Cable lug, contact element and method for producing said element

Abstract

The invention relates to a cable lug (10, 10′, 10″, 10′″) having a connection region (9, 9″, 9′″) for connecting the cable lug (10, 10′, 10″, 10′″) to an electrical conductor (4) and having a contact part (11) for establishing contact with a terminal part (40) of an electrical system (42), in particular of an electrical system of a motor vehicle, the contact part (11) comprising a fastening opening (12) for guiding therethrough a fastening element (46) for fastening the cable lug (10, 10′, 10″, 10′″) to a terminal part (4), and wherein the contact part (11) comprises one or more further openings (13). The invention further relates to the use of the cable lug (10, 10′, 10″, 10′″), a contact element (2) with such a cable log (10, 10′, 10″, 10′″) as well as to a method for producing the same.

Claims

1. Contact element for establishing electrical contact of an electrical conductor to a terminal part of an electrical system comprising: a cable lug, which is conductively connected to the electrical conductor, wherein the cable lug has a connection region for connecting the cable lug to the electrical conductor, wherein the cable lug has a contact part for establishing contact with the terminal part; wherein the contact part comprises a fastening opening for guiding therethrough a fastening element for fastening the cable lug to the terminal part, and wherein the contact part comprises one or more further openings; a housing overmoulded by injection moulding onto the cable lug in such manner that a part of the contact part having the fastening opening is exposed, and wherein the housing is injection-moulded at least through one of the one or more further openings of the cable lug; and, an element (30) injection-moulded onto the housing, wherein material of the element (30) injection-moulded onto the housing is injection-moulded through at least one of the one or more further openings of the cable lug.

2. Contact element according to claim 1, wherein the one or more further openings of the cable lug are smaller than the fastening opening at least in one direction.

3. Contact element according to claim 1, wherein the one or more further openings of the cable lug are arranged closer to the edge of the contact part than the fastening opening.

4. Contact element according to claim 1, wherein the one or more further openings of the cable lug comprises a plurality of further openings, which are arranged around the fastening opening.

5. Contact element according to claim 1, wherein the housing comprises a channel which extends from an opening of the housing to the exposed part of the contact part having the fastening opening, and in that the element (30) injection-moulded on is a sealing element for sealing a closure, in particular a cover, usable for closing the opening.

6. Method for producing a contact element comprising: providing a cable lug, wherein the cable lug has a connection region for connecting the cable lug to an electrical conductor, wherein the cable lug has a contact part for establishing contact with a terminal part of an electrical system, wherein the contact part comprises a fastening opening for guiding therethrough a fastening element for fastening the cable lug to a terminal part, and wherein the contact part comprises one or more further openings; injection-moulding through at least one of the one or more further openings of the contact part so as to overmould a housing onto the cable lug, such that a part of the contact part having the fastening opening is exposed; and injection-molding an element (30) on the housing, wherein at least one of the one or more further openings of the cable lug are injected-molded through with the material of the element (30).

7. Method according to claim 6, wherein at least one of the one or more further openings of the cable lug remains free during the production of the housing, and in that the element (30) connected to the housing is produced by injection-moulding onto the housing, the material of the element being injection-moulded through the at least one opening which remained free during the production of the housing.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the drawing,

(2) FIG. 1a-b show an exemplary embodiment of the cable lug and of the contact element,

(3) FIG. 2a-b show the contact element of FIG. 1a-b after producing an electrical contact with a terminal part of an electrical system,

(4) FIG. 3a-b show an exemplary embodiment of the method for producing the contact element of FIG. 1a-b, and

(5) FIG. 4a-d show various exemplary embodiments of the cable lug for various exemplary embodiments of the contact element.

DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS

(6) FIG. 1a-b show an exemplary embodiment of the cable lug 10 and an exemplary embodiment of a contact element 2 comprising the cable lug in isometric view (FIG. 1a and in sectional view (FIG. 1b).

(7) The contact element 2 comprises an electrical conductor 4, which is sheathed with a conductor insulation 6 made of quite soft polyurethane, for example with the Shore-A hardness 80. One end 8 of the conductor 4 is stripped and is conductively connected by means of ultrasound welding to a connection region 9 of a cable lug 10. The cable lug 10 comprises a flat annular contact part 11 having a fastening opening in the form of a central bore 12 and a plurality of smaller further openings 13 arranged around the latter.

(8) The cable lug 10 and a section 14, attached thereto, of the electrical conductor 8, are overmoulded with an electrically insulating housing 16 made of a polyurethane, a part 17 of the contact part 11 having the bore 12 being exposed. The overmoulding is carried out in such manner that the material of the housing 16 is injection-moulded through some of the further openings 13 of the contact part 11, so that the housing extends through these further openings 13. In this way, the contact part 11 and therefore the cable lug 10 are firmly anchored in the housing.

(9) The housing 16 forms a first socket 18 having a first channel 20, which extends from a first opening 22 of the housing to the exposed part 17 of the contact part 11, and a second socket 24 having a second channel 26, which extends from a second opening 28 of the housing 16 to the exposed part 17 of the contact part 11.

(10) In the first and second channels 20, 26, a sealing element 30 having annular sealing lips 32, which consists of a softer plastic than the housing 16, for example of thermoplastic polyethylene, is injection-moulded onto the housing 16. The material of the sealing element 30 is injection-moulded through some further openings of the plurality of openings 13 of the contact part 11. This allows a one-piece sealing element 30 on both sides of the contact part 11, i.e. here in the first and second channels 20, 26.

(11) By means of a filamentary holding element 32, a cover 34 is connected inseparably to the housing 16. The cover 34 consists of a harder material than the housing, for example of polyamide, and is latched by means of a form-fit connection to the end of the filamentary holding element 32.

(12) The shape of the cover 34 is matched to the shape of the first socket 18, so that the cover 34 can be placed onto the first socket 18 in order to close the opening 22.

(13) FIG. 2a-b show the contact element 2 of FIG. 1a after attachment to a terminal part 14 of an electrical system 42 of a motor vehicle, specifically in isometric view (FIG. 2a) and in sectional view (FIG. 2b). The terminal part 40 comprises a slightly conical electrically insulating base 44 having an electrically conductive threaded bolt 46 made of metal. During the attachment, the contact element 2 is fitted with the second channel 26 over the base 44 so that the threaded bolt 46 is guided through the bore 12 of the contact part 11 of the cable lug 10. Through the first channel 20, the threaded bolt may be secured with a nut 48.

(14) By the further openings 13 of the contact part 11, through which the material of the housing 16 is injection-moulded, and their arrangement around the fastening opening 12, strong anchoring of the contact part in the housing 16 is achieved, so that the large forces possibly exerted when tightening the nut 48 cannot detach the contact part 11 from the housing 16.

(15) The sealing element 30 presses in the second channel onto the outer side of the base 44 and thereby seals the contact element 2 from sides of the second hole 28. The sealing from sides of the first hole 22 is carried out by placing the cover 34 on the first socket 18, the sealing element 30 pressing onto the outer side of an inner contour 50 of the cover 34 and thereby achieving a water-tight seal.

(16) For secure fixing of the cover 34 on the housing 16, the cover 34 and the housing 16 comprise complementary fastening means in the form of latching tongues 52 on the first socket 18 and clips 54 on the cover 34, the latching tongues 52 being engageable in the clips 54 by rotating the fitted cover 34. The latching is, for example, possible by fitting and engagement in a transverse movement.

(17) As further complementary fastening means, a locking element 56 may be provided on the cover 34 and a corresponding undercut 58 may be provided on the housing 16, which interlock behind one another when the cover 34 is rotated.

(18) The contact element 2 allows secure and leaktight contact of the electrical conductor 4 with the terminal part 40 of the electrical system 42. In particular, the overmoulded housing made of thermoplastic polyurethane leads to a leaktight connection to the conductor insulation 6. The material of the sealing element 30, which is softer than the housing 16, leads to good sealing of the exposed part 17 of the contact part 11 on both sides, particularly in combination with the material of the cover 34 and of the base 44, which is harder than the housing 16. On the other hand, the material of the housing 16 is hard enough to ensure a geometrically stable housing and in particular, to achieve the form-fit securing of the cover 34 on the housing 16 by the latching tongues 52 and the undercut 56.

(19) FIGS. 3a-b show an exemplary embodiment of the method for producing the contact element 2 of FIG. 1a in a schematic representation.

(20) In a first step of the method, the conductor 4 sheathed with the conductor insulation 6 and connected to the cable lug 10 by ultrasound welding is provided, and as shown in FIG. 3a is arranged in a first injection mould 80. The first injection-moulding step is then carried out in the injection mould 80, during which the cable lug 10 and the section 14, attached thereto, of the electrical conductor 4 are overmoulded with the housing 16 made of thermoplastic polyurethane, specifically in such manner that the part 17 of the contact part 11 having the bore 12 is exposed, the first and second bases 18, 24 with the channels 20, 26 are produced and the material of the housing 16 is injection-moulded through some of the further openings 13, while other openings of the further openings 13 remain free.

(21) The component produced in this way is subsequently arranged as shown in FIG. 3b in a second injection mould 84, in which a second injection-moulding step is then carried out, during which the sealing element 30 is injection-moulded onto the housing 16.

(22) The material injection-moulded in the second injection-moulding step may reach both sides of the contact part 11 through the further openings 13 which previously remained free, without injection-moulding on both sides being necessary. In this way, the production method is simplified.

(23) After the second injection-moulding step, in order to manufacture the contact element represented in FIG. 1a, the separately produced cover 34 is connected to the holding element 32.

(24) FIGS. 4a-d show various exemplary embodiments of the cable lug for various exemplary embodiments of the contact element.

(25) FIG. 4a shows the cable lug 10 of the contact element 2 of FIG. 1a. The cable lug comprises a flat connection region 9, in which the conductor 4 is welded on, and a flat contact part 11 having the central bore 12 for the threaded bolt 46 and the openings 13 arranged around it for injection-moulding the sealing element 30 through. During the production of the contact element 2, the material of the housing 16 may be injection-moulded through some of the openings 13 in the first injection-moulding step, so that they are filled with the material of the housing 16. In this way, better anchoring of the contact part 11 in the housing 16 may be achieved. Furthermore, as described in connection with FIG. 3a-b, some of the openings may remain free during the first injection-moulding step and have the material of the sealing element 30 injection-moulded through them in the second injection-moulding step, so that the production of the contact element 2 is simplified.

(26) FIG. 4b shows an alternative cable lug 10′, which differs from the cable lug 10 only by a different shape of the openings 13′, which in FIG. 4b are configured to be elongate while the openings 13′ are configured to be round.

(27) FIG. 4c shows a further alternative cable lug 10″, which differs from the cable lug 10 only by a contact layer 90 which is applied on the terminal part 9″ and improves the weld connection to the conductor 4. The contact layer 90 may, for example, be applied by friction welding.

(28) FIG. 4d shows a further alternative cable lug 10′″, which differs from the cable lug 10 only in that the connection region 9′″ is configured for a crimp connection 92. To this end, lateral crimping tabs, which are crimped around the strands of the conductor 4, are provided in the connection region 9′″.

(29) The cable lug 10′″ is crimped to the electrical conductor 4 only in the stripped part of the latter. The insulation crimping which is normally conventional for crimp connection is not necessary in the case of a contact element produced with the cable lug 10′″, since sufficient stabilisation of the crimping is achieved by the overmoulded housing.