JPH0442215Y2 - - Google Patents

Description

[Detailed explanation of the idea] [Industrial application field]

This invention relates to a steering wheel equipped with an impact energy absorbing device.

[Conventional technology]

Conventionally, as an energy absorption structure of a steering wheel, for example, as shown in Fig. 7 (Japanese Patent Application Laid-open No.
No. 58-152660, US Pat. No. 4,098,525), a configuration is known in which the steering wheel has a rim portion 1, spoke portions 2, and a hub portion 3, and the hub portion 3 is covered with a cover pad 5 and fixed to the steering shaft 4. ing. An energy absorbing member (not shown) is provided inside the cover pad 5 to absorb impact energy at the time of a vehicle collision and prevent the driver from being hit in the chest.

[Problem that the idea aims to solve]

However, in the case of conventional devices, the energy absorbing member is easily deformed when the driver's body collides from the direction of arrow A, for example, whereas the energy absorbing member is easily deformed when the driver's body collides from a different direction, for example from the direction of arrow B or arrow C. In this case, the energy absorbing member is difficult to deform and generates a larger reaction force than in the A direction, and the energy absorption properties differ depending on the direction of collision, making it difficult to obtain uniform shock absorbing performance. Ta.

[Means to solve the problem]

In order to solve such problems, this invention provides a steering wheel in which an impact energy absorption device is provided between a hub portion attached to the tip of the steering shaft and a cover pad that covers the hub portion, the impact energy absorption device comprising: a hub-side fixing plate fixed on the hub portion and having a substantially U-shaped cross section and absorbing energy through cross-sectional deformation;
A cover-side fixing plate is arranged on the inner surface of the cover pad apart from the hub-side fixing plate, and is interposed and fixed between the hub-side fixing plate and the cover-side fixing plate so that the central axis is along a substantially horizontal direction. , a cylindrical impact energy absorbing member having a predetermined length that absorbs energy through deformation, and the hub side fixing plate includes a fixing surface portion to which the impact energy absorbing member is fixed, and legs extending from the fixing surface portion. It is formed into a substantially U-shaped cross section from the part, and
A steering wheel with an impact energy absorbing device, wherein a high rigidity portion is formed at both ends of the cylindrical impact energy absorbing member, and the high rigidity portion is interposed and fixed between the hub side fixing plate and the cover side fixing plate. It is characterized by what it did.

[Effect]

According to this means, when the driver's body collides with the cover pad during a vehicle collision, this impact force is input to the impact energy absorbing member via the cover side fixing plate. In this case, the cover-side fixing plate is spaced apart from the hub-side fixing plate, and most of the impact force input to the cover-side fixing plate is first input to the impact energy absorbing member. The impact force is absorbed by the deformation of the In this case, even if impact forces are applied from different directions, since the impact energy absorbing member has a cylindrical shape, the deformation characteristics will be approximately the same, and the impact energy absorption characteristics will be good against impact forces from each direction. be. For example, even if an impact force acts on the corner of the cover pad from an oblique direction of the cylindrical impact energy absorbing member, the cover side fixing plate immediately faces the direction of the impact force, allowing a large area to receive the impact force. . In other words, since the cover-side fixing plate is separated from the hub-side fixing plate and is connected only to the impact energy absorbing member, and the hub-side fixing plate has a U-shaped cross section, the force causes the hub-side fixing plate to By inclining the leg portion and inclining the fixing surface portion, the cover-side fixing plate immediately faces in a direction substantially perpendicular to the direction in which the impact force is applied, and can receive the impact force over a large area.
When the impact force is applied to such a large area, the impact force is not concentrated and the energy absorption characteristics are better than when the impact force is applied to a small area. Moreover, since the relative position of the impact energy absorbing member that primarily absorbs energy and the cover side fixing plate that transmits force to the impact energy absorbing member does not change due to the tilting of the fixed surface portion, the impact input to the impact energy absorbing member is not changed. The state can always be the same, and substantially the same energy absorption characteristics can be obtained. Moreover, in this case, the impact energy absorbing member initially tries to twist and deform due to the impact force from the diagonal direction, but as described above, the fixing surface of the hub side fixing plate is approximately perpendicular to the direction of force action. Therefore, the impact energy absorbing member can collapse and absorb impact energy without receiving a large twisting force.
In this case, since the impact energy absorbing member has a cylindrical shape, the crushing characteristics can be made substantially the same even if the direction of the impact force is different. In this way, according to the present invention, by deforming the hub-side fixing plate, impact force can always be input to the impact energy absorbing member in the same state, so even if impact force is applied from different directions. , approximately the same energy absorption characteristics are obtained. At this time, the hub side fixing plate also deforms and absorbs the impact energy, but as the legs etc. are tilted as mentioned above, it is not able to absorb that much impact energy, and for the most part, The impact energy is absorbed by the deformation of the impact energy absorbing member. Since this hub-side fixing plate has an asymmetrical shape, it is difficult (though not impossible) to make the energy absorption characteristics the same regardless of the direction of the impact force. However, in the present invention, as described above, the impact energy absorbed by the hub-side fixing plate is not so large, and most of it is absorbed by the impact energy absorbing member. As described above, the impact energy absorbing member has substantially the same energy absorption characteristics regardless of the direction of the impact force. Therefore, compared to conventional systems that do not use a cylindrical impact energy absorbing member or a substantially U-shaped hub-side fixing plate, the impact energy absorbing device as a whole has improved impact energy absorption characteristics in each direction. , it is possible to approach the same characteristics as before.

【Example】

This invention will be explained below based on each example. 1 to 4 are diagrams showing an embodiment of this invention. First, to explain the structure, the steering wheel of this embodiment has a rim portion 11, spoke portions 12, and a hub portion 13 that are continuously formed, and a cover pad 14 that covers the hub portion 13 is attached.
An impact energy absorbing device 15 is provided inside the cover pad 14, that is, between the cover pad 14 and the hub portion 13. In the hub portion 13, a core member 16 extending from the spoke portion 12 side is fixed to a boss portion 17 by welding or the like.
are fitted and fixed with nuts 21. Further, the cover pad 14 is made up of a core material 22 and a pad 23, and is attached to cover the boss portion 17. On the other hand, the impact energy absorbing device 15 includes hub side and cover side fixing plates 24, 25, and a cylindrical impact energy absorbing member 36 of a predetermined length fixed therebetween. The hub-side fixing plate 24 forms a second energy absorbing member, and has a rectangular opening 24b formed in a fixing surface portion 24a to which a cylindrical impact energy absorbing member 36, which is a first energy absorbing member, is fixed. A pair of legs 24c ₁ and 24c ₂ bent into a hook-shaped cross section extend from both sides of the fixing surface 24a, and the mounting surface 24d of the legs 24c is attached to the core 16 of the hub 13. is fixed. The pair of leg portions 24c ₁ and 24c ₂ and the fixed surface portion 24a form a substantially U-shaped cross section. The impact force is absorbed by the cross-sectional deformation of the hub-side fixing plate 24. Further, the cover side fixing plate 25 has a fixing surface portion 25a to which the impact energy absorbing member 36 is fixed.
A rectangular opening 25b is formed in the opening 25b, and flanges 25c are formed extending from both sides of the fixing surface 25a, and the fixing surface 25a is fixed to the core 22 of the cover pad 14. The cover-side fixing plate 25 is set apart from the hub-side fixing plate 24. Further, the impact energy absorbing member 36 has a cylindrical shape with a predetermined length that absorbs energy through deformation, and has grooves 36c formed at both ends to form a high rigidity portion. The lower part 36a of this groove 36c is inserted into the opening 24b of the hub-side fixing plate 24 and fixed by welding or the like, and the upper part 36a
6b is the opening 25 of the cover side fixing plate 25
b and are fixed by welding or the like, and both fixing plates 24,
It is interposed and fixed between 25. Next, the operation of the steering wheel equipped with an impact energy absorbing device constructed as described above will be explained. In the event of a vehicle collision, the driver moves forward due to inertia and collides with the steering wheel.
C, . . . will hit the cover pad 14 from various directions. Since the cover-side fixing plate 25 is provided over substantially the entire back surface of the cover pad 14, force is always transmitted when the occupant comes into contact with the cover pad. This impact force is input to the hub-side fixing plate 24 via the groove 36c of the impact energy absorbing member 36, and is absorbed by the deformation of both. in this case,
The cover side fixing plate 25 and the hub side fixing plate 24 are spaced apart, and the hub side fixing plate 2
4 has a U-shaped cross section, and since the cylindrical impact energy absorbing member 36 is interposed between them, the impact energy absorbing member 36 can be effectively deformed no matter which direction force is applied. ,
This deformation absorbs the impact force. For example, even if an impact force acts on the corner of the cover pad 14 from an oblique direction (for example, the direction of arrow B in FIGS. 1 and 4) of the cylindrical impact energy absorbing member 36, the cover pad 14 is fixed in the direction in which the load is applied. The plate 25 is immediately oriented and can receive impact forces over a large area. That is, in the present invention, the cover side fixing plate 25 is connected only to the impact energy absorbing member 36, which is the first energy absorbing member, and the hub side fixing plate 24 has a substantially U-shaped cross section. Therefore, due to the impact force in the direction of arrow B, the leg portion 24c ₁ in the direction opposite to the pressing direction is displaced in the pressing direction, as shown by the dashed line in FIG.
The other leg portion 24c ₂ is displaced toward the steering shaft 18 side. As a result, the fixed surface portion 24a is
By tilting in a direction substantially perpendicular to the direction of arrow B, the cover-side fixing plate 25 also immediately faces in a direction substantially perpendicular to the direction of arrow B, and can receive impact force over a large area. Therefore, in the present application, since the impact force is received over a large area, the impact force is not concentrated compared to the case where the impact force is applied to only a portion, and the energy absorption property is good. Moreover, in this way, the fixed surface portion 24
By tilting, the impact energy absorbing member 36 which mainly absorbs energy and the cover side fixing plate 25 which transmits force to the impact energy absorbing member 36.
Since the relative position with respect to the impact energy absorbing member 36 does not change, the impact input to the impact energy absorbing member 36 can always be kept in the same state, and substantially the same energy absorption characteristics can be obtained. Furthermore, at this time, the impact energy absorbing member 36 initially tries to twist and deform due to the impact force from the diagonal direction, but as described above, the fixing surface portion 24a of the hub side fixing plate 24 Since the structure is substantially vertical, the impact energy absorbing member 36 can collapse and absorb impact energy without being subjected to a large twisting force. In this case, since the impact energy absorbing member 36 has a cylindrical shape, the crushing characteristics can be substantially the same even if the direction of the impact force is different. Note that when an impact force in the direction of arrow C is applied, the legs 24c ₁ and 24c ₂ tilt in the opposite direction to the above as shown by the two-dot chain line in FIG. 4, and the fixed surface part 24a becomes approximately perpendicular to the direction of arrow C By tilting in the direction, the same effect as above is produced. At this time, the hub-side fixing plate 24 also deforms and absorbs the energy, but since the leg portions 24c ₁ and the like are tilted as described above, it is not possible to absorb that much impact energy, and most of the impact energy is is absorbed by the deformation of the impact energy absorbing member 36. Since the hub-side fixing plate 24 has an asymmetrical shape, it is difficult (though not impossible) to make the energy absorption characteristics the same regardless of the direction of the impact force. However, in the present invention, as mentioned above,
The impact energy absorbed by the hub-side fixing plate 24 is not so large, and most of it is absorbed by the impact energy absorbing member 36. As described above, the impact energy absorbing member 36 has substantially the same energy absorption characteristics regardless of the direction of the impact force. Therefore, unlike the conventional case, the cylindrical impact energy absorbing member 36 and the substantially U-shaped hub side fixing plate 2 are not used.
4, the impact energy absorption characteristics of the impact energy absorbing device 15 as a whole in each direction can be made closer to the same characteristics as before. FIG. 5 shows a modification of the impact energy absorbing member 36 of the above embodiment. The impact energy absorbing member 46 shown in FIG. 5 has a cylindrical main body 46a with a swollen intermediate portion 46b, and a lid member 46d as a high-rigidity portion that closes the opening is attached to both ends 46c of a cylindrical main body 46a with a bulged intermediate portion 46b. A pull-out hole 46e is provided, and the rigidity of both ends 46c is further improved than that described above. Therefore, by controlling the rigidity of both ends, the energy absorption characteristics of the impact energy absorption device 15 can be easily adjusted. According to these, when an impact force acts on the approximately central portion of the impact energy absorbing members 36, 46, the central portion is deformed and then both end portions 36c, 46c are deformed, so that energy absorption occurs in two stages. characteristics will be obtained. Further, according to the modification shown in FIG. 5, since the high-rigidity portion 46d is a lid member, impact force can be transmitted reliably. FIG. 6 shows still another modification of this embodiment. In this embodiment, a plurality of energy absorbing members 50 similar to those shown in FIG. 5 are connected using a connecting cylinder 51. According to such a configuration, the plurality of lid members 50a
Because of this, no matter where on the cylindrical shaft an impact force is applied, there is little change in rigidity depending on the load position, and stable energy absorption characteristics can be obtained.

[Effect of the idea]

As explained above, according to this idea,
The impact energy absorbing member has a cylindrical shape, and is fixed to the hub side fixing plate which has a U-shaped cross section.Furthermore, since the hub side fixing plate and the cover side fixing plate are separated from each other, the impact energy absorbing member has a cylindrical shape. The crushing characteristics when subjected to impact can be brought closer to the same characteristics as conventional products, and it has the practical effect of being able to provide effective cushioning in response to changes in vehicle collision conditions, etc. do.

[Brief explanation of the drawing]

1 to 4 are views showing an embodiment of a steering wheel with an impact energy absorbing device of this invention, FIG. 1 is a side view with main parts cut away, and FIG. 2 is a perspective view showing the impact energy absorbing device. Fig. 3 is a sectional view of the impact energy absorbing member, Fig. 4 is an explanatory view showing a deformed state of the hub side fixing plate, and Figs. 5 and 6 are sectional views showing modified examples of the impact energy absorbing member, respectively. , FIG. 7 is a side view showing a conventional steering wheel. 13...Hub part, 14...Cover pad, 15
... Shock energy absorption device, 18 ... Steering shaft, 24 ... Hub side fixing plate, 24
a...Fixed surface part, 24c ₁ , 24c ₂ ... Leg part, 25
...Cover side fixing plate, 36, 46, 50...
...Impact energy absorbing member, 36c...Groove (highly rigid part), 46d...Lid member (highly rigid part), 50a...
...Lid member (high rigidity part).

Claims (1)

[Claims for Utility Model Registration] In a steering wheel in which an impact energy absorption device is provided between a hub portion attached to the tip of the steering shaft and a cover pad that covers the hub portion, the impact energy absorption device is provided between the hub portion and the cover pad that covers the hub portion. a hub-side fixing plate with a substantially U-shaped cross section that is fixed on the top and absorbs energy through cross-sectional deformation; a cover-side fixing plate that is spaced from the hub-side fixing plate and arranged on the inner surface of the cover pad; and the hub-side fixing plate. Between the fixed plate and the cover side fixed plate,
Interposed and fixed so that the central axis is along the approximately horizontal direction,
The hub side fixing plate has a cylindrical impact energy absorbing member having a predetermined length that absorbs energy through deformation, and the hub side fixing plate includes a fixing surface portion to which the impact energy absorbing member is fixed, and a leg portion extending from the fixing surface portion. The cylindrical impact energy absorbing member is formed with a substantially U-shaped cross section, and a high-rigidity portion is formed at both ends of the cylindrical impact energy absorbing member, and the high-rigidity portion is formed between the hub-side fixing plate and the cover-side fixing plate. A steering wheel with an impact energy absorbing device characterized by having a rigid part interposed and fixed.