JP4421912B2 - Steering device fixing device - Google Patents

Description

  The present invention relates to a steering device fixing device that can perform tilt adjustment without applying an excessive tightening load to the device by a cam operation and has a very simple cam structure.

  In a tilt / telescopic steering device in which the height and axial position of the steering wheel can be appropriately changed according to the physique and driving posture of the driver, the side plate of the fixed bracket attached to the vehicle body and the steering column have been conventionally used. A structure in which an operation lever is attached to a tilt bolt that penetrates the side plate of the movable bracket attached to the side of the movable bracket, and the both sides of the fixed bracket and the movable bracket are pressed against each other by rotation of the operation lever. There is a steering device provided with the tilt adjustment mechanism.

  In this type, as shown in Patent Document 1 below, two cam members are provided, one cam member is mounted on the fixed bracket side, and the other cam member is mounted on an operation lever for tilt adjustment. Things exist. This is because the cam surface of one cam member acts on the cam follower surface of the other cam member and the other cam member is pressed against the side of the fixed bracket by the rotation of the operation lever. The fixed bracket has a structure for fixing the movable bracket. The cam member attached to the operation lever is screwed into the screw portion of the tilt bolt, and the other cam member fixed to the fixed bracket side is rotated by one cam member in accordance with the rotation operation of the operation lever. Acting on the cam follower surface, the side portion of the fixed bracket is pressed against the side portion of the movable bracket.

Specifically, as shown in FIGS. 11A to 11C, this conventional cam configuration includes a main cam 50 having a cam follower surface 51 (a peak portion 51a, an inclined portion 51b, a valley portion 51c), A driven cam 60 having a protrusion 61 that moves up and down along the cam follower surface 51 is provided. The main driving cam 50 and the driven cam 60 are overlapped with each other, the main driving cam 50 is rotated with respect to the driven cam 60, and the protrusion 61 of the driven cam 60 is formed on the peak portion 51a of the cam follower surface 51 of the main driving cam 50. The riding state is set as a locked state, and the state in which the protrusion 61 moves from the peak portion 51a to the valley portion 51c of the cam follower surface 51 is set as a release state.
JP 2002-59851

  As shown in FIG. 11, a conventional cam mechanism such as the above-mentioned Patent Document 1 has a peak 51a of the cam follower surface 51 during a tilt / telescopic operation in which an operation lever is opened (released) and tightened (locked). The protrusion 61 is moved up and down along the inclined portion 51b and the valley portion 51c, and the cam follower surface 51 is worn due to factors such as the contact friction of the cam follower surface 51 and the frequency (largeness) of lever operation. And it will be worn out. Therefore, the durability as a tilt / telescopic steering device is impaired, and the wear of the cam follower surface 51 causes the surface to become rough and the feeling during operation to deteriorate (the lever load during operation increases). The problem occurs. In order to prevent cam surface wear, the number of cam surfaces and protrusions may be increased to reduce the axial force applied to one cam surface. However, there are limitations when considering the size of the cam. It is difficult to increase the cam surface with the size of the cam. The problem to be solved by the present invention is to solve the above problems.

  In view of the above, the inventor has intensively and intensively studied to solve the above-described problems. As a result, the inventor of the present invention has the following features: a fixed bracket having a fixed side portion; a movable bracket having a movable side portion; And a lock bolt that penetrates the movable side, a main drive cam that passes through the lock bolt, a follower cam that passes through the lock bolt and is mounted non-rotatably, and an operation lever that rotates the main drive cam. The main driving cam and the driven cam are formed in the order of a low-order surface, an inclined surface portion, a high-order surface and a cam projection portion having the same shape, and the high-order surface is located on one side in the width direction of the cam projection portion and the other side A plurality of cam actuating portions having a cam projection with a lower surface positioned in the circumferential direction are formed along the circumferential direction, and the main driving cam and the driven cam are axially moved by rotating the operation lever. Separated and close to In the main cam, only the top surface of the cam projection is in contact with the lower surface, the inclined surface, and the higher surface of the cam operating portion of the driven cam when the main cam is rotated. By making the fixing device of the steering device in which only the top surface portion comes into contact with the lower surface, the inclined surface, and the higher surface of the cam operating portion of the main cam, and the top surface portions of the two cam projections cannot be contacted, It solves the above problems.

  Next, the invention according to claim 2 is the steering device according to claim 1, wherein a guide surface is formed on the top surface portion of the cam projection portion near the high surface side so as to be inclined toward the high surface surface. By using a fixing device, the above-described problems have been solved.

  According to a third aspect of the present invention, the above problem is solved by using the steering device fixing device according to the second aspect, wherein the guide surface is an inclined surface that is inclined so as to be lowered toward the higher surface side. According to a fourth aspect of the present invention, in the third aspect of the present invention, the guide surface having the inclined surface is a steering device fixing device having the same gradient as the inclined surface portion, thereby solving the above-described problem.

  According to the first aspect of the present invention, the axial force applied to the mutual cam operating portions of the primary cam and the driven cam is shared by the respective contact surfaces, the axial force applied to one cam operating portion is reduced, and the cam surface is damaged. The durability of the tilt / telescopic steering device can be improved, and the operation can be ensured. Further, since the main driving cam and the driven cam are formed in the order of the low-order surface, the slope portion, the high-order surface and the cam projection portion having the same shape, the cam operation can be performed more reliably. According to the invention of claim 2 or 3, the operation of the cam projection can be made smooth, and according to the invention of claim 4, a sufficient contact area between the cam projection and the other side can be ensured. .

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. As shown in FIGS. 1 and 9, etc., the present invention mainly comprises a fixed bracket A, a movable bracket B, a lock bolt 10, an operation lever 25, a main driving cam C, a driven cam D, and the like. As shown in FIG. 9, the fixed bracket A is mainly formed by fixed side portions 1, 1, a connecting portion 2, and mounting portions 3, 3. Both the fixed side portions 1 and 1 are substantially flat portions facing in parallel. In both the fixed side portions 1 and 1, tilt adjusting long holes 1a and 1a are formed substantially along the vertical direction, which is a portion through which a lock bolt 10 described later passes.

  Both the fixed side portions 1 and 1 are connected to each other at the upper portion by a connecting portion 2 by welding means or the like. The connecting portion 2 is formed in a substantially trapezoidal gate shape, an arch shape or the like when viewed from the front. Further, horizontal mounting portions 3 and 3 are formed outward from the upper end portions of the fixed side portions 1 and 1. The fixing bracket A is fixed to a frame member or the like of a front portion of a traveling vehicle such as an automobile via the mounting portions 3 and 3.

  As shown in FIG. 9, the movable bracket B is mainly formed from the movable side parts 4, 4 and the bottom part 5. The two movable side parts 4 and 4 are arranged in parallel, and the two movable side parts 4 and 4 are arranged between the two fixed side parts 1 and 1 of the fixed bracket A. , 4 is set slightly smaller than the fixed side portions 1, 1. Both the movable side portions 4 and 4 are formed with tilt adjusting through holes 4a and 4a, and the fixed side portions 1 and 1 of the fixed bracket A and the movable side portions 4 and 4 of the movable bracket B are locked to be described later. The bolt 10 penetrates the structure.

  As shown in FIGS. 1 and 9, a steering column 6 is fixed to upper end portions of both movable side portions 4 and 4 of the movable bracket B. The steering column 6 and the movable side parts 4 and 4 are fixed by welding means or the like. A steering shaft 7 is rotatably mounted on the steering column 6, and a steering wheel 8 is mounted on the tip of the steering shaft 7.

  Next, as shown in FIGS. 2, 9 and the like, the lock bolt 10 includes a bolt shaft portion 10a, a bolt screw portion 10b, and a bolt head portion 10c, and a bolt screw portion at one end in the axial direction of the bolt shaft portion 10a. 10b is formed, and a bolt head portion 10c is formed at the other axial end. Further, in the bolt shaft portion 10a, a press-fitting region 10d is formed near the bolt head portion 10c, and is press-fitted and fixed in a mounting hole 11a of a main driving cam C, which will be described later, along with the rotation of the lock bolt 10 in the axial direction. The main drive cam C is also rotated together. The press-fitted region 10d is formed so as to have a shaft diameter slightly larger than the shaft diameter of the bolt shaft portion 10a, or a knurl is formed so as to have a substantially spline shape.

With respect to the screw forming direction of the bolt screw portion 10b, the operation lever 25 is mounted on the bolt screw portion 10b together with a main driving cam C described later, and the tilt lock state is brought about by rotating the operation lever 25 from below to above. Thus, it is preferable that the screw direction of the bolt screw portion 10b is determined. In the lock bolt 10, both movable side portions 4 and 4 of the movable bracket B are disposed between the fixed side portions 1 and 1 of the fixed bracket A, and the tilt adjusting elongated holes 1a of the both fixed side portions 1 and 1 are arranged. , 1a and the movable bracket B both through the tilt adjusting through holes 4a, 4a. In this way, the lock bolt 10 can be moved up and down in the tilt adjusting long holes 1a and 1a, and the movable bracket B can be moved up and down with respect to the fixed bracket A. As shown in FIG. 2, the operating lever 25 is formed by integrally forming a lever portion 25b on a rotation center portion 25a. A fixed hole 25a ₁ is formed in the rotation center portion 25a, and a main driving cam C, which will be described later, is attached to the fixed hole 25a ₁ .

Next, the main cam C and the driven cam D will be described. First, the main drive cam C and the follower cam D are formed in the same shape. However, since the mounting state and the operation state thereof are different, different reference numerals are given respectively. As shown in FIGS. 1 to 5 and the like, the main drive cam C is formed by forming a plurality of cam operation parts C ₁ , C ₁ ,... As shown in FIGS. 3, 4, etc., the cam operating portion C ₁ is formed by continuously forming a low-order surface 12, a slope portion 13, a high-order surface 14, and a cam projection 15. First, the cam base 11 is formed in a substantially disc shape. A mounting hole 11 a is formed at the center of the cam base portion 11. The mounting hole 11a is press-fitted into the press-fitting region 10d of the lock bolt 10, and as described above, the main cam C can be rotated together with the axial direction of the lock bolt 10. .

A plurality of cam operating portions C ₁ , C ₁ ,... Are formed in any one side surface of the cam base portion 11 and in an appropriate region on the outer periphery along the circumferential direction. As described above, each cam operating portion C ₁ has the low level surface 12, the inclined surface portion 13, the high level surface 14, and the cam projection portion 15, and a plurality of cam operating portions C ₁ , C having these as one set. ₁ ,... Are formed at equal intervals with respect to the outer periphery of the cam base portion 11. Specifically, as shown in FIGS. 3A and 4A, the outer periphery of the cam base 11 is divided into four equal parts, and one cam operating part C ₁ is formed in each of the four divided areas. As a result, four cam operating portions C ₁ , C ₁ ,... Are formed in _one cam base portion 11.

Further, the formation order of the low-order surface 12, the slope portion 13, the high-order surface 14 and the cam projection 15 in all the cam operation portions C ₁ , C ₁ ,... Formed in the cam base portion 11 is the same. That is, when one cam operating portion C ₁ is formed in the order of the lower surface 12, the slope portion 13, the high surface 14, and the cam projection 15, the other cam operating portions C ₁ , C ₁ ,. In order. That is, when one cam operating portion C ₁ is in the order of the low-order surface 12, the slope portion 13, the high-order surface 14, and the cam projection portion 15, the cam operation portion C ₁ adjacent to the cam projection portion 15 is The lower surface 12 is formed.

Incidentally, lower surface 12 of the camming portion C _1, the order of the inclined surface portion 13, the high surface 14 and the cam protrusion 15 first was set to begin at lower surface 12, which is simply for convenience, lower surface 12 For example, the cam protrusion 15 as the starting point, and the cam protrusion 15, the lower surface 12, the inclined surface 13, and the higher surface 14. The starting point is the slope 13, the high level surface 14, the cam projection 15, the low level 12, etc., and any of the low level 12, slope 13, high level 14 and cam projection 15 is the starting point in that order. The order may be changed.

The lower surface 12 and the higher surface 14 are surfaces along the surface of the disc of the cam base portion 11 as shown in FIGS. 3 (A), (B), (C) and FIGS. 4 (A), (B). The lower surface 12 is a cam surface formed at a lower position, and serves to bring the main driving cam C and the driven cam D into a close state. The high level surface 14 is a cam surface formed at a high position, and is a cam surface that serves to separate the main driving cam C and the driven cam D from each other. Here, the proximity state of the main drive cam C and the follower cam D means that the main drive cam C and the follower cam D are relatively rotated while maintaining the contact state, and the interval between them is minimized. There, FIG. 6 (a), the FIG. 7 (D), the as shown in FIG. 8 (C), are shown at the minimum interval T _min. Further, the separated state of the main drive cam C and the follower cam D is that the main drive cam C and the follower cam D are relatively rotated while maintaining the contact state, and the interval between them is maximized. 6 (B), FIG. 7 (A), and FIG. 8 (A), the maximum interval T _max is indicated. The inclined surface portion 13 is an inclined surface formed between the lower surface 12 and the higher surface 14. In addition, as shown in FIGS. 3 (A), (B), (C) and FIGS. 4 (A), (B), the cam projection 15 has a substantially rectangular shape when viewed from the outer side. It is formed of a top surface portion 15a, a high surface rising side portion 15b, and a low surface rising side portion 15c.

  The high surface rising side portion 15b is a side surface near the high level surface 14 in the cam projection 15, and the low surface rising side portion 15c is a side surface close to the low level surface 12. That is, the high level surface 14 is located on one side of the cam projection 15 in the width direction (along the outer peripheral direction of the cam base portion 11), and the low level surface 12 is located on the other side. The side surface located on the high level surface 14 side is referred to as the high surface rising side portion 15b as described above, and the side surface located on the low level surface 12 side is referred to as the low surface rising side portion 15c.

In the top surface portion 15a of the cam projection 15, the guide surface 15a ₁ of slightly inclined is formed on the high surface rising side 15b side closer. The guide surface 15a ₁ is formed to be inclined downward toward the high surface rising side portion 15b. The guide surface 15a ₁ may be a flat inclined surface or an arcuate surface. By forming the guide surface 15a _1, when the cam projection 15 moves, it can move smoothly. Furthermore, the inclination angle of the guide surface 15a ₁ may be the same as the inclination angle of the slope portion 13. By making the guide surface 15a _{1 the} same as the slope portion 13, the cam operating portion C ₁ of the main cam C is provided.
For the driven cam D having the cam operating portion D ₁ having the same shape as that of the cam projection portion 15, the contact area of the cam projection portion 15 can be increased.

As shown in FIGS. 2 and 4C, the center of the cam base portion 11 is located on the opposite side of the cam base portion 11 on the side where the cam operating portions C ₁ , C ₁ ,. A non-circular bulging portion 16 having the same center is formed. The bulging portion 16 is formed in an oval shape, a rectangular shape, an elliptical shape, or a circular shape in which a part thereof is flat. The bulging portion 16 is mounted so as to be inserted into the fixing hole 25a ₁ of the operation lever 25 described above, and the operation lever 25 and the main driving cam C are integrally rotated. Therefore, the fixing hole 25a ₁ of the operation lever 25 is a hole having substantially the same shape as that of the bulging portion 16 or a hole shape that can be idled with respect to the bulging portion 16. Yes.

Next, the follower cam D has the same shape as the main drive cam C, but the reference numerals of the respective parts are different. First, a plurality of cam operating portions D ₁ , D ₁ ,... Are formed on the cam base portion 17. The cam operation part D ₁ is formed by continuously forming a lower surface 18, a slope 19, a higher surface 20 and a cam projection 21. The cam base portion 17 is formed in a disc shape, and a mounting hole 17a is formed at the center thereof. The mounting hole 17a of the driven cam D is mounted on the bolt shaft portion 10a of the lock bolt 10 so as to be idle.

A plurality of cam operating portions D ₁ , D ₁ ,... Are formed along a circumferential direction on any one side surface of the cam base portion 17 and in an appropriate region on the outer periphery thereof. Each cam operating part D ₁ has a low-order surface 18, an inclined surface part 19, a high-order surface 20 and a cam projection part 21, and a plurality of cam operating parts D ₁ , D ₁ ,. The cam base portion 17 is formed so as to be equidistant from the outer periphery. The cam actuating portion D ₁ is related to the low-order surface 18, the slope portion 19, the high-order surface 20, and the cam projection portion 21. It is exactly the same in shape and size, and is formed under the same conditions.

Similarly to the cam projection portion 15 of the main cam C, the cam projection portion 21 is composed of a top surface portion 21a, a high surface rising side portion 21b, and a low surface rising side portion 21c, and these top surface portions 21a. The formation conditions of the high surface rising side portion 21b and the low surface rising side portion 21c are exactly the same as the top surface portion 15a, the high surface rising side portion 15b, and the low surface rising side portion 15c of the cam protrusion 15 described above. Furthermore, a slightly inclined guide surface 21a ₁ is formed on the top surface portion 21a of the cam projecting portion 21 near the high surface rising side portion 21b, and this guide surface 21a ₁ is also in the same condition as the guide surface 15a ₁ of the main cam C. Is formed.

Further, the cam base portion 17 has a non-circular bulging portion 22 having the same center as the center of the cam base portion 17 on the opposite side to the side where the cam operating portions D ₁ , D ₁ ,. The bulging portion 22 has the same shape as the bulging portion 16 of the main cam C. The bulging portion 22 of the follower cam D is installed so that the follower cam D cannot be rotated on the fixed bracket A side tilt adjusting long hole 1a.

  Next, the configuration of the entire apparatus will be described. First, as shown in FIGS. 1 and 9, both movable side portions 4 and 4 of the movable bracket B are disposed between the fixed side portions 1 and 1 of the fixed bracket A. Then, the tilt adjusting long holes 1a and 1a formed in the fixed side portions 1 and 1 and the tilt adjusting through holes 4a and 4a formed in the movable side portions 4 and 4 are aligned with each other. . The bolt side 10a of the lock bolt 10 is set so as to penetrate through the tilt adjusting long holes 1a, 1a and the tilt adjusting through holes 4a, 4a of the fixed side portions 1, 1 and the movable side portions 4, 4.

Here, in FIG. 1, when the state where the fixed bracket A and the movable bracket B are combined is viewed from the driver side (that is, the steering wheel 8 side), the bolt head portion 10c of the lock bolt 10 is positioned on the left side. The bolt screw portion 10b is located on the right side. The bolt screw portion 10b has a structure that protrudes toward the outside of the fixing bracket A from the tilt adjusting long hole 1a of the right fixing side portion 1. Further, the driven cam D is mounted in a non-rotating state in the tilt adjusting long hole 1a of the left fixed side 1 as viewed from the driver of the fixed bracket A. At this time, the bulging portion 22 of the driven cam D is inserted into the tilt adjusting long hole 1a, so that the driven cam D can be installed in a non-rotating state with respect to the fixed bracket A.

Further, the bolt screw portion 10b of the lock bolt 10 is passed through the mounting hole 17a of the driven cam D in a loosely inserted state. The main driving cam C is press-fitted and fixed in the press-fitting region 10 d of the lock bolt 10. Further, an operation lever 25 is attached to the main drive cam C, and the main drive cam C can turn the lock bolt 10 in the axial direction by turning the operation lever 25. By properly mounting the lock bolt 10 to the fixed bracket A and the movable bracket B, cam operating portions C ₁ , C ₁ ,... Of the main cam C are formed as shown in FIGS. The surface on which the cam actuating portions D ₁ , D ₁ ,... Of the driven cam D are formed face each other. In other words, each camming portion C ₁ and the cam actuating portion D ₁ is brought into contact to overlap.

  Further, on the other end side of the lock bolt 10 from the bolt head 10c formation side, as shown in FIGS. 1 and 9, the washer 26, the thrust bearing 27, the thrust washer 29, The lock nut 10 is composed of a lock nut 28, and the lock bolt 10 is fastened and fixed to the fixed bracket A and the movable bracket B so as to be rotatable. The operation lever 25, the lock bolt 10, and the main drive cam C are configured to rotate together. Further, in order to prevent loosening due to frictional engagement of the lock nut 28, a thrust bearing 27 and a thrust washer 29 are provided on the bracket side of the lock nut 28. As the lock bolt 10 rotates, the thrust washer 29 and the thrust bearing 27 rotate around the axis. Rotate to.

In FIG. 10, the operation lever 25 is rotated from the lower side to the upper side, that is, counterclockwise in the axial direction of the lock bolt 10, whereby the lock bolt 10 and the driven cam C are fixed (the driven cam D is fixed). Because of the rotation, the main cam C and the driven cam D rotate with each other. As a result, the cam operation portions C ₁ , C ₁ ,... And the cam operation portions D ₁ , D ₁ ,. Will move to each other.

The process from the tilt lock release to the tilt lock state in the rotational operation of the main cam C and the driven cam D will be described. The cam operation portion C ₁ is connected between the cam operation portion C ₁ and the cam operation portion D _{1. by} the _first top wall 15a of the cam projection 15 reaches the position of the higher surface 20 passes through the inclined surface portion 19 from the position of the lower surface 18 of the cam actuating portion D _1, and a primary cam C and follower cam D Separate. At this time the top surface 21a of the cam protrusion 21 of the cam actuating portion D ₁ is to reach the position of the higher surface 14 through the inclined surface portion 13 from the position of the lower surface 12 of the cam actuating portion C _1.

At this time, when the guide surface 15a ₁ of the cam projection 15 is the same inclined surface as the slope portion 19, the guide surface 15a ₁ is always in surface contact with the slope portion 19, and the cam projection 15 is inclined. The part 19 can be moved in a stable state. The same applies to the relationship between the guide surface 21 a ₁ of the cam projection 21 and the slope portion 13. That is, as shown in FIG. 5B, the inclination angle θb of the guide surface 15a ₁ (21a ₁ ) and the inclination angle θa of the inclined surface portion 19 (13) are set to the same angle (that is, θa = θb). Even when the cam projection 15 (21) moves on the slope 19 (13), as shown in FIG. 8C, the guide surface 15a ₁ (21a ₁ ) is in surface contact with the slope 19 (13). Thus, the contact area between the cam projection 15 (21) and the slope 19 (13) can be increased. Moreover, it is preferable that the guide surface 15a ₁ (21a ₁ ) is formed in an approximately half region when the top surface portion 15a (21a) is viewed from the outer peripheral side surface.

That is, the top wall 15a of the cam projection 15 of the cam actuating portion C _1, top wall 21a of the cam protrusion 21 of the cam actuating portion D ₁ are each constantly abut the camming portion C _1, D ₁ of the mating Maintained. As described above, the main cam C and the driven cam D are separated along the axial direction of the lock bolt 10, so that the fixed side portions 1, 1 of the fixed bracket A and the movable side portion 4 of the movable bracket B are separated. , 4 are pressed against each other, and the tilt lock state can be obtained.

At this time, the lower surface 12 thickness T ₁ (for low surface 18) portion of the primary cam C (including the case of driven cam D), the high surface 14 (high surface 20) the thickness of the portion as T _2, the cam When the thickness of the protruding portion 15 (cam protruding portion 21) is T ₃ , the separated total thickness Ta = T ₃ + T _{2 in} the separated state of the main cam C and the driven cam D. This is the result that the main cam C and the driven cam D have the maximum interval T _max . In the proximity state of the main cam C and the driven cam D, the total proximity thickness Tb = T ₃ + T ₁ . This is the result of the minimum interval T _min between the main cam C and the driven cam D. Therefore, the distance difference between the separated state and the proximity state of the main cam C and the driven cam D is T = maximum interval T _max −minimum interval T _min = Ta−Tb = T ₂ −T ₁ . This distance difference T is a tightening amount at which the movable bracket B is fixed to the fixed bracket A by the cam.

Next, the process from the tilt lock state to the tilt lock release state will be described. When the operation lever 25 is rotated from the upper side to the lower side, that is, clockwise, the main cam C is moved in the opposite direction to the previous time. pivoted, in mutually rotation of this primary cam C and follower cam D, between the camming portion C ₁ and the cam actuating portion D _1, top wall 15a of the cam projection 15 of the cam actuating portion C ₁ is The main driving cam C and the driven cam D are brought close to each other by passing through the inclined surface portion 19 from the position of the high level surface 20 of the cam operating portion D ₁ and reaching the position of the low level surface 18.

At this time, results in reaching the position of the lower surface 12 through the inclined surface portion 13 top wall 21a of the cam protrusion 21 of the cam actuating portion D ₁ is the position of the higher surface 14 of the cam actuating portion C ₁ , a top wall 15a of the cam projection 15 of the cam actuating portion C _1, top wall 21a of the cam protrusion 21 of the cam actuating portion D ₁ is in contact at all times with the cam actuating portion C _1, D ₁ mating with each other State is maintained. In this manner, the main cam C and the driven cam D are close to each other along the axial direction of the lock bolt 10, so that the fixed side portions 1, 1 of the fixed bracket A and the movable side portion 4 of the movable bracket B are arranged. , 4 can be loosened from each other and the tilt lock can be released, and the movable bracket B can be tilted and telescopically made to the fixed bracket A.

A plurality of (4 in the above embodiment) cam operating portions C ₁ , C ₁ ,... Of the main cam C and a plurality (4 in the above embodiment) cam operating portions D ₁ , D ₁ ,. In the overlapped state of..., The timing of movement of the cam protrusions 15, 15,... And the cam protrusions 21, 21,. , (B), the top surface portions 15a, 15a,... Of the cam projections 15, 15,... And the top surface portions 21a, 21a,. Are in contact with the parts C ₁ , C ₁ ,... And the cam operating parts D ₁ , D ₁ ,. 7A to 7D show a process in which the main cam C rotates with respect to the driven cam D and gradually shifts from the separated state to the close state. FIG. 8 is an enlarged view showing the mutual operation of the cam projection 15 and the cam projection 21 of FIG.

Further, in mutual rotation operation in the tilt lock and release by the primary cam C and follower cam D, the cam projection 15 of the cam actuating portion C _1, and the cam protrusion 21 of the cam actuating portion D ₁ is one of the times Also in the moving operation, the cam projection 15 and the cam projection 21 come into contact with each other, and serve as a stopper to regulate the tilt lock position and the release position accurately. As a result, stable performance can be ensured with an inexpensive configuration.

According to the above configuration, the cam operating portions C ₁ , C ₁ ,... Of the main driving cam C and the driven cam D, the cam protruding portions 15, 15,... And the cam protruding portions 21 of the cam operating portions D ₁ , D ₁ ,. 21,... Always move in contact with the lower surface 12, the inclined surface portion 13, the higher surface 14, the lower surface 18, the inclined surface portion 19, and the higher surface 20 when the operation lever 25 is operated. The number is
Compared to a conventional cam mechanism in which only one cam projection is provided and the other cam projection is in contact with the cam surface, the contact area is doubled and the contact pressure is distributed to the contact area. Will be.

In the present invention, the cam projections 15 and 21 of the main cam C and the driven cam D are in contact with each other along the axial rotation direction (or circumferential direction) of the cam. However, the top surface portions 15a and 21a are not in contact with each other in the axial direction. In the process in which the main driving cam C and the driven cam D reach the tilt lock release state from the tilt lock state or the opposite process, the cam projection 15 and the cam projection 21 always have the opposite cam (main drive cam). C, the cam operating portions C ₁ and D ₁ of the driven cam D) are kept in contact (surface contact).

  As a result, the pressure applied to one cam projection 15 and cam projection 21 is half that of the conventional type compared to the conventional type, and wear of the cam projection 15 and cam projection 21 is reduced over a long period of time. Damage can be prevented, and the durability of the tilt / telescopic steering device can be improved. Moreover, the main cam C and the driven cam D are both formed in the same shape, so that the parts can be shared and the productivity can be improved, and as a result, the cost can be reduced.

  In FIG. 1C, the driving cam C is arranged on the fixed side 1 side of the fixing bracket A, and the driven cam D is arranged outside. The lock bolt 10 is fixed to the fixed side portions 1 and 1 of the fixed bracket A so as not to rotate in the axial circumferential direction, and the driven cam D is fixed by the lock bolt 10 so as not to rotate. The main drive cam C is provided so as to be rotatable with respect to the lock bolt 10, and the rotation center portion 25 a of the operation lever 25 is attached to the bulging portion 16 of the main drive cam C. The main drive cam C is connected to the operation lever 25. In addition, it can be rotated freely. In this way, the main drive cam C and the follower cam D can be separated and brought close to each other so that the fixed bracket A and the movable bracket B can be tilt-locked and unlocked.

(A) is a longitudinal front view with a partial cross section of the present invention, (B) is an enlarged view of the main part of (A), and (C) is an enlarged view in which the positions of the primary cam and the driven cam are changed in (A). FIG. It is a disassembled perspective view of operation members, such as a lock bolt, an operation lever, a main drive cam, and a driven cam. (A) is a perspective view of a main drive cam (driven cam), (B) is an enlarged perspective view of a main part of (A), and (C) is an enlarged perspective view of a main part of another part of (A). (A) is a front view of a main drive cam (driven cam), (B) is a rear view of the main drive cam (driven cam), and (C) is a cross-sectional view of the main part of (A). (A) is the development seen from the outer peripheral side surface of the cam action part of a main drive cam (driven cam), (B) is the principal part enlarged view of (A). (A) is a side view of the state where the main drive cam and the driven cam are close to each other, and (B) is a side view of the state where the main drive cam and the driven cam are separated from each other. (A) is a state diagram of the cam protrusions in a state where the main cam and the driven cam are separated from each other, (B) is a state diagram in which the protrusion is located between the high surface and the inclined surface, (C) is FIG. 4D is a state diagram in which the protrusions are positioned on the slope portion, and FIG. 4D is a state diagram of the cam protrusions in a state where the main cam and the driven cam are close to each other. (A) is an enlarged state diagram of cam protrusions in a state where the main cam and the driven cam are separated from each other, (B) is an enlarged state diagram in which the guide surface of the protrusion is in contact with the inclined surface in a surface contact state. C) is an enlarged state diagram of the cam protrusions in a state where the main driving cam and the driven cam are close to each other. It is an exploded view of the main member in this invention. It is the side view made into the partial cross section of the steering device provided with this invention. (A) is a plan view of a conventional type driven cam, (B) is a plan view of a conventional type driven cam, and (C) is a schematic view showing a cam operation in the conventional type.

Explanation of symbols

A ... fixed bracket, B ... movable bracket, C ... driving member, D ... driven cam C _1, D ₁ ... camming portion, 1 ... fixed side, 4 ... movable side, 10 ... lock bolt 12, 18 ... low Surface, 13, 19 ... Slope, 14, 20 ... Higher surface 15, 21 ... Cam projection, 15a, 21a ... Top surface, 15a ₁ , 21a ₁ ... Guide surface 25 ... Operation lever

Claims (4)

A fixed bracket having a fixed side part, a movable bracket having a movable side part, a lock bolt that penetrates the fixed side part and the movable side part, a main cam that the lock bolt penetrates, and the lock bolt penetrates a driven cam which is non-rotatably mounted, consists of a control lever for rotating said driving member, lower surfaces of the same shape in the primary cam and the driven cam, the inclined surface portion, in the order of the higher surface and the cam protrusion A plurality of cam actuating portions are formed along the circumferential direction, the cam projecting portions having a cam projecting portion in which a high level surface is located on one side in the width direction of the cam projection and a low level surface is located on the other side ; When the operation lever is rotated, the main cam and the driven cam are separated from and close to each other in the axial direction, and only the top surface portion of the cam projection is in the main cam when the main cam is rotated. Driven cam In contact with the lower surface, inclined surface, and higher surface of the cam operating portion, and in the driven cam, only the top surface portion of the cam projection portion contacts the lower surface, inclined surface, and higher surface of the cam operating portion of the main cam; and It said top surface of both the cam protrusion fixing device of a steering apparatus characterized by comprising a non contact.   2. The steering device fixing device according to claim 1, wherein a guide surface that is inclined toward the high surface side is formed near the high surface side of the top surface portion of the cam projection.   3. The steering device fixing device according to claim 2, wherein the guide surface is an inclined surface that is inclined so as to be lowered toward the high-level surface.   4. The steering device fixing device according to claim 3, wherein the inclined guide surface has the same slope as the slope portion.

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