EP1972033A2 - Contact cell for accepting a cable end by means of an insulation piercing connection technique, and method for the production thereof - Google Patents

Abstract

The invention relates to a method for producing a plastic contact cell comprising a contact element (2) that is provided with an insulation piercing connecting device and is used for attaching one end of an electric cable in at least one contact chamber within the contact cell (1). According to the invention, the contact cell (1) is produced in a generative process in such a way that the contact cell (1) is constructed layer by layer from an amorphous starting material by irradiating the same with light. Also disclosed is a contact cell which is produced according to said method.

Description

 DESCRIPTION

Contact cell for receiving a cable end by insulation displacement technology and method for their preparation

Technical area

The invention relates to a method for producing a plastic contact cell, which comprises a contact element having a cutting terminal for fixing one end of an electric cable in at least one contact chamber in the contact cell, and a contact cell produced thereafter, according to the preamble of claim 1.

State of the art

The increasing trend towards miniaturization and rationalization in all sectors of industry make it necessary to correspondingly improve and reduce the associated cable connection technology. Cable connections still play a special role in electronics, as they are indispensable for the coupling of different components.

Contacting non-stripped lead wires with insulation displacement terminals is one of the most reliable and efficient solderless electrical connections. It is doing the isolated line (= electrical cable, ie metallic core, surrounded by an insulating) pressed into a defined slot of a terminal, the flanks of the insulation displacement plug and compress the metallic core so that a gas-tight connection is formed. As a rule, the lead wire is fed perpendicularly to the plane spanned by the insulation displacement flanks. Often, as for example in the case of straight connectors, it is necessary, however, to supply the conductor in a space-saving manner in alignment with the slot direction. In this regard, there are already several solutions where the line core is not pressed perpendicularly, but at an acute angle to the flank plane in the slot, so for example in DE 42 03 455 C1, EP 0 886 156 A2, DE 295 12 585 U1, EP 1 158 611 A2 or DE 103 23 615 A1.

These are so-called quick connection techniques that allow the user to produce a very efficient electrical connection between non-stripped electrical lines and corresponding contact elements provided with insulation displacement terminals in a very efficient manner and without the use of auxiliary tools.

A common feature of these solutions is that the conductor wires to be inserted into the respective corresponding insulation displacement terminals are introduced in advance into chambers of a part consisting of electrical insulation material. The wires are hereby positioned or fixed with respect to the insulation displacement clamps so that a Ausbeziehungsweise retraction of the wires is prevented when pressed into the slot. All these parts are so far designed so that they can be produced by injection molding. In this process, molten plastic is injected at high pressure into closed, tempered tools. After solidification of the melt, the tool is opened, and the moldings are ejected.

Although injection molding has a number of advantages, it also has a number of limitations. Injection molding is a pronounced mass production process. An economical production is possible depending on the type of parts only from a correspondingly high production quantities. The permanent dimensional accuracy of the parts depends on various parameters such as the environment, raw material batches, machine settings, mold wear and the like. The supply of the molding compound and its flow behavior within the mold is crucial for the mechanical properties of the parts. As a result of Different orientation of the molecules in or transverse to the direction of flow, the strength of the parts is anisotropic. Concurrent flow fronts, such as behind obstacles or multiple gates, create weld lines that cause significant loss of strength. Especially with multiple gates there is a risk of air bubbles. By cooling the finished parts from the processing to the room temperature, they disappear, ie their mass decreases. If this process runs asymmetrically, additional dimensional distortion of the parts is to be expected in terms of dimensional and dimensional stability. In order to keep such procedural disadvantages as small as possible, injection-molded parts must be designed according to certain principles, which may be contradictory in individual cases with each other and / or in terms of the part function. Therefore, compromise solutions are usually required. The most important design guidelines are: Wall thicknesses of parts should be the same in principle. Unless preventable, differences should be smoothed out as gently as possible. Furthermore, the wall thickness should - be chosen as small as possible - but taking into account the viscosity of the molding material. Mass accumulations are to be avoided if possible, as they can cause voids, sink marks, distortion and the like. All surfaces in the direction of demoulding must - if functionally not absolutely necessary - have draft angles in order to be able to remove the parts from the tool without any problems and without damage. The same is true if necessary also for sideshifter. Undercuts are only possible with complicated and very expensive tools with side pulls or jaws. Form separations along parts surfaces cause burrs and molding offset, which can be a serious quality defect on sealing surfaces, for example. Holes and slots are formed in the removal direction by corresponding cores in the tool. In order to keep the mechanical and thermal loads of these cores within reasonable limits in the manufacturing process, certain guidelines must be taken into consideration: for example, a minimum diameter of approx. 1 mm should not be undercut and a maximum aspect ratio (length / diameter) of approx be crossed, be exceeded, be passed. Because of the danger of breaking out, care must also be taken that the distance from holes to the edge of the molding does not become less than about half of its diameter. Of course, the problem of draft angles and undercuts also applies to Holes, and to an increasing extent, the closer one approaches the mentioned boundary areas.

In view of the design rules to be considered in injection molding, contact cells made by this process can be designed to function properly only in terms of shape. At the same time, such moldings could not be scaled below certain dimensions. For example, miniature cables with diameters below or far below the 1 mm limit can not be produced in this way.

Despite all these requirements described and also the certain disadvantages, the production of such contact cells has prevailed and established by injection molding. In contrast, other methods, if known at all, could not prevail, in particular due to the significantly higher material and / or process costs.

Presentation of the invention

The invention is therefore based on the object of being able to produce contact cells of a connector on the one hand more flexible and in a better quality with respect to the respective line conductors with respect to current solutions. In addition, the potential for a significant miniaturization of this type of contact technology is to be tapped.

The invention thus relates to a manufacturing method for provided with corresponding line chambers contact cells and then manufactured contact cells for contacting line wires by means of insulation displacement terminals, wherein the wire is pressed at an acute angle into the slot of the insulation displacement terminal. In addition, examples of multi-pole strand holders are shown, which are formed by the assembly of such contact cells by means of connecting ribs or other geometries and serve to connect corresponding multi-core cables. The most important functions and advantages resulting from the manufacturing process are:

• Pick up the line core via the opening and guide it along a defined path to its exact position up to an end stop with the least possible frictional resistance and divert it from its longitudinal extent. Openings or interruptions along the line chamber, for example, for the purpose of inserting the cutting clamp are to be kept as small as possible in principle, and at their edges with curves, chamfers and the like to make so that a snagging of the line core is prevented

• Take the insulation displacement terminal over the opposite opening and also guide it so that the edges of the insulation displacement terminal can not be pressed apart transversely to the direction of penetration when entering the core.

• The cable chamber must also be designed such that, when pressed into the insulation displacement clamp, the wire is fixed solely as a result of the resulting reaction forces and can not escape or retreat either in the transverse or in the longitudinal direction.

• Contact pairing Finally, enclose or insulate the cable core and the insulation displacement terminal in such a way that the required minimum mass for clearances and creepage distances is maintained with sufficient certainty.

According to the invention, the generative process is thus mentioned as a production possibility for the contact cells described below. These are original forming processes in which a workpiece is generated in layers on the basis of its 3D data set from an informal starting material (powder, liquids and the like) with the aid of light. In the present case, it is above all those methods which produce very filigree, electrically insulating parts, such as, for example, stereolithography, micro-stereolithography, RMPD methods and the like, which are important. The parts are layered by their CAD data "from This process is induced by irradiation with guided, focused (ultraviolet) UV laser beams or beams based on the two-photon effect (simultaneous absorption of two photons with correspondingly high light intensity) by simultaneous exposure each whole layers, for example, using DLP chips and the like

With regard to the contact cells listed below, the production method according to the invention has extraordinary advantages:

• Functional patterns and serial parts are identical, i. Initial sample tests can be transferred to the series without compromising

• Due to the very short process chain, the dimensional accuracy of the parts is essentially influenced only by the accuracy of the system and the properties of the photopolymer used,

As a result, and since only the 3D data set is required to operate the system, the very time-consuming preparation of drawing documents can in principle be dispensed with during construction. Alternatively, for example, with respect to process monitoring, relatively simple drawings with few proof masses would suffice,

• The time-consuming and expensive release of injection-molded parts, which in practice is usually accompanied by considerable changes in the drawing and the tools, can also be dispensed with,

• The shape and properties of the contact cells can be tailored very flexibly to the respective parameters of the conductor line in a trend-specific or customer-specific manner In principle, a "batch size 1" is not inconceivable,

• In principle, there are no limits in the context of the dissolution of the respective procedure with regard to the structural freedom of design. Especially interesting are the possibilities for the realization of undercuts, thin partitions and high aspect ratios,

• With the PMPD technologies, for example, further significant advantages can be achieved with regard to the material properties, such as: Different material properties (physical, chemical, optical and the like) can be integrated both transversely and longitudinally to the layer structure in one component (,, In this context, combinations of different tribological and / or optical properties are of particular interest with regard to contact cells: Sealing surfaces can be provided on the component without subsequent assembly steps Chemical resistances to certain media can be selectively produced.

In the following, the invention, in particular differently designed and manufactured according to the inventive method contact cells and thus formed contact carrier of connectors, further explained, without the invention being limited thereto.

Short description of the drawing

With respect to the coordinates shown in the following figures, the z axis always indicates the feed direction of the line conductor, while the z 'and optionally z "axis passes through the center of the respective insulation displacement slot Figures described details and properties, depending on the implementation options and as needed, in a meaningful way as well as the remaining examples transferable and / or interchangeable, which of course a further variety of variants of such examples are conceivable.

FIGURE 1, FIGURE 2, FIGURE 3 Ways to carry out the invention

1 shows a contact cell 1, assembled with a mounting group consisting of a contact carrier 3 and a cutting element exhibiting a contact element 2. Details of the contact cell 1 and the contact element 2 are shown in the FIGURES 2 and 3 respectively.

The existing of insulating material contact carrier 3 has regard to the contact element 2 has the function to fix this defined - for example, by overmolding, press-fitting, bonding and the like. An important feature is the contact socket 3.1, which has a Anschlagbeziehungsweise mounting surface 3.1.1 with respect to the contact element 2 and corresponds in shape and dimensions of a corresponding cavity 1.5 to the contact cell 1, that the minimum required for air and creepage distances are met ,

The contact cell 1, which is likewise made of insulating material and shown in FIG. 2, has a funnel-shaped opening 1.1, a line chamber 1.2, an end stop 1.3 and a contact chamber 1.4 and the already mentioned cavity 1.5.

The course of the conduction chamber 1.2 or of the conduction vein with the diameter "D", which is not shown here, is essentially characterized by the shape of the neutral fiber NF In this example, the LF initially runs straight in the z direction up to the Point P and then intersects arcuately the contact chamber 1.4, wherein the xz plane in which the NF is located, preferably also includes the passing through the middle of the terminal slot z 'axis xy projection of the line chamber 1.2 at point P and the With respect to the z'-axis, the xy-projection of the end stop 1.3 is arranged so that the metallic core of the conductor is pressed into the slot of the terminal with sufficient certainty to create a permanent electrical connection Diameter of the metallic core is necessarily smaller than the core diameter "D", it is in principle not mandatory that the contact cell is the same as in the FIGURE 2 is designed. A secure contacting is basically also achievable if both at the point P and at the end stop 1.3, the NF has a distance with respect to the z'-axis or with respect to the center of the terminal slot, which is smaller than "D / 2" For example, such contact cells can be realized with very slim designs, which makes it possible to produce compact structures in particular when assembling a plurality of such cells into multi-pole strand holders.An important role for the properties of the contact cell 1 is played by those inclined at the z'-axis, ie beginning at point P. and surfaces 1.2.1 and 1.2.2 ending at the end stop 1.3 The surfaces 1.2.1 pointing in the z'-direction serve to move a line vein, introduced through the opening 1.1, out of its longitudinal extent into the z-direction For example, it is necessary to redirect along the NF to the end stop 1.3 to direct friction forces to surfaces 1.2.1. To the extent that it is possible to minimize these forces, the radius of curvature of the NF can be reduced and the contact cell can be made correspondingly compact. In this regard, on the one hand the material pairing is relevant. On the other hand, the surface microstructure of the surfaces 1.2.1 with respect to the corrugated sheath should be set to the lowest possible friction coefficient (keyword "lotus effect"). The surfaces 1.2.2 facing the z'-direction have in turn the task of a vein located in the conduction chamber 1.2 Depending on the shape of the surface, it may also be positively fixed in such a way that, when pressed into the terminal slot, it can not move back either in the z'-direction or in the xy-direction With regard to the non-positive fixing, it is in contrast to the surfaces previously 1.2.2 strive to generate the highest possible frictional forces, analogous to the above, this can - again in the context of manufacturing possibilities - via a corresponding surface microstructure, and / or via corresponding, partially limited to the surfaces 1.2.2 material properties (for example, generated with Help the above-mentioned "RMPD multimaf method" erzie In addition, alternatively or additionally, the surfaces 1.2.2 may not be "smooth" but ribbed, so that the reaction forces created when the wire is pressed into the terminal slot presses the wire jacket material into the cavities of that corrugation, again between the wire jacket and the areas 1.2.2 at least one, However, preferably produces a quasi-positive connections in many places. Some basic design possibilities for such corrugations are shown in FIGS. 22 to 27, whereby, of course, variations and / or combinations, as well as other embodiments of these examples, are conceivable. The shape and shape of the corrugation should be chosen essentially depending on the characteristics and dimensions of the respective conductor.

In the general case, the line chamber 1.2 along the NF has a cross-sectional contour (see FIGURE 2, section BB), which is composed of curved and / or polygonal sections, this contour over the NF depending on the application at least partially consistent and / or at least partially can be made variable. With regard to the chamber assembly, the smallest transverse mass over this cross-section must of course always have "air" to the diameter of the largest strand "D max" still to be connected. A possible design of this cross-section is shown in section BB in FIGURE 2 as an example. The contour is rhomboid-like with rounded corners, with the basic masses "a ^{1 *} b1", and is basically suitable for contacting differently thick wires with diameters "D _m j _n <D <D _max ". While "a1" denotes the distance of the vertices of the areas 1.2.1 and 1.2.2 described above, "b1" defines the distance between the generatrices or the jacket areas where these areas are virtually adjacent to each other. The massive design of the contour, which as mentioned above along the NF can be constant and / or variable, is crucial for the properties of the line chamber both in terms of their assembly and in terms of wire contacting. Thus, the wedge-shaped tapers to the ends defined by the dimension "a1" are possible, but not compulsory.These tapers over the surfaces 1.2.1 and 1.2.2 cause on the one hand, that a line vein, on the z- or Z ' axis pressure is exerted, is centered towards chamber center, which is advantageous especially for thinner wires. to ensure this effect for all core diameter, however, must be taken to ensure that "2 ^* _r. i <D _min" or "2 ^* n.2 <D _m j _n ". When the amount can More of the friction forces generated in the chamber to be substantially increased over such tapers, in the mass, in which the respective angle" alpha 1.1 "or" alpha 1.2 " sharpener is executed. On the basis of the previous statements on the areas 1.2.1 and 1.2.2, it would therefore be sensible, if necessary, to make "alpha 1.1" relatively small along the areas 1.2.2 and "alpha 1.2" along the areas 1.2.1 relatively large. The dimension "b1" in turn depends on the core diameter "D" in such a way that the wire can avoid as little as possible in the lateral direction when pushing into the insulation displacement, of course, "b ¹ > D _max " must apply.The simplest case, the line chamber 1.2 also consistently have a circular cross-section with a diameter "2 ^* R 1", with respect to core diameter "D _max " only so much "air" that trouble-free placement is possible.

These comments regarding mass and shape of the chamber cross-section are neither complete nor in any way limiting. They are merely intended to show that there are many possibilities for adapting the functional characteristics of the line chamber to the respective core properties. Moreover, it is not mandatory (as shown in FIG. 2) that the individual cross sections along the NF result in a continuous course of the conduction chamber lateral surface (s) or the NF. Depending on the requirements, these lateral surfaces may have over their longitudinal extent at least partially a continuous course and / or at least partially also a more or less pronounced stepped or provided with gap-like recesses course.

Another important part of the contact cell 1 is the contact chamber 1.4. Their function is to receive the insulation displacement edges 2.4 and at least partially guide them so that they can escape undefined as a result of the reaction forces arising when pressing in the line core neither in the x nor y direction. In order to keep the resulting friction between the insulation displacement edges 2.4 and the contact chamber 1.4 as low as possible, here are the same considerations as on the line chamber surfaces 1.2.1. As already mentioned, it should also be noted that the edges on the outbreaks generated by the contact chamber 1.4 on the line chamber 1.2 are designed in such a way that hooking of the line wire, in particular when loading the chamber, is prevented. In addition, in principle it should be striven for that the xy projections of these outbreaks should be kept as low as possible. Furthermore, the extent of the Contact chamber 1.4 over the z'-axis be at least as long as the respective penetration depth of the insulation displacement terminal 2 in the contact cell. 1

The cavity 1.5 at the contact cell 1 serves to receive the contact socket 3.1 and together with this to comply with the required air and creepage distances. It has for this purpose an opening provided with bevels 1.5.2 and serving with respect to the contact carrier 3 stop surface 1.5.1. To insert the insulation displacement edges 2.4, it also has in the direction of the contact chamber 1.4 another, also provided with insertion bevels opening 1.5.3.

In FIGURE 3, a contact element 2 is shown, which is designed as a flat contact pin 2.1 at the opposite end of the wire connection, but depending on the application as round contact pin, contact socket, hybrid contact, PCB contact, soldering contact and the like can be designed. For attachment in an insulating support, the contact element 2 is provided with characteristics 2.2. As an assembly stop and to catch the resulting forces when pressing the wire into the cutting clamps serve the surfaces 2.3. In the direction of the line conductor, the contact element 2 as a planar cutting terminal with the cross-sectional masses "b1 ^* h1" designed with at least two insulation displacement 2.4 with the intervening insulation displacement slot 2.4.1 with the width "s1" and with the introduction bevels 2.4.2, with respect on the one hand have a centering effect on the line and on the other hand contribute to a reduction in the penetration forces. An additional reduction of these forces is achieved when the insertion bevels 2.4.2 are in turn provided with edge slopes 2.4.2.1, which can be provided on the respective edge both one-sided as shown in FIGURE 3 and on both sides. The insulation displacement slot 2.4.1 between the flanks 2.4 can on the one hand have a constant width "s1" corresponding to the metallic core of the conductor vein, but also embodiments in which the slot 2.4.1 is at least partially equal in width and / or at least partially In this case, the slot 2.4.1 can, for example, have a straight, stepped, corrugated or serpentine course A further interesting design with regard to all these construction variants arises if the slot width "s1" is not constant over the slot length, but instead variable, in particular V-shaped, is designed so that the slot at the bottom of the slot is slightly narrower than at the insertion bevels 2.4.2. This design is particularly important in such contacts where the line core is at an acute angle to the insulation displacement slot, since in this case a correspondingly larger Kontaktierungslänge is formed as in transversely arranged cores. Since there is a fixed relationship with regard to the contact quality between the diameter of the metallic core of the wire and the slot width "s1", such a V-slot would result in thinner metallic conductors in the direction of the slot base, but rather thicker metallic conductors on the tip Moreover, it is conceivable, for example, with punched or lasered insulation displacement terminals, likewise to make the individual edges of the terminal slot 2.4.4 identical or different in order to improve the contact quality and / or extend the application spectrum , wherein these at least partially straight and / or at least partially in the form of very shallow "serpentine", flat merging stages and the like may be performed, and further, the slot width "s1" may be either constant or variable Such measures can be made even more difficult or prevented after retraction of the lead wire in the longitudinal direction after contacting. Furthermore, the orientations of the boundary surfaces of the insulation displacement slot 2.4.1, the insertion bevels 2.4.2 and the edge slopes 2.4.2.1 in the x'-y'-plane over the z'-longitudinal extent of these areas at least partially consistent and / or at least partially be made variable. It is also conceivable that the bevels 2.4.2.1 not only extend at least partially over the region of the insertion bevels 2.4.2, but are at least partially provided along the insulation displacement slot, whereby a further optimization of the Eindringkraftcharakteristik can be achieved. In addition, of course, the edge slopes 2.4.2.1 can be completely dispensed with.

As already indicated, the descriptions in FIGS. 1, 2, 3 apply mutatis mutandis to the following figures, in which further embodiments of such contact cells and associated insulation displacement terminals are shown. It will be focused on the previous differences occurring or newly added details.

FIGURE 4, FIGURE 5, FIGURE 6

FIG. 4 illustrates a contact cell 4 assembled with a mounting group consisting of the contact carrier 6 and the contact element 5. Details of the contact cell 4 and of the contact element 5 are shown in FIGS. 5 and 6, respectively.

The distinction, for example, from FIGS. 1, 2, 3 is the design of the contact cell 4 shown in FIG. 5, specifically in the course of its conduction chamber or its NF. Thus, in this example, the NF initially likewise runs straight in the z direction up to the point P, but subsequently forms an arc directed away from the contact chamber 4.4, at which turn again an arc follows at the point of inflection W, which has a vertex S, and then Comparable to earlier, the contact chamber 4.4 cuts. The xy plane, in which the NF is located, here too preferably also includes the z'-axis passing through the center of the terminal slot. As in the case of secure contacting, it must be ensured that the xy projection of the conduction chamber at the apex S as well as the xy projection of the end stop 4.3 lying opposite to the z'-axis are arranged in such a way that the metallic core of the conduction conductor has sufficient Safety is pushed into the slot of the insulation displacement terminal. Such a running NF causes on the one hand that a correspondingly more frequently deflected from its longitudinal extent vein even before pressing into the insulation displacement slot, generated by their residual elasticity a higher holding or friction force within the contact cell 4 than in a comparable contact cell 1. In addition, arise within the Core in the contact cell 4 when pressed into the terminal slot much higher buckling stresses, which causes additional holding or friction forces on the side walls of the conduit chamber 4.2. For a given holding force, as a result, the transverse extent of a contact cell 4 on the x-axis can be made correspondingly more compact than in the case of a contact cell 1. Furthermore, of course, contact cells with Conduction chambers conceivable, the NF two or any number of inflection points W, and thus have a correspondingly higher number of arcuate portions, as listed in this example. In addition, such conduit chambers can also be designed so that their NF at least partially composed of generally curved and / or at least partially composed of generally polygonal sections, the course of which can be performed in addition both steadily and discontinuously.

FIGURE 7, FIGURE 8, FIGURE 9

As the examples above, FIGURE 7 also shows a contact cell 7, assembled with a mounting group of a contact carrier 9 and a contact element 8. The line chamber 7.2 of the contact cell 7 in Figure 8 has a NF with two turning points W1, W2 and two corresponding vertices S1, S2 on. The peculiarity of this contact cell is that the contact chamber 7.4 along its longitudinal extent over the z'-axis, the course of the line chamber 7.2 or their NF cuts three times, which in cooperation with the insulation displacement of the contact element 8.4 a corresponding triple contacting the metallic core of a within allows the vein located in the chamber. In the sense of a secure contact, care must also be taken here for the correct arrangement of the x-y projections of the end stop 7.3, as well as the line chamber cross sections at the vertices S1, S2, as well as at the point P.

The contact element 8 shown in FIG. 9 has along the insulation displacement edges 8.4 three contact areas or terminal slots 8.4.1.1, 8.4.1.2 and 8.4.1.3, which, as shown in FIG. 7, can be seen in their longitudinal arrangement over the z'-axis correspond, where a contacting of the wire takes place within the line chamber 7.2. The comments made under point 2.2.1 with respect to the contact element 2 with respect to the design of the IDC details apply mutatis mutandis to each of these contact areas 8.4.1.1, 8.4.1.2 and 8.4.1.3 and of course also to the lead-in chamfers 8.4.2 and chamfers 8.4 .2.1. Furthermore, it is of course not mandatory that these contact areas as shown in FIG. 9 are defined separated from each other, because there are also conceivable uniform terminal slots, which may have some or all of the features listed so far.

The interaction of such a contact cell 7 with an associated contact element 8 has over the line core on the one hand the advantage that in the mass, as this is repeatedly contacted, the redundancy and thus the security of the electrical connection is increased accordingly. Furthermore, with respect to the end stop 7.3 nearest contacting (in this example, the terminal slot 8.4.1.1) along the z'-axis each following (n) quasi as a strain relief, which the reliability of such a compound, especially in harsh environment in addition elevated. In addition, such a Mehrfachkontaktierung causes on the same line wire that the respective resulting volume resistance is lowered compared to a simple contact accordingly. If, moreover, the contact element 8 is embodied as shown in FIG. 9 such that the individual contact areas 8.4.1.1, 8.4.1.2 and 8.4.1.3 have the same or different slot widths "3.1", "3.2" or "3.3", where preferably "s 3.1> s 3.2> s 3.3" should be, can be contacted in this way within the same chamber line cores with approximately comparable sheath diameters, but with relatively widely dispersed diameters of the metallic core, which of course further extends the scope of such a configuration.

Based on this example, it is generally noted that the number of locations or areas arranged along the z'-axis, at which a wire located within a line chamber is contacted sequentially by means of a cutting clamp, must be at least one, but also as required can be any amount.

FIG. 10, FIG. 11, FIG. 12

FIG. 10 shows the contact cell 10 assembled with the assembly consisting of the contact carrier 12 and the contact element 11. The particularity of this example consists primarily in the design of the contact element 11 of FIGURE 12. The contact element 11 is designed as round contact pin 11.1 at the opposite end of the line core connection, but depending on the application as a flat contact pin, contact socket, hybrid contact, PCB contact, soldering and the like. For attachment in an insulating support, the contact element 11 is provided with characteristics 11.2. As an assembly stop and to catch the resulting forces when pressing the wire into the cutting clamps serve the surfaces 11.3. In the direction of the conductor, the contact element 11 is designed as a cutting terminal with at least two cutting edge 11.4 with the intervening insulation displacement slot 11.4.1 with the width "s 4" and with the introduction bevels 11.4.2, on the one hand have a centering effect in relation to the line vein An additional reduction of these forces is achieved if the insertion bevels 11.4.2 are in turn provided with an edge slope 11.4.2.1 With regard to the insulation displacement slot 11.4.1, the insertion bevels 11.4.2 and the edge slopes 11.4. 2.1 continue to apply here with respect to the insulation displacement of the contact element 2 (see FIGURE 3) made comments.

The insulation displacement edges 11.4 shown in FIG. 12 have the shape of ring segments in cross-section, wherein the dimension "u" is equal to or slightly smaller than the diameter of the conductor core "D" to be contacted. In the case where "u <D", the edges defined by the dimension "u" can act as strain relief with respect to the wire contacted at the insulation displacement slot 11.4.1. The orientation of the edges on the dimension "u" does not necessarily have to correspond to the illustration in FIGURE 12, but depending on the application may have any orientation in the x'-y'-plane With regard to the edge cross sections, ring segments are only a special embodiment of the general one If, according to which, these cross-sections at least partially have a regularly curved (for example elliptical, parabolic and the like) and / or an at least partially irregularly curved shape Furthermore, basic shapes are also conceivable which consist of at least partially regular and / or at least partially irregular polygonal sections (For example, an L-shape) or consist of combinations of such curved and polygonal sections.

Cutting clamps with such at least partially closed flanks (see FIG. 12) have the significant advantage over planar clamps (see FIGS. 3, 6, 9) that they have substantially smaller dimensions in y with respect to a given spring stiffness as well as to a current density which is too conductive or y-direction than this. The supposed disadvantage that this type of clamps require correspondingly more installation space over the x 'or x axis is not or is not relevant in the mass, as it is possible to accommodate this space within the x y projection surface, which for the respective conduit chamber 10.2 (see FIGURE 11) is needed anyway. With regard to a compact design is basically to be noted that contact cells for or with insulation displacement terminals with at least partially closed edges (see FIGURES 10, 11, 12) at the same or comparable functional density over its x-y cross-section noticeably less space than contact cells with planar terminals.

Furthermore, it is possible to align the lateral surface (s) of the terminal flanks 11.4 at least partially parallel and / or at least partially inclined or perpendicular to the z'-axis at such snow clamps. As shown by way of example on the contact element 11 in FIG. 12, the inner surface 11.4.3 can be designed, for example, from two cylindrical partial surfaces having the diameters "d 4.2" and "d 4.3" and a conical connecting surface arranged therebetween. In the case of "d 4.2> d 4.3", a better centering of the wire can be achieved before it is pushed into the insulation displacement terminal and, above all, an additional reduction of the penetration forces. depending on how pronounced the inclination of the conical surface to the z 'axis is designed, a more or less effective strain relief with respect to a contacted conductor vein are achieved. Of course, the number, arrangement and order of such sub-areas need not correspond to the representation in FIG. 12, but are defined depending on the application. In a similar way, functional properties can also be achieved via the outer surfaces of the terminal flanks 11.4 are influenced, in interaction with their associated surfaces of the contact chamber 10.4. Thus, it would be conceivable, for example, by correspondingly arranged projections on these Außenf laugh that have a slight excess over the contact chamber 10.4, along the insulation displacement slot 11.4.1 targeted voltage curves with respect to the contacted wire.

The contact cell 10 shown in FIG. 11 is similar to the contact cell 4 shown in FIG. 5, with the difference that the contact chamber 10.4 and the cavity 10.5 are adapted to the contact element 11 described above. To emphasize here are still the contact chamber guide surfaces 10.4.1, which correspond to the defined by the measure "u" at the cutting edges 11.4 edges and prevent them can dodge when pressing the wire into the terminal slot in the x direction.

FIG. 13, FIG. 14, FIG. 15

FIG. 13 shows the contact cell 13, assembled with the assembly consisting of the contact carrier 15 and the contact element 14.

The example shown in these figures is similar to that shown in FIGURES 10, 11, 12. The distinction here again lies in the design of the insulation displacement edges 14.4 of the contact element 14 and, of course, in the embodiment of the corresponding contact chamber 13.4 on the contact cell 13.

The cutting edge edges 14.4 on the contact element 14 are here designed so that the above-described measure "u" on the contact element 11 corresponding, and here with the measure "5.2" defined edges of the terminal flanks are so far approximated that thereby adjacent to the insulation displacement slot 14.4.1 a second terminal slot 14.4.3 is formed. According to these slots 14.4.1 and 14.4.3, the contact element 14 furthermore has two insertion bevels 14.4.2 and 14.4.4, each with two bevel slopes 14.4.2.1 and 14.4.4.1. On the arrangement of the lead-in bevels 14.4.2 and 14.4.4 along the z'- or z "-axis can, with reference to the respective Inclination of the NF of the line chamber 13.2 in the region of the contact chamber 13.4 to be defined, in which order these bevels respectively penetrate into the line core.

Compared with the example of FIGS. 7, 8, 9 shown in point 2.2.3, where a double or multiple contacting of the wire over the z'-axis is achieved, it is possible with such a cutting terminal of a contact element 14, a Contact line vein at least twice along the x or x 'axis. With regard to the slot widths, "s 5.1> s 5.2", "s 5.1 = s 5.2" or, preferably, "s 5.1 <s 5.2" may hold true for such at least two-way contacting along the x or x 'axis. Redundancy, - safety, strain relief, volume resistance and extended range of applications, the same remarks made as in the past.

In the event that the required structural details or properties of the examples in the FIGURES 7, 8, 9 and FIGURES 13, 14, 15 are combined accordingly, of course, embodiments are conceivable where the line wire in both z, z '- or z "-direction, as well as in x- or x'-direction can be contacted simultaneously two or more times.

With regard to the configuration of the cross sections of the insulation displacement edges 14.4 and their inner and outer lateral surfaces (the inner surface is shown in FIG. 15 as an example of two conical surfaces defined by the mass "d 5.2", "d 5.3" and "d 5.4" ) are again the same comments as those that have been made to the contact element 11 of FIG.

FIG. 16, FIG. 17, FIG. 18

FIG. 16 shows the contact cell 16, assembled with the assembly consisting of the contact carrier 18 and the contact element 17. In principle, this is a very similar example, as shown in FIGS. 13, 14, 15, with the peculiarity that the contact element 17 listed here has at least two-fold insulation displacement terminal with flat edge pairs 17.4 and 17.5, with the respective terminal slots 17.4.1 and 17.5 .1, the insertion bevels 17.4.2 and 17.5.2 and the corresponding edge slopes 17.4.2.1 and 17.5.2.1, wherein the individual insulation displacement terminals are joined together via the connection loop 17.6.

The advantage of such a design, preferably produced by punching technology, is that it is very simple with the aid of such connecting loops 17.6 or by its helical repetition to line up at least two or a plurality of such individual cutting clamps along the x'-axis on a contact element 17 , whereby a corresponding number of contacts can be produced on a line wire via this direction.

Corresponding to these individual insulation displacement terminals of the contact element 17, the contact cell 16 of FIG. 17 has individual contact chambers 16.4.1 and 16.4.2 which are separated from one another by intermediate ribs such that within each individual contact chamber when the core is pressed into the insulation displacement slot, the clamping edges are deflected is prevented both over the x'- and the y'-axis. These intermediate ribs must, of course, be designed so that they do not protrude into the course of the line chamber 16.2 with regard to their transversal dimension on the y-axis, and thus impair or prevent their assembly.

It is also possible here, by combining the corresponding construction details or properties of the examples in the FIGURES 7, 8, 9 and FIGURES 16, 17, 18 to design embodiments where the line vein in both z-, z'- or z "Direction as well as in the x or x 'direction can be contacted simultaneously two or more times.

FIGURE 19, FIGURE 20, FIGURE 21 These figures show, by way of example, three different multi-pole strand holders 19, 20, 21, which consist of a plurality of contact cells 19.1, 20.1, 21.1 joined together by intermediate ribs and similar connecting elements and serve for connecting corresponding multi-core cable conductors. With regard to the type and shape of the respective contact cells, as well as with regard to their arrangement with certain plug-in patterns, these strand holders represent only illustrative examples. They are neither complete in this nor restrictive in any way.

The other details given to these strand holders, which are also exemplary and constructive neither completely nor in any way limiting, correspond in principle with counter-elements of adjacent parts, for example with individual parts within a corresponding connector, a sensor, an electronic module and the like. Thus, for example, 19.2, 20.2, 21.2 stop or mounting surfaces, 19.3, 20.3, 21.3 or 19.4, 20.4, 21.4 corresponding codes or anti-rotation and 19.5, 20.5, 21.5 handle or handle-like surfaces.

Claims

PATENT CLAIMS

1. A method for producing a contact cell (1) made of plastic, which comprises a cutting terminal exhibiting a contact element (2) for fixing an end of an electric cable in at least one contact chamber in the contact cell (1), characterized in that the contact cell (1) is produced in a generative process such that the contact cell (1) is built up in layers from a shapeless starting material under irradiation with light.

2. The method according to claim 1, characterized in that the

Starting material is a powder or a liquid.

3. The method according to claim 1 or 2, characterized in that the starting material is a photoreactive polymer.

4. The method according to any one of the preceding claims, characterized in that the irradiation is carried out with a steered and focused light beam, wherein the irradiation takes place in dependence on CAD data, which include the shape of the manufactured contact cell (1).

5. The method according to any one of the preceding claims, characterized in that the irradiation is carried out with ultraviolet light.

6. contact cell (1), produced by the method of at least one of the preceding claims.

7. contact cell (1) according to claim 6, characterized in that the contact cell (1) has a straight course in the axial direction.

8. Contact cell (1) according to claim 6, characterized in that the contact cell (1) has an at least once curved course in the axial direction.

9. contact cell (1) according to one of claims 6 to 8, characterized in that a plurality of contact cells (1) are combined to form a contact carrier (3) and form a structural unit, wherein in each case a contact cell (1) a cutting clamp is introduced and fixed after the contact carrier (3) has been produced.

10. contact cell (1) according to one of claims 6 to 9, characterized in that the contact cell (1) has a shape according to one of the figures 2, 5, 8, 11, 14 or 17.