NO781336L - ELECTRICAL CONTACT. - Google Patents

Description

Electrical contact

The invention relates to electrical connectors of the insulation-opening or insulation-displacing type, and in particular to electrical connectors which have contacts with displaceable or flexible side walls which retain and support the contacts in the cavities in the connectors in which the contacts are mounted.

Electrical connectors with insulation piercing contacts are well known in the art and have experienced considerable commercial success. Typical examples of such previously known connectors are shown in US patents 3,867,005 and 3,926,498. The contacts used in these connectors generally comprise contact or connection elements that cut or cut through the insulation and establish an electrical connection with the conductor without the need for any stripping or soldering operation. The insulation piercing connection elements. typically include opposing cutting edges that cut and pierce the insulation, and in some designs serve as drag or wipe surfaces to make the necessary electrical connection with the conductor. The insulation-piercing contact element therefore serves both to cut the insulation and to establish an electrical connection with the conductor. For a more detailed description of the special construction details of these known coupling pieces, together with their special method of application, reference is hereby made to the above-mentioned US patents.

As mentioned above, the insulation piercing connectors according to the prior art have experienced considerable commercial success. Nevertheless, certain problems arising in the manufacture of the miniaturized electrical components used in these connectors have resulted in designs that make impossible the optimal performance characteristics that could otherwise be achieved. Since, for example, the insulation-piercing contacts can be produced most economically by means of press and rod operations, it is necessary to use sheet metal material which is easily mouldable. Such sheet metal material has a tensile strength which is less than that which is usually considered optimal for withstanding the forces arising in the connection operation. Certain of the construction components in previously known contacts that include insulation piercing

connecting elements, can thus in some cases be deformed or bent during the connection operation to the point where the appropriate electrical connection can be adversely affected.

Moreover, due to tolerance ranges necessary to minimize manufacturing costs and ease of assembly, a small space often exists between the side walls of the connector and the side surfaces of the insertion cavity in which the connector is mounted. The side walls thus have little or no lateral support and are sensitive to outward, lateral deformation during the connection operation, thereby further jeopardizing the quality of the electrical connection achieved.

Another problem associated with previously known insulation piercing connectors is that they are not well-suited for conductors with a stranded core. Individual strands in such conductors are often stuck on or cut off by the opposing cutting edges of the insulation-piercing contact element. After a termination, cold melting of the insulation can also result in movement of the individual wires and changes in the connection area and the connection force between the conductor and the sidewalls of the contact. When using conductors with a multi-wire core, the quality of both the electrical and mechanical connection achieved with connectors according to the known technique can therefore be seriously degraded.;

The present invention therefore relates to an electrical connector with insulation-opening contacts which overcomes the aforementioned problems regarding the deformation of the contact force-carrying components. The contacts used in the connecting pieces according to the invention are also designed to minimize the hanging and cutting problems that are encountered in some cases when connecting insulated conductors with a multi-wire core.

In accordance with the general aspects of the present invention, a coupling piece is provided which has a cavity or recess where the individual contact parts are mounted. The contact parts comprise a connection element with two side walls which is adapted to receive an insulating ion-covered conductor. At least one of the side walls comprises a portion which is displaceable from an initial, pre-mounting position in which the cross-dimensional dimension of the contact is greater than the cross-dimensional dimension of the recess, to a final mounting position in which the side walls are located within and engage with the recess side surfaces. The contact is thus constructed with a connecting element comprising a longitudinal portion in which one or both side walls are designed with an outward arc to form secure engagement with and exert a force on the side surfaces of the recess. The contact further comprises at least one pair of projections which form a conductor receiving notch which is adapted to open or displace the insulation and form an electrical connection with the conductor. The protrusions protrude inwards

from the side walls of the connecting element and is located at the displaceable or curved part of these. Finally, the various construction components in the connector are dimensioned in relation to each other and to the conductor being terminated, in order to minimize the changes in termination resistance that typically occur when conductors with a stranded core are terminated with conventional connectors.

The contact element used in the connector according to the invention overcomes problems associated with the previously known devices, as the side walls of the contact, which must withstand the lateral forces produced by the introduction of the insulated conductor, are designed to form an engagement with and rest against the side surfaces of the contact retaining recess. The strength and stiffness of the relatively thick walls of the connector's contact attachment are utilized in this way to resist the connection forces, and a contact with relatively low tensile strength can be used without adversely affecting the quality or properties of the electrical connection obtained. Sheet metal material with a relatively low tensile strength can therefore be used in the contact elements, thereby greatly facilitating their manufacture.

The contact provided according to the invention is distinguished by the characterizing features stated in the subsequent patent claims.

Further objects and advantages of the invention shall be described in more detail below in connection with a number of exemplary embodiments with reference to the drawings, where fig. 1 is a perspective view illustrating a connection element for a contact part which is constructed in accordance with the invention and is intended for use in an electrical connector, fig. 2 shows an incomplete perspective view of the connection element in fig. 1 and illustrates in more detail one of the protrusions or latches which act to open or displace the insulation and make electrical connection with the conductor, fig. 3 shows a plan view of the connection element in fig. 1, fig. 4 is an incomplete sectional view showing the contact part according to the invention in operating position in a contact-retaining recess in an electrical connector, and further shows an insulated conductor with a multi-wire core which is placed over the contact part immediately before the connection operation, fig. 5 is a similar sectional view as in fig. 4 and shows the insulated multi-wire conductor in its final position in the contact part where the projection of the contact part has opened and displaced the insulation and forms electrical contact with the multi-wire core of the conductor, fig. 6 shows a similar drawing as fig. 1, but shows a preferred embodiment of the invention, fig. 7 shows an incomplete perspective view of the connection element in fig. 6, fig. 8 shows a plan view of those in fig. 6 showed connection elements, and fig. 9 shows an incomplete side view of that in fig. 6 shown connection element.

Referring now to fig. 1 - 3, a connection element 10 in a contact part is shown to comprise a channel with an elongated, U-shaped design. The channel comprises opposite side walls 12 and 14 and a bottom wall 16 which unites at least a part of the side walls 12 and 14 with each other. Each side wall 12 or 14 comprises a displaceable part 18 which carries at least one

indenting projections or a detent 20. The projections

20 on each side wall part 18 are mutually arranged to

forming conductor receiving notches or indentations adapted to penetrate the insulation and establish electrical connection with a conductor. The parts 18 of each side wall are displaceable in the transverse direction in relation to each other. In its initial position, which is best shown in fig. 3, the parts 18 of each side wall are 12 or 14 curved outwards. The displaceable parts 18 are preferably placed between the essentially stationary end parts 22 and 24. The parts 18 are also separated from the bottom wall 16 by openings 26 so that their transverse displacement is thus permitted. The stationary end parts 22 and 24, together with the bottom wall 16, give the connecting element 10 the desired stiffness for successful function in the connecting piece.

The protrusions 20 are formed in one piece in the displaceable parts 18 of the respective side walls and comprise an upper, insulation displacing part 27 with an inclined surface 28 and a lower, conductor wiping part 29 with an essentially flat wiping surface 30. The inclined surfaces 28 of each respective pair of protrusions 20 form an entrance path to the conductor-receiving recess formed by the protrusions.

The sloping surfaces 28 end in an upper cutting edge 32 which is located at a distance from the wiping surface 30 and which initially serves to penetrate the insulation of the conductor when it is introduced into the connection element 10 of the contact part. In an arbitrary given conductor receiving notch, the cutting edges 32 are separated by a distance greater than the diameter of the conductor's core but less than the diameter of the conductor insulation. The protrusions 20 are thus approximately half closed at their conductor receiving upper surface.

It will be appreciated by one skilled in the art that the smooth, inclined surface 28 together with the location of the cutting edge 32 which is separated from or is spaced from the wiping surface 30 and the longitudinal center line of the connecting element, serves to increase the quality of the connection obtained as the attachment or "Hanging" encountered with stranded conductors is essentially eliminated. Since, moreover, the displaceable parts 18 of each side wall are separated from the wall 16 by means of the slots or openings 36, the displaceable parts remain essentially perpendicular to the wall 16 regardless of their relative positions. The wiping surfaces 30 of the projections 20 also remain essentially parallel to each other.

It should also be noted that the inclined surfaces 28 are essentially planar and sufficiently wide to ensure proper removal of the majority of insulation from the metallic core in the conductor when this is pressed into the connection element 10. The surfaces 30 are also essentially planar and sufficiently wide to to remove any residual insulation film from the core and provide a clean surface on the core to establish optimal electrical contact.

An alternative and preferred construction of the protrusions 20 is shown in fig. 6-9. In accordance with this embodiment, the insulation displacing part 27' is extended so that its dimension along the longitudinal axis of the connecting element 10 (the distance a on Fig. 8) is greater than the same dimension (the distance b on Fig. 8) of the conductor wiping part 29' . Consequently, insulation is displaced or removed from a longer section of the conductor than is actually contacted by the conductor wiping surface 30'. It has been found that this arrangement improves the electrical quality of the termination, particularly when conductors with a multi-stranded core are used.

It has also been discovered that the dimensions of the protrusions 20, in relation to the size of the conductor C, play a significant role in optimizing the quality of the termination. To ensure proper insulation removal, the insulation-displacing part 27 of the projections should have a vertical dimension (distance c in Fig. 4) which is at least as large as the radius of the conductor being terminated. In order to properly clean the exposed conductor core, the conductor wiping portion 29 of the projections 20 should furthermore have a vertical dimension (the distance d in Fig. 4) which is at least as large as the diameter of the conductor. Finally, the inclined surface 28 should form an angle with the vertical, longitudinal plane of the connecting element 10 (distance e in Fig. 4) of approx. 35°.

The connection element 10 described above forms part of a contact part which is used in connection with a contact holder or a contact attachment for an electrical connection piece. The special design features of the contact mount and the other coupling piece components, and the assembly of the contact part with. the coupling piece is shown in more detail in the above-mentioned US patent 3,867,005..to which reference is hereby made. In general, the contact part comprises both a connection element and an active contact element which is placed in a contact attachment 34 made of dielectric material. The contact mount comprises an elongated contact mounting recess 36 with a mainly U-shaped configuration with inner and outer ends, the connection element 10 of the contact part being placed at the outer end of the recess.

It will be understood that in order to facilitate the assembly of the connector, it is necessary that the contact mounting cavity and the connection element are dimensioned with tight tolerances. Nevertheless, in previously known connecting pieces, a small space is often present between the side surfaces of the contact mounting cavity and the side walls of the connecting element. This distance is undesirable as it allows the side walls to expand when the insulated conductor is inserted between them. The coupling piece according to the invention overcomes this problem.

In order to ensure that the ferminal or connecting element 10 has sufficient lateral support to withstand the forces encountered when connecting the conductor C, the parts 18 of connecting. The connecting element 10 curves outwards so that they have an initial pre-assembly transverse dimension which is larger than the dimension of the contact mounting recess 36. The connecting element's transverse dimension at the stationary end portions 22 and 24 is of course smaller than the recess 36's transverse dimension. An example of dimensions for the connecting element 10, for use in a recess with a width of 1.35 mm, includes a width at the stationary parts (distance f in Fig. 3) of 1.27 mm and an initial pre-assembly width at the movable part, (distance g in fig. 3) of 1.39 mm. When the contact part is introduced into the contact attachment 34 during assembly of the coupling piece, the parts 18 of the connection element 10 are consequently shifted inwards to a final, mounted position in which the side walls 12 and 14 of the displaceable parts 18 lie directly against the recess. ning's 36 side surfaces 38 and 40.' The connection element 10 is thus placed in the contact mounting recess 36 in a press fit connection without any space between the side surfaces 3 8 and 40 and the side walls 12 and 14. The projections 20 also have! substantial support on each side of these at the points 21 where the projections join their respective side walls.

As clearly shown in fig. 5, when the conductor C is pressed into the connection element 10 by means of a suitable insertion tool 42, the conductor insulation is removed from the conductor's core, and the protrusions 20's wiping surfaces 30 are brought into engagement with the core to provide the desired electrical connection.

The construction of the connecting element 10 in accordance with the present invention prevents the outward displacement of the side walls 12 and 14 as sometimes occurs with previously known connecting pieces. The t<y>err dimension of this conductor receiving notch or groove (represented by the double-headed arrow in Fig. 5) thus remains essentially constant and uniform during the connection operation, so that a proper electrical connection is thus ensured even with conductors with multi-wire core. The cutting edge 32 of each projection 20 is also separated a sufficient distance outwards from the center line of the connecting element 10 to ensure that the stranded core in the conductor does not hang up. The risk of individual threads in the core being cut off by the cutting edge 32 is further greatly reduced.

Since the connector according to the invention relies on the strength of the dielectric contact attachment to support the side walls of the connection element, the contacts can be made of sheet metal material with relatively low tensile strength without this adversely affecting the quality of the electrical connection obtained. Furthermore, since the side walls of the connecting element are displaceable in the transverse direction, the dimensional variations in both the contacts and the contact-retaining recesses become less critical.

It will of course be realized that various changes and modifications to the preferred embodiments described herein will be obvious to those skilled in the art. For example, the displaceable part 18 can be used only in one side wall of the connecting element, and other construction designs than the three-sided channel shown can be used to place and align the opposite side walls 12 and 14. Such changes and modifications can be made without to deviate from the basic idea of the invention

and without reducing the accompanying benefits.

Claims (9)

1. Insulation-piercing contact for electrical connection with an insulation-covered conductor, character: i - s e r t in that it comprises two opposite side walls which are arranged to accommodate the insulated conductor in the longitudinal direction between them, at least one side wall comprising a part which is displaceable in the transverse direction in relation to the rest of the side wall, and at least one pair of projections forming a conductor-receiving notch adapted to penetrate the insulation and form electrical connection with the conductor, one of the projections extending inwardly from the displaceable portion of each side wall. 2. Contact according to claim 1, characterized in that the side walls are united with a bottom wall to thereby form an elongated channel, the displaceable parts of the side the walls are separated from the aforementioned bottom wall. 3. Contact according to claim 2, characterized in that each projection comprises a detent with an inclined surface and a mainly flat wiping surface, the inclined surfaces of a respective pair of projections forming an introduction path to the aforementioned incision. 4. Contact according to claim 3, characterized in that the latches further comprise cutting edges which are arranged on the inclined surfaces and are separated from the wiping floats. 5. Contact according to claim 4, characterized in that the wiper blades of a pair of protrusions are essentially parallel to each other without regard to the position of the displaceable part. 6. Contact according to claim 1, characterized in that each of the protrusions comprises a catch which is formed in one piece in a respective side wall and comprises an insulation displacing part and a conductor wiping part, the insulation displacing part along the longitudinal axis of the channel having a dimension that is greater than the dimension of the leader-wiping party.. 7. Contact according to claim 1, characterized in that each of the protrusions comprises a locking hook which is formed in one piece in a respective side wall and comprises an insulation sliding end part and a conductor wiping part, the insulation displacing part having such a size and design that the insulation is displaced from a significantly larger section of the conductor than that which is contacted by the party removing the leader. 8. Contact according to claim 1, characterized in that each projection comprises a locking hook which is formed in one piece in a respective side wall and comprises an insulating displacement portion with an inclined surface and a conductor wiping portion, the insulation displacement portion having a vertical dimension not less than the radius of the insulation covered conductor, and the conductor wiping portion having a vertical dimension not less than the diameter of the insulation covered conductor, as the sloping surface is arranged at an angle of approx. 35° in relation to the channel's longitudinal vertical plane. 9. Electrical connector for connecting electrical circuits containing insulation-covered conductors, characterized in that it comprises a contact attachment of dielectric material which has at least one elongated contact mounting recess with inner and outer ends, and at least one contact part which is mounted in the recess, each contact part comprising an active contact element and a connection element which is placed at the outer end of the recess, the connection element comprising a U-shaped channel containing opposite side walls with portions which are displaceable in the transverse direction from an initial pre-assembly position in which the transverse dimension of the channel at the displaceable portions is larger than the dimension of the recess, to an end position in which the displaceable portions are located in said recess and abut against the side surfaces of the recess in a press fit connection, and at least one pair of protrusions forming a conductor receiving notch which is adapted to penetrate the insulation and make electrical connection, with the conductor, one of the projections extending inwards from the movable portion of each side wall.