DE4008439A1 - DEVICE FOR CONNECTING A VARIETY OF INSULATED LADDERS TO ELECTRICAL CONTACTS - Google Patents

Abstract

A connector for use with close-spaced insulated wires which make an insulation displacement wire connection. The contacts have parallel extending legs defining a wire receiving slot, with each leg having a narrow portion of constant width and a broader portion beginning at the plane of the wires affording constant bending thereon when a wire is inserted in the slot.

Description

The invention relates to a device for connecting a variety of conductors provided with insulation electrical contacts, especially one close to each other ordered flat cable, according to the generic term of claim 1.

With increasing miniaturization in microelectronics u. a. the need to arrange a variety of in very dense reliable connection of adjacent wires or conductors to connect electrical contacts, the wires z. B. as  discrete individual wires or as so-called flat cables lie. The contacts usually have one end a contact pin or socket and are in two or more rows arranged on the support body to the connector pins of an adapted connector. The distances the sockets and plug pins are standardized.

It is known to make electrical contact with a lot to produce a number of wires by making U-shaped Insulation displacement contacts at the same time with the wires in Intervention. To ensure that the IDC contacts in the correct position with the assigned wires ten interact, it is known to use a wire Press body against the insulation displacement contacts in the carrier body to press on. The pressing body has recesses into which engage the free ends of the insulation displacement contacts. It is also known for this purpose grooves or channels in to mold the press body through which the wires over passed the width of the compact and with respect to Contact elements can be defined. To be as large as possible Number of adjacent wires with small Connecting diameter with a contact arrangement was already proposed in DE 39 20 367.0, in relation only a short channel-like guide to the width of the compact Adjacent sections to the respective recesses  leave while the wires are outside the guide sections when pressing the carrier body and the pressing body since can dodge. Outside the area of Füh sections, the wires can be limited laterally move and thus when pressing the carrier body and dodge the compact laterally. This allows two or more rows of insulation displacement contacts with a lot number of closely spaced wires of small diameter knives are brought into contact. This ensures that they are in the area where the insulation displacement contacts cut the insulation of the assigned wire, are exactly aligned to these.

From DE-PS 29 41 029 has become known for Kontaktie tion of each conductor to provide three prongs, whereby a first and a second tine spaced apart opposite and a third prong in the gap between the first and second tine is arranged and with these each because it forms a press-fit slot. The press-in slot associated edges of the tines are broken. With the be Known contacts should be achieved that the connection partly receives smaller dimensions. But builds for that Connector part in the direction of the wires bigger, what is going on all things noticeable when more than one set of Contact elements is required.  

Finally, U-shaped insulation displacement contacts are known been placed side by side in at least two rows are arranged and that with two approximately parallel legs form a receiving slot for a conductor, the Width of the slot is smaller than the diameter of the Ladder and the legs near the free end a schma ler first section of approximately constant width and an adjoining wider second section of also have a constant width. With the help of such Contact elements can also with a very small pitch Head of a flat cable who connects the without the insulation of a contact element be neighboring cables are damaged inadmissibly. Because of the The course of the second section of the legs is that for Available deflection for a given con tact power relatively low, so there is a risk that with a certain yielding of the leader after a the required contact force for longer operating times more is generated. The shape of the second section of the Thighs also cause a relatively high load in the area of the connection with the web and carries the risk that permanent deformation occurs, causing the ge desired contact force is no longer ensured. The selected shape of the legs of the well-known insulation displacement cone clock also requires a relatively large length  the leg so that the contact force does not become too great. However, this means that the load in the connection area to the Bridge particularly large.

The invention has for its object a device for connecting a variety of with insulation provided conductors with electrical contacts, in particular of a conductor arranged closely next to one another Flat cable, to create a connection even with very small wire spacing allowed, a given Kon tact power guaranteed even over a longer period and avoids stress peaks in the insulation displacement contacts.

This object is achieved by the Merk male of the labeling part of claim 1.

In the device according to the invention, the second section of the legs of the U-shaped insulation displacement contacts gradually from the first section such that the bending stress of the second section when receiving of a ladder between the legs along its length is approximately the same.

The outer edges of the second section run after one Embodiment of the invention preferably straight and oblique  outward. The transition area from the first to the second Section of the leg lies after another configuration tion of the invention approximately in the plane in which the axes the leader lie.

According to another embodiment of the invention Division of a series of insulation displacement contacts twice large as the division of the ladder, and the dimensions of the second section of the contact legs are such that the outer edge of the second leg sections to the iso lation of the adjacent conductor or something deformed. With such training can be Contact ribbon cable, the very small pitch of 0.635 mm.

Outside the area of the insulation displacement contacts Head preferably in guides of the support body and the Press body held. The legs of the insulation displacement contacts have according to another embodiment of the invention free end sloping edges to form a entry gradually narrowing towards the receiving slot area for a leader. This ensures that when pressing the carrier body and the pressing body Head in the correct position in the slot between the Legs of the insulation displacement contacts. Similar  Chen purpose serve the external bevels on the Schen the insulation displacement contacts after another Ausge staltung of the invention, which cause neighboring Heads are deflected laterally so that they are in the correct position between the legs of adjacent insulation displacement contacts come to rest.

The force with which ladder between the legs of U- shaped insulation displacement contacts should be clamped, is given. It should also last for a longer period be maintained to prevent after a contact by enlargement during certain operating times the contact resistance is deteriorated. With very ge The division of the ladder is the width of the first Ab cuts of the legs naturally very small, but also the width of the second sections is limited if one relatively small division of a number of contact elements the aim is, for example, a division twice as large like a small division of the ladder. The required con tact power can then, for example, compared to conventional U insulation displacement contacts can be achieved in that the Length of the leg is chosen shorter. Is it at Example with conventional insulation displacement contacts, which at a conductor pitch of 1.27 mm can be used, 2 mm, the leg length in the Vorrich invention  for example shortened to 1.4 mm. The shortening of the Leg is to achieve the required contact force however, through the formation of the legs according to the invention not critical. The formation of the legs according to the invention causes an even distribution of the load and therefore sees an optimal use of the material in the rear look at the spring behavior. Peak loads, wel for example at the connection point between the legs and web can lead to permanent deformation, do not occur.

The formation of the legs according to the invention enables a double deflection with the same spring force in the ver ratio to conventional contact elements. This means, that the legs are deflected by a larger amount can without causing permanent deformation. In addition, the legs can travel a greater distance give way when they dig further into the ladder or the conductor is reduced by further deformation Receives width or something from the slot between the Legs of the contact element migrates out without there is noticeably reduced by the contact force.

In summary, it can therefore be stated that the optimal shape of the contact elements according to the invention  Guaranteed material utilization and thus extensive Miniaturization with a given contact force enables. In addition, the contact force is greater Deflection area of the legs applied, therefore remains sufficiently high even after a long period of operation to maintain a safe contact.

The invention is based on an embodiment example explained in more detail.

The average figure shows part of the Vorrich tion according to the invention.

In the figure, a carrier body 10 is indicated, which can consist of plastic material. He can e.g. B. have a construction as described in connection with DE 39 20 367.0. He can e.g. B. at the ends not shown tongues. The carrier body 10 has, for. B. two rows of spring contacts that can accommodate pins of a connector arrangement, not shown. Each spring contact is a U-shaped insulation displacement contact 12 net assigned. In the drawing, three insulation displacement contacts 12 of a series of clamping contacts can be seen, the carrier body 10 correspondingly receiving two rows of insulation displacement contacts, which were offset relative to one another by the spacing between the contacts.

A pressing body 20 made of plastic material can have a shape similar to that of the carrier body 10 . According to DE 39 20 367.0 already mentioned, it can be provided at the ends with insertion openings for receiving the tongues of the carrier body 10 .

A flat cable 30 consists of a large number of small diameter, closely adjacent cables 32 , which have a conductor 34 and insulation 36 . The Iso lations 36 are connected to each other via webs (not visible in the drawing), as known per se.

The contact surface of the carrier body 10 is indicated by the dash-dotted line 14 . In the area of the row of insulation displacement contacts 12 a continuous slot 16 is formed in the support body 10 from the support surface 14 , which, as indicated by line 18 , widens conically as seen in cross section towards the support surface 14 . At the continuous slot 16 , individual stepped slots 40 for receiving the insulation displacement contacts 12 close. They are shaped so that they speak the contour of the insulation displacement contacts 12 ent in the recorded area. Outside the slot 16 , the support surface 14 guides for the cable 32 of the ribbon cable 30 (known per se).

The pressing body 20 has recesses 22 for receiving the contact elements 12 . The webs between the recesses 22 have at the free end a rounding 24 for guiding the cable 32 of the ribbon cable 30 also in the region of the recesses.

The structure of the insulation displacement contacts 12 is measured by the drawn in the drawing middle Kon clock described. The insulation displacement contacts 12 are made of metallic, electrically conductive flat material, from which they are punched out, for example. The insulation displacement contact 12 has two legs 42 , 44 . The legs 42 , 44 have a first section 46 , 48 and a second section 50 , 52 . Together they form a slot 54 with parallel walls and a rounded bottom. The width of the slot is smaller than the diameter of the conductor 34 . The first sections 46 , 48 have essentially the same width over their length. You are at the free end with an oblique edge 56 see ver to form a gradually narrowing to the receiving slot 54 entry area for a cable 32 or a conductor 34th At the free end, the sections 46 , 48 have a bevel 58 on the outside.

The second section 50 , 52 widens gradually from the first section 46 , 48 such that the bending stress of the second section when receiving a conductor between the legs 42 , 44 is approximately the same over its length. The legs 42 , 44 are connected to a section 60 which has a width in the region 62 of the end of the slot 54 which is somewhat larger than the width of the receiving slot 40 . Below section 62 , section 60 has the width of receiving slot 40 . The width of the section 60 decreases downwards in two stages, the section 64 being connected to the spring contact already described but not shown.

In an actual embodiment, the pitch of the cables 32 is 0.635 mm. The legs 42 , 44 have a length of 1.4 mm and are about 1.0 mm beyond the bearing side 14 of the carrier body 10 .

When connecting the conductor 34 of the flat cable 30 to the contacts 12 , the flat cable 30 is placed between the carrier body 10 and the pressing body 20 . Carrier body 10 and pressing body 20 are then pressed against each other. The cables 32 are guided and held in their position outside the insulation displacement contacts 12 ; the insulation displacement contacts 12 engage the conductors 34 , in which the sections 46 , 48 first penetrate through the insulation 36 and gradually come into contact with the conductors 34 . Here, the sections 46 , 48 are bent apart somewhat with a still relatively small spring force. When the conductor 34 approaches the sections 50 , 52 , the spring force increases, the spring force depending on the contour of the sections 50 , 52 . The spring force naturally also depends on the length of the slot 54 . The longer the sections 50 , 52 , the lower the clamping force that can be achieved. Since the clamping force is predetermined in order to generate a predetermined contact force on the conductor 34 , on the other hand the maximum width of the second sections 50 , 52 is limited by the described division of the ribbon cable 30 , the length of the sections 50 , 52 with a predetermined thickness must be so be chosen that the required contact force is sufficient. However, the shape of the sections 50 , 52 ensures that a peak load does not occur at a particular location, rather the load is approximately the same over its length. In addition, the shape allows a relatively large deflection with the same contact force and thus a reliable contact with tolerances in the diameter of the conductor 34 or with too strong a deformation due to the engagement of the legs 42 , 44th

As can be seen, there is sufficient space between the legs 42 , 44 adjacent insulation displacement contacts 12 to take on the cable 32 , the insulation 36 being deformed only slightly. Such a deformation can be accepted since the electrical properties of the cables 32 are not impaired thereby. The outer chamfers 58 on the legs 42 , 44 ensure that the cable 32 lying between the contact elements 12 occupy the position shown and are not unilaterally loaded from the outside of a leg 42 or 44 in order to avoid a leg an insulation displacement contact 12 penetrates into the insulation 36 and even touches the conductor 34 .

Claims (7)

1. Device for connecting a plurality of insulated conductors with electrical contacts, in particular a closely arranged conductor ( 34 ) having a flat cable ( 30 ) with a carrier body ( 10 ) that holds U-shaped insulation displacement contacts ( 12 ) which are arranged next to one another in at least two rows and which, with two approximately parallel legs ( 42 , 44 ), form a receiving slot ( 54 ) for a conductor ( 34 ), the width of the slot being smaller than the diameter of the conductor ( 34 ) and wherein the legs ( 42 , 44 ) near the free end have a narrower first section ( 46 , 48 ) of approximately constant width and an adjoining wider second section ( 50 , 52 ), and a pressing body ( 20 ) which is on the side of the conductor facing away from the carrier body ( 10 ) and has guides ( 22 , 24 ) in which the conductors are guided when the carrier body ( 10 ) and Press body ( 20 ) are pressed against each other, the mutually facing edges of the legs ( 42 , 44 ) cut through the insulation ( 36 ) and the somewhat bent legs ( 42 , 44 ) come into contact with the conductor ( 34 ), the final spring force for the maintenance of contact is essentially determined by the second leg sections ( 52 , 54 ), characterized in that the second section ( 50 , 52 ) of the legs ( 42 , 44 ) of the insulation displacement contacts ( 12 ) from the first section ( 46 , 48 ) gradually widened such that the bending stress of the second section when receiving a conductor ( 34 ) between the legs ( 42 , 44 ) is approximately the same over its length. 2. Device according to claim 1, characterized in that the outer edges of the second section ( 50 , 52 ) are straight and run obliquely outwards. 3. Apparatus according to claim 1 or 2 for flat cable, characterized in that the transition region from the first ( 46 , 48 ) to the second section ( 50 , 52 ) of the legs ( 42 , 44 ) lies approximately in the plane in which the axes the conductor ( 34 ) lie. 4. Device according to one of claims 1 to 3 for flat cables, characterized in that the pitch of a number of insulation displacement contacts ( 12 ) is twice as large as the pitch of the conductor ( 34 ) and the dimensions of the second section ( 50 , 52 ) the contact legs ( 42 , 44 ) are such that the outer edge of the second Schenkelab cuts ( 50 , 52 ) on the insulation ( 36 ) of the adjacent conductor ( 34 ) or slightly deformed. 5. Device according to one of claims 1 to 4, characterized in that the carrier body ( 10 ) has a support surface ( 14 ) over which the legs ( 42 , 44 ) of the insulation displacement contacts ( 12 ) protrude and the Lei ter ( 34 ) outside the area of the insulation displacement contacts ( 12 ) between the guides of the pressing body ( 22 , 24 ) and the bearing surface ( 14 ) are held in a clamping manner. 6. Device according to one of claims 1 to 5, characterized in that the legs ( 42 , 44 ) of the insulation displacement contacts ( 12 ) at the free end have inclined edges ( 56 ) to form a gradually narrowing entry slot for an entry area for one Ladder. 7. Device according to one of claims 1 to 6, characterized in that the legs ( 42 , 44 ) of the insulation displacement contacts ( 12 ) have a bevel ( 58 ) at the free end outside.