METHOD FOR PRODUCING A CONNECTION ELEMENT, AND CONNECTION ELEMENT

Abstract

A method for producing a connection element (1, 30), in particular for an articulated connection of components arranged in a chassis. The connection element (1, 30) is formed by a profile element (6, 31) which includes a joint portion (2), for accommodating a joint component (5), a central portion (4), and a connection portion (3). The profile element (6, 31) is formed by an arrangement of at least one first profile section (7, 32) and at least one second profile section (8, 33), which are held in position, with interlock, by at least one fixing element (9, 10), a joint component (5) is inserted, into the joint portion (2) so formed, and the profile element (6, 31) and the joint component (5) are partially overmolded with a plastic material.

Claims

1-12. (canceled)

13. A method of producing a connection element (1, 30), the connection element (1, 30) having a profile element (6, 31), which includes a joint portion (2) for accommodating a joint component (5), a central portion (4), and a connection portion (3), the method comprising: forming the profile element (6, 31) by an arrangement of at least one first profile section (7, 32) and at least one second profile section (8, 33), holding the at least one first profile section and the at least one second profile section in position, with interlock, by at least one fixing element (9, 10), inserting the joint component (5) into the joint portion (2) so formed, and partially overmolding the profile element (6, 31) and the joint component (5) with a plastic material.

14. The method according to claim 13, further comprising prior to overmolding in an area of the at least one first and the second profile sections (7, 32; 8, 33), which defines the central portion (4) and the connection portion (3) of the profile element (6, 31), inserting a core (16) between the first profile section (7, 32) and the second profile section (8, 33).

15. The method according to claim 13, further comprising forming the at least one first profile section (7, 32) and the at least one second profile section (8, 33) from either a metal or another plastic material that is different from the plastic material used for the overmolding.

16. The method according to claim 13, further comprising overmolding the profile element (6, 31) with a fiber-reinforced plastic.

17. The method according to claim 13, further comprising producing the at least one first profile section (7, 32) and the at least one second profile section (8, 33) by a cutting manufacturing method.

18. The method according to claim 13, further comprising producing the at least one first profile section (7, 32) and the at least one second profile section (8, 33) by transfer molding.

19. The method according to claim 13, further comprising pressing the at least one fixing element (9, 10) onto the at least one first profile section (7, 32) and the at least one second profile section (8, 33).

20. A connection element (1, 30) for an articulated connection of components arranged in a chassis, the connection element (1, 30) comprising: a profile element (6, 31), which has a joint portion (2) for accommodating a joint component (5), a central portion (4), and a connection portion (3), the profile element (6, 31) being formed by an arrangement of at least one first profile section (7, 32) and at least one second profile section (8, 33), at least one fixing element (9, 10) holding the at least one first profile section (7, 32) and at least one second profile section (8, 33) in position, with interlock, and the joint portion (2) of the profile element (6, 31) accommodating the joint component (5), and the profile element (6, 31) and the joint component (5), accommodated in the joint portion (2), being partially overmolded with a plastic material applied by an injection-molding process.

21. The connection element (1, 30) according to claim 20, wherein the at least one first profile section (7, 32) and the at least one second profile section (8, 33) are of a half-shell shaped design.

22. The connection element (1, 30) according to claim 20, wherein the connection element (1, 30) is designed either as a track-rod outer link or a transverse control arm.

23. The connection element (1, 30) according to claim 20, wherein the joint component (5) is either a ball joint (5) or a ball stud (14).

24. The connection element (1, 30) according to claim 20, wherein the connection element is formed by a method including: forming the profile element (6, 31) by the arrangement of the at least one first profile section (7, 32) and the at least one second profile section (8, 33), holding the at least one first profile section and the at least one second profile section in position with interlock by the at least one fixing element (9, 10); inserting the joint component (5) into the joint portion (2) so formed; and partially overmolding the profile element (6, 31) and the joint component (5) with the plastic material.

25. A method of producing an articulated connecting element which connects components arranged on a chassis of a motor vehicle, the method comprising; arranging at least one first profile section and at least one second profile section to form a profile element having a joint portion, a central portion, and a connection portion; interlocking the at least one first profile section and the at least one second profile section with one another by at least one fixing element; inserting a joint component into the joint portion of the profile element; and partially overmolding the profile element and the joint component with a plastic material to form the connecting element.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] Advantageous embodiments of the invention, which will be explained below, are illustrated in the drawings, which show:

[0024] FIG. 1: A schematic view of a connection element;

[0025] FIG. 2a: A schematic representation of a first profile section, viewed in perspective;

[0026] FIG. 2b: A schematic representation of the first profile section and a second profile section;

[0027] FIG. 2c: A schematic representation of the first profile section and the second profile section with a first fixing element;

[0028] FIG. 2d: A schematic representation of the first profile section and the second profile section With a second fixing element;

[0029] FIG. 2e: A schematic representation of a profile element formed from the first profile section and the second profile section with a joint component;

[0030] FIG. 2f: A schematic representation of the profile element according to FIG. 2e, with plastic overmolding;

[0031] FIG. 3: A schematic view of a connection element according to a second embodiment;

[0032] FIG. 4a: A schematic representation of a semifinished part, viewed in perspective;

[0033] FIG. 4b: A schematic representation of a first profile section and a second profile section:

[0034] FIG. 4c: A schematic representation of the first profile section and the second profile section with a first fixing element;

[0035] FIG. 4d: A schematic representation of the first profile section and the second profile section with a second fixing element;

[0036] FIG. 4e: A schematic representation of a profile element formed from the first profile section and the second profile section with a joint component; and

[0037] FIG. 4f; A schematic representation of the profile element according to FIG. 4e, with plastic overmolding.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0038] FIG. 1 shows a schematic representation of a connection element 1 in the form of an outer track-rod joint. The connection element 1 is divided into a number of portions, namely a joint portion 2, a connection portion 3, and a central portion 4 which connects the joint portion 2 and the connection portion 3 to one another. The joint portion 2 serves to accommodate a joint component 5 whereas the connection portion 3 serves to form an adjustable-length arrangement on a track rod (not shown).

[0039] The connection element is formed of a partially cylindrical profile element 6. The profile element 6 comprises at least one first profile section 7 and at least one second profile section 8. The first profile section 7 and the second profile section 8 are each partially half-shell shaped and are arranged in mirror-image relationship to one another. In the example embodiment illustrated the two profile sections 7 and 8 which form the profile element 6 are made as two separate semifinished parts. A first fixing element 9 is arranged on the central portion 4. The first fixing element 9 is essentially ring-shaped. On the connection portion 3 is arranged a second fixing element 10. The second fixing element 10 is also essentially ring-shaped. The inside contours of the first and second fixing elements 9 and 10 are shaped to fit the outer contour of the profile element 6, so that the first profile section 7 and the second profile section 8 are held in theft position with interlock.

[0040] The joint portion 2 accommodates the joint component 5, which is in the form of a ball joint 11. The ball joint 11 comprises a housing 12, a ball socket 13 arranged therein and a ball stud 14 fitted into the ball socket 13.

[0041] The profile element 6 and the housing 12 of the ball joint 11 are partially overmolded with a plastic covering 15. As can be seen from the illustration, the opening of the housing 12 out of which the ball stud 14 projects is not overmolded. The second fixing element 10 arranged on the connection portion 3 is also only partially overmolded, since the outer coating surface of the second fixing element 10 is designed to be an engagement area for a tool. In the hollow space of the profile element 6 formed by the partially half-shell shaped profile sections 7 and 8, an extractable core 16 is positioned.

[0042] FIGS. 2a to 2f explain in greater detail the sequence of production steps of the connection element 1.

[0043] FIG. 2a shows a schematic perspective view of the first profile section 7 in the form of a semifinished part. The first profile section 7 has a half-shell shaped section 17 which is connected by an offset section 18 to a ring-shaped, flat segment 19. The first profile section 7 is produced by a cutting manufacturing method, for example by stamping or laser-beam cutting. The second profile section 8 is identically designed and is produced in just the same way.

[0044] FIG. 2b shows a schematic representation of the first profile section 7 and the second profile section 8. In a first process step the two profile sections 7 and 8 are arranged mirror-symmetrically relative to one another. The two half-shell shaped sections 17 form the connection portion 3 and the central portion 4, which open into the offset sections 18. The ring-shaped, flat segments 19 of the two profile sections 7 and 8 mutually aligned one above the other form the joint portion 2, which serves for the later accommodation of the joint component 5.

[0045] FIG. 2c shows a schematic representation of the first profile section 7 and the second profile section 8 with a first fixing element 9 arranged on them. The ring-shaped first fixing element 9 is pushed from the connection portion 3 onto the central portion 4 of the profile element 6. The inner contour of the first fixing element 9 is shaped to fit the outer contour of the central portion 4, so that an interlock is formed. In the area of the offset sections 18 of the first profile section 7 and the second profile section 8 opposite one another, the first fixing element 9 is pressed on and thereby locally fixed on the central portion 4.

[0046] FIG. 2d shows a schematic representation of the first profile section 7 and the second profile section 8 with a second fixing element 10. The second fixing element 10 is also ring-shaped and is pressed onto the end of the connection portion 3. At its periphery the second fixing element 10 has at least two tool engagement areas 20.

[0047] FIG. 2e shows a schematic representation of the profile element 6 formed of the first profile section 7 and the second profile section 8, with the joint component 5 arranged in the joint portion 2. After this production step all the individual components of the connection element 1 are connected to one another in such manner that the individual components can be handled as a single unit 22 stable in its own right. Into the hollow space formed between the first profile section 7 and the second profile section 8 is inserted a core 16. In that way some space is kept free, which must be available during the later use of the connection element 1. The unit 22 is placed in an injection-molding die and partially overmolded with a plastic, so that a covering of plastic 15 that surrounds part of the unit 22 is formed, as shown in FIG. 2f. The finished connection element 1 is more inexpensive and has lower weight than a comparable connection element made of metal in one piece. Compared with the method of the prior art known from DE 10 2008 049 946 A1, according to which individual steel inserts are embedded in a body consisting of plastic, each of them having to be placed individually in the injection-molding die, the ability of the unit 22 forming a stable composite to be handled provides a simpler solution. The individual components of the unit have already been positioned relative to one another before insertion into the injection-molding die.

[0048] The representation in FIG. 3 shows a schematic view of a connection element 30 according to a second embodiment. The same indexes are retained for components identical to those in the connection element 1 according to the first embodiment.

[0049] The connection element 30 is formed by a partially cylindrical profile element 31. The profile element 31 comprises a first profile section 32 and a second profile section 33. The first profile section 32 and the second profile section 33 are in each case partially half-shell shaped and are arranged mirror-symmetrically relative to one another. In the forward area of the joint portion 2 the two profile sections 32 and 33 are connected to one another by a web 34. In the example embodiment illustrated, the first profile section 32 and the second profile section 33 which form the profile element 31 are produced as a single semifinished part.

[0050] Alternatively, the web 34 can be made in two parts so that the first profile section 32 and the second profile section 33 each have a web-like interlock element which are designed to correspond to one another in order to form an interlock with one another.

[0051] FIG. 4a shows a schematic representation of a semifinished part 35, viewed in perspective. The semifinished part 35 comprises the first profile section 32 and the second profile section 33 connected thereto by the web 34. In a first step the semifinished part 35 is deformed by bending. In that way the first profile section 32 and the second profile section 33 are arranged mirror-symmetrically relative to one another, as shown in FIG. 4b. After the deformation of the two profile sections 32 and 33, the web 34 extends essentially perpendicularly between them.

[0052] FIG. 4c shows a schematic representation of the first profile section 32 and the second profile section 33 with the first fixing element 9 pushed onto the central portion 4 of the profile element 31. As already explained earlier, due to the fit between the shapes of the outer contour of the two profile sections 32 and 33 and the inner contour of the enveloping surface of the first fixing element 9, an interlocking connection is formed. The fixing element 10 is then pressed onto the profile element 31.

[0053] FIG. 4d shows a schematic representation of the first profile section 32 and the second profile section 33 with the second fixing element 10, which is pushed onto the connection portion 3 of the profile element 31. The fixing element 10, provided at its periphery with at least two tool engagement areas, is pressed onto the profile element 31.

[0054] FIG. 4e shows a schematic representation of the profile element 31 formed of the first profile section 32 and the second profile section 33, with a joint component 5 in the form of a ball stud 14. The ball of the ball stud 14 is held by the two ring-shaped, flat segments 19, The core 16 is inserted into the hollow-cylindrical central portion 4. The unit 22, consisting of a stable composite, is placed in the injection-molding the and partially overmolded with plastic to form the plastic covering 15.

[0055] FIG. 4f shows a schematic representation of the profile element 31 as in FIG. 4e, with the plastic covering 15. In the area of the joint portion 2 the plastic covering 15 forms a housing for the ball of the ball stud 14. To overmold the profile element 6 or 31, a plastic or fiber-reinforced plastic is used. Correspondingly, the injection-molding processes for producing the connection elements 1 or 30 may differ from one another.

[0056] A further development provides that the profile element 6 or 31 is also made of a plastic instead of from a metal such as steel or aluminum. In such a case at least the plastic used for the profile element 6 or 31 is different from the plastic used for overmolding the profile element 6 or 31. In particular, a high-strength plastic is used for the profile element 6 or 31.

INDEXES

[0057] 1 Connection element [0058] 2 Joint portion [0059] 3 Connection portion [0060] 4 Central portion [0061] 5 Joint component [0062] 6 Profile element [0063] 7 First profile section [0064] 8 Second profile section [0065] 9 First fixing element [0066] 10 Second fixing element [0067] 11 Ball joint [0068] 12 Housing [0069] 13 Ball socket [0070] 14 Ball stud [0071] 15 Plastic covering [0072] 16 Core [0073] 17 Half-shell shaped section [0074] 18 Offset section [0075] 19 Ring-shaped segment [0076] 20 Tool engagement area [0077] 21 Semifinished part [0078] 22 Unit [0079] 30 Connection element [0080] 31 Profile element [0081] 32 First profile section [0082] 33 Second profile section [0083] 34 Web [0084] 35 Semifinished part