NL8002692A - CONTACT DEVICE FOR A MULTI-WIRE CABLE. - Google Patents

Abstract

A connector comprising a terminal support member (10), supporting a multiplicity of electrical terminals, a cable support member (14) and a terminal cover (15). The cable support member (14) being placed between the terminal support (10) and the terminal cover (15). Insulated wire (16) retained between the cable support (14) and terminal cover (15) is pushed down within a recess (22) in the terminal support (10) to contact an insulation piercing contact (5,6,7) of an electrical terminal.

Description

i N.0. 29,025 -1-. . . _.--- ..

Contact device for a multi-core cable.

The Applicant mentions as inventors: W. Powderer, in Best and P. Voorn, in Waalwijk.

The invention relates to a contact device for a multi-core cable, consisting of a contact carrier and a contact cover of insulating material, wherein the contact carrier has openings in which contact elements are included, which are provided with bifurcated plug-in contacts located on the side of the contact cover. insulated electrical conductors of the multi-core cable are fed through the contact cover to these bifurcated vein receptacles.

Such a contact device is known from Netherlands Patent Application 7603291 laid open to public inspection. In this known device 10, the insulated electrical conductors are fed through separate suitable openings in the contact cover, after which the ends are pressed between the teeth of the bifurcated vein plug-in contacts placed in the contact carrier. In the bottom face of the contact cover there are recesses for receiving the bifurqued vein plug-in contacts, while a deep groove is provided perpendicular to each recess for receiving the bent end of the electrical conductor slipped between the teeth of the plug-in contact. When mounting this contact device, each conductor must first be bent in a rectangular manner at its end to be connected, after which this bent part is pressed between the teeth of a corresponding vein plug-in contact. The free part of the electrical conductor is passed through corresponding openings in the contact cover, which is then pushed over the wire receptacles on the contact holder while the conductors protruding from the cover are tightened.

When using a large number of conductors, the mounting of such a contact device takes a long time. It is also less suitable for automating the assembly process. If any of the lead conductors needs to be repaired or replaced, the contact cover must be removed, then the conductor replaced, and then the contact cover replaced.

It must of course be ensured that the other conductors are not damaged or pulled loose.

The above-mentioned drawbacks are avoided in the contact device according to the invention, characterized in that the insulated electrical conductors in contact with the contact elements are bent U-shaped over a part of their length and are supported here, the base part of the U-shaped curved conductor section is slid into the groove between the teeth of the bifurqued wire insert contact and 800 2 6 92 κ * * f • 2 “'- - -., - *. 3 the electrical contact to the contact element up to establishes.

The use of a supported, U-shaped conductor part offers the possibility of contacting the conductors without separate penetration through a contact cover with the bifurcated coring plug-in contacts.

This can be done simply by pushing the conductors down through an opening or cavity between the teeth of the bifurcated vein receptacles. The U-shape then provides good strain relief, which can be improved with additional pressing means. Repair or replacement of the conductors can easily be done, because a separate lead-through 10 is missing through a contact cover.

In a preferred embodiment of the contact device according to the invention, the cover is provided with recesses for receiving and supporting the U-shaped curved conductor parts, which recesses are arranged such that all U-shaped curved conductor parts lie in mutually parallel planes. , which contact cover is also provided with recesses for the bifurqued coring plug contacts, which open into the recesses for the U-shaped curved conductor parts.

The recesses in the contact cover for the U-shaped curved conductor members preferably extend from the top surface of the contact cover to the bottom surface, while the recesses for the bifurcated vein receptacles consist of slots transverse to the longitudinal direction of said recesses, which recesses are so deep that, when the contact device is mounted, a bifurqued vein plug contact extending into a slot extends into the recess, whereby sufficient length remains in the recess on either side of a bifurcated vein plug contact between the teeth of this bifurcated Push-on-wire contact pushes part of an insulated electrical conductor that is routed longitudinally on the top surface of the contact cover over the recess.

When mounting the contact device according to the invention, the contact cover is first placed on the contact holder with the contact elements arranged therein. The bifurcated vein plug-in contacts slide through the slots in the contact cover into the recesses, which open into the top surface of the cover. Subsequently, the electrical conductors on the top surface of the contact cover are laid longitudinally over the associated recesses. Then the conductors can be pressed one after the other and individually, but also all simultaneously in each corresponding recess between the teeth of a bifurqued vein plug-in contact. This can be done with the aid of a separate tool in the form of a flat strip-shaped anvil - 80 0 2 6 92 -3- - - --- -.-- ¾% * 4, which shows the part of the a conductor can press into the recesses, into the groove between two teeth, cutting the insulation through the sharp edges of the teeth and contacting the vein with these edges. Also, as mentioned, the pressing can be done simultaneously for all conductors using a conductor holder, which consists of a plate with a bottom surface which can rest on the insulated electrical conductors, which rest on the top surface of the contact cover. In this lower surface, parallel, adjacent grooves are provided for at least partially receiving this electrical conductor. In the grooves opposite each recess in the contact cover, conductor pressure members are provided, each of which consists of a strip part facing the cover, the largest width of which extends transversely to the plane of the bifurcated vein plug contact located in the recesses, while the length and the position 15 of each strip portion are selected so that when the container is placed on the lid, it can be fed into the slot between the teeth of the bifurcated vein plug-in contact. When this conductor holder is placed on the contact cover, all conductors are simultaneously pressed between the teeth of the contact elements. Preferably, a clamp is used here to hold the conductor holder in place. This clamp can for instance be built into or be part of a conventional dust cover for the contact device.

The contact device according to the invention is particularly suitable for mounting using an automatically operating connection device.

25 If a conductor needs to be repaired or replaced, it is only necessary to manipulate this conductor. All remaining parts of the contact device, with the exception of the possible conductor holder, can remain in place. Even when the conductor holder is removed, the contact between each vein and the associated bifurcated vein plug-in contact is maintained. Bending each conductor several times to insert it into the recesses of the lid and between the. pressing teeth from the conductor plug-in contact leads to a U-shaped bend in the conductor, which provides strain relief due to its position in the contact cover. This strain relief is further enhanced by the presence of the conductor holder, which is clamped on the insulated electrical conductors, which rest side by side on the top surface of the contact cover. Both the bottom surface of the conductor holder and the top surface of the contact cover can be provided with adjacent grooves for at least partially receiving these electrical conductors.

40 In multi-core cable contact devices, the aim is to increase the density of the terminals, i.e., a greater number of terminal conductors and contact elements per contact device.

With the increasing density, the above mentioned mounting and repair problems naturally increase with the above-mentioned known contact devices.

The usual dimensioning of such contact devices, in which the distance between the center lines of the openings, for example 2.54 mm, and the number of openings situated one behind the other in a row is three, forms a limit to the number of contact elements to be used in a row. contact device, the length of which must also remain within certain dimensions, in particular when all conductors are fed from one side to the contact device, which is customary when a ribbon or ribbon cable is used. In the known device, the conductors are then forced to feed the conductors from above or from different opposite sides to the top surface of the contact holder.

This problem is also solved with the contact device according to the invention, which is characterized in that contact elements are arranged in a row behind each other in a row of contact carrier with different distances between the center line of the middle part and the slot between the teeth of the bifurqued vein plug-in contact, wherein the 20 contact elements of a pair of equal distance have been mutually rotated through 180 °.

A central contact element, the groove of which coincides with the center line of the central part of this contact element, while the outer contact elements are rotated through 180 °, can be used at three openings in a row. In this case, within the above-mentioned dimensioning, three conductors can be fed from a side of the contact device to the top surface of the cover.

The invention will now be further elucidated on the basis of the exemplary embodiments shown in the drawings.

FIG. 1 shows a side view of an example of a contact element according to the present invention; Fig. 2 shows the contact element according to Fig. 1 in side view rotated through 90 ° from the view in Fig. 1; Fig. 3 shows an example of a modified contact element for the contact device according to the present invention, also rotated through 90 ° relative to the side view of Fig. 1; fig. 4 shows a top view of the contact element according to fig. 2; Fig. 5 shows a top view of the contact element according to Fig. 3; 8002692 * * FIG. 6 shows an exemplary embodiment of a disassembled contact device according to the present invention; FIG. 7 is a plan view of the contact cover of the contact device of FIG. 2 with insulated electrical conductors mounted thereon; Figures 8, 9 and 10 show cross-sections of the mounted contact device according to Figure 7 over the respective three contact elements arranged one behind the other; Figures 11, 12 and 13 show contact devices according to the present invention, with a number of possibilities to which the electrical conductors can be mounted; Fig. 14 shows a contact device according to the invention in which a dust cover is used.

In the contact device according to the present invention, 15 contact elements can be used, of which Figs. 1 to 5 show exemplary embodiments.

Each contact element consists of an upper part 1, a middle part 2 and a lower part 3. The contact element can consist of a U-shaped bent electrically conductive plate. The two parallel side surfaces of this bent plate are extended upwards and downwards relative to the central part 2 and are connected to each other by means of the connecting strip 4 in the central part 2. The elongated upper parts form bifurcated vein-up contacts, each consisting of a pair of upright teeth 5 and 6, respectively, which are separated from each other by a slot 7. The edges of the teeth 5 and 6 bounding the slot 7 are sharpened such that when an insulated conductor is pressed from above into the slot 7, the insulating jacket is cut and the sharp edges of the slot 7 are buried to a certain depth in the vein of the electrical conductor. Hereby a very reliable contact is established between the core and the 30 terminal.

Figures 1, 4 and 5 show two parallel bifurcated vein plug-in contacts in the top section. The use of one or more bifurcated vein plug-in contacts per contact terminal is possible, whereby in the device according to the present invention two bi-furred vein plug-in contacts are usually used. FIGS. 6, 12 and 13 show as an example a bifurcated vein plug-in contact per contact terminal. In Fig. 1, two are used per contact terminal.

The connecting strip 4 of the central part 2 is displaced by a certain distance to the right 40 relative to the right edge of the side surfaces, so that a shoulder is obtained at 8. When the contact element in the contact carrier 10 is fitted, the 8002692 ί '- * Ó * - ..... · β ** · ίι - rests on a ridge in the openings 11 of this contact carrier 10. On the opposite side edge of the central part 2, a sharp protruding barb 9 is formed, which, when inserting into the opening 11, burrows into the plastic material 5 of the edge of this opening, so that the contact elements cannot be accidentally pulled out or fall out of the opening.

The lower part 3 of each contact element is formed on two converging contact terminals 12, 13, for connecting a further conductor. This one. contact clamps do not, of course, have to be constructed in the manner shown, and may also form part of the middle part 2.

Between the contact terminals according to Figs. 2 and 4 and 3 and 5, respectively, there is the difference that the bifurcated core plug-in contacts in the contact clamp according to Figs. 2 and 3 are displaced with respect to the center line by the center part 2. The slot 7 in Fig. 2 lies to the left of the center line over a certain distance, which is determined by the diameter of the electrical conductors to be used. When these contact clamps are placed in the contact carrier 10, a pair of each pair is rotated through 180 °, so that the bifurcated vein receptacles 20 are displaced to the left or right relative to the longitudinal direction of each row of openings 11. According to the invention, a larger connection density can be achieved by using a further contact terminal whose bifurqued wire-mounting contact is not offset from the centerline, as shown in Figures 3 and 5.

25 "" The shape of the central part 2 is adapted to the shape of the openings 11, so that the contact fits tightly into these openings.

Fig. 6 shows openings with a rectangular cross-section. In this case, the cross section of the central part 2 is also rectangular.

This is visible in fig. 6.

FIG. 6 shows the disassembled parts of a contact device according to the invention. This consists of the contact carrier 10, the contact cover IA- and the conductor holder 15. The parts 10, 14 and 15 are drawn one above the other, so that they assume the correct mutual position when they are moved downwards. Between the conductor holder 15 and 35 the contact cover 14, an electrically insulated conductor 16 to be connected is shown, with insulating jacket 17 and core core 18.

The contact carrier 10 consists of a plastic block, which in the illustrated case is provided with three rows of equally spaced openings 11 of square or rectangular cross-section.

40 The pitch between the openings, that is to say the distance between the respective axes 80 0 2 6 92 * fr -7- ~ * ·, both of the openings 11 which are situated one behind the other and next to each other, amounts to contact devices generally 2.54 mm, or 0.100 inch. This size is virtually standardized, and except in the U.S.A. also used in Europe. Between the 5 openings 11 there are dams 19, which therefore have the same width, as long as the openings 11 have a square cross-section. The top surfaces of these dams 19 serve as contact surfaces for the contact elements, as can be seen from Fig. 1, where the shoulders 20 rest on the top of the dams 19 between the openings 11.

In the middle row of the openings shown, parallel to the direction of the grooves 21 in the conductor holder 15, contact terminals according to FIGS. 2 and 3 are provided. In the central opening there is a contact clamp according to Fig. 3, while contact clamps according to Fig. 2 rotated by 180 ° relative to each other are arranged thereon. When these contact clamps are slid into the openings 11, the barbs 9 dig into the material of the dams, so that the clamps are fixed sufficiently firmly. The openings in Fig. 6 have a square cross-section, but the invention is of course not limited to such a cross-section. The cross-section can also be circular or elliptical, in which case the central parts 2 of the contact clamps must of course be adapted to this modified cross-section such that the contact clamps cannot rotate along the center line of the openings.

Above the contact carrier 10, the contact cover partially drawn in cross section is shown.

The cover 14 is provided at the top with parallel grooves 21 with a cross section such that the round outer surface of each guide 16 is fully supported over part of its circumference. Within the distance between two openings 11, viewed transversely to the direction of the grooves, three parallel grooves 21 are provided.

A recess 22 opens into each groove 21. In the lower end of the recess 22 a slot 23 again opens, which extends into the lower surface of the contact cover 14. The slot 23 takes the bifurcated vein plug-in contact when the contact cover 14 is placed on the contact carrier 10 in Fig. 6. which forms part of the contact clamp shown on the right in the contact carrier 10. The recess 22 has such a depth that the upper parts of the two fork legs 5 and 6 with the intermediate slot 7 project into the recess 22 over a sufficient height in order to obtain a good contact between the conductor 18 of the conductor 16 when it is pressed down into the recess 22 and between the legs 8002692 -8- ..... ~ 3 5 and 6. In Fig. 6, the recess 22 is angled at the bottom. However, this bottom side can also be semi-circular in shape.

When mounting the contact device according to the invention, the contact clamps are first placed in the openings 11 of the contact carrier 10 in the manner shown. Only three openings are filled in Fig. 6, but it goes without saying that the invention is not limited thereto. Then, the contact cover 14 is placed on the top surface of the contact carrier 10, with all bifurqued vein plug contacts 10 sliding into the associated slots 23.

Subsequently, guides 16 are placed in the grooves 21, which must in any case extend over the recesses 22, leaving sufficient length on either side to completely fill them in with the U-shaped curved part when pressed into the recess 22. these conductor 16. See also fig. 11, 12 and 13. After all the desired conductors have been applied, the conductor holder 15 is pressed onto the top surface of the contact cover 14. This conductor holder 15 is also provided with parallel grooves 24 which, together with the grooves 22 in the contact cover 14, can clamp an electric conductor 16. A strip-shaped anvil 25 is formed in each groove 24 of the conductor holder 15, here consisting of the same material as that of the conductor holder 15. Each anvil 25 slides into the associated recess 22 when the conductor holder 15 is placed on the contact cover 14. of the anvil 25 again forms a rounded hollow abutment surface 26 for the insulating jacket 17 of the conductor 16. A recess 27 is also made in the center, which has such a width that the two remaining legs of the anvil 25 on either side of this recess 27, on either side of the slot 7 of the bifurqued vein plug-in contact. If a conductor 16 extends over the recess 22 on the underlying groove 22 of the contact cover 30, when the conductor holder 15 is placed on the contact cover 14 through the anvil 25, the part of the conductor 16 will rise above the recess 22 are pressed down into this recess and further between the legs 5 and 6 of the bifurqued vein plug-in contact, the vein 18 entering into the slot 17 after the insulation 17 has been cut through the legs 5 and 6. A very good electrical contact is established between the wire 18 and the contact terminal.

From the above it appears that when the conductor holder 15 is placed on the cover 14, all conductors 16 40 present in the grooves 22 are connected almost simultaneously with the associated bifurcated vein plug-in contact 8002692 -9- * - ----- - brought. A special pressing device for the conductor holder 15 is necessary for pressing a large number of conductors. However, the guides can also be pressed separately by a suitable tool, the end of which has the shape of the anvil 25 in each of the associated recesses 22 and between the teeth 5 and 6.

In addition to the U-shaped bent portion, which is located within the recess 22, the conductor holder 15 with the anvil 25, if present, provides an additional strain relief for the conductors 16.

Instead of using the permanently present conductor holder 15 with 10 anvils 25, the different conductors can also be fed into the recesses 22 and into the slot 7 of the bifurcated vein plug contacts by means of a correspondingly shaped special tool. This special tool must then also be provided with anvils 25 corresponding to the number of slots in which a guide must be attached. After application, the special tool can be replaced by the guide holder 15, which can also be designed without anvils 25.

A dust cover can be placed over the whole of contact carrier 10 with contact clamps, contact cover 14 and conductor holder 15 with intermediate conductors 16 placed thereon, which can provide an additional pressing force 20 between the three plastic parts 10, 14 and 15. This dust cover can be provided with a clamp.

Fig. 7 shows a top view of the contact cover 14 after the various conductors 16 have been placed between the teeth of bifurqued vein receptacles. In the illustrated embodiment 25 'according to Fig. 7, in contrast to the embodiment according to Fig.

6 each contact clamp provided with two bifurqued wire insertion contacts.

These are shown in broken lines in the top view according to Fig. 7. It can be seen from Fig. 7 that three conductors 16 can be arranged between the openings 11 within a usual distance of 2.54 mm.

Figures 8, 9 and 10 show cross sections of the contact cover 14 and the contact carrier 10, respectively, with contact clamps placed in the openings 11 of the contact carrier 10 with associated bifurcated plug-in contacts. Fig. 8 is a section along the center row in FIG. 7; FIG. 9 is a section through the top row, and FIG. 10 is a section through the bottom row, viewed in the plane of the drawing of FIG. 7.

It is clear from FIGS. 8, 9 and 10 that the mid-row bifurquous lead-in contacts coincide with the centerline of the contact terminal, while the bifurqued lead-in contacts of the outer rows of FIGS. 9 and 10 are offset from said centerline. From this it appears that the three consecutively arranged bifurqued vein plug-in contacts arranged in a row can be brought into contact with a separate conductor 16, the three conductors being able to come out of the contact device on one side. are being fed. These three conductors thus take up the space of a pitch between two openings 11 in the contact carrier 10.

Figures 8, 9 and 10 also show the manner in which the contact clamps with the shoulders 20 and 8 rest in the openings 11 of the contact carrier 10. The barbs 9 form an additional locking means for the contact. stroke clamps.

Figs. 11, 12 and 13 show modified embodiments for applying the conductors 16. In the embodiment according to Fig. 11, the conductors 16 are first fitted and connected, after which they are all simultaneously attached to an edge of the contact device, at 28 , are cut off.

The wires approach the contact device here in the top surface of the contact cover 14.

As shown in FIG. 11, two bifurcated core plug-in contacts per contact terminal are used here.

In the embodiment of Fig. 12, the guides 16 approach from above. Again, all conductors at 28 are cut simultaneously.

In the embodiment according to Fig. 13, the guides 16 also approach from the top, but are cut in the plane of the grooves 21, where the bent parts of the guides 16 emerge from the recess 22 again.

If a single conductor is to be repaired or replaced separately • only the conductor holder 15 needs to be lifted, after which the respective conductor can be removed by removing it from the recess 22 and the bifurcated vein plug-in contact (s) contained therein. to pull. After this, the new conductor can be fitted and connected, after which the conductor holder 15 is put back in place.

The embodiment according to Figs. 11 and 12 is preferable to that of Fig. 13, because all conductors 16 in the embodiments according to Figs. 11 and 12 can be cut in a cutting operation, the cutting surfaces coming to lie in the side face of the contact-35 device. Also, in this cutting operation, at least in the embodiment according to Fig. 11, all guides 16 are well supported.

In the contact device according to Fig. 14, a two-piece dust cover 29 is used. These halves 29 are pressed together and engage the contact carrier 10, the contact cover 14 and the conductor holder 15 and keep them clamped together. The conductors 28 are led out through 8002692 -11- the same pipe which also consists of two halves 30. Obviously, the number of conductors is not limited to three, as shown.

Which embodiment is chosen in practice depends on the respective circumstances.

The contact device according to the present invention can be used with different cables. If ribbon or ribbon cables are used, the individual conductors must be cut from each other beforehand. The cores 17 can be either solid or of the braided type.

The size and shape of the contact device of the present invention conforms to DIN 41612 for contact systems.

Within the scope of the invention, however, sufficient freedom is still provided to design contact devices with different dimensions and different numbers of contact clamps in one or more rows of openings.

It goes without saying that the invention is not limited to a contact device with only three consecutive openings in a row. The invention applies wherever space problems exist due to a high packing density of the conductors and contact terminals. The problems which arise here are solved in the device according to the present invention by moving the individual conductors downwards from a plane U-shaped, contacting the lower part in the recess in the recess in the lower part in the recess. bifurqued vein plug-in contacts. Between the adjacent bifurcated vein plug-in contacts, sufficient insulation has been created by displacing the bifurcated vein plug-in contacts of the different contact terminals relative to the center line of the respective terminals and rotating them through 180 °. This also makes it easier to repair individual conductors.

It therefore goes without saying that the invention is not limited to the embodiments shown, but that modifications and additions are possible without departing from the scope of the invention.

800 2 6 92

Claims (10)

1. Contact device for a multi-core cable, consisting of a contact carrier and a contact cover of insulating material, wherein the contact carrier has openings in which contact elements are included, which are provided with bifurcated vein plug contacts located on the side of the contact cover, while the insulated electrical conductors of the multi-core cable are fed through the contact cover to these bifurcated plug-in receptacles, characterized in that the insulated electric conductors in contact with the contact elements are bent U-shaped over part of their length and are supported here, wherein the base portion of the U-shaped curved conductor portion is slid into the slot between the teeth of the bifurcated vein plug-in contact and establishes electrical contact with the contact element. Contact device according to claim 1, characterized in that the cover has recesses for receiving and supporting the U-shaped curved conductor parts, which recesses are arranged such that all U-shaped curved conductor parts lie in mutually parallel planes, and recesses for the bifurcated vein plug-in contacts which open into the recesses for the U-shaped curved conductor members. 3. Contact device according to claim 1 and 2, characterized in that the recesses in the contact cover for the U-shaped curved conductor parts extend from the top surface to the bottom surface of the contact cover, while the recesses for the bifurcated vein plug contacts consist of transverse slots located on the longitudinal direction of the recesses, which recesses are so deep that with a mounted contact device a bifurcated vein plug contact extending into a slot extends into the recess, with sufficient length on either side of a bifurcated vein plug contact remaining in the recess pressing a part of an insulated electrical conductor between the teeth of this bifurcated vein plug-in contact which is guided longitudinally over the recess on the top surface of the contact cover. Contact device according to claims 1, 2 and 3, characterized in that contact elements are arranged in a row behind each other in a row of contact carriers, with different distances between the center line of the middle part and the slot between the teeth of the bifurcated vein plug-in contact, wherein the contact elements 4-0 of a pair of equal distance mentioned are mutually rotated by 180 ° 80 0 2 6 92 -13- '- ------ --- a.-' «*. Contact device according to claim 1 or 2, characterized in that the top surface of the contact cover is provided with parallel, adjacent grooves for receiving at least partly insulated electrical conductors, at least one of the said recesses in each groove for receiving the U-shaped bent conductor part opens, the recess of which the longitudinal direction coincides with the longitudinal direction of the groove. 6. Contact device as claimed in any of the foregoing claims, characterized by a conductor holder, consisting of a plate with a bottom surface, which can rest on the insulated electrical conductors, which rest on the top surface of the contact cover, which bottom surface is provided with parallel, adjacent spaced grooves for at least partially receiving these electrical conductors, a clamping device being provided for pressing the conductor holder onto the contact cover. Contact device according to claim 6, characterized in that in the grooves of the conductor holder opposite conductor recesses are provided in the contact cover, each of which consists of a strip part directed towards the contact cover, the largest width of which extends transversely in the plane of the bifurcated vein plug-in contact projecting into the recess, while the length and position of each strip portion are selected such that when the conductor holder is placed on the contact cover, it can be fed into the slot between. . ; 25; the teeth of the bifurcated vein receptacle. 8. Contact device according to claim 7, characterized in that the end surface of the conductor pressing member resting on the insulated electrical conductor is formed in accordance with the outer surface of the insulated electrical conductor and is provided with a recess which, in operative condition Conductor pinch is located at the groove between the teeth of the bifurcated vein receptacle. 9. Contact device as claimed in any of the foregoing claims, wherein each contact element consists of an upper part with at least a bifurqued vein plug-in contact which, after receiving the contact element in the opening in the contact carrier, protrudes from this opening, a middle part which extends into the opening adapted to the shape of this opening to hold the contact element in place and a lower part forming electrical conductor terminals, 4-Onret characterized in that each contact element consists of an 800 2 6 92 -14- .....-- rectangular shaped part of electrically conductive material, with opposite side surfaces and a connecting strip at least in the middle part between these side surfaces, which side surfaces are elongated on both sides with respect to the middle part, on the one hand forming at least a bifurqued vein plug-in contact and on the other hand forming a conductor connecting terminal consisting of two tapering narrow side surfaces, while the connecting strip of the middle part is such with respect to the edges of the adjacent side surfaces, that a shoulder is formed on the side of the terminal, which, when the contact element is placed in an opening of the contact carrier, abuts against a cam in this opening for limiting the insertion depth, while barbs are formed at the opposite edges of the side surfaces for holding in the opening and of the contact element. Conductor pressing member for use in mounting the contact device according to any one of the preceding claims, characterized by an anvil in the form of a strip end, of which a longitudinal screw is arranged in the end face which is adapted to the external shape of the insulated electrical conductor to be closed, while a notch is provided in the center of the strip end, which extends transversely to the end face through the narrow width of the strip end, which notch has a width greater than the thickness of the bifurcated wire plug-in contact. 80 0 2 6 92