EP0580053A1 - A method of producing plugs or sockets for electrical coupling devices - Google Patents

Abstract

A method for producing the plug (1) or a coupling socket for electrical plug devices having a cable (3) whose cable end region (2) is surrounded, such that the material is integral, by a housing consisting of insulating material which can be cast or injection-moulded, has the following method steps: - the cable end region (2) is fitted into the intermediate space (interspace) (18) between two flat strips (4) which are aligned such that they are approximately superimposed and consist of the housing material, the cable (3) and its contact elements (19) running essentially at right angles to the longitudinal direction (5) of the flat strips (4), - the flat strips (4) are connected to one another, such that the material is integral, with the interposition of the cable end region (2), - the sandwich-like composite part which is formed from the cable end region (2) and the flat strip regions surrounding it is cut off by means of a cut running transversely with respect to the longitudinal direction (5) of the flat strips (4), - the connection of the flat strips (4) such that the material is integral and the cutting-off of the complete composite part take place in one process. <IMAGE>

Description

The invention relates to a method for producing a plug or a coupling socket for electrical plug devices with the features of the preamble of claim 1.

It is known to prefabricate electrical lines and then to extrusion-coat the line end region of the line with insulating material, in particular plastic, to form the plug or the coupling socket.
The cable is pre-assembled by an electrically conductive connection of the individual conductors with contact elements such as plug pins, sockets and, if applicable, protective contacts, and by their position and distance from one another. After the overmolding of the cable end area provided with the contact elements and after the material has cooled, the plug or the coupling socket is ready for use. The material connection created by the spraying process creates a moisture-tight unit between the line and the housing material of the plug or the coupling socket. In this way, for example, the Euro plugs are manufactured. Plugs or coupling sockets connected to the pipe with a material fit are used wherever plug devices are subject to increased moisture and moisture attack, for example in automobile construction.

The disadvantage of the spraying process is the use of complex spraying machines and devices for the external shaping of the plug or the coupling socket.

From US-A-3 392 070 a device for the mass production of coupling socket-like electrical connections is known. The electrical contact elements are formed by two adjacent cable lugs. So it is a 2-pin socket. A connecting cable is fixed to each cable lug in a known manner. There are two cable lugs each combined by a material connection of two flat strips to form a unit.

The known device contains a fixed and a movable die, the pressure surfaces of which are interrupted by recesses for the insertion and fixing of the cable lugs. Another flat band is arranged approximately congruently above a first flat band. The cable lugs are arranged in the space between the two flat strips. In order to produce the composite part consisting essentially of two cable lugs and the flat band areas surrounding them, the movable die is moved against the fixed die. The shape recesses of the fixed and the movable die correspond to each other and, when the two dies are closed, form a cavity for receiving the cable lug and the flat band areas surrounding it. The pressure surface areas of the matrices form heating surfaces for a material connection between the two flat strips. In the closed state of the two dies, the pressure surfaces corresponding to one another lie against one another with the interposition of the flat strips. A cable lug encased by both flat strips lies in each case in the form recesses.

To carry out the individual process steps, the movable die is structurally very complex. First, the movable die with its heating surfaces is moved against the corresponding heating surfaces of the stationary die. The flat band areas clamped in between the corresponding heating surfaces are first heated up and are thus cohesively connected to one another. The two matrices acting against each other remain in this position after the heating process, so that the cohesively connected flat strip areas can cool down. In a next step, a blade plate as part of the movable die is moved against the two pressure tools that remain in their closed position. Blades running perpendicular to the flat strips are fixed to the blade plate. When the blade plate is lowered, the blades separate the composite parts from the flat strips. Accordingly, the movable die for carrying out the known method must be constructed from components which are movable relative to one another. The overall structurally very complex design of the device causes unnecessarily high acquisition and maintenance costs. Another disadvantage is that the individual process steps for producing the composite part in a chronologically separate sequence be carried out and the manufacturing time of the composite parts is very long. This in turn increases the cost of manufacturing the individual composite part.

Starting from the disadvantages described, the invention is based on the object of simplifying the production of such plugs and coupling sockets in terms of production technology and of making them more cost-effective.

This object is achieved by the combination of features of claim 1.

Manufacturing time is saved by combining the material connection and separating it into a single work step. This saving is particularly important when it comes to the production of bulk items - as is the case with the manufacture of plugs or coupling sockets. Here, savings can also be felt in the sum of seconds between individual work steps. As a result, the production costs of the individual composite part can be reduced.

Additional manufacturing means for separating the composite parts are eliminated. The production as a whole is simplified since the means used are used simultaneously for the material connection and for the separation. The simultaneous use of individual components for several work steps also reduces the component expenditure of the device for carrying out the method. As a result, the manufacturing costs of the composite part can be reduced further.

According to claim 2, further production time is saved during the implementation of the method. The number of necessary manufacturing machines and devices is reduced again.

The re-cooling, which has not yet taken place completely during the material connection of the flat strip material and its separation, is advantageously used in accordance with claim 2 to carry out the shaping of the composite part which is common in many cases with low mechanical energy of the production means used. The shape embossing can be both the outline shape of the composite part and engravings, lettering or the like. act on the outer surfaces of the composite part.

The preforming of the flat strips with a negative relief results in a reduced degree of deformation in the material connection of the two flat strips. This improves the material security. In addition, the pre-embossed flat strips allow simple positive pre-fixing of the line end area between the two flat strips and the material connection by means of an adhesive.

Claim 4 relates to an advantageous implementation of individual process steps.

Claim 5 relates to an advantageous embodiment of the printing tools for producing the composite part in a cycle production.

Claim 6 relates to the combination of the clock production with a weld to produce the material connection.

According to claim 7, the work cycles for producing a certain number of composite parts are reduced. As a result, the production system is exposed to less wear. More composite parts are produced per unit of time, which makes the production system more cost-effective.

Claims 8 and 9 relate to measures for producing the composite parts in a flow production. As a result, the manufacturing system works even more cost-effectively. According to claim 9, the flow production is combined with a weld to produce the material connection. The flat strips are fed continuously to the printing tools.

Claim 10 relates to a type of process for producing the material connection.

Claim 11 enables the exact manufacture of the composite part with the desired outline shape and the desired cross section in a simple manner. For this purpose, the flat band regions inserted within the cavity formed by two corresponding shaped recesses are heated. The softened flat strip material penetrates the entire cavity of the mold recesses due to the compression of the printing tools. Any plug or coupling socket shape can thus be achieved solely by appropriate design and arrangement of the heating surfaces and the side walls of the recesses. Claim 11 also uses in advantageously the double function of the heating surface, namely on the one hand as part of the mold recess and on the other hand as a means for the material connection. The manufacturing effort of the printing tools and thus the entire device for performing the method is thus reduced. Furthermore, the double function of the heating surface ensures that there is not only a material connection between the two flat strips themselves, but also between the flat strips and the line end area. This leads to a strain relief of the line against the contact elements. This increases the service life of the plug or coupling socket.

The heating surfaces are preferably heated by electric current and at the same time support the compression of the two flat strip regions by their mechanical pressure effect and by their simultaneous softening the complete filling of the cavity formed by two corresponding recesses.

Claim 12 avoids any waste of the ribbon material. This makes it possible to dispense with complex recycling processes for processing the waste material as a reusable flat belt.

The cutting edges according to claim 11 and 12 also fulfill a double function. They are part of the form recesses and at the same time ensure the separation of the composite part. The component expenditure of the device for carrying out the method is thereby further reduced.

According to claim 13, the thermal energy required to produce the flat strips for further process steps, e.g. used for embossing or for material connection. This saves energy and thereby lowers the manufacturing costs of the composite part. In addition, the manufacturing time is reduced because the warm-up process for the welded or adhesive connection is at least partially eliminated.

Claim 14 relates to a preferred embodiment of the flat strips in order to facilitate the manufacture and to act as insulation of the line end area to protect against electrical hazards.

Flat strips designed according to claim 15 enable damage or breaks in the line, conductor or contact elements in the region of End of the line are recognizable. As a result, an electrical device connected to the plug device is additionally protected against electrical dangers. This also simplifies the cause analysis for an operator in the event of an electrical defect.

Claim 16 relates to a measure to ensure the standardized position and the standardized distance between the contact elements.

A fixing bridge designed according to claim 17 additionally supports the measures according to claim 16. The contact elements remain fixed in place during the implementation of the method.

The design of the fixing bridge according to claim 18 facilitates its integration as part of the connector or coupling socket housing. The connector remains as a moisture-tight unit. During the production of the material connection, the fixing bridge and flat strips are deformed in the same way, so that no additional weak points for possible damage or breaks occur in the finished composite part. In addition, the production of the material connection itself is facilitated due to the same material of the fixing bridge and flat strips.

According to claim 19, an error-free, standard-compliant manufacture of plug and coupling socket is guaranteed.

According to claim 20, the individual supply of a line end area between the two flat strips is superfluous. Likewise, complex feeding and holding devices for the line end areas can be dispensed with. Such end-to-end line areas favor the mass and flow production of the plug or the coupling socket.

According to claim 21, the automated manufacture of the plug or the coupling socket is facilitated. Such an alignment of the contact elements and line feeds also saves space when dimensioning the entire production system. The lining up of the line end areas according to claim 20 is thereby facilitated.

According to claim 22, the supply of the line end areas to the flat strips is additionally improved without special holding devices. The lined up Line end areas remain reliably in their mutual relative position during the implementation of the method. This supports a trouble-free production process.

According to claim 23, a particularly space-saving arrangement of line end areas is created during production. This means that a larger number of plugs or coupling sockets can be produced per unit of time. Since the flat strips according to claim 3 are preformed according to the surface shape of the line end regions, the waste or waste of the flat strips is reduced in this way.

The arrangement of the fixing bridges according to claim 24 has the effect that the production of the material connection between the flat strips and the line end area is not hindered.

According to claim 25, steps for removing the fixing bridges during the manufacturing process may be unnecessary. The fixing bridges thus have a double function as a holding and fixing means on the one hand and as an integral part of the plug or coupling socket housing on the other.

Fig. 1

eine schematische Darstellung der Herstellung eines Flachsteckers in einer Taktfertigung,

Fig. 2

eine perspektivische Darstellung zweier vorgeprägter Flachbänder mit den dazugehörigen Prägestempeln,

Fig. 3

eine perspektivische Teildarstellung zweier alternierend nebeneinanderliegender Leitungen, wobei die Kontaktelemente jeweils eines Leitungsendbereiches durch eine Fixierbrücke gehalten sind,

Fig. 4

die perspektivische Darstellung von vier alternierend nebeneinanderliegender Leitungen und zwei Fixierbrücken, wobei die beiden Fixierbrücken jeweils in ihrer Längsrichtung hintereinander alternierend die Leitungszuführung und die Kontaktelemente der vier Leitungen halten,

Fig. 5

die perspektivische Darstellung zweier Leitungen ensprechend Fig. 3, jedoch im Zwischenraum zwischen zwei vorgeprägten Flachbändern vor Vollzug der Stoffschluß-Verbindung mittels zweier ebenfalls dargestellter Schweißstempel,

Fig. 6

eine schematische Darstellung der Herstellung des Flachsteckers in einer Fließfertigung.

The subject matter of the invention is explained in more detail with reference to exemplary embodiments shown in the figures. Show it:

Fig. 1

1 shows a schematic representation of the manufacture of a flat connector in a cycle production,

Fig. 2

2 shows a perspective illustration of two pre-embossed flat strips with the associated embossing stamps,

Fig. 3

2 shows a perspective partial illustration of two lines lying next to one another in alternation, the contact elements of each line end area being held by a fixing bridge,

Fig. 4

the perspective representation of four alternately adjacent lines and two fixing bridges, the two fixing bridges alternately holding the line feed and the contact elements of the four lines one behind the other in their longitudinal direction,

Fig. 5

the perspective view of two lines corresponding to Fig. 3, but in the space between two pre-stamped flat strips before completion of the material connection by means of two welding stamps, also shown,

Fig. 6

is a schematic representation of the manufacture of the tab connector in a flow production.

The process implementation is essentially described with reference to FIG. 1. The illustration in FIG. 1 is limited to the essential functional parts of a manufacturing system for producing a connector. In the drawings, the procedure is explained using a two-pin flat connector 1 (Euro connector).
In principle, however, other types of plugs can also be produced, eg multi-pole round or angled plugs with possibly several protective contacts (eg BEN plugs).
Coupling sockets can also be manufactured in this way.

To manufacture the flat connector 1, a line end region 2 (FIG. 3) of a pre-assembled two-wire line 3 is connected to two flat strips 4 in a materially bonded manner.

The flat strips 4 extend essentially in a longitudinal direction 5. All rubber-like plastics known for the one-piece connector housing production are suitable as the material for the flat strips 4.
After extrusion from an extruder 6, which is only indicated schematically, the flat strips 4 are advanced in the longitudinal direction 5. The two flat belts 4 arranged parallel to one another are temporarily stored in a buffer memory 7, which is also only indicated schematically. The flat strips 4 can also be additionally processed, for example cleaned or coated, in the buffer store 7.
After leaving the buffer store, the flat strips 4 each pass into the space between a pressure stamp 8 and an embossing stamp 9.
The octagonal stamp 9 has eight stamping surfaces 10. The mutually facing inner sides of the flat strips 4, which act as contact sides 11, in FIG. 1 lie directly against an embossing surface 10 in the area of the stamp 9. As soon as the flat strip 4 lies against the embossing surface 10, the pressure stamp 8 is moved in a height direction 12 running perpendicular to the longitudinal direction 5 to the outside 13 of the flat strip 4 opposite the contact side 11. The pressure stamp 8 pressurized with a flat pressure surface 14, the outside 13 of the flat strip 4 in the area of the stamp 9. The stamp 8 and the stamp 9 act on the flat strip 4 in the manner of two clamping jaws. The embossing surfaces 10 are designed in such a way that the contact sides 11 of the flat strips 4 are embossed with a negative relief to the surface shape of the part of the line end region 2 (FIG. 3) to be accommodated by them.

After pre-embossing of the contact sides 11, the pressure stamps 8 are moved back against the height direction 12.
The stamp 9 can also have the function of a drive element for moving the flat strips 4 in the longitudinal direction 5. The embossing stamp 9 is driven, for example, by a motor and rotates clockwise around a stamp axis 15.

The pre-stamped flat strips 4 are moved in the longitudinal direction 5 in the direction of the space between two welding punches 16. The welding stamps 16 face each other with their welding surfaces 17. The welding surfaces 17 are arranged parallel to the flat strips 4. The distance between the two flat strips 4 in the area of the welding stamps 16 is less than during the pre-embossing of the contact sides 11. In the area of the welding stamps 16, the line end region 2 is introduced into an intermediate space 18 between the two flat strips 4.

In Fig. 1, a total of four line end areas 2 are introduced into the space 18. When viewed in the longitudinal direction 5 of the line end regions 2, alternatively effective plug pins 19 and a feed side 20 can be seen as contact elements of the flat plug 1. The longitudinal direction of the line end regions 2 runs essentially perpendicular to the plane of the drawing in FIG. 1.

The welding stamps 16, like the pressure stamps 8, are moved in the height direction 12. The flat strips 4 pressurized by the welding punches 16 reduce their mutual distance and embed the line end regions 2 in a form-fitting manner between them due to the pre-embossed contact sides 11. The two welding punches 16 clamp the two flat strips 4 and the line end area 2 between them in the manner of a vice. The welding is then carried out in order to produce a material connection between the flat strips 4 and the line end region 2. The sandwich-like composite part consisting of the layer sequence of flat strip 4 - line end region 2 - flat strip 4 is separated from the remaining region of the flat strips 4 after the welding. For this purpose, the welding surfaces 17 can additionally be designed as cutting tools. The cut is made in the vertical direction 12. After the composite part has been separated, the one-piece tab connector 1 is completed.

2, stamping surfaces 10 of two stamping dies 9 can be seen. The embossing surfaces 10 have a rectangular outer contour and are arranged in a plane spanned by the longitudinal direction 5 and a longitudinal line direction 21. The two stamping dies 9 are moved along a lifting direction 22 by holding and lifting devices (not shown). The stroke direction 22 corresponds to the height direction 12 (FIG. 1).

In the direction of the stroke direction 22, the outer contours of the two dies 9 are congruent.

While the two flat strips 4 are pre-embossed in FIG. 1 by a stroke movement of the pressure stamp 8 in the direction of the outer sides 13, the flat strip 4 in FIG. 2 are embossed in the direction of the contact sides 11 by a stroke movement. With this type of pre-embossing, pressure parts for generating a counter pressure with respect to the movable embossing dies 9 rest on the outer sides 13 of the flat strips 4, not shown here.

The flat strips 4 have a rectangular cross section along the stroke direction 22 and are already pre-embossed as negative reliefs 29 in accordance with the elevations of the embossing surfaces 10.
Exactly one half of the volume of the line end region 2 is inserted into the negative reliefs 29 of the flat strips 4 before the welding. For this purpose, the elevations of the embossing surfaces 10 are designed as an image of a volume half of the line end area 2.
The two stamping surfaces 10 are constructed identically. The elevations of the two embossing surfaces 10 face away from one another in the stroke direction 22. Each embossing surface has as elevations two volume halves of the line end area 2 lying next to one another in the longitudinal direction 5. The pin reliefs 23 assigned to the connector pins 19 of one volume half and the supply relief 24 assigned to the feed side 20 are the other volume half arranged in the longitudinal direction 5 adjacent. This results in a point-symmetrical structure of the embossing surface 10 in the viewing direction of the stroke direction 22. This configuration of the embossing surfaces 10 reduces the waste of the flat strips 4 and is particularly suitable for symmetrically constructed connectors.

The material connection of line end area 2 and flat strips 4 results in strain relief for line 3. The strain relief is further improved by a curved line guide in the area of the feed side 20. For this purpose, the elevations of the embossing surfaces 10 in the area of a strain relief relief 25 are curved. As a result, when the line end area 2 is inserted into the pre-embossments of the flat strips 4, a curved line course is forced in the area of the feed side 20.

3 two line end regions 2 lying side by side in the longitudinal direction 5 can be seen. The lines 3 extend essentially along the line longitudinal direction 21. It is arranged perpendicular to the longitudinal direction 5.
The line end regions 2 lie in a plane spanned by the longitudinal direction 5 and the line longitudinal direction 21. In the viewing direction of the height direction 12, their arrangement corresponds to the configuration of the embossing surfaces 10 in FIG. 2.

Each line end area 2 contains two conductors 26 corresponding to the two-pole flat plug 1. A plug pin 19 is fastened to the ends of each conductor 26 in an electrically contacting manner. The connector pins 19 are arranged in the longitudinal direction 21 of the line.
The line 3 is stripped in the area of the feed side 20 up to the ends of the conductors 26. As a result, the conductors 26 are freely movable in the line end region 2. The standardized distance can be established between the two connector pins 19 of a line end region 2. For this purpose, the plug pins 19 are positively locked into a fixing bridge 27. The fixing bridge 27 has rectangular outer contours and extends in the longitudinal direction 5. The fixing bridge 27 is pierced by two cutouts in the longitudinal direction 21 of the cable so that it can form-fit around the outer surface of the plug pins 19. The two fixing bridges 27 in FIG. 3 limit the extension of the line end region 2 in the longitudinal direction 21 of the line.

A total of four lines 3 can be seen in FIG. 4. The alternating arrangement of the line end regions 2 known from FIG. 3 is retained in FIG. 4. The fixing bridge 27 also has rectangular outer contours in FIG. 4, but is lengthened in the longitudinal direction 5 compared to the embodiment in FIG. 3. As a result, the two connector pins 19 and the feed side 20 of adjacent line end regions 2 snap into corresponding recesses in one and the same fixing bridge 27. All plug pins 19 and feed sides 20 are arranged parallel to one another in the longitudinal direction 21 of the line.
Viewed along the longitudinal direction 5, there are a plurality of rectangular notches 28 on the fixing bridge 27. The notches 28 can facilitate the positive locking of the plug pins 19 and the feed sides 20 into the fixing bridge 27. They can also serve as fixing means for feed devices when feeding the line end regions 2 into the intermediate space 18 (FIG. 1).
Each line end area 2 is held by two fixing bridges 27 of the same type. The two fixing bridges 27 are arranged parallel to one another. Their parallel spacing corresponds approximately to the longitudinal plugging of the cable end regions 2 in the longitudinal direction 21 of the cable. Thus, each cable end region 2 is held in the region of the plug pins 19 and in the region of the feed side 20 by a fixing bridge 27.
The fixing bridges 27 are preferably made of dimensionally stable plastic so that the relative position of the connector pins 19 and the feed side 20 relative to one another is preserved before the welding.

5 shows an arrangement for establishing a material connection between line end regions 2 and flat strips 4 by means of two welding punches 16.
The arrangement of the two line end regions 2 shown in FIG. 5 corresponds to the description in FIG. 3. The contact side 11 visible in FIG. 5 is embossed with four negative reliefs 29. Their design and arrangement correspond to the description in FIG. 2.

The two fixing bridges 27 are preferably made of the extruded flat strip material. After welding, they form a material unit with the flat strips 4.
For the flat strips 4, such materials are advantageous which have a relatively large surface hardness at ambient temperature, for example after externally protruding conductors 26 are bent in the direction of the plug pins 19 when the welding punches 16 move together and before the molding process associated with softening or liquefying the connector housing material. This prevents such conductors 26 from being able to protrude from the finished plug housing into its circumferential area.
The welding surfaces 17 have four shaped recesses 30 corresponding to the surface shape of the finished flat connector housing. Their arrangement corresponds to the arrangement of the four negative reliefs 29. The side walls of the mold recesses 30 running in the longitudinal direction 21 of the line are designed and effective as cutting edges 31.
The boundary walls of the form recesses 30 running in the longitudinal direction 5 are recessed approximately semicircularly, viewed in the longitudinal direction 21 of the line, in order to be able to insert the plug pins 19 or the feed side 20 into the welding punches 16 in a form-fitting manner during the welding.

Before the welding process, the two welding stamps 16 are moved towards one another in the height direction 12. You clamp the flat strips 4 and the cable end areas 2 between them in the manner of the jaws of a vice. The flat strips 4 are then welded over their entire area to the associated line end regions 2. Any known welding method, for example ultrasonic welding method, is conceivable for this purpose. Full-surface gluing is also possible.
During the complete movement of the two welding punches 16 in the vertical direction 12, the cutting edges 31 separate the finished plug housing from the remaining flat strip material.
During the welding process, the outer sides 13 of the flat strips 4 are embossed by the shape recesses 30. For this purpose, the shaped recesses 30 in the exemplary embodiment each have three groove-like embossing depressions 32 which extend in the longitudinal direction 5 and are arranged parallel to one another.
The material connection of the flat strips 4 to the line end area 2, the separation of the finished, sandwich-like composite part and the embossing of the outer sides 13 take place in one work step.

The parting line between the two flat strips 4 forms the plug pin level. With connector types other than the flat connector 1, the connector pins 19 or sockets and possibly protective contacts are not necessarily in a common one Level arranged. With such plugs, it is conceivable that three or more flat strips 4 are used for carrying out the method. In each case two flat strips 4 then fix at least one plug pin 19 or a socket between them and thus enable the sandwich-like housing structure of a plug or a coupling socket.

5, the two flat strips 4 have a cut surface 33 which extends approximately in the longitudinal direction 21 of the line. The course of the direction of the cut surface 33 corresponds approximately to the course of a side edge of the flat connector 1 in the longitudinal direction 21 of the line.
The cut surfaces 33 arise due to the separation of the finished composite parts by the cutting edges 31 during the previous work cycle.

In Fig. 1 and Fig. 5 it can be seen that the tab 1 is made in a cycle. The use of welding punches 16 with a large number of shaped recesses 30 is advantageous here in order to produce a large number of flat plugs 1 in one work cycle.

6 shows the manufacture of the tab connector 1 in a continuous production. There is therefore no flow stoppage due to a welding cycle.
A plurality of line end areas is arranged in the manner described in FIG. 4 by means of two fixing bridges 27 and is fed in the longitudinal direction 5 to the space between the two flat strips 4.
The two flat strips 4 are extruded from two separate, opposing extruders 6 and are first advanced in the height direction 12.
Each ribbon 4 is pre-embossed by a pressure roller 34 and an embossing roller 35. Printing roller 34 and embossing roller 35 are each shown in a circle in FIG. 6. While the outer surface of the pressure roller 34 abuts the outer side 13, the outer surface of the embossing roller 35 acts on the contact side 11. Both rollers rotate in the feed direction of the flat strip 4 and can support the movement of the flat strip 4 to the line end regions 2. The outer surface of the embossing roller 35 acts in the manner of the embossing surface 10 (FIG. 1, FIG. 2) and has a large number of relief-like elevations over its circumference.
The outer surface of the pressure roller 34 acts in the manner of the pressure surface 14 (FIG. 1).

After the embossing, the flat strips 4 are bent approximately in a quarter circle and are then aligned approximately in the longitudinal direction 5. In this area, the flat strips 4 receive the line end area 2 between them in a positive manner. Thereupon two welding rollers 36, shown in a circle in FIG. 6, act with their outer surfaces on the outer sides 13 of the flat belts 4. The two welding rollers 36 rotate in the longitudinal direction 5. The outer surfaces of the welding rollers 36 have the same function as the welding surfaces 17 (FIG. 5). A plurality of shape recesses 30 and cutting edges 31 are therefore arranged over the circumference of the welding rollers 36.

The flat strips 4 are preferably made of transparent material. Damage to the manufacture or use of the flat connector 1, for example wire breaks, can thereby be recognized from the outside.
The extruded flat strips 4 can be fed to the line end regions 2 continuously in an endless length. This facilitates the automated manufacture of the tab connector 1.
The feed movement of the flat belts 4 only has to be interrupted during the work cycle in a cycle production. This can be done, for example, by the buffer memory 7 (FIG. 1).

The symmetrical structure of the production plants (FIG. 1, FIG. 6) and the movement directions arranged essentially parallel or perpendicular to one another likewise favor the automated production of the flat connector 1.

Reference list

1

Flat connector

2nd

Line end range

3rd

management

4th

Flat ribbon

5

Longitudinal direction

6

Extruder

7

Buffer storage

8th

Pressure stamp

9

Embossing stamp

10th

Stamping surface

11

Contact page

12th

Height direction

13

Outside

14

Printing area

15

Stamp axis

16

Welding stamp

17th

Welding surface

18th

Space

19th

Connector pin

20th

Feed side

21

Longitudinal line

22

Stroke direction

23

Pen relief

24th

Feed relief

25th

Strain relief relief

26

ladder

27

Fixing bridge

28

notch

29

Negative relief

30th

Mold recess

31

Cutting edge

32

Embossing recess

33

Cutting surface

34

Pressure roller

35

Embossing roller

36

Welding roller

Claims (25)

Method for producing a plug (1) or a coupling socket for electrical plug devices with a line (3) containing at least one conductor (26), the line end region (2) of which contains at least one contact element (19) from a housing consisting of pourable or sprayable insulating material surrounded by the following process steps: - The cable end area (2) is introduced into the intermediate space (18) between two approximately congruent flat tapes (4) made of housing material, the line (3) and its contact elements (19) essentially at right angles to the longitudinal direction (5) of the flat tapes (4 ) run, - The flat strips (4) are integrally connected with each other with the interposition of the line end area (2) the sandwich-like composite part formed from the line end region (2) with the flat band regions surrounding it is separated by a cut running transversely to the longitudinal direction (5) of the flat bands (4), characterized,
that the material connection of the flat strips (4) and the separation of the finished composite part take place in one work step. Method according to claim 1,
characterized,
that - The material connection of the flat strips (4), - The separation of the finished composite part and - A shaped embossing of the composite part done in one step. Method according to claim 1,
characterized,
that at least the mutually facing contact sides (11) of the flat strips (4) are embossed with a negative relief (29) to the surface shape of the line end region (2) to be accommodated by them. Method according to one of claims 1 to 3,
characterized,
that the cohesive connection and the separation and, if necessary, the embossing are carried out by pressure tools (8, 9, 16, 34, 35, 36) working against one another. Method according to claim 4,
characterized,
that the printing tools are acting on the flat strips (4) in a stamp-like manner (8, 9, 16). Method according to claim 5,
characterized,
that the stamps are welding stamps (16). Method according to claim 5,
characterized,
that the printing tools (8,9,16) produce several adjacent composite parts with one work cycle. Method according to claim 4,
marked by
Printing rollers (34, 35, 36) as printing tools for the production of the connector (1) or the coupling socket in a continuous production. A method according to claim 8,
characterized,
that the rollers are rotary welding tools (36). Method according to one or more of the preceding claims,
marked by
an ultrasonic welding as a material connection. Method according to one or more of the preceding claims,
characterized
that mutually facing pressure surfaces of the printing tools each contain at least one shaped recess (30) for receiving the line end area (2) and the flat band areas surrounding it, the shaped recess (30) - A floor as a heating surface [= welding surface (17)] for the material connection and - As a cutting (31) trained side walls for the separation consists. A method according to claim 11,
characterized,
that two adjacent recesses (30) lie directly next to one another and are separated from one another by the common side wall designed as a cutting edge (31). Method according to one or more of the preceding claims,
characterized,
that it is carried out using the extrusion heat as welding heat for the welded connection or to accelerate the setting of an adhesive connection without significant delay following the extrusion of the flat strips (4) from an extruder (6). Method according to one or more of the preceding claims,
characterized,
that the flat strips (4) consist of plastic. The method of claim 14
marked by
a transparency of the plastic. Method according to one or more of the preceding claims,
characterized,
that when carrying out the method, a plurality of contact elements (19) of the line end area lying next to one another are held at a nominal distance and a nominal orientation from one another by a fixing bridge (27). A method according to claim 16,
characterized,
that the fixing bridge (27) consists of dimensionally stable plastic. Method according to claim 16 or 17,
characterized,
that the fixing bridge (27) consists of the same material as the flat strips (4). Method according to one of claims 16 to 18,
characterized,
that the contact elements (19) are positively engaged in recesses in the fixing bridge (27). Method according to one of claims 16 to 19,
characterized,
that a fixing bridge (27) in the manner of a cartridge belt detects the line end areas (2) of a plurality of lines (3) and adjoins them side by side. A method according to claim 20,
marked by
a parallel alignment of the contact elements (19) and line feeds (20) of lines (3) held adjacent to the fixing bridge (27). A method according to claim 20 or 21,
characterized,
that the line end areas (2) are held by two spaced, approximately parallel fixing bridges (27). The method of claim 22
characterized,
that the fixing bridges (27) in their longitudinal direction (5) alternately hold the line feed (20) and the contact elements (19) in each case one line end area (2). A method according to claim 22 or 23,
characterized,
that the distance between the two fixing bridges (27) corresponds approximately to the width of the flat strips (4). Method according to one or more of the preceding claims,
characterized,
that the fixing bridges (27) with the flat strips (4) are integrally connected.

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