a first pressing member 43, a second pressing member 44, a nut 45, and an elastic member 46.

  The insertion shaft 40 is a bolt and has a shaft portion 40a, a head portion 40b, and a male screw portion 40c. A direction in which the central axis A2 of the shaft portion 40a extends is referred to as an insertion axis direction J. The insertion axis direction J is orthogonal to the column axis direction X and the tilt direction T. The head portion 40b is provided at one end of the shaft portion 40a in the insertion axial direction J. The male screw portion 40c is provided at the other end of the shaft portion 40a in the insertion axis direction J.

The shaft portion 40a of the insertion shaft 40 includes a tilt long hole 25 of the first outer plate 22, a tilt long hole 25 of the second outer plate 23, a telescopic long hole 29 of the first inner plate 26, and a second. The telescopic elongated hole 29 of the inner plate 27 is inserted. The long hole for tilt 25 is an example of an insertion hole through which the insertion shaft 40 is inserted.
The head 40 b of the insertion shaft 40 is located on the opposite side of the first inner plate 26 with the first outer plate 22 in between. The male screw portion 40 c of the insertion shaft 40 is located on the opposite side of the second inner plate 27 with the second outer plate 23 interposed therebetween. A nut 45 is screwed into the male screw portion 40 c of the insertion shaft 40.

The operating member 41, the fixed cam member 42, and the first pressing member 43 are supported by the peripheral portion of the head portion 40b in the shaft portion 40a of the insertion shaft 40.
The operation member 41 is a lever that can be rotated. The operation member 41 is supported by the insertion shaft 40 so as to rotate integrally with the insertion shaft 40.
The fixed cam member 42 is press-fitted into the shaft portion 40a at a position adjacent to the head portion 40b between the head portion 40b of the insertion shaft 40 and the first outer plate 22. Therefore, the movement of the fixed cam member 42 in the insertion axis direction J with respect to the insertion shaft 40 is restricted, and the fixed cam member 42 can rotate integrally with the insertion shaft 40. The fixed cam member 42 is connected to the operation member 41 so as to be integrally rotatable. Therefore, when the operation member 41 is rotated, the fixed cam member 42 and the insertion shaft 40 rotate integrally. The central axis A2 of the shaft portion 40a of the insertion shaft 40 corresponds to the rotation center of the operation member 41.

  The first pressing member 43 is externally fitted to the shaft portion 40 a at a position adjacent to the fixed cam member 42. The first pressing member 43 has a first annular portion 50 and a first tubular portion 51. The first tubular portion 51 is inserted into the long slot for tilt 25 of the first outer plate 22 and the long hole for telescopic 29 of the first inner plate 26. The first cylindrical portion 51 is configured so that the rotation with respect to the upper fixing bracket 17 and the upper movable bracket 18 is restricted, and the telescopic length of the first inner plate 26 and the peripheral portion of the tilting long hole 25. The hole 29 is engaged with at least one of the peripheral portions. The first annular portion 50 protrudes from the first tubular portion 51 in the radial direction. The first annular portion 50 faces the outer surface 22 b of the first outer plate 22.

The second pressing member 44 and the elastic member 46 are supported by the peripheral portion of the male screw portion 40c (nut 45) in the shaft portion 40a of the insertion shaft 40.
The second pressing member 44 is externally fitted to the shaft portion 40 a so as to be rotatable relative to the insertion shaft 40. The second pressing member 44 has a second annular portion 52 and a second tubular portion 53. The second cylindrical portion 53 is inserted through the long slot for tilt 25 of the second outer plate 23. The second cylindrical portion 53 is engaged with the peripheral edge portion of the long slot for tilt 25 of the second outer plate 23 so that the rotation of the second pressing member 44 with respect to the upper fixing bracket 17 is restricted. The second cylindrical portion 53 is not inserted through the telescopic slot 29 of the second inner plate 27, and faces the portion around the telescopic slot 29 of the second inner plate 27 from the insertion axis direction J. ing.

  The second annular portion 52 protrudes from the second tubular portion 53 in the radial direction. The second annular portion 52 has a facing surface 52a that faces the outer surface 23b. The second annular portion 52 is an example of a facing portion that faces the outer surface 23 b of the second outer plate 23. An elastic member 46 is interposed between the facing surface 52 a of the second annular portion 52 and the outer surface 23 b of the second outer plate 23. The elastic member 46 is a metal spring such as a disc spring, for example. Unlike the present embodiment, the elastic member 46 may be a coil spring. The elastic member 46 is elastically deformable between the opposing surface 52 a of the second annular portion 52 and the outer surface 23 b of the second outer plate 23. A needle roller bearing 47 and a thrust washer 48 are interposed between the second pressing member 44 and the nut 45.

  The lock mechanism 19 further includes a drive mechanism 60 that moves the second pressing member 44 so that the first pressing member 43 and the second pressing member 44 approach each other with respect to the insertion axial direction J. The drive mechanism 60 is a cam mechanism including, for example, a first cam 61 and a second cam 62 that engages with the first cam 61. The first cam 61 is formed in a portion of the fixed cam member 42 that faces the first pressing member 43. The second cam 62 is formed in the first annular portion 50 of the first pressing member 43. Depending on the rotation operation of the operation member 41, the first cam 61 can be ridden on the second cam 62, or the ridden movement of the first cam 61 on the second cam 62 can be released.

  In the unlocked state of the steering device 1 shown in FIG. 2, the riding of the first cam 61 with respect to the second cam 62 is released. At the time of tilt adjustment, the insertion shaft 40 moves together with the upper movable bracket 18. At this time, the insertion shaft 40 moves in the tilt direction T within the long slot 25 for tilt. Each member (the operation member 41, the fixed cam member 42, the first pressing member 43, the second pressing member 44, the nut 45, and the elastic member 46) supported directly or indirectly by the insertion shaft 40 is also tilted in the tilt direction T together with the insertion shaft 40. Move to.

The insertion shaft 40 is restricted from moving in the column axis direction X with respect to the upper fixing bracket 17. Therefore, the upper jacket 7 moves in the column axis direction X with respect to the insertion shaft 40 during telescopic adjustment. At that time, the insertion shaft 40 relatively moves in the column axis direction X within the telescopic slot 29.
When the operation member 41 is rotated after the telescopic adjustment and the tilt adjustment, and the first cam 61 rides on the second cam 62 as shown in FIG. 3, the fixed cam member 42 and the insertion shaft 40 are moved to the first one. It moves in the insertion axis direction J with respect to the pressing member 43. As a result, the distance between the head 40 b of the insertion shaft 40 and the first pressing member 43 is increased, and the second pressing member 44 is pulled toward the first pressing member 43 together with the nut 45. Therefore, the first pressing member 43 and the second pressing member 44 approach each other in the insertion axis direction J. Thus, the operation load required for the rotation operation of the operation member 41 is converted into an axial force for bringing the first pressing member 43 and the second pressing member 44 close to each other in the insertion axis direction J.

  When the first pressing member 43 and the second pressing member 44 are brought close to each other, the first pressing member 43 presses the first outer plate 22 toward the first inner plate 26. As a result, the first outer plate 22 is pressed against the first inner plate 26. On the other hand, the second pressing member 44 directly presses the second inner plate 27 through the long slot for tilt 25 without passing through the second outer plate 23. The second inner plate 27 is connected to the first inner plate 26 via the connecting plate 28 and the upper jacket 7. Therefore, when the second pressing member 44 presses the second inner plate 27, the first inner plate 26 is pressed against the first outer plate 22.

  When the first inner plate 26 and the first outer plate 22 are pressed against each other, friction is generated between the first inner plate 26 and the first outer plate 22. The movement of the upper movable bracket 18 with respect to the upper fixed bracket 17 in the tilt direction T and the column axis direction X is restricted by the friction generated between the first inner plate 26 and the first outer plate 22. That is, the movement of the column jacket 4 with respect to the upper fixing bracket 17 is restricted. As a result, tilt lock and telescopic lock are achieved.

As described above, the position of the column jacket 4 with respect to the upper fixing bracket 17 is locked.
In the first embodiment, the position of the column jacket 4 with respect to the upper fixing bracket 17 can be locked without holding the upper movable bracket 18 between the first outer plate 22 and the second outer plate 23 of the upper fixing bracket 17. Therefore, the difference in the operation load of the operation member 41 due to the position of the column jacket 4 after the tilt adjustment can be reduced.

The elastic member 46 is elastically deformed between the second annular portion 52 of the second pressing member 44 and the second outer plate 23 when the second pressing member 44 presses the second inner plate 27. . Therefore, the gap between the second outer plate 23 and the second annular portion 52 of the second pressing member 44 is filled by the elastic member 46 while maintaining the pressing of the second inner plate 27 by the second pressing member 44 with certainty. be able to.
Therefore, it is possible to improve the support rigidity while achieving a reduction in the difference in operation load of the operation member 41 depending on the position of the column jacket 4 after tilt adjustment.

  In order to reduce the difference in operation load of the operation member 41 caused by the position of the column jacket 4 after tilt adjustment, the repulsive force received from the elastic member 46 when the operation member 41 is rotated is adjusted. It is preferable to be constant regardless of the position of 4. For this purpose, regardless of the position of the column jacket 4 in the tilt direction T, the distance between the outer surface 22b of the first outer plate 22 and the outer surface 23b of the second outer plate 23 in the locked state (first distance D1). It is preferable that the difference between the outer surface 22b of the first outer plate 22 in the locked state and the distance (second distance D2) between the opposing surface 52a of the second annular portion 52 is constant.

In the first embodiment, the elastic member 46 is a disc spring. Therefore, the elastic member 46 has a smaller amount of change in the repulsive force when the amount of elastic deformation changes compared to the case where the elastic member 46 is a coil spring. That is, the stable region of the repulsive force of the elastic member 46 is wide. Therefore, compared with the case where the elastic member 46 is a coil spring, a change in the difference between the first distance D1 and the second distance D2 due to the position of the column jacket 4 in the tilt direction T can be allowed.
In the first embodiment, the first pressing member 43 and the second pressing member 44 can be brought close to each other by the drive mechanism 60 having a simple configuration in which the first cam 61 and the second cam 62 are engaged.

Second Embodiment
Next, a steering device 1P according to the second embodiment will be described. 4 and 5 are cross-sectional views around the lock mechanism 19P of the steering device 1P. FIG. 4 is a diagram illustrating the unlocked state of the steering device 1P, and FIG. 5 is a diagram illustrating the locked state of the steering device 1P.

  The steering device 1P is mainly different from the steering device 1 of the first embodiment in that the drive mechanism 60P of the lock mechanism 19P is configured by the male screw portion 40c of the insertion shaft 40 and the nut 45. Hereinafter, the lock mechanism 19P of the steering device 1P will be described in detail. However, in FIG. 4 and FIG. 5, the same reference numerals are given to the same members as those described so far, and the description thereof is omitted.

The lock mechanism 19P includes an insertion shaft 40, an operation member 41, a first pressing member 43P, a second pressing member 44, a nut 45, and an elastic member 46.
The head 40 b of the insertion shaft 40 is located on the opposite side of the second inner plate 27 with the second outer plate 23 interposed therebetween. The male screw portion 40 c of the insertion shaft 40 is located on the opposite side of the first inner plate 26 with the first outer plate 22 in between.

The operating member 41 and the first pressing member 43P are supported by the peripheral portion of the male screw portion 40c (nut 45) in the shaft portion 40a of the insertion shaft 40. The second pressing member 44 and the elastic member 46 are supported by the peripheral portion of the head portion 40 b in the shaft portion 40 a of the insertion shaft 40.
The operation member 41 is externally fitted to the shaft portion 40 a at a position adjacent to the nut 45. The operation member 41 is connected to the nut 45 so as to be rotatable together with the nut 45. The first pressing member 43P is externally fitted to the shaft portion 40a at a position adjacent to the operation member 41. The first pressing member 43P is a spacer interposed between the operation member 41 and the first outer plate 22. No cam is formed on the first annular portion 50 of the first pressing member 43P.

  The insertion shaft 40 is restricted from rotating with respect to the upper fixed bracket 17 and the upper movable bracket 18. For example, the inner peripheral surface of the telescopic elongated hole 29 of the second inner plate 27, the inner peripheral surface of the first cylindrical portion 51 of the first pressing member 43 </ b> P, and the second cylindrical portion 53 of the second pressing member 44. By engaging the insertion shaft 40 with at least one of the peripheral surfaces, the rotation of the insertion shaft 40 with respect to the upper fixing bracket 17 and the upper movable bracket 18 is restricted. Alternatively, the rotation of the insertion shaft 40 with respect to the upper fixing bracket 17 and the upper movable bracket 18 may be restricted by fixing the head 40 b of the insertion shaft 40 to the second annular portion 52 of the second pressing member 44. .

Since the rotation of the insertion shaft 40 is restricted, the insertion shaft 40 moves in the insertion axis direction J when the nut 45 is rotated according to the rotation operation of the operation member 41. Thereby, the head 40b of the insertion shaft 40 can be brought close to the nut 45, and the head 40b of the insertion shaft 40 can be separated from the nut 45.
After performing telescopic adjustment and tilt adjustment, when the operating member 41 is rotated in the locking direction to move the insertion shaft 40 in the insertion axis direction J, as shown in FIG. 5, the head 40b and the nut of the insertion shaft 40 45 approach each other. Thereby, the 2nd press member 44 is drawn near to the 1st press member 43P side with the head 40b of the insertion shaft 40. As shown in FIG. Therefore, the first pressing member 43P and the second pressing member 44 approach each other in the insertion axial direction J.

  When the first pressing member 43P and the second pressing member 44 are brought close to each other, the first pressing member 43P presses the first outer plate 22 toward the first inner plate 26. As a result, the first outer plate 22 is pressed against the first inner plate 26. On the other hand, the second pressing member 44 directly presses the second inner plate 27 through the long slot for tilt 25 without passing through the second outer plate 23. The second inner plate 27 is connected to the first inner plate 26 via the connecting plate 28 and the upper jacket 7. Therefore, when the second pressing member 44 presses the second inner plate 27, the first inner plate 26 is pressed against the first outer plate 22.

  When the first inner plate 26 and the first outer plate 22 are pressed against each other, friction is generated between the first inner plate 26 and the first outer plate 22. The movement of the upper movable bracket 18 with respect to the upper fixed bracket 17 in the tilt direction T and the column axis direction X is restricted by the friction generated between the first inner plate 26 and the first outer plate 22. That is, the movement of the column jacket 4 with respect to the upper fixing bracket 17 is restricted. As a result, tilt lock and telescopic lock are achieved.

As described above, the position of the column jacket 4 with respect to the upper fixing bracket 17 is locked.
Even in the configuration of the second embodiment, the position of the column jacket 4 with respect to the upper fixing bracket 17 can be locked without holding the upper movable bracket 18 between the first outer plate 22 and the second outer plate 23 of the upper fixing bracket 17. Can do. Therefore, the difference in the operation load of the operation member 41 due to the position of the column jacket 4 after the tilt adjustment can be reduced.

The drive mechanism 60 </ b> P is configured by the male screw portion 40 c of the insertion shaft 40 and the nut 45. Therefore, the first pressing member 43P and the second pressing member 44 can be brought closer to each other using a simple configuration of engagement between the bolt (insertion shaft 40) and the nut 45.
In the second embodiment, the head 40b of the insertion shaft 40 is located on the opposite side of the second inner plate 27 with the second outer plate 23 interposed therebetween, and the male screw portion 40c of the insertion shaft 40 is the first outer plate. It is assumed that it is located on the opposite side of the first inner plate 26 across 22. However, the direction of the insertion shaft 40 may be reversed as in the modification shown in FIG. That is, the head 40 b of the insertion shaft 40 is located on the opposite side of the first inner plate 26 with the first outer plate 22 interposed therebetween, and the male screw portion 40 c of the insertion shaft 40 has the second inner plate 23 with the second outer plate 23 interposed therebetween. 27 may be located on the opposite side.

  In this modification, the head 40 b of the insertion shaft 40 is fixed to the operation member 41, and the insertion shaft 40 can rotate with respect to the upper fixing bracket 17 and the upper movable bracket 18. On the other hand, the nut 45 is fixed to the second pressing member 44 so that the rotation with respect to the upper fixing bracket 17 and the upper movable bracket 18 is restricted. Therefore, when the insertion shaft 40 is rotated according to the rotation operation of the operation member 41, the nut 45 moves in the insertion shaft direction J. Thereby, the nut 45 can be brought close to the head 40b of the insertion shaft 40, or the nut 45 can be separated from the head 40b of the insertion shaft 40.

  After the telescopic adjustment or the tilt adjustment, if the nut 45 is moved in the insertion axis direction J by rotating the operation member 41 in the locking direction, the head 40b of the insertion axis 40 and the nut 45 come closer to each other. Thereby, the 2nd press member 44 with the nut 45 is drawn near to the 1st press member 43P side. Therefore, the first pressing member 43P and the second pressing member 44 approach each other in the insertion axial direction J.

<Third Embodiment>
Next, a steering device 1Q according to the third embodiment will be described. FIG. 7 is a perspective view of the steering device 1Q. 8 and 9 are sectional views of the periphery of the lock mechanism 19 of the steering device 1Q. FIG. 8 is a diagram illustrating the unlocked state of the steering device 1Q, and FIG. 9 is a diagram illustrating the locked state of the steering device 1Q.

As shown in FIG. 7, the steering device 1 </ b> Q is mainly different from the steering device 1 of the first embodiment in that the column jacket 4 has a first support portion 30 and a second support portion instead of the upper movable bracket 18. 31 is provided. 7 to 9, the same members as those described so far are denoted by the same reference numerals, and the description thereof is omitted.
Referring to FIG. 8, the column jacket 4 according to the third embodiment includes a first support portion 30 and a second support portion 31 in addition to the upper jacket 7 and the lower jacket 8. The lower jacket 8 according to the first embodiment is internally fitted to the upper jacket 7 (see FIG. 2), whereas the lower jacket 8 according to the third embodiment is external to the upper jacket 7. It is fitted.

  The first support part 30 and the second support part 31 are provided integrally with the lower jacket 8 and support the insertion shaft 40. The first support part 30 and the second support part 31 face each other in the insertion axis direction J. Both the first support portion 30 and the second support portion 31 are substantially rectangular parallelepipeds that are long in the column axial direction X. The first support part 30 and the second support part 31 are disposed between the first outer plate 22 and the second outer plate 23.

Between the first support part 30 and the second support part 31, a slit 32 extending from the upper end in the axial direction of the lower jacket 8 toward the lower side in the column axial direction X is provided. By narrowing the slit 32, the lower jacket 8 can be elastically reduced in diameter.
The head 40 b of the insertion shaft 40 is located on the opposite side of the first support part 30 with the first outer plate 22 interposed therebetween. The male screw portion 40 c of the insertion shaft 40 is located on the opposite side of the second support portion 31 with the second outer plate 23 interposed therebetween. The operating member 41, the fixed cam member 42, and the first pressing member 43 are supported by the peripheral portion of the head portion 40b in the shaft portion 40a of the insertion shaft 40. The second pressing member 44, the elastic member 46, the needle roller bearing 47, and the thrust washer 48 are supported by the peripheral portion of the male screw portion 40c (nut 45) in the shaft portion 40a of the insertion shaft 40.

A circular hole 33 through which the insertion shaft 40 is inserted is formed in each of the first support part 30 and the second support part 31. Since the insertion shaft 40 is inserted into the circular hole 33, the insertion shaft 40 is moved integrally with the lower jacket 8 at the time of tilt adjustment and telescopic adjustment.
The first support portion 30 is formed with a fitting hole 34 into which the first cylindrical portion 51 of the first pressing member 43 is fitted. The fitting hole 34 is a bottomed hole in which the outer surface 30 a of the first support part 30 is recessed. The circular hole 33 of the first support portion 30 passes through the bottom surface of the fitting hole 34 and the inner side surface of the first support portion 30. The first tubular portion 51 is inserted through the long slot for tilt 25 of the first outer plate 22 and the fitting hole 34 of the first support portion 30. Since the first cylindrical portion 51 is fitted in the fitting hole 34, the rotation of the first pressing member 43 relative to the upper fixing bracket 17 and the first support portion 30 is restricted.

  The second cylindrical portion 53 of the second pressing member 44 is inserted through the long slot for tilt 25 of the second outer plate 23. The second cylindrical portion 53 is engaged with the peripheral edge portion of the long slot for tilt 25 of the second outer plate 23 so that the rotation of the second pressing member 44 with respect to the upper fixing bracket 17 is restricted. The second cylindrical portion 53 is not inserted through the circular hole 33 of the second support portion 31, and faces the portion around the circular hole 33 in the second support portion 31 from the insertion axial direction J.

  In the unlocked state of the steering device 1 </ b> Q shown in FIG. 8, the riding of the first cam 61 with respect to the second cam 62 is released. At the time of tilt adjustment, the insertion shaft 40 moves together with the lower jacket 8. At this time, the insertion shaft 40 moves in the tilt direction T within the tilt slot 25. At the time of tilt adjustment, each member (the operation member 41, the fixed cam member 42, the first pressing member 43, the second pressing member 44, the nut 45, and the elastic member 46) supported directly or indirectly on the insertion shaft 40 is also inserted into the insertion shaft 40. At the same time, it moves in the tilt direction T.

  After the telescopic adjustment and the tilt adjustment, when the operation member 41 is rotated in the locking direction and the first cam 61 rides on the second cam 62 as shown in FIG. 9, the fixed cam member 42 and the insertion shaft 40 moves in the insertion axis direction J with respect to the first pressing member 43. As a result, the distance between the head 40 b of the insertion shaft 40 and the first pressing member 43 is increased, and the second pressing member 44 is pulled toward the first pressing member 43 together with the nut 45. Therefore, the first pressing member 43 and the second pressing member 44 approach each other in the insertion axis direction J. Thus, the operation load required for the rotation operation of the operation member 41 is converted into an axial force for bringing the first pressing member 43 and the second pressing member 44 close to each other in the insertion axis direction J.

  When the first pressing member 43 and the second pressing member 44 are brought close to each other, the first pressing member 43 presses the first outer plate 22 toward the first support portion 30. Thereby, the first outer plate 22 is pressed against the first support portion 30. On the other hand, the second pressing member 44 directly presses the second support part 31 through the long slot for tilt 25 without using the second outer plate 23. Since the 2nd support part 31 and the 1st support part 30 are connected via the lower jacket 8, when the 2nd press member 44 presses the 2nd support part 31, the 1st support part 30 is the 1st. Pressed against the outer plate 22. As a result, the lower jacket 8 of the column jacket 4 is pressed against the first outer plate 22.

The lower jacket with respect to the upper fixing bracket 17 in the tilt direction T due to friction generated between the first support portion 30 and the first outer plate 22 by the first support portion 30 and the first outer plate 22 being pressed against each other. 8 movement is restricted. That is, tilt lock is achieved.
The first pressing member 43 presses the first outer plate 22 toward the first support portion 30, and the second pressing member 44 presses the second support portion 31, whereby the first support portion 30 and the second support portion are pressed. The width of the slit 32 between 31 is reduced. Thereby, the lower jacket 8 is elastically reduced in diameter, and the upper jacket 7 is tightened and held. Thereby, the movement of the upper jacket 7 with respect to the lower jacket 8 is regulated. That is, telescopic lock is achieved.

As described above, the position of the column jacket 4 with respect to the upper fixing bracket 17 is locked.
According to 3rd Embodiment, there exists an effect similar to 1st Embodiment. Specifically, also in the third embodiment, the position of the column jacket 4 with respect to the upper fixing bracket 17 is locked without holding the column jacket 4 between the first outer plate 22 and the second outer plate 23 of the upper fixing bracket 17. Can do. Therefore, the difference in the operation load of the operation member 41 due to the position of the column jacket 4 after the tilt adjustment can be reduced.

  In the third embodiment, as described above, the first pressing member 43 presses the first outer plate 22 toward the first support portion 30, and the second pressing member 44 presses the second support portion 31. The lower jacket 8 is elastically reduced in diameter. Accordingly, the first pressing member 43 and the second pressing member 44 are necessary for appropriately reducing the diameter of the lower jacket 8 depending on which position of the first support portion 30 and the second support portion 31 is pressed in the tilt direction T. The axial force changes.

  However, in the third embodiment, since the insertion shaft 40 is inserted into the circular hole 33, the position pressed by the first pressing member 43 and the second pressing member 44 in the first support portion 30 and the second support portion 31. Does not change even if the tilt position is changed. Therefore, the axial force required to appropriately reduce the diameter of the lower jacket 8 tends to be constant regardless of the position of the column jacket 4 after the tilt adjustment. Therefore, also in the steering device 1Q having the configuration in which the first support portion 30 and the second support portion 31 are provided instead of the upper movable bracket 18, similarly to the steering device 1 according to the first embodiment, after the tilt adjustment. The difference in the operation load of the operation member 41 due to the position of the column jacket 4 can be reduced.

The elastic member 46 is elastically deformed between the second annular portion 52 of the second pressing member 44 and the second outer plate 23 when the second pressing member 44 presses the second support portion 31. . Therefore, the gap between the second outer plate 23 and the second annular portion 52 of the second pressing member 44 is filled by the elastic member 46 while maintaining the pressing of the second supporting portion 31 by the second pressing member 44 with certainty. be able to.
Therefore, it is possible to improve the support rigidity while achieving a reduction in the difference in operation load of the operation member 41 depending on the position of the column jacket 4 after tilt adjustment.

  In order to reduce the difference in operation load of the operation member 41 caused by the position of the column jacket 4 after tilt adjustment, the repulsive force received from the elastic member 46 when the operation member 41 is rotated is adjusted. It is preferable to be constant regardless of the position of 4. For this purpose, regardless of the position of the column jacket 4 in the tilt direction T, the distance between the outer surface 22b of the first outer plate 22 and the outer surface 23b of the second outer plate 23 in the locked state (first distance D1). It is preferable that the difference between the outer surface 22b of the first outer plate 22 in the locked state and the distance (second distance D2) between the opposing surface 52a of the second annular portion 52 is constant.

In the third embodiment, the elastic member 46 is a disc spring. Therefore, the elastic member 46 has a smaller amount of change in the repulsive force when the amount of elastic deformation changes compared to the case where the elastic member 46 is a coil spring. That is, the stable region of the repulsive force of the elastic member 46 is wide. Therefore, compared with the case where the elastic member 46 is a coil spring, a change in the difference between the first distance D1 and the second distance D2 due to the position of the column jacket 4 in the tilt direction T can be allowed.
In the third embodiment, the first pressing member 43 and the second pressing member 44 can be brought close to each other by the drive mechanism 60 having a simple configuration in which the first cam 61 and the second cam 62 are engaged.

<Fourth embodiment>
Next, a steering device 1R according to the fourth embodiment will be described. The main difference between the steering device 1R and the steering device 1Q of the third embodiment is that the locking mechanism 19P according to the second embodiment is used as the locking mechanism. That is, as the drive mechanism according to the fourth embodiment, a drive mechanism 60P configured by the male screw portion 40c of the insertion shaft 40 and the nut 45 is used.

10 and 11 are cross-sectional views of the periphery of the lock mechanism 19P of the steering device 1R. FIG. 10 is a diagram illustrating the unlocked state of the steering device 1R, and FIG. 11 is a diagram illustrating the locked state of the steering device 1R. 10 and 11, the same members as those described so far are denoted by the same reference numerals, and the description thereof is omitted.
The head 40 b of the insertion shaft 40 is located on the opposite side of the second support portion 31 with respect to the second outer plate 23. The male screw portion 40 c of the insertion shaft 40 is located on the opposite side of the first support portion 30 with respect to the first outer plate 22.

  The insertion shaft 40 includes an inner peripheral surface of the circular hole 33 of the first support portion 30, an inner peripheral surface of the circular hole 33 of the second support portion 31, an inner peripheral surface of the first cylindrical portion 51 of the first pressing member 43, And, it is engaged with at least one of the inner peripheral surfaces of the second cylindrical portion 53 of the second pressing member 44. Therefore, the insertion shaft 40 is restricted from rotating with respect to the upper fixing bracket 17 and the column jacket 4. Alternatively, the head 40 b of the insertion shaft 40 is fixed to the second annular portion 52 of the second pressing member 44, whereby the insertion shaft 40 with respect to the upper fixing bracket 17, the first support portion 30, and the second support portion 31. The rotation may be restricted.

Since the rotation of the insertion shaft 40 is restricted, the insertion shaft 40 moves in the insertion axis direction J when the nut 45 is rotated according to the rotation operation of the operation member 41. Thereby, the head 40b of the insertion shaft 40 can be brought close to the nut 45, and the head 40b of the insertion shaft 40 can be separated from the nut 45.
After performing telescopic adjustment and tilt adjustment, when the operating member 41 is rotated in the locking direction to move the insertion shaft 40 in the insertion shaft direction J, as shown in FIG. 11, the head 40b and the nut of the insertion shaft 40 45 approach each other. Thereby, the 2nd press member 44 is drawn near to the 1st press member 43P side with the head 40b of the insertion shaft 40. As shown in FIG. Therefore, the first pressing member 43P and the second pressing member 44 approach each other in the insertion axial direction J.

  When the first pressing member 43P and the second pressing member 44 are brought close to each other, the first pressing member 43P presses the first outer plate 22 toward the first support portion 30. Thereby, the first outer plate 22 is pressed against the first support portion 30. On the other hand, the second pressing member 44 directly presses the second support part 31 through the long slot for tilt 25 without using the second outer plate 23. When the second pressing member 44 presses the second support portion 31, the first support portion 30 is pressed against the first outer plate 22. As a result, the lower jacket 8 of the column jacket 4 is pressed against the first outer plate 22.

When the first support portion 30 and the first outer plate 22 are pressed against each other, friction is generated between the first support portion 30 and the first outer plate 22. In the tilt direction T, the movement of the lower jacket 8 relative to the upper fixing bracket 17 is restricted by the friction generated between the first support portion 30 and the first outer plate 22. That is, tilt lock is achieved.
The first pressing member 43P presses the first outer plate 22 toward the first support part 30, and the second pressing member 44 presses the second support part 31, whereby the first support part 30 and the second support part. The width of the slit 32 between 31 is reduced. Thereby, the lower jacket 8 is elastically reduced in diameter, and the upper jacket 7 is tightened and held. Thereby, the movement of the upper jacket 7 with respect to the lower jacket 8 is regulated. That is, telescopic lock is achieved.

As described above, the position of the column jacket 4 with respect to the upper fixing bracket 17 is locked.
According to 4th Embodiment, there exists an effect similar to 2nd Embodiment. Specifically, even in the configuration of the fourth embodiment, the position of the column jacket 4 with respect to the upper fixing bracket 17 is locked without the column jacket 4 being held between the first outer plate 22 and the second outer plate 23 of the upper fixing bracket 17. can do. Therefore, the difference in the operation load of the operation member 41 due to the position of the column jacket 4 after the tilt adjustment can be reduced.

  In addition, since the insertion shaft 40 is inserted through the circular hole 33, the position pressed by the first pressing member 43P and the second pressing member 44 in the first support part 30 and the second support part 31 changes the tilt position. Even if it does not change. Therefore, the axial force necessary for appropriately reducing the diameter of the lower jacket 8 is easily constant regardless of the position of the column jacket 4 after the tilt adjustment. Therefore, also in the steering device 1R having the first support portion 30 and the second support portion 31 provided in place of the upper movable bracket 18, similarly to the steering device 1P according to the second embodiment, after the tilt adjustment. The difference in the operation load of the operation member 41 due to the position of the column jacket 4 can be reduced.

The drive mechanism 60 </ b> P is configured by at least one of the head 40 b of the insertion shaft 40 and the nut 45. Therefore, the first pressing member 43P and the second pressing member 44 can be brought closer to each other using a simple configuration of engagement between the bolt (insertion shaft 40) and the nut 45.
In the fourth embodiment, the head 40b of the insertion shaft 40 is located on the opposite side of the second support 31 with the second outer plate 23 interposed therebetween, and the male screw portion 40c of the insertion shaft 40 is the first outer plate. It is located on the opposite side of the first support part 30 across the 22. However, the direction of the insertion shaft 40 may be reversed as in the modification shown in FIG. That is, the head 40b of the insertion shaft 40 is located on the opposite side of the first support 30 with the first outer plate 22 interposed therebetween, and the male screw portion 40c of the insertion shaft 40 has the second support plate sandwiched with the second outer plate 23. It may be located on the opposite side of 31.

  In this modification, the insertion shaft 40 is rotatable with respect to the upper fixing bracket 17 and the first support portion 30 and the second support portion 31. On the other hand, the nut 45 is fixed to the second pressing member 44, so that the rotation with respect to the upper fixing bracket 17, the first support portion 30, and the second support portion 31 is restricted. Therefore, when the insertion shaft 40 is rotated according to the rotation operation of the operation member 41, the nut 45 moves in the insertion shaft direction J. Thereby, the nut 45 can be brought close to the head 40b of the insertion shaft 40, or the nut 45 can be separated from the head 40b of the insertion shaft 40.

After the telescopic adjustment or the tilt adjustment, when the operation member 41 is rotated to move the nut 45 in the insertion axis direction J, the head 40b of the insertion axis 40 and the nut 45 approach each other. Thereby, the 2nd press member 44 with the nut 45 is drawn near to the 1st press member 43P side. Therefore, the first pressing member 43P and the second pressing member 44 approach each other in the insertion axial direction J.
The present invention is not limited to the embodiment described above, and various modifications can be made within the scope of the claims.

  Moreover, in the above-described embodiment, it has been described that the first pressing members 43 and 43P and the second pressing member 44 approach each other when the second pressing member 44 is pulled toward the first pressing members 43 and 43P. However, the drive mechanisms 60, 60P are configured so that the first pressing members 43, 43P and the first pressing members 43, 43P and the second pressing members 44 approach each other in the insertion axis direction J as the operation member 41 rotates. Both of the two pressing members 44 may be moved.

  As a configuration for realizing this, for example, in the first embodiment, a configuration in which a drive mechanism is provided between the nut 45 and the second outer plate 23 in addition to the drive mechanism 60 can be assumed. Specifically, a cam member in which the first cam is formed is interposed between the nut 45 and the second pressing member 44, and the second cam that engages with the first cam is the second pressing member 44. The second annular portion 52 is formed. In this case, when the operation member 41 is rotated, both the first pressing member 43 and the second pressing member 44 move in the insertion axis direction J so that the first pressing member 43 and the second pressing member 44 approach each other.

Unlike the above-described embodiment, the driving mechanisms 60 and 60P are configured such that the first pressing members 43 and 43P and the second pressing member 44 are obtained by the first pressing members 43 and 43P being drawn toward the second pressing member 44. May be configured to approach each other.
In addition, various changes can be made within the scope described in the claims.

  1; 1P; 1Q: 1R ... steering device, 2 ... steering member, 3 ... steering shaft, 4 ... column jacket, 13 ... vehicle body, 19; 19P ... lock mechanism, 22 ... first outer plate (first side plate), 23 2nd outer side plate (second side plate), 23b ... outer surface, 25 ... long hole for tilting (insertion hole), 40 ... insertion shaft (bolt), 40a ... shaft part, 40b ... head, 40c ... male screw part, DESCRIPTION OF SYMBOLS 41 ... Operation member, 43; 43P ... 1st press member, 44 ... 2nd press member, 45 ... Nut, 46 ... Elastic member, 52 ... 2nd annular part (opposing part), 60; 60P ... Drive mechanism, 61 ... First cam 62 ... Second cam J ... Insertion shaft direction

Claims (4)

A steering device capable of tilt adjustment,
A steering shaft to which a steering member is coupled at one end;
A fixing bracket having a first side plate and a second side plate in which an insertion hole is formed, and fixed to the vehicle body;
A column jacket that rotatably supports the steering shaft, is disposed between the first side plate and the second side plate, and moves relative to the fixed bracket during tilt adjustment;
A lock mechanism that locks the position of the column jacket relative to the fixed bracket after tilt adjustment,
The locking mechanism is
An insertion shaft inserted through the insertion hole of the first side plate and the insertion hole of the second side plate;
An operation member supported by the insertion shaft and rotatable.
A first pressing member that presses the first side plate against the column jacket by pressing the first side plate;
A second pressing member that presses the column jacket against the first side plate by pressing the column jacket through the insertion hole of the second side plate;
As the operation member rotates, at least one of the first pressing member and the second pressing member is moved so that the first pressing member and the second pressing member come closer to each other in the axial direction of the insertion shaft. A steering mechanism including a driving mechanism. The second pressing member has a facing portion facing the outer surface of the second side plate;
The locking mechanism further includes an elastic member that elastically deforms between the facing portion of the second pressing member and the outer side surface of the second side plate when the second pressing member presses the column jacket. The steering apparatus according to claim 1.   The drive mechanism includes a first cam that rotates integrally with the operation member, and a second cam that is provided on at least one of the first pressing member and the second pressing member and engages with the first cam. The steering device according to claim 1 or 2. The drive mechanism includes a male screw portion provided at one end of a shaft portion of a bolt serving as the insertion shaft, and a nut that engages with the male screw portion. The steering according to any one of claims 1 to 3, wherein the first pressing member and the second pressing member are brought closer to each other in the axial direction by bringing the head provided at the end and the nut closer to each other. apparatus.

Images