JP7013125B2 - Handle core - Google Patents

Description

The present invention relates to, for example, a core metal of a steering wheel for a vehicle.

Conventionally, in a vehicle such as an automobile, a rim portion that forms an annular shape and is gripped by an occupant, a boss portion that is located inside the rim portion and is connected to the steering shaft, and these rim portions and the boss portion are connected to each other. A steering wheel, which is a steering wheel with a plurality of spokes, is used. And this steering wheel is equipped with a metal core metal. A rim core metal portion, a boss core metal portion, and a plurality of spoke core metal portions corresponding to each of the rim portion, the boss portion, and each spoke portion are set in the core metal portion.

When improving the operability of the steering wheel, the rim part (rim core metal part) is used to suppress the vibration of the engine transmitted through the steering shaft, which is the steering shaft, and the vibration generated by the reaction force from the road surface during driving. ) Can be made heavy. However, when the rim portion (rim core metal portion) is made heavy in this way, there is a concern that the moment of inertia will increase and the resonance frequency of the steering wheel will decrease, and the desired characteristics will not be satisfied.

In this respect, for example, a steering wheel is known that improves operability while maintaining a resonance frequency by connecting adjacent spoke cores to improve the rigidity of the core (for example, Patent Document 1). reference.).

JP-A-2005-14641 (Pages 3-6, FIGS. 1 and 2)

On the other hand, from the viewpoint of occupant protection, the steering wheel is designed so that the strength at the lower end of the rim portion (rim core metal portion) is set to a predetermined level or less, and the occupant who has moved forward due to an impact such as a collision hits the steering wheel. It is desirable to deform when in contact and suppress the reaction force.

Therefore, it is required to satisfy various performances such as the weight of the steering wheel, the moment of inertia, the resonance frequency, and the strength at the lower end of the rim portion.

The present invention has been made in view of such a point, and an object of the present invention is to provide a core metal of a handle whose performance of the handle can be easily adjusted.

The core metal of the handle according to claim 1 includes a boss core metal portion connected to a steering shaft, a rim core metal portion located surrounding the boss core metal portion, and these boss core metal portions and rim core metal portions. It is provided with a plurality of spoke core metal portions that connect the portions on both sides and the lower portion, respectively, and the rim core metal portion is located between the spoke core metal portions on both sides and the spoke core metal portion on the lower portion. Each of the weak portions is provided with a weak portion, and the boss core metal portion connects the boss core metal main body portion, the spoke core metal portions on both sides at positions parallel to the weak portions, and the spoke core metal portion at the lower portion. A connecting portion is provided, and the boss core metal main body portion of the boss core metal portion, the rim core metal portion, and the connecting portion of the boss core metal portion are positioned differently from each other in the axial direction of the steering shaft. The connecting portion of the boss core metal portion is arranged along a virtual plane substantially parallel to each other, and the connecting portion of the boss core metal portion includes the boss core metal body portion of the boss core metal portion and the rim core metal portion in the axial direction of the steering shaft. It is located between.

The core metal of the handle according to claim 2 is the core metal of the handle according to claim 1, wherein a plurality of lower spoke core metal portions are provided.

According to the core metal of the handle according to claim 1, the steering of the boss core metal body portion , the rim core metal portion, and the connecting portion of the boss core metal portion of the boss core metal portion is connected to the boss core metal portion. The positions are different from each other in the axial direction of the shaft and are arranged along a virtual plane substantially parallel to each other, and the position of the connecting portion of the boss core is set to the position of the boss core of the boss core in the axial direction of the steering shaft. In addition to being between the main body and the rim core, each weak part is provided at the position between the spoke core on both sides and the lower spoke core at the rim core, and the boss core is provided. The boss core metal portion can be formed as a box-shaped rigid body portion by providing a connecting portion connecting the spoke core metal portions on both sides and the lower spoke core metal portion at a position parallel to each weak portion. Therefore, the increase / decrease of the resonance frequency can be suppressed, the stress can be concentrated on the weak part at the time of contact with the occupant, the reaction force to the occupant can be easily adjusted by the weak part, and the wall thickness of the boss core metal part can be increased. The resonance frequency can be adjusted without changing the moment of inertia by increasing or decreasing. Therefore, the performance of the handle such as weight, moment of inertia, resonance frequency and reaction force can be easily adjusted.

According to the core metal of the handle according to claim 2, in addition to the effect of the core metal of the handle according to claim 1, by using a plurality of spoke core metal portions at the lower portion, the handle has four or more spoke portions. I can handle it.

It is a front view which shows the core metal of the handle of 1st Embodiment of this invention. It is a side view of the same as above core metal. It is a front view which shows the handle provided with the same-top core metal. It is a graph which shows the example of the relationship between the bending load for every cutting amount of the weak part of the core metal, and the deformation amount of the core metal. It is a front view which shows the core metal of the handle of the 2nd Embodiment of this invention.

Hereinafter, the configuration of the first embodiment of the present invention will be described with reference to the drawings.

In FIG. 3, reference numeral 10 denotes a steering wheel which is a steering wheel as an automobile part, and the steering wheel 10 is arranged in front of an occupant in the driver's seat of the automobile, and has a steering wheel main body 11 which is a steering wheel main body and the steering wheel main body 11. It is composed of a module 12 which is an installation body attached to the occupant side of the steering wheel main body 11 and a cover body as a covering member (not shown) attached to the anti-occupant side of the steering wheel main body 11, that is, the side opposite to the module 12. There is. Further, a finisher (garnish) or the like as a decorative member (not shown) is attached to the steering wheel 10 on the occupant side of the steering wheel main body 11, if necessary. As the module 12, for example, an airbag device containing an airbag is preferably used, but instead of the airbag device, for example, a pad body containing a shock absorber or a mere horn having no internal inclusion is used. Any other device, such as a pad, can also be used.

The steering wheel 10 is usually mounted on a steering shaft, which is a steering shaft as a steering device (not shown) provided in a state of being tilted with respect to the horizontal direction (vertical direction). The 12 side is the occupant side, the front side or the rear side (arrow RR side shown in FIG. 2), and the steering shaft side is the vehicle body side, the back side or the front side (arrow FR side shown in FIG. 2), and the front and rear along this steering shaft. The direction is the axial direction, and the horizontal direction (arrows L and R directions shown in FIG. 1 and the like) and the vertical direction (arrows U and D directions shown in FIG. 1 and the like) with respect to the straight direction of the vehicle body provided with the steering wheel 10. ) And other directions. Further, the steering wheel 10 will be described as a neutral state unless otherwise specified.

The steering wheel 10 (steering wheel body 11) has a rim portion (ring portion) 21 forming an annular shape (donut shape) and a boss portion (a hub portion) as a central portion located inside the rim portion 21. It is composed of a mount portion) 22 and a plurality of spoke portions 23 connecting the rim portion 21 and the boss portion 22. Further, the steering wheel 10 (steering wheel main body 11) includes the core metal 25 shown in FIGS. 1 and 2. Further, the steering wheel 10 (steering wheel main body 11) includes a covering portion 26 shown in FIG. The rear side of the steering wheel 10 (steering wheel main body 11) is covered with a cover body (not shown).

The rim portion 21 is located so as to surround the outside of the boss portion 22. In the present embodiment, the rim portion 21 is continuously provided in an annular shape.

The number of spoke portions 23 can be set variously depending on the vehicle type and the like, but in the present embodiment, for example, three spoke portions are set on both left and right sides and a lower portion. That is, the spoke portions 23 include side spoke portions 23a and 23b located on both upper left and right sides, and lower spoke portions 23c located at the lower portion. The side spoke portion 23a extends along the left-right direction so as to connect the left side portion of the boss portion 22 and the analog clock 9 o'clock position of the rim portion 21. Further, the side spoke portion 23b extends along the left-right direction so as to connect the right side portion of the boss portion 22 and the analog clock 3 o'clock position of the rim portion 21. Further, the lower spoke portion 23c extends in the vertical direction so as to connect the lower portion of the boss portion 22 and the analog clock 6 o'clock position of the rim portion 21. Therefore, the spoke portions 23 are arranged in a T shape when viewed from the front.

The core metal 25 shown in FIGS. 1 and 2 is made of metal, which is integrally formed of a metal such as aluminum or iron. The core metal 25 corresponds to the rim portion 21, the boss portion 22, and the spoke portion 23 (FIG. 3), and includes an arcuate rim core metal portion 31, a boss core metal portion 32, and a spoke core metal portion 33. There is.

The rim core metal portion 31 constitutes the rim portion 21 (FIG. 3). The rim core metal portion 31 is formed in an annular shape in the present embodiment. The rim core metal portion 31 includes a spoke connecting portion 36. Further, the rim core metal portion 31 includes a rim connecting portion 37. Further, the rim core metal portion 31 includes a easily deformable portion 38 which is a weak portion (fragile portion).

The spoke connecting portion 36 is a portion to which the end portion of the spoke core metal portion 33 opposite to the boss core metal portion 32 is connected. In the present embodiment, the spoke connecting portion 36 is arranged corresponding to the spoke core metal portion 33. That is, the spoke connecting portions 36 are arranged on both the left and right side portions and the lower portion of the rim core metal portion 31. In other words, the spoke connecting portions 36 are arranged in the analog clock 9 o'clock direction, 3 o'clock direction and 6 o'clock direction of the rim core metal portion 31, respectively. Therefore, in the present embodiment, the spoke connecting portion 36 includes left and right (one and other) side spoke connecting portions 36a and 36b, and a lower spoke connecting portion 36c located at the lower part. The spoke connecting portion 36 is formed in a short arc shape. The spoke connecting portion 36 may be provided integrally with the spoke core metal portion 33.

The rim connecting portion 37 is a portion of the rim core metal portion 31 that constitutes a portion other than the spoke connecting portion 36. That is, in the present embodiment, the rim connecting portion 37 is arranged at the upper portion and the lower both side portions of the rim core metal portion 31. In other words, the rim connecting portion 37 includes an upper rim connecting portion 37a and (one and the other) lower rim connecting portions 37b and 37c. The rim connecting portion 37 is formed in an arc shape that connects the terminal portions of the spoke connecting portions 36 to each other. The rim connecting portion 37 is formed to be longer than the spoke connecting portion 36. Further, the rim connecting portion 37 is formed in a columnar shape having an outer diameter smaller than that of the spoke connecting portion 36. That is, the rim connecting portion 37 is composed of a solid metal rod.

The upper rim connecting portion 37a connects the upper portions of the left and right spoke connecting portions 36 to each other. That is, the upper rim connecting portion 37a connects the upper portions of the side spoke connecting portions 36a and 36b. The upper rim connecting portion 37a is formed in an arc shape longer than the lower rim connecting portions 37b and 37c. The upper rim connecting portion 37a is arranged in the rim core metal portion 31 over a range of, for example, 10 o'clock to 2 o'clock of an analog clock.

The lower rim connecting portion 37b connects the lower portion of the left spoke connecting portion 36 and the left side of the lower spoke connecting portion 36. That is, the lower rim connecting portion 37b connects the side spoke connecting portion 36a and the lower spoke connecting portion 36c. Further, the lower rim connecting portion 37b is arranged in the rim core metal portion 31 over a range of, for example, 7 o'clock to 8 o'clock of an analog clock.

Similarly, the lower rim connecting portion 37c connects the lower portion of the right spoke connecting portion 36 and the right side of the lower spoke connecting portion 36. That is, the lower rim connecting portion 37c connects the side spoke connecting portion 36b and the lower spoke connecting portion 36c. Further, the lower rim connecting portion 37c is arranged in the rim core metal portion 31 over a range of, for example, 4 o'clock to 5 o'clock of an analog clock.

The lower rim connecting portions 37b and 37c are arranged at positions substantially symmetrical with respect to the rim core metal portion 31.

The easily deformable portion 38 bends and deforms the rim portion 21 (rim core metal portion 31) toward the front by abutting on the rim portion 21 (FIG. 3) of the occupant, so that the steering wheel 10 (FIG. 3) is transferred to the occupant. It is a part that suppresses the reaction force of. That is, the easily deformable portion 38 is adapted to release the impact due to the contact of the occupant by deforming the rim core metal portion 31 (rim portion 21 (FIG. 3)). The easily deformable portion 38 is provided in a part of the rim connecting portion 37. More specifically, the easily deformable portion 38 is provided at a position between the spoke core metal portions 33 on both sides and the spoke core metal portion 33 on the lower side. In the present embodiment, the easily deformable portion 38 is provided in a part of the lower rim connecting portions 37b and 37c. That is, the easily deformable portion 38 is arranged on both lower side portions of the rim core metal portion 31. Further, the easily deformable portion 38 is arranged at a position substantially symmetrical in the rim core metal portion 31. The easily deformable portion 38 is provided, for example, by cutting the counter-occupant side of the rim connecting portion 37, that is, the front side which is the back side of the rim connecting portion 37. Therefore, the easily deformable portion 38 is a thin-walled portion provided so as to reduce the cross-sectional area of the rim core metal portion 31. The easily deformable portion 38 is provided so as to be thinner than the rest of the rim core metal portion 31.

The boss core metal portion 32 is a portion connected to the steering shaft. That is, the boss core metal portion 32 includes a boss 41 that is connected to the steering shaft and serves as the rotation center of the steering wheel 10. Further, the boss core metal portion 32 includes a boss core metal body portion 42 connected to the spoke core metal portion 33. Further, the boss core metal portion 32 includes a connecting portion 43. Further, the boss core metal portion 32 includes a support portion 44 that supports the module 12. The boss core metal portion 32 may be provided with a contact for a horn switch. The boss core metal portion 32 is located on the front side with respect to the rim core metal portion 31.

The boss 41 is integrally provided with the boss core metal main body portion 42.

The boss core metal main body 42 is provided with an upper portion extending along the left-right direction and a lower portion extending along the vertical direction. That is, the boss core metal body portion 42 has side boss core metal body portions 42a and 42b connected to the left and right spoke core metal portions 33 and a lower boss core metal body portion 42c connected to the lower spoke core metal portion 33. And have. More specifically, in the boss core metal body portion 42, the side spoke core metal portions 33a and 33b (one and the other) described later and the side boss core metal body portions 42a and 42b are connected to each other, and the lower spoke core metal portions 42a and 42b are connected to each other. The portion 33c and the lower boss core metal main body portion 42c are connected to each other. Therefore, the boss core metal main body 42 is provided in a substantially T shape when viewed from the front. Further, in the boss core metal main body portion 42, in the present embodiment, the lower boss core metal main body portion 42c is composed of a pair of elongated core metal bodies 42c1 and 42c1. These core bodies 42c1 and 42c1 are separated from each other to the left and right and arranged linearly along the vertical direction, and are substantially parallel to each other.

The connecting portion 43 connects the spoke core metal portions 33 on both sides and the spoke core metal portions 33 on the lower side. That is, the connecting portion 43 connects the side spoke core metal portions 33a and 33b and the lower spoke core metal portion 33c, respectively. In other words, the connecting portion 43 spans between the side spoke core metal portion 33a and the lower spoke core metal portion 33c, and between the side spoke core metal portion 33b and the lower spoke core metal portion 33c. It is provided. More specifically, the connecting portion 43 is formed between the lower portion of the side spoke core metal portion 33a and the left side portion of the lower spoke core metal portion 33c, and the lower portion and the lower spoke core metal portion of the side spoke core metal portion 33b. It is provided so as to be bridged between the right side of 33c and the right side. Further, the connecting portion 43 includes the end portion of the side spoke core metal portions 33a and 33b on the boss core metal portion 32 (boss core metal main body portion 42) side and the boss core metal portion 32 of the lower spoke core metal portion 33c (the boss core metal portion 32 (). It is connected to the end of the boss core metal body 42) side. That is, the connecting portion 43 is between the right end portion of the side spoke core metal portion 33a and the left end portion of the upper end portion of the lower spoke core metal portion 33c, and the left end portion of the side spoke core metal portion 33b and the lower spoke. It is located between the core metal portion 33c and the right side of the upper end portion. Therefore, the connecting portion 43 is provided at a position parallel to each easily deformable portion 38 of the rim core metal portion 31. In other words, the connecting portion 43 is inclined toward the center side in the left-right direction of the core metal 25 from the upper side (side spoke core metal portions 33a, 33b side) to the lower side (lower spoke core metal portion 33c side). Arranged to do. In the present embodiment, the connecting portion 43 is provided at a position parallel to the lower rim connecting portions 37b and 37c. Therefore, the boss core metal portion 32 is provided by the boss core metal main body portion 42 and each connecting portion 43 so as to surround the triangular space portion S on both the left and right sides of the lower portion. Further, in this connecting portion 43, the upper portion 43a, which is one end portion connected to the side spoke core metal portions 33a, 33b, is connected to the lower side portion 43b, which is the other end portion connected to the lower spoke core metal portion 33c. It is provided so that it becomes thicker in comparison.

The support portion 44 is provided in a hook shape for hooking and holding the module 12, for example. The support portion 44 is arranged on both the left and right side portions and the lower portion of the boss core metal main body portion 42, for example.

The spoke core metal portion 33 connects the boss core metal portion 32 and the rim core metal portion 31 and extends radially. In the present embodiment, the spoke core metal portions 33 are set corresponding to all the spoke portions 23. Therefore, the spoke core metal portion 33 extends in both the upper left and right sides and downward. In other words, the spoke core metal portion 33 includes side spoke core metal portions 33a and 33b corresponding to the side spoke portions 23a and 23b, and a lower spoke core metal portion 33c corresponding to the lower spoke portion 23c. .. Therefore, the spoke core metal portions 33 are arranged in a T shape when viewed from the front in the present embodiment.

The side spoke core metal portion 33a is provided from the left side portion of the boss core metal portion 32 to the left side portion of the rim core metal portion 31. More specifically, the side spoke core metal portion 33a is provided by connecting the left side portion (side boss core metal body portion 42a) of the boss core metal body portion 42 and the side spoke core metal portion 36a. The side spoke core metal portion 33a extends in the left-right direction and is inclined forward from the boss core metal portion 32 side toward the rim core metal portion 31 side.

Similarly, the side spoke core metal portion 33b is provided from the right side portion of the boss core metal portion 32 to the right side portion of the rim core metal portion 31. More specifically, the side spoke core metal portion 33b is provided by connecting the right side portion (side boss core metal main body portion 42b) of the boss core metal main body portion 42 and the side spoke core metal portion 36b. The side spoke core metal portion 33b extends in the left-right direction and is inclined forward from the boss core metal portion 32 side toward the rim core metal portion 31 side.

The lower spoke core metal portion 33c is provided from the lower portion of the boss core metal portion 32 to the lower portion of the rim core metal portion 31. More specifically, the lower spoke core metal portion 33c is provided by connecting the lower portion of the boss core metal main body portion 42 (lower boss core metal main body portion 42c) and the lower spoke core metal portion 36c. The lower spoke core metal portion 33c extends in the vertical direction and is bent forward in a crank shape from the boss core metal portion 32 side toward the rim core metal portion 31 side. In the present embodiment, the lower spoke core metal portion 33c is composed of a pair of left and right spoke core metal bodies 33c1 and 33c1. These spoke core bodies 33c1 and 33c1 are separated from each other to the left and right, along the vertical direction, and are arranged substantially parallel to each other when viewed from the front. These spoke core bodies 33c1 and 33c1 are integrally connected to the core metal bodies 42c1 and 42c1, respectively, and are arranged on the extensions of these core metal bodies 42c1 and 42c1. These two spoke core bodies 33c1 and 33c1 form one spoke portion 23 (lower spoke portion 23c) shown in FIG.

The covering portion 26 constitutes the design surface of the rim portion 21. The covering portion 26 is made of a synthetic resin molded from a soft synthetic resin (for example, a synthetic resin softer than the conjugate) such as polyurethane. The covering portion 26 is provided so as to cover the rim core metal portion 31 (FIG. 1) and the connecting portion between the rim core metal portion 31 and the spoke core metal portion 33 (FIG. 1). If necessary, a skin body such as leather or synthetic resin can be wrapped around the covering portion 26.

Then, when manufacturing the steering wheel 10, the core metal 25 is set in the molding die, and the reaction mixture is filled in the cavity of the mold, so that the reaction mixture reacts in the cavity and the core metal 25 is manufactured. A soft covering portion 26 made of polyurethane or the like is formed so as to cover the rim core metal portion 31 of the above and the connecting portion between the rim core metal portion 31 and the spoke core metal portion 33. Then, the steering wheel 10 (steering wheel body 11) on which the covering portion 26 is formed is removed from the mold, the skin is wound around the covering portion 26 as necessary, connected to the steering shaft, and then the module 12 is further required. The steering wheel 10 is completed by attaching the finisher and the finisher.

The steering wheel 10 manufactured in this way suppresses the vibration of the engine transmitted through the steering shaft during driving and the vibration generated by the reaction force from the road surface by making the rim portion 21 (rim core metal portion 31) heavier. Will be possible. On the other hand, the resonance frequency of the steering wheel 10 is usually inversely proportional to the increase or decrease in the weight of the rim portion 21 (rim core metal portion 31).

Therefore, in the present embodiment, in the boss core metal portion 32, the spoke core metal portions 33 on both sides (side spoke core metal portions 33a, 33b) are located at positions parallel to the easily deformable portions 38 of the rim core metal portion 31. By providing a connecting portion 43 for connecting the lower spoke core metal portion 33 (lower spoke core metal portion 33c), the boss core metal portion 32 can be formed as a box-shaped rigid body portion, so that the increase or decrease in the resonance frequency is suppressed. can.

Further, since the connecting portion 43 is provided in parallel with the easily deformable portion 38, the boss core metal portion 32, which is a rigid body portion of the box shape, becomes strong, and when the occupant comes into contact with the rim portion 21, the easily deformable portion 38 Since it is possible to concentrate stress on the steering wheel 10, the reaction force from the steering wheel 10 (rim portion 21) to the occupant can be easily adjusted only by changing the cross-sectional area of the easily deformable portion 38, in other words, the cutting amount.

For example, the graph of FIG. 4 shows the relationship between the deformation amount and the load according to the magnitude of the cutting amount (cross-sectional area) of the easily deformable portion 38. This graph shows the amount of deformation of the core metal 25 in the vertical direction with respect to a load applied from above by inclining the core metal 25 arranged upside down by, for example, 60 ° with respect to the vertical direction. As shown in this graph, the reaction force can be easily tuned by increasing or decreasing the cutting amount (cross-sectional area) of the easily deformable portion 38.

In addition, since the boss core metal portion 32 becomes strong and difficult to deform, the module 12 fixed to the boss core metal portion 32 does not easily come off, and the lower spokes when the occupant comes into contact with the rim portion 21. Stress can also be concentrated on the core metal portion 33c, and the lower spoke core metal portion 33c can be easily bent.

Further, since the resonance frequency can be changed by increasing or decreasing the wall thickness of the boss core metal portion 32 which is a rigid body portion, the resonance frequency can be adjusted without affecting the moment of inertia of the steering wheel 10.

Therefore, the weight, moment of inertia, resonance frequency and reaction force from the rim portion 21 of the steering wheel 10 can be adjusted independently and independently without affecting each other, so that the performance of the steering wheel 10 can be easily adjusted depending on the vehicle. Different required characteristics can be easily met.

In the first embodiment described above, as in the second embodiment shown in FIG. 5, a plurality of lower spoke core metal portions 33, that is, a plurality of lower spoke core metal portions 33c may be provided. In this case, it can correspond to the steering wheel 10 having four or more spoke portions 23. For example, in this second embodiment, by providing a pair of lower spoke core metal portions 33c on the left and right, it is possible to correspond to the four spoke portions 23 on the left and right side portions and the lower side side portions. Even with this configuration, it is possible to obtain the same effect as that of the first embodiment described above.

Further, in each of the above embodiments, the rim core metal portion 31 does not have to be an annular shape, and may be formed in an arc shape in which a part of the annular ring is cut off, for example. Therefore, the rim portion 21 does not have to be an annular shape, for example, the rim portion 21 may be formed in an arc shape in which a part of the ring shape is cut off, or the terminal portions of the arcuate rim core metal portion 31 are other than each other. It may be formed in an annular shape by being connected by members.

Further, the steering wheel 10 can be used not only for automobiles but also for steering of any other vehicle.

INDUSTRIAL APPLICABILITY The present invention can be suitably used as a core metal of a steering wheel for a vehicle such as an automobile.

Steering wheel with 10 steering wheels
25 core metal
31 Rim core metal part
32 Boss core metal part
33 Spoke core metal part
38 Easy-to-deform part that is a weak part
42 Boss core metal body
43 Connection

Claims (2)

The boss core metal part connected to the steering shaft,
The rim core metal part located around this boss core metal part and
It is provided with a plurality of spoke core metal portions that connect the boss core metal portion and the rim core metal portion at both side portions and the lower portion, respectively.
The rim core metal portion is provided with a weak portion at a position between the spoke core metal portion on both sides and the spoke core metal portion at the lower portion.
The boss core metal portion includes a boss core metal main body portion and a connecting portion for connecting the spoke core metal portions on both sides and the spoke core metal portion at the lower portion at positions parallel to each weak portion.
The boss core metal body portion of the boss core metal portion, the rim core metal portion, and the connecting portion of the boss core metal portion are positioned differently from each other in the axial direction of the steering shaft and are substantially parallel to each other. Arranged along the
The connecting portion of the boss core metal portion is located between the boss core metal body portion of the boss core metal portion and the rim core metal portion in the axial direction of the steering shaft. Money. The core metal of the handle according to claim 1, wherein a plurality of spoke core metal portions at the lower portion are provided.

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