JP6119890B2 - Steering device - Google Patents

Description

The present invention relates to improvements of the steering apparatus for applying a steering angle to the steering wheel of the car. Specifically, it is a support bracket for supporting the steering column to the vehicle body those realized at low cost.

  The steering apparatus for an automobile is configured as shown in FIG. 24, and transmits the rotation of the steering wheel 1 to the input shaft 3 of the steering gear unit 2, and a pair of left and right tie rods 4 in accordance with the rotation of the input shaft 3. 4 is pushed and pulled to give a steering angle to the front wheels. The steering wheel 1 is supported and fixed at the rear end portion of the steering shaft 5, and the steering shaft 5 is rotatably supported by the steering column 6 with the cylindrical steering column 6 inserted in the axial direction. Has been. Further, the front end portion of the steering shaft 5 is connected to the rear end portion of the intermediate shaft 8 via a universal joint 7, and the front end portion of the intermediate shaft 8 is connected to the input shaft 3 via another universal joint 9. Connected to.

  With such a steering device, a tilt mechanism for adjusting the vertical position of the steering wheel 1 and a telescopic mechanism for adjusting the front-rear position according to the physique and driving posture of the driver have been widely known. ing. In order to constitute the tilt mechanism, the steering column 6 is in the width direction with respect to the vehicle body 10 (the width direction is the width direction of the vehicle body and coincides with the left-right direction. Description and claims) The same is applied to the entire range. In addition, the movable bracket fixed to the rear end portion of the steering column 6 with respect to the support bracket 12 supported by the vehicle body 10 is vertically and longitudinally (the longitudinal direction is the longitudinal direction of the vehicle body). This is the same throughout the present specification and claims). Further, in order to constitute a telescopic mechanism that enables displacement in the front-rear direction, the steering column 6 has a structure in which an outer column 13 and an inner column 14 are telescopically combined so that the steering shaft 5 can be expanded and contracted. The outer tube 15 and the inner shaft 16 are combined in a manner that allows torque transmission and expansion and contraction by spline engagement or the like. The illustrated example also incorporates an electric power steering device that reduces the force required to operate the steering wheel 1 using the electric motor 17 as an auxiliary power source. The structure of the steering device having the tilt mechanism and the telescopic mechanism as described above, and the operation method thereof are described widely in the prior art as described in Patent Documents 1 to 4, and the detailed explanation thereof is as follows. Omitted.

By the way, with the recent reduction in size and weight of vehicles, there is a demand for downsizing and weight reduction of the steering device as described above.
FIG. 25 shows the structure of the steering device described in Patent Document 4. The support bracket 12 a constituting the steering device includes a pair of intermediate bracket members 18 and 18 and a connecting plate portion 19.

Of these, the intermediate bracket members 18, 18 each have an L-shaped cross section, and the mounting plate portions 20, 20 provided at the upper portion, and these mounting plate portions 20, 20 are integrated with these mounting plate portions 20. , 20 from the inner end edge in the width direction, and support plate portions 21 and 21 provided in a state where each hangs downward. Further, notches 22 and 22 are formed in both the mounting plate portions 20 and 20 so as to open to the rear end edges of the both mounting plate portions 20 and 20. The support plate portions 21 and 21 are formed with long tilt holes 36 and 36 that are long in the vertical direction. The both intermediate bracket members 18 and 18 are arranged in a state in which the inner side surfaces in the width direction of the support plate portions 20 and 20 are opposed to each other and are separated from each other in the width direction.
The connecting plate portion 19 is a plate-like member provided separately from the intermediate bracket members 18, 18, and between the mounting plate portions 20, 20 of the intermediate bracket members 18, 18. The both end portions are joined to the inner end edges in the width direction of both the mounting plate portions 20 and 20 by welding.

  The support bracket 12a is a member fixed to the vehicle body (or to the vehicle body) via capsules 23 and 23 and bolts (not shown) assembled in the notches 22 and 22 of the mounting plate portions 20 and 20. ) Is supported. In this way, in order to alleviate the impact applied to the driver at the time of the secondary collision, the steering column 6a falls off when a large forward force is applied to the vehicle body (or a member fixed to the vehicle body). Like to support. Such a support structure for the support bracket 12a with respect to the vehicle body and the structure of the steering device in which the support bracket 12a is incorporated are described in Patent Documents 5 to 8 and the like. Since it is the same and is not the main point of this invention, detailed description is abbreviate | omitted.

In the case of the structure of the support bracket 12a constituting the steering device as described above, the size of the support bracket 12a in the width direction can be reduced to reduce the size and weight of the steering device in the width direction. That is, the support bracket 12 a forms the intermediate bracket members 18, 18, and then connects the connecting plate portion 19 to the inner end edges in the width direction of the mounting plate portions 20, 20 of the intermediate bracket members 18, 18. It is made by joining to each other by welding. For this reason, the dimension in the width direction of the connecting plate portion 19 can be appropriately set in accordance with a dimension necessary for reducing the size and weight of the steering device.
However, in the case of the support bracket 12a constituting the steering device, the intermediate bracket members 18 and 18 and the connecting plate portion 19 are provided separately. For this reason, it is disadvantageous from the viewpoint of reducing the part management cost. The intermediate bracket members 18 and 18 and the connecting plate portion 19 are connected by welding. Such welding work is cumbersome and disadvantageous from the viewpoint of reducing work costs.

JP 2001-322552 A JP 2008-302751 A JP 2008-1000059 A1 JP 2000-302048 A JP 2004-182216 A JP 2004-338509 A JP 2005-53349 A JP 2005-96731 A

  In view of the above-described circumstances, the present invention has been invented in order to realize a reduction in size and weight of a steering device at a low cost by devising a manufacturing method of a support bracket constituting the steering device. .

Scan tearing device of the present invention includes a steering column, a steering shaft, a steering wheel, a support bracket.
Of these, the steering column is supported by the vehicle body.
The steering shaft is rotatably supported inside the steering column.
The steering wheel is fixed to a portion protruding from the rear end portion of the steering column at the rear end portion of the steering shaft.
Further, the support bracket is for supporting the steering column on the vehicle body, and a pair of left and right mounting plate portions provided on the upper side, and both of the mounting plate portions from the inner side in the width direction downward. It has a pair of supporting plate parts that hang down, and a continuous part that makes these mounting plate parts continue in the width direction. Such a support bracket is supported with respect to the vehicle body by the both attachment plate portions in a state where the intermediate portion of the steering column is sandwiched from both sides in the width direction by the both support plate portions. Specifically, such a support bracket is formed by subjecting one plate-shaped material to plastic working.

In particular, if the steering device of the present invention, the upper edge of the two support plate portions is continuous in the width direction within the edges of the two mounting plate portions. On the other hand, the lower end edges of these support plate portions are free ends that are not coupled to other portions.
Further, the continuous portion is in a state of being spanned between the both mounting plate portions, and both end edges in the width direction are arranged other than the two supporting plate portions among the inner end edges of the both mounting plate portions. Consecutive parts. Such a continuous portion is provided in a state of being inclined backward as it goes from the both end edges in the width direction to the center in the width direction.
When the dimension in the width direction of each of the mounting plate parts is A, the dimension in the vertical direction of each of the support plate parts is B, and the dimension in the width direction of the support bracket is D, 2 The relationship of (A + B)> D is satisfied.

According to the steering equipment of the present invention, miniaturization of the steering apparatus, and the weight reduction can be realized at a low cost.
First, miniaturization of the steering apparatus, and weight reduction, the continuous unit elements constituting the continuous portion of the support bracket constituting a scan tearing device of the present invention, as directed from the both widthwise end edges in the width direction center, rear This can be achieved by providing it in an inclined state . That is, by adjusting the inclined state of the continuous part , the dimension in the width direction of the continuous part can be adjusted to a desired dimension necessary for the reduction in size and weight. As a result, the dimensions of the support bracket in the width direction are reduced, and the steering device can be reduced in size and weight .

The top view of the support bracket which shows the 1st example of the reference example relevant to this invention. Similarly, the figure which looked at the support bracket from the lower part of FIG. Similarly, the figure seen from the right side of FIG. The top view of an intermediate bracket material. The figure similar to FIG. 1 which shows the 2nd example of the reference example relevant to this invention. Similarly, the same figure as FIG. Similarly, the same figure as FIG. The figure similar to FIG. 1 which shows the 3rd example of the reference example relevant to this invention. Similarly, the same figure as FIG. Similarly, the same figure as FIG. The figure similar to FIG. 1 which shows the 4th example of the reference example relevant to this invention. Similarly, the same figure as FIG. Similarly, the same figure as FIG. The figure similar to FIG. 1 which shows the 5th example of the reference example relevant to this invention. Similarly, the same figure as FIG. Similarly, the same figure as FIG. It shows an example embodiment of the present invention, similar to FIG. 1. Similarly, the same figure as FIG. Similarly, the same figure as FIG. The figure similar to FIG. 1 which shows the 6th example of the reference example relevant to this invention. Similarly, the same figure as FIG. Similarly, the same figure as FIG. Similarly, the perspective view which shows the state which assembled the steering apparatus. The partial cutaway side view which shows an example of the steering device for motor vehicles incorporating a steering device. Longitudinal side view showing an example of a conventionally known steering device

[ First example of reference example related to the present invention ]
1 to 4 show a first example of a reference example related to the present invention . The feature of the present invention including this reference example is that the structure of the support bracket 12b constituting the target steering device and the manufacturing method thereof are devised. Note that, in the present reference example , a tilt mechanism for adjusting the vertical position of the steering wheel 1 (see FIG. 24) and a telescopic for adjusting the front-rear position are the same as the structure shown in FIG. It is a structure with a mechanism. However, the present invention , including this reference example, is also applicable to a steering device having a structure having only one of a tilt mechanism or a telescopic mechanism, or a structure having neither of these mechanisms. it can. Including such a tilt mechanism and a telescopic mechanism, the structure other than the features of the present reference example and the present invention, and the operation method thereof, including the structures shown in FIGS. Since it is the same as the structure of the apparatus, illustrations and explanations are omitted or simplified with respect to parts that are configured in the same manner as in the prior art, and the characteristic parts of this reference example will be mainly described below.

As in the basic structure of the support racket 12a constituting the steering device having the conventional structure shown in FIG. 25, the support bracket 12b constituting the steering device of the present reference example has a pair of mounting plate portions 24, 24, A pair of support plate portions 25, 25 and a continuous portion 26 are provided. However, in the case of this reference example, these portions 24, 25, and 26 are integrally formed by plastic processing a single metal plate-like intermediate bracket material 27 as shown in FIG. .

  Of these, the mounting plate portions 24, 24 are provided in a state of being separated in the width direction (the left-right direction in FIGS. 1-2, 4). Further, like the above-described conventional structure, the mounting plate portions 24, 24 are opened at the rear end edges thereof (lower sides of FIGS. 1 and 4, the front side of FIG. 2, the left side of FIG. 3). The notches 22 and 22 are formed. These notches 22 and 22 are for assembling the capsules 23 and 23 (see FIG. 25) as in the conventional structure described above. Also, locking pieces 28 and 28 (see FIG. 23) formed on the front end edges of the capsules 23 and 23 are locked in front of the notches 22 and 22 (upper side in FIG. 1). Locking holes 29, 29 (or locking grooves) are formed.

  Further, the both support plate portions 25, 25 are in a state in which the respective upper end edges (the front side in FIG. 1 and the upper side in FIGS. 2 and 3) are continuous with the inner end edges in the width direction of the both attachment plate portions 24, 24. Is provided. On the other hand, each lower end edge is a free end that is not continuous with any part. The reinforcing bent plate portions 30 and 30 are formed in a state of being bent outward in the width direction from the rear end edges of the support plate portions 25 and 25. The upper end edge of each of the reinforcing bent plate portions 30 and 30 is continuous with the portion near the inner end in the width direction of the rear end edges of the mounting plate portions 24 and 24.

The continuous portion 26 includes a pair of continuous portion elements 31a and 31b. The width direction both end edges of both the continuous portion elements 31a and 31b are the front end portions of the width direction inner end edges of the mounting plate portions 24 and 24 (the upper end edges of the support plate portions 25 and 25 are continuous. It is continuous to the front part). Of the continuous element elements 31a and 31b, the continuous element element 31a provided forward is provided in a state of being inclined forward as it goes from the both edges in the width direction to the inner side in the width direction (the center in the width direction). It has been. On the other hand, the continuous element 31b provided on the rear side is provided in a state of being inclined rearward from the both ends in the width direction toward the inner side in the width direction. That is, the distance between the rear side surface of the continuous element 31a and the front side surface of the continuous element 31b increases toward the inner side in the width direction. In the case of this reference example, the two continuous portion elements 31a and 31b correspond to the plastically deformed portion described in the claims.

  In the support bracket 12b, the dimension in the width direction of each of the mounting plate portions 24, 24 is A, the dimension in the vertical direction of each of the support plate portions 25, 25 is B, and the intermediate bracket material When the dimension in the width direction of 27 is C (see FIG. 4) and the dimension in the width direction of the support bracket 12b is D, the relationship of 2 (A + B)> D and C> D is satisfied.

The support bracket 12b having the above-described configuration is manufactured by the following procedure. First, on one metal plate material, by applying a punching molding by a press to form the intermediate bracket material 27. The intermediate bracket material 27 has a pair of intermediate mounting plate portions 32 and 32, a pair of intermediate support plate portions 33 and 33, and an intermediate continuous portion 34.
Of these, the intermediate attachment plate portions 32, 32 are portions that become the attachment plate portions 24, 24 of the support bracket 12b after plastic working. Of the intermediate bracket material 27, chain lines α, α in FIG. It is provided in the outer part with respect to the width direction. That is, these intermediate attachment portions 32 and 32 are provided in a state of being separated from each other in the width direction. Further, the notches 22 and 22 are formed at the rear end edges of the intermediate mounting portions 32 and 32 so as to open to the rear end edges.

Moreover, the two intermediate support plate portions 33 is a portion serving as the support plates portions 25 and 25 of the after plastic working before Ki支 lifting brackets 12b, of the intermediate bracket material 27, a chain line in FIG. 4 alpha , Α in the width direction, and in the rear part (lower part in FIG. 4) from the chain lines β, β.
Both the intermediate support plate portions 33 and 33 have outer end edges (end edges corresponding to upper end edges (upper side in FIG. 2) of the both support plate portions 25 and 25) in the respective width directions. It continues to the width direction inner end edges (positions of the chain lines α and α) of the plate portions 32 and 32. On the other hand, the inner end edge in the width direction of both the intermediate support plate portions 33, 33 (the end edge corresponding to the lower end edge of the support plate portions 25, 25 (the lower side in FIG. 2)) is a free end. That is, the inner edges of the intermediate support plate portions 33, 33 in the width direction are separated from each other in the width direction.

  The intermediate continuous portion 34 is a portion that becomes the continuous portion 26 of the support bracket 12b after plastic working, and is an inner portion of the intermediate bracket material 27 with respect to the width direction from the chain lines α and α in FIG. And it is provided in the front part (upper part of Drawing 4) rather than chain lines β and β. The intermediate continuous portion 34 is extended between the intermediate mounting plate portions 32 and 32, and both end edges in the width direction are connected to inner end edges in the width direction of the intermediate mounting plate portions 32 and 32. Among these, it is continuous with the front end portion (the portion other than where both the intermediate support plate portions 33, 33 are disposed). In addition, a slit 35 is formed in the central portion of the intermediate continuous portion 34 in the front-rear direction so as to extend over the entire length of the intermediate continuous portion 34 in the width direction. A portion of the intermediate continuous portion 34 that sandwiches the slit 35 in the front-rear direction is a pair of intermediate continuous portion elements 37 and 37. These intermediate continuous elements 37, 37 are the parts that become the continuous elements 31a, 31b after plastic working.

In the intermediate bracket material 27 configured in this way, the dimension in the width direction of each of the intermediate mounting plate portions 32, 32 is a, and the dimension in the width direction of each of the intermediate support plate portions 33, 33 is b. In this case, the relationship of 2 (a + b) <C is satisfied between the intermediate bracket material 27 and the dimension C in the width direction. In the case of this reference example, the dimension a in the width direction of each of the intermediate mounting plate portions 32, 32 is substantially equal to the dimension A in the width direction of each of the mounting plate portions 24, 24 (a≈A ). Further, the dimension b in the width direction of each of the intermediate support plate portions 33 and 33 is substantially equal to the dimension B in the vertical direction of each of the support plate portions 25 and 25 (b≈B).

After forming the intermediate bracket material 27 as described above, the support bracket 12b is formed by subjecting the intermediate bracket 27 to plastic working such as press working. Such plastic working may be performed in one process or may be performed in a plurality of processes. Below, the explanation will be given for each part subjected to the plastic working.
In order to form both the support plate portions 25, 25, the intermediate support plate portions 33, 33 are arranged with respect to the intermediate attachment plate portions 32, 32 in the width direction of both the intermediate support plate portions 33, 33. Starting from the outer edge (the part indicated by the chain line α in FIG. 4), it is bent downward at a right angle. In this way, the support plate portions 25, 25 are formed. The support plate portions 25 and 25 are formed, and the reinforcing folding plate portions 30 and 30 are also formed.

Further, in order to form the continuous portion 26, the intermediate continuous portion 34 has a dimension in the front-rear direction of the slit 35 of the intermediate continuous portion 34 (the distance between the intermediate continuous portion elements 37, 37 in the front-rear direction is increased). (It becomes large). In the case of this reference example, plastic working is performed so that the dimension of the slit 35 in the front-rear direction is the largest rhombus at the center in the width direction. In this way, the dimension in the width direction of the continuous part 26 (continuous part elements 31a, 31b) is made smaller than the dimension in the width direction of the intermediate continuous part 34 (intermediate continuous part elements 37, 37) .

In the case of this reference example, the direction in which the intermediate continuous portion 34 (intermediate continuous portion elements 37, 37) is plastically deformed is only the front-rear direction. However, it addition to such plastic working, before Killen thickness of connection portion 26 (the vertical direction or the longitudinal direction of thickness) also be dimensioned applying is such plastic working greater. If Hodokose such a plastic working, the dimension in the width direction before Killen connection part 26, can be reduced more effectively.
After performing the plastic processing as described above, the mounting plate portions 24, 24 or the support plate portions 25, 25 are subjected to punching processing, cutting processing, or the like to form the insertion holes (for example, the locking holes). Holes 29, 29, a long slot 36 for tilting, etc.). In the above-described plastic working, if there is no possibility that the insertion holes are distorted, the insertion holes can be formed at the stage of the intermediate bracket material 27.

According to the steering device of this reference example as described above, the steering device can be reduced in size and weight at low cost.
First, the steering device can be reduced in size and weight by reducing the size of the continuous portion 26 of the support bracket 12b constituting the steering device in the width direction. That is, in the case of the present reference example, when the intermediate bracket material 27 is plastically processed to form the support bracket 12b, the dimensions in the width direction of the continuous portion 26 are necessary for size reduction and weight reduction. Can be plastically deformed to the required dimensions. As a result, the dimensions of the support bracket 12b in the width direction are reduced, and the steering device can be reduced in size and weight.

Further, the reason that it can be realized at low cost is that the support bracket 12b is integrally formed by plastic processing the intermediate bracket material 27 made of a single plate-shaped material.
That is, in the case of this reference example , both the mounting plate portions 24, 24, both the supporting plate portions 25, 25, and the continuous portion 26 are integrally formed (without welding). Therefore, as in the conventional structure described above, the pair of intermediate bracket members 18 and 18 and the continuous plate portion 19 constituting the mounting plate portions 20 and 20 (see FIG. 25) and the support plate portions 21 and 21 are separated from each other. Compared with the structure of the support bracket 12a provided in (5), in addition to suppressing the part management cost, productivity can be improved. In addition, since troublesome work such as welding is unnecessary, work costs can be reduced. As a result, the manufacturing cost of the support bracket 12b and hence the manufacturing cost of the steering device can be suppressed.

[Second example of reference example related to the present invention ]
5-7 has shown the 2nd example of the reference example relevant to this invention . The continuous portion 26a of the support bracket 12c constituting the steering device of the present reference example includes an intermediate continuous portion 34 (intermediate continuous portion element 37, the same as the first embodiment of the reference example described above) of the intermediate bracket material 27 (see FIG. 4). 37) is formed by plastic deformation not only in the front-rear direction but also upward. The structure (plastic deformation state) of the support bracket 12c other than the continuous portion 26a is the same as that of the first example of the reference example described above.

That is, among the pair of continuous element elements 38a and 38b constituting the continuous part 26a, the continuous element 38a arranged in the front direction has a portion closer to the center from both outer ends in the width direction as it goes inward in the width direction. The pair of inclined portions 39a and 39a are inclined obliquely forward and upward. Further, the portion closer to the center in the width direction is a flat portion 40a which is inclined only forward as it goes inward in the width direction and does not change in the vertical direction.
On the other hand, the continuous element 38b arranged on the rear side has a pair of inclined portions 39b and 39b that are inclined obliquely rearward and upward toward the inner side in the width direction from the outer end in the width direction toward the center. In addition, the portion closer to the center in the width direction is a flat portion 40b that is inclined only backward as it goes inward in the width direction and does not change in the vertical direction.

In the steering apparatus of this reference example, the intermediate continuous portion 34 (continuous portion elements 38a and 38b) is plastically deformed upward in addition to the front-rear direction to form the continuous portion 26a. For this reason, the dimension regarding the width direction of the said intermediate | middle continuous part 34 (continuous part element 38a, 38b) can be made small effectively. As a result, it is possible to reduce the size of the support bracket 12c in the width direction, and further reduce the size and weight of the entire steering apparatus.
This reference example can be applied to the structure of a steering device in which no member that interferes with the continuous portion 26a exists above the continuous portion 26a in the assembled state.
In the case of this reference example, the intermediate continuous portion 34 (continuous portion elements 38a, 38b) is plastically deformed upward. However, in the assembled state, the intermediate continuous portion 34 (continuous portion elements 38a, 38b) is moved downward so as not to interfere with a member {for example, the steering column 6a (see FIG. 25)} existing below the continuous portion 26a. The continuous portion can also be formed by plastic deformation. Other structures, operations and effects are the same as those of the first example of the reference example described above .

[Third example of reference example related to the present invention ]
8 to 10 show a third example of the reference example related to the present invention . In the case of the support bracket 12d constituting the steering device of the present reference example, the pair of continuous portion elements 31c and 31d constituting the continuous portion 26b are directed from the respective widthwise outer ends toward the widthwise inner side (widthwise center). As shown, the dimension in the front-rear direction is increased. The other structure of the support bracket 12d including the direction of plastic deformation of the continuous portion 26b (continuous portion elements 31c and 31d) is the same as that of the second example of the reference example described above.

Further, in order to manufacture the support bracket 12d as described above, the width in the front-rear direction increases toward the inner side in the width direction (the center in the width direction) at the center portion in the front-rear direction of the intermediate continuous portion 34a of the intermediate bracket material 27a. A slit 35a is formed.
Further, in the intermediate continuous portion 34a, the pair of intermediate continuous portion elements 41a and 41b existing in the front-rear direction of the slit 35a are in a state where the thickness in the front-rear direction increases as going toward the center in the width direction. Forming. The other structures of the intermediate bracket material 27a are the same as those of the reference examples described above.

The support bracket 12d is formed by subjecting the intermediate bracket material 27a to plastic working by the same method as in the second example of the reference example described above.
In the steering apparatus of this reference example, the slit 35a is formed in the state as described above. For this reason, the intermediate continuous portion 34a (intermediate continuous portion elements 41a and 41b) is easily plastically deformed into a diamond shape. Other structures, operations and effects are the same as those of the first example of the reference example described above.

[Fourth Reference Example Related to the Present Invention ]
FIGS. 11-13 has shown the 4th example of the reference example relevant to this invention . In the case of the support bracket 12e constituting the steering device of this reference example, the width direction both ends and the width of the rear side surface of the front continuous element 31e among the pair of continuous elements 31e, 31f constituting the continuous part 26c. Notches 43a and 43a are formed at the center in the direction. On the other hand, notches 43b and 43b are formed at both ends in the width direction and at the center in the width direction of the front side surface of the rear continuous element 31f. The structure of other portions of the support bracket 12e is the same as that of the second example of the reference example described above.

Further, in order to manufacture the support bracket 12e as described above, the slit 35b formed in the intermediate continuous portion 34b of the intermediate bracket material 27b is used as an inner side surface in the front-rear direction of the slit 35b (the rear side surface of the intermediate continuous portion element 42a described later). And the front side surface of the intermediate continuous element 42b are in close proximity to each other over the entire length in the width direction.
Further, the notches 43a and 43a are formed at both end portions in the width direction and the center portion in the width direction of the rear side surface of the intermediate continuous portion element 42a on the front side of the slit 35b in the intermediate continuous portion 34b. . On the other hand, the respective 43b and 43b are formed at both ends in the width direction and at the center in the width direction of the front side surface of the intermediate continuous portion element 42b on the rear side of the slit 35b. The other structures of the intermediate bracket material 27b are the same as those of the reference examples described above.

Such an intermediate bracket material 27b is formed by punching or the like on one metal plate-like member to form portions other than the slit 35b and the notches 43a and 43b, and then using a cutter, a drill, or the like. The slit 35b and the notches 43a and 43b are formed by cutting. The slit 35b and the notches 43a and 43b can be formed simultaneously with the punching.
The method of forming the support bracket 12e by plastic processing the intermediate bracket material 27b includes the above-mentioned reference including the direction in which the intermediate continuous portion 34b (intermediate continuous portion elements 42a and 42b) is plastically deformed. This is the same as the second example.

In the case of such a steering apparatus of this reference example, the dimension of the slit 35b in the front-rear direction is reduced. Therefore, the two intermediate successive section elements 42a constituting the intermediate continuous portion 34b, the dimensions for the longitudinal direction of the 42b, the first example of the reference example described above, similarly to the intermediate successive portions element 37, 37 of the second example Even in the case of ensuring, the dimension in the front-rear direction of the entire intermediate continuous portion 34b can be reduced. As a result, the size in the front-rear direction of both mounting plate portions 24, 24 of the intermediate bracket material 27b can be reduced, so that the support bracket 12e can be reduced in size, and the steering device as a whole can be reduced in size and weight.

Even when the dimensions of the intermediate continuous part 34b in the front-rear direction are the same as those of the intermediate continuous part 34 of the first example and the second example of the reference example described above, the front-rear direction of the intermediate continuous part elements 42a, 42b. The dimension relating to the first and second examples of the reference example described above can be ensured larger than the dimension relating to the front-rear direction of each of the intermediate continuous portion elements 37 and 37 of the second example. For this reason, the rigidity of the continuous portion 26c (continuous portion elements 31e and 31f) of the support bracket 12e can be increased.

The notches 43a and 43b are formed in the intermediate continuous element 42a and 42b (continuous element 31e and 31f). For this reason, when plastic working is performed on the intermediate continuous portion 34b, the portion where the notches 43a and 43b are formed becomes the starting point of plastic deformation, and the dimensional accuracy after plastic deformation can be stabilized. Other structures, functions and effects are the same as those of the second example of the reference example described above .

[Fifth example of reference example related to the present invention ]
14-16 has shown the 5th example of the reference example relevant to this invention . If the support bracket 12f constituting the steering apparatus of the present embodiment, the continuous section element 31g which constitutes the continuous unit 26 d, of 31h, continuous dimension W _1, the rear about the longitudinal direction of the front of the continuous section element 31g It is greater than the dimension _{W 2} about the longitudinal direction of the section element _{31h (W 1> W 2)} . Further, notches 43a and 43a are formed at both end portions in the width direction of the rear side surface of the continuous portion element 31g as in the fourth example of the reference example described above. On the other hand, notches 43b and 43b are formed at both ends in the width direction of the front side surface of the continuous element 31h. In addition, a notch can be provided in the center in the width direction on the rear side of the continuous element 31g or in the center in the width direction on the front side of the continuous element 31h. In particular, if a notch is provided in the center in the width direction of the rear side surface of the continuous element 31g having a large dimension in the front-rear direction, the processing force during plastic processing can be suppressed. The other structure of the support bracket 12f is the same as that of the second example of the reference example described above.

Further, in order to manufacture the support bracket 12f as described above, a slit extending over the entire length in the width direction of the intermediate continuous portion 34c is formed in a portion closer to the rear than the center position in the front-rear direction of the intermediate continuous portion 34c of the intermediate bracket material 27c. 35c is formed. That is, in the present reference example, of the intermediate continuous portion 34c, an intermediate continuous section dimension w ₁ about the longitudinal direction of the intermediate continuous section element 44a is, which have the same position on the rear side located in front side of the slit 35c It is larger than the dimension w _{2 in} the front-rear direction of the element 44b (w ₁ > w ₂ ). The intermediate bracket material 27c is formed by punching or the like on one metal plate-like member to form a portion other than the slit 35c, as in the fourth example of the reference example described above. It is formed by cutting with a cutter or the like. The slit 35c can be formed at the same time as the punching. The other structures of the intermediate bracket material 27c are the same as those of the reference examples described above.
Further, the method of forming the support bracket 12f by plastic processing such an intermediate bracket material 27c is the same as the second example of the reference example described above including the direction in which the intermediate continuous portion 34c is plastically deformed. is there.

In the case of such a steering device of this reference example, the continuous element elements 31g, 31h (intermediate continuous element elements 44a, 44a) constituting the continuous part 26d (intermediate continuous part 34c) of the support bracket 12f (intermediate bracket material 27c). 44b), the dimension W ₁ (w ₁ ) in the front-rear direction of the front-side continuous element 31g (intermediate continuous element 44a) is made larger than those of the reference examples described above. For this reason, the rigidity regarding the front-back direction of the said continuous part element 31g (intermediate continuous part element 44a) can be enlarged. As a result, the impact generated when the support bracket 12f is displaced forward by a secondary collision and interferes with other members existing around the support bracket 12f is absorbed by the continuous element 31g of the continuous part 26d. I can do it. The position of the slit 35c in the front-rear direction (the dimension W _{1 in} the front-rear direction of the continuous element 31g) can be appropriately set in consideration of the degree of the impact absorption effect as described above. Other structures, functions and effects are the same as those of the second example of the reference example described above .

[1 Example Embodiment
Figure 17-19 shows one example of an embodiment of the present invention. In the case of the support bracket 12g constituting the steering device of this example, the continuous portion 26e has a pair of inclined portions 39c inclined obliquely rearward and upward toward the inner side in the width direction from the outer ends in the width direction toward the inner side in the width direction. 39c. In addition, the portion closer to the center in the width direction is a flat portion 40c that is inclined only backward as it goes inward in the width direction and does not change in the vertical direction. Further, a notch 45 is formed at the center in the width direction of the rear side surface of the continuous portion 26e. The other structure of the support bracket 12g is the same as that of the second example of the reference example described above.

Further, in order to manufacture the support bracket 12g as described above, the slits 35 to 35c as in the above examples of the reference example are not formed in the intermediate continuous portion 34d of the intermediate bracket material 27d. Further, the intermediate continuous portion 34d is slightly inclined rearward from the outer ends in the width direction toward the inner side in the width direction (the center in the width direction). Further, a notch 45 is formed in the center portion in the width direction of the rear end edge of the intermediate continuous portion 34d. In addition to the cutout 45, a cutout can be provided at the center in the width direction of the front end edge of the intermediate continuous portion 34d. The other structures of the intermediate bracket material 27d are the same as those of the reference examples described above.

In the case of this example, the intermediate continuous portion 34d of the intermediate bracket material 27d is divided into a portion existing on one side in the width direction (left side in FIG. 19) of the intermediate continuous portion 34d and the other in the width direction ( The angle θ formed with the portion existing on the right side of FIG. 19 is plastically deformed in the direction of decreasing (reversely plastically deformed), and the intermediate continuous portion 34d is moved upward as in the second example of the reference example described above. Also plastically deform.

In the case of the steering device of this example configured by the support bracket 12g as described above, the intermediate continuous portion 34d is plastically deformed only rearward in the front-rear direction. Therefore, the continuous portion 26e of the support bracket 12g does not protrude forward from the front end edges of the mounting plate portions 24, 24, and the continuous portion 26e is positioned in front of the support bracket 12g at the time of a secondary collision. It is possible to prevent interference with existing members. As a result, the collapse stroke at the time of the secondary collision {the amount by which the entire length of the steering column (see FIG. 24) can be contracted when the secondary collision occurs (the amount by which the outer column 13 and the inner column 14 can be relatively displaced in the axial direction) } Is easy to secure. Other structures, functions and effects are the same as those of the second example of the reference example described above .

[ Sixth Reference Example Related to the Present Invention ]
20 to 23 show a sixth example of the reference example related to the present invention . In the case of the support bracket 12h constituting the steering device of this reference example, the continuous portion 26f is provided in a state of being plastically deformed only upward.
That is, the continuous portion 26f is formed as a pair of inclined portions 39d and 39d that are inclined upward toward the inner side in the width direction from the outer ends in the width direction toward the center. These both inclined portions 39d and 39d are not inclined in the front-rear direction. Further, the central portion in the width direction is a flat portion 40d that does not change in the front-rear direction and the up-down direction. The other structure of the support bracket 12h is the same as that of the second example of the reference example described above.

In order to manufacture the support bracket 12h as described above, the slits 35 to 35c as in the first to fifth examples of the reference example described above are not formed in the intermediate continuous portion 34e of the intermediate bracket material 27e. The intermediate continuous portion 34e is not inclined with respect to the front-rear direction. The other structures of the intermediate bracket material 34e are the same as those of the reference examples described above.
In the case of this reference example, the intermediate continuous portion 34e of the intermediate bracket material 27e is not plastically deformed in the front-rear direction, but is plastically deformed only upward to form the continuous portion 26f of the support bracket 12h.

In the case of such a steering apparatus of this reference example, as shown in FIG. 23, it is possible to prevent interference with a member such as a housing 46 that supports the electric motor 17 and exists in front of the support bracket 12h. Although FIG. 23 shows the structure of the steering device of this reference example, it can be replaced with the support bracket 12g constituting the steering device of the first example of the embodiment described above. Further, when there is a space between the housing 46 and the front end edge of the support bracket, it is placed with the support brackets 12b to 12f constituting the steering devices of the first to fifth examples of the reference example described above. It can also be changed. The other structure of the steering device shown in FIG. 23 is the same as that of the steering device having the conventional structure described above, and a detailed description thereof will be omitted.

Each example of the reference example described above and one example of the embodiment are provided with a tilt mechanism for adjusting the vertical position of the steering wheel in addition to the telescopic mechanism for adjusting the front-rear position of the steering wheel. I explained the device. However, each example of the reference example described above and the present invention can also be applied to a steering device having a structure including only one of a telescopic mechanism and a tilt mechanism, or a structure not including both mechanisms. .

DESCRIPTION OF SYMBOLS 1 Steering wheel 2 Steering gear unit 3 Input shaft 4 Tie rod 5 Steering shaft 6, 6a Steering column 7 Universal joint 8 Intermediate shaft 9 Universal joint 10 Car body 11 Axis 12, 12a, 12b, 12c, 12d, 12e, 12f, 12g, 12h Support bracket 13 Outer column 14 Inner column 15 Outer tube 16 Inner shaft 17 Electric motor 18 Intermediate bracket member 19 Connecting plate portion 20 Mounting plate portion 21 Support plate portion 22 Notch 23 Capsule 24 Mounting plate portion 25 Support plate portions 26, 26a, 26b, 26c, 26d, 26e, 26f Continuous portion 27, 27a, 27b, 27c, 27d, 27e Intermediate bracket material 28 Locking piece 29 Locking hole 30 Reinforcement bent plate portion 31a, 31b, 31c, 31 , 31e, 31f, 31g, 31h Continuous element 32 Intermediate mounting plate part 33 Intermediate support plate part 34, 34a, 34b, 34c, 34d, 34e Intermediate continuous part 35, 35a, 35b, 35c Slit 36 Tilting long hole 37 Intermediate Continuous element 38a, 38b Continuous element 39a, 39b, 39c, 39d Inclined part 40a, 40b, 40c, 40d Flat part 41a, 41b Intermediate continuous element 42a, 42b Intermediate continuous element 43a, 43b Notch 44a, 44b Intermediate Continuous element 45 Notch 46 Housing

Claims (1)

Equipped and vinegar tearing column, and a support bracket for supporting the previous Symbol steering column on the vehicle body,
Support bracket of this, a mounting plate portion of the pair provided at the upper portion so as to direct the width direction of the own in the width direction of the vehicle body, their respective the width direction in the edge of both the mounting plate portion below a 1 and a support plate portion of the pair provided on so that Taresaga towards, and a continuous portion that Oite consolidated these two mounting plate portions in the width direction of the vehicle body, said these two support plate portions in a state sandwiching the steering Kola beam from both sides in the width direction of the vehicle body, said a steering device is intended to be supported against the vehicle body by two mounting plate portions,
The two support plate portions, each upper edge, wherein with has led to the width direction in the edge of the two mounting plate portions, are each a lower edge free end,
Wherein among the widthwise inner edge of the two mounting plate portions, said and portions other than the two support plate portions are disposed portions are connected by the continuous unit, the continuous unit may widthwise center from both widthwise end edges more towards the, is inclined to go to the rear,
The dimension in the width direction of each of the mounting plate parts is A,
The dimension regarding the up-and-down direction of each of the both support plate portions is B,
When the dimension in the width direction of the support bracket is D,
A steering device characterized by satisfying a relationship of 2 (A + B)> D.

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