JP6222195B2 - Steering wheel damping structure - Google Patents

Description

  The present invention relates to a damping structure that suppresses (damps) vibration of a steering wheel in which an airbag device is installed.

  When the vehicle is traveling at high speeds or idling an in-vehicle engine, if vibrations in the vertical and horizontal directions are transmitted to the steering wheel, the vibrations may be transmitted to the driver through the hand holding the steering wheel, which may impair comfortable driving. There is. Thus, techniques for suppressing (suppressing) the vibration of the steering wheel have been developed and proposed. One of them is a technique that uses a dynamic damper including a weight and an elastic member that supports the weight on a core metal of a steering wheel. According to this technique, when vibration having the same frequency as or close to the resonance frequency unique to the dynamic damper is transmitted from the steering wheel to the dynamic damper, the dynamic damper resonates and absorbs vibration energy of the steering wheel. This absorption suppresses (suppresses) the vibration of the steering wheel.

  On the other hand, an air bag device is incorporated in the steering wheel to protect the driver in the event of a vehicle collision. The airbag device includes an airbag and an inflator that supplies gas to the airbag. When the vehicle collides, the airbag device is inflated rearward by the gas supplied from the inflator so that the driver Protect from impact.

  Here, since the airbag device occupies most of the internal space of the steering wheel, it is difficult to incorporate the above-described dynamic damper in a recent steering wheel.

Thus, it has been proposed to cause the airbag device to function as a dynamic damper (see, for example, Patent Document 1).
As shown in FIG. 18, the steering wheel includes a fixing member (horn plate) 51, an airbag device 52, a horn switch mechanism 53, and an elastic member 54. The fixing member (horn plate) 51 is fixed to a steering shaft (not shown) extending in the front-rear direction, and has an attachment hole (opening) 55. The airbag device 52 includes a bag holder (base plate) 56 and is disposed on the rear side of the fixing member (horn plate) 51.

  The horn switch mechanism 53 includes a support member (guide member) 57 and a slider (bush) 58. The support member (guide member) 57 is attached to the bag holder (base plate) 56 and extends forward, and is inserted into the attachment hole (opening) 55 of the fixing member (horn plate) 51. The slider (bush) 58 is disposed between the support member (guide member) 57 and the mounting hole (opening) 55 so as to be slidable in the front-rear direction. The horn switch mechanism 53 having such a configuration activates the horn device by the relative movement of the slider (bush) 58 and the bag holder (base plate) 56 accompanying the pressing operation of the airbag device 52.

  The elastic member 54 has an annular shape and is attached to a slider (bush) 58. The elastic member 54 is attached to the fixing member (horn plate) 51 in the attachment hole (opening) 55.

The names in parentheses are the member names used in Patent Document 1.
According to the steering wheel, the airbag device 52 functions as a damper mass of the dynamic damper, and the elastic member 54 functions as a spring of the dynamic damper. Therefore, when the steering wheel vibrates at a predetermined frequency in a direction perpendicular to the steering shaft, such as up and down, left and right, the elastic member 54 is elastically deformed at a resonance frequency that is the same as or close to that frequency, and the airbag device 52 is Accordingly, it vibrates in a direction perpendicular to the steering shaft, and absorbs vibration energy of the steering wheel. This absorption suppresses (suppresses) the vibration of the steering wheel.

JP 2012-158236 A

  However, in Patent Document 1, in order to attach the elastic member 54 to the fixing member (horn plate) 51, a groove portion 59 is provided in the outer peripheral portion of the elastic member 54, and this groove portion 59 is formed in the attachment hole (opening portion) 55. A configuration is adopted in which the insulator 61 is fitted. Therefore, in the structure in which the elastic member 54 is attached to the fixing member (horn plate) 51 only at the outer peripheral portion in this way, it is difficult to say that the attachment strength of the elastic member 54 to the fixing member (horn plate) 51 is sufficiently high. . Further, since the elastic member 54 having an outer diameter larger than the inner diameter of the attachment hole (opening) 55 is attached to the attachment hole (opening) 55, the elastic member 54 is attached to the fixing member (horn plate) 51. The work is complicated.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a damping structure for a steering wheel capable of attaching an elastic member with high strength by performing a simple operation. It is in.

Damping structure for a steering wheel for solving the above-mentioned problems, and path head portion, and an air bag device and a bag holder for forming a bag receiving space between said pad portion, and a flange portion, the flange And a support member that is attached to the steering wheel using a snap fit structure at the front end portion of the elongated portion and supports the airbag device at the flange portion . And an elastic material made of rubber or elastomer, which is formed in an annular shape as a whole, on the outer peripheral side of the long portion of the support member , and between the bag holder and the long portion of the support member And an elastic member that suppresses vibration transmitted between the airbag device and the support member, the airbag device being a dynamic damper. To function as a damper mass, a damping structure for a steering wheel to function the elastic member as the spring of the dynamic damper, said bag holder includes a bag holder side mounting hole penetrating the bag holder before-rear direction, said support A long portion of the member is inserted through the bag holder side mounting hole, and a damper holder for holding the elastic member is disposed between the elastic member and the bag holder, and the elastic member holds the damper holder. And is attached to the periphery of the bag holder-side attachment hole, and a portion extending forward is formed in the radially inner portion of the elastic member, and the front end edge of the radially inner portion of the elastic member is in the radial direction. located in front of the front end edge of the outer portion, the damper holder has a side wall portion which is located radially outwardly of said resilient member, said side walls With the radial direction and the front wall outer portion being disposed on the front side of the damper holder side mount hole penetrating in the longitudinal direction in the radially inward of the front wall portion of the elastic member extending in Luo radially inwardly , wherein the elongated portion of the support member is inserted into the damper holder-side mounting hole through the elastic member, a portion which extends forwardly of the elastic member, a radial direction of the damper holder side mounting hole Located inside.
Damping structure for a steering wheel for solving the above-mentioned problems, and path head portion, and an air bag device and a bag holder for forming a bag receiving space between said pad portion, and a flange portion, the flange And a support member that is attached to the steering wheel using a snap fit structure at the front end portion of the elongated portion and supports the airbag device at the flange portion . And an elastic material made of rubber or elastomer, which is formed in an annular shape as a whole, on the outer peripheral side of the long portion of the support member , and between the bag holder and the long portion of the support member is disposed between, and suppresses the elastic member vibrations transmitted between said supporting member and the airbag apparatus, the elongated portion of the support member and with said resilient member A pin holder for slidably holding the placed in the supporting member in the longitudinal direction, and a damper holder which holds the placed in the elastic member between said bag holder and the elastic member, the air bag device to function as a damper mass of the dynamic damper, a damping structure for a steering wheel to function the elastic member as the spring of the dynamic damper, said bag holder is provided with a mounting hole penetrating the bag holder before-rear direction, said support The elongated portion of the member is inserted through the mounting hole, and the elastic member includes a first portion extending from a radially inner side of the damper holder to a radially outer side of the pin holder, and a front side from a front end of the first portion. A first portion extending radially inward of the damper holder and radially outward of the pin holder. In contact with, said first portion is located only at the rear side of said bag holder.

According to each configuration described above, the airbag device supported by the rear end portion of the support member functions as a damper mass of the dynamic damper. An elastic member disposed on the outer peripheral side of the support member and between the bag holder and the support member functions as a spring of the dynamic damper. Therefore, when the steering wheel vibrates at a predetermined frequency, the elastic member is elastically deformed at the resonance frequency that is the same as or close to that frequency, and vibrates with the airbag device (the airbag device and the elastic member resonate), thereby steering. Absorbs wheel vibration energy. This absorption suppresses (suppresses) the vibration of the steering wheel.

In damping of the upper Symbol steering wheel, the between the elastic member and the bag holder is arranged damper holder for holding the elastic member, the elastic member of the mounting hole in the bag holder through the damper holder It is preferable that it is attached to the periphery.

According to said structure, an elastic member is attached to the circumference | surroundings of the attachment hole in a bag holder in the state hold | maintained by the damper holder.
In the vibration damping structure of the steering wheel, the steering wheel is further provided with a horn switch mechanism that activates a horn device by a pressing operation on the airbag device, and the horn switch mechanism includes an outer periphery of the support member and the elastic member. It is preferable to include a slider that is disposed between the member and moves forward by the pressing operation.

According to said structure, if an airbag apparatus is pressed, the slider of a horn switch mechanism will move ahead on a support member, and a horn apparatus will act | operate.
In the steering wheel vibration damping structure, it is preferable that a biasing member that biases the airbag device so as to move away from the steering wheel is disposed on an outer periphery of the support member.

  According to the above configuration, when operating the horn device, the airbag device is pushed forward against the urging force of the urging member disposed on the outer periphery of the support member. By this urging member, a load when the airbag device is pressed to operate the horn device is determined.

  In the vibration damping structure of the steering wheel, the steering wheel includes a through-hole penetrating the steering wheel in the front-rear direction, and the snap-fit structure includes a locking groove provided at the front end portion of the support member. And a clip that is held by the steering wheel in correspondence with the through hole and engages with the locking groove.

  According to the above configuration, the support member is inserted into the through hole of the steering wheel, and the clip is engaged with the locking groove at the front end of the support member, so that the support member snap-fits to the steering wheel. It is installed by.

  In the vibration damping structure of the steering wheel, a biasing force directed forward of the biasing member is received between the front end portion of the support member and an inner wall surface of the through hole, and the support member is disposed on the steering wheel. It is preferable that resin-made pieces to be supported are arranged.

  According to the above configuration, the urging force toward the front of the urging member is received by the resin piece disposed between the front end portion of the supporting member and the inner wall surface of the through hole, and the supporting member is the steering wheel. Supported by

  In the vibration damping structure of the steering wheel, the steering wheel has a skeleton portion including a fixing member, the through hole is provided in the fixing member, and the support member is attached to the fixing member using a snap-fit structure. It is preferably attached directly.

According to said structure, a support member is directly attached with the snap fit structure with respect to the fixing member in the frame | skeleton part of a steering wheel.
Damping structure for a steering wheel for solving the above-mentioned problems, and path head portion, and an air bag device and a bag holder for forming a bag receiving space between said pad portion, and a flange portion, the flange And a support member that is attached to the steering wheel using a snap fit structure at the front end portion of the elongated portion and supports the airbag device at the flange portion . And an elastic material made of rubber or elastomer, which is formed in an annular shape as a whole, on the outer peripheral side of the long portion of the support member , and between the bag holder and the long portion of the support member And an elastic member that suppresses vibration transmitted between the airbag device and the support member, the airbag device being a dynamic damper. To function as a damper mass, the elastic member to function as a spring of the dynamic damper, the elastic member has a front surface and a rear surface, and includes a groove which opens in at least one of said front and said rear surface.

According to said structure, the airbag apparatus supported by the rear-end part of the supporting member functions as a damper mass of a dynamic damper. An elastic member disposed on the outer peripheral side of the support member and between the bag holder and the support member functions as a spring of the dynamic damper. Therefore, when the steering wheel vibrates at a predetermined frequency, the elastic member is elastically deformed at the resonance frequency that is the same as or close to that frequency, and vibrates with the airbag device (the airbag device and the elastic member resonate), thereby steering. Absorbs wheel vibration energy. This absorption suppresses (suppresses) the vibration of the steering wheel.
Moreover, the elastic member is easily elastically deformed by providing the elastic member with a groove portion that opens at at least one of the front surface and the rear surface. Therefore, when the steering wheel vibrates, the elastic member easily resonates with the airbag device.

  According to the vibration damping structure of the steering wheel, the elastic member can be attached with high strength by performing a simple operation.

It is a figure which shows 1st Embodiment of the damping structure of a steering wheel, (A) is a side view of a steering wheel, (B) is an A arrow view of (A). The partial front view of the metal core in the steering wheel of 1st Embodiment. The perspective view of the airbag apparatus in 1st Embodiment. The disassembled perspective view of the airbag apparatus of FIG. (A) is a perspective view of the horn switch mechanism etc. in 1st Embodiment, (B) is an exploded perspective view of (A). (A) is sectional drawing, such as a horn switch mechanism in 1st Embodiment, (B) is an exploded sectional view of (A). (A) is sectional drawing which shows the state in which the horn switch mechanism etc. of 1st Embodiment were assembled | attached to the bag holder, (B) is a fragmentary sectional view which expands and shows a part of (A). The partial perspective view which notches and shows a part of elastic member of 1st Embodiment. It is a figure which shows 1st Embodiment and is a fragmentary sectional view which shows internal structures, such as a horn switch mechanism in the state with which the metal core was mounted | worn. The fragmentary sectional view which shows internal structures, such as a horn switch mechanism, when an airbag apparatus is pressed from the state of FIG. It is a figure which shows the effect by the damping structure of 1st Embodiment, and is a graph which shows the result of having measured the inertance (vibration level) for every frequency. It is a figure which shows 2nd Embodiment of the damping structure of a steering wheel, and is a partial front view which shows a part of bag holder to which the horn switch mechanism was attached. (A) is a fragmentary sectional view which shows structures, such as a horn switch mechanism along the 13-13 line | wire of FIG. 12, (B) is a fragmentary sectional view which expands and shows a part of (A). The fragmentary sectional view which shows structures, such as a horn switch mechanism along the 14-14 line | wire of FIG. It is a figure which shows 3rd Embodiment of the damping structure of a steering wheel, and is a fragmentary sectional view which shows a part of horn switch mechanism attached to the bag holder. It is a figure which shows 4th Embodiment of the damping structure of a steering wheel, and is a fragmentary sectional view which shows a part of horn switch mechanism attached to the bag holder. (A)-(E) are the fragmentary perspective views which cut and show the part about the modification of the elastic member in 1st Embodiment. The fragmentary sectional view which shows the damping structure of the conventional steering wheel.

(First embodiment)
Hereinafter, a first embodiment of a vibration damping structure for a steering wheel will be described with reference to FIGS.

  As shown in FIG. 1A, in front of the driver's seat of the vehicle (to the right of FIG. 1A), the steering extends in the front-rear direction along the axis L1 and rotates about the coaxial line L1. The shaft (steering shaft) 14 is disposed in an inclined state so as to become higher toward the driver's seat side (left side in FIG. 1A). A steering wheel 10 is attached to the rear end portion of the steering shaft 14 so as to be integrally rotatable.

  In the first embodiment, when describing each part of the steering wheel 10, the axis L1 of the steering shaft 14 is used as a reference. The direction along the axis L1 is referred to as the “front-rear direction” of the steering wheel 10, and the direction in which the steering wheel 10 stands up among the directions along the plane perpendicular to the axis L1 is referred to as the “vertical direction”. Therefore, the front-rear direction and the vertical direction of the steering wheel 10 are slightly inclined with respect to the front-rear direction (horizontal direction) and the vertical direction (vertical direction) of the vehicle.

  3, FIG. 5 (B), FIG. 6 (A), (B), FIG. 7 (A), (B), FIG. 9, FIG. 10, and FIG. It is shown in a state where the front-rear direction matches the horizontal direction and the vertical direction of the steering wheel 10 matches the vertical direction.

  As shown in FIG. 1B, the steering wheel 10 includes an airbag device (airbag module) 20 at the center. The skeleton part of the steering wheel 10 is constituted by a cored bar 12 as a fixing member. FIG. 2 shows a part of the cored bar 12. The cored bar 12 is made of iron, aluminum, magnesium, or an alloy thereof. The metal core 12 is attached to the steering shaft 14 at the boss portion 12a located at the center thereof, and rotates integrally with the steering shaft 14.

  In the core metal 12, holding portions 12b each having a through hole 12c are provided at a plurality of locations around the boss portion 12a. In the cored bar 12, when it is necessary to distinguish between the holding portion 12b and the other part, the latter part is referred to as a cored bar body 12d. As shown in FIG. 9, the inner wall surface of each through-hole 12 c has a tapered shape whose diameter increases toward the rear side (left side in FIG. 9). In FIG. 2, the illustration of the tapered inner wall surface is omitted.

  As shown in FIGS. 2 and 9, clips 13 are respectively incorporated between the holding portions 12b and the cored bar body 12d and in the vicinity of the through holes 12c. Each clip 13 is formed by bending a wire made of metal such as a spring rope having conductivity into a predetermined shape, and is incorporated between the holding portion 12b and the cored bar body 12d in a slightly elastically deformed state. Are held by the cored bar 12. The clip 13 is in contact with at least one of the holding part 12b and the cored bar body 12d at a part, for example, an end part thereof. The clip 13 has a function of locking a snap pin 31 of the horn switch mechanism 30 described later with respect to the core metal 12 in a conductive state. A part of each clip 13 is located near the front of the through hole 12c.

  The vehicle is provided with a horn device 40, and a plurality of horn switch mechanisms 30 for operating the horn device 40 are mounted on the cored bar 12 in a snap-fit structure in each holding portion 12b. Each horn switch mechanism 30 has the same configuration. The airbag device 20 is supported by the cored bar 12 via these horn switch mechanisms 30. Thus, each horn switch mechanism 30 has both the support function of the airbag apparatus 20 and the function of a horn switch.

  Furthermore, in the first embodiment, an elastic member 41 and a damper holder 42 are interposed between the bag holder 21 and each horn switch mechanism 30 in the airbag device 20. These airbag device 20, horn switch mechanism 30, elastic member 41, damper holder 42, cored bar 12, and the like constitute a damping structure for suppressing (suppressing) the vibration of the steering wheel 10.

Next, each part which comprises the said damping structure is demonstrated.
<Airbag device 20>
As shown in FIGS. 3 and 4, the airbag device 20 has the pad portion 24, the airbag (not shown), and the inflator 23 assembled to the bag holder 21 disposed at the front portion of the airbag device 20. It is constituted by. The airbag device 20 is disposed on the rear side of the cored bar 12 (see FIG. 9).

  The pad portion 24 is formed by resin molding, and is erected in a substantially rectangular ring shape on the outer skin portion 24a whose surface forms a design surface and on the back surface side (front side: right side in FIGS. 3 and 4) of the outer skin portion 24a. Storage wall portion 24b. An inner side surface of the outer skin portion 24a surrounded by the housing wall portion 24b forms a bag housing space x for mainly housing an airbag (not shown) with the bag holder 21. A thin-walled portion 24c that is pushed and broken when the airbag is deployed and inflated is formed in a portion that forms the bag housing space x of the outer skin portion 24a.

  A plurality of locking claws 24d each having a rectangular plate shape are integrally formed at the front end portion of the accommodating wall portion 24b. Each locking claw 24d is formed to be wide with a predetermined length, and a locking projection 24e is formed on the front end portion of each locking claw 24d so as to protrude outward (side away from the bag housing space x). .

  Switch support portions 24f for supporting the horn switch mechanism 30 are formed at a plurality of locations of the pad portion 24, respectively. Each switch support portion 24f is formed integrally with the housing wall portion 24b so as to extend from the outer skin portion 24a of the pad portion 24 to the back surface side (front side).

  The bag holder 21 is formed in a substantially rectangular shape by pressing a conductive metal plate. The bag holder 21 may be formed by means other than pressing, for example, die casting. The peripheral part of the bag holder 21 is configured as a substantially square annular peripheral fixing part 21 a for fixing the pad part 24.

  In the peripheral edge fixing portion 21a, claw locking holes 21b are formed at locations corresponding to the respective locking claws 24d of the pad portion 24 (locations on the front side). Each claw locking hole 21b has a long slit shape in the side direction of the bag holder 21 corresponding to each of the wide locking claw 24d. The front end portions of the respective locking claws 24d are inserted and locked in the respective claw locking holes 21b.

  An inner portion of the peripheral edge fixing portion 21a constitutes a substantially square pedestal portion 21c. A circular opening 21d is formed at the center of the pedestal 21c. Screw insertion holes 21e are formed at a plurality of locations in the vicinity of the peripheral edge of the opening 21d in the pedestal 21c. A part of the inflator 23 is inserted and attached to the opening 21d of the pedestal 21c.

  More specifically, the inflator 23 has a low columnar main body 23a, and a flange portion 23b is formed on the outer peripheral surface of the main body 23a. In the flange portion 23b, a plurality of attachment pieces 23c are extended outward in the radial direction of the main body 23a at equal angular intervals in the circumferential direction of the main body 23a. In each attachment piece 23c, a screw insertion hole 23d is formed at a location in front of the screw insertion hole 21e of the bag holder 21. In the inflator 23, a portion on the rear side of the flange portion 23b is configured as a gas ejection portion 23e that ejects an expansion gas. And it is penetrated by the opening part 21d of the bag holder 21 from the front side so that the gas ejection part 23e of the inflator 23 may protrude to the bag accommodating space x side. Further, the flange 23b is brought into contact with the peripheral edge of the opening 21d. In this state, the inflator 23 is attached to the bag holder 21 together with the ring retainer 25.

  More specifically, the ring retainer 25 has a circular opening 25a equivalent to the opening 21d of the bag holder 21 through which the gas ejection part 23e of the inflator 23 is inserted. The ring retainer 25 has mounting screws 25b at a plurality of locations corresponding to the screw insertion holes 21e of the bag holder 21. Between the ring retainer 25 and the bag holder 21, an opening portion of an airbag (not shown) that is folded so as to be deployed and inflated is disposed. The plurality of mounting screws 25b of the ring retainer 25 are connected to the screw insertion holes (not shown) provided in the peripheral portion of the opening of the airbag and the screw insertion holes 21e and 23d of the bag holder 21 and the inflator 23. It is inserted from the rear side. Further, the nut 26 is screwed from the front side to each of the mounting screws 25b after the insertion, whereby the airbag is fixed to the bag holder 21 via the ring retainer 25 and the inflator 23 is fixed to the bag holder 21. Yes.

  Attachment portions 21f for attaching the horn switch mechanism 30 are formed at a plurality of locations on the peripheral edge fixing portion 21a of the bag holder 21 so as to protrude outward in the radial direction of the circular opening 21d. Each attachment part 21f is located in the location which becomes the front of the switch support part 24f of the pad part 24 mentioned above, and is orthogonally crossed with respect to the front-back direction. As shown in FIGS. 3, 4, and 7 (A) and 7 (B), a mounting hole 21 g for mounting the horn switch mechanism 30 is circularly formed in each mounting portion 21 f. A plurality of sandwiching portions 21 i extending rearward are integrally formed on the periphery of each attachment hole 21 g in the bag holder 21. In 1st Embodiment, each clamping part 21i is formed by bending the location which opposes on both sides of each attachment hole 21g in the bag holder 21 back. By the above-described bending formation of each clamping part 21i, a hole 21j is formed in the bag holder 21 outside each clamping part 21i, that is, on the side opposite to the attachment hole 21g across each clamping part 21i.

<Horn switch mechanism 30>
As described above, the horn switch mechanism 30 is for operating the horn device 40, and a plurality of horn switch mechanisms 30 are used in the first embodiment. The distance from each horn switch mechanism 30 to the center (boss portion 12a) of the steering wheel 10 is preferably set to be substantially equal to each other. This is because a contact terminal 34, which will be described later, and a flange 31a of the snap pin 31 are reliably brought into contact with each other to be in a conductive state.

  As shown in FIGS. 5A and 5B, each horn switch mechanism 30 includes a snap pin 31 as a support member, a pin holder 32, a contact holder 33, a contact terminal 34 as a movable side contact portion, a piece 35, and A coil spring 36 as an urging member is provided. Next, each component of the horn switch mechanism 30 will be described.

  The snap pin 31 is a member supported by the cored bar 12 in front of the bag holder 21 and is made of a conductive metal material. The support structure for the core metal 12 of the snap pin 31 will be described later. Many portions of the snap pin 31 have a long shape extending in the front-rear direction, and a concave portion is provided on the outer peripheral surface of the front end portion thereof. In the first embodiment, an annular locking groove 31 b is formed over the entire circumference of the snap pin 31 as the recess. Most of the snap pin 31 except for the rear end portion is formed to have a slightly smaller diameter than the mounting hole 21g of the bag holder 21. As shown in FIG. 7 (A), the rear end portion of the snap pin 31 is formed with a flange portion 31a that has a disk shape and functions as a fixed-side contact portion. The flange portion 31a has an outer diameter D1 larger than the inner diameter D2 of the mounting hole 21g. In FIG. 6B, the snap pin 31 is shown with a part thereof omitted.

  As shown in FIGS. 5A and 5B and FIGS. 6A and 6B, the pin holder 32 is made of a material having characteristics as an insulator, for example, a resin material. The pin holder 32 has a cylindrical shape having a stepped shape, and is disposed between the snap pin 31 and the elastic member 41. The pin holder 32 is used as a slider that slides in the longitudinal direction (front-rear direction) with respect to the snap pin 31 when the horn switch mechanism 30 is operated. In the pin holder 32, an enlarged diameter portion 32b having a larger diameter than that of the cylindrical portion 32a is formed at the rear end of the portion through which the snap pin 31 is inserted (hereinafter referred to as “cylindrical portion 32a”). The flange portion 31a of the snap pin 31 is fitted into the enlarged diameter portion 32b.

  The contact holder 33 is formed of a resin material into a bottomed cylindrical shape with the front surface opened. The contact holder 33 is assembled so as to cover the snap pin 31 and the pin holder 32 from behind. The contact holder 33 has a substantially circular top plate portion 33a and a substantially cylindrical side wall portion 33b extending forward from the outer peripheral edge of the top plate portion 33a. A hook portion 33c is formed at a location facing the radial direction of the side wall portion 33b so as to be elastically deformable in the radial direction.

  A groove 33d for aligning the direction of the contact holder 33 when the contact holder 33 is assembled to the snap pin 31 and the pin holder 32 is formed in the rear portion of the top plate portion 33a.

  Claw engaging holes 33f are formed at a plurality of locations that are intermediate portions of the side wall portion 33b in the front-rear direction and are spaced apart from each other in the circumferential direction. In addition, notches 33g are formed at a plurality of locations at the front end portion of the side wall portion 33b and separated from each other in the circumferential direction.

  The contact terminal 34 is formed by pressing a conductive metal plate. The contact terminal 34 includes a long main body portion 34a extending in the radial direction of the contact holder 33 and a pair of side portions 34b extending forward from both ends of the main body portion 34a. The main body portion 34 a is in contact with the front surface of the top plate portion 33 a of the contact holder 33, and each side portion 34 b is in contact with the inner wall surface of the side wall portion 33 b of the contact holder 33. A plurality of contact protrusions 34c protruding forward are formed on the main body 34a at regular intervals along the longitudinal direction of the main body 34a.

  In addition, the enlarged diameter part 32b of the said pin holder 32 is interposed between each side part 34b and the collar part 31a of the snap pin 31, and the insulation state of each side part 34b and the collar part 31a is ensured. (See FIG. 6A). Further, the cylindrical portion 32a of the pin holder 32, the elastic member 41, and the damper holder 42 are interposed between each side portion 34b and the snap pin 31 (portion excluding the flange portion 31a). Insulation with the pin 31 is ensured.

  The entire piece 35 is integrally formed of a resin material that is an insulating material. A part of the piece 35 is configured by an annular annular portion 35b having an insertion hole 35a having a slightly larger diameter than the portion excluding the flange portion 31a of the snap pin 31. The outer diameter of the annular portion 35b is set to be approximately equal to the outer diameter of the coil spring 36 and the outer diameter of the rear end portion of the inner wall surface of the through hole 12c, that is, the maximum diameter of the tapered inner wall surface ( (See FIG. 9).

  A locking piece 35c extends forward from a plurality of locations around the insertion hole 35a on the front surface of the annular portion 35b. At the front end of each locking piece 35 c, a claw portion 35 d is projected inward in the radial direction, and these claw portions 35 d enter the locking groove 31 b of the snap pin 31. In addition, the outer surface of each locking piece 35c constitutes a part of a cylindrical surface having the same diameter at any part in the front-rear direction. That is, the outer surface of each locking piece 35c does not correspond to the tapered inner wall surface of the through hole 12c, and therefore does not come into surface contact with the inner wall surface.

  A plurality of engaging pieces 35e extend forward from between the adjacent locking pieces 35c around the insertion hole 35a on the front surface of the annular portion 35b. The outer surface of each engagement piece 35e constitutes a part of a tapered surface whose diameter increases toward the rear side.

  A pair of mounting portions 35f extends rearward from the annular portion 35b. Each mounting portion 35f is curved so as to bulge outward in the radial direction of the piece 35, corresponding to the outer shape of the snap pin 31.

  As shown in FIG. 9, the piece 35 is fitted to the outer side of the snap pin 31 in the annular portion 35b and the both mounting portions 35f, and each claw portion 35d enters the locking groove 31b. It is mounted so that it cannot be removed. As described above, in the piece 35, the axis passing through the center of the annular portion 35b is intermittently (intermittently) surrounding the outer surface of the plurality of engagement pieces 35e with the outer surface of the plurality of locking pieces 35c interposed therebetween. Yes. With such a configuration, the piece 35 as a whole is in the same state as that having a tapered outer surface whose diameter increases toward the rear side.

  The coil spring 36 is wound around a portion of the snap pin 31 excluding the flange portion 31a. The coil spring 36 is disposed in a compressed state between the step portion 32 c formed in the cylindrical portion 32 a of the pin holder 32 and the annular portion 35 b of the piece 35. In this state, the annular portion 35 b receives a forward biasing force of the compressed coil spring 36.

  In this way, a plurality of single components, that is, the snap pin 31, the pin holder 32, the contact holder 33, the contact terminal 34, the coil spring 36, and the piece 35 are unitized to form the horn switch mechanism 30 that is an assembly. ing. Therefore, when the horn switch mechanism 30 is attached or replaced, the unitized horn switch mechanism 30 can be handled as one aggregate.

<Elastic member 41>
As shown in FIGS. 8 and 9, the elastic member 41 is interposed between the pin holder 32 and the bag holder 21 in the horn switch mechanism 30. The entire elastic member 41 is formed of an elastic material such as rubber (for example, EPDM, silicon rubber, etc.), an elastomer, or the like. The elastic member 41 has an insertion hole 41a having a slightly larger diameter than the cylindrical portion 32a of the pin holder 32, and has a substantially annular shape. Furthermore, the elastic member 41 is formed with an annular groove 41b that opens on the front surface thereof, concentrically with the insertion hole 41a. The groove part 41b has a rectangular cross section. 7B, the elastic member 41 is sandwiched from the front and rear by the attachment portion 21f of the bag holder 21 and the enlarged diameter portion 32b of the pin holder 32. Further, the elastic member 41 is sandwiched from the outer side and the inner side in the radial direction by the clamping part 21 i of the bag holder 21 and the cylindrical part 32 a of the pin holder 32.

  The elastic member 41 constitutes a dynamic damper together with the airbag device 20 described above. In the first embodiment, the elastic member 41 is caused to function as a dynamic damper spring, and the airbag device 20 is caused to function as a damper mass.

  Here, by tuning the size of the elastic member 41, the thickness in the radial direction, the length in the front-rear direction, etc., the resonance frequency of the dynamic damper in the up-down direction and the left-right direction can be increased. Is set to a target vibration suppression frequency (frequency to be controlled).

<Damper holder 42>
As shown in FIGS. 5A and 5B and FIGS. 6A and 6B, the damper holder 42 is engaged with the horn switch mechanism 30 before the horn switch mechanism 30 is attached to the bag holder 21. The elastic member 41 is stopped and held in a state of being attached to the outside of the cylindrical portion 32 a of the pin holder 32. The damper holder 42 is located between the elastic member 41 and the bag holder 21 in a state where the horn switch mechanism 30 is attached to the bag holder 21.

  The main part of the damper holder 42 is composed of a side wall part 42a and a front wall part 42b, both of which are made of a resin material. The side wall portion 42a is formed in a substantially cylindrical shape having a diameter slightly larger than that of the elastic member 41 and smaller in diameter than the side wall portion 33b of the contact holder 33, and the outer side in the radial direction of the elastic member 41; It arrange | positions inside the radial direction of the clamping part 21i in the bag holder 21. As shown in FIG. The front wall portion 42b has a mounting hole 42c having a slightly larger diameter than the cylindrical portion 32a of the pin holder 32 and has a substantially annular shape. The front wall portion 42 b is disposed on the front side of the elastic member 41 and on the rear side of the attachment portion 21 f in the bag holder 21.

  Engagement claws 42d (see FIG. 5B) are formed at a plurality of locations on the side wall portion 42a that are separated from each other in the circumferential direction. The damper claw 42 d is engaged with the claw engagement hole 33 f of the contact holder 33 from the inside so that the damper holder 42 is locked to the contact holder 33.

  Stoppers 42e (see FIGS. 5A and 5B) are formed at a plurality of locations at the front end of the side wall portion 42a and spaced apart from each other in the circumferential direction. These stoppers 42e are engaged with the notches 33g of the contact holder 33, whereby the damper holder 42 is positioned in the front-rear direction with respect to the contact holder 33.

As described above, the vibration damping structure for the steering wheel of the first embodiment is configured. Next, the operation of the first embodiment will be described focusing on the operation of this vibration damping structure.
Initially, the operation | work which attaches each horn switch mechanism 30 to the bag holder 21 via the elastic member 41 and the damper holder 42 is demonstrated. As this work, the work of attaching the elastic member 41 and the damper holder 42 to each horn switch mechanism 30 and the work of attaching each horn switch mechanism 30 to each mounting hole 21g are performed.

  As shown in FIGS. 5B and 6A, in the former operation, the cylindrical portion 32 a of the pin holder 32 in each horn switch mechanism 30 is inserted into the insertion hole 41 a of the elastic member 41. This insertion is performed to a position where the enlarged diameter portion 32b of the pin holder 32 contacts the elastic member 41 from behind. By this insertion, the elastic member 41 is attached to the outside of the cylindrical portion 32 a of the pin holder 32.

  Next, the side wall part 42 a of the damper holder 42 is inserted between the outer peripheral surface of the elastic member 41 and the side wall part 33 b of the contact holder 33 and the side part 34 b of the contact terminal 34. In this insertion process, when the front wall portion 42 b of the damper holder 42 approaches the elastic member 41, the engaging claw 42 d shown in FIG. 5B is engaged with the claw engaging hole 33 f of the contact holder 33, and the damper holder 42 Is locked to the contact holder 33 (see FIG. 5A). The elastic member 41 is surrounded by the damper holder 42 and the pin holder 32. A side wall portion 42a of the damper holder 42 engaged with the contact holder 33 is located outside the elastic member 41 in the radial direction, and a front wall portion 42b of the damper holder 42 is located on the front side. The elastic member 41 is held in a state of being attached to the outside of the cylindrical portion 32a of the pin holder 32. Therefore, it is difficult for the elastic member 41 to fall off the pin holder 32.

  In addition, the stoppers 42e of the damper holder 42 are engaged with the corresponding notches 33g of the contact holder 33 substantially simultaneously with the engagement of the engaging claws 42d. These engagements restrict further insertion of the damper holder 42 into the contact holder 33 and position the damper holder 42 in the front-rear direction with respect to the contact holder 33. In this state, a gap is formed between the side wall portion 42a and the side portion 34b so that the clamping portion 21i can be inserted.

  In the latter operation, the horn switch mechanism 30 to which the elastic member 41 and the damper holder 42 are mounted as described above is used for the snap pin 31 (support member), the piece 35, the coil spring 36 (biasing member), and the pin holder 32. In the cylindrical part 32a, it inserts into the attachment hole 21g of the bag holder 21 shown with a dashed-two dotted line from FIG. 6 (A) from back. In the process of this insertion, as shown in FIGS. 7A and 7B, both sandwiching portions 21 i in the bag holder 21 enter the gap between the side wall portion 42 a of the damper holder 42 and the side portion 34 b of the contact terminal 34. Further, the hook portion 33 c in the contact holder 33 is inserted into the hole 21 j in the bag holder 21. By this hook portion 33 c, the side portion 34 b of the contact terminal 34 is brought into contact with the outer surface of the clamping portion 21 i in the bag holder 21. By this contact, the bag holder 21 and the contact terminal 34 are brought into conduction.

  The insertion of the horn switch mechanism 30 is performed up to a position where the front wall portion 42b of the damper holder 42 contacts the attachment portion 21f of the bag holder 21. In this position, the front end portion of the side portion 34b urged by the hook portion 33c of the contact holder 33 is locked to the front side of the clamping portion 21i in the bag holder 21, and the contact holder 33 and, consequently, the horn switch mechanism 30 is connected to the bag holder. 21 is restricted from moving backwards.

  In this way, the elastic member 41 is sandwiched from the front and the rear by the attachment portion 21f of the bag holder 21 and the enlarged diameter portion 32b of the pin holder 32. Further, the elastic member 41 is sandwiched from the outer side and the inner side in the radial direction by the clamping part 21 i of the bag holder 21 and the cylindrical part 32 a of the pin holder 32.

  In the state where each horn switch mechanism 30 is attached to the bag holder 21 as described above, the movement of the elastic member 41 in the direction (front-rear direction) along the axis L1 of the steering shaft 14 causes the attachment portion 21f and the enlarged diameter portion to move. It is regulated by 32b. Further, the movement of the elastic member 41 in the direction orthogonal to the axis L1 of the steering shaft 14 is restricted by the sandwiching portion 21i and the cylindrical portion 32a.

  In the state in which each horn switch mechanism 30 is attached as described above, the flange portion 31 a of the snap pin 31 is located on the rear side of the attachment hole 21 g of the bag holder 21. The flange 31 a receives a backward biasing force from the coil spring 36.

  Further, in the attached state, the pin holder 32 is disposed between the snap pin 31 and the bag holder 21, and the bag holder 21 is moved back and forth with respect to the snap pin 31 while preventing contact between them, that is, in an insulated state. While supporting it as possible, a rearward biasing force of the coil spring 36 is transmitted to the flange 31 a of the snap pin 31.

  Further, in the mounted state, the top plate portion 33a of the contact holder 33 contacts the switch support portion 24f of the pad portion 24 described above (see FIG. 3). Therefore, for example, when the airbag device 20 is struck, the reaction force is received by the switch support portion 24 f and the contact holder 33 is restricted from coming off the pin holder 32.

  Furthermore, in the mounted state, the coil spring 36 in each horn switch mechanism 30 and the snap pin 31 inserted through the coil spring 36 protrude forward from the bag holder 21 (in a direction away from the pad portion 24).

Next, an operation of assembling the airbag device 20 to the core metal 12 via the plurality of horn switch mechanisms 30 will be described.
In this operation, as shown in FIG. 9, the snap pin 31 for each horn switch mechanism 30 is brought close to the through hole 12 c of the holding portion 12 b corresponding to the core metal 12 from the rear. At this time, the front portion (hereinafter referred to as “front end 31c”) of each snap pin 31 slightly protrudes forward from each coil spring 36 and each piece 35 (see FIG. 5A).

  Since each piece 35 is attached to the snap pin 31 before the snap pin 31 is inserted into the through hole 12c, the piece 35 is also inserted in the process in which the snap pin 31 is inserted into the through hole 12c. Further, it is inserted into the through hole 12c.

  With the insertion, the annular portion 35b of the piece 35 approaches the holding portion 12b, and the engagement piece 35e approaches the inner wall surface of the through hole 12c. Further, the front end 31 c of the snap pin 31 contacts the clip 13. Further, when the snap pin 31 or the like is moved forward against the urging force of the clip 13, the clip 13 is elastically deformed outward in the radial direction of the snap pin 31. When the snap pin 31 is moved to a position where the locking groove 31b faces the clip 13, the clip 13 tries to enter the locking groove 31b by its own elastic restoring force.

  On the other hand, the claw portion 35d of the piece 35 biased forward by the coil spring 36 enters the locking groove 31b. Therefore, the clip 13 enters between the claw portion 35d and the front wall surface 31d in the locking groove 31b while compressing the coil spring 36 rearward in the process of entering the locking groove 31b. By this entry, the claw portion 35d is positioned on the rear side of the clip 13 in the locking groove 31b. In the clip 13, the portion located in front of the through hole 12 c is sandwiched from the front and rear by the claw portion 35 d urged forward by the coil spring 36 and the front wall surface 31 d of the locking groove 31 b, and the movement is restricted. On the other hand, the movement of the snap pin 31 in the front-rear direction is restricted by the clip 13 that has entered the locking groove 31b. In this way, the snap pin 31 is locked to the metal core 12 by the clip 13, so that each horn switch mechanism 30 is fastened to the metal core 12 and the airbag device 20 is attached to the metal core 12. . The structure that is locked to the core metal 12 by the elasticity of the clip 13 as the snap pin 31 is inserted is also called a snap-fit structure.

  In this assembled state, the outer surface of each engagement piece 35e contacts the inner wall surface of the through hole 12c. Further, the claw portion 35d is slightly separated forward from the rear wall surface 31e in the locking groove 31b. In this way, the piece 35 is interposed between the inner wall surface of the through hole 12 c in the holding portion 12 b of the core metal 12 and the snap pin 31.

  In the assembled state, the snap pin 31 of each horn switch mechanism 30 locked to the core metal 12 can advance and retract the bag holder 21 of the airbag device 20 with respect to the core metal 12 via the pin holder 32. That is, it supports so that it can approach or leave | separate with respect to the metal core 12. FIG.

  Here, the coil spring 36 interposed between the stepped portion 32 c of the pin holder 32 and the annular portion 35 b of the piece 35 is in a more compressed state than before being attached to the core metal 12. The coil spring 36 in the compressed state urges the pin holder 32 rearward in the direction away from the core metal 12, and separates the contact protrusion 34 c of the contact terminal 34 from the flange 31 a of the snap pin 31 rearward.

  The coil spring 36 is further compressed, thereby allowing the airbag device 20 to move toward the core metal 12. That is, the coil spring 36 is compressed with a horn stroke secured. The horn stroke means that the contact protrusion 34c comes into contact with the flange 31a from a state where the contact protrusion 34c of the contact terminal 34 is separated from the flange 31a of the snap pin 31 (the horn switch mechanism 30 is turned off: FIG. 9). This is the amount of movement of the airbag device 20 to the cored bar 12 side that is required to enter the state (the on state of the horn switch mechanism 30: FIG. 10). The coil spring 36 determines a horn load that is a load when the driver presses the airbag device 20 to turn on each horn switch mechanism 30.

  By the way, in the steering wheel 10, as shown in FIG. 9, the contact of the contact terminal 34 is normal when the airbag device 20 is not pushed forward or an excessive load is applied to the airbag device 20. The protrusion 34c is moved rearward from the flange 31a of the snap pin 31 that is the stationary contact portion. The contact terminal 34 and the snap pin 31 are turned off, and the horn device 40 does not operate. At this time, a backward biasing force of the coil spring 36 is applied via the pin holder 32 to the flange portion 31 a of the snap pin 31 locked to the core metal 12 by the clip 13.

  Further, at this time, the forward biasing force of the coil spring 36 is applied to the piece 35 through the annular portion 35b, and the claw portion 35d that has entered the locking groove 31b of the snap pin 31 in the piece 35 becomes the locking groove 31b. The inner clip 13 is pressed forward. By this pressing, the clip 13 is sandwiched from the front and rear by the front wall surface 31d and the claw portion 35d in the locking groove 31b, and the movement is restricted.

  On the other hand, when the airbag device 20 is pushed forward or an excessive load is applied to the airbag device 20, the bag holder 21 is moved forward against the coil spring 36. The pin holders 32 of the two horn switch mechanisms 30 are pressed against the urging force of the coil spring 36 via the bag holder 21 and move to the core metal 12 side (front side). The contact holder 33 and the contact terminal 34 also move to the core metal 12 side (front side) together with the bag holder 21 and the pin holder 32. As a situation where an excessive load is applied, for example, it is assumed that the vehicle is traveling on a rough road and the airbag apparatus 20 vibrates greatly.

  As shown in FIG. 10, when at least one of the plurality of contact protrusions 34c of the contact terminal 34 comes into contact with the collar 31a of the snap pin 31, the core 12 connected to the ground GND (vehicle body ground) and the bag The holder 21 is electrically connected via the clip 13, the snap pin 31 and the contact terminal 34. By this conduction, the horn switch mechanism 30 is closed, and the horn device 40 electrically connected to the bag holder 21 is activated.

  As described above, the snap pin 31 exhibits a function of being locked to the holding portion 12b of the core metal 12 and a function of supporting the bag holder 21 so as to be movable in the front-rear direction with respect to the core metal 12. It also functions as a fixed contact point.

  Further, when the bag holder 21 is moved forward as described above, the backward biasing force of the coil spring 36 that has been applied to the flange 31a of the snap pin 31 through the pin holder 32 and the bag holder 21 until then disappears. . For this reason, the snap pin 31 is in a state of being able to swing with the portion locked to the cored bar 12 by the clip 13 as a fulcrum. At this time, the backward urging force that has been applied to the clip 13 through the front wall surface 31d in the locking groove 31b is no longer applied, and the clip 13 can move in the locking groove 31b.

  On the other hand, in the airbag device 20, the gas is not ejected from the gas ejection portion 23e of the inflator 23 and the airbag is folded at the normal time when a frontal impact (front collision) or the like is not applied to the vehicle. Maintained in a state.

  In the normal time, when the vehicle is traveling at high speed or when the vehicle-mounted engine is idling, vibrations in the vertical direction and the horizontal direction may be transmitted to the steering wheel 10. This vibration is transmitted to the airbag device 20 through the cored bar 12, each horn switch mechanism 30, and each elastic member 41.

In response to the vibration, the airbag device 20 functions as a damper mass of the dynamic damper, and each elastic member 41 functions as a spring of the dynamic damper.
For example, when the steering wheel 10 vibrates in the vertical direction at a predetermined frequency, the elastic members 41 vibrate (resonate) in the vertical direction with the airbag device 20 while elastically deforming each elastic member 41 at a resonance frequency that is the same as or close to that frequency. The vibration energy in the vertical direction of the steering wheel 10 is absorbed. Due to this absorption, vibration in the vertical direction of the steering wheel 10 is suppressed (damped).

  Further, when the steering wheel 10 vibrates in the left-right direction at a predetermined frequency, each elastic member 41 vibrates in the left-right direction with the airbag device 20 while elastically deforming at a resonance frequency that is the same as or close to that frequency. Absorbs vibration energy in the horizontal direction. By this absorption, the vibration in the left-right direction of the steering wheel 10 is attenuated (damped).

In this way, in the first embodiment, the steering wheel 10 is attenuated (damped) in both the vertical and horizontal directions.
The groove part 41b formed in the elastic member 41 makes the elastic member 41 easily elastically deformed. Therefore, when the steering wheel 10 vibrates, the elastic member 41 easily resonates with the airbag device 20.

  Here, FIG. 11 shows the result of measuring the inertance for each frequency by vibrating the steering wheel 10 at various frequencies. Inertance is a frequency response function based on the ratio of acceleration to excitation force (acceleration / excitation force), and the vibration level deteriorates as the value increases. The solid line in FIG. 11 shows the frequency characteristic in the first embodiment in which the elastic member 41 is used, and the two-dot chain line shows the frequency characteristic in the case where the elastic member 41 is not used (comparative example). . From FIG. 11, it can be seen that, in the first embodiment, the level of vibration in the vicinity of 40 Hz generated during idling of the vehicle-mounted engine or during idling of the vehicle-mounted engine is particularly improved.

  When an impact is applied to the vehicle from the front due to a front collision or the like, the driver tends to lean forward due to inertia. On the other hand, in the airbag device 20, the inflator 23 is operated in response to the impact, and gas is ejected from the gas ejection part 23e. By supplying this gas to the airbag, the airbag is deployed and inflated. When the pressing force applied to the outer skin portion 24a of the pad portion 24 increases by the airbag, the outer skin portion 24a is broken at the thin portion 24c. The airbag continues to be deployed and inflated backward through the opening created by the break. A deployed and inflated airbag is interposed in front of the driver who leans forward due to the impact of the front collision, restrains the driver's forward tilt and protects the driver from the impact.

  When the airbag is inflated rearward, a force directed rearward is applied to the bag holder 21. In this regard, in the first embodiment, the snap pin 31 for each horn switch mechanism 30 is supported by the holding portion 12 b of the core metal 12. A flange 31 a formed at the rear end of each snap pin 31 is located behind the attachment hole 21 g of the bag holder 21. The flange portion 31a has an outer diameter D1 larger than the inner diameter D2 of the mounting hole 21g (see FIG. 7A). For this reason, when the bag holder 21 moves rearward, the flange 31a functions as a stopper by contacting the peripheral portion of the attachment hole 21g in the bag holder 21.

According to the first embodiment described in detail above, the following effects can be obtained.
(1) The elastic member 41 is sandwiched from the front and rear by the attachment portion 21f of the bag holder 21 and the enlarged diameter portion 32b of the pin holder 32 (slider). Further, the elastic member 41 is sandwiched from the outer side and the inner side in the radial direction by the clamping part 21i of the bag holder 21 and the cylindrical part 32a of the pin holder 32 (slider) (FIGS. 7A and 7B). )).

  Therefore, the elastic member 41 can be attached with high strength by performing a simple operation of sandwiching the elastic member 41 between the bag holder 21 and the pin holder 32 (slider).

  (2) In the snap pin 31 (support member), a flange 31a having an outer diameter D1 larger than the inner diameter D2 of the mounting hole 21g is provided at the rear end portion that is a position behind the mounting hole 21g of the bag holder 21. (FIG. 7A).

  Therefore, when the airbag is inflated, a rearward force is applied to the bag holder 21, but the bag holder 21 and thus the airbag device 20 move excessively rearward by the flange 31a of the snap pin 31 (support member). Can be regulated.

  (3) With the elastic member 41 attached to the outside of the cylindrical portion 32a of the pin holder 32 (slider), the snap pin 31 (support member) and the pin holder 32 (slider) are inserted through the mounting holes 21g, The horn switch mechanism 30 is attached to the bag holder 21 (FIG. 7A).

  In the steering wheel 10 in which each horn switch mechanism 30 is attached to the bag holder 21 in such a form, the damper holder 42 is locked to the horn switch mechanism 30 and the elastic member 41 is attached to the pin holder 32 before the attachment to the bag holder 21. The slider is held attached to the outside of the cylindrical portion 32a (FIG. 6A). Further, when the horn switch mechanism 30 is attached to the bag holder 21, the damper holder 42 is positioned between the elastic member 41 and the bag holder 21 (FIG. 7A).

  For this reason, the damper holder 42 suppresses the elastic member 41 from dropping from the cylindrical portion 32a of the pin holder 32 (slider) before or during the operation of attaching each horn switch mechanism 30 to the bag holder 21, and each horn The switch mechanism 30 can be easily handled, and the workability of the mounting operation can be improved.

  Further, in a state where each horn switch mechanism 30 is attached to the bag holder 21, the damper holder 42 is positioned between the elastic member 41 and the bag holder 21. For this reason, the addition of the damper holder 42 has an effect on the elastic member 41 being sandwiched from the front and rear by the bag holder 21 and the pin holder 32 (slider) and from the outside and the inside in the radial direction. Can be suppressed.

(Second Embodiment)
Next, a second embodiment of the steering wheel damping structure will be described with reference to FIGS.

In the second embodiment, an elastic member 41 having a different form from the first embodiment is used.
FIG. 13A shows a cross-sectional structure of the horn switch mechanism 30 attached to the bag holder 21, and FIG. 14 shows a cross-sectional structure of the horn switch mechanism 30 in a cross section different from that in FIG. More specifically, FIG. 13A shows a cross-sectional structure taken along line 13-13 in FIG. 12, and FIG. 14 is taken along line 14-14 perpendicular to line 13-13 in FIG. The cross-sectional structure is shown.

  As shown in FIGS. 13A and 14, a recess 32d is formed on the outer periphery of the cylindrical portion 32a of the pin holder 32 between the enlarged diameter portion 32b and the stepped portion 32c. In the cylindrical portion 32a, the portion sandwiched between the step portion 32c and the concave portion 32d constitutes an annular protrusion 32e. The annular protrusion 32e is located in front of the attachment hole 21g of the bag holder 21. The annular protrusion 32 e has a function of receiving the rear end portion of the coil spring 36.

  As shown in FIG. 13B, the elastic member 41 includes an inner cylinder portion 41c, an outer cylinder portion 41d, and a connecting portion 41e. The inner cylinder portion 41c has a cylindrical shape extending in the front-rear direction, has an insertion hole 41a, and is mounted on the outside of the recess 32d. The outer cylinder part 41d has a larger inner diameter than the inner cylinder part 41c and has a cylindrical shape extending in the front-rear direction. The outer cylinder portion 41d is disposed on the same axis as the inner cylinder portion 41c, and surrounds the inner cylinder portion 41c. The connecting portion 41e has an annular shape, and connects the rear end portion of the inner cylindrical portion 41c and the rear end portion of the outer cylindrical portion 41d. A space between the inner cylinder portion 41c and the outer cylinder portion 41d and in front of the connecting portion 41e constitutes a groove portion 41b.

  As shown in FIG. 14, the elastic member 41 is sandwiched from the outer side and the inner side in the radial direction by the clamping part 21 i of the bag holder 21 and the concave part 32 d of the cylindrical part 32 a. The elastic member 41 is sandwiched from the front and rear by the attachment portion 21f and the enlarged diameter portion 32b of the bag holder 21. In this regard, the second embodiment is common to the first embodiment.

  In 2nd Embodiment, the front-end part of the inner cylinder part 41c in the elastic member 41 is extended ahead rather than 1st Embodiment, and has penetrated in the attachment hole 21g. The front end surface of the inner cylinder part 41c is located in the vicinity of the front surface of the attachment part 21f, and approaches or contacts the annular protrusion 32e. With this configuration, the front end portion of the inner cylinder portion 41c is positioned inside the mounting hole 21g in the radial direction. Moreover, the inner cylinder part 41c of the elastic member 41 is located inside the attachment hole 42c of the damper holder 42 in the radial direction.

  Here, as shown in FIG. 13A, the smaller one of the interval between the inner wall surface of the mounting hole 42c and the inner cylinder part 41c and the interval between the inner wall surface of the attachment hole 21g and the inner cylinder part 41c is defined as an interval C1. To do. Further, the distance between the side wall portion 33b of the contact holder 33 and the enlarged diameter portion 32b of the pin holder 32 is C2. In the second embodiment, the intervals C1 and C2 are set so that C1 <C2.

Other configurations are the same as those in the first embodiment. For this reason, the same elements as those described in the first embodiment are denoted by the same reference numerals, and redundant description is omitted.
In the vibration damping structure of the second embodiment configured as described above, the damper holder 42, the pin holder 32, and the contact holder 33 are all made of resin and are hard. The bag holder 21 is made of metal and is hard. Therefore, the elastic member 41 is elastically deformed along with the vibration of the steering wheel 10 and greatly vibrates with the airbag device 20, so that the inner wall surface of the mounting hole 42 c of the damper holder 42 and the inner wall surface of the mounting hole 21 g of the bag holder 21 are When contacting the cylindrical portion 32a of the pin holder 32, there is a possibility that abnormal noise (sounding sound) is generated. Such a situation can occur, for example, when the vehicle is traveling on a rough road. Further, when the enlarged diameter portion 32b of the pin holder 32 comes into contact with the side wall portion 33b of the contact holder 33, there is a possibility that abnormal noise may be generated as described above.

  In this regard, in the second embodiment in which the front end portion of the inner cylindrical portion 41c of the elastic member 41 enters the mounting hole 21g, the inner wall surface of the mounting hole 42c of the damper holder 42 approaches the cylindrical portion 32a as described above. In this case, the inner wall surface is received by the inner cylinder portion 41c. The inner cylindrical portion 41c prevents the inner wall surface of the mounting hole 42c from coming into contact with the cylindrical portion 32a. Similarly, when the inner wall surface of the attachment hole 21g of the bag holder 21 approaches the cylindrical portion 32a, the inner wall surface is received by the front end portion of the inner cylinder portion 41c. The front end portion of the inner cylinder portion 41c prevents the inner wall surface of the mounting hole 21g from coming into contact with the cylindrical portion 32a.

  Therefore, even if sound is generated by the inner wall surfaces of the mounting holes 42c and 21g coming into contact with the inner cylinder portion 41c, the sound is generated when the inner wall surfaces are in contact with the cylindrical portion 32a, that is, between the hard parts. It is smaller than the sound generated by contact. This is because the generation of sound is suppressed by the elastic deformation of the inner cylinder portion 41c due to the contact with the inner wall surface.

  Further, as shown in FIG. 13A, since the interval C2 is larger than the interval C1, the inner wall surfaces of the mounting holes 42c and 21g are received by the inner cylinder portion 41c as described above, so that the pin holder 32 is expanded. The diameter portion 32 b is prevented from contacting the side wall portion 33 b of the contact holder 33.

Therefore, according to the second embodiment, the same effects as the above (1) to (3) can be obtained, and the following effects can be obtained.
(4) The inner cylinder part 41c in the elastic member 41 is extended forward, and is inserted into the attachment hole 21g of the bag holder 21 (FIG. 13A).

  Therefore, when a large vibration is transmitted to the steering wheel 10, the hard parts (the bag holder 21 and the pin holder 32, the damper holder 42 and the pin holder 32) are prevented from coming into contact with each other, and unpleasant noise caused by the contact. Can be suppressed.

(5) Both intervals C1 and C2 are set so that the interval C2 is larger than the interval C1 (FIG. 13A).
Therefore, when a large vibration is transmitted to the steering wheel 10, the enlarged diameter portion 32 b of the hard pin holder 32 is prevented from coming into contact with the side wall portion 33 b of the hard contact holder 33, and abnormal noise is generated due to the contact. Can be suppressed.

Moreover, it is only necessary to set both the intervals C1 and C2 so as to satisfy the above conditions, and it is not necessary to add a part for preventing contact or to provide a structure.
(Third embodiment)
Next, a third embodiment of the steering wheel damping structure will be described with reference to FIG.

  The third embodiment is common to the second embodiment in that the elastic member 41 includes an inner cylinder portion 41c, an outer cylinder portion 41d, and a connecting portion 41e. The difference of the third embodiment from the second embodiment is that the connecting portion 41e is arranged at an intermediate portion instead of the end portions of the inner cylinder portion 41c and the outer cylinder portion 41d in the front-rear direction. By this connecting part 41e, the intermediate part in the front-rear direction of the inner cylinder part 41c and the intermediate part in the front-rear direction of the outer cylinder part 41d are connected. The connection part 41e is orthogonal to the front-back direction.

The configuration other than the above is the same as that of the second embodiment. For this reason, the same elements as those described in the second embodiment are denoted by the same reference numerals, and redundant description is omitted.
In the vibration damping structure of the third embodiment configured as described above, the elastic member 41 vibrates with the airbag device 20 while elastically deforming along with the vibration of the steering wheel 10. At this time, in the elastic member 41, the movement of the bag holder 21 and the damper holder 42 is transmitted to the connecting part 41e via the outer cylinder part 41d, or the movement of the pin holder 32 is transmitted to the connecting part 41e via the inner cylinder part 41c. . Due to this transmission, the connecting portion 41e is elastically deformed, so that the elastic member 41 functions as a spring of the dynamic damper.

  Here, since the connection part 41e is located in the intermediate part about the front-back direction between the inner cylinder part 41c and the outer cylinder part 41d, the movement of the bag holder 21 and the damper holder 42 passes through the outer cylinder part 41d. Therefore, the movement of the pin holder 32 is easily transmitted to the connection part 41e via the inner cylinder part 41c. The connecting portion 41e is elastically deformed by being compressed in the radial direction so that the inner cylindrical portion 41c and the outer cylindrical portion 41d are substantially parallel to each other.

Therefore, according to the third embodiment, the following effects can be obtained in addition to the same effects as the above (1) to (5).
(6) As the elastic member 41, an inner cylinder part 41c mounted on the outside of the cylindrical part 32a of the pin holder 32, an outer cylinder part 41d surrounding the inner cylinder part 41c, and an intermediate part in the front-rear direction of the inner cylinder part 41c Are connected to an intermediate portion of the outer cylinder portion 41d in the front-rear direction and provided with a connecting portion 41e orthogonal to the front-rear direction.

  Therefore, the connecting portion 41e can be easily elastically deformed by compressing the connecting portion 41e in the radial direction. By tuning the thickness and the like of the connecting portion 41e, the dynamic damper can be vibrated at the target vibration suppression frequency in the target vibration suppression direction.

(Fourth embodiment)
Next, a fourth embodiment of the vibration damping structure for the steering wheel will be described with reference to FIG.

  The fourth embodiment differs from the third embodiment in which the annular connecting portion 41e in the elastic member 41 is inclined with respect to the front-rear direction, that is, has a tapered shape, and is orthogonal to the front-rear direction. Yes. In 4th Embodiment, the connection part 41e has comprised the taper shape which diameter-reduces toward the front side. The rear end portion of the connecting portion 41e is connected to the outer tube portion 41d, and the front end portion of the connecting portion 41e is connected to the inner tube portion 41c in front of the connecting portion between the rear end portion and the outer tube portion 41d. ing.

The configuration other than the above is the same as that of the third embodiment. For this reason, the same elements as those described in the third embodiment are denoted by the same reference numerals, and redundant description is omitted.
In the vibration damping structure of the fourth embodiment configured as described above, when the elastic member 41 is elastically deformed along with the vibration of the steering wheel 10, the connecting portion 41e is elastically deformed by being compressed in the radial direction. This is the same as in the third embodiment. In addition, in 4th Embodiment, the connection part 41e is elastically deformed by bending so that the inclination | tilt angle with respect to the front-back direction may be changed. The repulsive force generated by the connecting portion 41e with this elastic deformation is smaller than when the connecting portion 41e is simply compressed in the radial direction and elastically deformed, and the connecting portion 41e is more easily elastically deformed.

Therefore, according to the fourth embodiment, the same effects as the above (1) to (6) can be obtained, and the following effects can be obtained.
(7) The connecting portion 41e of the elastic member 41 is inclined with respect to the front-rear direction.

  Therefore, the connecting portion 41e can be more easily elastically deformed by compressing and bending the connecting portion 41e in the radial direction. By tuning the thickness and the like of the connecting portion 41e, it is possible to set a target vibration suppression frequency lower.

In addition, said each embodiment can also be implemented as a modification which changed this as follows.
<About the bag holder 21>
The attachment portion 21f is not limited to being orthogonal to the front-rear direction, and may be inclined.

-The clamping part 21i may be provided in a different location from the said embodiment on the condition that it is a peripheral part of the attachment hole 21g.
-The clamping part 21i may be provided in three or more places of the peripheral part of the attachment hole 21g.

-The clamping part 21i may be comprised by another member from the attachment part 21f.
<About support members>
A member that satisfies the following condition may be used as the support member instead of the snap pin 31.

Condition 1: Inserted into the through hole 12c and locked to the cored bar 12 by the clip 13.
Condition 2: The bag holder 21 is supported by the core metal 12 so as to be movable in the front-rear direction by being inserted through the bag holder 21.

Condition 3: A pressure receiving portion (a flange portion 31a) that receives a rearward biasing force by a biasing member (coil spring 36) is provided behind the bag holder 21.
Condition 4: It is made of conductive metal, and its rear end surface (the flange 31a) functions as a fixed contact point.

  -The collar part 31a may be provided in the location different from a rear-end part on the condition that it is a location behind the attachment hole 21g of the bag holder 21 in the snap pin 31 (support member).

<About Pin Holder 32 (Slider)>
-The enlarged diameter part 32b may be provided in the outer periphery of the pin holder 32 (slider), and a location different from a rear-end part.

-In 1st Embodiment, the recessed part 32d may be formed in the cylindrical part 32a similarly to the 2nd-4th embodiment, and the elastic member 41 may be mounted | worn by this recessed part 32d.
-In 2nd-4th embodiment, the recessed part 32d of the cylindrical part 32a may be abbreviate | omitted similarly to 1st Embodiment.

<About the elastic member 41>
-As elastic member 41 in a 1st embodiment, what is shown in the following Drawing 17 (A)-(E) may be used.

FIG. 17A shows the elastic member 41 in which the groove 41b is not formed.
FIG. 17B shows an elastic member 41 in which long holes 43 that penetrate in the front-rear direction and extend in the circumferential direction are formed at a plurality of locations separated from each other in the circumferential direction.

FIG. 17C shows an elastic member 41 in which round holes 44 penetrating in the front-rear direction are formed at a plurality of locations separated from each other in the circumferential direction.
FIG. 17D shows an elastic member 41 in which an annular groove 45 opened on the outer peripheral surface is formed over the entire circumference.

FIG. 17E shows an elastic member 41 in which an annular groove 46 opened on the inner peripheral surface is formed over the entire periphery.
The various elastic members 41 described above are preferably selected and used as appropriate according to the characteristics required for damping.

-In 1st Embodiment, it replaces with the front surface of the elastic member 41, and the groove part 41b may open in a rear surface.
-The cross-sectional shape of the groove part 41b may be changed into the cross-sectional shape different from 1st Embodiment.

When the thickness of the elastic member 41 in the first embodiment is sufficiently large in the radial direction, the groove 41b may be provided at a plurality of locations in the radial direction of the elastic member 41.
-The inner peripheral part of the elastic member 41 of the said FIG. 17 (A)-(E) may be extended ahead, and may be penetrated in the attachment hole 21g. If it does in this way, the same effect as the above (4) in a 2nd embodiment will be acquired.

  -In 3rd and 4th embodiment, although the connection part 41e may have comprised the annular | circular shape, the some connection part 41e is mutually spaced apart in the circumferential direction so that it may form an annular | circular shape as a whole. It may be arranged. Also in this case, the plurality of connecting portions 41e are arranged at intermediate portions in the front-rear direction of the inner cylinder portion 41c and the outer cylinder portion 41d.

  -As the elastic member 41 in 4th Embodiment, what connected the inner cylinder part 41c and the outer cylinder part 41d by the taper-shaped connection part 41e which diameter-expands toward the front side may be used. In this case, the same effect as in the above (7) can be obtained.

  -In 2nd-4th embodiment, the front end surface of the inner cylinder part 41c is the same surface shape as the front surface of the attachment part 21f, or the same in the point which suppresses a contact with the cylindrical part 32a of the inner wall surface of the attachment hole 21g. Although it is desirable to be positioned in front of the front surface, it may be positioned slightly rearward of the front surface of the mounting portion 21f on the condition that it is in the mounting hole 21g.

  -In 2nd-4th embodiment, although it is desirable for the connection part 41e to be located in the center part about the length direction of the outer cylinder part 41d, even if located in the fixed area | region including a center part about the same direction Good.

<Others>
The vibration damping structure can also be applied to a steering wheel of a steering device in a vehicle other than a vehicle, such as an aircraft or a ship.

  DESCRIPTION OF SYMBOLS 10 ... Steering wheel, 12 ... Core metal (fixing member), 14 ... Steering shaft, 20 ... Airbag device, 21 ... Bag holder, 21f ... Mounting part, 21g ... Mounting hole, 21i ... Nipping part, 30 ... Horn switch mechanism 31 ... Snap pins (support members), 31a ... collars, 32 ... pin holders (sliders), 32a ... cylindrical parts, 32b ... enlarged diameter parts, 40 ... horn devices, 41 ... elastic members, 41c ... inner cylinder parts, 41d ... outer cylinder part, 41e ... connection part, 42 ... damper holder.

Claims (9)

And path head portion, and an air bag device and a bag holder for forming a bag receiving space between said pad portion,
A flange portion and a long portion extending forward from the flange portion, and attached to a steering wheel using a snap fit structure at a front end portion of the elongated portion , and the airbag at the flange portion A support member for supporting the device;
The whole is formed in an annular shape by an elastic material made of rubber or elastomer, and is on the outer peripheral side of the long portion of the support member and between the bag holder and the long portion of the support member. An elastic member that is disposed and suppresses vibration transmitted between the airbag device and the support member;
A damping structure for a steering wheel that causes the airbag device to function as a damper mass of a dynamic damper and allows the elastic member to function as a spring of a dynamic damper;
It said bag holder includes a bag holder side mount hole penetrating in a direction after pre-the bag holder,
The elongated portion of the support member is inserted through the bag holder side mounting hole,
A damper holder that holds the elastic member is disposed between the elastic member and the bag holder,
The elastic member is attached around the bag holder side attachment hole via the damper holder,
A portion extending forward is formed in the radially inner portion of the elastic member, and the front end edge of the radially inner portion of the elastic member is located in front of the front end edge of the radially outer portion,
The damper holder includes a side wall portion disposed radially outside the elastic member, a front wall portion extending radially inward from the side wall portion and disposed on a front side of the radially outer portion of the elastic member , A damper holder side mounting hole penetrating in the front-rear direction inward of the front wall in the radial direction;
The elongated portion of the support member is inserted into the damper holder side mounting hole through the elastic member ,
A portion of the elastic member that extends forward is a vibration damping structure for a steering wheel that is positioned radially inward of the damper holder side mounting hole. And path head portion, and an air bag device and a bag holder for forming a bag receiving space between said pad portion,
A flange portion and a long portion extending forward from the flange portion, and attached to a steering wheel using a snap fit structure at a front end portion of the elongated portion , and the airbag at the flange portion A support member for supporting the device;
The whole is formed in an annular shape by an elastic material made of rubber or elastomer, and is on the outer peripheral side of the long portion of the support member and between the bag holder and the long portion of the support member. An elastic member disposed to suppress vibration transmitted between the airbag device and the support member;
A pin holder that is disposed between the elongated portion of the support member and the elastic member and holds the support member slidably in the front-rear direction;
A damper holder disposed between the elastic member and the bag holder to hold the elastic member;
With
A damping structure for a steering wheel that causes the airbag device to function as a damper mass of a dynamic damper and allows the elastic member to function as a spring of a dynamic damper;
It said bag holder includes a mounting hole penetrating in a direction after pre-the bag holder,
The elongated portion of the support member is inserted through the mounting hole,
The elastic member has a first portion extending from the radially inner side of the damper holder to the radially outer side of the pin holder, and a second portion extending forward from the front end of the first portion,
The first portion is in contact with a radially inner side of the damper holder and a radially outer side of the pin holder;
The first portion is a steering wheel damping structure that is located only on the rear side of the bag holder. Before SL elastic member damping the steering wheel according to claim 2 mounted on the periphery of the mounting hole in the bag holder through the damper holder. The steering wheel is further provided with a horn switch mechanism that operates the horn device by a pressing operation on the airbag device,
2. The vibration damping structure for a steering wheel according to claim 1, wherein the horn switch mechanism includes a slider that is disposed between an outer periphery of the support member and the elastic member and moves forward by the pressing operation. 5. The steering wheel damping structure according to claim 4, wherein a biasing member that biases the airbag device away from the steering wheel is disposed on an outer periphery of the support member. The steering wheel includes a through hole penetrating the steering wheel in the front-rear direction,
The snap-fit structure includes a locking groove provided at the front end portion of the support member, and a clip that is held by the steering wheel and that engages with the locking groove corresponding to the through hole. Item 6. The steering wheel damping structure according to Item 5. Between the front end portion of the support member and the inner wall surface of the through hole, a resin piece for receiving the urging force toward the front of the urging member and supporting the support member on the steering wheel is disposed. The vibration damping structure for a steering wheel according to claim 6. The steering wheel has a skeleton portion including a fixing member,
The through hole is provided in the fixing member,
The vibration damping structure for a steering wheel according to claim 7, wherein the support member is directly attached to the fixing member using a snap-fit structure. And path head portion, and an air bag device and a bag holder for forming a bag receiving space between said pad portion,
A flange portion and a long portion extending forward from the flange portion, and attached to a steering wheel using a snap fit structure at a front end portion of the elongated portion , and the airbag at the flange portion A support member for supporting the device;
The whole is formed in an annular shape by an elastic material made of rubber or elastomer, and is on the outer peripheral side of the long portion of the support member and between the bag holder and the long portion of the support member. An elastic member that is disposed and suppresses vibration transmitted between the airbag device and the support member;
Allowing the airbag device to function as a damper mass of a dynamic damper, and causing the elastic member to function as a spring of the dynamic damper;
The elastic member has a front surface and a rear surface, and includes a groove portion opening in at least one of the front surface and the rear surface.

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