KR101068585B1 - Apparatus for adjusting the steering column - Google Patents

Abstract

The present invention relates to a steering column control device, and more particularly, it is very easy to adjust the inclination angle (tilting) and vertical height adjustment (telescoping) of the steering column and also to maintain the steering column adjustment position firmly It relates to a steering column control device.

The present invention provides a steering column having a top jacket and a bottom jacket that is telescoping; A telescoping bracket fixed to the upper jacket of the steering column; A rake bracket disposed to surround the telescoping bracket; A telescope lock member detachably engageable with said telescope rack; A rake lock member detachably engageable with the rake rack; A lake bolt installed through the lake bracket and the telescoping bracket and having an operating lever at one end thereof; A cam plate for moving the telescope lock member as it rotates with the lake bolt; And a cam member for moving the rake lock member as it rotates together with the lake bolt, wherein the cam plate and the cam member are installed on an outer circumferential surface of the lake bolt, and the cam plate and the cam member are connected to the lake bolt. It is characterized in that it is installed to rotate together.

Steering, Column, Telescope, Rake, Cam Member

Description

Steering column adjustment device {APPARATUS FOR ADJUSTING THE STEERING COLUMN}

The present invention relates to a steering column control device, and more particularly, it is very easy to adjust the inclination angle (tilting) and vertical height adjustment (telescoping) of the steering column and also to maintain the steering column adjustment position firmly It relates to a steering column control device.

As is well known, a vehicle is provided with a steering device for adjusting the traveling direction, and the steering device is a device for transmitting a steering force to a steering gear, a link, etc. by the driver by direct steering operation. It consists of a steering wheel, a steering shaft, a steering column and the like.

In particular, a steering column adjusting device is installed to adjust the position of the steering wheel to suit the driver's physical condition, driver's attitude, and the like. The steering column adjusting device is configured to adjust the inclination angle to the height of the steering column by operating the operating lever.

Conventional steering column control device is a control lever installed on one side of the steering column, a rake bracket for adjusting (tilting) the inclination angle of the steering column by the control lever, the height of the steering column by the control lever (tele) Telescoping brackets, etc., wherein the rake bracket and telescoping bracket are configured to maintain the adjusted position of the steering column by frictional force.

On the other hand, in the event of a collision of the vehicle, when the upper body or head of the driver collides with the steering wheel or the airbag, the conventional steering column adjusting device has a weak holding force for maintaining the adjustment position of the steering column, so that the steering column or the steering wheel is in an upward direction. At the same time, as the upper body of the driver or the head rotates, there is a disadvantage that can significantly reduce the collision energy absorption performance of the intended airbag and steering column in the design.

The present invention has been made in view of the above-mentioned, it is very easy to adjust the inclination angle (tilting) and height adjustment (telescoping) of the steering column and at the time of a vehicle collision by maintaining the steering column adjustment position firmly In addition, an object of the present invention is to provide a steering column control device that optimally exhibits the collision energy absorption performance of the airbag and the steering column.

The present invention for achieving the above object,

A steering column having a top jacket and a bottom jacket mounted telescopeably;

A telescope rack fixed to an upper jacket of the steering column, having a telescope slot extending in a longitudinal direction of the steering column, and having a telescope rack proximate to the telescope slot, the telescope rack having a plurality of teeth Scoping brackets;

A rake slot disposed to surround the telescoping bracket, having a rake slot extending in a direction orthogonal to the telescope slot, and having a rake rack proximate to the rake slot, the rake rack having a plurality of teeth ;

A telescope lock member detachably engageable with said telescope rack;

A rake lock member detachably engageable with the rake rack;

A lake bolt installed through the lake bracket and the telescoping bracket and having an operating lever at one end thereof;

A cam plate for moving the telescope lock member as it rotates with the lake bolt; And

And a cam member for moving the rake lock member as it rotates with the rake bolt.

The cam plate and the cam member are installed on an outer circumferential surface of the lake bolt, and the cam plate and the cam member are installed to rotate together with the lake bolt.

The telescope lock member has a base and a pair of side walls provided on both sides of the base,

The base has a through hole through which the rake bolt penetrates, and a plurality of teeth are formed on the upper surface of each side wall, and the teeth are detachably engageable with the teeth of the telescope rack.

A plurality of cam inclined surfaces are formed under the through hole of the base, and the plurality of cam inclined surfaces are formed with the mountain portion and the valley portion continuous with each other in the circumferential direction, and the cam plate is installed opposite the cam inclined surfaces of the base. The cam plate has a plurality of cam inclined surfaces that are in rotational contact with the cam inclined surface of the base, and the plurality of cam inclined surfaces are formed with the mountain portion and the valley portion continuously formed in the circumferential direction.

The rake lock member and the cam member are installed between the pair of side walls of the telescope lock member, and an elastic body is applied between the cam member and the telescope rack to apply an elastic force in the axial direction of the lake bolt. It is done.

The cam member has a protrusion formed on one side thereof, a circumferential surface is formed on the other surface thereof, and the circumferential surface of the cam member is rotated and supported by the telescope lock member.

The cam member is fixed in the rotational direction of the lake bolt, characterized in that configured to move in the longitudinal direction of the lake bolt.

A rake lock member is installed to be movable linearly opposite to the protrusion of the cam member, a plurality of teeth are formed at one end of the rake lock member, the head portion in contact with the protrusion of the cam member at the other end of the rake lock member And an elastic body is interposed between the head portion of the rake lock member and the telescope lock member.

The cam member and the rake lock member are configured to interlock with each other by a pin and a guide slot.

On one side wall of the telescoping bracket, a mounting groove is formed in the longitudinal direction of the steering column, and the telescope rack is mounted in the mounting groove, and a tolerance absorption plate is interposed between the mounting groove and the telescope rack. It is characterized by.

According to the present invention as described above, it is possible to easily adjust the vertical height and the inclination angle of the steering column by the rotation operation of the operating lever, and also by the telescope lock member and the rake lock member of the lock unit having a positive lock structure Since the adjusted position of the column can be maintained very firmly, there is an advantage in that the collision energy absorption performance of the airbag and the steering column can be optimally exhibited even in a vehicle crash.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 illustrate a steering column adjusting apparatus according to an embodiment of the present invention.

As shown, the steering column adjustment device of the present invention is configured to adjust the inclination angle and the vertical height of the steering column 10.

The steering column 10 extends in the longitudinal direction, and the steering shaft 11 is rotatably disposed therein, and a steering wheel (not shown) is coupled to an upper end of the steering shaft 11 and operated by a driver. .

The steering column 10 has an upper jacket 12 and a lower jacket 14 that are telescoping (movably relative to one another), the upper jacket 12 having a lock unit 100. Is installed, the lower jacket 14 is pivotally installed on the lower bracket 14a side, and the lower bracket 14a is fixed to the vehicle body side.

The lock unit 100 is configured to firmly maintain the adjusted position of the steering column 10. As shown in FIG. 2, the lock unit 100 includes a telescoping bracket 110 and a telescoping bracket 110 fixed to an upper circumferential surface of the steering column 10. rake bracket).

The telescoping bracket 110 is fixed to the steering column 10, in particular, the upper outer circumferential surface of the upper jacket 12, and a telescope slot 111 is disposed on one sidewall of the telescoping bracket 110. Elongate in the longitudinal direction of As shown in FIGS. 2 and 3, the mounting groove 113 extends in the longitudinal direction of the steering column 10 on one sidewall of the telescoping bracket 110, and the telescope rack ( 112, telescope tooth rack) is installed. A telescope rack 112 is installed in the mounting groove 113 of the telescoping bracket 110, and a tolerance absorbing plate 114 is interposed between the telescope rack 112 and the mounting groove 113. By absorbing the tolerance between the telescope rack 112 and the mounting groove 113 by the tolerance absorbing plate 114, the telescope rack 112 can be precisely mounted in the mounting groove 113. The telescope rack 112 has a plurality of teeth 112a, and the plurality of teeth 112a may be symmetrically disposed at both left and right sides of the telescope slot 111. The upper jacket 12 and the lower jacket 14 of the steering column 10 are telescoped along the telescope slot 111 and the telescope rack 112, whereby the steering column 10 can be adjusted up and down. Can be.

One side of the rake bracket 120 is installed on the frame side of the vehicle body, and one side wall of the rake bracket 120 is formed with a rake slot 121 extending in a direction orthogonal to the telescope slot 111. A rake tooth 122 is mounted below the rake slot 121, and the rake rack 122 has a plurality of teeth 122a. The rake slot 121 and the rake rack 122 are formed to be inclined at a curvature angle at a predetermined radius on the horizontal line, the steering column 10 along the rake slot 121 and the rake rack 122 of the rake bracket 120 It can be tilted, and thus the steering column 10 can be adjusted at its inclination angle.

As shown in FIG. 3, a rake bolt 130 penetrates between the telescoping bracket 110 and the rake bracket 120. A head portion 131 is formed at one end of the rake bolt 130, and an operating lever 135 is installed close to the head portion 131, and the other end of the rake bolt 130 is rake by the nut 132. It is coupled to the bracket 120 side. The rake bolt 130 may move along the telescope slot 111 and the rake slot 121 while penetrating through the telescope slot 111 and the rake slot 121 such that the steering column 10 may be telescoped or tilted. .

On the opposite side of the telescope rack 112, a telescope lock member 140 is disposed, the telescope lock member 140 has a plurality of teeth 140a, and the telescope lock member 140 The teeth 140a are configured to engage the teeth 112a of the telescope rack 112.

As shown in FIG. 10, the telescope lock member 140 has a base 141 and a pair of side walls 142 and 143 provided on both sides of the base 141. The base 141 is formed with a through hole 141a through which the brake bolt 130 penetrates, and a plurality of teeth 140a are formed on the upper surfaces of the side walls 142 and 143, respectively. Meshes with teeth 112a of telescope rack 112.

As shown in FIG. 11, a plurality of cam inclined surfaces 144 is formed below the through hole 141a of the base 141, and the plurality of cam inclined surfaces 144 are a peak portion 144a and a valley portion 144b. It is formed continuously to each other in the circumferential direction.

Cam plates 150 are disposed opposite the cam inclined surfaces 144 of the base 141, and the cam plates 150 are cam inclined surfaces 154 that are in rotational contact with the cam inclined surfaces 144 of the base 141. Are formed, and the plurality of cam inclined surfaces 154 are formed such that the peak portion 154a and the valley portion 154b are continuous to each other in the circumferential direction. The cam plate 150 is fixedly installed adjacent to the operation lever 135 of the rake bolt 130, and thus the cam plate 150 rotates together with the lever 135. As the cam inclined surfaces 154 of the cam plate 150 are in rotational contact with the cam inclined surfaces 144 of the base 141 by the rotation of the cam plate 150, the telescope lock member 140 is rake bolt 130. Can move in the axial direction of. For example, when the peak portion 154a of the cam inclined surface 154 and the peak portion 144a of the cam inclined surface 144 contact each other, the telescope lock member 140 moves toward the telescope rack 112. The teeth 140a of the telescope lock member 140 are engaged with the teeth 112a of the telescope rack 112, and the valley portion 154b of the cam inclined surface 154 and the cam inclined surface 144 as shown in FIG. 3A. The teeth 140a of the telescope lock member 140 are spaced apart from the teeth 112a of the telescope rack 122 when the peaks 144a of the.

In addition, auxiliary side walls 146 and 147 are formed on the inner side surfaces of the side walls 142 and 143, and locking jaws 146a and 147a are formed in front of the auxiliary side walls 146 and 147, respectively. The curved portions 146b and 147b are formed behind the 146 and 147. A space 145 is formed between the pair of auxiliary side walls 146 and 147, and the rake lock member 160 and the cam member 170 are installed in the space 145 as shown in FIG. 4. 3 and 6, after the rake lock member 160 and the cam member 170 are installed in the space 145 of the telescope lock member 140, the upper surface of the telescope lock member 140 is disposed on the upper surface of the telescope lock member 140. By installing the cover 149, the upper portion of the telescope lock member 140 is sealed to the outside.

The cam member 170 is coupled to one outer peripheral surface of the lake bolt 130 through the serration 133 as shown in Figure 3, the rotational force of the lake bolt 130 is transmitted to the cam member 170 to the cam The member 170 may rotate together with the lake bolt 130, and the cam member 170 may be configured to move in the longitudinal direction of the lake bolt 130.

As shown in FIG. 4, the cam member 170 has a protrusion 171 formed at one side thereof, a circumferential surface 172 is formed at the other side thereof, and a circumferential surface of the cam member 170 is formed at each auxiliary side wall. It is rotatably supported by the curved portions 146b and 147b of 146 and 147.

Meanwhile, as shown in FIG. 3, the operating lever 135, the cam plate 150, the telescope lock member 140, the cam member 170, and the telescope rack 112 in the axial direction of the lake bolt 130. ) Is installed sequentially, the elastic member 175 is installed between the cam member 170 and the telescope rack 112, the elastic member 175 is installed to apply an elastic force in the axial direction of the lake bolt (130). Accordingly, when the cam inclined surfaces 154 of the cam plate 150 and the cam inclined surfaces 144 of the telescope lock member 140 are engaged with each other to release the pressurized state of the telescope lock member 140, the restoring force of the elastic body 175 may be reduced. The teeth 140a of the telescope lock member 140 may be spaced apart from the teeth 112a of the telescope rack 112.

As shown in FIGS. 4 and 6, a rake lock member 160 is installed on the opposite side of the protrusion 171 of the cam member 170 so as to be linearly movable, and the rake lock member 160 is It is configured to move by the rotation operation of the cam member 170. The rake lock member 150 is installed on the opposite side of the rake rack 122, the rake lock member 160 has a plurality of teeth (160a) at one end thereof, and has a head portion 161 at the other end. Both edges of the head portion 161 of the rake lock member 160 are disposed adjacent to the engaging jaws 146a and 147a of the telescope lock member 140.

An elastic body 162 is interposed between the head portion 161 of the rake lock member 160 and the locking projections 146a and 147a of the telescope lock member 140, and the elastic body 162 is the rake lock member 160. It is configured to apply the elastic force in the longitudinal direction of the steering column (10). Accordingly, the rake lock member 160 may move in the longitudinal direction of the steering column 10 by the rotation of the cam member 170. For example, when the protrusion 171 of the cam member 170 presses the center portion of the head portion 161 of the rake lock member 160 as shown in FIG. 4 by the rotation of the cam member 170, the teeth of the rake lock member 160 are fixed. The 160a may be engaged with the teeth 122a of the rake rack 122, and as shown in FIG. 4A, the protrusion 171 of the cam member 170 may move toward the edge of the head portion 161 of the rake lock member 160. When moved, the rake lock member 160 returns to its original position by the restoring force of the elastic body 162, whereby the teeth 160a of the rake lock member 160 may be spaced apart from the teeth 122a of the rake rack 122. .

On the other hand, a locking groove 161a is formed on the rear surface of the center portion of the head portion 161 of the rake lock member 160, and the tip of the protrusion 171 of the cam member 170 is caught by the locking groove 161a so that the cam member is caught. The pressing operation of the rake lock member 160 by 170 may proceed very smoothly.

8 and 8A illustrate a variant embodiment of FIG. 4, whereby the rake lock member 160 and the cam member 170 are configured to interlock with each other via a pin 165 and a guide slot 163. . As shown in FIG. 8A, a groove 167 is formed in the rake lock member 160, and a protrusion 171 of the cam member 170 is inserted into the groove 167, and guide slots 163 are formed at both sides of the groove 167. ) Is formed. The protrusion 171 and the lock member 160 of the cam member 170 are connected by the pin 165, and the pin 165 is configured to slide along the guide slot 163. In response to the rotation of the cam member 170, the rake lock member 160 is approached or spaced toward the rake rack member 122 side, so the teeth 160a of the rake lock member 160 is the teeth of the rake rack member 122 ( 122a) may be engaged or spaced apart.

FIG. 9 is a diagram illustrating a modified embodiment of FIG. 6, and illustrates a configuration in which an elastic body 162 ′ and 175 ′ in the form of a leaf spring is applied instead of the elastic bodies 162 and 175 in the form of a coil spring.

The operating relationship of the present invention configured as described above will be described in detail as follows.

In FIG. 1, when adjusting the inclination angle or the up and down height of the steering column 10, the operation lever 135 is turned clockwise (that is, the release operation of the operation lever 135). By the loosening operation of the operation lever 135, the lake bolt 130, the cam plate 150 and the cam member 170 rotates together in the clockwise direction.

By clockwise rotation of the cam plate 150, the cam inclined surfaces 154 of the cam plate 150 and the cam inclined surfaces 144 of the telescope lock member 140 as shown in FIGS. 3A and 6A. The bone parts are in contact with each other, the telescope lock member 140 is moved to the cam plate 150 by the elastic force of the elastic body 175, so that the teeth (140a) of the telescope lock member 140 is telescope It is spaced apart from the teeth 112a of the rack member 112. In this state, the driver moves the upper jacket 12 of the steering column 10 up and down relative to the lower jacket 14 (that is, telescoping) so that the steering column 10 can be adjusted in its upper and lower heights. Can be.

In addition, by the clockwise rotation of the cam member 170, as shown in Figures 4a and 6a, the tip 171a of the protrusion 171 of the cam member 170 is the head portion of the rake lock member 160 (161) move to the edge side, the rake lock member 160 is moved to the cam member 170 side by the elastic force of the elastic body 162, whereby the teeth (160a) of the rake lock member 160 is the rake rack member 122 Is spaced apart from the tooth 122a. In this state, the driver can adjust the inclination angle of the steering column 10 by tilting the steering column 10 based on the pivot point of the lower bracket 14a.

When it is necessary to maintain the position of the steering column 10 in which the inclination angle or the vertical height is adjusted in this way, turn the operation lever 135 counterclockwise in FIG. 1 (locking operation of the operation lever 135). ). By the locking operation of the operation lever 135, the lake bolt 130, the cam plate 150 and the cam member 170 rotates together in the counterclockwise direction.

By counterclockwise rotation of the cam plate 150, the mountain portions 154a and the telescope lock member 140 of the cam inclined surface 154 of the cam plate 150, as shown in FIGS. 3 and 6. The valley portions 144b of the cam inclined surface 144 of the cams come into contact with each other, and the telescope lock member 140 moves toward the telescope rack member 112 while pressing the elastic body 175, and the telescope lock member 140. Teeth 140a of) are engaged with teeth 112a of the telescope rack member 112, and thus the telescope lock member 140 is coupled to the telescope rack member 112 side so that the top and bottom of the steering column 10 The position adjusted in the height direction is kept fixed.

In addition, by counterclockwise rotation of the cam member 170, as shown in FIGS. 4 and 6, the tip 171a of the protrusion 171 of the cam member 170 is the head of the rake lock member 160. The central portion of the portion 161 is pressed, and the rake lock member 160 moves to the rake rack member 122 while pressing the elastic body 162, and the teeth 160a of the rake lock member 160 are rake rack members. Meshes with tooth 122a of 122. The rake lock member 160 is coupled to the rake rack member 122, thereby maintaining a fixed inclination angle of the steering column 10 fixedly.

As such, the present invention can easily adjust the vertical height and the inclination angle of the steering column 10 by the rotation operation of the operating lever 135, and also the telescope lock member of the lock unit 100 having a positive lock structure Since the adjusted position of the steering column 10 can be maintained very firmly by the 140 and the rake lock member 160, the collision energy absorption performance of the airbag and the steering column can be optimally exhibited even during a vehicle crash. There is this.

1 is a perspective view showing a steering column control device according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view taken along the portion A-A of FIG. 1.

3 and 3a are enlarged views of arrow B of FIG. 2, and FIG. 3 shows the locking operation of the operation lever, and FIG. 3a shows the unlocking operation of the operation lever.

4 and 4A are cross-sectional views taken along the lines C-C of FIGS. 3 and 3A, and FIG. 4 shows the locking operation of the operation lever, and FIG. 4A shows the unlocking operation of the operation lever.

5 and 5A are enlarged views of the respective arrows D in FIGS. 4 and 4A, and FIG. 5 shows the locking operation of the operation lever, and FIG. 5A shows the unlocking operation of the operation lever.

6 and 6A are cross-sectional views taken along line E-E of FIGS. 4 and 4A, and FIG. 6 shows the locking operation of the operation lever, and FIG. 6A shows the unlocking operation of the operation lever.

7 and 7A are enlarged views of the respective arrows F of FIGS. 6 and 6A, and FIG. 7 shows the locking operation of the operation lever, and FIG. 7A shows the unlocking operation of the operation lever.

8 is a view showing a modified embodiment of FIG.

8A is a cross-sectional view taken along the line H-H of FIG. 8.

9 is a view showing another modified embodiment of FIG.

10 is a top perspective view of the telescope lock member of the steering column control device according to the present invention.

11 is a bottom perspective view illustrating the telescope lock member and the cam plate of the steering column adjusting device according to the present invention.

Brief description of symbols for the main parts of the drawings

10: steering column 11: steering shaft

100: lock unit 110: telescoping bracket

112: telescope rack 120: lake bracket

122: rake rack 140: telescope lock member

150: cam plate 160: rake lock member

170: cam member

Claims (9)

delete A steering column having a top jacket and a bottom jacket mounted telescopeably; A telescope rack fixed to an upper jacket of the steering column, having a telescope slot extending in a longitudinal direction of the steering column, and having a telescope rack proximate to the telescope slot, the telescope rack having a plurality of teeth Scoping brackets; A rake slot disposed to surround the telescoping bracket, having a rake slot extending in a direction orthogonal to the telescope slot, and having a rake rack proximate to the rake slot, the rake rack having a plurality of teeth ; A telescope lock member detachably engageable with said telescope rack; A rake lock member detachably engageable with the rake rack; A lake bolt installed through the lake bracket and the telescoping bracket and having an operating lever at one end thereof; A cam plate for moving the telescope lock member as it rotates with the lake bolt; And And a cam member for moving the rake lock member as it rotates with the rake bolt. The cam plate and the cam member is installed on the outer circumferential surface of the lake bolt, the cam plate and the cam member is installed to rotate together with the lake bolt, The telescope lock member has a base and a pair of side walls provided on both sides of the base, The base has a through hole through which the rake bolt penetrates, a plurality of teeth are formed on the upper surface of each side wall, the teeth can be detachably engaged with the teeth of the telescope rack steering column adjustment Device. The method of claim 2, A plurality of cam inclined surfaces are formed under the through hole of the base, and the plurality of cam inclined surfaces are formed with the mountain portion and the valley portion continuous with each other in the circumferential direction, and the cam plate is installed opposite the cam inclined surfaces of the base. And the cam plate has a plurality of cam inclined surfaces that are in rotational contact with a cam inclined surface of the base, wherein the plurality of cam inclined surfaces are formed with a mountain portion and a valley portion continuously formed in a circumferential direction. The method of claim 3, The rake lock member and the cam member are installed between the pair of side walls of the telescope lock member, and between the cam member and the telescope rack, an elastic body for applying an elastic force in the axial direction of the lake bolt is interposed. Steering column adjustment device. 5. The method of claim 4, The cam member has a protruding portion formed on one side thereof, and a circumferential surface is formed on the other surface thereof, and the circumferential surface of the cam member is rotated and supported by the telescope lock member. The method of claim 2, The cam member is fixed in the rotational direction of the lake bolt, steering column adjustment device, characterized in that configured to move in the longitudinal direction of the lake bolt. The method of claim 6, A rake lock member is installed to be movable linearly opposite to the protrusion of the cam member, a plurality of teeth are formed at one end of the rake lock member, the head portion in contact with the protrusion of the cam member at the other end of the rake lock member And an elastic body is interposed between the head portion of the rake lock member and the telescope lock member. The method of claim 6, And the cam member and the rake lock member are configured to interlock with each other by a pin and a guide slot. The method of claim 2, On one side wall of the telescoping bracket, a mounting groove is formed in the longitudinal direction of the steering column, and the telescope rack is mounted in the mounting groove, and a tolerance absorption plate is interposed between the mounting groove and the telescope rack. Steering column adjuster, characterized in that.

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