JP6697336B2 - Steering device - Google Patents

Description

  The present invention relates to a steering device that includes a mechanism that regulates a telescopic adjustment range, and that can perform an independent operation that is not affected by the mechanism that regulates the telescopic adjustment range in a shock absorbing operation during a secondary collision.

  Conventionally, there are various types which are equipped with a telescopic adjustment mechanism and a shock absorbing device for protecting a driver at the time of a secondary collision. As a prior art document relating to such a steering device, there is Patent Document 1. An outline of Patent Document 1 (JP 2005-1517 A) will be given. In addition, in order to distinguish it from the description of the invention of the present application, in the description of Patent Document 1, the reference numerals are parenthesized. In the steering device in Patent Document 1, one end of the link member (33) is attached to the operation lever portion (20), and the other end of the link member (33) is provided with the cylindrical portion (21a) of the outer jacket (21). It is attached to the lower end of a restricting member (34) pivotally attached to the lower surface.

  The restriction part (34a) formed on the upper end of the restriction member (34) can enter the cylindrical part (21a) through the opening (21g) formed in the lower part of the cylindrical part (21a). . Further, a long hole (11f) is formed in the upper part of the inner column (11), and the tip of the bolt 35 screwed into the upper part of the outer jacket (21) projects into the long hole (11f). It is installed so that

  In this state, the limiting member (34) pulled by the link member (33) tilts, and the limiting portion 34 at the upper end thereof is pulled out of the opening (21g) of the outer jacket (21) (that is, retracted from the limiting position). Then, it moves to a position where it does not contact the inner column (11) (outward in the radial direction from the inner peripheral surface of the outer jacket (21)). Therefore, even if a secondary collision occurs in which the driver collides with a steering wheel (not shown) during a vehicle collision, the inner column (11) moves (collapses) without colliding with the restriction member (34). Therefore, stable energy absorption can be performed.

  Further, the restriction member (34) pushed by the link member (33) stands upright, and the restriction member (34) at the upper end of the restriction member (34) extends from the opening (21g) of the outer jacket (21) to the inside (that is, the outer jacket (21)). Since it projects inward in the radial direction from the inner peripheral surface (that is, moves to the limit position), the inner column (11) can be brought into contact therewith. Therefore, when the inner column (11) is pressed toward the outer jacket (21) during telescoping adjustment, the end portion of the inner column (11) abuts the limiting member (34a) to prevent further displacement in the reduction direction. Function as.

JP 2005-1517 A

  However, the above-mentioned Patent Document 1 has the following problems. First, the limiting member is configured so that the limiting member projects from the opening of the cylindrical portion of the outer jacket by the rotation of the operation lever portion via the link member. The amount of protrusion changes depending on the rotation angle of the operation lever portion, and it is difficult to always have a constant amount of protrusion, which may make it difficult to manage the component dimensions.

  Further, the limiting member becomes vertical by the rotation of the operation lever portion via the link member, and the limiting member projects from the opening of the cylindrical portion of the outer jacket. When the inner shaft bumps into the restricting member vigorously, the restricting member may be pushed back in the retreat direction by the force and tilted. When the limiting member is inclined, the proper telescopic adjustment range may be misaligned.

  Therefore, an object (technical problem to be solved) of the present invention is to provide a steering device that includes a mechanism that regulates a telescopic adjustment range, and that is an independent operation that is not affected by the telescopic mechanism in a shock absorbing operation during a secondary collision. In (1), appropriate telescopic adjustment can be performed, and stable energy absorption can be performed during a secondary collision.

  Then, as a result of earnestly researching in order to solve the above-mentioned subject, the inventor has made the invention of claim 1 the outer column having an inner column to which a stopper bracket is fixed and a split groove portion in which the stopper bracket is arranged. A fixing bracket that holds the outer column, a fastening tool that has a bolt shaft and an operating lever portion to lock and release, an elastic member that has a pressing portion and is attached to the fixing bracket, and the pressing member. And a telescopic stopper having a restriction portion whose height position is displaced according to the height position of the portion, and a slide member that moves in the front-back direction by swinging the operation lever portion and maintains the pressing portion at the high position and the low position. The above-described problem is solved by providing a steering device that includes a stopper that allows the stopper bracket and the restriction portion to contact each other in the unlocked state and cannot contact each other in the locked state.

  According to the invention of claim 2, an inner column, a holding main body portion for moving and fixing the inner column in the front-rear direction, a split groove portion formed below the holding main body portion and extending in the front-rear direction, and a diameter. An outer column having a clamp portion that expands and contracts in the direction, a fixed bracket having fixed side portions that sandwich both widthwise sides of the outer column, a bolt shaft and an operation lever portion, and the outer column and the fixed bracket. A fastener that locks and unlocks the inner column, an elastic member that is locked to the fixing bracket and that has a pressing portion that elastically biases the outer column upward from below, and in the front-back direction. A stopper bracket having a rear stopper portion and a front stopper portion and fixed to the inner column, a swing receiving portion on the front side, a restricting portion on the rear side, and pivotally connected to the bolt shaft. And a telescopic stopper that swings in the vertical direction, a high position support portion that supports the pressing portion at a high position, and a low position support portion that supports the pressing portion at a low position, and is fixed to the operation lever portion. A slide member that moves in the front-rear direction in accordance with the operation of the operation lever portion, the pressing portion being locked to the low position support portion of the slide member in the unlocked state by the operation lever portion, The above-described problem is solved by using the steering device in which the pressing portion is locked to the high position support portion of the slide member in the locked state.

  According to a third aspect of the present invention, in the steering apparatus according to the second aspect, the steering device in which the high position support portion and the low position support portion of the slide member are recesses that can accommodate the pressing portions of the elastic member. As a result, the above problems have been solved. The invention according to claim 4 is the steering device according to claim 2, wherein the high position support portion and the low position support portion of the slide member are continuously formed in an inclined shape. Solved the problem.

  In the first and second aspects of the invention, the telescopic stopper has a restriction portion whose height position is displaced according to the height position of the pressing portion of the elastic member. By the swing of the operation lever portion, the slide member moves in the front-rear direction and maintains the pressing portion at the high position and the low position. The stopper bracket and the restricting portion can contact each other in the unlocked state and cannot contact each other in the locked state.

  Therefore, when the stopper bracket and the restriction portion come into contact with each other, an appropriate telescopic adjustment range can be set, and stable energy absorption can be performed without the stopper bracket and the restriction portion coming into contact with each other at the time of a secondary collision.

  Further, at the time of a secondary collision, the function of the telescopic stopper is released, so that a smooth and stable load characteristic can be obtained without generating a telescopic stopper abutting load. Further, since the elastic member is connected to the operation lever portion via the slide member, the biasing force of the elastic member provides the effect of preventing the operation lever portion from rebounding when the lever is released. Further, since the urging force of the elastic member is constantly applied to the bolt via the telescopic stopper, there is an effect of preventing rattling of the bolt, and the telescopic operation feel can be improved.

  Particularly, in claim 2, the slide member has a high position support portion and a low position support portion, and the high position support portion supports the pressing portion of the elastic member at a high position, The position support portion is configured to support the pressing portion of the elastic member at a low position. As a result, it is possible to more reliably set the upper and lower positions of the regulating portion by the swinging movement of the telescopic stopper, and it is possible to more reliably switch the operation between the telescopic adjustment and the energy absorption at the time of a secondary collision, and the structure is extremely simple. It can be something.

  In the invention of claim 3, the high-position support portion and the low-position support portion of the slide member are recesses capable of accommodating the pressing portion of the elastic member. And maintained in the low position. In the invention of claim 4, since the high position support portion and the low position support portion of the slide member are continuously formed in a slanted shape, the pressing portion relatively moves between the high position support portion and the low position support portion. Can move smoothly when moving.

(A) is a side view of the present invention, (B) is an enlarged view of the X1-X1 arrow of (A), (C) is an enlarged view of (α) part of (A), (D) is (C) ( It is a figure which removed the operation lever part of a fastening tool in (beta) part. 1A is an enlarged side view of an essential part of the present invention, which is a partial cross section, FIG. 1B is an enlarged side view of an essential part, which is a partial cross section of FIG. 1A excluding a slide member, and FIG. ) Is an enlarged sectional view taken along the line Y1-Y1 of FIG. (A) is a side view showing the operating state of the operating lever portion and the slide member, (B) to (D) shows an embodiment of the connecting structure of the operating lever portion and the slide member, Y2-Y2 arrow of (A). (E) is a side view of the stabilizing member, (F) is a sectional view taken along the line Y3-Y3 of (E), and (G) is a state in which the stabilizing member is attached to the outer column via a fastener. (H) is a sectional view taken along the line Y4-Y4 of (G). (A) is a perspective view of a telescopic stopper, (B) is a perspective view of an elastic member, (C) is a perspective view of a slide member, and (D) and (E) are high position support parts and low position support parts of the slide member. FIG. 3 is a side view of a main part showing the embodiment of FIG. (A) is a figure which shows the state of each member in a telescopic lock release state, (B) is a figure which shows the state of each member in a telescopic lock state. (A) is a figure which shows operation | movement in a telescopic adjustment state, (B) is a figure which shows operation | movement in the energy absorption state in a secondary collision.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Here, in the present invention, the wording indicating the direction includes the front side, the rear side, and the front-back direction. The front side and the rear side refer to the front and rear direction of the vehicle with the steering device of the present invention mounted on the vehicle. Specifically, in each component of the steering device, the front wheel side of the automobile is the front side, and the steering wheel (steering wheel) side is the rear side.

  As shown in FIGS. 1 and 2, etc., the structure of the present invention mainly includes an outer column 1, a fixed bracket 2, a fastening tool 3, an inner column 4, a stopper bracket 5, a telescopic stopper 6, an elastic member 7 and a slide. And a member 8. The outer column 1 is composed of a holding body 11 and a clamp 12. The wrapping body 11 is formed in a substantially cylindrical shape having a hollow inside, and specifically, the inside has a wrapping inner peripheral side surface portion 11a formed in a hollow shape. A split groove portion 11b is formed on the lower side in the diametrical direction of the holding main body portion 11 [see FIGS. 1 (B) and 2 (C)].

  The split groove portion 11b is a portion that is separated in the width direction from the front side to the rear side in the axial direction of the packaging main body 11. Since the edge portions facing each other on both sides in the width direction of the split groove portion 11b come close to each other, the diameter of the inner peripheral side surface portion 11a of the wrapping is reduced, and the inner column 4 housed and mounted in the wrapping main body 11 is provided. Can be locked by tightening.

  The wrapping inner peripheral side surface portion 11a of the wrapping main body portion 11 is formed to be slightly larger than the outer diameter of the inner column 4 so that the inner column 4 can easily slide in the unlocked state. There is. In addition, the holding main body portion 11 is formed to have a length that can appropriately support a substantially intermediate portion of the inner column 4 in the axial direction in the axial direction. The inner columns 4 project from the front end portion and the rear end portion in the axial direction of the holding main body portion 11, respectively.

  Clamp portions 12, 12 are integrally formed on the lower portion of the outer column 1 (see FIGS. 1B and 2C). Both clamp parts 12 and 12 have a bilaterally symmetrical shape and are integrally formed at positions of both widthwise ends of the dividing groove part 11b, and specifically, both widthwise ends of the dividing groove part 11b or in the vicinity thereof. Is a thick-walled plate-shaped portion formed in a substantially hanging shape.

  Through holes 12a, 12a for tightening are formed in both clamp parts 12, 12, and a bolt shaft 31 of the tightening tool 3 described later is inserted therein. An arm portion 13 is formed on the front side in the front-rear direction of the holding body portion 11 as shown in FIGS. 1 (B) and 3 (C). The arm portion 13 is composed of two arm-shaped portions 13a and 13a, and both arm-shaped portions 13a and 13a are arranged in a bifurcated shape.

  Next, the fixed bracket 2 is composed of fixed side portions 21 and 21 and mounting top portions 22 formed on both sides in the width direction. Tilt slots 21a, 21a, which are slots formed substantially vertically or vertically, are formed in both the fixed side portions 21 and 21 [see FIGS. 1 (C) and 2 (C)]. Further, upper surface portions 23, 23 are formed on the upper ends of both the fixed side portions 21, 21. Locked holes 23a, 23a for attaching an elastic member 7, which will be described later, are formed in both upper surface portions 23, 23.

  The tightening tool 3 includes a bolt shaft 31, an operating lever portion 32, a tightening cam 33, and a nut 34 [see FIGS. 1 and 2C, etc.]. The tightening tool 3 is attached by a nut 34 together with the operation lever portion 32 and the tightening cam 33. The inner column 4 is internally provided with a middle portion of a steering shaft, and a steering wheel (handle) is attached to the tip of the steering shaft protruding from the rear side of the inner column 4.

  Next, the stopper bracket 5 has two stopper portions in the front-back direction of the base portion 51 [see FIGS. 1 (C) and 2 (B)]. The front side of the stopper portion is the front stopper portion 52, and the rear side thereof is the rear stopper portion 53. Specifically, the front stopper portion 52 is a portion formed in a hanging plate shape from both ends in the width direction of the base portion 51. Further, the rear stopper portion 53 is a portion formed as a substantially inverted L-shaped bent piece from the rear end portion of the base portion 51. The stopper bracket 5 is fixed to the diametrically lower end of the inner column 4 by welding or the like.

  The inner column 4 is wrapped by the wrapping body 11 of the outer column 1, and the stopper bracket 5 is set to fit in the split groove portion 11b. When the inner column 4 reciprocates in the axial direction, the stopper bracket 5 reciprocates in the front-rear direction in the split groove portion 11b [see FIG. 3 (A)].

  During the telescopic adjustment, when the stopper bracket 5 moves in the front-rear direction, the front stopper portion 52 comes into contact with the bolt shaft 31 of the fastener 3 and becomes the end of the rearward movement of the inner column 4. That is, the steering wheel is in the most extended state that is closest to the driver.

  The telescopic stopper 6 includes a swing base portion 61, a swing receiving portion 62, and a regulating portion 63 [see FIGS. 2 (B) and 4 (A)]. The oscillating base portion 61 has two oscillating plate portions 61a and 61a of the same shape formed on both sides in the width direction of the telescopic stopper 6 at appropriate intervals, and the oscillating plate portions 61a and 61a are pivotally supported at the same position. Through holes 61b, 61b are formed.

  The telescopic stopper 6 is disposed at the position of the split groove portion 11b of the outer column 1 and between the clamp portions 12 and 12, and the bolt shaft 31 of the fastening tool 3 penetrates the pivot through holes 61b and 61b. ing. The telescopic stopper 6 is located at the position of the split groove portion 11b of the outer column 1 and in both the clamp portions 12, 12 with the bolt shaft 31 penetrating the pivotal support holes 61b, 61b of the swing base portion 61 as the swing center. It can swing on a vertical plane in the vertical direction.

  A swing receiving portion 62 is formed on the front side of the swing base portion 61, and a restricting portion 63 is formed on the rear side of the swing base portion 61. The rocking | fluctuation receiving part 62 is a site | part which receives the pressing part 71 of the elastic member 7 mentioned later. A bent end portion 62a that is bent and formed in a substantially U shape is formed at a front end portion of the swing receiving portion 62, and has a shape suitable for receiving a substantially shaft-shaped pressing portion.

  The restricting portion 63 includes an arm portion 63b extending rearward from the swing base portion 61 and a contact end piece 63a. The contact end piece 63a is formed at a right angle to the substantially flat arm-shaped portion 63b. The contact end piece 63a is a portion that contacts the rear stopper portion 53 of the stopper bracket 5 at the time of telescopic adjustment (see FIGS. 2A, 2B, and 6A).

  As described above, the telescopic stopper 6 is arranged at the position of the split groove portion 11b and between the clamp portions 12 and 12, and swings on the vertical plane in the front-rear direction with the bolt shaft 31 as the swing center. In this swinging operation, the telescopic stopper 6 is in the form of a balance, the regulating portion 63 is located below when the swing receiving portion 62 is located above, and the regulating portion 63 is located above when the swing receiving portion 62 is located below. Will be located in.

  Then, when the restricting portion 63 is located above, the contact end piece 63a contacts the rear stopper portion 53 of the stopper bracket 5 during the telescopic adjustment, and the contacted position moves to the front side of the telescopic adjustment. Is the end position, that is, the telescopic adjustment is in the most contracted state [see (I) of FIG. 6 (A)]. Further, the front stopper portion 52 of the stopper bracket 5 abuts on the bolt shaft 31, and the abutted position becomes the end position in the rearward movement of the telescopic adjustment, that is, the fully extended state by the telescopic adjustment [FIG. 6]. (See (II) of (A)].

  The elastic member 7 has torsion coil spring portions 72, 72 formed from both ends in the width direction in substantially the same direction [see FIG. 4 (B)]. Specifically, an elastic shaft portion 72a is formed substantially at a right angle from the end portion of the pressing portion 71, a coil portion 72b is formed at the other end of the elastic shaft portion 72a, and the other end of the coil portion 72b is engaged. A stop shaft portion 72c is formed. The pressing portion 71 has a linear shaft shape, and the pressing portion 71 and the elastic shaft portions 72a, 72a are formed in a substantially U shape.

  The locking shafts 72c, 72c are locked and mounted in the locked holes 23a, 23a of the upper surface parts 23, 23 of the fixed bracket 2 described above. Then, the pressing portion 71 is elastically biased upward through the coil portions 72b, 72b. When the elastic member 7 is mounted on the fixed bracket 2, the pressing portion 71 elastically biases the swing receiving portion 62 of the telescopic stopper 6 so as to lift the swing receiving portion 62 upward.

  The slide member 8 includes an operating portion 81, a mounting portion 82, and a connecting portion 83 [see FIGS. 2 (A), 3 (A), 4 (C) to 4 (E)]. The operation portion 81 is formed in a substantially rectangular shape, and a horizontal long slide hole 81a is formed on the upper side thereof along the front-rear direction. In addition, a high position support portion 81b and a low position support portion 81c are formed at the lower end of the operation portion 81.

  The high position support portion 81b and the low position support portion 81c are portions that are formed in a substantially notched shape from the lower end position of the operation portion 81, and the high position support portion 81b is cut off more than the low position support portion 81c. There is. In other words, the high position support portion 81b and the low position support portion 81c are formed as two recesses from the lower end with respect to the operation portion 81, and the high position support portion 81b and the low position support portion 81c are different from each other. They are adjacent to each other in the front-rear direction, and both of them form a substantially M-shaped cutout portion (or dent portion).

  The highest position of the high-position support part 81b is higher than the highest position of the low-position support part 81c, that is, it is formed above. Further, the high position support portion 81b and the low position support portion 81c are continuously formed in an inclined shape (see FIG. 4D), or the high position support portion 81b and the low position support portion 81c are flat. , There is also a configuration in which both are connected by an inclined side [see FIG. 4 (E)].

  The attachment portion 82 is formed continuously with the operation portion 81 via the connection portion 83. The operation portion 81, the attachment portion 82, and the connection portion 83 are formed in a substantially U-shape when viewed two-dimensionally. The mounting portion 82 is formed in a substantially rectangular shape. The slide member 8 clamps one of the clamp portions 12 of the outer column 1 and the fixed side portion 21 of the fixed bracket 2 located on the same side as the clamp portion 12 between the operation portion 81 and the mounting portion 82. Is arranged as. Then, the bolt shaft 31 of the fastener 3 is inserted into the long slide hole 81a of the operation portion 81, and the slide member 8 is attached to the outer column 1 through the fastener 3 (see FIG. 2 (A)). ].

  The slide member 8 moves substantially linearly in the front-rear direction between the clamp portions 12, 12 as the operation lever portion 32 swings when the telescopic adjustment is performed. Specifically, the elongated hole 32b is formed in the lever plate 32a of the operation lever portion 32, and the pin member 82a is attached to the attachment portion 82. The pin member 82a is inserted into the long hole 32b of the lever plate 32a [see FIGS. 3 (A) and 3 (B)]. There is also an embodiment in which a long hole 82b is formed in the attachment portion 82 of the slide member 8 and a pin member 32c is attached to the lever plate 32a of the operation lever portion 32 [see FIG. 3 (C)]. The pin member 82a or 32c may be a bolt or a screw [see FIG. 3 (D)].

  Then, due to the swing of the operation lever portion 32, the slide member 8 moves in the front-rear direction together with the pin member 82a. The elongated hole 32b of the operation lever portion 32 is formed with a substantially vertical direction as a longitudinal direction, and when the operation lever portion 32 swings, the elongated hole 32b and the pin member 82a are relatively moved in the up and down direction. ..

  By moving the slide member 8 in the front-rear direction, the pressing portion 71 of the elastic member 7 is locked to one of the high position support portion 81b and the low position support portion 81c. Specifically, during the telescopic adjustment, that is, in the telescopic lock released state, the pressing portion 71 is locked to the low position support portion 81c. Further, when the telescopic adjustment is completed, that is, in the telescopic lock state, the pressing portion 71 is locked to the high position support portion 81b.

  Therefore, in the telescopic lock released state, the upward biasing force of the pressing portion 71 on the swing receiving portion 62 of the telescopic stopper 6 is regulated by the low position support portion 81c, whereby the regulation portion 63 causes the rear stopper of the stopper bracket 5. It is held at a height position where it can abut the portion 53 [see FIG. 5 (A)].

  Further, in the telescopic lock state, the upward biasing force of the pressing portion 71 applied to the swing receiving portion 62 of the telescopic stopper 6 is restricted by the high position supporting portion 81b, but the high position supporting portion 81b supports the low position. Since the pressing portion 71 is regulated above the portion 81c, the regulation portion 63 is located at a lower position than when the telescopic lock is released and is held at a height position where it does not contact the rear stopper portion 53 of the stopper bracket 5 [Fig. 5 (B)].

  Further, in the slide member 8, the bolt shaft 31 is inserted into the long slide hole 81a, and the slide member 8 linearly moves in the front-rear direction along the position of the bolt shaft 31. The slide member 8 may be provided with a stabilizing member 9 [see FIG. 2 (C)]. The elastic member 7 applies a rotational force to the slide member 8 so that the rear portion of the slide member 8 is lowered.

  The stabilizing member 9 serves to linearly move the slide member 8 in the front-rear direction in a stable state even when a rotational force acts on the slide member 8 (see FIG. 3 (H)). The stabilizing member 9 serves to assist the smooth movement of the slide member 8 in the front-rear direction. The stabilizing member 9 is such that a bolt insertion hole 92 is formed in a support substrate 91, an upper holding protrusion 93 is formed at the upper end of the support substrate 91, and a lower holding protrusion 94 is formed at the lower end [FIG. E) and (F)].

  A step portion 12b linearly extending in the front-rear direction is formed on the inner surface side of one of the clamp portions 12 of the outer column 1 so that the upper holding protrusion 93 of the stabilizing member 9 extends along the step portion 12b. Are arranged [see FIGS. 1 (C), 3 (G), and (H)]. The upper holding protrusion 93 is locked to the upper end of the operating portion 81 of the slide member 8, and the lower holding protrusion 94 is locked to the lower end of the operating portion 81 of the slide member 8.

  The bolt shaft 31 is inserted into the bolt insertion hole 92 [see FIG. 3 (G)]. The slide member 8 is guided by the upper holding projections 93 and the lower holding projections 94 of the stabilizing member 9, and even if the sliding member 8 is given a rotational force about the bolt shaft 31 by the elastic member 7, the sliding member 8 8 is prevented from rotating, and the slide member 8 can linearly move in the front-rear direction in a stable state (see FIG. 3 (H)).

  Next, in the present invention, an operation at the time of unlocking and locking at the telescopic adjustment will be described. First, in order to perform the telescopic adjustment, the fastener 3 is loosened to unlock the inner column 4 by the outer column 1 and the fixing bracket 2 [see (I) in FIG. 5 (A)]. By swinging the operation lever portion 32 rearward in the unlocking direction, the slide member 8 also moves rearward via the pin member 82a [see (II) in FIG. 5 (A)].

  The pressing portion 71 of the elastic member 7 is locked to the low position support portion 81c of the slide member 8. As a result, the pressing portion 71 is set at a low position. Therefore, the swing receiving portion 62 of the telescopic stopper 6 is at a lower position together with the pressing portion 71, and the restricting portion 63 located on the opposite side of the swing base portion 61 of the telescopic stopper 6 is at a high position.

  At this time, the abutting end piece 63a of the restriction portion 63 of the telescopic stopper 6 is at a height position where it can abut the rear stopper portion 53 of the stopper bracket 5 (see (III) in FIG. 5A). That is, in the telescopic adjustment, the movement of the inner column 4 to the front side is restricted, and the end position in the movement to the front side is determined.

  Further, in the telescopic adjustment, the rearward movement of the inner column 4 is restricted by the front stopper portion 52 of the stopper bracket 5 contacting the bolt shaft 31 to determine the end position in the rearward movement. As described above, during the telescopic adjustment, the position of the restriction portion 63 of the telescopic stopper 6 is set to a high position by unlocking, and the telescopic adjustment range is set [see FIG. 6 (A)].

  Next, after the telescopic adjustment is completed, the outer column 1, the fixing bracket 2 and the inner column 4 are locked (tightened and fixed) by the fastener 3. First, the operation lever portion 32 is rocked forward to lock it (see (I) in FIG. 5B). The slide member 8 moves to the front side. The pressing portion 71 of the elastic member 7 moves from the low position support portion 81c of the slide member 8 to the high position support portion 81b and is locked to the high position support portion 81b. As a result, the pressing portion 71 is set to a high position [see (II) in FIG. 5 (B)].

  Therefore, the swing receiving portion 62 of the telescopic stopper 6 is at a high position together with the pressing portion 71, and the restricting portion 63 located on the opposite side of the swing base portion 61 of the telescopic stopper 6 is at a low position. As a result, the rear stopper portion 53 of the stopper bracket 5 and the restricting portion 63 of the telescopic stopper 6 have different height positions and cannot be brought into contact with each other [see (III) in FIG. 5 (B)]. Therefore, at the time of a secondary collision, the rear stopper portion 53 of the stopper bracket 5 does not collide with the restriction portion 63 of the telescopic stopper 6 when the inner column 4 moves forward due to the impact, and is smooth. Thus, stable impact absorption characteristics can be obtained.

DESCRIPTION OF SYMBOLS 1 ... Outer column, 11 ... Enclosing main body part, 11b ... Split groove part, 12 ... Clamp part,
2 ... Fixed bracket, 21 ... Fixed side part, 3 ... Tightening tool, 31 ... Bolt shaft,
32 ... Operation lever part, 4 ... Inner column, 5 ... Stopper bracket,
52 ... front stopper part, 53 ... rear stopper part, 6 ... telescopic stopper, 61 ... swing base part,
62 ... Swing receiving part, 63 ... Restricting part, 7 ... Elastic member, 71 ... Pressing part, 8 ... Sliding member,
81 ... Operation part, 81a ... Sliding long hole, 81b ... High position support part,
81c ... Low position support part.

Claims (4)

  An inner column to which a stopper bracket is fixed, an outer column having a split groove portion in which the stopper bracket is arranged, a fixing bracket that holds the outer column, a bolt shaft and an operating lever portion, and a locking and unlocking lock. An attachment, an elastic member that has a pressing portion and is attached to the fixed bracket, a telescopic stopper having a restricting portion whose height position is displaced according to the height position of the pressing portion, and a swing of the operating lever portion. A slide member that moves in the front-rear direction by movement and maintains the pressing portion at the high position and the low position, and the stopper bracket and the restricting portion can contact in the released state and contact in the locked state. A steering device characterized by being impossible.   An inner column, a holding main body that moves and fixes the inner column in the front-rear direction, a split groove portion that is located below the holding main body and that extends in the front-rear direction, and a clamp portion that expands and contracts in the diameter direction. An outer column having, a fixed bracket having fixed side portions for sandwiching both sides in the width direction of the outer column, a bolt shaft and an operation lever portion, and locking the outer column, the fixed bracket, and the inner column, and A fastener for unlocking, an elastic member having a pressing portion that is locked to the fixed bracket and elastically biases upward from the lower side of the outer column, a rear stopper portion and a front stopper portion in the front-rear direction. And a stopper bracket fixed to the inner column, a swing receiving portion on the front side, a restricting portion on the rear side, pivotally connected to the bolt shaft, and swings in the vertical direction. It has a telescopic stopper, a high position support part for supporting the pressing part in a high position, and a low position support part for supporting the pressing part in a low position, and is fixed to the operation lever part to operate the operation lever part. And a slide member that moves in the front-rear direction together, the pressing portion is locked to the low position support portion of the slide member in the unlocked state by the operation lever portion, and the pressing portion in the locked state by the operation lever portion. The steering device is characterized in that it is locked to the high position support portion of the slide member.   The steering device according to claim 2, wherein the high position support portion and the low position support portion of the slide member are recesses that can accommodate the pressing portion of the elastic member.   The steering apparatus according to claim 2, wherein the high position support portion and the low position support portion of the slide member are continuously formed in an inclined shape.

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