JP2012106575A - Steering column support device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve a structure that facilitates tuning for allowing a steering wheel to be stably displaced forward during a secondary collision and prevents the side edges of a locking capsule from being strongly pressed against the side edges of a locking notch of a vehicle-body-side bracket regardless of a direction in which the locking capsule is pushed during a secondary collision.SOLUTION: A steering column support device is configured as follows. Both right and left side edges of a part, with which a locking capsule 47b is engaged at least before the occurrence of a secondary collision, of a locking notch 45a are inclined in directions opposite to each other with respect to the center line of the locking notch 45a and in a direction in which the width dimension regarding the right and left direction of the locking notch 45a is gradually increased as going forward.

Description

  In this invention, the steering column is displaced forward with respect to the vehicle body so as to enable the forward displacement of the steering wheel while absorbing the impact energy applied to the steering wheel from the driver's body in the event of a collision. The present invention relates to an improvement of a support device for a steering column for supporting the vehicle.

[Conventional technology]
The automobile steering device is configured as shown in FIG. 15, 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. The intermediate shaft 8 is configured such that torque can be transmitted and the entire length can be contracted by an impact load. In the event of a collision accident (in the case of a primary collision described below), the steering wheel 1 is displaced rearward via the steering shaft 5 regardless of the rearward displacement of the steering gear unit 2 ( It is configured so that it can be prevented from being pushed up toward the driver's body.

  In order to protect the driver, it is necessary for the above-described automobile steering device to have a structure that displaces the steering wheel 1 while absorbing impact energy in the event of a collision. That is, in the event of a collision accident, a secondary collision in which the driver's body collides with the steering wheel 1 occurs following a primary collision in which the automobile collides with another automobile or the like. In order to alleviate the impact applied to the driver's body during the secondary collision and to protect the driver, the steering column 6 supporting the steering wheel 1 is associated with the vehicle body with the secondary collision. An energy absorbing member that absorbs the impact load by plastic deformation may be provided between the vehicle body and the portion that displaces forward together with the steering column 6 while being supported so as to be detachable forward by an impact load forward. For example, as described in Patent Documents 1 to 3 and the like, it is conventionally known and widely implemented.

  FIGS. 16 to 18 show an example of a conventional steering apparatus (which is not publicly known but is basically not different from the related art in relation to the present invention). A housing 10 that houses a reduction gear or the like constituting the electric power steering device is fixed to the front end portion of the steering column 6a. A steering shaft 5a is supported on the inner side of the steering column 6a so as to be rotatable only. A portion of the steering shaft 5a protruding from the rear end opening of the steering column 6a at the rear end portion of the steering shaft 5a (See FIG. 15). The steering column 6a and the housing 10 are subjected to an impact load directed forward with respect to the vehicle body side bracket 11 (for example, see FIG. 25 showing the structure according to the prior invention described later) which is a portion fixed to the vehicle body. Based on this, it supports to be able to move forward.

  For this purpose, the column side bracket 12 supported on the intermediate portion of the steering column 6a and the housing side bracket 13 supported on the housing 10 are both separated forward by an impact load directed forward. Supports against. Each of the brackets 12 and 13 is provided with one or two mounting plate portions 14a and 14b, and the mounting plate portions 14a and 14b are respectively formed with notches 15a and 15b that open to the rear edge side. Yes. Then, sliding plates 16a and 16b are assembled to the left and right end portions of the brackets 12 and 13 so as to cover the notches 15a and 15b.

  Each of these sliding plates 16a and 16b is a metal such as a carbon steel plate or a stainless steel plate, on which a slippery synthetic resin layer such as polyamide resin (nylon) or polytetrafluoroethylene resin (PTFE) is formed on the surface. By bending the thin plate, the rear end edges of the upper and lower plate portions are connected to each other by a connecting plate portion, thereby forming a generally U-shape. And the through-hole for inserting a volt | bolt or a stud is formed in the part which mutually aligns each upper and lower plate part. In a state where the sliding plates 16a and 16b are mounted on the mounting plate portions 14a and 14b, the through holes are aligned with the notches 15a and 15b formed in the mounting plate portions 14a and 14b, respectively. To do.

  The brackets 12 and 13 are tightened by screwing bolts or studs and nuts inserted through the notches 15a and 15b of the mounting plate portions 14a and 14b and the through holes of the sliding plates 16a and 16b. To support the vehicle body side bracket 11. At the time of a secondary collision, the bolts or studs are pulled out from the notches 15a and 15b together with the slide plates 16a and 16b, and the steering column 6a and the housing 10 are moved together with the brackets 11 and 12 and the steering wheel 1. Allow displacement forward.

  Further, in the illustrated example, energy absorbing members 17 and 17 are provided between the bolt or stud and the column side bracket 12. As the column side bracket 12 is displaced forward, the energy absorbing members 17 and 17 are plastically deformed, and the column side bracket is moved from the steering wheel 1 through the steering shaft 5a and the steering column 6a. The impact energy transmitted to 12 is absorbed.

  At the time of a secondary collision, the bolts or studs are pulled out of the notches 15a and 15a to allow the column side bracket 12 to be displaced forward as shown in FIG. The steering column 6 a is displaced forward together with the column side bracket 12. At this time, the housing side bracket 13 is also detached from the vehicle body, and the housing side bracket 13 is allowed to be displaced forward. As the column side bracket 12 is displaced forward, the energy absorbing members 17 and 17 are plastically deformed, and from the driver's body via the steering shaft 5a and the steering column 6a, the column side The impact energy transmitted to the bracket 12 is absorbed, and the impact applied to the driver's body is reduced.

  In the conventional structure shown in FIGS. 16 to 18 described above, the column side bracket 12 is supported to the vehicle body side bracket 11 at two positions on both the left and right sides so that the column side bracket 12 can be detached forward during a secondary collision. . Therefore, at the time of a secondary collision, it is possible to disengage the pair of left and right support portions at the same time, making the steering wheel 1 forward and stable (without tilting in the state of the moment of occurrence of the secondary collision). It becomes important from the surface to be displaced. On the other hand, the tuning for simultaneously disengaging the two support portions is the resistance against the disengagement of both the support portions (friction resistance, shear resistance, etc.) and the inertia of the portion displaced forward together with the steering column 6a. Since there is an influence such as left and right imbalance regarding the mass, it is a laborious work.

  Adopting the structure described in Patent Document 1 is effective in eliminating the factor that destabilizes the forward disengagement due to such a cause. 19 to 21 show a conventional structure described in Patent Document 1. FIG. In the case of this conventional structure, a locking notch 18 is provided at the center in the width direction of the vehicle body side bracket 11a that is supported and fixed to the vehicle body side and does not displace forward during a secondary collision. It forms in the state which the front-end edge side of this opens. Further, the column side bracket 12a is supported and fixed on the steering column 6b side, and the column side bracket 12a can be displaced forward together with the steering column 6b at the time of a secondary collision.

  Further, the left and right end portions of the locking capsule 19 fixed to the column side bracket 12 a are locked to the locking notch 18. That is, the locking grooves 20 and 20 formed on the left and right side surfaces of the locking capsule 19 are engaged with the left and right side edges of the locking notch 18, respectively. Accordingly, the portions present on the upper and lower sides of the locking grooves 20 and 20 at the left and right end portions of the locking capsule 19 are located on both sides of the locking notch 18 and above the vehicle body side bracket 11a. Yes. The vehicle body side bracket 11a and the locking capsule 19 are portions in which both the members 11a and 19 are aligned with each other in a state where the both locking grooves 20 and 20 are engaged with both side edges of the notch 19. The locking pins 21 and 22 (shown only in FIG. 21) are press-fitted into the locking holes 21a and 21b formed in the above. Each of the locking pins 22 and 22 is made of a relatively soft material such as an aluminum alloy or a synthetic resin that is torn by an impact load applied at the time of a secondary collision.

When a forward impact load is applied to the locking capsule 19 from the steering column 6b through the column side bracket 12a during the secondary collision, the locking pins 22 and 22 are torn. Then, the locking capsule 19 is allowed to move forward from the locking notch 18, and the steering column 6b (and the steering wheel supported by the steering column 6b via the steering shaft) is allowed to displace forward. To do.
In the case of the conventional structure shown in FIGS. 19 to 21 described above, there is only one engagement portion between the locking capsule 19 fixed to the column side bracket 12a and the vehicle body side bracket 11a at the center portion in the width direction. For this reason, it is easy to perform tuning for removing the engaging portion at the time of a secondary collision and stably displacing the steering wheel forward.

[Technology related to the prior invention]
Furthermore, the present inventors have invented a steering column support device as shown in FIGS. 22 to 26 as an improved structure of the above-described conventional structure in order to enhance the protection of the driver at the time of a secondary collision. . The present invention is an improvement of the steering column support device according to the present invention, and has much in common with the structure according to the prior invention. First, the structure according to the prior invention will be described with reference to FIGS. .

  22 to 26 show a tilt / telescopic steering device having both a tilt mechanism for adjusting the vertical position of the steering wheel 1 (see FIG. 15) and a telescopic mechanism for adjusting the front / rear position. The case where the prior invention is applied is shown. In order to constitute the telescopic mechanism, the steering column 6c has a telescopic shape in which the rear part of the front inner column 23 is fitted into the front part of the rear outer column 24 so that the entire length can be expanded and contracted. Is used. A steering shaft 5b is rotatably supported on the inner diameter side of the steering column 6c.

  The steering shaft 5b has a spline engagement between a male spline portion provided at the rear portion of a circular inner shaft disposed on the front side and a female spline portion provided at the front portion of a circular outer shaft 25 disposed on the rear side. By combining them, it is possible to transmit torque and to expand and contract. The outer shaft 25 has a single-row deep groove ball bearing 26 and the like on the inner diameter side of the outer column 24 with a rear end projecting rearward from the rear end opening of the outer column 24. Only the rotation is supported by the bearing that can support the load. The steering wheel 1 is supported and fixed to the rear end portion of the outer shaft 25. When adjusting the front-rear position of the steering wheel 1, the outer column 24 is displaced in the front-rear direction together with the outer shaft 25, and the steering shaft 5b and the steering column 6c expand and contract.

  Further, a housing 10a for housing a reduction gear or the like constituting the electric power steering device is coupled and fixed to a front end portion of the steering column 6c (the inner column 23 constituting the steering column 6c). An electric motor 27 serving as an auxiliary power source of the electric power steering device and a controller 28 for controlling energization of the electric motor 27 are supported and fixed on the upper surface of the housing 10a. And in order to comprise the said tilt mechanism, the said housing 10a is supported with respect to the vehicle body so that rocking displacement centering on a horizontal axis is possible. For this reason, in the case of this example, a support cylinder 29 is provided in the left-right direction at the upper front end of the housing 10a. The horizontal axis such as a bolt inserted into the center hole 30 of the support cylinder 29 enables the front end of the steering column 6c to swing with respect to the vehicle body in the direction in which the rear portion of the steering column 6c is raised and lowered. The supporting structure is adopted.

  Further, the inner diameter of the front half portion of the outer column 24 constituting the intermediate portion or the rear portion of the steering column 6c can be elastically expanded / contracted. For this purpose, a slit 31 is formed in the axial direction on the lower surface of the outer column 24. The front end portion of the slit 31 is opened in a circumferential through hole formed in a portion excluding the front end edge of the outer column 24 or the upper end portion of the outer column 24 near the front end. Further, a pair of supported plate portions 32, 32 each having a thick flat plate shape are provided at a portion sandwiching the slit 31 from both sides in the width direction. Both of the supported plate portions 32 and 32 function as a displacement side bracket that is displaced together with the outer column 24 when the position of the steering wheel 1 is adjusted.

  In the case of the structure according to the illustrated prior invention, both the supported plate portions 32 and 32 are supported with respect to the column side bracket 33 so that the vertical position and the front and rear position can be adjusted. The column-side bracket 33 is normally supported by the vehicle body. However, in the event of a collision, the column-side bracket 33 disengages forward based on the impact of the secondary collision and allows the outer column 24 to be displaced forward. I try to do it. For this reason, the column side bracket 33 is supported to the vehicle body side bracket 11 so as to be able to be detached forward by an impact load applied during a secondary collision.

  In a state where the steering wheel 1 is held at the adjusted position, the supported plate portions 32 and 32 are strongly clamped by a pair of left and right support plate portions 34 and 34 constituting the column side bracket 33. ing. These support plate portions 34, 34 have partial circular arc-shaped elongated holes 35 centering on the horizontal axis that supports the support cylinder 29 with respect to the vehicle body, and both of the supported plate portions 32, 32. A longitudinally long hole 36 that is long in the axial direction of the outer column 24 is formed. The adjustment rod 37 is inserted through each of the long holes 35 and 36. The head portion 38 provided at the base end portion (the right end portion in FIG. 23) of the adjusting rod 37 is formed in the vertical direction long hole formed in one support plate portion 34 (the right side in FIG. 23). Only the displacement along the axis can be engaged (in a state where rotation is prevented). On the other hand, between the nut 39 screwed to the tip end portion (left end portion in FIG. 23) of the adjusting rod 37 and the outer side surface of the other support plate portion 34 (left side in FIG. 23), the driving cam A cam device 42 composed of 40 and a driven cam 41 is provided. Of these, the driving cam 40 can be driven to rotate by the adjusting lever 43.

  When the position of the steering wheel 1 is adjusted, the driving cam 40 is rotationally driven by rotating the adjusting lever 43 in a predetermined direction (downward), thereby reducing the axial dimension of the cam device 42. And the space | interval of the mutually opposing inner surfaces of the said drive side cam 41 and the said head 38 is expanded, and both the said support plate parts 34 and 34 hold down the said both supported plate parts 32 and 32. FIG. Release power. At the same time, the inner diameter of the portion where the rear portion of the inner column 23 is fitted is elastically expanded at the front portion of the outer column 24, and the front inner peripheral surface of the outer column 24 and the rear outer peripheral surface of the inner column 23 are in contact with each other. The surface pressure acting on the part is reduced. In this state, the vertical position and the front / rear position of the steering wheel 1 can be adjusted within a range in which the adjustment rod 37 can be displaced inside the vertical slot 35 and the longitudinal slot 36.

  After the steering wheel 1 is moved to a desired position, the axial dimension of the cam device 42 is expanded by rotating the adjustment lever 43 in the direction opposite to the predetermined direction (upward). Thereby, the space | interval of the mutually opposing inner surface of the said driven cam 41 and the said head 38 is shrunk | reduced, and the said both supported plate parts 32 and 32 are strongly suppressed by the said both supported plate parts 34 and 34. . At the same time, the inner diameter of the portion of the front portion of the outer column 24 where the rear portion of the inner column 23 is fitted is elastically reduced, and the front inner peripheral surface of the outer column 24 and the rear outer peripheral surface of the inner column 23 are in contact with each other. Increase the surface pressure acting on the part. In this state, the vertical position and front / rear position of the steering wheel 1 are held at the adjusted positions.

  In the case of this example, in order to increase the holding force for holding the steering wheel 1 in the adjusted position, the inner side surfaces of the both support plate portions 34 and 34 and the both supported plate portions 32 are used. , 32 are sandwiched between the friction plate units 44, 44, respectively. These friction plate units 44, 44 each have one or more first friction plates formed with a long hole that matches the vertical long hole 35 and a long hole that matches the long front hole 36. Or a plurality of second friction plates alternately stacked, and has a role of increasing the friction area and increasing the holding force. Such a specific structure and operation of the friction plate units 44, 44 are conventionally known, for example, as described in Patent Documents 4 to 5, and are not related to the gist of the present invention and the present invention. Therefore, detailed illustration and description are omitted.

  Further, the column side bracket 33 is separated from the vehicle body side bracket 11 by the impact load of the secondary collision, but supports the column side bracket 33 so that it does not fall off even when the secondary collision has progressed. The vehicle body side bracket 11 is supported and fixed on the vehicle body side and does not displace forward even in the event of a secondary collision, and is stamped and bent by a press into a metal plate having sufficient strength and rigidity such as a steel plate. Made by processing. Such a vehicle body side bracket 11 improves the bending rigidity by bending the side edge portions and the rear end edge portion downward, and a locking notch 45 having an opening at the front end edge side at the center in the width direction is provided at the rear portion. A pair of mounting holes 46 are formed at positions where the notch 45 is sandwiched from both the left and right sides. The locking notch 45 is formed to the vicinity of the rear end portion of the vehicle body side bracket 11 covered with a locking capsule 47 described below. Such a vehicle body side bracket 11 is supported and fixed to the vehicle body by bolts or studs inserted through the mounting holes 46 and 46.

  The column side bracket 33 is coupled to the vehicle body side bracket 11 as described above via a locking capsule 47 so that the column side bracket 33 can be detached forward during a secondary collision. As the locking capsule 47, a structure as shown in FIG. 25 can be preferably used, but a locking capsule 47a as shown in FIG. 26 can also be used. Of these, the locking capsule 47a shown in FIG. 26 will be described later. First, the case where the locking capsule 47 shown in FIG. 25 is used will be described.

  The locking capsule 47 is formed by subjecting a metal material such as an aluminum alloy or mild steel to plastic processing such as forging, die casting of a light alloy such as an aluminum alloy or magnesium alloy, or polyacetal. It is made by injection molding of high-strength, high-performance resin. Then, the width dimension in the left-right direction and the length dimension in the front-rear direction are made larger in the upper half than in the lower half, and both the left and right sides of the locking capsule 47 and the upper half of the rear side are There are provided flanges 48 projecting in the rear and rear directions. Such a locking capsule 47 is engaged forward with respect to the vehicle body side bracket 11 at the time of a secondary collision with the lower half engaged with the locking notch 45 (internally fitted). Supporting the withdrawal of. For this purpose, there are small passages at a plurality of positions (eight positions in the example shown in the drawing) of the flange portion 48 and the peripheral edge portion of the locking notch 45 at a part of the vehicle body side bracket 11. Holes 49a and 49b are formed. And the latching pins 50 and 50 are spanned between these small through-holes 49a and 49b, respectively.

  These locking pins 50, 50 are prepared by injecting synthetic resin into these small through holes 49a, 49b (injection molding) in a state where the small through holes 49a, 49b are aligned, or in advance. By inserting a synthetic resin or light alloy element pin formed in a cylindrical shape into the small through holes 49a and 49b (pressing with a large force in the axial direction), the small through holes 49a and 49b are connected to each other. Hang over between. In any case, a part of the synthetic resin material or light alloy material constituting each of the locking pins 50, 50 is the upper and lower surfaces of the vehicle body side bracket 11, the lower surface of the flange portion 48, and the mating surface, and It enters between the upper surface of the column side bracket 33. Then, the rattling of the mounting portion of the column side bracket 33 with respect to the vehicle body side bracket 11 is eliminated regardless of the gaps existing between these surfaces. Accordingly, in order to reliably close the gaps and to eliminate the rattling, it is preferable to form the locking pins 50 and 50 by synthetic resin injection molding (injection molding). In FIG. 25 and FIG. 26, which will be described later, for the sake of clarity, the height of the gap that causes the shakiness is drawn larger than the actual height.

  When the locking pins 50 are injection-molded, the molten resin enters the gaps between the surfaces and solidifies by cooling, thereby eliminating the rattling. On the other hand, when the element pin is press-fitted, on the basis of the axial force applied to the element pin, the portion corresponding to each of the gaps expands radially outward in the axial intermediate portion of the element pin. The rattling based on the existence of these gaps is eliminated. In any case, the locking capsule 47 is applied to the vehicle body side bracket 11 at the time of a secondary collision by spanning the locking pins 50, 50 between the small through holes 49a, 49b. Supports disengagement forward by impact load.

  The above-described locking capsule 47 is in a non-separated state with respect to the column side bracket 33 by a plurality (three in the illustrated example) of bolts 51 and 51 and nuts 52 and 52 regardless of the impact load. And fixed. That is, the top surface of the locking capsule 47 is inserted at the tip (upper end) of each of the bolts 51 and 51 inserted from below through the through holes formed at positions where the locking capsule 47 and the column side bracket 33 are aligned with each other. The locking capsule 47 and the column side bracket 33 are coupled and fixed by screwing and tightening the nuts 52, 52 to the protruding portion. Therefore, the impact load transmitted from the outer column 24 to the column side bracket 33 at the time of a secondary collision is transmitted to the locking capsule 47 as it is, and the locking pins 50 and 50 are broken as the locking pins 50 and 50 are broken. In synchronization with the capsule 47 being displaced forward, the outer column 24 is also displaced forward.

In this way, the length L ₄₅ in the front-rear direction of the locking notch 45 that locks the locking capsule 47 that is displaced forward together with the outer column 6 c at the time of a secondary collision is the length of the locking capsule 47. It is sufficiently larger than the length L ₄₇ in the same direction (L ₄₅ >> L ₄₇ ). In the case of the illustrated example, the length L ₄₅ of the locking notch 45 is at least twice as long as the length L ₄₇ of the locking capsule 47 (L ₄₅ ≧ 2L ₄₇ ). Even when the locking capsule 47 is completely displaced forward together with the outer column 24 at the time of a secondary collision (in the impact load applied from the steering wheel 1, the locking capsule 47 is not displaced further forward). At least the rear end portion of the flange portion 48 that constitutes the portion 47, a portion capable of supporting the weight of the steering column 6c, the column side bracket 33, and the like is prevented from coming out of the locking notch 45. That is, even in a state where the secondary collision has progressed, the rear end portion of the flange portion 48 formed on both side portions in the width direction of the upper half portion of the locking capsule 47 is above the front end portion of the vehicle body side bracket 11. The locking capsule 47 can be prevented from falling off.

According to the steering column supporting device according to the present invention configured as described above, tuning for stably displacing the steering wheel 1 forward in a secondary collision is easy, and the secondary collision proceeds. Even in such a state, the steering wheel 1 can be prevented from being excessively displaced downward.
First, in order to facilitate the tuning for stably displacing the steering wheel 1 forward at the time of a secondary collision, the vehicle body side bracket 11 and the locking capsule 47 are arranged only in the center in the width direction of the vehicle body side bracket 11. This can be achieved by engaging with.

  That is, since the single locking capsule 47 is disposed immediately above the outer column 24, the locking capsule 47 is passed from the steering wheel 1 through the outer shaft 25 and the outer column 24 at the time of a secondary collision. The impact load transmitted to is applied to each of the locking pins 50, 50, which joins the locking capsule 47 and the vehicle body side bracket 11, substantially evenly. In short, the impact load acts on the central portion of the locking capsule 47 in the axial direction of the outer column 24. Then, a force in a direction in which the single locking capsule 47 comes out of the locking notch 45 forward is applied. For this reason, the respective locking pins 50, 50 connecting the locking capsule 47 and the vehicle body side bracket 11 are torn substantially simultaneously. As a result, the forward displacement of the outer column 24 coupled to the locking capsule 47 via the column side bracket 33 or the like is stably performed without excessively tilting the central axis.

  In particular, in the illustrated example, there is provided a tilt / telescopic mechanism for adjusting the vertical position and the front / rear position of the steering wheel 1, and a friction plate for increasing the holding force for holding the steering wheel 1 in the adjusted position. Units 44 and 44 are installed. Providing the tilt / telescopic mechanism and the friction plate units 44, 44 tends to cause a large variation in separation load due to accumulation of manufacturing errors, etc., but in the case of the illustrated example, Due to the engagement between the single locking capsule 47 and the vehicle body side bracket 11, variations in the separation load can be suppressed. As a result, it is possible to appropriately perform tuning for alleviating the impact applied to the driver's body that has collided with the steering wheel 1 at the time of the secondary collision, and to easily enhance the protection of the driver.

Further, to prevent the steering wheel 1 from being excessively displaced downward even in a state in which a secondary collision has progressed, the longitudinal length L ₄₅ of the locking notch 45 is set to the longitudinal direction of the locking capsule 47. This can be achieved by making it sufficiently larger than the length L ₄₇ of. That is, since these lengths L ₄₅ and L ₄₇ are regulated in this way, even when the secondary collision proceeds and the locking capsule 47 is fully displaced forward together with the steering wheel 1, The entire locking capsule 47 does not escape forward from the locking notch 45. For this reason, even in a state in which a secondary collision has progressed, the steering wheel 1 secured to the outer column 24 via the outer column 24 and the outer shaft 25 while securing the supporting force of the outer column 24 is ensured. It is possible to prevent excessive descending. Then, it is easy to operate the steering wheel 1 even after an accident. For example, when the accident vehicle can be self-propelled, it is easy to perform driving when the accident vehicle is self-propelled from the accident site to the road shoulder. .

  Next, the structure shown in FIG. 26 will be described. In the structure shown in FIG. 25, the shape of the locking capsule 47 is simple, so that the manufacturing cost of the locking capsule 47 can be suppressed, and the assembly height of the portion where the locking capsule 47 is installed can be suppressed low. Such a structure reduces the size and weight of the support device for the steering column, and is a position where the outer column 24 is separated from the central axis of the outer column 24 where impact load is applied. This is advantageous in that the distance between the side bracket 11 and the engaging portion of the locking capsule 47 is shortened to stabilize the detachment load of the engaging portion (to suppress the twist associated with the increase of the distance).

  In contrast, the structure shown in FIG. 26 is advantageous in terms of facilitating injection molding of the locking pins 50 and 50. That is, in the case of the structure shown in FIG. 25, when the locking pins 50, 50 are injection-molded, the vehicle body side bracket 11, the locking capsule 47, and the column side bracket 33 are connected to the bolts. 51, 51 and the nuts 52, 52 are connected. In contrast, in the case of the structure shown in FIG. 26, only the vehicle body side bracket 11 and the locking capsule 47a need be set in the mold for injection molding the locking pins 50, 50. It is easy to reduce the size of the mold. That is, the locking capsule 47a is formed with locking grooves 53, 53 on the left and right side surfaces, respectively, and both side edges of the locking notch 45 of the vehicle body side bracket 11 are formed in the locking grooves 53, 53. Engaged. Therefore, after the vehicle body side bracket 11 and the locking capsule 47a are coupled by the locking pins 50 and 50, the locking capsule 47a is connected to the column side bracket 33 with the bolts 51 and 51 and the locking capsules 47a. The nuts 52 and 52 can be coupled and fixed.

  The structure of the prior invention as described above has the advantage of facilitating the design for enhancing the protection of the driver at the time of the secondary collision, but in order to further enhance the protection of the driver at the time of the secondary collision. It is desirable to improve the following points. That is, with respect to the width direction of the vehicle, the acting direction of the impact load applied to the locking capsules 47 and 47a at the time of the secondary collision does not necessarily coincide with the axial direction of the steering column 6c. Rather, the driver's body often collides with the steering wheel obliquely with respect to the width direction of the vehicle. Therefore, in many cases, an impact load directed obliquely forward is applied to the locking capsules 47 and 47a at the time of a secondary collision. Then, due to the component force in the width direction of the impact load, one of the left and right side edges of the locking capsules 47, 47 a is strongly pressed against the inner edge of the locking notch 45. . Then, the side capsules strongly pressed against each other strongly rub against each other (while being frictionally engaged), and the locking capsules 47 and 47a come out of the locking notch 45 forward.

  In this way, when the locking capsules 47, 47a are pulled forward from the locking notches 45, the energy (load) required to displace the locking capsules 47, 47a forward is the capsules 47, 47a. The larger the angle formed by the direction in which is pressed and the inner edge where any one of the side edges rubs, the larger the angle. If the energy required to displace the locking capsules 47 and 47a increases at the moment of occurrence of the secondary collision, the impact applied to the driver's body at the moment of occurrence of the secondary collision increases, It is disadvantageous from the aspect of protection. In consideration of such circumstances, the locking capsule 47 is used regardless of the direction in which the locking capsules 47 and 47a are pushed in order to reduce the impact applied to the driver's body at the moment of occurrence of the secondary collision. 47a is preferably prevented from being strongly pressed against the side edge of the locking notch 45.

Japanese Utility Model Publication No. 51-121929 JP-A-2005-219641 JP 2000-6821 JP 2007-69821 A JP 2008-1000059 A1

  In view of the circumstances as described above, the present invention is easy to tune to stably displace the steering wheel forward at the time of a secondary collision, and is concerned with the direction in which the locking capsule is pushed at the time of the secondary collision. The side edge of the locking capsule is not strongly pressed against the side edge of the locking notch of the vehicle body side bracket, and further, if necessary, a structure that can prevent the steering wheel from being lowered excessively after a secondary collision. It was invented to realize.

The steering column support device of the present invention includes a vehicle body side bracket, a locking notch, a column side bracket, and a locking capsule as in the conventional structure shown in FIGS.
Of these, the vehicle body side bracket is supported and fixed to the vehicle body side, and is not displaced forward even in a secondary collision.
The locking notch is formed at the center in the width direction of the vehicle body side bracket, and the front end edge side of the vehicle body side bracket is open.
The column side bracket is supported on the steering column side and is displaced forward together with the steering column at the time of the secondary collision.
Furthermore, the locking capsule is fixed to the column-side bracket, and both ends are locked to the locking notch, and both upper end side portions are fixed to the vehicle-side bracket at both side portions of the locking notch. It is located on the upper side.
Then, by connecting the locking capsule and the vehicle body side bracket with a connecting member that breaks based on the impact load applied at the time of the secondary collision, the column side bracket is connected to the vehicle body side bracket. It is supported so that it can be detached forward by the impact load applied at the time of collision.

In particular, in the steering column support device of the present invention, a portion of the right and left side edges of the locking notch that may rub against the locking capsule at least at the moment of occurrence of the secondary collision, The entire length of the portion is inclined toward the outside in the width direction of the vehicle body side bracket as it goes forward.
That is, of the locking notches, at least the left and right side edges of the portion with which the locking capsule is engaged before the occurrence of the secondary collision is parallel to the central axis of the steering column, They are inclined in opposite directions with respect to the center line of the locking notch. The inclined direction is a direction in which the width dimension of the locking notch in the left-right direction is gradually increased toward the front. Further, the inclined range is a range extending over the entire length of the portion that engages with the left and right side edges of the locking capsule before the secondary collision occurs, and preferably the front end of the locking capsule Inclined by the same angle in the same direction up to the front of the surface.

  When implementing the present invention as described above, preferably, the length of the locking notch in the front-rear direction is larger than the length of the locking capsule in the same direction as in the invention described in claim 2. To do. Specifically, even when the locking capsule is displaced forward together with the steering column at the time of the secondary collision in the locking notch, at least a part of the locking capsule is at the front end portion of the vehicle body side bracket. It is located on the upper side and has a length sufficient to prevent the locking capsule from falling off.

  When the invention described in claim 2 described above is carried out, as in the invention described in claim 3, for example, in the locking notch, the locking capsule before the secondary collision occurs. The left and right side edges of the portion exposed forward are also gradually opposite to each other with respect to the center line of the locking notch, and the width dimension in the left-right direction of the locking notch is gradually increased toward the front. Tilt in the direction to be. In short, the right and left side edges of the locking notch are inclined at the same angle in the same direction over their entire length.

  Alternatively, as in the invention described in claim 4, at least the first half portion of the locking notch that is exposed forward of the locking capsule before the secondary collision occurs. Is parallel to the center line of the locking notch. In short, of the right and left side edges of the locking notch, only the portion that engages the side surface of the locking capsule immediately after the occurrence of the secondary collision and immediately after the occurrence of the secondary collision is inclined. After the locking capsule starts to be displaced forward, the locking capsule is guided forward in parallel to the center line of the locking notch.

  Alternatively, as in the invention described in claim 5, at least the first half portion of the locking notch that is exposed forward of the locking capsule before the secondary collision occurs. Are inclined with respect to the center line of the locking notch in the opposite direction to the left and right side edges of the portion with which the locking capsule is engaged before the secondary collision occurs. Then, the width dimension of the at least the first half portion is gradually reduced toward the front.

  When carrying out the invention described in claims 2 to 5 as described above, for example, as in the invention described in claim 6, before the secondary collision occurs at the front part of the vehicle body side bracket (normally Of the portion exposed in the front of the locking capsule, the left and right side portions of the locking notch are corrugated in the front-rear direction. In short, by curving the portions protruding forward from the front end surface of the locking capsule in the normal state in both sides of the front portion of the locking notch of the vehicle body side bracket, The apparent thickness dimension of this part is made larger than the height dimension of the part that clamps the vehicle body side bracket from above and below between the locking capsule and the vehicle body side bracket in the normal state. And as the secondary collision proceeds, the locking capsule is configured to be displaced forward while plastically deforming the corrugated portion at the front portion of the vehicle body side bracket.

  When the present invention is carried out, it is preferable that the locking capsule and the vehicle body side bracket are torn apart by an impact load applied based on the secondary collision, as in the invention described in claim 7. It couple | bonds with the coupling member of. Further, each of these coupling members is formed by a small through-hole formed in a flange provided in a state of projecting from the upper half of the locking capsule at least to the left and right sides, and a part of the bracket on the vehicle body side. Synthetic resin is produced by injection molding between the portions that match the small holes and the receiving portions that are formed in the portions that match the small holes. Then, a part of the synthetic resin is allowed to enter between the inner surface of the locking notch and the surface of the locking capsule that faces the inner surface, and a gap between the surfaces is formed. Block at least some of them.

  When the invention described in claim 7 is carried out, it is more preferable that, as in the invention described in claim 8, each of the receiving portions is a small notch opened in the locking notch. Part. The left and right inner edges of the locking notch and the left and right side edges of the locking capsule are opposed to each small through hole and a part of the synthetic resin injected into each small notch. The gap that exists between the faces is covered by the entire length.

  When the present invention is implemented, preferably, the column side bracket and the locking capsule are made of metal plates that can be welded to each other as in the invention described in claim 9. The locking capsule is a base plate portion welded and fixed to the upper plate portion in a state of being superimposed on the upper plate portion on the upper surface of the upper plate portion provided at the upper end portion of the column side bracket, Bending upward from both ends in the width direction of the substrate part, at least in the same direction as the left and right side edges of the part where the locking capsule is engaged at least before the secondary collision occurs among the locking notches It is assumed that a pair of left and right rising parts inclined and a pair of left and right flange parts bent outward from the substrate part in opposite directions from the upper ends of both rising parts are provided. Then, the column side bracket and the locking capsule are welded to each other, and both side portions of the locking notch of the vehicle body side bracket are connected to the upper surface of the column side bracket and the lower surfaces of the both flanges. In the meantime, it is detachably engaged based on the impact energy applied to the column side bracket during the secondary collision.

  According to the steering column support device of the present invention configured as described above, tuning for stably displacing the steering wheel forward at the time of a secondary collision is easy, and it is related to the moment when the secondary collision occurs. Regardless of the direction in which the stop capsule is pushed, the side edge of the lock capsule is not strongly pressed against the side edge of the lock notch of the vehicle body side bracket, and if necessary, the steering wheel becomes excessive after the secondary collision. It can be prevented from descending.

First, to facilitate the tuning to stably displace the steering wheel forward in the event of a secondary collision, the vehicle body side bracket and the locking capsule are engaged only at the center in the width direction of the vehicle body side bracket. I can plan.
Also, regardless of the direction in which the locking capsule is pushed at the moment of occurrence of the secondary collision, the side edge of the locking capsule should not be pressed strongly against the side edge of the locking notch of the vehicle body side bracket. The left and right side edges can be inclined in directions opposite to each other in a direction in which the distance between the left and right edges increases toward the front.

The locking notch in the direction of action of the force applied to the locking capsule even when a force that pushes the locking capsule straight forward is applied along with the secondary collision and when it is applied obliquely forward. If the angle of inclination with respect to the center line is less than the angle of inclination of the inner edge of the locking notch, the right and left inner edges of the locking notch and the locking capsule facing the inner edges of the locking notch The left and right sides are separated immediately. Therefore, a large frictional force does not act between the both inner edges and the mating surface.
On the other hand, when the acting direction of the force applied to the locking capsule due to the secondary collision increases beyond the inclination angle of the inner edge of the locking notch, the locking capsule Any one of the left and right side surfaces is pressed against any one of the inner edges. Even in this case, the magnitude of the component force acting in the direction of pressing the side surface against the side edge can be kept small by an amount corresponding to the inclination angle of the side edge. For this reason, at the moment of the occurrence of the secondary collision, the load required to start displacing the locking capsule is kept low, the impact applied to the driver's body at this moment is reduced, and the driver is protected. Can be enriched.

  Further, if necessary, preventing the steering wheel from descending excessively after the secondary collision is the same as the invention described in claim 2 in that the length of the locking notch in the front-rear direction is locked. This can be achieved by making the length sufficiently larger than the length of the capsule in the same direction so that the locking capsule does not escape forward from the locking notch. If it is possible to prevent the steering wheel from being lowered excessively, it is easy to operate the steering wheel even after an accident. For example, when the accident vehicle is capable of running on its own, the accident vehicle is automatically moved from the accident site to the shoulder. It is possible to easily perform driving when moving.

When carrying out the invention described in claim 2 as described above, as in the invention described in claim 3, if the left and right inner edges of the locking notch are inclined over their entire length, The frictional force between any one of the inner edges and the side surface of the locking capsule can be made substantially constant regardless of the progress of the secondary collision.
Further, as in the invention described in claim 4, if the left and right side edges of the locking notch are made parallel to each other at the respective front parts, the left and right sides of the steering wheel are moved in the stage where the secondary collision has progressed. It is possible to suppress the movement of the directional position.
Further, as in the invention described in claim 5, the right and left side edges of the locking notch are inclined in the opposite direction to the respective rear portions at the respective front portions, and the width dimension of the front half portion is moved forward. If it is gradually decreased, the resistance against the forward displacement of the locking capsule can be gradually increased at the stage where the secondary collision has progressed. And the impact energy applied to the said steering wheel from a driver | operator's body can be absorbed by the engaging part of this latching capsule and the said vehicle body side bracket.
Further, according to the invention described in claim 6, in the structure of any of the inventions described in claims 2 to 5, the engagement portion between the locking capsule and the vehicle body side bracket can be used to move the driver body from the body. The impact energy applied to the steering wheel can be absorbed.

  Further, as in the invention described in claim 7, the vehicle body side bracket and the locking capsule are coupled by a coupling member formed by injection molding a synthetic resin, and a part of the synthetic resin allows the vehicle body side If at least a part of the gap existing between the upper and lower surfaces of the bracket and the mating surface is closed, rattling of the joint between the vehicle body side bracket and the column side bracket that supports and fixes the locking capsule is prevented. It can be lost. The steering wheel supported by the column side bracket via the steering column and the steering shaft can be prevented from rattling, and the operational feeling of the steering wheel can be improved.

  Further, as in the invention described in claim 8, due to a part of the synthetic resin, between the left and right inner edges of the locking notch and a surface of the locking capsule facing both side edges. If the existing gap is covered over the entire length, it is possible to prevent these inner edges from directly rubbing against each other. And even when both the locking capsule and the vehicle body side bracket are made of metal such as carbon steel, the metal is prevented from rubbing strongly at the moment when the secondary collision occurs, and the locking When the capsule is pulled forward from the locking notch, the resistance due to friction between the two surfaces can be reduced.

Furthermore, as in the invention described in claim 9, if a structure in which a locking capsule and a column side bracket each made of a metal plate are welded and fixed is adopted, a reduction in size, weight, and cost can be achieved. In addition, it is possible to realize a structure that can ensure a degree of freedom in design.
That is, each of the locking capsules and the column side brackets, each made of a metal plate, is connected and fixed by welding, so that the bolt tip protrudes above the locking capsule and a nut is attached to the tip. There is no need for screwing. Therefore, the increase in assembly dimensions based on the presence of the bolts and nuts, which occurs in the above-described conventional structure and the structure of the prior invention, can be suppressed, and the size and weight can be reduced. Further, it is possible to reduce the cost based on the fact that these bolts and nuts are not required, and to secure the degree of freedom in designing the steering device installation portion based on the downsizing.

  However, when the gap between the locking capsule and the column side bracket and the vehicle body side bracket is closed with a synthetic resin in a structure using the locking capsule made of the metal plate, this gap portion is formed at the time of a secondary collision. There is a possibility that the synthetic resin filled in will become a resistance against the forward displacement of the locking capsule and the column side bracket with respect to the vehicle body side bracket. Even in this case, in the case of the present invention, the left and right side edges of the rear half of the locking notch are inclined in a direction in which the width dimension of the locking notch gradually increases toward the front. , Immediately after the secondary collision, the synthetic resin tends to be separated from the mating surface. Accordingly, it is possible to prevent the synthetic resin and the mating surface from strongly rubbing each other, and the steering wheel together with the locking capsule and the column side bracket can be displaced more smoothly forward.

The perspective view equivalent to the center part of FIG. 22 which shows the 1st example of embodiment of this invention. Similarly, the top view which abbreviate | omits and shows. The schematic plan view seen from the same direction as FIG. 2 for demonstrating the filling condition of the synthetic resin containing the coupling member for couple | bonding a vehicle body side bracket and a latching capsule. The partial top view (A) showing the small notch which comprises a preferable structure, and the partial top view (B) showing the small through-hole which comprises the structure which remove | deviates from this preferable structure. The figure similar to FIG. 2 which shows the 2nd example of embodiment of this invention. The figure similar to FIG. 2 which shows the 3rd example. The aa sectional view (A) and the bb sectional view (B) of FIG. The schematic side view which shows another 3 examples of the shape of the front half part of a vehicle body side bracket. The figure similar to FIG. 1 which shows the 7th example of embodiment of this invention. Similarly, the same figure as FIG. Cc sectional drawing of FIG. The figure equivalent to the left part of FIG. 11 which shows the state after a secondary collision. Sectional drawing which shows the process of making the latching capsule of the 7th example of embodiment of this invention from a metal plate in order. The figure similar to FIG. 2 which shows the 8th example of embodiment of this invention. The partial cut side view which shows an example of the steering apparatus known conventionally. The top view which shows one example of the conventional steering column support apparatus in the state of normal time. Similarly side view. The side view which shows the state which the steering column displaced forward with the secondary collision regarding one example of the conventional support apparatus for steering columns. Sectional drawing regarding the virtual plane which exists in the direction orthogonal to the central axis of a steering column which shows an example of the conventional structure. Similarly, the perspective view shown in the state before couple | bonding a vehicle body side bracket and a column side bracket. Similarly, the perspective view shown in the state which described the connecting pin instead of omitting a steering column. The perspective view which shows the structure of a prior invention in the state seen from back upper direction. Similarly, the end view which shows in the state which abbreviate | omitted one part and was seen from back. Similarly, the top view shown in the state seen from the upper part of FIG. FIG. 25 is an enlarged dd cross-sectional view of FIG. 24 showing a first example of the structure of the coupling portion between the vehicle body side bracket and the column side bracket. The figure similar to FIG. 25 which shows the 2nd example.

[First example of embodiment]
1 to 4 show a first example of an embodiment of the present invention corresponding to claims 1 to 3, 7 and 8. The feature of this example is that the load required to start the forward displacement of the locking capsule 47b with respect to the vehicle body side bracket 11b is kept low regardless of the direction of the impact load applied to the steering column 6c when a secondary collision occurs. Accordingly, the shape of the locking notch 45a formed in the vehicle body side bracket 11b is devised, and accordingly, the shape of the locking capsule 47b is different from the structure according to the previous invention shown in FIGS. It is in the point. Since the structure and operation of the other parts are the same as the structure according to the previous invention, the illustration and description of the equivalent parts are omitted or simplified. Hereinafter, the characteristic part of this example and the structure according to the previous invention will be described. The description will focus on the different parts.

  The locking capsule 47b is coupled and fixed to the upper surface of the column side bracket 33 by a plurality of (three in the illustrated example) rivets 54 and 54. The basic shape and structure of the locking capsule 47b are the same as the locking capsule 47 incorporated in the structure of the first example of the previous invention shown in FIG. However, the planar shape of the lower half part of the locking capsule 47b incorporated in the structure of this example is such that the left and right side edges are inclined in opposite directions to each other in a direction in which the width dimension of the lower half part decreases toward the rear. It is trapezoidal. That is, the shape of the locking capsule 47b is bilaterally symmetric in both the upper half and the lower half, but the left and right side surfaces of the lower half are inclined in opposite directions with respect to the front-rear direction. Similarly, the upper half of the locking capsule 47b protrudes from the lower half to both sides and rear to form a flange 48a.

  On the other hand, the locking notches 45a formed on the vehicle body side bracket 11b are inclined in the direction toward the outer side in the width direction of the vehicle body side bracket 11b as it goes forward over the entire length of the respective left and right sides. Yes. That is, the left and right edges of the locking notch 45a are parallel to the central axis of the steering column 6c and are opposite to the center line α of the locking notch 45a. In contrast, they are inclined by the same angle θ. The inclined direction is a direction in which the width dimension in the left-right direction of the locking notch 45a gradually increases toward the front. The inclination angle θ of the left and right side edges with respect to the center line α and the inclination angles of the left and right side surfaces of the lower half of the locking capsule 47b are made to coincide with each other. However, the width dimension of the locking notch 45a is slightly smaller than the width dimension of the portion of the lower half of the locking capsule 47b where the front and rear positions match in the combined state shown in FIG. About 5 to 2 mm) large. The width dimension W of the flange portion 48a is sufficiently larger than the width dimension w of the front end opening of the locking notch 45a where the distance between the left and right end edges is widest (W> w).

  Further, a pair of left and right hanging plate portions 58 and 58 are formed on the left and right side edge portions of the vehicle body side bracket 11b by bending the metal plate constituting the vehicle body side bracket 11b downward. The bending rigidity of the bracket 11b is improved. The front end portions of the both hanging plate portions 58 and 58 are parallel to each other, and the distance D between the inner side surfaces of the front end portions is based on the width (length in the left-right direction) L of the upper end portion of the column side bracket 33. Is slightly larger (D> L). Further, the lower end edges of the both hanging plate portions 58, 58 are positioned slightly below the upper end portion of the column side bracket 33. Further, of the both hanging plate portions 58, 58, the continuous portion between the front end portion and the intermediate portion is curved in a direction in which the interval between the inner side surfaces of both hanging plate portions 58, 58 is smoothly spread. . Accordingly, as the secondary collision progresses, the upper end portion of the column side bracket 33 enters between the front end portions of the both hanging plate portions 58 and 58, and the inner side surfaces of the both hanging plate portions 58 and 58. Move forward while being guided by.

  Further, small notches 55 as shown in FIGS. 3 to 4 are formed at a plurality of locations (six locations in the illustrated example) on the inner edge of the locking notches 45a. As shown in FIG. 4A, each of the small notches 55 is open toward the inside of the locking notch 45a. Furthermore, small through holes 49a and 49a (see FIGS. 1 and 2) are respectively formed in portions of the collar portion 48a of the locking capsule 47b and aligned with the small notches 55.

  As described above, each of the small through holes 49a, 49a is formed in the flange portion 48a of the upper half, and the locking capsule 47b coupled and fixed to the column side bracket 33 by the rivets 54, 54; The vehicle body side bracket 11b in which each small cutout portion 55 is formed is detachably coupled by a synthetic resin 56 based on an impact load at the time of a secondary collision. That is, the thermoplastic resin is between the small notches 55 formed on the vehicle body side bracket 11b and the small through holes 49a and 49a formed on the locking capsule 47b. The synthetic resin 56 is injected and solidified (injection molding) in a molten state so as to be spanned between the vehicle body side bracket 11b and the flange portion 48a. At this time, the lower half of the locking capsule 47b is positioned at the center in the width direction of the locking notch 45a, and between the left and right side edges of the lower half and the inner edge of the locking notch 45a. In addition, a minute gap 57 (see FIG. 3) is interposed over the entire length including a portion between the back end portion of the locking notch 45a and the rear end surface of the lower half portion.

  The synthetic resin 56 is fed into the small cutouts 55 through the small through holes 49a and 49a, and the small cutouts 55 are opened into the locking cutouts 45a. . Accordingly, the synthetic resin 56 fed into each of the small notches 55 enters the minute gap 57 over the entire length of the minute gap 57 and is cooled and solidified in the minute gap 57. The synthetic resin 56 flows smoothly from the small notches 55 into the minute gaps 57. That is, as shown in FIG. 4B, when a small through hole independent of the locking notch 45a is formed in a part of the vehicle body side bracket 11b, the small gap 57 is sufficient. It is difficult to feed an amount of synthetic resin 56. On the other hand, in the case of this example, each of the small notches 55 opens into the locking notch 45a as shown in FIG. A sufficient amount of synthetic resin 56 can be reliably fed.

  In the synthetic resin 56, the small holes 49 a and 49 a and the small notches 55 are spanned between the small holes 49 a and 49 a and the small notches 55. The parts that are cooled and solidified in such a state constitute a plurality of connecting members (members corresponding to the locking pins 50 and 50 of the structure of the previous invention) described in claim 7 in the claims. Then, the locking capsule 47b is coupled and supported to the vehicle body side bracket 11b so that it can be displaced forward by an impact load applied during a secondary collision. Further, a part of the synthetic resin 56 fed into each of the small notches 55 includes the upper and lower surfaces of the vehicle body side bracket 11b, and the lower surface of the flange portion 48a and the column side bracket, which are mating surfaces, respectively. It enters into a minute gap existing between the upper surface of 33 and solidifies by cooling in this minute gap. As a result, it is possible to eliminate the rattling of the mounting portion of the column side bracket 33 with respect to the vehicle body side bracket 11b, and to improve the operational feeling of the steering wheel as described above. It should be noted that any one of the upper and lower surfaces of the vehicle body side bracket 11b and the lower surface of the flange portion 48a and the upper surface of the column side bracket 33, which are mating surfaces that are opposed to the upper and lower surfaces, respectively. A part of the synthetic resin 56 may be allowed to enter only within a minute gap existing between the other surfaces without any gap.

  Further, an energy absorbing member 59 is provided between the locking capsule 47b and the vehicle body side bracket 11b, which are combined with each other as described above. The energy absorbing member 59 is formed by bending a plastically deformable wire such as a wire made of low carbon steel, and has a base 60 whose planar shape is a U-shape and a pair of folded portions 65 on the left and right sides, 65 and an extension part 66. As shown in FIG. 1, the energy absorbing member 59 is stretched between the locking capsule 47b and the vehicle body side bracket 11b. That is, the base 60 is engaged with the upper half of the locking capsule 47b so as to wrap around the portion protruding from the upper surface of the vehicle body side bracket 11b, and the folded portions 65 and 65 are engaged with the vehicle body side bracket. A pair of small through holes provided at the rear edge of 11b so as to oppose the pair of left and right convex surfaces 61, 61, and the extending portions 66 are provided below the convex surfaces 61, 61, respectively. 62 and 62 are inserted from the rear to the front.

  According to the steering column support device of the present example configured as described above, for the same reason as in the above-described prior invention, it is easy to tune to stably displace the steering wheel forward at the time of a secondary collision. Become. In the case of the structure of this example, as in the structure of the previous invention, the length (depth) of the locking notch 45a formed in the vehicle body side bracket 11b is set to be the same as that of the locking capsule 47b. Since the length is sufficiently longer than the length in the direction, it is possible to prevent the steering wheel from being lowered excessively even when the secondary collision has progressed.

In particular, in the case of the structure of this example, the left and right side edges of the locking notch 45a are inclined in directions opposite to each other in a direction in which the interval increases toward the front. Regardless of the direction in which the locking capsule 47b is pressed, the side edge of the locking capsule 47b is not strongly pressed against the inner edge of the locking notch 45a of the vehicle body side bracket 11b.
That is, when a force is applied to push the locking capsule 47b straight forward with the secondary collision, and even when it is applied obliquely forward, the acting direction of the force applied to the locking capsule 47b is When the inclination angle of the locking notch 45a with respect to the center line α is less than the inclination angle θ of the inner edge of the locking notch 45a, the left and right inner edges of the locking notch 45a and the both inner sides The left and right side surfaces of the locking capsule 47b facing the edge are immediately separated. Therefore, a large frictional force does not act between the both inner edges and the mating surface.

  On the other hand, when the acting direction of the force applied to the locking capsule 47b due to the secondary collision becomes larger than the inclination angle θ of the inner edge of the locking notch 45a, the engagement is increased. Any one of the left and right side surfaces of the stop capsule 47b is pressed against any one of the inner edges. Even in this case, the magnitude of the component force acting in the direction of pressing the side surface against the side edge is small by an amount corresponding to the inclination angle θ of the outer edge (the magnitude corresponding to the inclination angle −θ in the action direction). ) It can be suppressed. Moreover, in this example, the synthetic resin 56 is interposed between the inner edge of the locking notch 45a and the left and right side surfaces of the locking capsule 47b. For this reason, for example, both the locking capsule 47b and the vehicle body side bracket 11b are made of metal such as carbon steel, and even if an oblique force is applied to the locking capsule 47b due to the secondary collision, The side surface and the inner edge do not rub against each other strongly. For this reason, the load required to start displacing the locking capsule 47b forward at the moment of occurrence of the secondary collision is kept low, and the impact applied to the driver's body at the moment of occurrence of the secondary collision is reduced. Enhance driver protection.

  In the case of the structure of this example, the width dimension of the locking notch 45a gradually increases to the front end opening of the locking notch 45a, but from the state where the secondary collision has progressed to some extent. In a later state, the displacement of the locking capsule 47b in the width direction is restricted by the engagement between the upper end portion of the column side bracket 33 and the front end portions of the both hanging plate portions 58 and 58. Therefore, even if the width of the flange 48a provided in the upper half portion of the locking capsule 47b is not particularly increased, the lower surface of both ends of the flange 48a and the vehicle body can be obtained even when the secondary collision has progressed. Excessive lowering of the steering wheel can be prevented by keeping the upper surface of the front end portion of the side bracket 11b engaged.

  The energy absorbing member 59 is plastically deformed in the process in which the locking capsule 47b is displaced forward with respect to the vehicle body side bracket 11b in accordance with the secondary collision. That is, with the forward displacement of the locking capsule 47b, the base 60 constituting the energy absorbing member 59 is pulled forward, and the front side edges (inner peripheral edges) of the folded portions 65, 65 are the both convex surfaces. 61, pressed against 61. Then, when the locking capsule 47b is further displaced forward from this state and the base 60 is further pulled forward, a part of the energy absorbing member 59 is handled by the both convex surfaces 61 and 61 and is plastically deformed. To do. Specifically, the folded capsules 65b are moved forward by moving the folded portions 65, 65 toward the distal ends of the extended portions 66 while being handled by the convex surfaces 61, 61. Allow displacement. Thus, the locking capsule 47b moves forward while plastically deforming the energy absorbing member 59, so that the outer shaft 25, the ball bearing 26, the outer column 24, the adjusting rod 37, the column are removed from the steering wheel. The impact energy applied to the locking capsule 47b via the side bracket 33 or the like is absorbed. Then, the impact applied to the driver's body colliding with the steering wheel is alleviated to protect the driver.

[Second Example of Embodiment]
FIG. 5 shows a second example of an embodiment of the present invention corresponding to claims 1, 2, 4, 7, and 8. In the case of this example, of the locking notch 45b formed in the center in the width direction of the vehicle body side bracket 11c, the portion exposed forward of the locking capsule 47b before the secondary collision occurs. Of these, the front half is parallel to the center line α of the locking notch 45b. In short, of the right and left side edges of the locking notch 45b, only the portion that engages with the side surface of the locking capsule 47b immediately after the occurrence of the secondary collision and immediately after the occurrence of the secondary collision, It is inclined in the direction of spreading. Then, after the locking capsule 47b starts to be displaced forward with the secondary collision, the locking capsule 47b is directed forward and guided in the direction of the center line α.

According to the structure of this example configured in this way, a pair of hanging plates in which the upper end portion of the column side bracket 33 is provided at the left and right side edge portions of the vehicle body side bracket 11c in the course of the secondary collision. It can be made to enter more smoothly between the inner side surfaces of the front end portions of the portions 58 and 58. That is, it is possible to slightly suppress the deviation between the left and right outer side surfaces of the upper end portion of the column side bracket 33 and the inner side surfaces of the both hanging plate portions 58 and 58, which are generated in the course of the secondary collision. And the upper end part of the said column side bracket 33 can be approached more smoothly between the inner side surfaces of the said both drooping board parts 58 and 58. FIG. Then, at the final stage of the secondary collision, the upper end portion of the column side bracket 33 is guided between the inner side surfaces of the both hanging plate portions 58, 58 so that the lateral position of the steering wheel is shifted. This steering wheel can be displaced forward while restraining movement.
Since the configuration and operation of other parts are the same as those of the first example of the above-described embodiment, illustration and description regarding the equivalent parts are omitted.

[Third example of embodiment]
FIGS. 6-7 has shown the 3rd example of embodiment of this invention corresponding to Claim 1, 2, 5-8. In the case of this example, the portion of the locking notch 45c formed at the center in the width direction of the vehicle body side bracket 11d is exposed forward of the locking capsule 47b before the secondary collision occurs. Of these, the middle part or the front end part is opposite to the left and right side edges of the rear half part where the locking capsule 47b is engaged with the center line α of the locking notch 45c before the secondary collision occurs. It is inclined in the direction. And the width dimension of the said intermediate | middle part thru | or front-end part is gradually reduced as it goes ahead. The width w of the front end opening of the locking notch 45c is smaller than the width W of the lower half of the locking capsule 47b engaged with the locking notch 45c (w <W).

  In the case of this example, of the portion exposed forward of the locking capsule 47b before the secondary collision occurs at the front portion of the vehicle body side bracket 11d (in a normal state), As shown in FIG. 7A, the left and right side portions of the notch 45b have a waveform shape in the front-rear direction. In short, the portions of the vehicle body side bracket 11d that protrude forward from the front end surface of the locking capsule 47b in the normal state on both sides of the front portion of the locking notch 45b are alternately reversed in the front-rear direction. By curving in the direction, a corrugated portion 63 is formed, and the apparent thickness dimension T of the corrugated portion 63 is made larger than the thickness dimension t of the metal plate constituting the vehicle body side bracket 11d (T> t). ing. The thickness t of the metal plate is the gap between the lower surface of the flange portion 48a formed on the upper left and right side surfaces of the locking capsule 47b and the upper surface of the column side bracket 33, as shown in FIG. 64, that is, the height dimension h of the portion that sandwiches the vehicle body side bracket 11d from above and below in the normal state, or slightly smaller than the height dimension h (t ≦ h). Therefore, the apparent thickness dimension T of the corrugated portion 63 is larger than the height dimension h (T> h).

In the case of the structure of the present example having the above-described configuration, the locking capsule 47b is displaced forward while plastically deforming the vehicle body side bracket 11d during a secondary collision. First, the lower half of the locking capsule 47b displaces forward while pushing the front half of the locking notch 45c left and right. At this time, the impact energy applied to the locking capsule 47b due to the secondary collision is absorbed by the amount of plastic deformation of the front portion of the vehicle body side bracket 11d. Second, when the corrugated portion 63 passes through the gap 64 portion, the locking capsule 47b is displaced forward while plastically deforming the corrugated portion 63 in a crushing direction. At this time, the impact energy is also absorbed by plastically deforming the corrugated portion 63. The degree to which the corrugated portion 63 absorbs this impact energy can be arbitrarily adjusted by changing the height of the corrugation. Therefore, when arranging a plurality of waveforms in the front-rear direction, if the height of each waveform is lowered on the rear side and increased toward the front side, the degree of impact energy absorbed gradually as the secondary collision progresses. It can be enlarged, and favorable characteristics can be obtained from the viewpoint of driver protection.
Since the configuration and operation of other parts are the same as those of the first example of the above-described embodiment, illustration and description regarding the equivalent parts are omitted. In addition, the structure which makes a waveform shape the part which pinches | pinches a notch from both sides in the front part of a vehicle body side bracket like this example is implemented in combination with the structure of the 1st-2nd example of above-mentioned embodiment. You can also do things.

[Fourth to Sixth Embodiments]
8A to 8C show fourth to sixth examples of the embodiment of the present invention. In the first to third examples of the embodiment described above, the front part of the vehicle body side bracket is positioned on the same plane as the rear part, whereas the fourth example shown in FIG. In the case of the example structure, the front part is bent upward with respect to the rear part. In the case of the structure of the fifth example shown in FIG. 8B, the front part is bent downward with respect to the rear part. Further, in the case of the structure of the sixth example shown in FIG. 8C, the front portion is bent downward (or upward) with respect to the rear portion, and the front portion is corrugated. In the case of such structures of the fourth to sixth examples, the vertical position of the steering wheel can be regulated after the secondary collision occurs.

[Seventh example of embodiment]
FIGS. 9-13 has shown the 7th example of embodiment of this invention corresponding to Claims 1-3 and 7-9. In the case of this example, in order to simplify the structure of the coupling portion between the locking capsule 47c and the column side bracket 33, the locking capsule 47c and the column side bracket 33 can be welded to each other, such as a carbon steel plate. It is made of the same kind of metal plate that can secure sufficient strength and rigidity, and the shape of the locking capsule 47c is devised. That is, the locking capsule 47c includes a base plate portion 67, a pair of left and right rising portions 68 and 68, and a pair of left and right flange portions 69 and 69. Among these, the board | substrate part 67 is flat form. Further, both the rising portions 68 and 68 are bent at substantially right angles upward from both end portions in the width direction of the substrate portion 67. Further, both the rising portions 68, 68 are inclined at the same angle in the same direction as the left and right side edges of the locking notch 45a formed in the vehicle body side bracket 11b, and the interval between the both rising portions 68, 68 is set. , Narrowing towards the front. Further, the both flange portions 69, 69 are bent in opposite directions from the upper ends of the rising portions 68, 68. The height H of the step existing between the lower surface of the both flanges 69 and 69 and the lower surface of the substrate portion 67 is slightly larger than the thickness t of the metal plate constituting the vehicle body side bracket 11b ( H> t).

  The locking capsule 47c having the above-described configuration is formed in a state where the base plate portion 67 is superposed on the upper plate portion 70 provided at the upper end portion of the column side bracket 33. It is fixed by welding 71, 71. The upper plate portion 70 is provided in a state where the upper end edges of the pair of left and right support plate portions 34, 34 constituting the column side bracket 33 are continuous. In the case of this example, the dimension in the front-rear direction of the substrate part 67 is made smaller than the dimension in the same direction of the upper plate part 70 where the substrate part 67 is overlapped. Further, the front and rear end portions of the upper plate portion 70 are projected from the front and rear end edges of the substrate portion 67 in the front-rear direction in a state where the substrate portion 67 is superposed on the upper plate portion 70. The welds 71, 71 are applied between the front and rear end edges of the substrate portion 67 and the upper surfaces of the front and rear end portions of the upper plate portion 70. In the case of this example, these two welds 71 and 71 are fillet welds.

  In a state where the locking capsule 47c is welded and fixed to the center of the upper surface of the upper plate portion 70 of the column side bracket 33 as described above, the upper plate portion 70 and the flange portions 69, 69 Locking grooves 72, 72 are formed between the lower surface and part of the metal plate constituting the vehicle body side bracket 11b, into which both side portions of the locking notch 45a can be inserted. Therefore, while inserting both side portions of the locking notch 45a out of the metal plate into both the locking grooves 72, 72, the locking capsule 47c is placed at the inner back end of the locking notch 45a. Assemble. In this state, both the flange portions 69, 69 and both side portions of the locking notch 45a of the metal plate overlap. Therefore, the synthetic resin 56 is injection-molded into the small through holes 49a and 49b {or the small notches 55 as shown in FIG. 4A) provided in alignment with each other in the overlapping portion. The locking pins 50, 50 are configured. In this state, the locking capsule 47c and the column side bracket 33 are coupled to the vehicle body side bracket 11b so as to be able to be detached forward by an impact load at the time of a secondary collision.

  According to the structure of the present example configured as described above, tuning for stably displacing the steering wheel forward at the time of the secondary collision can be easily performed, and the body of the driver is instantly generated at the moment when the secondary collision occurs. In addition to alleviating the impact applied to the vehicle and enhancing the protection of the driver, it is possible to realize a structure that can be reduced in size, weight and cost, and can secure design freedom. That is, each of the locking capsules 47c and the column side bracket 33, which are each made of a metal plate, is coupled and fixed by welding, so that the tip of the bolt protrudes above the locking capsule 47c and the tip There is no need to screw the nut onto the screw. In short, only the pair of left and right flanges 69 and 69 out of the locking capsule 47c protrude from the upper surface of the vehicle body side bracket 11b. The thickness of the metal plate constituting the flanges 69, 69 is as small as about 2 to 4 mm in the case of a general steering column support device for passenger cars, for example. Moreover, no protrusions (for example, bolt heads) are present on the lower surface side of the upper plate portion 70. Therefore, an increase in assembly dimensions based on the presence of bolts and nuts can be suppressed, and a reduction in size and weight can be achieved. Further, the cost can be reduced based on the fact that the bolts and nuts are not required, and the degree of freedom in designing the steering device installation portion can be secured based on the downsizing.

  However, as in this example, the metal plate locking capsule 47c is used, and the gap between the locking capsule 47c and the column side bracket 33 and the vehicle body side bracket 11b is made of synthetic resin. The following issues arise when plugged. That is, when the left and right edges of the locking notches 45 formed in the vehicle body side bracket 11 are parallel to each other as in the structure of the previous invention shown in FIGS. The synthetic resin 56 may be a resistance against the forward displacement of the locking capsule 47c and the column side bracket 33 with respect to the vehicle body side bracket 11b. On the other hand, in the case of this example, the left and right inner edges of the locking notch 45a are inclined in a direction that gradually increases as the width dimension of the locking notch 45a moves forward. Immediately after the secondary collision, even if the synthetic resin 56 and the left and right side edges of the locking notch 45a are separated or rubbed, the surface pressure of the rubbed portion can be kept low. Therefore, it is possible to prevent the synthetic resin 56 and the left and right inner edges of the locking notch 45a from rubbing against each other, so that the steering wheel together with the locking capsule 47c and the column side bracket 33 can be made smoother. It can be displaced forward.

  This point will be described with reference to FIGS. 12 to 13 in addition to FIGS. When the metal plate-made locking capsule 47c is manufactured, the bending process shown in FIGS. 13A to 13C is performed on the metal plate 73 shown in FIG. To the locking capsule 47c shown in FIG. Of the locking capsule 47c thus obtained, the continuous portion between the lower surface of the substrate portion 67 and the outer surfaces of the pair of left and right rising portions 68, 68 has a quarter arc shape. A certain convex curved surface 74, 74 is formed. In such a state where the base plate portion 67 of the locking capsule 47c and the upper plate portion 70 of the column side bracket 33 are fixed by welding, the upper surface of the upper plate portion 70, the biconvex curved surfaces 74 and 74, and A wedge-shaped gap is formed between the two. When the locking pins 50 and 50 for connecting the locking capsule 47c and the column side bracket 33 and the vehicle body side bracket 11b are formed by injection molding of the synthetic resin 56, a part of the synthetic resin 56 is obtained. It enters into the wedge-shaped gap and solidifies within the gap. In particular, when the receiving portion formed on the vehicle body side bracket 11b is a small cutout portion 55 as shown in FIG. 4A, the synthetic resin 56 extends over the entire length in the gap. Get in.

  Thus, the fact that a part of the synthetic resin is solidified within the wedge-shaped gap itself prevents the locking capsule 47c and the joint between the column side bracket 33 and the vehicle body side bracket 11b from rattling. From the aspect, it is preferable. However, the inner surface of the wedge-shaped gap and the synthetic resin 56 solidified in the gap are in contact with each other over a wide area. The friction coefficient of the rubbing portion between the synthetic resin 56 and the locking capsule 47c and the column side bracket 33, each of which is made of metal, is small, but since the rubbing area is wide, these locking capsules are used at the time of a secondary collision. 47c and the column side bracket 33 are not preferable from the viewpoint of reducing the load required to displace forward. That is, the synthetic resin 56 having a pointed tip shape solidified within the gap remains attached to the vehicle body side bracket 11b as shown in FIG. Thus, the locking capsule 47c and the column side bracket 33 are displaced forward. If the locking capsule 47c and the column side bracket 33 are displaced forward while the synthetic resin 56 having a sharp tip is present in the wedge-shaped gap, the friction of the rubbing portion increases. This is disadvantageous in terms of stabilizing the load required to displace the steering wheel forward and enhancing the protection of the driver.

On the other hand, in the case of the structure of this example, the left and right side edges of the locking notch 45a are inclined in a direction that gradually increases as the width dimension of the locking notch 45a moves forward. Therefore, immediately after the secondary collision, the synthetic resin 56 tends to be separated from the surfaces of the locking capsule 47c and the column side bracket 33, which are mating surfaces. In other words, the synthetic resin 56 having a sharp tip easily escapes immediately from the wedge-shaped gap. Accordingly, the synthetic resin 56 and the locking capsule 47c and the surface of the column side bracket 33 are prevented from frictioning strongly, and the steering wheel together with the locking capsule 47c and the column side bracket 33 can be made smoother. Can be displaced forward.
Since the configuration and operation of the other parts are the same as in the case of the first example of the above-described embodiment, overlapping description is omitted.

[Eighth Example of Embodiment]
FIG. 14 shows an eighth example of the embodiment of the present invention corresponding to claims 1, 2, and 5-9. The structure of this example is incorporated in the vehicle body side bracket 11d incorporated in the third example of the embodiment shown in FIGS. 6 to 7 and the seventh example of the embodiment shown in FIGS. The locking capsule 47c made of a metal plate is combined.
Such a structure of this example can be obtained by combining the action / effect obtained by the third example of the embodiment and the action / effect obtained by the seventh example of the embodiment.
Since the configuration and operation of the other parts are the same as in the case of the first example of the above-described embodiment, overlapping description is omitted.

In the embodiment described above, the present invention is applied to a steering column support device having both a tilt mechanism for adjusting the vertical position of the steering wheel and a telescopic mechanism for adjusting the front-back position. Explained. However, the present invention is implemented by a steering column support device having only a tilt mechanism or only a telescopic mechanism, and further by a steering column support device having a fixed steering wheel position that does not have both of these mechanisms. You can also do it.
Further, when the present invention is carried out, it is not always necessary to press-fit a locking pin or injection-mold a synthetic resin in order to couple the locking capsule to the vehicle body side bracket. For example, a locking groove portion of the locking capsule can be press-fitted into a locking notch formed in the vehicle body side bracket, and the vehicle body side bracket and the locking capsule can be coupled.

DESCRIPTION OF SYMBOLS 1 Steering wheel 2 Steering gear unit 3 Input shaft 4 Tie rod 5, 5a, 5b Steering shaft 6, 6a, 6b, 6c Steering column 7 Universal joint 8 Intermediate shaft 9 Universal joint 10, 10a Housing 11, 11a, 11b, 11c, 11d Car body side brackets 12, 12a, 12b Column side brackets 13 Housing side brackets 14a, 14b Mounting plates 15a, 15b Notches 16a, 16b Sliding plates 17 Energy absorbing members 18 Locking notches 19 Locking capsules 20, 20a Locking grooves 21a, 21b Locking hole 22 Locking pin 23 Inner column 24 Outer column 25 Outer shaft 26 Ball bearing 27 Electric motor 28 Controller 29 Support cylinder 30 Center hole 31 Slit 32 Supported plate part 33 Column side block Ket 34 support plate portion 35 vertical slot 36 longitudinal slot 37 adjusting rod 38 head 39 nut 40 driving cam 41 driven cam 42 cam device 43 adjusting lever 44 friction plate unit 45, 45a, 45b, 45c Stop cutout 46 Mounting hole 47, 47a, 47b, 47c Locking capsule 48, 48a Hut 49a, 49b, 49c Small hole 50 Locking pin 51 Bolt 52 Nut 53 Locking groove 54 Rivet 55 Small cutout 56 Composite Resin 57 Gap 58 Drooping plate part 59 Energy absorbing member 60 Base part 61 Convex surface 62 Small hole 63 Corrugated part 64 Gap part 65 Clearance part 66 Extension part 67 Substrate part 68 Rising part 69 Gutter part 70 Upper plate part 71 Welding 72 Locking groove 73 Metal plate 74 Convex curved surface

Claims (9)

  A steering column for rotatably supporting the steering shaft on the inside, a vehicle body side bracket that is supported and fixed on the vehicle body side and does not displace forward in the event of a secondary collision, and a center part in the width direction of the vehicle body side bracket A locking notch formed on the front end edge side of the vehicle body side bracket formed on the side, a column side bracket supported on the steering column side and displaced forward together with the steering column at the time of a secondary collision, and the column side A locking capsule in which both ends are locked to the locking notches while being fixed to the bracket, and both left and right ends are positioned above the vehicle body side brackets at both side portions of the locking notches. The locking capsule and the vehicle body side bracket are assembled in a state where a part of the locking capsule is positioned inside the locking notch. In the steering column support device in which the column side bracket is supported with respect to the vehicle body side bracket so that the column side bracket can be detached forward by an impact load applied during a secondary collision. The right and left side edges of the portion with which the locking capsule is engaged at least before the secondary collision occurs are parallel to the central axis of the steering column, with respect to the center line of the locking notch A support device for a steering column, characterized in that they are inclined in directions opposite to each other and in a direction in which the width dimension of the locking notch in the left-right direction gradually increases toward the front.   Even when the length of the locking notch in the front-rear direction is larger than the length of the locking capsule in the same direction, and the locking capsule is displaced forward together with the steering column at the time of the secondary collision, the locking capsule 2. The steering column support device according to claim 1, wherein at least a part of the steering column is positioned above the front end portion of the vehicle body side bracket and has a length sufficient to prevent the locking capsule from falling off.   The left and right side edges of a portion of the locking notch that is exposed forward of the locking capsule before the secondary collision occurs are also opposite to each other with respect to the center line of the locking notch. The steering column support device according to claim 2, wherein the steering column support device is inclined in a direction and a direction in which the width dimension of the locking notch in the left-right direction gradually increases toward the front.   Of the portion of the locking notch that is exposed forward of the locking capsule before the secondary collision occurs, at least the first half is parallel to the center line of the locking notch. The support device for a steering column according to claim 2, wherein   Of the portions of the locking notches that are exposed forward of the locking capsules before the secondary collision occurs, at least the first half portion is relative to the center line of the locking notches, The tilted in the opposite direction to the left and right side edges of the portion where the locking capsule is engaged before the secondary collision occurs, and the width dimension of the at least the first half portion gradually decreases toward the front. The steering column support device described in 2.   Of the portion exposed to the front of the locking capsule before the secondary collision occurs at the front portion of the vehicle body side bracket, the left and right side portions of the locking notch are wave-shaped in the front-rear direction. Item 6. The steering column support device according to any one of Items 2 to 5.   The locking capsule and the vehicle body side bracket are coupled by a plurality of coupling members that are broken by an impact load applied based on the secondary collision, and each coupling member is an upper half of the locking capsule. A small through hole formed in a flange provided so as to protrude at least from the left and right sides, and a portion of the vehicle body side bracket that is aligned with each small through hole. Is formed by injection molding a synthetic resin between the receiving portion formed in the portion that matches with the inner surface of the locking notch and the locking capsule. It entered between the surface which opposes this inner surface, and block | closed at least one part of the clearance gap which exists between these each surface, It described in any one of Claims 1-6 Steering column support device   Each of the receiving portions is a small notch opening in the locking notch, and each of the small through holes and a part of the synthetic resin injected into each of the small notches are The steering column support device according to claim 7, wherein a gap existing between the left and right inner edges and a surface of the locking capsule facing the both side edges is closed over the entire length.   The column side bracket and the locking capsule are made of a metal plate that can be welded to each other, and the locking capsule of the column side bracket and the locking capsule is formed on the upper surface of the upper plate portion provided at the upper end of the column side bracket. At least the secondary collision occurs between the substrate portion welded and fixed to the upper plate portion in a state of being overlapped with the portion, and the locking notch bent upward from both widthwise end portions of the substrate portion. A pair of left and right rising portions inclined in the same direction as the left and right side edges of the portion where the locking capsule has been previously engaged, and opposite directions outward from the upper end of the both rising portions with respect to the substrate portion. The column side bracket and the locking capsule are welded to each other, and the locking notch of the vehicle body side bracket is The side portion is detachably engaged between an upper surface of the column side bracket and a lower surface of the both flanges based on impact energy applied to the column side bracket at the time of the secondary collision. The support device for steering columns described in any one of -8.

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