EP0235338B1 - Multipole electrical connector - Google Patents

Description

The invention relates to a multi-pole connector with a strip of numerous plug or socket parts with different numbers of poles, and with corresponding socket or plug parts for plugging into the strip, the plug parts and the socket parts each having plug receptacles for receiving coding elements.

The coding of plug connectors that has been customary up to now is limited to the creation of receptacles on the one hand on the plug parts and on the other hand on the socket parts and the fitting of these receptacles with coding elements in accordance with the coding, with various known embodiments relating to the position of the receptacles and the type of coding elements ( US-A 4 449 767, US-A 4 376 565, DE-B-28 07 017, DE-A-34 17 855, DE-C-30 14 804). This type of coding can be used to code plug and socket parts with the same number of poles, but this type of coding becomes problematic when there are long strips with a high total number of poles, and coding should also prevent plug parts and socket parts with different numbers of poles from being inserted into one another . The problem becomes particularly great when there are a relatively large number of plug or socket parts with a low number of poles, for example two to three-pole parts, and if there is also the possibility of a large-pole part, for example a six-pole socket part, if necessary Insert the bar into such a plug part with a total of six poles, which, however, is composed of two three-pole plug parts or, for example, three two-pole plug parts, in particular for manufacturing reasons.

This system-inherently only possible number of different coding possibilities is not sufficient in such applications in the coding system which has been customary to date. In such cases, a certain remedy can be achieved by including the poles themselves in the coding, which then naturally results in pole losses.

The present invention has for its object to provide a multi-pin connector of the generic type, which makes it possible, with structurally simple means and without pole loss, to mismatch not only with the same number of poles of the plug and socket parts among one another, but also incorrect plug connections for plug and socket parts to prevent an unequal number of poles, in addition to the possibility of creating a strip section composed of a plurality of plug or socket parts with a low number of poles not only with the associated parts of the same number of poles in the same order, but also, if necessary, with a socket part or plug part of a large, to connect the total number of poles corresponding to the number of poles.

The solution according to the invention essentially consists in the fact that the plug parts and the socket parts have a contour that can be plugged into one another and is formed from projections and recesses and that follows a predetermined grid dimension, the corner edges of the contour differing in the sense of the collision with one of their contours that cooperate during the plugging the rastered contouring are otherwise formed and the plug parts and the socket parts have a further contour, which is formed from projections and recesses and which follows the grid dimension and which can be plugged into one another, on a further contour interacting with the plugging, here on the corner edges forming the part abutting edges containing the projections Contouring is formed without a protrusion, while the contouring having the receptacles is provided here with such receptacles in the parts overlapping both a projection is provided, in the parts overlapping s Both a projection and a blocking element preventing the reception of such a projection can be inserted.

Thanks to the inclusion of the contour of the plug parts and the socket parts in the coding, the rastered contouring with a different design of the corner edges of the contouring can avoid misplacement with regard to plug parts and socket parts with an unequal number of poles, since in such a case there is always at least one corner edge of the part with the a smaller number of poles collides with the rastered contour of the other part of a larger number of poles and therefore it is not possible to join them together. The coding is also done without any loss of poles and it is also extremely simple in terms of its construction and can also be easily produced, for example, by injection molding with a simple tool structure. Thanks to this configuration, it is also possible to connect a bar consisting of numerous, relatively small number of poles, for example a plug connector, to a socket strip, if this is also composed of parts with a correspondingly small number of poles, but in any case constructed in the same order. Even within these rows, it is not possible to insert strip sections that are constructed differently in terms of the number of poles with respect to the individual elements, despite the same total number of poles.

On the other hand, however, thanks to the further contouring and the corresponding corner edge configuration in accordance with the configuration of the abutting edges of the parts in the position area of this contouring, it is in turn possible to have a continuous uniform plug or socket strip section with the same number of poles as the above-mentioned total number of poles in a strip section of a predetermined total pole number composed of several individual parts , to the extent that it spans parts, because insofar as this contouring in the corner edge areas and thus the part abutting edges, pictures of the adjoining parts are formed, which in principle include a corresponding projection, as is naturally the case here in a grid dimension Plugs or sockets are part of a large number of poles, is possible. Should this possibility not used, but on the contrary prevented within the framework of the overall coding, the blocking element is used in this special receptacle in the corner edge and thus part abutting edge area, with which this plugging is then prevented.

It should also be emphasized that this way, the usual coding, which is also available, is kept completely free via the coding elements that can be used in the plug-in receptacles of the plug parts and the socket parts, in order to prevent only undesired plug connections in the case of plug parts and socket parts of the same number of poles.

Preferred configurations are characterized in the subclaims.

• Figur 1 ein Grundschema eines derartigen Steckverbinders mit perspektivischer, teilweise schematisierter Darstellung einer Steckleiste mit mehreren Steckerteilen unterschiedlicher Polzahl sowie mit einem der zugehörigen Buchsenteil,
• Figur 2 einen aus zwei dreipoligen und einem zweipoligen Steckerteil gebildeten Leistenabschnitt mit Illustration der Fehlsteckvermeidung mit einem zweipoligen sowie mit einem dreipoligen Buchsenteil,
• Figur 3 einen aus vier zweipoligen Steckerteilen aufgebauten Leistenabschnitt mit einem eingesteckten einstückigen achtpoligen Buchsenteil,
• Figur 4 einen aus zwei dreipoligen Steckerteilen aufgebauten Leistenabschnitt in gewollter Steckverbindung mit zwei dreipoligen Buchsenteilen unter Einsatz eines Blockierelementes,
• Figur 5 die aus zwei dreipoligen Steckerteilen gebildete Leiste nach Figur 4 mit Illustration der Verhinderung einer Steckverbindung mit einem einstückigen sechspoligen Buchsenteil durch das Blockierelement.

An embodiment of such a multi-pin connector is described below with reference to the drawing. Show it

• 1 shows a basic diagram of such a connector with a perspective, partially schematic representation of a connector strip with a plurality of connector parts with different numbers of poles and with one of the associated socket parts,
• FIG. 2 shows a strip section formed from two three-pole and one two-pole plug part with illustration of the avoidance of misplugging with a two-pole and with a three-pole socket part,
• FIG. 3 shows a strip section constructed from four two-pole plug parts with an inserted, one-piece, eight-pole socket part,
• FIG. 4 shows a strip section constructed from two three-pin plug parts in a desired plug connection with two three-pin socket parts using a blocking element,
• 5 shows the strip formed from two three-pin connector parts according to FIG. 4 with illustration of the prevention of a plug connection with a one-piece six-pin socket part by the blocking element.

In Figure 1, a connector strip with a high total number of poles is illustrated, which includes, for example in one of its sections, a series of three two-pin connector parts 1 a and a three-pin connector part 1. Other connector parts with different numbers of poles can be present in the strip. Such connector strips can be formed, for example, on printed circuit boards, so that after the connector strips have been formed from the individual connector parts, the joints between the individual connector parts 1 a, 1 b, etc. are barely visible and the risk of incorrect insertion of the corresponding socket parts is therefore great.

For reasons of simplicity, only one four-pole socket part 2a 'is shown in FIG. 1 for the associated socket parts. There is a requirement, on the one hand, to be able to connect only male and female parts with the same number of poles to one another, while avoiding incorrect plug connections, while on the other hand there should also be the possibility of a strip section made up of several parts with a small number of poles, for example a strip section consisting of four two-pole strips arranged next to one another Plug parts 1 a is formed (Figure 3) in a plug connection with an overall uniform eight-pin socket part 2a '(Figure 3), but also the possibility to block such a connection if necessary as undesirable. The basic requirement of coding, even in the case of a plurality of plug parts and socket parts with identical number of poles in one strip, to avoid undesired plug connections with one another by appropriate coding remains.

As can be seen from the figures, in order to avoid incorrect connections and socket parts and connector parts, each with a different number of poles, and also in composite strip sections, the upper-side contour of the connector and socket parts interacting when the affected parts are inserted, each with a contour formed from projections and recesses , which follows a predetermined grid dimension, the end edges of the contouring each being designed differently in the sense of the collision with the grid contouring.

Specifically, in the exemplary embodiment shown, the plug parts 1 a, 1 b and the socket parts 2a ', 2a ", 2b and 2b' have on their interacting top contour, following a predetermined grid dimension x, facing each other after the plugging-in, each opening towards the counterpart and opening 3 for coding element 4 which is indicated by dash-dotted lines in Figure 4. As a contour for avoiding incorrect plug connections with regard to plug parts and socket parts with different numbers of poles, the plug parts 1 a, 1 are in their central regions between the plug receptacles 3 for the coding elements , provided with projecting ribs 5 which follow the same pitch x in the case of connector parts having a larger number of poles, while grooves 6 for receiving the ribs 5 are provided in the socket parts 2a ', 2a ", 2b and 2b'. The corner edge areas and thus the part abutting edges are now designed differently from this rib-like contouring 5, 6 in the sense of the collision with the described contoured contouring 5, 6, for example such that, as shown in the exemplary embodiment, the upper corner edges of the Socket parts 2a ', 2a ", 2b and 2b' are formed in one piece, although there, if one followed the grid dimension x, partial recesses would have to be corresponding to a partial area of the groove 6.

The undersides of the plug parts 1 a, 1 b and the socket parts 2a ', 2a ", 2b and 2b' which cooperate in the plug connection also have a contour provided with projections and recesses, namely a contour which is symmetrically different from the contour on the upper sides The exemplary embodiment shown has for this purpose the socket parts 2a ', 2a ", 2b and 2b' with relatively wide ribs 7, wherein in the connector parts 1a, 1b in their central regions corresponding grooves 8 are precisely matched in cross section are seen. The ribs 7 and the grooves 8 in turn follow the grid dimension x. Here too, a special corner edge configuration is provided on the interacting undersides, that is to say also the configuration of the abutting edges of the parts in their arrangement with one another. While the corner edge areas of the socket parts 2a ', 2a ", 2b and 2b' are left without a corresponding rib 7, or a corresponding part of the rib 7 following the grid dimension, in the corner edge areas of the plug parts 1a, 1 undercut groove sections 8 ', following the slots 8 in accordance with the grid dimension x, which then together form an undercut overall groove 8 'in each case when two parts are lined up together. The dimensions are such that the overall groove 8' still has such a clear width at its narrowest point that, if necessary, a wide rib 7 can enter here, special blocking elements 9 are now also provided in this connector, the cross-section of which is adapted to the overall groove 8 'in such a way that they can be inserted into it, but without the cross-section of the overall groove 8 'with its own cross section, in particular without projecting upwards from the overall groove 8' If such a blocking element 8 'is inserted into the overall groove 8' formed on the abutting edge of two parts, the insertion of a rib 7 into this overall groove 8 ', which is possible per se, can be prevented if necessary.

The various possibilities for preventing incorrect plug-in of the plug parts and socket parts are illustrated in the figures, the collision areas preventing a incorrect plug-in connection in each case highlighting the interacting contours of the plug parts and socket parts as black areas.

Figure 2 illustrates by way of example that it is not possible for a strip section, which is formed from the joining of a two-pole plug part 1 a and two three-pole plug parts 3b, to insert a two-pole socket part 2a and a three-pole socket part 3b from the wrong end, and so on This bottle side also does not include a female header section, formed from the two-pole socket part 2a and the three-pole socket part 2b, because here the corner edge regions of the socket parts 2a which do not match the number of poles always do not match due to the number of poles on the interacting upper sides of the parts formed during the plug connection , 2b would collide with one of the ribs 5 of the plug parts 1 a, 1 b lying in the middle region.

The illustration also shows that a socket strip section could easily be inserted into the illustrated connector strip section, which, starting from the left-hand side of FIG. 2, would be constructed from a two-pole socket part in a row with two three-pole socket parts. The view also shows that individual socket parts with the corresponding number of poles could easily be inserted if one would not prevent such a plugging in the usual way by inserting corresponding coding elements 4 into the corresponding plug receptacles 3 of the plug part and socket part.

It follows from the foregoing that, due to the contouring, plug parts and socket parts of different numbers of poles cannot be joined together, although another sequence of poles in a row of strip sections cannot be plugged together as a result of the collision described.

The deliberate and desired exception of the ability to plug together a part with a large total number of poles with a strip section which is made up of parts with a small total number of poles but, as a result, with the same number of poles is illustrated in FIGS. 3 and 4.

FIG. 3 shows a connector strip section which is constructed from four two-pole connector parts 1a arranged next to one another, a uniform eight-piece socket part 2a, 2a being inserted here without collision. In the same way, the four-pole socket part 2a 'shown in FIG. 1 can easily be inserted into the two two-pole plug parts 1a which are lined up in a row. In the bottom-side abutting edge areas of the plug parts 1 a, the total grooves 8 a ′ form corresponding receptacles for the ribs 7 of the socket part that follow the grid dimension x here. In addition, it should be noted that, in the exemplary embodiment according to FIG. 3, a socket strip section, formed from four adjacent two-pole socket parts, could of course also be inserted into the socket strip section there.

FIG. 4 illustrates the possibility of being able to insert a socket strip section, correspondingly formed from two three-pole socket parts 2b, into a socket strip section made, for example, of two three-pole plug parts 1 lined up, even if here between the two plug parts 1b in their abutting edge region into the overall groove 8 formed In order to avoid the connection explained in more detail in connection with FIG. 5, a blocking element 9 should be used.

The plug connection is thereby made possible even in this case, since the corner edge and thus the edge areas of the two socket parts are left without a corresponding section of a rib 7.

In order to prevent an undesired insertion of two matching strip sections in the case of FIG. 4, the usual coding elements 4 are inserted into the corresponding plug receptacles 3 of a plug part and a socket part, as indicated by dash-dotted lines.

FIG. 5 again shows a strip section which is formed from the series connection of two three-pole plug parts 1b, but now, in contrast to FIG. 4, a uniformly six-pole socket part 2b 'is provided in comparison to FIG. 3, where the implementation of such a part Cross-part insertion is illustrated, is shown in Figure 5, as by inserting a blocking element 9 in the overall groove 8 'on the If necessary, the butt edge of the two plug parts 1b can be prevented from inserting the six-pin socket part 2b here, since when the blocking part 9 is inserted, the rib 7 present in the central region can no longer enter the overall groove 8 'in the underside contouring of the socket part.

In the case of the exemplary embodiments described above, it is assumed that there is a connector strip which is formed from rows of connector parts and into which socket parts or connector strip sections are to be inserted. Conversely, it can also be the case that socket parts with different numbers of poles are combined to form a longer socket strip and are fixed, for example, on a printed circuit board and then plug parts or socket strip sections are provided for insertion into the socket strip.

In addition, different geometrical contours can be provided in the interacting upper and lower sides of the plug parts and socket parts, which, however, can follow all simple geometric shapes to fulfill the purpose intended according to the invention. In reverse of the relationships shown, grooves can in principle also be provided where ribs are now provided, while the ribs are then arranged at the corresponding opposite.

Claims (5)

1. A multipole plug connector with a strip comprising numerous plug or socket portions (1a, 1b; 2a, 2b, 2a', 2b', 2a") with different nubmers of poles, and corresponding socket or plug portions (2a, 2b, 2a', 2b', 2a"; 1a, 1b), for engagement into the strip, wherein the plug portions and the socket portions each have respective plug-in mountings (3) for receiving coding elements (4), characterised in that the plug portions (1a, 1 b) and the socket portions (2a, 2b, 2a', 2b', 2a") have at one of their contours which co-operate in plugging engagement respective contouring which can be brought into plugging interengagement and which is respectively formed from projections (5) and recesses (6) and which follows a predetermined pattern pitch (x), wherein the corner edges of the contouring are formed differently to provide for collision with the patterned contouring and the plug portions (1 a, 1 b) and the socket portions (2a, 2b, 2a', 2b', 2a"), on a further contour co-operating in plugging engagement, have a further contouring which can be brought into plugging engagement and which is respectively formed from projections (7) and recesses (8, 8') and which follows the pattern pitch (x), wherein here the contouring containing the projections (7) is formed in a projections-less manner on the corner edges forming the butting edges of the portion while the contouring having the receiving means (8, 8') is provided here at the pattern pitch with such receiving means (8') into which in overlapping relationship of the portions both a projection (7) and also a blocking element (9) preventing such a projection (7) from being received can be inserted.

2. A multipole plug connector according to claim 1 characterised in that provided on the top-side co-operating contour of the plug portions (1 a, 1b) at the pattern pitch (x) in the middle region thereof are ribs (5) for which receiving grooves (6) are provided in a manner corresponding to the pattern pitch (x) in the socket portions (2a, 2b, 2a', 2b', 2a") in the mi- die region thereof, wherein the end edges of said socket portions, contrary to the pattern pitch, are left solid without grooves, while the edges of the plug portions (1a, 1b), contrary to the pattern pitch, are left without ribs (5).

3. A multipole plug connector according to claim 1 characterised in that provided in the plug portions (1a, 1b) and the socket portions (2a, 2b, 2a', 2b', 2a"), facing towards each other and opening towards each other, in accordance with the pattern pitch (x), between the ribs (5) and the recieving grooves (6) respectively, are the respective mountings (3) for the coding elements (4).

4. A multipole plug connector according to claim 1 characterised in that the butting edge contouring of the contour which contains the recesses (8, 8') is respectively provided with half a receiving groove (8') which is of a dovetail configuration in overall cross-section and the smallest internal width of which is adapted to receive the projection (7), wherein the blocking elements (9) are adapted in respect of their cross-section to said receiving groove (8_') and in their cross-sectional size do not exceed the groove cross-section.

5. A multipole plug connector according to claim 1 or claim 4 characterised in that the co-operating underside contours of the plug portions (1 a, 1 b) and the socket portions (2a, 2b, 2a', 2b_', 2a") are formed in their middle regions from grooves (8) and ribs (7) which differ in their geometrical dimensions from the top-side ribs (5) and grooves (6), but following the same pattern pitch (x).

Images