JP2014088902A - Ball joint - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ball joint capable of ensuring conductivity between a ball stud and a knuckle without affecting slidability.SOLUTION: A stud part 22 of a ball stud 15 and a conductive arm 16 are directly connected with a conductive member 19 to electrically connect the arm 16 and a conductive knuckle 13. The ball joint can be constituted not to apply electrical current to sliding parts such as a ball 21 slidably housed in a housing 31 of the arm 16, and conductivity can be ensured without affecting slidability.

Description

  The present invention relates to a ball joint including a ball stud having a ball portion slidably received in a housing.

  In recent years, with the development of vehicle technology such as an in-wheel motor used in an electric vehicle, for example, a configuration capable of supplying electric power from a vehicle power source to the vicinity of the wheel is required.

  Therefore, conventionally, for example, a configuration in which a power source on the vehicle body side and a motor on the axle side are directly connected by a conductor (for example, refer to Patent Document 1), and a configuration in which conductive wires are disposed in a groove-type suspension link (for example, a patent). Reference 2), or a structure in which the suspension arm is formed of a conductive member, and the power source on the vehicle body side and the motor on the axle side are electrically connected by the suspension arm (see, for example, Patent Document 3). It has been known.

  However, in the configuration described in each of the above patent documents, it is not considered to secure the conductivity of the ball joint that performs a movement such as a swing or a rotation and directly connects the suspension and the knuckle. Ball joints generally use resin ball seats (bearing seats) and lubricants (grease) at the sliding parts, so they become insulators and make the ball joints conductive. It is not easy.

  In this regard, it is conceivable to electrically connect the housing and the ball stud via a conductive ball sheet and a ball portion (see, for example, Patent Document 4). However, in this configuration, a current flows through the sliding portion, which may adversely affect the slidability such as deterioration due to electrolysis of the lubricant.

  If the ball joint is insulative, it is necessary to electrically connect the conductive part to the vehicle body or knuckle via a connector after mounting on the vehicle. To increase.

Japanese Patent Laying-Open No. 2005-75319 (page 3-5, FIG. 2-4) JP-A-6-278433 (page 2-3, FIG. 1-3) JP 2009-248902 A (page 3-5, FIG. 1) Japanese translation of PCT publication No. 2003-525404 (page 5-7, FIG. 1)

  As described above, there is a demand for a ball joint that can ensure electrical conductivity between the ball-side member and the mounted portion without deteriorating slidability.

  This invention is made in view of such a point, and it aims at providing the ball joint which can ensure the electroconductivity between a ball side member and a to-be-attached part, without affecting slidability. .

  The ball joint according to claim 1 includes a ball part, a ball side member provided with a shaft part that protrudes from the ball part and is attached to a conductive attached part, and a conductive material that slidably accommodates the ball part. A ball receiving side member, and the ball receiving side member and the shaft portion of the ball side member which are directly connected to electrically connect the ball receiving side member and the mounted portion to which the shaft portion is attached. And a sex member.

  According to a second aspect of the present invention, there is provided a ball joint according to the first aspect, wherein the ball joint is housed in the ball receiving side member and slidably holds the ball portion; And a lubricant interposed therebetween.

  The ball joint according to claim 3 is the ball joint according to claim 1 or 2, wherein the conductive member includes a conductive retainer fitted to the shaft portion of the ball side member, and one end side electrically connected to the retainer. The other end side includes a conductor electrically connected to the ball receiving side member.

  According to a fourth aspect of the present invention, there is provided the ball joint according to the third aspect, further comprising a dust cover that covers a space between the ball receiving side member and the ball side member, and the retainer is located outside the dust cover and is electrically conductive. The body is a conducting wire located outside the dust cover.

  The ball joint according to claim 5 is provided with a dust cover covering the space between the ball receiving side member and the ball side member in the ball joint according to claim 3, wherein the retainer is located inside the dust cover and is electrically conductive. The body is a conductive coil spring located inside the dust cover.

  A ball joint according to a sixth aspect of the present invention is the ball joint according to the fifth aspect, wherein the ball receiving side member includes a groove portion that fits and holds the other end side of the coil spring.

  According to the ball joint of claim 1, the conductive ball receiving side member and the shaft portion of the ball side member are directly connected by the conductive member, and the ball receiving side member and the shaft portion are attached. By electrically connecting to the mounted portion of the ball, it can be configured so that no current flows to the ball portion side slidably accommodated in the ball receiving side member without affecting the slidability. The conductivity between the ball side member and the ball receiving side member can be ensured.

  According to the ball joint of claim 2, in addition to the effect of the ball joint of claim 1, the bearing seat for slidably holding the ball portion is accommodated in the ball receiving side member, and the bearing seat By interposing a lubricant between the inside of the ball and the ball portion, the slidability can be further improved, and even when energized between the ball receiving side member and the mounted portion, the lubricant is deteriorated. Can be prevented.

  According to the ball joint described in claim 3, in addition to the effect of the ball joint described in claim 1 or 2, the conductive retainer is fitted to the shaft portion of the ball side member, and one end side is electrically connected to the retainer. By electrically connecting the other end of the electrically connected conductor to the ball receiving side member, the conductive member can be easily configured, and the ball receiving side member and the mounted portion can be easily electrically connected. .

  According to the ball joint according to claim 4, in addition to the effect of the ball joint according to claim 3, the retainer is disposed outside the dust cover, and the conductor is disposed outside the dust cover as a conductor. Connection work of the conductive member becomes easier, and space is not taken outside the dust cover.

  According to the ball joint of claim 5, in addition to the effect of the ball joint of claim 3, the retainer is arranged inside the dust cover and the conductor is arranged inside the dust cover as a conductive coil spring. This saves space outside the dust cover.

  According to the ball joint of the sixth aspect, in addition to the effect of the ball joint of the fifth aspect, by providing the ball receiving side member with a groove portion that fits and holds the other end side of the coil spring, The displacement of the other end side of the coil spring due to the operation can be prevented more reliably.

It is sectional drawing which shows the ball joint of the 1st Embodiment of this invention. It is a top view which shows the retainer of a ball joint same as the above. It is sectional drawing which shows the ball joint of the 2nd Embodiment of this invention.

  The configuration of the first embodiment of the present invention will be described below with reference to FIGS.

  In FIG. 1, reference numeral 11 denotes a ball joint. The ball joint 11 is a conductive member located on a suspension (suspension device) (not shown) which is a vehicle body side member located on the vehicle body side of a vehicle such as an automobile and a wheel (wheel) side. The suspension link is connected to the knuckle 13, which is a wheel side member as the attached portion. The ball joint 11 includes a ball stud 15 made of metal that is a ball side member as a movable member, a metal arm 16 that is a ball receiving side member as a fixed member, and the arm 16 and the ball stud. A ball seat 17 that is a bearing seat made of a synthetic resin or the like interposed between the ball stud 15, a dust cover 18 that is a dust-proof member disposed between the ball stud 15 and the arm 16, and a ball stud 15. A conductive member 19 that directly connects the arm 16 is provided. In addition, the up-down direction shown below shall mean the up-down direction of FIG.

  The ball stud 15 is integrally formed of a member such as metal, for example, and is a ball portion 21 that is a substantially spherical sphere head, and a shaft portion that is a round shaft that is long in the vertical direction and protrudes from the ball portion 21. Stud portion 22 is provided.

  The ball portion 21 is attached to the arm 16 while being slidably (rotatably) held inside the ball seat 17.

  The stud portion 22 protrudes upward from the ball portion 21 at a position where the axial center passes through the center position of the ball portion 21, for example. Further, the stud portion 22 includes a diameter-expanding portion 24 that is a base end portion that gradually increases in diameter from the ball portion 21 side that is the base end side to the upper side (tip end side) that is the anti-ball portion 21 side. A cylindrical conductive member mounting portion 25 located at the upper end, which is the tip portion of the diameter portion 24, and gradually from the upper side on the side opposite to the ball portion 21 of the conductive member mounting portion 25 to the upper side (tip side) A diameter-reduced portion 26, which is a tapered portion as a connecting portion for reducing the diameter, and a screw groove 27, which is a fixing portion provided at an upper end portion, which is a tip portion of the diameter-reduced portion 26, are integrally provided. Then, the reduced diameter portion 26 side of the stud portion 22 is inserted into the knuckle 13, and a nut (not shown) is screwed into the screw groove 27 so that the ball joint 11 is connected and fixed to the knuckle 13. . The knuckle 13 is electrically connected to a power-supplied part arranged on the wheel side, such as an in-wheel motor.

  The arm 16 constitutes a part of the suspension, and includes a cylindrical housing portion 31 as a ball receiving portion, and a circular plate-like plug that is a separate closing member attached to the housing portion 31. 32 and an arm main body 33 projecting sideways from the outer periphery of the housing 31, that is, along a direction intersecting (orthogonal) with the axial direction of the ball stud 15. In the arm 16, the housing portion 31 and the arm main body portion 33 are integrally formed of a conductive member such as iron or aluminum, and the plug 32 is formed of, for example, a synthetic resin using at least a part of a metal member. It is formed by inclusion. The suspension is electrically connected to a power source arranged on the vehicle body side.

  The housing portion 31 is also called a socket, and has an inner chamber 35 that holds the ball portion 21 via the ball seat 17, and first and second openings 36 and 37 that communicate with the inner chamber 35. . Further, a stepped portion 38 that is a groove-like cover groove into which the lower end side of the dust cover 18 is fitted is formed on the outer periphery of the housing portion 31 on the first opening 36 side. An attachment step 39 for attaching the plug 32 is formed on the inner periphery of the second opening 37 of the housing part 31.

  The first opening 36 is positioned coaxially with the housing portion 31 and gradually expands from the inner chamber 35 side to the upper side, which is the outer side. Further, the stud portion 22 of the ball stud 15 is inserted into the first opening 36, and the upper side of the ball portion 21 and the stud portion 22 are exposed to the outside of the housing portion 31.

  The second opening 37 is located coaxially with the housing portion 31 and is covered and closed by the plug 32.

  The plug 32 is held by a caulking deformation portion 41 which is a holding portion in which the outer peripheral edge portion is attached to the attachment step portion 39 and the edge portion of the second opening 37 is caulked and deformed inward. Thus, it is fixed to the housing part 31 (arm 16). A space surrounded by the plug 32, the ball portion 21, and the ball seat 17 serves as a lubricant accommodating portion 43 that accommodates an insulating lubricant (grease) 42, for example.

  Further, the ball sheet 17 is integrally formed in an approximately cylindrical shape having an opening on the upper and lower surfaces, for example, with insulating synthetic resin. In other words, the ball seat 17 has substantially circular (first and second) end surface openings 45 and 46 at the upper and lower end portions in the axial direction, the opening diameter of which is smaller than the outer diameter of the ball portion 21. doing. In addition, a sliding contact surface 47 that is a holding surface communicating with the end surface openings 45 and 46 is formed inside the ball seat 17, and the sliding contact surface 47 slides on the outer peripheral surface of the ball portion 21 (rotation). It is held possible. Therefore, the ball seat 17 is accommodated in the inner chamber 35 of the arm 16 together with the ball portion 21 of the ball stud 15, and the ball portion 21 is rotatably held in the inner chamber 35 via the ball seat 17. Has been. Further, the lubricant 42 accommodated in the lubricant accommodating portion 43 is interposed between the sliding contact surface 47 of the ball seat 17 and the outer peripheral surface of the ball portion 21. The ball seat 17 is, for example, a so-called two-piece type that is divided into a seat body portion that holds the ball portion 21 and a cushion portion that is attached in the ball portion 21 and elastically supports the ball portion 21. And so on.

  The dust cover 18 is also called a dust seal or boot, and is a flat, generally cylindrical shape in which the central portion between both ends in the axial direction bulges in the radial direction by an elastic member such as soft rubber or soft synthetic resin. Is formed. The dust cover 18 has an upper end portion that is one end portion in the axial direction fitted on the outer peripheral side of the stud portion 22, and a lower end portion that is the other end portion in the axial direction is fitted on the outer peripheral side of the step portion 38 of the arm 16. Yes. Further, the lower end portion of the dust cover 18 is fixed to the step portion 38 by a clip 49 which is a substantially circular annular member.

  The conductive member 19 electrically connects the arm 16 to the stud portion 22 of the ball stud 15 and the knuckle 13 to which the stud portion 22 is attached. The retainer 51 and the conductive member connected to the retainer 51 are electrically connected. A conductor 52 which is a body and is located outside the dust cover 18.

  The retainer 51 is integrally formed of a conductive material having high conductivity (low resistance) such as copper or silver, or an alloy containing them, and is a cylindrical holding portion. It has a wearing part 54 and a connecting part 55 projecting laterally from the fitting part 54 (FIG. 2).

  In the fitting portion 54, the stud portion 22 of the ball stud 15 is press-fitted, and is fitted on the outer periphery of the conductive member mounting portion 25 of the stud portion 22 of the ball stud 15, and is integrally fixed. Further, a flange portion 54a as a mounted portion connecting portion that directly contacts the knuckle 13 is provided in a flange shape at the upper end portion, which is one end portion of the fitting portion 54, for example. The upper end of the dust cover 18 is fitted to the outer periphery of the fitting part 54 at a position below the flange part 54a. That is, the fitting portion 54 is a support portion for the dust cover 18.

  The connecting portion 55 is a portion where one end side of the conducting wire 52 is electrically and mechanically connected, and extends from the flange portion 54a of the fitting portion 54 to the axial direction of the fitting portion 54 (the axial direction of the stud portion 22). It protrudes in the direction intersecting (orthogonal).

  The conducting wire 52 is formed of a material having high conductivity (low resistance) such as copper or silver, or an alloy containing them. The other end of the conducting wire 52 is electrically and mechanically connected to the upper portion of the arm main body 33 of the arm 16. The conductive wire 52 has a coil spring shape, for example, spirally wound between both ends, and can be expanded and contracted following the swing and rotation of the ball stud 15.

  Therefore, the conductive member 19 electrically connects the suspension and the knuckle 13 without passing through the sliding portions such as the ball portion 21 and the ball seat 17 of the ball stud 15 (bypassing the sliding portion). It has become.

  Next, the operation of the first embodiment will be described.

  First, when the ball joint 11 is assembled, a ball stud 15 formed in advance is inserted from the second opening 37 of the housing portion 31 formed in advance.

  Next, the outer peripheral surface of the ball portion 21 of the ball stud 15 is rotatably held by the sliding contact surface 47 of the ball seat 17, and the ball seat 17 is opened together with the ball portion 21 in the inner chamber 35 of the housing portion 31. Press fit from 37. In this state, the stud portion 22 is inserted through the first opening 36 and protrudes above the housing portion 31. The lubricant 42 may be applied in advance to the outer peripheral surface of the ball portion 21 or may be injected later.

  Further, the outer peripheral edge portion of the plug 32 is attached to the stepped portion 38, and the edge portion of the second opening 37 is caulked and deformed toward the center side to form a caulking deformed portion 41 to fix the outer peripheral edge portion of the plug 32. .

  Further, the dust cover 18 is attached between the mounting step portion 39 of the housing portion 31 and the stud portion 22 of the ball stud 15, and the lower end portion of the dust cover 18 is fixed to the mounting step portion 39 by the clip 49.

  Thereafter, the fitting portion 54 of the retainer 51 is press-fitted between the stud portion 22 and the upper end portion of the dust cover 18, and the fitting portion 54 is fixed to the conductive member mounting portion 25.

  Then, the lead wire 52 is connected between the fitting portion 54 of the retainer 51 and the upper portion of the arm main body portion 33 of the arm 16 to complete the ball joint 11.

  In the completed ball joint 11, the reduced diameter portion 26 side of the stud portion 22 of the ball stud 15 is inserted into the knuckle 13, and a nut is tightened in the screw groove 27, whereby the knuckle 13 has the flange portion 54a of the retainer 51 as a seating surface. Fixed to the connection. That is, the flange portion 54a of the retainer 51 is in direct contact with and electrically connected to the knuckle 13. As a result, the suspension and the knuckle 13 are electrically connected by the conductive member 19.

  As described above, according to the first embodiment, the conductive arm 16 and the stud portion 22 of the conductive ball stud 15 are directly connected by the conductive member 19, and the arm 16 and the stud portion are connected. By electrically connecting a knuckle (attached part) 13 to which 22 is attached, a current is not passed through a sliding part such as a ball part 21 slidably accommodated in a housing part 31 of the arm 16. Thus, the conductivity between the ball stud 15 and the arm 16 can be ensured without affecting the slidability.

  That is, the ball sheet 17 that slidably holds the ball part 21 is accommodated in the housing part 31 of the arm 16, and the lubricant 42 is interposed between the inside of the ball sheet 17 and the ball part 21. As a result, the slidability can be further improved, and even when the arm 16 (suspension) and the knuckle 13 are energized, deterioration due to the electrolysis of the ball seat 17 and the lubricant 42 can be prevented. Since the generated fine particles (spatter) can be prevented from adhering to the ball portion 21 and the like, the slidability is not affected.

  Further, a conductive retainer 51 is fitted and electrically connected to the stud portion 22 of the ball stud 15, and the other end of the conducting wire 52 electrically connected at one end to the retainer 51 is electrically connected to the arm 16. Thus, the conductive member 19 can be easily configured, and the arm 16 (suspension) and the knuckle 13 can be easily electrically connected.

  That is, in this ball joint 11, since the connection between the ball stud 15 and the arm 16 is completed as a single unit, the electrical connection between the suspension side and the knuckle 13 side can be achieved simply by connecting the stud portion 22 to the knuckle 13 and assembling. Therefore, it is not necessary to perform connection using a connector or the like after assembly, and the number of man-hours for assembling the vehicle can be reduced.

  The retainer 51 is arranged outside the dust cover 18 and the conductor is arranged outside the dust cover 18 as the conducting wire 52, so that the connection work of the conductive member 19 becomes easier and the conducting wire 52 is arranged. Can be set freely, so there is no space outside the dust cover 18.

  In addition, since the retainer 51, the conductive wire 52, and the arm 16 can be configured by the conductive member 19 and a circuit without using an organic material, stable energization is possible.

  Next, a second embodiment will be described with reference to FIG. In addition, about the structure and effect | action similar to the said 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  In the second embodiment, a conductive member 61 is provided in place of the conductive member 19 of the first embodiment.

  The conductive member 61 is configured to directly connect the arm 16 (housing part 31) and the stud part 22 of the ball stud 15 to electrically connect the arm 16 (housing part 31) and the knuckle 13. And a coil spring 64 which is a conductor connected to the retainer 63 and is located inside the dust cover 18.

  The retainer 63 is formed in a cylindrical shape from a conductive material having high conductivity (low resistance) such as copper or silver, or an alloy containing them, and the stud portion 22 of the ball stud 15 is formed. Is inserted into the outer periphery of the conductive member mounting portion 25 of the stud portion 22 of the ball stud 15 and fixed integrally therewith, and the upper end portion is directly connected to the knuckle 13 to which the stud portion 22 is attached. Touch and be electrically connected. Further, a flange 63a as a conductor connecting portion protrudes from the lower end portion of the retainer 63 in a flange shape. The upper end portion of the dust cover 18 is fitted to the outer periphery of the retainer 63 at a position above the flange portion 63a. That is, the retainer 63 serves as a support portion for the dust cover 18.

  The coil spring 64 is made of a material having high conductivity (low resistance) such as copper or silver, or an alloy containing them. The coil spring 63 is wound so that the diameter dimension is larger on the lower end side, which is the other end side, than the upper end side, which is the one end side, and the stud portion 22 is inserted inside. In other words, the coil spring 64 is located around the stud portion 22 (the enlarged diameter portion 24). Furthermore, the upper end side of the coil spring 64 is fixed and electrically connected to the flange portion 63a of the retainer 63, and the lower end side is a seat surface recessed in an annular shape when viewed from above at the upper portion of the housing portion 31. It is fitted and held in a fixed groove 66 which is a groove portion. Therefore, the coil spring 64 is stably fixed at a fixed position with respect to the arm 16 (housing portion 31). The coil spring 64 can expand and contract and deform following the swing of the ball stud 15, and the upper end of the coil spring 64 is in sliding contact with the flange 63a of the retainer 63 with respect to the rotation of the ball stud 15. The contact with the retainer 63 is maintained.

  Therefore, the conductive member 61 electrically connects the suspension and the knuckle 13 without passing through the sliding parts such as the ball portion 21 and the ball seat 17 of the ball stud 15 (bypassing the sliding parts). It has become.

  Furthermore, in the present embodiment, the ball seat 17 includes, for example, a seat body portion 17a that holds the stud portion 22 side of the ball portion 21, and an anti-stud portion 22 of the ball portion 21 that is disposed inside the seat body portion 17a. This is a so-called two-piece type separately provided with a cushion portion 17b that elastically supports the side.

  The conductive arm 16 (housing portion 31) and the stud portion 22 of the ball stud 15 are directly connected by the conductive member 61 to electrically connect the arm 16 and the knuckle (attached portion) 13. By having the same configuration as that of the first embodiment, the same effects as those of the first embodiment can be obtained.

  In addition, the retainer 63 is disposed inside the dust cover 18 and the conductor is disposed inside the dust cover 18 as a conductive coil spring 64, so that a space for the conductive member 61 is provided outside the dust cover 18. Therefore, the ball joint 11 can be further downsized, and pebbles and the like bounce when the vehicle travels, and disconnection due to so-called chipping hardly occurs.

  Furthermore, by providing the arm 16 (housing 31) with a fixing groove 66 that fits and holds the other end of the coil spring 64, the coil stud can be moved by the movement of the ball stud 15 such as swinging or turning. It is possible to more reliably prevent the other end side of the spring 64 from being displaced from the arm 16 (housing portion 31).

  The conductive member 61 can constitute a circuit without the organic material through the retainer 63, the coil spring 64, and the arm 16 (housing portion 31), and the coil spring 64 reliably follows the operation of the ball stud 15. And a stable contact area can be maintained, so that stable energization is possible.

  In the second embodiment, the ball seat 17 may be a one-piece type similar to the first embodiment.

  Further, in each of the above embodiments, the retainers 51 and 63 are directly connected to the knuckle (attached portion) 13 to electrically connect the arm 16 and the knuckle 13, but at least the stud portion 22 of the ball stud 15 is The arm 16 and the knuckle (attached portion) 13 may be electrically connected via the conductive members 19 and 61 and the stud portion 22.

  Further, although the stud portion 22 is directly connected to the knuckle 13, it may be configured to be connected to the knuckle 13 by interposing a separate conductive member having a mounted portion.

  Further, the ball joint 11 may be used for a tie rod end of a steering device.

  In the housing portion 31, the second opening 37 is closed by the plug 32. However, the housing portion 31 may be previously formed in a bottomed cylindrical shape, for example.

11 Ball joint
13 Knuckle as attached part
15 Ball stud as ball side member
16 Arm as ball receiving member
17 Ball seat as bearing seat
18 Dust cover
19, 61 Conductive member
21 Ball part
22 Stud part which is a shaft part
42 Lubricant
51, 63 Retainer
52 Conductor wire
64 Coil spring that is a conductor
66 Fixed groove as groove

Claims (6)

A ball-side member including a ball portion and a shaft portion protruding from the ball portion and attached to a conductive attachment portion;
A conductive ball receiving side member that slidably accommodates the ball portion;
A conductive member that directly connects the ball receiving side member and the shaft portion of the ball side member to electrically connect the ball receiving side member and the mounted portion to which the shaft portion is attached; A ball joint characterized by A bearing seat that is housed inside the ball receiving side member and slidably holds the ball portion;
The ball joint according to claim 1, further comprising a lubricant interposed between the inside of the bearing seat and the ball portion. The conductive member is
A conductive retainer fitted to the shaft of the ball side member;
The ball joint according to claim 1 or 2, further comprising: a conductor having one end electrically connected to the retainer and the other end electrically connected to the ball receiving side member. Comprising a dust cover covering between the ball receiving side member and the ball side member;
The retainer is located outside the dust cover,
The ball joint according to claim 3, wherein the conductor is a conductive wire located outside the dust cover. Comprising a dust cover covering between the ball receiving side member and the ball side member;
The retainer is located inside the dust cover,
The ball joint according to claim 3, wherein the conductor is a conductive coil spring located inside the dust cover. The ball joint according to claim 5, wherein the ball receiving side member includes a groove portion that fits and holds the other end side of the coil spring.

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