JP2006300204A - Ball joint - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ball joint capable of effectively improving durability and sealing performance. <P>SOLUTION: This ball joint 1 has a ball stud 2 having a spherical head portion 21 and a shaft portion 22, a socket 3 rotatably holding the spherical head portion 21, and a dust cover 4 covering an opened clearance 30 between the socket 3 and the ball stud 2. The dust cover 4 has an insertion hole 41 for inserting the shaft portion 22 of the ball stud 2, and a peripheral edge portion of the insertion hole 41 has a sealing projection portion slid on a ring plate 6 fitted to the shaft portion 22. The sealing projection portion has a DLC coating film on its surface. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a ball joint capable of rotatably connecting various members.

A ball joint having a rotatable ball stud is used, for example, in a suspension device of an automobile.
For example, as disclosed in Patent Document 1, the ball joint is configured such that a ball stud is rotatably held in a socket. In order to prevent foreign matter such as muddy water and dust from entering the socket from the open gap between the socket and the ball stud, a dust cover is disposed between the socket and the ball stud to cover the open gap. Has been established.

  Further, as disclosed in Patent Document 1, the dust cover has an insertion hole through which the shaft portion of the ball stud is inserted, and the periphery of the insertion hole is fitted into the shaft portion. A seal protrusion that slides with the ring plate is provided. In order to prevent foreign matter such as muddy water and dust from entering the dust cover from between the ring plate and the seal projection, the seal projection is pressed against the ring plate and crushed.

By the way, if the crushing amount (tightening allowance) of the above-mentioned seal projection is reduced, the seal projection will sag due to aging and heat history, and the crushing amount disappears, and there is a gap between the ring plate and the seal projection. May occur.
On the other hand, when the crushing amount of the seal protrusion is increased, the sliding resistance between the ring plate and the seal protrusion is increased. In this case, the surface pressure applied to the seal projection increases, and the seal projection tends to wear due to frequent rotation and swinging motion of the ball stud. In addition, when the sliding between the ring plate and the seal protrusion is not sufficiently performed, the dust cover may rotate together with the ball stud and be threaded.
Therefore, in order to reduce the sliding resistance between the ring plate and the seal projection, grease is applied to the seal projection to improve its slidability and improve the durability of the dust cover.

However, simply applying grease to the seal protrusions has the following problems.
That is, when the ball joint is used for a long period of time, the grease may deteriorate and the lubrication performance at the beginning of assembly may not be maintained. Further, since the dust cover is made of rubber, depending on the compatibility with the grease, the seal protrusion may contract or expand, and the durability and sealing performance may deteriorate. Further, when the automobile with the ball joint attached is not used for a long period of time, there is a risk that the seal protrusion will run out of grease (the oil film of grease will disappear).
Therefore, in order to suppress an increase in the amount of wear of the seal protrusion and improve both the durability and sealing performance of the ball joint, further contrivance has been required.

JP 2002-98133 A

  The present invention has been made in view of such conventional problems, and an object of the present invention is to provide a ball joint capable of effectively improving durability and sealing performance.

The present invention provides a ball stud having a ball head and a shaft, a socket that rotatably holds the ball head, and a dust cover that covers an open gap between the socket and the ball stud. At the joint,
The dust cover has an insertion hole through which the shaft portion is inserted, and a seal projection portion that slides on a ring plate fitted and disposed in the shaft portion is provided at a peripheral portion of the insertion hole. ,
The seal protrusion is formed on a ball joint formed by forming a DLC coating film (Claim 1).

The ball joint of the present invention is devised on the seal projection in the dust cover.
Specifically, the ball joint of the present invention has a DLC (diamond-like carbon) coating film formed on the seal protrusion that contacts the ring plate, thereby reducing the friction coefficient of the seal protrusion and improving the wear resistance. It is improving.

  The ball joint can freely rotate the ball stud with respect to the socket. The open gap between the socket and the ball stud is covered with a dust cover. Further, the dust cover has one end attached to the ball stud by engaging the peripheral edge portion of the insertion hole with a ring plate fitted and arranged in the shaft portion of the ball stud. The ring plate is in contact with the seal projection of the dust cover, and the seal projection is crushed by a predetermined crushing amount (tightening allowance). This prevents foreign matter such as muddy water and dust from entering the dust cover from between the ring plate and the seal projection.

  When using the ball joint, when the ball stud rotates with respect to the socket, the ring plate fitted in the shaft portion of the ball stud and the seal projection slide. At this time, since the DLC coating film is formed on the seal projection, the friction coefficient of the seal projection against the ring plate can be effectively reduced. Thereby, the wear resistance of the seal protrusion can be improved.

  Further, by effectively reducing the friction coefficient of the seal projection, the amount of crushing of the seal projection with respect to the ring plate can be increased. Thereby, it can prevent more effectively that the said foreign material penetrate | invades in a dust cover from between a ring plate and a seal projection part. In addition, the foreign matter can be prevented from entering even if the seal protrusion has a sag due to long-term use of the ball joint. Therefore, the sealing performance of the ball joint can be effectively improved.

In addition, even if the crushing amount of the seal protrusion is increased, the friction coefficient can be kept small, so that the seal protrusion can always slide with the ring plate, preventing the dust cover from being twisted or torn. can do. Therefore, the durability of the ball joint can be improved.
Therefore, according to the ball joint of the present invention, durability and sealing performance can be effectively improved.

A preferred embodiment of the present invention described above will be described.
In the present invention, the dust cover including the seal protrusion can be made of rubber, and can be made of, for example, chloroprene rubber (CR rubber), nitrile rubber (NBR), or the like.

The ball joint is configured so that the shaft portion of the ball stud is inserted and disposed in a through hole formed in the underbody member, and the dust cover is formed on a dust protrusion that contacts the underbody member. It is preferable to form a DLC coating film (claim 2).
In this case, the coefficient of friction of the dust projection can be effectively reduced by forming the DLC coating film on the dust projection. As a result, the amount of crushing of the dust projections with respect to the suspension member such as the suspension device can be increased, and it is more effective that the foreign matter enters the dust cover from between the suspension member and the dust projection. Can be prevented. Therefore, the sealing performance of the ball joint can be improved more effectively.

Further, the DLC coating film on the seal projection can be formed by using a so-called plasma polymerization method and fixing carbon contained in a hydrocarbon gas such as methane to the surface of the seal projection.
Further, when forming the DLC coating film on the surface of the seal protrusion, the surface of the seal protrusion is plasma-cleaned, hydrogen radicals are bonded to carbon on the surface, and then hydrocarbon gas is applied to the surface. By supplying and removing the hydrogen radicals by reacting with carbon and hydrogen contained in the hydrocarbon gas, the carbon contained in the hydrocarbon gas can be fixed to the surface of the seal projection. In this case, it is possible to form a DLC coating film that hardly peels off, particularly on the rubber seal projection.
The same method as described above can also be used when a DLC coating film is formed on the surface of the dust projection.

Hereinafter, embodiments of the ball joint of the present invention will be described with reference to the drawings.
As shown in FIG. 1, the ball joint 1 of this example includes a ball stud 2 having a ball head 21 and a shaft portion 22, a socket 3 that rotatably holds the ball head 21, and the socket 3 and ball stud. 2 and a dust cover 4 covering the open gap 30 between the two.

As shown in FIGS. 1 and 2, the dust cover 4 has an insertion hole 41 through which the shaft portion 22 of the ball stud 2 is inserted. The periphery of the insertion hole 41 is fitted into the shaft portion 22. A seal protrusion (seal lip) 5 that slides on the ring plate 6 is provided.
The seal projection 5 is formed by forming a DLC coating film 7 on the surface thereof as shown in FIG. In FIG. 3, a two-dot chain line indicates a place where the DLC coating film 7 is formed.

Below, it explains in full detail about the ball joint 1 of this example.
As shown in FIG. 1, the socket 3 is formed by disposing a resin ball sheet 31 in a holding recess facing the ball head 21 of the ball stud 2. The ball sheet 31 is formed with a grease groove.
Grease 10 is injected into the dust cover 4, and this grease 10 is also interposed between the ball seat 31 and the ball head 21 of the ball stud 2.

  As shown in the figure, the ball joint 1 is configured to freely rotate the ball stud 2 with respect to the socket 3. The movement of the ball stud 2 includes a rotation A and a swing B. The rotation A refers to a movement around the axial center of the shaft portion 22 of the ball stud 2, and the swing B is a ball stud. This is a movement in which the shaft portion 22 swings left and right around the center of the sphere of the second spherical head 21.

  As shown in FIG. 1, the dust cover 4 has the insertion hole 41 at one end and an engagement hole 42 for engaging the end 32 of the socket 3 at the other end. In the engagement hole 42, an insertion member 45 for fitting the end 32 of the socket 3 and fixing the dust cover 4 to the socket 3 is disposed integrally with the dust cover 4.

The dust cover 4 has an insertion hole 41 engaged with the ring plate 6 fitted and disposed in the shaft portion 22 of the ball stud 2. The dust cover 4 has an engagement hole 42 fitted into the end 32 of the socket 3 by a fitting member 45. Thus, the dust cover 4 is spanned between the shaft portion 22 of the ball stud 2 and the socket 3.
Note that the engagement hole 42 of the dust cover 4 is fixed to the end portion 32 of the socket 3 using another member such as a set ring instead of being inserted into the end portion 32 of the socket 3 using the insertion member 45. You can also.

Further, as shown in FIG. 1, the dust cover 4 is made of rubber and has flexibility. The dust cover 4 can follow when the ball stud 2 swings B.
Further, as shown in FIG. 2, the seal protrusion 5 has an annular shape, and protrudes toward the inner peripheral side (the central axis side of the ball stud 2) in the insertion hole 41 of the dust cover 4. Is formed. A reinforcing ring 44 is disposed around the insertion hole 41 in the dust cover 4.

  As shown in FIG. 2, the ring plate 6 is made of metal and has an annular shape. The ring plate 6 has a cylindrical portion 61 having an inner diameter slightly smaller than the outer diameter of the shaft portion 22 of the ball stud 2 and a flange formed so as to protrude radially outward from an end portion of the cylindrical portion 61 on the socket 3 side. Part 62. The cylindrical portion 61 is fitted into the shaft portion 22 of the ball stud 2, and the flange portion 62 is in contact with the vicinity of the insertion hole 41 of the dust cover 4 and holds one end of the dust cover 4.

  Further, as shown in the figure, the inner diameter of the seal projection 5 is slightly smaller than the outer diameter of the cylindrical portion 61 of the ring plate 6, and the insertion hole 41 of the dust cover 4 and the cylindrical portion 61 of the ring plate 6 are It is inserted. Since the seal projection 5 is in circumferential contact with the ring plate 6, the entire circumference of the seal projection 5 is crushed by a predetermined crushing amount (tightening allowance) X1. This prevents foreign matter such as muddy water and dust from entering the dust cover 4 from between the ring plate 6 and the seal projection 5.

Further, as shown in FIG. 4, the ball joint 1 of this example is used for a suspension device of an automobile, and is disposed between the two suspension members 81, 82 so as to be provided with the two suspension members 81. , 82 are rotatably connected.
The socket 3 is fixed to one suspension member 81, and the shaft portion 22 of the ball stud 2 is fixed to the other suspension member 82. Further, a threaded portion 221 is formed at the tip of the shaft portion 22 of the ball stud 2. The distal end portion of the shaft portion 22 is inserted and disposed in a through hole 821 formed in the other underbody member 82, and is fixed to the other underbody member 82 by screwing a nut 222 into the screw portion 221.

  In FIG. 4, the suspension member 81 is an arm member, and the suspension member 82 is a knuckle member. In addition, the suspension member 81 can be a knuckle member and the suspension member 82 can be an arm member. The suspension members 81 and 82 are determined by the structure and type of the suspension device, and can be other various members.

As shown in FIG. 3, dust projections (dust strips) 43 are formed on the periphery of the insertion hole 41 of the dust cover 4 in the direction in which the shaft portion 22 of the ball stud 2 is formed. A DLC coating film 7 is formed on the surface of the dust projection 43 similarly to the seal projection 5.
As shown in FIG. 2, the dust projection 43 is crushed by a predetermined crushing amount (tightening margin) X <b> 2 because the dust projection 43 is in contact with the other underbody member 82. This makes it difficult for foreign matters such as muddy water and dust to reach between the ring plate 6 and the seal protrusion 5.

Further, as shown in FIG. 3, the DLC coating film 7 in the seal projection 5 and the dust projection 43 uses a so-called plasma polymerization method to convert carbon contained in a hydrocarbon gas such as methane into the seal projection 5 and dust. It is formed by being fixed to the surface of the protrusion 43.
In addition, the DLC coating film 7 can be formed not only partially on the seal protrusion 5 and the dust protrusion 43 but also on the entire range including both.

  When using the ball joint 1, when the ball stud 2 rotates with respect to the socket 3, the ring plate 6 inserted into the shaft portion 22 of the ball stud 2 and the seal projection 5 of the dust cover 4. And slide. At this time, since the DLC coating film 7 is formed on the seal projection 5, the friction coefficient of the seal projection 5 against the ring plate 6 can be effectively reduced. Thereby, the wear resistance of the seal protrusion 5 can be improved.

  Further, by effectively reducing the friction coefficient of the seal projection 5, the amount X1 of crushing the seal projection 5 with respect to the ring plate 6 can be increased. Thereby, it is possible to more effectively prevent the foreign matter from entering the dust cover 4 from between the ring plate 6 and the seal protrusion 5. Further, even when the seal protrusion 5 is sag by using the ball joint 1 for a long period of time, the entry of the foreign matter can be prevented. Therefore, the sealing performance of the ball joint 1 can be effectively improved.

  Even if the crushing amount X1 of the seal projection 5 is increased, the friction coefficient can be kept small. Therefore, the seal projection 5 can always slide with the ring plate 6, and the dust cover 4 is twisted or torn. Can be prevented. Therefore, the durability of the ball joint 1 can be improved.

  Furthermore, since the DLC coating film 7 is formed on the dust projection 43 of the dust cover 4, the friction coefficient of the dust projection 43 can be effectively reduced. As a result, the crushing amount X2 of the dust projection 43 with respect to the underbody member 82 can be increased, and the foreign matter can enter the dust cover 4 from between the underbody member 82 and the dust projection 43. It can be effectively prevented. Therefore, the sealing performance of the ball joint 1 can be improved more effectively.

  Therefore, according to the ball joint 1 of this example, durability and sealing performance can be effectively improved.

Sectional explanatory drawing which shows the ball joint in an Example. Cross-sectional explanatory drawing which expands and shows the periphery of the seal | sticker protrusion part and dust protrusion part in an Example. Cross-sectional explanatory drawing which expands and shows the seal | sticker protrusion part and dust protrusion part of the state in which the DLC coating film in the Example was formed. Explanatory drawing which shows the ball joint arrange | positioned between a pair of suspension members in an Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Ball joint 2 Ball stud 21 Ball head 22 Shaft part 3 Socket 30 Open gap 4 Dust cover 41 Insertion hole 43 Dust protrusion part 5 Seal protrusion part 6 Ring plate 7 DLC coating film 81, 82 Suspension member

Claims (2)

In a ball joint having a ball stud having a ball head and a shaft, a socket that rotatably holds the ball head, and a dust cover that covers an open gap between the socket and the ball stud.
The dust cover has an insertion hole through which the shaft portion is inserted, and a seal projection portion that slides on a ring plate fitted and disposed in the shaft portion is provided at a peripheral portion of the insertion hole. ,
The ball-joint characterized in that the seal projection is formed by forming a DLC coating film. In claim 1, the ball joint is configured to insert and arrange the shaft portion of the ball stud in a through hole formed in the underbody member,
The dust cover is formed by forming a DLC coating film on a dust projection that comes into contact with the underbody member.

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