This application is a U.S. National Stage Application under 35 U.S.C § 371 of International Patent Application No. PCT/JP2017/030139 filed 23 Aug. 2017, which claims the benefit of priority to Japanese Patent Application No. 2016-164647 filed 25 Aug. 2016, the disclosures of all of which are hereby incorporated by reference in their entireties.
The present invention relates to a stabilizer link for coupling a suspension device and a stabilizer provided in a vehicle to each other, and to a method for manufacturing the stabilizer link.
A vehicle is provided with a suspension device that absorbs and reduces impact and vibration transmitted from a road surface via wheels to a vehicle body, and a stabilizer for enhancing roll rigidity of the vehicle body. A rod-like member called a stabilizer link is used in the vehicle in order to couple the suspension device and the stabilizer to each other. The stabilizer link is provided with a support bar and ball joints provided at both ends of the support bar, for example, as disclosed in Patent Literature 1.
The stabilizer link disclosed in Patent Literature 1 is composed of ball studs each of which has a ball part, and housings each of which is provided at both ends of the support bar and rotatably houses the ball part of the ball stud. Inside the housing, a ball seat made of resin is provided to be interposed between an inner wall of the housing and the ball part of the ball stud. An outer peripheral surface of the ball part housed in the housing slides on while being in contact with an inner peripheral surface of the ball seat, thereby allowing the ball stud to be supported to freely tilt. Thus, the ball joints provided in the stabilizer link allow the suspension device and the stabilizer to be smoothly coupled to each other.
Patent Literature 1: Japanese Unexamined Patent Application Publication No. 2016-84057
In the stabilizer link disclosed in Patent Literature 1, the support bar is constituted using a hollow pipe made of metal such as steel. At both ends of the hollow pipe constituting the support bar, a sealing part plastically deformed into a plate shape by press working is provided to prevent water or the like from entering the hollow pipe. Both end parts of the support bar are insert-molded in the housing made of resin.
However, in the stabilizer link disclosed in Patent Literature 1, each of the both end parts of the support bar does not extend so as to surround the periphery of the ball part. Accordingly, the support bar cannot reinforce the periphery of the ball part. In short, in the stabilizer link disclosed in Patent Literature 1, the housing made of resin mainly supports tensile breaking strength of the periphery of the ball part. Consequently, the housing becomes greater in its external size for the purpose of enhancement of rigidity in section thereof. As a result, there has been room for improvement left in the stabilizer link disclosed in Patent Literature 1, with respect to a reduction in the size of the stabilizer link.
The present invention has been made in view of the above actual circumstances, and an object thereof is to provide a stabilizer link, and a method for manufacturing the stabilizer link, that are capable of realizing both securing of tensile breaking strength of the periphery of a ball part and a reduction in an external size thereof.
To solve the above problems, a stabilizer link according to a first aspect (1) of the present invention is a stabilizer link provided in a vehicle provided with a suspension device and a stabilizer, and adapted to couple the suspension device and the stabilizer to each other, the stabilizer link including: a support bar made of metal; and ball joints each provided at both ends of the support bar, wherein the ball joints each include: a ball stud one end of which is fastened to a structural member, and which has a ball part at the other end thereof; and a housing made of resin that rotatably supports the ball part of the ball stud, and the support bar includes: a body part extending in a nearly linear shape; and reinforcement parts each having a nearly annular shape and each provided at both ends of the body part, and wherein the reinforcement parts of the support bar are each embedded in the housing so as to surround the ball part.
The stabilizer link according to the first aspect (1) of the present invention allows each reinforcement part having a nearly annular shape and provided at both ends of the support bar to be embedded in the housing made of resin so as to surround the ball part, thus making it possible for the reinforcement part to serve as a core metal of the housing to reinforce the periphery of the ball part.
The stabilizer link according to the first aspect (1) of the present invention makes it possible to obtain a stabilizer link capable of realizing both securing of tensile breaking strength of the periphery of the ball part and a reduction in the external size thereof.
Moreover, a stabilizer link according to a second aspect (2) of the present invention is the stabilizer link according to the first aspect (1), wherein the body part of the support bar has a nearly U-shaped cross section continuously.
The stabilizer link according to the second aspect (2) of the present invention allows the body part of the support bar to have a nearly U-shaped cross section continuously, thus making it possible to secure the strength of the body part in the support bar.
Moreover, a stabilizer link according to a third aspect (3) of the present invention is the stabilizer link according to the second aspect (2), wherein a nearly U-shaped and curved outer wall part in the body part is provided to follow a circular arc of a circumscribed circle of the body part.
The stabilizer link according to the third aspect (3) of the present invention allows the nearly U-shaped and curved outer wall part in the body part to be provided to follow a circular arc of a circumscribed circle of the body part, thus making it possible, even if movement rotating around an axis of the body part is caused in the support bar, to prevent mutual interference between the body part and members existing around the support bar.
Moreover, a stabilizer link according to a fourth aspect (4) of the present invention is the stabilizer link according to the first aspect (1), wherein the reinforcement parts of the support bar each have a nearly L-shaped cross section continuously.
The stabilizer link according to the fourth aspect (4) of the present invention allows each reinforcement part of the support bar to have a nearly L-shaped cross section continuously, thus making it possible to secure the strength of each reinforcement part in the support bar.
Moreover, a method for manufacturing a stabilizer link according to a fifth aspect (5) of the present invention is a method for manufacturing a stabilizer link according to any one of the first to fourth aspects (1) to (4), the method including forming the support bar, the forming the support bar including: a step of carrying out press-forming to a workpiece having a greater size by a folding margin than an external size of the support bar, to form a part that is to form the body part and the reinforcement parts; and after the step, a step of carrying out punching by which holes are punched in parts that are to form the reinforcement parts, the holes each having an inner diameter that allows passage of the ball part of the ball stud.
In the method for manufacturing a stabilizer link according to the fifth aspect (5) of the present invention, the support bar is formed by carrying out press-forming to a workpiece having a greater size by a folding margin than an external size of the support bar, to form a part that is to form the body part and the reinforcement parts, and then carrying out punching by which holes are punched in parts that are to form the reinforcement parts, the holes each having an inner diameter that allows passage of the ball part of the ball stud.
The method for manufacturing a stabilizer link according to the fifth aspect (5) of the present invention allows the support bar to be formed by carrying out the press-forming and the punching, thus making it possible to obtain a stabilizer link capable of realizing both securing of tensile breaking strength of the periphery of the ball part and a reduction in the external size thereof, through a relatively simple process.
The present invention makes it possible to provide a stabilizer link capable of realizing both securing of tensile breaking strength of the periphery of the ball part and a reduction in the external size thereof.
Hereinafter, a stabilizer link according to one or more embodiments of the present invention will be described in detail with reference to the drawings when appropriate.
Configuration of the stabilizer link 11 according to the embodiment of the present invention will be described, by way of example, taking the case in which the stabilizer link 11 is mounted on a vehicle (not shown).
As shown in
As shown in
The shock absorber 15b supporting the wheel W and the stabilizer 17 are coupled to each other through the stabilizer link 11. The manner of connection is the same for the right and left wheels W. As shown in
As shown in
The stabilizer link 11 according to the embodiment of the present invention is manufactured by an insert injection molding process in which the support bar 12 and the ball stud 21 are inserted in given positions inside a metal mold (not shown) having a predetermined shape, and with the state being kept, resin that is to form the housing 23 is injected into the metal mold. Note that the term “insert injection molding process” used in the description below means the process described above.
Of the pair of ball joints 13, the ball joint 13 of one side is fastened and fixed to the tip of the arm part 17b of the stabilizer 17, and the ball joint 13 of the other side is fastened and fixed to a bracket 15c of the shock absorber 15b. Note that the pair of ball joints 13 has the same configuration.
As shown in
The stud part 21a of the ball stud 21 has a great flange part 21a1 and a small flange part 21a2 formed to be mutually separated. Between the great flange part 21a1 and the small flange part 21a2, an encircling recessed part 21a3 is formed. Moreover, a male screw part 21a4 is provided on the tip side from the great flange part 21a1 of the stud part 21a (on the opposite side of the ball part 21b of the ball stud 21).
Between an upper end of the housing 23 and the encircling recessed part 21a3 of the stud part 21a, an encircling dust cover 27 composed of an elastic body such as rubber is fitted so as to cover a gap between them. The dust cover 27 has a function of preventing rainwater, dust or the like from entering into the ball joint 13.
As shown in
As a resin material for the housing 23, considering that it has thermal plasticity (because it is formed by injection molding) and satisfies requirements for a predetermined strength, for example, PA66-GF30 (which mixes PA66 with glass fibers having a weight ratio of 30 to 50% and has a melting point of approximately 270 degrees Celsius) is preferably used. Note that examples of the resin material for appropriate use in the housing 23 include, other than PA66-GF30, engineering plastics and super engineering plastics such as PEEK (polyetheretherketone), PA66 (polyamide 66), PPS (polyphenylenesulfide) and POM (polyoxymethylene), FRP (fiber reinforced plastics), GRP (glass reinforced plastics) and CFRP (carbon fiber reinforced plastics).
As shown in
Note that the equator part 21b1 of the ball part 21b means a part at which an encircling length in the horizontal direction of the ball part 21b around the stud shaft line C (see
Thus, the ball seat 25 having the housing part 25a for the ball part 21b includes the encircling belt-shaped part 25b that covers the equator part 21b1 of the ball part 21b, thus making it possible to allow sliding movement of the ball part 21b to be smoothly performed and to reinforce the periphery of the equator part 21b1 of the ball part 21b.
In the ball joint 13 configured as described above, when the ball stud 21 is moved relatively to the housing 23, a spherical outer peripheral surface of the ball part 21b housed in the semispherical recessed part 23a of the housing 23 slides on while being in contact with an inner peripheral surface of the ball seat 25. Thus, the ball stud 21 is supported to freely swing (see an arrow α1 in
The suspension device 15 and the stabilizer 17 are smoothly coupled to each other through the ball joint 13 provided in the stabilizer link 11. Note that a resin material for the ball seat 25 is appropriately selected according to a resin material for the housing 23 described above.
Next, detailed structure of the support bar 12 will be described with reference to
As shown in
As shown in
Thus, in the reinforcement part 12b provided with the base part 12b2 and the folded part 12b3 in the support bar 12, the folded part 12b3 extends inwardly toward the encircling belt-shaped part 25b and the reinforcement part 12b is embedded in the housing 23 so as to surround the periphery of the encircling belt-shaped part 25b, thus making it possible to allow the sliding movement of the ball part 21b to be smoothly performed and to realize both securing of tensile breaking strength of the periphery of the ball part 21b and a reduction in an external size thereof.
The inner semi-diameter size Dc-in of the reinforcement part 12b is set to be greater by a gap G1 (preferably, G1=>1 mm) than the maximum outer semi-diameter size Db-out (see
Moreover, an outer semi-diameter size Dc-out (see
As shown in
On the other hand, as shown in
Moreover, a height dimension of the body part 12a of the support bar 12 is set to be increased gradually and gently from the axial end part 12a4 toward the axial central part 12a3. This causes, when an external force is applied to the support bar 12, the stress on the body part 12a to act uniformly on the region from the axial central part 12a3 to the axial end part 12a4. Furthermore, the height dimension h1 of the axial end part 12a4 is set to be smaller than the height dimension h2 of the axial central part 12a3, thus contributing to a reduction in weight of the support bar 12.
Note that a height dimension h0 (see
Although an axial dimension of the body part 12a of the support bar 12 is not particularly limited, for example, it is appropriately set to be about 100 to 300 mm.
Next, a manufacturing process of the support bar 12 will be described with reference to
First, as shown in
Next, for example, punch-pressing using a punch (not shown) and dies (not shown) is carried out to the workpiece 31 of the support bar 12, thereby cutting out the first-stage work 12-1 in progress of the support bar 12 as shown in
Next, pressing is carried out to the first-stage work 12-1 in progress of the support bar 12, thereby obtaining the second-stage work 12-2 in progress of the support bar 12 as shown in
Next, punch-pressing (hole punching) is carried out to the second-stage work 12-2 in progress of the support bar 12, thereby obtaining the support bar 12 as an end product as shown in
The operation and effects produced by the stabilizer link 11 according to the embodiment of the present invention will be described below.
The stabilizer link 11 according to a first aspect (1) of the present invention includes the support bar 12 made of metal, and the ball joints 13 each provided at both ends of the support bar 12. Each ball joint 13 includes the ball stud 21 one end of which is fastened to the suspension device 15 or the stabilizer 17 (the structural member), and which has the ball part 21b at the other end thereof, and the housing 23 that rotatably supports the ball part 21b of the ball stud 21. The support bar 12 includes the body part 12a extending in a nearly linear shape, and the reinforcement parts 12b each having a nearly annular shape and each provided at both ends of the body part 12a. The reinforcement parts 12b of the support bar 12 are each embedded in the housing 23 so as to surround the ball part 21b.
The stabilizer link 11 according to the first aspect (1) of the present invention allows each reinforcement part 12b having a nearly annular shape and provided at both ends of the support bar 12 to be embedded in the housing 23 made of resin so as to surround the ball part 21b, thus making it possible for the reinforcement part 12b to serve as a core metal of the housing 23 to reinforce the periphery of the ball part 21b.
The stabilizer link 11 according to the first aspect (1) of the present invention makes it possible to obtain a stabilizer link capable of realizing both securing of tensile breaking strength of the periphery of the ball part 21b and a reduction in the external size thereof.
Moreover, the stabilizer link 11 according to a second aspect (2) of the present invention is the stabilizer link 11 according to the first aspect (1), wherein the body part 12a of the support bar 12 has a nearly U-shaped cross section continuously.
The stabilizer link 11 according to the second aspect (2) of the present invention allows the body part 12a of the support bar 12 to have a nearly U-shaped cross section continuously, thus making it possible to secure the strength of the body part 12a of the support bar 12. Moreover, since the body part 12a of the support bar 12 has a nearly U-shaped cross section (apart of which is open) continuously, the following effects can be expected. That is, when the body part 12a of the support bar 12 is plated where the body part 12a is composed of a hollow pipe, there is a risk that plating liquid or the like enters an internal space of the hollow pipe to allow rust to be generated in the internal space.
In this respect, the stabilizer link 11 according to the second aspect (2) of the present invention allows a nearly U-shaped internal space in the body part 12a of the support bar 12 to be partly open. Therefore, even if any liquid enters the nearly U-shaped internal space, the liquid is discharged through the open part, allowing no rust to be generated in the internal space.
Moreover, the stabilizer link 11 according to a third aspect (3) of the present invention is the stabilizer link 11 according to the second aspect (2), wherein the nearly U-shaped and curved outer wall part 12a2 in the body part 12a of the support bar 12 is provided to follow the circular arc of a circumscribed circle of the body part 12a.
The stabilizer link 11 according to the third aspect (3) of the present invention allows the nearly U-shaped and curved outer wall part 12a2 in the body part 12a of the support bar 12 to be provided to follow the circular arc of the circumscribed circle of the body part 12a, thus making it possible, even if movement rotating around the axis of the body part 12a is caused in the support bar 12, to prevent mutual interference between the body part 12a and the members existing around the support bar 12.
Moreover, the stabilizer link 11 according to a fourth aspect (4) of the present invention is the stabilizer link 11 according to the first aspect (1), wherein the reinforcement parts 12b of the support bar 12 each have a nearly L-shaped cross section continuously.
The stabilizer link 11 according to the fourth aspect (4) of the present invention allows each reinforcement part 12b of the support bar 12 to have a nearly L-shaped cross section continuously, thus making it possible to secure the strength of each reinforcement part 12b in the support bar 12.
Moreover, the method for manufacturing the stabilizer link 11 according to a fifth aspect (5) of the present invention is a method for manufacturing the stabilizer link 11 according to any one of the first to fourth aspects (1) to (4), the method including forming the support bar 12, the forming the support bar 12 including: a step of carrying out press-forming to the workpiece 31 having a greater size by the folding margin BD (see
In the method for manufacturing the stabilizer link 11 according to the fifth aspect (5) of the present invention, the support bar 12 is formed by carrying out press-forming to the workpiece 31 having a greater size by the folding margin BD than the external size of the support bar 12, to form the part that is to form the body part 12a and the reinforcement parts 12b, and then carrying out punching by which the holes 12b1 are punched in the parts that are to form the reinforcement parts 12b, the holes 12b1 each having the inner diameter Dc-in that allows passage of the ball part 21b of the ball stud 21.
The method for manufacturing the stabilizer link 11 according to the fifth aspect (5) of the present invention allows the support bar 12 to be formed by carrying out the press-forming and the hole punching, thus making it possible to obtain the stabilizer link 11 capable of realizing both securing of tensile breaking strength of the periphery of the ball part 21b and a reduction in the external size thereof, through a relatively simple process.
The embodiments described above show examples of materialization of the present invention. Accordingly, the technical scope of the present invention should not be restrictively interpreted by the embodiments. This is because the present invention can be put into effect in various forms without departing from the gist or essential features thereof.
Although the above embodiments of the present invention have been described, by way of example, taking the case in which the ball seat 25 made of resin is provided to be interposed between the ball part 21b of the ball stud 21 and the housing 23 made of resin, the present invention is not limited to this example. The ball seat 25 made of resin may be omitted as long as torque associated with slide of the ball part 21b on the housing 23 can be appropriately managed.
11 Stabilizer link
12 Support bar
12
a Body part
12
b Reinforcement part
13 Ball joint
15 Suspension device (Structural member)
17 Stabilizer (Structural member)
21 Ball stud
21
b Ball part
23 Housing
Number | Date | Country | Kind |
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JP2016-164647 | Aug 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2017/030139 | 8/23/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/038163 | 3/1/2018 | WO | A |
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